SARS-COV-2 VACCINES

Abstract

Disclosed herein are vaccine compositions that include SARS-CoV-2 MHC epitope-encoding cassettes and/or full-length SARS-CoV-2 proteins. Also disclosed are nucleotides, cells, and methods associated with the compositions including their use as vaccines.

Claims

1. (canceled)

2. An antigen-based vaccine comprising: (i) at least one SARS-CoV-2 derived immunogenic polypeptide, or at least one SARS-CoV-2 derived nucleic acid sequence encoding the at least one SARS-CoV-2 derived immunogenic polypeptide, wherein the immunogenic polypeptide comprises: at least one MHC class I epitope comprising a polypeptide sequence as set forth in Table A, at least one MHC class II epitope comprising a polypeptide sequence as set forth in Table B, at least one MHC class I epitope comprising a polypeptide sequence as set forth in Table C, optionally wherein the at least one MHC I epitope is present in a concatenated polypeptide sequence as set forth in SEQ ID NO:57 or SEQ ID NO:58, at least one polypeptide sequence as set forth in Table 10, or an epitope-containing fragment thereof, optionally wherein the at least one polypeptide sequence is present in a concatenated polypeptide sequence as set forth in SEQ ID NO:92, at least one polypeptide sequence as set forth in Table 12A, Table 12B, or Table 12C, or an epitope-containing fragment thereof, optionally wherein the at least one polypeptide sequence is present in a concatenated polypeptide comprising each of the sequences set forth in Table 12A, Table 12B, or Table 12C, optionally wherein the concatenated polypeptide comprises the order of sequences set forth in Table 12A, Table 12B, or Table 12C, at least one MHC class I epitope comprising a polypeptide sequence as set forth in Table A and/or Table C or MHC class II epitope comprising a polypeptide sequence as set forth in Table B, wherein the encoded SARS-CoV-2 immunogenic polypeptide is conserved between SARS-CoV-2 and a Coronavirus species and/or sub-species other than SARS-CoV-2, optionally wherein the Coronavirus species and/or sub-species other than SARS-CoV-2 is Severe acute respiratory syndrome (SARS) and/or Middle East respiratory syndrome (MERS), one or more validated epitopes and/or at least 4, 5, 6, or 7 predicted epitopes, wherein at least 85%, 90%, or 95% of a population carries at least one HLA validated to present at least one of the one or more validated epitopes and/or at least one HLA predicted to present each of the at least 4, 5, 6, or 7 predicted epitopes, a SARS-CoV-2 Spike protein comprising a Spike polypeptide sequence as set forth in SEQ ID NO:59 or an epitope-containing fragment thereof, optionally wherein the Spike polypeptide comprises a D614G mutation with reference to SEQ ID NO:59, and optionally wherein the Spike polypeptide is encoded by the nucleotide sequence shown in SEQ ID NO:79, SEQ ID NO:83, SEQ ID NO:85, or SEQ ID NO:87, a SARS-CoV-2 modified Spike protein comprising a mutation selected from the group consisting of: a Spike R682 mutation, a Spike R815 mutation, a Spike K986P mutation, a Spike V987P mutation, and combinations thereof with reference to the Spike polypeptide sequence as set forth in SEQ ID NO:59, and optionally wherein the modified Spike protein comprises a polypeptide sequence as set forth in SEQ ID NO:60 or SEQ ID NO:90 or an epitope-containing fragment thereof, a SARS-CoV-2 Membrane protein comprising a Membrane polypeptide sequence as set forth in SEQ ID NO:61 or an epitope-containing fragment thereof, a SARS-CoV-2 Nucleocapsid protein comprising a Nucleocapsid polypeptide sequence as set forth in SEQ ID NO:62 or an epitope-containing fragment thereof, a SARS-CoV-2 Envelope protein comprising an Envelope polypeptide sequence as set forth in SEQ ID NO:63 or an epitope-containing fragment thereof, a variant of any of the above comprising a mutation found in 1% or greater of SARS-CoV-2 subtypes, optionally wherein the variant comprises a SARS-CoV-2 variant shown in Table 1, and/or optionally wherein the variant comprises a SARS-CoV-2 variant Spike protein comprising a Spike D614G mutation with reference to the Spike polypeptide sequence as set forth in SEQ ID NO:59, a SARS-CoV-2 variant Spike protein corresponding to a B.1.351 SARS-CoV-2 isolate optionally comprising the Spike polypeptide sequence as set forth in SEQ ID NO: 112, or a SARS-CoV-2 variant Spike protein corresponding to a B.1.1.7 SARS-CoV-2 isolate optionally comprising the Spike polypeptide sequence as set forth in SEQ ID NO:110, or combinations thereof; and  wherein the immunogenic peptide optionally comprises a N-terminal linker and/or a C-terminal linker (ii) optionally, at least one MHC class II antigen; and (iii) optionally, at least one GPGPG amino acid linker sequence (SEQ ID NO:56).

3. The composition of claim 2, wherein the at least one SARS-CoV-2 derived immunogenic polypeptide comprises: (A) a SARS-CoV-2 Spike protein comprising a Spike polypeptide sequence as set forth in SEQ ID NO:59 or an epitope-containing fragment thereof and a SARS-CoV-2 Membrane protein comprising a Membrane polypeptide sequence as set forth in SEQ ID NO:61 or an epitope-containing fragment thereof, optionally wherein the SARS-CoV-2 derived nucleic acid sequence comprises the sequence as set forth in SEQ ID NO:66 or SEQ ID NO:67, (B) a SARS-CoV-2 Spike protein comprising a Spike polypeptide sequence as set forth in SEQ ID NO:59 or an epitope-containing fragment thereof and at least one MHC I epitope comprising a polypeptide sequence as set forth in Table C, optionally wherein the at least one MHC I epitope is present in a concatenated polypeptide sequence as set forth in SEQ ID NO:57 or SEQ ID NO:58, optionally wherein the SARS-CoV-2 derived nucleic acid sequence comprises the sequence as set forth in SEQ ID NO:68, (C) a SARS-CoV-2 Spike protein comprising a Spike polypeptide sequence as set forth in SEQ ID NO:59 or an epitope-containing fragment thereof, optionally wherein the Spike polypeptide comprises a D614G mutation with reference to SEQ ID NO:59, and optionally wherein the SARS-CoV-2 derived nucleic acid sequence comprises the sequence as set forth in SEQ ID NO:69, SEQ ID NO:79, SEQ ID NO:83, SEQ ID NO:85, or SEQ ID NO:87, (D) at least one MHC class I epitope comprising a polypeptide sequence as set forth in Table C, optionally wherein the at least one MHC I epitope is present in a concatenated polypeptide sequence as set forth in SEQ ID NO:57 or SEQ ID NO:58, optionally wherein the SARS-CoV-2 derived nucleic acid sequence comprises the sequence as set forth in SEQ ID NO:64 or SEQ ID NO:65, (E) a SARS-CoV-2 modified Spike protein comprising a mutation selected from the group consisting of: a Spike D614G mutation, a Spike R682V mutation, a Spike R815N mutation, a Spike K986P mutation, a Spike V987P mutation, and combinations thereof with reference to the Spike polypeptide sequence as set forth in SEQ ID NO:59, and optionally wherein the modified Spike protein comprises a polypeptide sequence as set forth in SEQ ID NO:60 or SEQ ID NO:90 or an epitope-containing fragment thereof, optionally wherein the SARS-CoV-2 derived nucleic acid sequence comprises the sequence as set forth in SEQ ID NO:70 or SEQ ID NO:89, (F) a SARS-CoV-2 Spike protein comprising a Spike polypeptide sequence as set forth in SEQ ID NO:59 or an epitope-containing fragment thereof, a SARS-CoV-2 Membrane protein comprising a Membrane polypeptide sequence as set forth in SEQ ID NO:61 or an epitope-containing fragment thereof, a SARS-CoV-2 Nucleocapsid protein comprising a Nucleocapsid polypeptide sequence as set forth in SEQ ID NO:62 or an epitope-containing fragment thereof, and a SARS-CoV-2 Envelope protein comprising an Envelope polypeptide sequence as set forth in SEQ ID NO:63 or an epitope-containing fragment thereof, optionally wherein the SARS-CoV-2 derived nucleic acid sequence comprises the sequence as set forth in SEQ ID NO:71, (G) a SARS-CoV-2 Spike protein comprising a Spike polypeptide sequence as set forth in SEQ ID NO:59 or an epitope-containing fragment thereof, a SARS-CoV-2 Membrane protein comprising a Membrane polypeptide sequence as set forth in SEQ ID NO:61 or an epitope-containing fragment thereof, and a SARS-CoV-2 Nucleocapsid protein comprising a Nucleocapsid polypeptide sequence as set forth in SEQ ID NO:62 or an epitope-containing fragment thereof, optionally wherein the SARS-CoV-2 derived nucleic acid sequence comprises the sequence as set forth in SEQ ID NO:72, (H) a SARS-CoV-2 Spike protein comprising a Spike polypeptide sequence as set forth in SEQ ID NO:59 or an epitope-containing fragment thereof, a SARS-CoV-2 Membrane protein comprising a Membrane polypeptide sequence as set forth in SEQ ID NO:61 or an epitope-containing fragment thereof, and a SARS-CoV-2 Envelope protein comprising an Envelope polypeptide sequence as set forth in SEQ ID NO:63 or an epitope-containing fragment thereof, optionally wherein the SARS-CoV-2 derived nucleic acid sequence comprises the sequence as set forth in SEQ ID NO:73, (I) at least one MHC class I epitope comprising a polypeptide sequence as set forth in Table C, optionally wherein the at least one MHC I epitope is present in a concatenated polypeptide sequence as set forth in SEQ ID NO:57 or SEQ ID NO:58, a SARS-CoV-2 Spike protein comprising a Spike polypeptide sequence as set forth in SEQ ID NO:59 or an epitope-containing fragment thereof, a SARS-CoV-2 Membrane protein comprising a Membrane polypeptide sequence as set forth in SEQ ID NO:61 or an epitope-containing fragment thereof, and a SARS-CoV-2 Envelope protein comprising an Envelope polypeptide sequence as set forth in SEQ ID NO:63 or an epitope-containing fragment thereof, optionally wherein the SARS-CoV-2 derived nucleic acid sequence comprises the sequence as set forth in SEQ ID NO:74, (J) a SARS-CoV-2 Spike protein comprising a Spike polypeptide sequence as set forth in SEQ ID NO:59 or an epitope-containing fragment thereof and a SARS-CoV-2 modified Spike protein comprising a mutation selected from the group consisting of: a Spike D614G mutation, a Spike R682V mutation, a Spike R815N mutation, a Spike K986P mutation, a Spike V987P mutation, and combinations thereof with reference to the Spike polypeptide sequence as set forth in SEQ ID NO:59, and optionally wherein the modified Spike protein comprises a polypeptide sequence as set forth in SEQ ID NO:60 or SEQ ID NO:90 or an epitope-containing fragment thereof, (K) a SARS-CoV-2 Spike protein comprising a modified Spike polypeptide sequence as set forth in SEQ ID NO:90 or an epitope-containing fragment thereof and at least one polypeptide sequence as set forth in Table 10, or an epitope-containing fragment thereof, optionally wherein the at least one polypeptide sequence is present in a concatenated polypeptide sequence as set forth in SEQ ID NO:92, (L) at least one polypeptide sequence as set forth in Table 12A, Table 12B, or Table 12C, or an epitope-containing fragment thereof, optionally wherein the at least one polypeptide sequence is present in a concatenated polypeptide comprising each of the sequences set forth in Table 12A, Table 12B, or Table 12C, optionally wherein the concatenated polypeptide comprises the order of sequences set forth in Table 12A, Table 12B, or Table 12C, (M) at least one MHC class I epitope comprising a polypeptide sequence as set forth in Table A and/or Table C or MHC class II epitope comprising a polypeptide sequence as set forth in Table B, wherein the encoded SARS-CoV-2 immunogenic polypeptide is conserved between SARS-CoV-2 and a Coronavirus species and/or sub-species other than SARS-CoV-2, optionally wherein the Coronavirus species and/or sub-species other than SARS-CoV-2 is Severe acute respiratory syndrome (SARS) and/or Middle East respiratory syndrome (MERS), or (N) one or more validated epitopes and/or at least 4, 5, 6, or 7 predicted epitopes, wherein at least 85%, 90%, or 95% of a population carries at least one HLA validated to present at least one of the one or more validated epitopes and/or at least one HLA predicted to present each of the at least 4, 5, 6, or 7 predicted epitopes.

4. The composition of claim 2, wherein the antigen-based vaccine comprises: (i) at least 18 SARS-CoV-2 derived immunogenic polypeptides, or SARS-CoV-2 derived nucleic acid sequences encoding the same, as set forth in Table C, optionally wherein the immunogenic polypeptide sequences are linked in a concatenated polypeptide sequence as set forth in SEQ ID NO:57 or SEQ ID NO:58; (ii) at least 15 SARS-CoV-2 derived immunogenic polypeptides, or SARS-CoV-2 derived nucleic acid sequences encoding the same, as set forth in Table 10, optionally wherein the immunogenic polypeptide sequences are linked in a concatenated polypeptide sequence as set forth in SEQ ID NO:92; (iii) the nucleotide sequence as set forth in SEQ ID NO:93.

5-7. (canceled)

8. The composition of claim 2, wherein the antigen-based vaccine comprises an antigen expression system, wherein the antigen expression system comprises. (a) one or more vectors, the one or more vectors comprising: a vector backbone, optionally wherein the vector backbone comprises an alphavirus vector, optionally wherein the alphavirus vector is a Venezuelan equine encephalitis virus vector, and wherein the backbone comprises: (i) at least one promoter nucleotide sequence, and (ii) at least one polyadenylation (poly(A)) sequence; and (b) an antigen cassette, wherein the antigen cassette is inserted into the vector backbone such that the antigen cassette is operably linked to the at least one promoter nucleotide sequence, and wherein the antigen cassette comprises: (i) at least one SARS-CoV-2 derived nucleic acid sequence encoding the at least one SARS-CoV-2 derived immunogenic polypeptide; (ii) optionally, a second promoter nucleotide sequence operably linked to the SARS-CoV-2 derived nucleic acid sequence; and (iii) optionally, at least one MHC class II epitope-encoding nucleic acid sequence; (iv) optionally, at least one nucleic acid sequence encoding a GPGPG amino acid linker sequence (SEQ ID NO:56); and (v) optionally, at least one second poly(A) sequence, wherein the second poly(A) sequence is a native poly(A) sequence or an exogenous poly(A) sequence to the vector backbone, optionally wherein the exogenous poly(A) sequence comprises an SV40 poly(A) signal sequence or a Bovine Growth Hormone (BGH) poly(A) signal sequence.

9-12. (canceled)

13. The composition of claim 2, the composition further comprising a nanoparticulate delivery vehicle.

14-19. (canceled)

20. The composition of claim 8, wherein the one or more vectors comprise: (i) one or more +-stranded RNA vectors; (ii) a 5′ 7-methylguanosine (m7g) cap; (iii) RNA vectors produced by in vitro transcription; and/or (iv) vectors that are self-replicating within a mammalian cell.

21-26. (canceled)

27. The composition of claim 8, wherein the vector backbone comprises at least sequences for nonstructural protein-mediated amplification, a 26S promoter sequence, and a poly(A) sequence encoded by the nucleotide sequence of a Venezuelan equine encephalitis virus, wherein sequences for nonstructural protein-mediated amplification are selected from the group consisting of: an alphavirus 5′ UTR, a 51-nt CSE, a 24-nt CSE, a 26S subgenomic promoter sequence, a 19-nt CSE, an alphavirus 3′ UTR, or combinations thereof, and/or wherein the backbone does not encode structural virion proteins capsid, E2 and E1.

28-31. (canceled)

32. The composition of claim 8, wherein the alphavirus comprises the sequence of SEQ ID NO:3 or SEQ ID NO:5 further comprising a deletion between base pair 7544 and 11175, wherein the antigen cassette is inserted at position 7544 to replace the deletion between base pairs 7544 and 11175 as set forth in the sequence of SEQ ID NO:3 or SEQ ID NO:5.

33-35. (canceled)

36. The composition of claim 8, wherein the at least one promoter nucleotide sequence is the native 26S promoter nucleotide sequence encoded by the backbone.

37-50. (canceled)

51. The composition of claim 8, wherein the second promoter nucleotide sequence is present and comprises a 26S promoter nucleotide sequence, optionally comprising multiple 26S promoter nucleotide sequences, wherein each 26S promoter nucleotide sequence provides for transcription of one or more of the separate open reading frames.

52-56. (canceled)

57. The composition of claim 2, wherein at least one of the at least one SARS-CoV-2 derived nucleic acid sequences encodes (i) a polypeptide sequence or portion thereof that is presented by MHC class I; (ii) encodes a polypeptide sequence or portion thereof that is presented by MHC class II; and/or (iii) a polypeptide sequence or portion thereof capable of stimulating a B cell response, optionally wherein the polypeptide sequence or portion thereof capable of stimulating a B cell response comprises a full-length protein, a protein domain, a protein subunit, or an antigenic fragment predicted or known to be capable of being bound by an antibody.

58-60. (canceled)

61. The composition of claim 2, wherein at least one of the at least one SARS-CoV-2 derived nucleic acid sequences is linked to a distinct SARS-CoV-2 derived nucleic acid sequence with a nucleic acid sequence encoding a linker, optionally wherein the linker comprises one or more native sequences flanking the antigen derived from the cognate protein of origin and that is at least 2, 3, 4, 5, 6, 7, 8, 9, 10, 11, 12, 13, 14, 15, 16, 17, 18, 19, 20, or 2-20 amino acid residues in length.

62-68. (canceled)

69. The composition of claim 2, wherein each of the at least one SARS-CoV-2 derived immunogenic polypeptide comprises a polypeptide sequence or portion thereof that is less than 50%, less than 49%, less than 48%, less than 47%, less than 46%, less than 45%, less than 45%, less than 43%, less than 42%, less than 41%, less than 40%, less than 39%, less than 38%, less than 37%, less than 36%, less than 35%, less than 34%, or less than 33% of the corresponding full-length SARS-CoV-2 protein.

70. The composition of claim 2, wherein each of the at least one SARS-CoV-2 derived immunogenic polypeptide comprises a polypeptide sequence or portion thereof that does not encode a functional protein, functional protein domain, functional protein subunit, or functional protein fragment of the corresponding SARS-CoV-2 protein.

71. The composition of claim 2, wherein two or more of the at least one SARS-CoV-2 derived immunogenic polypeptide comprises—are derived from the same SARS-CoV-2 gene.

72. The composition of claim 71, wherein nucleic acid sequences encoding the two or more SARS-CoV-2 derived immunogenic polypeptide comprises derived from the same SARS-CoV-2 gene are ordered such that a first nucleic acid sequence cannot be immediately followed by or linked to a second nucleic acid sequence if the second nucleic acid sequence follows first nucleic acid sequence in the corresponding SARS-CoV-2 gene.

73. The composition of claim 2, wherein the at least one SARS-CoV-2 derived immunogenic polypeptide comprises at least 2-10, 2, 3, 4, 5, 6, 7, 8, 9, 10, 11-20, 15-20, 11-100, 11-200, 11-300, 11-400, 11, 12, 13, 14, 15, 16, 17, 18, 19, 20 or up to 400 immunogenic polypeptides or nucleic acid sequences encoding the same.

74-79. (canceled)

80. The composition of claim 2, wherein each MHC class I SARS-CoV-2 derived immunogenic polypeptide is-between 8 and 35 amino acids in length, optionally 9-17, 9-25, 8, 9, 10, 11, 12, 13, 14, 15, 16, 17, 18, 19, 20, 21, 22, 23, 24, 25, 26, 27, 28, 29, 30, 31, 32, 33, 34 or 35 amino acids in length.

81-125. (canceled)

126. A pharmaceutical composition comprising the composition of claim 2 and a pharmaceutically acceptable carrier.

127-139. (canceled)

140. A method for treating a SARS-CoV-2 infection or preventing a SARS-CoV-2 infection in a subject, the method comprising administering to the subject the composition of claim 2.

141-142. (canceled)

143. The method of claim 140, wherein the subject expresses at least one HLA allele predicted or known to present a MHC class I or MHC class II epitope associated with the at least one SARS-CoV-2 derived immunogenic polypeptide.

144-164. (canceled)

165. A method of assessing a subject at risk for a SARS-CoV-2 infection or having a SARS-CoV-2 infection, comprising the steps of: a) determining or having determined: 1) if the subject has an HLA allele predicted or known to present an antigen included in an antigen-based vaccine, b) determining or having determined from the results of (a) that the subject is a candidate for therapy with the antigen-based vaccine of claim 2 when the subject expresses the HLA allele, and c) optionally, administering of having administered the antigen-based vaccine of claim 2 to the subject.

166-189. (canceled)

190. The method of any of claim 140, wherein the method comprises a heterologous prime/boost strategy, wherein the heterologous prime/boost strategy comprises (a) an identical antigen cassette encoded by different vaccine platforms, (b) different antigen cassettes encoded by the same vaccine platform, and/or (c) different antigen cassettes encoded by different vaccine platforms.

191. The method of claim 190, wherein the different antigen cassettes comprise (i) a Spike-encoding cassette and a separate T cell epitope encoding cassette and/or (ii) cassettes encoding distinct epitopes and/or antigens derived from different isolates of SARS-CoV-2.

192. (canceled)

193. The composition of claim 2, wherein the at least one SARS-CoV-2 derived immunogenic polypeptide comprises each of: (i) a Spike protein comprising: (a) the SARS-CoV-2 Spike protein comprising a Spike polypeptide sequence as set forth in SEQ ID NO:59 or an epitope-containing fragment thereof, optionally wherein the Spike polypeptide comprises a D614G mutation with reference to SEQ ID NO:59, and optionally wherein the Spike polypeptide is encoded by the sequence shown in SEQ ID NO:79, SEQ ID NO:83, SEQ ID NO:85, or SEQ ID NO:87, (b) a SARS-CoV-2 variant Spike protein with reference to SARS-CoV-2 isolate NC_045512.2, optionally comprising a mutation found in 1% or greater of SARS-CoV-2 subtypes and/or distinct SARS-CoV-2 isolates, or (c) the SARS-CoV-2 modified Spike protein comprising a mutation selected from the group consisting of: a Spike D614G mutation, a Spike R682V mutation, a Spike R815N mutation, a Spike K986P mutation, a Spike V987P mutation, and combinations thereof with reference to the Spike polypeptide sequence as set forth in SEQ ID NO:59, optionally wherein the modified Spike protein comprises a polypeptide sequence as set forth in SEQ ID NO:60 or SEQ ID NO:90, and wherein optionally the SARS-CoV-2 modified Spike protein further comprises mutations present in a SARS-CoV-2 variant Spike protein with reference to SARS-CoV-2 isolate NC_045512.2; and (ii) at least one of the at least one polypeptide sequences as set forth in Table 10, Table 12A, Table 12B, or Table 12C, optionally wherein the at least one polypeptide sequence is present in a concatenated polypeptide comprising each of the sequences set forth in Table 10, Table 12A, Table 12B, or Table 12C, optionally wherein the concatenated polypeptide comprises the order of sequences set forth in Table 10, Table 12A, Table 12B, or Table 12C.

194. The composition of claim 2, wherein the at least one SARS-CoV-2 derived immunogenic polypeptide comprises each of: (i) a Spike protein comprising: (a) a SARS-CoV-2 variant Spike protein with reference to SARS-CoV-2 isolate NC_045512.2, optionally comprising a mutation found in 1% or greater of SARS-CoV-2 subtypes and/or distinct isolates, and (b) a Spike D614G mutation, a Spike R682V mutation, a Spike R815N mutation, a Spike K986P mutation, a Spike V987P mutation with reference to the Spike polypeptide sequence as set forth in SEQ ID NO:59; and (ii) a concatenated polypeptide comprising each of the sequences set forth in Table 12C, wherein the concatenated polypeptide comprises the order of sequences set forth in Table 12C; and (iii) a SARS-CoV-2 Nucleocapsid protein.

Description

BRIEF DESCRIPTION OF THE SEVERAL VIEWS OF THE DRAWINGS

[0170] These and other features, aspects, and advantages of the present invention will become better understood with regard to the following description, and accompanying drawings, where:

[0171] FIG. 1 presents a schematic of the SARS-CoV-2 genome structure depicting the at least 14 open reading frames (ORF) identified in. Figure adapted from Zhou et al. (2020) [A pneumonia outbreak associated with a new coronavirus of probable bat origin. Nature, 579(January)].

[0172] FIG. 2 depicts the 16 cleavage products of the replicase ORF1ab and related information. Figure adapted from Wu et al. (2020). [A new coronavirus associated with human respiratory disease in China. Nature, 579(January)]

[0173] FIG. 3 depicts the general vaccination approach of producing a balanced immune response inducing both neutralizing antibodies (from B cells) as well as effector and memory CD8+ T cell responses for maximum efficacy. SARS-CoV-2 genome structure adapted from Zhou et al. (2020) [A pneumonia outbreak associated with a new coronavirus of probable bat origin. Nature, 579(January)].

[0174] FIG. 4 demonstrates the known prevalence of the wildtype and D614G variant SARS-Cov-2 Spike protein over time across various geographic locations.

[0175] FIG. 5 demonstrates coverage of cassettes encoding only Spike or encoding Spike and the additional predicted concatenated T cell epitopes over the four populations shown. The first column demonstrates the number of SARS-CoV-2 epitopes predicted to be presented and the second column demonstrates the expected number of presented epitopes, based on a 0.2 PPV. Each row shows the protection coverage of each population if a certain number of epitopes is used.

[0176] FIG. 6A illustrates the number of predicted epitopes presented by each MHC class II allele separately for the Spike protein or the additional predicted concatenated T cell epitopes.

[0177] FIG. 6B illustrates the number of the number of SARS-CoV-2 epitopes predicted to be presented over the four populations shown from cassettes encoding only Spike (top panel) or encoding Spike and the additional predicted concatenated T cell epitopes (bottom panel).

[0178] FIG. 7A presents the number of training samples containing Class I alleles (with at least 10 samples).

[0179] FIG. 7B presents a histogram depicting the number of training samples per Class I allele versus the number of alleles.

[0180] FIG. 8A demonstrates T cell responses for mice immunized with a ChAdV68 vector encoding the SARS-CoV-2 Spike protein. Shown is IFNγ ELISpot following ex vivo stimulation (o/n) with overlapping peptide pools (15 aa long, 11 aa overlap) spanning SPIKE antigen. Left panel presents SFCs per 10.sup.6 splenocytes for each separate peptide pool tested (Mean+/−SE for each pool, N=6 per group (n=3 for naive)). Right panel presents SFCs per 10.sup.6 splenocytes for summed response across both peptide pools (Mean+/−SD, sum of response to two pools for each animal). Background corrected to DMSO control for each sample and pool.

[0181] FIG. 8B demonstrates T cell responses for mice immunized with a SAM vector encoding the SARS-CoV-2 Spike protein. Shown is IFNγ ELISpot following ex vivo stimulation (o/n) with overlapping peptide pools (15 aa long, 11 aa overlap) spanning SPIKE antigen. as SFCs per 10.sup.6 splenocytes for each separate peptide pool tested.

[0182] FIG. 8C demonstrates T cell responses for mice immunized with a SAM vector encoding the SARS-CoV-2 Spike protein. Shown is IFNγ ELISpot following ex vivo stimulation (o/n) with overlapping peptide pools (15 aa long, 11 aa overlap) spanning SPIKE antigen as SFCs per 10.sup.6 splenocytes for combined response across both peptide pools.

[0183] FIG. 9 depicts a schematic of SARS-CoV-2 vaccine efficacy studies in mice.

[0184] FIG. 10A shows a Western blot using an anti-Spike S2 antibody for Spike expression in vectors encoding various Spike variations.

[0185] FIG. 10B shows a Western blot using an anti-Spike S1 antibody for Spike expression in vectors encoding various Spike variations.

[0186] FIG. 10C shows a Western blot using an anti-Spike S1 antibody for Spike expression in vectors encoding full-length Spike, Spike S1 alone, or Spike S2 alone.

[0187] FIG. 10D shows a Western blot using an anti-Spike S2 antibody for Spike expression in vectors encoding full-length Spike, Spike S1 alone, or Spike S2 alone.

[0188] FIG. 11 shows a Western blot using an anti-Spike S2 antibody for Spike expression in vectors encoding various sequence-optimized Spike variations.

[0189] FIG. 12A depicts a schematic of PCR-based assay to assess RNA splicing of SARS-CoV-2 transcripts.

[0190] FIG. 12B shows PCR amplicons for encoded Spike proteins. Left panel depicts amplicons from cDNA templates from infected 293 cells (“ChAd-Spike (IDT) cDNA”) or from the plasmid encoding the SARS-CoV-2 Spike cassette (“Spike Plasmid”). Right panel depicts amplicons from the cDNA of 293 cells infected with a vector encoding Spike S1 alone (“SpikeS1”) or full-length Spike (“Spike”).

[0191] FIG. 13 shows PCR amplicons for encoded Spike proteins from the cDNA of 293 cells infected with vector encoding various Spike variations.

[0192] FIG. 14 presents estimated coverages for the percentage of the indicated ancestry populations having at least one HLA estimated to receive at least one immunogenic epitope encoded by TCE5, where receipt of the immunogenic peptide presentation is considered to occur when an individual's HLA is either (1) known to present an encoded epitope (“validated epitope”), or (2) predicted to present at least 4 (Col. 1), 5 (Col. 2), 6 (Col. 3), or 7 (Col. 4) encoded epitopes (“predicted epitope”; EDGE score>0.01). FA=African American, API=Asian or Pacific Islander, EUR=European, HIS=Hispanic

[0193] FIG. 15A presents T cell responses (left panel), Spike-specific IgG antibodies (middle panel) and neutralizing antibodies (right panel) following administration of ChAdV-platforms with Spike-encoding cassettes featuring different sequence optimizations “IDTSpike.sub.g” (shown as “Spike V1” or “v1”) or “CTSpike.sub.g” (shown as “Spike V2” or “v2”). Balb/c mice immunized with 1×10.sup.11 VP ChAdV-based vaccine platform.

[0194] FIG. 15B presents T cell responses (left panel), Spike-specific IgG antibodies (middle panel) and neutralizing antibodies (right panel) following administration of SAM-platforms with Spike-encoding cassettes featuring different sequence optimizations “IDTSpike.sub.g” (shown as “Spike V1” or “v1”) or “CTSpike.sub.g” (shown as “Spike V2” or “v2”). Balb/c mice immunized with 10 μg SAM-based vaccine platform.

[0195] FIG. 16 presents Spike-specific IgG antibody production following administration of either ChAdV-platform (left panel) or SAM-platform (right panel) with unmodified or modified (“CTSpikeF2P.sub.g” shown as “SpikeF2P”) Spike-encoding cassettes (all vectors utilize Spike sequence v2). Balb/c mice immunized with 1×10.sup.11 VP ChAdV-based vaccine platform or 10 μg SAM-based vaccine platform, as indicated.

[0196] FIG. 17A presents T cell responses to Spike (left panel) and T cell responses to the encoded T cell epitopes (right panel) following administration of ChAdV-platforms with a modified Spike-encoding only cassette (“CTSpikeF2P.sub.g” shown as “Spike”) and modified Spike together with additional non-Spike T cell epitopes encoded TCE5 (shown as “Spike TCE”). Balb/c mice immunized with 1×10.sup.11 VP ChAdV-based vaccine platform. Shown is IFNγ ELISpot, 2 weeks post immunization. T cell response to overlapping peptide pools spanning either Spike, Nucleocapsid, or Orf3a.

[0197] FIG. 17B presents T cell responses to Spike (left panel) and T cell responses to the encoded T cell epitopes (right panel) following administration of SAM-platforms with a modified Spike-encoding only cassette (“CTSpikeF2P.sub.g” shown as “Spike”) and modified Spike together with additional non-Spike T cell epitopes encoded TCE5 (shown as “TCE Spike”). Balb/c mice immunized with 10 μg SAM-based vaccine platform. Shown is IFNγ ELISpot, 2 weeks post immunization. T cell response to overlapping peptide pools spanning either Spike, Nucleocapsid, or Orf3a.

[0198] FIG. 18A presents T cell responses to Spike (top panel; IFNg ELISpot. Sum of response to 8 overlapping peptide pools spanning Spike antigen), T cell responses to the encoded T cell epitopes (middle panel; IFNg ELISpot. Sum of response to 3 overlapping peptide pools spanning NCap, Membrane, and Orf3a), and Spike-specific IgG antibodies (bottom panel; S1 IgG binding measured by MSD ELISA. Interpolated endpoint titer. Geomean, geometric SD) following immunization with SAM constructs including “IDTSpike.sub.g” alone (left columns), IDTSpike.sub.g expressed from a first subgenomic promoter followed by TCE5 expressed from a second subgenomic promoter (middle columns), or TCE5 expressed from a first subgenomic promoter followed by IDTSpike.sub.g expressed from a second subgenomic promoter (right columns). For T cell responses, Balb/c mice were immunized with 10 ug of each vaccine, n=6/group. Splenocyte isolation at 2-weeks post immunization. For IgG response, Balb/c mice immunized with 10 ug of each vaccine, n=4/group. Serum collected and analyzed at 4-weeks post immunization.

[0199] FIG. 18B presents T cell responses to Spike (top panel; IFNg ELISpot. Sum of response to 8 overlapping peptide pools spanning Spike antigen), T cell responses to the encoded T cell epitopes (middle panel; IFNg ELISpot. Sum of response to 3 overlapping peptide pools spanning NCap, Membrane, and Orf3a), and Spike-specific IgG antibodies (bottom panel; S1 IgG binding measured by MSD ELISA. Interpolated endpoint titer. Geomean, geometric SD) following immunization with SAM constructs including “IDTSpike.sub.g” alone (first column), IDTSpike.sub.g expressed from a first subgenomic promoter followed by TCE6 or TCE7 expressed from a second subgenomic promoter (columns 2 and 4, respectively), or TCE6 or TCE7 expressed from a first subgenomic promoter followed by IDTSpike.sub.g expressed from a second subgenomic promoter (columns 3 and 5, respectively). For T cell responses, Balb/c mice were immunized with 10 ug of each vaccine, n=6/group. Splenocyte isolation at 2-weeks post immunization. For IgG response, Balb/c mice immunized with 10 ug of each vaccine, n=4/group. Serum collected and analyzed at 4-weeks post immunization.

[0200] FIG. 18C presents T cell responses to Spike (top panel; IFNg ELISpot. Sum of response to 2 overlapping peptide pools spanning Spike antigen), T cell responses to the encoded T cell epitopes (middle panel; IFNg ELISpot. Sum of response to 2 overlapping peptide pools spanning NCap and Orf3a), and Spike-specific IgG antibodies (bottom panel; S1 IgG binding measured by MSD ELISA. Interpolated endpoint titer. Geomean, geometric SD) following immunization with SAM constructs including “CTSpike.sub.g” alone (first column), CTSpike.sub.g expressed from a first subgenomic promoter followed by TCE5 or TCE8 expressed from a second subgenomic promoter (columns 2 and 4, respectively), or TCE5 or TCE8 expressed from a first subgenomic promoter followed by CTSpike.sub.g expressed from a second subgenomic promoter (columns 3 and 5, respectively). For T cell responses, Balb/c mice were immunized with 10 ug of each vaccine, n=6/group. Splenocyte isolation at 2-weeks post immunization. For IgG response, Balb/c mice immunized with 10 ug of each vaccine, n=4/group. Serum collected and analyzed at 4-weeks post immunization.

[0201] FIG. 19A presents T cell responses across multiple Spike T cell epitope pools (left panel), Spike-specific IgG antibody titer over time (right top panel) and neutralizing antibody titer over time (right bottom panel) following administration of ChAdV-platforms with a Spike-encoding cassette featuring “CTSpike.sub.g”. Balb/c mice immunized with 1×10.sup.11 VP ChAdV-based vaccine platform. T cell response is IFNγ ELISpot, 2 weeks post immunization to 8 overlapping peptide pools spanning Spike antigen.

[0202] FIG. 19B presents T cell responses across multiple Spike T cell epitope pools (left panel), Spike-specific IgG antibody titer over time (right top panel) and neutralizing antibody titer over time (right bottom panel) following administration of with a Spike-encoding cassette featuring “CTSpike.sub.g”. Balb/c mice immunized with 10 μg SAM-based vaccine platform. Shown is IFNγ ELISpot, 2 weeks post immunization. T cell response is IFNγ ELISpot, 2 weeks post immunization to 8 overlapping peptide pools spanning Spike antigen.

[0203] FIG. 20A presents a heterologous immunization regimen in mice (top panel) and T cell responses across multiple Spike T cell epitope pools (bottom panel) following administration of a ChAdV-platform priming dose including a Spike-encoding cassette featuring “CTSpike.sub.g” then subsequent administration of a SAM platform boosting dose including a Spike-encoding cassette featuring “IDTSpike.sub.g”. Mice immunized with 6×10.sup.9 VP ChAdV-based vaccine platform and 10 μg SAM-based vaccine platform. T cell response is to 8 overlapping peptide pools spanning Spike antigen. IFNg ELISpot. Mean+/−SEM.

[0204] FIG. 20B presents Spike-specific IgG antibody titer at the indicated times (left panel; ELISA. Geomean endpoint titer, geometric SD) and neutralizing antibody titer at the indicated times (right panel; Pseudovirus neutralizing titer. Geomean, geometric SD) following administration of a ChAdV-platform priming dose including a Spike-encoding cassette featuring “CTSpike.sub.g” then subsequent administration of a SAM platform boosting dose including a Spike-encoding cassette featuring “IDTSpike.sub.g”. Mice immunized with 6×10.sup.9 VP ChAdV-based vaccine platform and 10 μg SAM-based vaccine platform.

[0205] FIG. 21A presents a heterologous immunization regimen in NHP (top panel) and peak T cell responses across multiple Spike T cell epitope pools (middle and bottom panels) following administration of a ChAdV-platform priming dose including a Spike-encoding cassette featuring “CTSpike.sub.g” then subsequent administration of a SAM platform boosting dose including a Spike-encoding cassette featuring “IDTSpike.sub.g”. NHPs (n=5) immunized with 1×10.sup.12 VP ChAdV-based vaccine platform and 100 μg SAM-based vaccine platform.

[0206] FIG. 21B presents Spike-specific IgG antibody titers over time (top left panel), neutralizing antibody titers over time (bottom left panel), and neutralizing antibody titers compared to titers found in convalescent human sera (right panel) following administration of a ChAdV-platform priming dose including a Spike-encoding cassette featuring “CTSpike.sub.g” then subsequent administration of a SAM platform boosting dose including a Spike-encoding cassette featuring “IDTSpike.sub.g”. NHPs (n=5) immunized with 1×10.sup.12 VP ChAdV-based vaccine platform and 100 μg SAM-based vaccine platform.

[0207] FIG. 22A presents a homologous immunization prime/boost regimen in mice (top panel) and T cell responses to Spike (bottom panel) following administration of a SAM platform including a Spike-encoding cassette featuring “IDTSpike.sub.D”. Balb/c mice were immunized with 10 μg SAM-based vaccine platform.

[0208] FIG. 22B presents Spike-specific IgG antibody titers (left panel) and neutralizing antibody titers at the indicated times (right panel) following administration of a SAM platform including a Spike-encoding cassette featuring “IDTSpike.sub.D”. Balb/c mice were immunized with 10 μg SAM-based vaccine platform.

[0209] FIG. 23 presents a homologous immunization prime/boost regimen in mice (top panel), Spike-specific IgG antibody titers (middle panels), neutralizing antibody titers (bottom panels) over time, and neutralizing antibody titers compared to titers found in convalescent human sera (bottom right panel) following administration of a SAM platform including a Spike-encoding cassette featuring “IDTSpike.sub.G”. Balb/c mice were immunized with 30 μg SAM-based vaccine platform.

[0210] FIG. 24A presents a map of sequences included in TCE10 for Nucleocapsid, including frames with flanking sequences, validated epitopes, predicted epitopes, mutations, and overlap between frames and mutations.

[0211] FIG. 24B presents a map of sequences included in TCE10 for ORF3a, including frames with flanking sequences, validated epitopes, predicted epitopes, mutations, and overlap between frames and mutations.

[0212] FIG. 24C presents a map of sequences included in TCE10 for nsp3, including frames with flanking sequences, validated epitopes, predicted epitopes, mutations, and overlap between frames and mutations.

[0213] FIG. 24D presents a map of sequences included in TCE10 for Membrane, including frames with flanking sequences, validated epitopes, predicted epitopes, mutations, and overlap between frames and mutations.

[0214] FIG. 24E presents a map of sequences included in TCE10 for nsp4, including frames with flanking sequences, validated epitopes, predicted epitopes, mutations, and overlap between frames and mutations.

[0215] FIG. 24F presents a map of sequences included in TCE10 for nsp12, including frames with flanking sequences, validated epitopes, predicted epitopes, mutations, and overlap between frames and mutations.

[0216] FIG. 25A presents a map of sequences included in TCE9 for nsp12, including frames with flanking sequences, validated epitopes, predicted epitopes, mutations, and overlap between frames and mutations.

[0217] FIG. 25B presents a map of sequences included in TCE9 for nsp4, including frames with flanking sequences, validated epitopes, predicted epitopes, mutations, and overlap between frames and mutations.

[0218] FIG. 25C presents a map of sequences included in TCE9 for Membrane, including frames with flanking sequences, validated epitopes, predicted epitopes, mutations, and overlap between frames and mutations.

[0219] FIG. 25D presents a map of sequences included in TCE9 for nsp3, including frames with flanking sequences, validated epitopes, predicted epitopes, mutations, and overlap between frames and mutations.

[0220] FIG. 25E presents a map of sequences included in TCE9 for ORF3a, including frames with flanking sequences, validated epitopes, predicted epitopes, mutations, and overlap between frames and mutations.

[0221] FIG. 25F presents a map of sequences included in TCE9 for Nucleocapsid, including frames with flanking sequences, validated epitopes, predicted epitopes, mutations, and overlap between frames and mutations.

[0222] FIG. 25G presents a map of sequences included in TCE9 for nsp6, including frames with flanking sequences, validated epitopes, predicted epitopes, mutations, and overlap between frames and mutations.

[0223] FIG. 26A presents a map of sequences included in TCE11 for nsp12, including frames with flanking sequences, validated epitopes, predicted epitopes, mutations, and overlap between frames and mutations.

[0224] FIG. 26B presents a map of sequences included in TCE11 for Membrane, including frames with flanking sequences, validated epitopes, predicted epitopes, mutations, and overlap between frames and mutations.

[0225] FIG. 26C presents a map of sequences included in TCE11 for nsp4, including frames with flanking sequences, validated epitopes, predicted epitopes, mutations, and overlap between frames and mutations.

[0226] FIG. 26D presents a map of sequences included in TCE11 for nsp3, including frames with flanking sequences, validated epitopes, predicted epitopes, mutations, and overlap between frames and mutations.

[0227] FIG. 27 presents the percentages of shared candidate 9-mer epitope distribution between SARS-CoV-2 and SARS-CoV (left panel) and between SARS-CoV-2 and MERS (right panel).

[0228] FIG. 28 presents T cell responses in PBMCs from convalescent SARS-CoV-2 donors (Cohort 1) tested directly ex vivo (i.e., without IVS expansion) to Spike and TCE5-encoded epitopes assessed by IFNγ ELISpot against the indicated peptide pools (see Tables D-F).

[0229] FIG. 29 presents T cell responses in IVS-expanded PBMCs from convalescent SARS-CoV-2 donors (Cohort 1) to Spike and TCE5-encoded epitopes assessed by IFNγ ELISpot against the indicated peptide pools (see Tables D-F).

[0230] FIG. 30 presents T cell responses in IVS-expanded PBMCs from convalescent SARS-CoV-2 donors (Cohort 2) to Spike and TCE5-encoded epitopes assessed by IFNγ ELISpot against the indicated peptide pools (see Tables D-F). ULOQ: Upper Limit of Quantitation

[0231] FIG. 31 presents T cell responses in a selection of IVS-expanded PBMCs from convalescent SARS-CoV-2 donors (Cohort 1 and Cohort 2) to Spike and TCE5-encoded epitopes assessed by IFNγ ELISpot against the indicated peptide pools (see Tables D-F). ULOQ: Upper Limit of Quantitation

[0232] FIG. 32 presents T cell responses in IVS-expanded PBMCs from convalescent SARS-CoV-2 donors (Cohort 1), including either CD4 or CD8 depleted PBMCs, to Spike and TCE5-encoded epitopes assessed by IFNγ ELISpot against the indicated peptide pools (see Tables D-F).

[0233] FIG. 33A presents T cell-mediated killing of targets as assessed by Incucyte® for (1) DMSO+Target only control [filled circles]; (2) peptides+Target only control [open circles]; (3) DMSO+Target+PBMC effectors control [filled squares]; and (4) Peptides+Target+PBMC effectors [open squares]. Shown is data for A*03:01 targets; Cohort 2 donor 169923; Validated Pool.

[0234] FIG. 33B presents T cell-mediated killing of targets as assessed by Incucyte® for (1) DMSO+Target only control [filled circles]; (2) peptides+Target only control [open circles]; (3) DMSO+Target+PBMC effectors control [filled squares]; and (4) Peptides+Target+PBMC effectors [open squares]. Shown is data for A*02:01 targets; Cohort 2 donor 389341; ORF3a Pool.

[0235] FIG. 33C presents T cell-mediated killing of targets as assessed by Incucyte® for (1) DMSO+Target only control [filled circles]; (2) peptides+Target only control [open circles]; (3) DMSO+Target+PBMC effectors control [filled squares]; and (4) Peptides+Target+PBMC effectors [open squares]. Shown is data for A*02:01 targets; Cohort 2 donor 941176; Validated Pool.

[0236] FIG. 33D presents T cell-mediated killing of targets as assessed by Incucyte® for (1) DMSO+Target only control [filled circles]; (2) peptides+Target only control [open circles]; (3) DMSO+Target+PBMC effectors control [filled squares]; and (4) Peptides+Target+PBMC effectors [open squares]. Shown is data for A*02:01 targets; Cohort 2 donor 941176; ORF3a Pool.

[0237] FIG. 33E presents T cell-mediated killing of targets as assessed by Incucyte® for (1) DMSO+Target only control [filled circles]; (2) peptides+Target only control [open circles]; (3) DMSO+Target+PBMC effectors control [filled squares]; and (4) Peptides+Target+PBMC effectors [open squares]. Shown is data for A*02:01 targets; Cohort 2 donor 941176; Nucleocapsid Pool.

[0238] FIG. 33F presents T cell-mediated killing of targets as assessed by Incucyte® for (1) DMSO+Target only control [filled circles]; (2) peptides+Target only control [open circles]; (3) DMSO+Target+PBMC effectors control [filled squares]; and (4) Peptides+Target+PBMC effectors [open squares]. Shown is data for A*01:01 targets; Cohort 2 donor 941176; Validated Pool.

[0239] FIG. 33G presents T cell-mediated killing of targets as assessed by Incucyte® for (1) DMSO+Target only control [filled circles]; (2) peptides+Target only control [open circles]; (3) DMSO+Target+PBMC effectors control [filled squares]; and (4) Peptides+Target+PBMC effectors [open squares]. Shown is data for A*01:01 targets; Cohort 2 donor 941176; ORF3a Pool.

[0240] FIG. 33H presents T cell-mediated killing of targets as assessed by Incucyte® for (1) DMSO+Target only control [filled circles]; (2) peptides+Target only control [open circles]; (3) DMSO+Target+PBMC effectors control [filled squares]; and (4) Peptides+Target+PBMC effectors [open squares]. Shown is data for A*30:01 targets; Cohort 2 donor 627934; Validated Pool.

[0241] FIG. 33I presents T cell-mediated killing of targets as assessed by Incucyte® for (1) DMSO+Target only control [filled circles]; (2) peptides+Target only control [open circles]; (3) DMSO+Target+PBMC effectors control [filled squares]; and (4) Peptides+Target+PBMC effectors [open squares]. Shown is data for A*30:01 targets; Cohort 2 donor 627934; Nucleocapsid Pool.

[0242] FIG. 33J presents T cell-mediated killing of targets as assessed by Incucyte® for (1) DMSO+Target only control [filled circles]; (2) peptides+Target only control [open circles]; (3) DMSO+Target+PBMC effectors control [filled squares]; and (4) Peptides+Target+PBMC effectors [open squares]. Shown is data for A*03:01 targets; Cohort 2 donor 627934; Validated Pool.

[0243] FIG. 33K presents T cell-mediated killing of targets as assessed by Incucyte® for (1) DMSO+Target only control [filled circles]; (2) peptides+Target only control [open circles]; (3) DMSO+Target+PBMC effectors control [filled squares]; and (4) Peptides+Target+PBMC effectors [open squares]. Shown is data for A*03:01 targets; Cohort 2 donor 627934; Nucleocapsid Pool.

[0244] FIG. 33L presents T cell-mediated killing of targets as assessed by Incucyte® for (1) DMSO+Target only control [filled circles]; (2) peptides+Target only control [open circles]; (3) DMSO+Target+PBMC effectors control [filled squares]; and (4) Peptides+Target+PBMC effectors [open squares]. Shown is data for A*11:01 targets; Cohort 2 donor 602232; Validated Pool.

[0245] FIG. 34 illustrates homologous and heterologous prime/boost regimens in Indian rhesus macaques assessing ChAdV and SAM vaccine platforms encoding different isolates of the SARS-CoV-2 Spike protein.

[0246] FIG. 35A presents T cell responses across multiple Spike T cell epitope pools (top panel; Mean+−SE for each pool), T cell responses for individual NHPs directed to a single large Spike T cell epitope pool over time (middle panel), and Spike-specific IgG antibody titers over time (bottom panel) for Group 1. n=5 NHPs

[0247] FIG. 35B presents T cell responses across multiple Spike T cell epitope pools (top panel; Mean+−SE for each pool), T cell responses for individual NHPs directed to a single large Spike T cell epitope pool over time (middle panel), and Spike-specific IgG antibody titers over time (bottom panel) for Group 2. n=5 NHPs

[0248] FIG. 35C presents T cell responses across multiple Spike T cell epitope pools (top panel; Mean+−SE for each pool), T cell responses for individual NHPs directed to a single large Spike T cell epitope pool over time (middle panel), and Spike-specific IgG antibody titers over time (bottom panel) for Group 5. n=5 NHPs

[0249] FIG. 35D presents T cell responses across multiple Spike T cell epitope pools (top panel; Mean+−SE for each pool), T cell responses for individual NHPs directed to a single large Spike T cell epitope pool over time (middle panel), and Spike-specific IgG antibody titers over time (bottom panel) for Group 6. n=5 NHPs

[0250] FIG. 36 presents summaries of T cell responses for individual NHPs directed to a single large Spike T cell epitope pool over time (top panel), T cell responses to the TCE5-encoded epitopes (middle panel), and Spike-specific IgG antibody titers over time (bottom panel) for Group 1. n=5 NHPs

[0251] FIG. 37 presents neutralizing antibody production to both the D614G pseudovirus (left panels) and B.1.351 pseudovirus (right panels) following Boost 1 (left columns) and Boost 2 (right columns) for each of the NHP Groups.

[0252] FIG. 38 presents neutralizing antibody production comparing the relative Nab titer levels against each of the pseudoviruses following Boost 1 (top panels) and following Boost 2 (bottom panels).

DETAILED DESCRIPTION

I. Definitions

[0253] In general, terms used in the claims and the specification are intended to be construed as having the plain meaning understood by a person of ordinary skill in the art. Certain terms are defined below to provide additional clarity. In case of conflict between the plain meaning and the provided definitions, the provided definitions are to be used.

[0254] As used herein the term “antigen” is a substance that stimulates an immune response. An antigen can be a neoantigen. An antigen can be a “shared antigen” that is an antigen found among a specific population, e.g., a specific population of SARS-CoV-2 patients with or at risk of infection for an infectious disease.

[0255] As used herein the term “antigen-based vaccine” is a vaccine composition based on one or more antigens, e.g., a plurality of antigens. The vaccines can be nucleotide-based (e.g., virally based, RNA based, or DNA based), protein-based (e.g., peptide based), or a combination thereof.

[0256] As used herein the term “candidate antigen” is a mutation or other aberration giving rise to a sequence that may represent an antigen.

[0257] As used herein the term “coding region” is the portion(s) of a gene that encode protein.

[0258] As used herein the term “coding mutation” is a mutation occurring in a coding region.

[0259] As used herein the term “ORF” means open reading frame.

[0260] As used herein the term “missense mutation” is a mutation causing a substitution from one amino acid to another.

[0261] As used herein the term “nonsense mutation” is a mutation causing a substitution from an amino acid to a stop codon or causing removal of a canonical start codon.

[0262] As used herein the term “frameshift mutation” is a mutation causing a change in the frame of the protein.

[0263] As used herein the term “indel” is an insertion or deletion of one or more nucleic acids.

[0264] As used herein, the term percent “identity,” in the context of two or more nucleic acid or polypeptide sequences, refer to two or more sequences or subsequences that have a specified percentage of nucleotides or amino acid residues that are the same, when compared and aligned for maximum correspondence, as measured using one of the sequence comparison algorithms described below (e.g., BLASTP and BLASTN or other algorithms available to persons of skill) or by visual inspection. Depending on the application, the percent “identity” can exist over a region of the sequence being compared, e.g., over a functional domain, or, alternatively, exist over the full length of the two sequences to be compared.

[0265] For sequence comparison, typically one sequence acts as a reference sequence to which test sequences are compared. When using a sequence comparison algorithm, test and reference sequences are input into a computer, subsequence coordinates are designated, if necessary, and sequence algorithm program parameters are designated. The sequence comparison algorithm then calculates the percent sequence identity for the test sequence(s) relative to the reference sequence, based on the designated program parameters. Alternatively, sequence similarity or dissimilarity can be established by the combined presence or absence of particular nucleotides, or, for translated sequences, amino acids at selected sequence positions (e.g., sequence motifs).

[0266] Optimal alignment of sequences for comparison can be conducted, e.g., by the local homology algorithm of Smith & Waterman, Adv. Appl. Math. 2:482 (1981), by the homology alignment algorithm of Needleman & Wunsch, J. Mol. Biol. 48:443 (1970), by the search for similarity method of Pearson & Lipman, Proc. Nat'l. Acad. Sci. USA 85:2444 (1988), by computerized implementations of these algorithms (GAP, BESTFIT, FASTA, and TFASTA in the Wisconsin Genetics Software Package, Genetics Computer Group, 575 Science Dr., Madison, Wis.), or by visual inspection (see generally Ausubel et al., infra).

[0267] One example of an algorithm that is suitable for determining percent sequence identity and sequence similarity is the BLAST algorithm, which is described in Altschul et al., J. Mol. Biol. 215:403-410 (1990). Software for performing BLAST analyses is publicly available through the National Center for Biotechnology Information.

[0268] As used herein the term “non-stop or read-through” is a mutation causing the removal of the natural stop codon.

[0269] As used herein the term “epitope” is the specific portion of an antigen typically bound by an antibody or T cell receptor.

[0270] As used herein the term “immunogenic” is the ability to stimulate an immune response, e.g., via T cells, B cells, or both.

[0271] As used herein the term “HLA binding affinity” “MHC binding affinity” means affinity of binding between a specific antigen and a specific MHC allele.

[0272] As used herein the term “bait” is a nucleic acid probe used to enrich a specific sequence of DNA or RNA from a sample.

[0273] As used herein the term “variant” is a difference between a subject's nucleic acids and the reference human genome used as a control.

[0274] As used herein the term “variant call” is an algorithmic determination of the presence of a variant, typically from sequencing.

[0275] As used herein the term “polymorphism” is a germline variant, i.e., a variant found in all DNA-bearing cells of an individual.

[0276] As used herein the term “somatic variant” is a variant arising in non-germline cells of an individual.

[0277] As used herein the term “allele” is a version of a gene or a version of a genetic sequence or a version of a protein.

[0278] As used herein the term “HLA type” is the complement of HLA gene alleles.

[0279] As used herein the term “nonsense-mediated decay” or “NMD” is a degradation of an mRNA by a cell due to a premature stop codon.

[0280] As used herein the term “exome” is a subset of the genome that codes for proteins. An exome can be the collective exons of a genome.

[0281] As used herein the term “logistic regression” is a regression model for binary data from statistics where the logit of the probability that the dependent variable is equal to one is modeled as a linear function of the dependent variables.

[0282] As used herein the term “neural network” is a machine learning model for classification or regression consisting of multiple layers of linear transformations followed by element-wise nonlinearities typically trained via stochastic gradient descent and back-propagation.

[0283] As used herein the term “proteome” is the set of all proteins expressed and/or translated by a cell, group of cells, or individual.

[0284] As used herein the term “peptidome” is the set of all peptides presented by MHC-I or MHC-II on the cell surface. The peptidome may refer to a property of a cell or a collection of cells (e.g., the infectious disease peptidome, meaning the union of the peptidomes of all cells that are infected by the infectious disease).

[0285] As used herein the term “ELISPOT” means Enzyme-linked immunosorbent spot assay—which is a common method for monitoring immune responses in humans and animals.

[0286] As used herein the term “dextramers” is a dextran-based peptide-MHC multimers used for antigen-specific T-cell staining in flow cytometry.

[0287] As used herein the term “tolerance or immune tolerance” is a state of immune non-responsiveness to one or more antigens, e.g. self-antigens.

[0288] As used herein the term “central tolerance” is a tolerance affected in the thymus, either by deleting self-reactive T-cell clones or by promoting self-reactive T-cell clones to differentiate into immunosuppressive regulatory T-cells (Tregs).

[0289] As used herein the term “peripheral tolerance” is a tolerance affected in the periphery by downregulating or anergizing self-reactive T-cells that survive central tolerance or promoting these T cells to differentiate into Tregs.

[0290] The term “sample” can include a single cell or multiple cells or fragments of cells or an aliquot of body fluid, taken from a subject, by means including venipuncture, excretion, ejaculation, massage, biopsy, needle aspirate, lavage sample, scraping, surgical incision, or intervention or other means known in the art.

[0291] The term “subject” encompasses a cell, tissue, or organism, human or non-human, whether in vivo, ex vivo, or in vitro, male or female. The term subject is inclusive of mammals including humans.

[0292] The term “mammal” encompasses both humans and non-humans and includes but is not limited to humans, non-human primates, canines, felines, murines, bovines, equines, and porcines.

[0293] The term “clinical factor” refers to a measure of a condition of a subject, e.g., disease activity or severity. “Clinical factor” encompasses all markers of a subject's health status, including non-sample markers, and/or other characteristics of a subject, such as, without limitation, age and gender. A clinical factor can be a score, a value, or a set of values that can be obtained from evaluation of a sample (or population of samples) from a subject or a subject under a determined condition. A clinical factor can also be predicted by markers and/or other parameters such as gene expression surrogates. Clinical factors can include infection type (e.g., Coronavirus species), infection sub-type (e.g., SARS-CoV-2 variant), and medical history.

[0294] The term “antigen-encoding nucleic acid sequences derived from an infection” refers to nucleic acid sequences obtained from infected cells or an infectious disease organism, e.g. via RT-PCR; or sequence data obtained by sequencing the infected cell or infectious disease organism and then synthesizing the nucleic acid sequences using the sequencing data, e.g., via various synthetic or PCR-based methods known in the art. Derived sequences can include nucleic acid sequence variants, such as sequence-optimized nucleic acid sequence variants (e.g., codon-optimized and/or otherwise optimized for expression), that encode the same polypeptide sequence as the corresponding native infectious disease organism nucleic acid sequence. Derived sequences can include nucleic acid sequence variants that encode a modified infectious disease organism polypeptide sequence having one or more (e.g., 1, 2, 3, 4, or 5) mutations relative to a native infectious disease organism polypeptide sequence. For example, a modified polypeptide sequence can have one or more missense mutations relative to the native polypeptide sequence of an infectious disease organism protein.

[0295] The term “SARS-CoV-2 nucleic acid sequence encoding an immunogenic polypeptide” refers to nucleic acid sequences obtained from a SARS-CoV-2 virus, e.g. via RT-PCR; or sequence data obtained by sequencing a SARS-CoV-2 virus or a SARS-CoV-2 virus infected cell, and then synthesizing the nucleic acid sequences using the sequencing data, e.g., via various synthetic or PCR-based methods known in the art. Derived sequences can include nucleic acid sequence variants, such as sequence-optimized nucleic acid sequence variants (e.g., codon-optimized and/or otherwise optimized for expression), that encode the same polypeptide sequence as the corresponding native SARS-CoV-2 nucleic acid sequence. Derived sequences can include nucleic acid sequence variants that encode a modified SARS-CoV-2 polypeptide sequence having one or more (e.g., 1, 2, 3, 4, or 5) mutations relative to a native SARS-CoV-2 polypeptide sequence. For example, a modified Spike polypeptide sequence can have one or more mutations such as one or more missense mutations of R682, R815, K986P, or V987P relative to the native spike polypeptide sequence of a SARS-CoV-2 protein.

[0296] The term “alphavirus” refers to members of the family Togaviridae, and are positive-sense single-stranded RNA viruses. Alphaviruses are typically classified as either Old World, such as Sindbis, Ross River, Mayaro, Chikungunya, and Semliki Forest viruses, or New World, such as eastern equine encephalitis, Aura, Fort Morgan, or Venezuelan equine encephalitis and its derivative strain TC-83. Alphaviruses are typically self-replicating RNA viruses.

[0297] The term “alphavirus backbone” refers to minimal sequence(s) of an alphavirus that allow for self-replication of the viral genome. Minimal sequences can include conserved sequences for nonstructural protein-mediated amplification, a nonstructural protein 1 (nsP1) gene, a nsP2 gene, a nsP3 gene, a nsP4 gene, and a polyA sequence, as well as sequences for expression of subgenomic viral RNA including a subgenomic promoter (e.g., a 26S promoter element).

[0298] The term “sequences for nonstructural protein-mediated amplification” includes alphavirus conserved sequence elements (CSE) well known to those in the art. CSEs include, but are not limited to, an alphavirus 5′ UTR, a 51-nt CSE, a 24-nt CSE, a subgenomic promoter sequence (e.g., a 26S subgenomic promoter sequence), a 19-nt CSE, and an alphavirus 3′ UTR.

[0299] The term “RNA polymerase” includes polymerases that catalyze the production of RNA polynucleotides from a DNA template. RNA polymerases include, but are not limited to, bacteriophage derived polymerases including T3, T7, and SP6.

[0300] The term “lipid” includes hydrophobic and/or amphiphilic molecules. Lipids can be cationic, anionic, or neutral. Lipids can be synthetic or naturally derived, and in some instances biodegradable. Lipids can include cholesterol, phospholipids, lipid conjugates including, but not limited to, polyethyleneglycol (PEG) conjugates (PEGylated lipids), waxes, oils, glycerides, fats, and fat-soluble vitamins. Lipids can also include dilinoleylmethyl-4-dimethylaminobutyrate (MC3) and MC3-like molecules.

[0301] The term “lipid nanoparticle” or “LNP” includes vesicle like structures formed using a lipid containing membrane surrounding an aqueous interior, also referred to as liposomes. Lipid nanoparticles includes lipid-based compositions with a solid lipid core stabilized by a surfactant. The core lipids can be fatty acids, acylglycerols, waxes, and mixtures of these surfactants. Biological membrane lipids such as phospholipids, sphingomyelins, bile salts (sodium taurocholate), and sterols (cholesterol) can be utilized as stabilizers. Lipid nanoparticles can be formed using defined ratios of different lipid molecules, including, but not limited to, defined ratios of one or more cationic, anionic, or neutral lipids. Lipid nanoparticles can encapsulate molecules within an outer-membrane shell and subsequently can be contacted with target cells to deliver the encapsulated molecules to the host cell cytosol. Lipid nanoparticles can be modified or functionalized with non-lipid molecules, including on their surface. Lipid nanoparticles can be single-layered (unilamellar) or multi-layered (multilamellar). Lipid nanoparticles can be complexed with nucleic acid. Unilamellar lipid nanoparticles can be complexed with nucleic acid, wherein the nucleic acid is in the aqueous interior. Multilamellar lipid nanoparticles can be complexed with nucleic acid, wherein the nucleic acid is in the aqueous interior, or to form or sandwiched between

[0302] Abbreviations: MHC: major histocompatibility complex; HLA: human leukocyte antigen, or the human MHC gene locus; NGS: next-generation sequencing; PPV: positive predictive value; TSNA: tumor-specific neoantigen; FFPE: formalin-fixed, paraffin-embedded; NMD: nonsense-mediated decay; NSCLC: non-small-cell lung cancer; DC: dendritic cell.

[0303] It should be noted that, as used in the specification and the appended claims, the singular forms “a,” “an,” and “the” include plural referents unless the context clearly dictates otherwise.

[0304] Unless specifically stated or otherwise apparent from context, as used herein the term “about” is understood as within a range of normal tolerance in the art, for example within 2 standard deviations of the mean. About can be understood as within 10%, 9%, 8%, 7%, 6%, 5%, 4%, 3%, 2%, 1%, 0.5%, 0.1%, 0.05%, or 0.01% of the stated value. Unless otherwise clear from context, all numerical values provided herein are modified by the term about.

[0305] Any terms not directly defined herein shall be understood to have the meanings commonly associated with them as understood within the art of the invention. Certain terms are discussed herein to provide additional guidance to the practitioner in describing the compositions, devices, methods and the like of aspects of the invention, and how to make or use them. It will be appreciated that the same thing may be said in more than one way. Consequently, alternative language and synonyms may be used for any one or more of the terms discussed herein. No significance is to be placed upon whether or not a term is elaborated or discussed herein. Some synonyms or substitutable methods, materials and the like are provided. Recital of one or a few synonyms or equivalents does not exclude use of other synonyms or equivalents, unless it is explicitly stated. Use of examples, including examples of terms, is for illustrative purposes only and does not limit the scope and meaning of the aspects of the invention herein.

[0306] All references, issued patents and patent applications cited within the body of the specification are hereby incorporated by reference in their entirety, for all purposes.

II. Antigen Identification

[0307] Research methods for NGS analysis of tumor and normal exome and transcriptomes have been described and applied in the antigen identification space. .sup.6,14,15 Certain optimizations for greater sensitivity and specificity for antigen identification in the clinical setting can be considered. These optimizations can be grouped into two areas, those related to laboratory processes and those related to the NGS data analysis. The research methods described can also be applied to identification of antigens in other settings, such as identification of identifying antigens from an infectious disease organism (e.g., SARS-CoV-2), an infection in a subject, or an infected cell of a subject. Examples of optimizations are known to those skilled in the art, for example the methods described in more detail in U.S. Pat. No. 10,055,540, US Application Pub. No. US20200010849A1, international patent application publications WO/2018/195357 and WO/2018/208856, U.S. application Ser. No. 16/606,577, and international patent application PCT/US2020/021508, each herein incorporated by reference, in their entirety, for all purposes.

[0308] Methods for identifying antigens (e.g., antigens derived from an infectious disease organism) include identifying antigens that are likely to be presented on a cell surface (e.g., presented by MHC on an infected cell or an immune cell, including professional antigen presenting cells such as dendritic cells), and/or are likely to be immunogenic. As an example, one such method may comprise the steps of: obtaining at least one of exome, transcriptome or whole genome nucleotide sequencing and/or expression data from an infected cell or an infectious disease organism (e.g., SARS-CoV-2), wherein the nucleotide sequencing data and/or expression data is used to obtain data representing peptide sequences of each of a set of antigens (e.g., antigens derived from the infectious disease organism); inputting the peptide sequence of each antigen into one or more presentation models to generate a set of numerical likelihoods that each of the antigens is presented by one or more MHC alleles on a cell surface, such as an infected cell of the subject, the set of numerical likelihoods having been identified at least based on received mass spectrometry data; and selecting a subset of the set of antigens based on the set of numerical likelihoods to generate a set of selected antigens.

IV. Antigens

[0309] Antigens can include nucleotides or polypeptides. For example, an antigen can be an RNA sequence that encodes for a polypeptide sequence. Antigens useful in vaccines can therefore include nucleotide sequences or polypeptide sequences.

[0310] Disclosed herein are peptides and nucleic acid sequences encoding peptides derived from any polypeptide associated with SARS-CoV-2, a SARS-CoV-2 infection in a subject, or a SARS-CoV-2 infected cell of a subject. Antigens can be derived from nucleotide sequences or polypeptide sequences of a SARS-CoV-2 virus. Polypeptide sequences of SARS-CoV-2 include, but are not limited to, predicted MHC class I epitopes shown in Table A, predicted MHC class II epitopes shown in Table B, predicted MHC class I epitopes shown in Table C, SARS-CoV-2 Spike peptides (e.g., peptides derived from SEQ ID NO:59), SARS-CoV-2 Membrane peptides (e.g., peptides derived from SEQ ID NO:61), SARS-CoV-2 Nucleocapsid peptides (e.g., peptides derived from SEQ ID NO:62), SARS-CoV-2 Envelope peptides (e.g., peptides derived from SEQ ID NO:63), SARS-CoV-2 replicase orf1a and orf1b peptides [such as one or more of non-structural proteins (nsp) 1-16], or any other peptide sequence encoded by a SARS-CoV-2 virus. Peptides and nucleic acid sequences encoding peptides can be derived from the Wuhan-Hu-1 SARS-CoV-2 isolate, sometimes referred to as the SARS-CoV-2 reference sequence (SEQ ID NO:76; NC_045512.2, herein incorporated by reference for all purposes). Peptides and nucleic acid sequences encoding peptides can be derived from an isolate distinct from the Wuhan-Hu-1 SARS-CoV-2 isolate, such as isolates having one or more mutations in proteins (also referred to as protein variants) with reference to the Wuhan-Hu-1 isolate. Vaccination strategies can include multiple vaccines with peptides and nucleic acid sequences encoding peptides derived from distinct isolates. For example, as an illustrative non-limiting example, a vaccine encoding a Spike protein from the Wuhan-Hu-1 SARS-CoV-2 isolate can be administered, followed by subsequent administration of a vaccine encoding a Spike protein from the B.1.351 (“South African”) SARS-CoV-2 isolate (e.g., SEQ ID NO:112) or from the B.1.1.7 (“South African”) SARS-CoV-2 isolate (e.g., SEQ ID NO:110). The one or more variants can include, but are not limited to, mutations in the SARS-CoV-2 Spike protein, SARS-CoV-2 Membrane protein, SARS-CoV-2 Nucleocapsid protein, SARS-CoV-2 Envelope protein, SARS-CoV-2 replicase orf1a and orf1b protein [such as one or more of non-structural proteins (nsp) 1-16], or any other protein sequences encoded by a SARS-CoV-2 virus. Variants can be selected based on prevalence of the mutation among SARS-CoV-2 subtypes/isolates, such as mutations/variants that are present in 1% or greater, 2% or greater, 3% or greater, 4% or greater, 5% or greater, 6% or greater, 7% or greater, 8% or greater, 9% or greater, 10% or greater, 20% or greater, 30% or greater, 40% or greater, 50% or greater, 60% or greater, 70% or greater, 80% or greater, 90% or greater of SARS-CoV-2 subtypes/isolates. Examples of mutations in greater than 1% of isolates are shown in Table 1. Variants can be selected based on prevalence of the mutation among SARS-CoV-2 subtypes/isolates present in a specific population, such as a specific demographic or geographic population. An illustrative non-limiting example of a prevalent variant/mutation is the Spike D614G missense mutation found in 60.05% of genomes sequenced worldwide, and 70.46% and 58.49% of the sequences in Europe and North America, respectively. Accordingly, vaccines can be designed to encode at least one immunogenic polypeptide corresponding to a polypeptide encoded by a SARS-CoV-2 subtype the subject is infected with or at risk for infection by, such as for use in prophylactic vaccines for a specific demographic or geographic population at risk for infection by the specific SARS-CoV-2 subtype/isolate. Vaccines can be designed to encode at least one immunogenic polypeptide corresponding to a polypeptide encoded by SARS-CoV-2 and at least one immunogenic polypeptide corresponding to a polypeptide encoded by a Coronavirus species and/or sub-species other than SARS-CoV-2, e.g., the Severe acute respiratory syndrome (SARS) 2002-associated species (NC_004718.3, herein incorporated by reference for all purposes) and/or Middle East respiratory syndrome (MERS) 2012-associated species (NC_019843.3, herein incorporated by reference for all purposes). Vaccines can be designed to encode at least one immunogenic polypeptide corresponding to a polypeptide encoded by SARS-CoV-2 that is conserved (e.g., 100% amino acid sequence conservation between epitopes) between SARS-CoV-2 and a Coronavirus species and/or sub-species other than SARS-CoV-2, e.g., Severe acute respiratory syndrome (SARS) and/or Middle East respiratory syndrome (MERS) species. SARS-CoV-2 epitopes that are conserved between SARS-CoV-2 and a Coronavirus species and/or sub-species other than SARS-CoV-2 can include epitopes derived from a Coronavirus Spike protein, a Coronavirus Membrane protein, a Coronavirus Nucleocapsid protein, a Coronavirus Envelope protein, a Coronavirus replicase orf1a and orf1b protein [such as one or more of non-structural proteins (nsp) 1-16], or any other protein sequences encoded by a Coronavirus, e.g., as illustrated in FIG. 27.

[0311] Antigens can be selected that are predicted to be presented on the cell surface of a cell, such as an infected cell or an immune cell, including professional antigen presenting cells such as dendritic cells. Antigens can be selected that are predicted to be immunogenic. Exemplary antigens predicted using the methods described herein to be presented on the cell surface by an MHC include predicted MHC class I epitopes shown in Table A, predicted MHC class II epitopes shown in Table B, and predicted MHC class I epitopes shown in Table C.

[0312] Antigens can be selected that have been validated to be presented by a specific HLA and/or stimulate an immune response, such as previously reported/validated in the literature (for example, as in Nelde et al. [Nature Immunology volume 22, pages 74-85 2021], Tarke et al. 2021, or Schelien et al. [bioRxiv 2020.08.13.249433]). The magnitude of stimulation of an immune response can be used to guide epitope/antigen selection, such as to select epitopes that stimulate as robust an immune response as possible, including when cassettes have a size constraint. As an illustrative non-limiting example of magnitude based-selection, the following can be used (1) An individual's magnitude is the sum of all epitope magnitudes across their respective diplotype alleles; (2) Each epitopes magnitude=(magnitude of response)×(Frequency of positive response/100), [e.g., using values found in Tarke et al. (Comprehensive analysis of T cell immunodominance and immunoprevalence of SARS-CoV-2 epitopes in COVID-19 cases. Cell Rep Med. 2021 Feb. 16; 2(2):100204. doi: 10.1016/j.xcrm.2021.100204. Epub 2021 Jan. 26.), herein incorporated by reference for all purposes]; (3) exclusion of epitopes other than those from starting proteins that span mutations with >5% frequency, optionally with mutations allowed in flanking regions; and/or (4) cassette order determined to minimize unintended junction epitopes across adjacent frames, as well as minimize consecutive frames in the same protein to reduce chance of functional protein fragments, as described herein.

[0313] A cassette can be constructed to encode one or more validated epitopes and/or at least 4, 5, 6, or 7 predicted epitopes, wherein at least 85%, 90%, or 95% of a population carries at least one HLA validated to present at least one of the one or more validated epitopes and/or at least one HLA predicted to present each of the at least 4, 5, 6, or 7 predicted epitopes. A cassette can be constructed to encode one or more validated epitopes and at least 4, 5, 6, or 7 predicted epitopes, wherein at least 85%, 90%, or 95% of a population carries at least one HLA validated to present at least one of the one or more validated epitopes or at least one HLA predicted to present each of the at least 4, 5, 6, or 7 predicted epitopes.

[0314] One or more polypeptides encoded by an antigen nucleotide sequence can comprise at least one of: a binding affinity with MHC with an IC50 value of less than 1000 nM, for MHC Class I peptides a length of 8-15, 8, 9, 10, 11, 12, 13, 14, or 15 amino acids, presence of sequence motifs within or near the peptide promoting proteasome cleavage, and presence or sequence motifs promoting TAP transport. For MHC Class II peptides a length 6-30, 6, 7, 8, 9, 10, 11, 12, 13, 14, 15, 16, 17, 18, 19, 20, 21, 22, 23, 24, 25, 26, 27, 28, 29, or 30 amino acids, presence of sequence motifs within or near the peptide promoting cleavage by extracellular or lysosomal proteases (e.g., cathepsins) or HLA-DM catalyzed HLA binding.

[0315] One or more antigens can be presented on the surface of an infected cell (e.g., a SARS-CoV-2 infected cell).

[0316] One or more antigens can be immunogenic in a subject having or suspected to have an infection (e.g., a SARS-CoV-2 infection), e.g., capable of stimulating a T cell response and/or a B cell response in the subject. One or more antigens can be immunogenic in a subject at risk of an infection (e.g., a SARS-CoV-2 infection), e.g., capable of stimulating a T cell response and/or a B cell response in the subject that provides immunological protection (i.e., immunity) against the infection, e.g., such as stimulating the production of memory T cells, memory B cells, or antibodies specific to the infection.

[0317] One or more antigens can be capable of stimulating a B cell response, such as the production of antibodies that recognize the one or more antigens (e.g., antibodies that recognize a SARS-CoV-2 antigen and/or virus). Antibodies can recognize linear polypeptide sequences or recognize secondary and tertiary structures. Accordingly, B cell antigens can include linear polypeptide sequences or polypeptides having secondary and tertiary structures, including, but not limited to, full-length proteins, protein subunits, protein domains, or any polypeptide sequence known or predicted to have secondary and tertiary structures. Antigens capable of stimulating a B cell response to an infection can be antigens found on the surface of an infectious disease organism (e.g., SARS-CoV-2). Antigens capable of stimulating a B cell response to an infection can be an intracellular antigen expressed in an infectious disease organism. SARS-CoV-2 antigens capable of stimulating a B cell response include, but are not limited to, SARS-CoV-2 Spike peptides, SARS-CoV-2 Membrane peptides, SARS-CoV-2 Nucleocapsid peptides, and SARS-CoV-2 Envelope peptides.

[0318] One or more antigens can include a combination of antigens capable of stimulating a T cell response (e.g., peptides including predicted T cell epitope sequences) and distinct antigens capable of stimulating a B cell response (e.g., full-length proteins, protein subunits, protein domains).

[0319] One or more antigens that stimulate an autoimmune response in a subject can be excluded from consideration in the context of vaccine generation for a subject.

[0320] The size of at least one antigenic peptide molecule (e.g., an epitope sequence) can comprise, but is not limited to, about 5, about 6, about 7, about 8, about 9, about 10, about 11, about 12, about 13, about 14, about 15, about 16, about 17, about 18, about 19, about 20, about 21, about 22, about 23, about 24, about 25, about 26, about 27, about 28, about 29, about 30, about 31, about 32, about 33, about 34, about 35, about 36, about 37, about 38, about 39, about 40, about 41, about 42, about 43, about 44, about 45, about 46, about 47, about 48, about 49, about 50, about 60, about 70, about 80, about 90, about 100, about 110, about 120 or greater amino molecule residues, and any range derivable therein. In specific embodiments the antigenic peptide molecules are equal to or less than 50 amino acids.

[0321] Antigenic peptides and polypeptides can be: for MHC Class 115 residues or less in length and usually consist of between about 8 and about 11 residues, particularly 9 or 10 residues; for MHC Class II, 6-30 residues, inclusive.

[0322] If desirable, a longer peptide can be designed in several ways. In one case, when presentation likelihoods of peptides on HLA alleles are predicted or known, a longer peptide could consist of either: (1) individual presented peptides with an extensions of 2-5 amino acids toward the N- and C-terminus of each corresponding gene product; (2) a concatenation of some or all of the presented peptides with extended sequences for each. In another case, when sequencing reveals a long (>10 residues) epitope sequence present, a longer peptide would consist of: (3) the entire stretch of novel infectious disease-specific amino acids—thus bypassing the need for computational or in vitro test-based selection of the strongest HLA-presented shorter peptide. In both cases, use of a longer peptide allows endogenous processing by patient cells and may lead to more effective antigen presentation leading to increased T cell responses. Longer peptides can also include a full-length protein, a protein subunit, a protein domain, and combinations thereof of a peptide, such as those expressed in an infectious disease organism. Longer peptides (e.g., full-length protein, protein subunit, or protein domain) and combinations thereof can be included to stimulate a B cell response.

[0323] Antigenic peptides and polypeptides can be presented on an HLA protein. In some aspects antigenic peptides and polypeptides are presented on an HLA protein with greater affinity than a wild-type peptide. In some aspects, an antigenic peptide or polypeptide can have an IC50 of at least less than 5000 nM, at least less than 1000 nM, at least less than 500 nM, at least less than 250 nM, at least less than 200 nM, at least less than 150 nM, at least less than 100 nM, at least less than 50 nM or less.

[0324] In some aspects, antigenic peptides and polypeptides do not stimulate an autoimmune response and/or invoke immunological tolerance when administered to a subject.

[0325] Also provided are compositions comprising at least two or more antigenic peptides. In some embodiments the composition contains at least two distinct peptides. At least two distinct peptides can be derived from the same polypeptide. By distinct polypeptides is meant that the peptide vary by length, amino acid sequence, or both. The peptides can be derived from any polypeptide known to or suspected to be associated with an infectious disease organism, or peptides derived from any polypeptide known to or have been found to have altered expression in an infected cell in comparison to a normal cell or tissue (e.g., an infectious disease polynucleotide or polypeptide, including infectious disease polynucleotides or polypeptides with expression restricted to a host cell).

[0326] Antigenic peptides and polypeptides having a desired activity or property can be modified to provide certain desired attributes, e.g., improved pharmacological characteristics, while increasing or at least retaining substantially all of the biological activity of the unmodified peptide to bind the desired MHC molecule and activate the appropriate T cell. For instance, antigenic peptide and polypeptides can be subject to various changes, such as substitutions, either conservative or non-conservative, where such changes might provide for certain advantages in their use, such as improved MHC binding, stability or presentation. By conservative substitutions is meant replacing an amino acid residue with another which is biologically and/or chemically similar, e.g., one hydrophobic residue for another, or one polar residue for another. The substitutions include combinations such as Gly, Ala; Val, Ile, Leu, Met; Asp, Glu; Asn, Gln; Ser, Thr; Lys, Arg; and Phe, Tyr. The effect of single amino acid substitutions may also be probed using D-amino acids. Such modifications can be made using well known peptide synthesis procedures, as described in e.g., Merrifield, Science 232:341-347 (1986), Barany & Merrifield, The Peptides, Gross & Meienhofer, eds. (N.Y., Academic Press), pp. 1-284 (1979); and Stewart & Young, Solid Phase Peptide Synthesis, (Rockford, Ill., Pierce), 2d Ed. (1984).

[0327] Modifications of peptides and polypeptides with various amino acid mimetics or unnatural amino acids can be particularly useful in increasing the stability of the peptide and polypeptide in vivo. Stability can be assayed in a number of ways. For instance, peptidases and various biological media, such as human plasma and serum, have been used to test stability. See, e.g., Verhoef et al., Eur. J. Drug Metab Pharmacokin. 11:291-302 (1986). Half-life of the peptides can be conveniently determined using a 25% human serum (v/v) assay. The protocol is generally as follows. Pooled human serum (Type AB, non-heat inactivated) is delipidated by centrifugation before use. The serum is then diluted to 25% with RPMI tissue culture media and used to test peptide stability. At predetermined time intervals a small amount of reaction solution is removed and added to either 6% aqueous trichloracetic acid or ethanol. The cloudy reaction sample is cooled (4 degrees C.) for 15 minutes and then spun to pellet the precipitated serum proteins. The presence of the peptides is then determined by reversed-phase HPLC using stability-specific chromatography conditions.

[0328] The peptides and polypeptides can be modified to provide desired attributes other than improved serum half-life. For instance, the ability of the peptides to stimulate CTL activity can be enhanced by linkage to a sequence which contains at least one epitope that is capable of inducing a T helper cell response. Immunogenic peptides/T helper conjugates can be linked by a spacer molecule. The spacer is typically comprised of relatively small, neutral molecules, such as amino acids or amino acid mimetics, which are substantially uncharged under physiological conditions. The spacers are typically selected from, e.g., Ala, Gly, or other neutral spacers of nonpolar amino acids or neutral polar amino acids. It will be understood that the optionally present spacer need not be comprised of the same residues and thus can be a hetero- or homo-oligomer. When present, the spacer will usually be at least one or two residues, more usually three to six residues. Alternatively, the peptide can be linked to the T helper peptide without a spacer.

[0329] Polypeptides encoding antigens can be modified to alter processing of the polypeptides, such as protease cleavage and/or other post-translation processing. Polypeptides encoding antigens can be modified such that the antigen favors a specific conformation. Polypeptides encoding antigens can be modified such that the mutations (e.g., one or more missense mutations) disrupt a specific conformation in the antigen, such as through the introduction of prolines that disrupt secondary and tertiary structures (e.g., alpha-helix or beta-sheet formation). Altering, reducing, or eliminating processing or conformation changes may, in some instances, bias the antigen to favor states favorable to neutralizing antibody production. In a series of illustrative examples, SARS-CoV-2 Spike mutations at amino acids 682, 815, 987, and 988 are engineered to bias the Spike protein to remain in a predominantly prefusion state, a potentially preferable state for antibody-mediated neutralization. Specifically, without wishing to be bound by theory, mutations at R682 (e.g., R682V) disrupt the Furin cleavage site involved in processing Spike into S1 and S2; mutations at R815 (e.g., R815N) disrupt the cleavage site within S2; and mutations at K986 and V987, such as K986P and V987P introducing two prolines, that interfere with the secondary structure of Spike making it less likely to be processed from the pre to post fusion state. Accordingly, an antigen cassette can encode a modified Spike protein having at least one mutation selected from: a Spike R682V mutation, a Spike R815N mutation, a Spike K986P mutation, a Spike V987P mutation, and combinations thereof with reference the Wuhan-Hu-1 isolate (see SEQ ID NO:59 reference and SEQ ID NO:60/SEQ ID NO:90 containing mutations). Modified polypeptide sequences can be at least 60%, 70%, 80%, or 90% identical to a native SARS-CoV-2 polypeptide sequence. Modified polypeptide sequences can be at least 91%, 92%, 93%, or 94% identical to a native SARS-CoV-2 polypeptide sequence. Modified polypeptide sequences can be at least 95%, 96%, 97%, 98%, or 99% identical to a native SARS-CoV-2 polypeptide sequence. Modified polypeptide sequences can be at least 99.1%, 99.2%, 99.3%, 99.4%, 99.5%, 99.6%, 99.7%, 99.8%, or 99.9% identical to a native SARS-CoV-2 polypeptide sequence.

[0330] An antigenic peptide can be linked to the T helper peptide either directly or via a spacer either at the amino or carboxy terminus of the peptide. The amino terminus of either the antigenic peptide or the T helper peptide can be acylated. Exemplary T helper peptides include tetanus toxoid 830-843, influenza 307-319, malaria circumsporozoite 382-398 and 378-389.

[0331] Proteins or peptides can be made by any technique known to those of skill in the art, including the expression of proteins, polypeptides or peptides through standard molecular biological techniques, the isolation of proteins or peptides from natural sources, or the chemical synthesis of proteins or peptides. The nucleotide and protein, polypeptide and peptide sequences corresponding to various genes have been previously disclosed, and can be found at computerized databases known to those of ordinary skill in the art. One such database is the National Center for Biotechnology Information's Genbank and GenPept databases located at the National Institutes of Health website. The coding regions for known genes can be amplified and/or expressed using the techniques disclosed herein or as would be known to those of ordinary skill in the art. Alternatively, various commercial preparations of proteins, polypeptides and peptides are known to those of skill in the art.

[0332] In a further aspect, an antigen includes a nucleic acid (e.g. polynucleotide) that encodes an antigenic peptide or portion thereof. The polynucleotide can be, e.g., DNA, cDNA, PNA, CNA, RNA (e.g., mRNA), either single- and/or double-stranded, or native or stabilized forms of polynucleotides, such as, e.g., polynucleotides with a phosphorothioate backbone, or combinations thereof and it may or may not contain introns. A polynucleotide sequence encoding an antigen can be sequence-optimized to improve expression, such as through improving transcription, translation, post-transcriptional processing, and/or RNA stability. For example, polynucleotide sequence encoding an antigen can be codon-optimized. “Codon-optimization” herein refers to replacing infrequently used codons, with respect to codon bias of a given organism, with frequently used synonymous codons. Polynucleotide sequences can be optimized to improve post-transcriptional processing, for example optimized to reduce unintended splicing, such as through removal of splicing motifs (e.g., canonical and/or cryptic/non-canonical splice donor, branch, and/or acceptor sequences) and/or introduction of exogenous splicing motifs (e.g., splice donor, branch, and/or acceptor sequences) to bias favored splicing events. Exogenous intron sequences include, but are not limited to, those derived from SV40 (e.g., an SV40 mini-intron [SEQ ID NO:88]) and derived from immunoglobulins (e.g., human β-globin gene). Exogenous intron sequences can be incorporated between a promoter/enhancer sequence and the antigen(s) sequence. Exogenous intron sequences for use in expression vectors are described in more detail in Callendret et al. (Virology. 2007 Jul. 5; 363(2): 288-302), herein incorporated by reference for all purposes. Polynucleotide sequences can be optimized to improve transcript stability, for example through removal of RNA instability motifs (e.g., AU-rich elements and 3′ UTR motifs) and/or repetitive nucleotide sequences. Polynucleotide sequences can be optimized to improve accurate transcription, for example through removal of cryptic transcriptional initiators and/or terminators. Polynucleotide sequences can be optimized to improve translation and translational accuracy, for example through removal of cryptic AUG start codons, premature polyA sequences, and/or secondary structure motifs. Polynucleotide sequences can be optimized to improve nuclear export of transcripts, such as through addition of a Constitutive Transport Element (CTE), RNA Transport Element (RTE), or Woodchuck Posttranscriptional Regulatory Element (WPRE). Nuclear export signals for use in expression vectors are described in more detail in Callendret et al. (Virology. 2007 Jul. 5; 363(2): 288-302), herein incorporated by reference for all purposes. Polynucleotide sequences can be optimized with respect to GC content, for example to reflect the average GC content of a given organism. Sequence optimization can balance one or more sequence properties, such as transcription, translation, post-transcriptional processing, and/or RNA stability. Sequence optimization can generate an optimal sequence balancing each of transcription, translation, post-transcriptional processing, and RNA stability. Sequence optimization algorithms are known to those of skill in the art, such as GeneArt (Thermo Fisher), Codon Optimization Tool (IDT), Cool Tool, SGI-DNA (La Jolla California). One or more regions of an antigen-encoding protein can be sequence-optimized separately. As a non-limiting illustrative example, SARS-CoV-2 Spike protein can be sequence-optimized (or unoptimized) in the S1 region of the protein and the S2 region is separately optimized (e.g., optimized using a different algorithm and/or optimized for one or more sequence properties specific for the S2 region).

[0333] A method disclosed herein can also include identifying one or more T cells that are antigen-specific for at least one of the antigens in the subset. In some embodiments, the identification comprises co-culturing the one or more T cells with one or more of the antigens in the subset under conditions that expand the one or more antigen-specific T cells. In further embodiments, the identification comprises contacting the one or more T cells with a tetramer comprising one or more of the antigens in the subset under conditions that allow binding between the T cell and the tetramer. In even further embodiments, the method disclosed herein can also include identifying one or more T cell receptors (TCR) of the one or more identified T cells. In certain embodiments, identifying the one or more T cell receptors comprises sequencing the T cell receptor sequences of the one or more identified T cells. The method disclosed herein can further comprise genetically engineering a plurality of T cells to express at least one of the one or more identified T cell receptors; culturing the plurality of T cells under conditions that expand the plurality of T cells; and infusing the expanded T cells into the subject. In some embodiments, genetically engineering the plurality of T cells to express at least one of the one or more identified T cell receptors comprises cloning the T cell receptor sequences of the one or more identified T cells into an expression vector; and transfecting each of the plurality of T cells with the expression vector. In some embodiments, the method disclosed herein further comprises culturing the one or more identified T cells under conditions that expand the one or more identified T cells; and infusing the expanded T cells into the subject.

[0334] Also disclosed herein is an isolated T cell that is antigen-specific for at least one selected antigen in the subset.

[0335] A still further aspect provides an expression vector capable of expressing a polypeptide or portion thereof. Expression vectors for different cell types are well known in the art and can be selected without undue experimentation. Generally, DNA is inserted into an expression vector, such as a plasmid, in proper orientation and correct reading frame for expression. If necessary, DNA can be linked to the appropriate transcriptional and translational regulatory control nucleotide sequences recognized by the desired host, although such controls are generally available in the expression vector. The vector is then introduced into the host through standard techniques. Guidance can be found e.g. in Sambrook et al. (1989) Molecular Cloning, A Laboratory Manual, Cold Spring Harbor Laboratory, Cold Spring Harbor, N.Y.

V. Vaccine Compositions

[0336] Also disclosed herein is an immunogenic composition, e.g., a vaccine composition, capable of raising a specific immune response, e.g., an infectious disease organism-specific immune response. Vaccine compositions typically comprise one or a plurality of antigens, e.g., selected using a method described herein. Vaccine compositions can also be referred to as vaccines.

[0337] A vaccine can contain between 1 and 30 peptides, 2, 3, 4, 5, 6, 7, 8, 9, 10, 11, 12, 13, 14, 15, 16, 17, 18, 19, 20, 21, 22, 23, 24, 25, 26, 27, 28, 29, or 30 different peptides, 6, 7, 8, 9, 10 11, 12, 13, or 14 different peptides, or 12, 13 or 14 different peptides. Peptides can include post-translational modifications. A vaccine can contain between 1 and 100 or more nucleotide sequences, 2, 3, 4, 5, 6, 7, 8, 9, 10, 11, 12, 13, 14, 15, 16, 17, 18, 19, 20, 21, 22, 23, 24, 25, 26, 27, 28, 29, 30, 31, 32, 33, 34, 35, 36, 37, 38, 39, 40, 41, 42, 43, 44, 45, 46, 47, 48, 49, 50, 51, 52, 53, 54, 55, 56, 57, 58, 59, 60, 61, 62, 63, 64, 65, 66, 67, 68, 69, 70, 71, 72, 73, 74, 75, 76, 77, 78, 79, 80, 81, 82, 83, 84, 85, 86, 87, 88, 89, 90, 91, 92, 93, 94, 95, 96, 97, 98, 99, 100 or more different nucleotide sequences, 6, 7, 8, 9, 10 11, 12, 13, or 14 different nucleotide sequences, or 12, 13 or 14 different nucleotide sequences. A vaccine can contain between 1 and 30 antigen sequences, 2, 3, 4, 5, 6, 7, 8, 9, 10, 11, 12, 13, 14, 15, 16, 17, 18, 19, 20, 21, 22, 23, 24, 25, 26, 27, 28, 29, 30, 31, 32, 33, 34, 35, 36, 37, 38, 39, 40, 41, 42, 43, 44, 45, 46, 47, 48, 49, 50, 51, 52, 53, 54, 55, 56, 57, 58, 59, 60, 61, 62, 63, 64, 65, 66, 67, 68, 69, 70, 71, 72, 73, 74, 75, 76, 77, 78, 79, 80, 81, 82, 83, 84, 85, 86, 87, 88, 89, 90, 91, 92, 93, 94, 95, 96, 97, 98, 99, 100 or more different antigen sequences, 6, 7, 8, 9, 10 11, 12, 13, or 14 different antigen sequences, or 12, 13 or 14 different antigen sequences.

[0338] A vaccine can contain between 1 and 30 antigen-encoding nucleic acid sequences, 2, 3, 4, 5, 6, 7, 8, 9, 10, 11, 12, 13, 14, 15, 16, 17, 18, 19, 20, 21, 22, 23, 24, 25, 26, 27, 28, 29, 30, 31, 32, 33, 34, 35, 36, 37, 38, 39, 40, 41, 42, 43, 44, 45, 46, 47, 48, 49, 50, 51, 52, 53, 54, 55, 56, 57, 58, 59, 60, 61, 62, 63, 64, 65, 66, 67, 68, 69, 70, 71, 72, 73, 74, 75, 76, 77, 78, 79, 80, 81, 82, 83, 84, 85, 86, 87, 88, 89, 90, 91, 92, 93, 94, 95, 96, 97, 98, 99, 100 or more different antigen-encoding nucleic acid sequences, 6, 7, 8, 9, 10 11, 12, 13, or 14 different antigen-encoding nucleic acid sequences, or 12, 13 or 14 different antigen-encoding nucleic acid sequences. Antigen-encoding nucleic acid sequences can refer to the antigen encoding portion of an “antigen cassette.” Features of an antigen cassette are described in greater detail herein. An antigen-encoding nucleic acid sequence can contain one or more epitope-encoding nucleic acid sequences (e.g., an antigen-encoding nucleic acid sequence encoding concatenated T cell epitopes).

[0339] A vaccine can contain between 1 and 30 distinct epitope-encoding nucleic acid sequences, 2, 3, 4, 5, 6, 7, 8, 9, 10, 11, 12, 13, 14, 15, 16, 17, 18, 19, 20, 21, 22, 23, 24, 25, 26, 27, 28, 29, 30, 31, 32, 33, 34, 35, 36, 37, 38, 39, 40, 41, 42, 43, 44, 45, 46, 47, 48, 49, 50, 51, 52, 53, 54, 55, 56, 57, 58, 59, 60, 61, 62, 63, 64, 65, 66, 67, 68, 69, 70, 71, 72, 73, 74, 75, 76, 77, 78, 79, 80, 81, 82, 83, 84, 85, 86, 87, 88, 89, 90, 91, 92, 93, 94, 95, 96, 97, 98, 99, 100 or more distinct epitope-encoding nucleic acid sequences, 6, 7, 8, 9, 10 11, 12, 13, or 14 distinct epitope-encoding nucleic acid sequences, or 12, 13 or 14 distinct epitope-encoding nucleic acid sequences. Epitope-encoding nucleic acid sequences can refer to sequences for individual epitope sequences, such as each of the T cell epitopes in an antigen-encoding nucleic acid sequence encoding concatenated T cell epitopes.

[0340] A vaccine can contain at least two repeats of an epitope-encoding nucleic acid sequence. A used herein, a “repeat” refers to two or more iterations of an identical nucleic acid epitope-encoding nucleic acid sequence (inclusive of the optional 5′ linker sequence and/or the optional 3′ linker sequences described herein) within an antigen-encoding nucleic acid sequence. In one example, the antigen-encoding nucleic acid sequence portion of a cassette encodes at least two repeats of an epitope-encoding nucleic acid sequence. In further non-limiting examples, the antigen-encoding nucleic acid sequence portion of a cassette encodes more than one distinct epitope, and at least one of the distinct epitopes is encoded by at least two repeats of the nucleic acid sequence encoding the distinct epitope (i.e., at least two distinct epitope-encoding nucleic acid sequences). In illustrative non-limiting examples, an antigen-encoding nucleic acid sequence encodes epitopes A, B, and C encoded by epitope-encoding nucleic acid sequences epitope-encoding sequence A (E.sub.A), epitope-encoding sequence B (E.sub.B), and epitope-encoding sequence C (E.sub.C), and exemplary antigen-encoding nucleic acid sequences having repeats of at least one of the distinct epitopes are illustrated by, but is not limited to, the formulas below: [0341] Repeat of one distinct epitope (repeat of epitope A): [0342] E.sub.A-E.sub.B-E.sub.C-E.sub.A; or [0343] E.sub.A-E.sub.A-E.sub.B-E.sub.C [0344] Repeat of multiple distinct epitopes (repeats of epitopes A, B, and C): [0345] E.sub.A-E.sub.B-E.sub.C-E.sub.A-E.sub.B-E.sub.C; or [0346] E.sub.A-E.sub.A-E.sub.B-E.sub.B-E.sub.C-E.sub.C [0347] Multiple repeats of multiple distinct epitopes (repeats of epitopes A, B, and C): [0348] E.sub.A-E.sub.B-E.sub.C-E.sub.A-E.sub.B-E.sub.C-E.sub.A-E.sub.B-E.sub.C; or [0349] E.sub.A-E.sub.A-E.sub.A-E.sub.B-E.sub.B-E.sub.B-E.sub.C-E.sub.C-E.sub.C

[0350] The above examples are not limiting and the antigen-encoding nucleic acid sequences having repeats of at least one of the distinct epitopes can encode each of the distinct epitopes in any order or frequency. For example, the order and frequency can be a random arrangement of the distinct epitopes, e.g., in an example with epitopes A, B, and C, by the formula E.sub.A-E.sub.B-E.sub.C-E.sub.C-E.sub.A-E.sub.B-E.sub.A-E.sub.C-E.sub.A-E.sub.C-E.sub.C-E.sub.B.

[0351] Also provided for herein is an antigen-encoding cassette, the antigen-encoding cassette having at least one antigen-encoding nucleic acid sequence described, from 5′ to 3′, by the formula:

(E.sub.x-(E.sup.N.sub.n).sub.y).sub.z

where E represents a nucleotide sequence comprising at least one of the at least one distinct epitope-encoding nucleic acid sequences, [0352] n represents the number of separate distinct epitope-encoding nucleic acid sequences and is any integer including 0, [0353] E.sup.N represents a nucleotide sequence comprising the separate distinct epitope-encoding nucleic acid sequence for each corresponding n, [0354] for each iteration of z: x=0 or 1, y=0 or 1 for each n, and at least one of x or y=1, and z=2 or greater, wherein the antigen-encoding nucleic acid sequence comprises at least two iterations of E, a given E.sup.N, or a combination thereof.

[0355] Each E or E.sup.N can independently comprise any epitope-encoding nucleic acid sequence described herein (e.g., a nucleotide sequence encoding a polypeptide sequence as set forth in Table A, Table B, and/or Table C). For example, Each E or E.sup.N can independently comprises a nucleotide sequence described, from 5′ to 3′, by the formula (L5.sub.b-N.sub.c-L3.sub.d), where N comprises the distinct epitope-encoding nucleic acid sequence associated with each E or E.sup.N, where c=1, L5 comprises a 5′ linker sequence, where b=0 or 1, and L3 comprises a 3′ linker sequence, where d=0 or 1. Epitopes and linkers that can be used are further described herein.

[0356] Repeats of an epitope-encoding nucleic acid sequences (inclusive of optional 5′ linker sequence and/or the optional 3′ linker sequences) can be linearly linked directly to one another (e.g., E.sub.A-E.sub.A- . . . as illustrated above). Repeats of an epitope-encoding nucleic acid sequences can be separated by one or more additional nucleotides sequences. In general, repeats of an epitope-encoding nucleic acid sequences can be separated by any size nucleotide sequence applicable for the compositions described herein. In one example, repeats of an epitope-encoding nucleic acid sequences can be separated by a separate distinct epitope-encoding nucleic acid sequence (e.g., E.sub.A-E.sub.B-E.sub.C-E.sub.A . . . , as illustrated above). In examples where repeats are separated by a single separate distinct epitope-encoding nucleic acid sequence, and each epitope-encoding nucleic acid sequences (inclusive of optional 5′ linker sequence and/or the optional 3′ linker sequences) encodes a peptide 25 amino acids in length, the repeats can be separated by 75 nucleotides, such as in antigen-encoding nucleic acid represented by E.sub.A-E.sub.B-E.sub.A . . . , E.sub.A is separated by 75 nucleotides. In an illustrative example, an antigen-encoding nucleic acid having the sequence VTNTEMFVTAPDNLGYMYEVQWPGQTQPQIANCSVYDFFVWLHYYSVRDTVTNTEMF VTAPDNLGYMYEVQWPGQTQPQIANCSVYDFFVWLHYYSVRDT (SEQ ID NO: 115) encoding repeats of 25mer antigens Trp1 (VTNTEMFVTAPDNLGYMYEVQWPGQ; SEQ ID NO: 116) and Trp2 (TQPQIANCSVYDFFVWLHYYSVRDT; SEQ ID NO: 117), the repeats of Trp1 are separated by the 25mer Trp2 and thus the repeats of the Trp1 epitope-encoding nucleic acid sequences are separated the 75 nucleotide Trp2 epitope-encoding nucleic acid sequence. In examples where repeats are separated by 2, 3, 4, 5, 6, 7, 8, or 9 separate distinct epitope-encoding nucleic acid sequence, and each epitope-encoding nucleic acid sequences (inclusive of optional 5′ linker sequence and/or the optional 3′ linker sequences) encodes a peptide 25 amino acids in length, the repeats can be separated by 150, 225, 300, 375, 450, 525, 600, or 675 nucleotides, respectively.

[0357] In one embodiment, different peptides and/or polypeptides or nucleotide sequences encoding them are selected so that the peptides and/or polypeptides capable of associating with different MHC molecules, such as different MHC class I molecules and/or different MHC class II molecules. In some aspects, one vaccine composition comprises coding sequence for peptides and/or polypeptides capable of associating with the most frequently occurring MHC class I molecules and/or different MHC class II molecules. Hence, vaccine compositions can comprise different fragments capable of associating with at least 2 preferred, at least 3 preferred, or at least 4 preferred MHC class I molecules and/or different MHC class II molecules.

[0358] The vaccine composition can stimulate a specific cytotoxic T-cell response and a specific helper T-cell response.

[0359] The vaccine composition can stimulate a specific B-cell response (e.g., an antibody response).

[0360] The vaccine composition can stimulate a specific cytotoxic T-cell response, a specific helper T-cell response, and/or a specific B-cell response. The vaccine composition can stimulate a specific cytotoxic T-cell response and a specific B-cell response. The vaccine composition can stimulate a specific helper T-cell response and a specific B-cell response. The vaccine composition can stimulate a specific cytotoxic T-cell response, a specific helper T-cell response, and a specific B-cell response.

[0361] A combination of vaccine compositions can stimulate a specific cytotoxic T-cell response, a specific helper T-cell response, and/or a specific B-cell response. Vaccine compositions can be homologous and stimulate a specific cytotoxic T-cell response, a specific helper T-cell response, and/or a specific B-cell response in combination. Vaccine compositions can be homologous and stimulate a specific cytotoxic T-cell response, a specific helper T-cell response, and a specific B-cell response in combination. Vaccine compositions can be heterologous and stimulate a specific cytotoxic T-cell response, a specific helper T-cell response, and/or a specific B-cell response in combination. Vaccine compositions can be heterologous and stimulate a specific cytotoxic T-cell response, a specific helper T-cell response, and a specific B-cell response in combination. Heterologous vaccines include an identical antigen cassette encoded by different vaccine platforms, e.g., a viral vaccine (e.g., a ChAdV-based platform) and a mRNA vaccine (e.g., a SAM-based platform). Heterologous vaccines include different antigen cassettes (e.g., a Spike cassette and a separate T cell epitope encoding cassette, or epitopes/antigens derived from different isolates of SARS-CoV-2, such as Spike protein variants from a Wuhan-Hu-1 isolate and a B.1.351 isolate) encoded by the same vaccine platform, e.g., either a viral vaccine (e.g., a ChAdV-based platform) or a mRNA vaccine (e.g., a SAM-based platform). Heterologous vaccines include different antigen cassettes (e.g., a Spike cassette and a separate T cell epitope encoding cassette or epitopes/antigens derived from different isolates of SARS-CoV-2, such as Spike protein variants from a Wuhan-Hu-1 isolate and a B.1.351 isolate) encoded by different vaccine platforms, e.g., a viral vaccine (e.g., a ChAdV-based platform) and a mRNA vaccine (e.g., a SAM-based platform). For example, as an illustrative non-limiting example, a viral vaccine (e.g., a ChAdV-based platform) can in particular stimulate a robust cytotoxic T-cell response and a mRNA vaccine (e.g., a SAM-based platform) can in particular stimulate a robust B-cell response.

[0362] A vaccine composition can further comprise an adjuvant and/or a carrier. Examples of useful adjuvants and carriers are given herein below. A composition can be associated with a carrier such as e.g. a protein or an antigen-presenting cell such as, e.g., a dendritic cell (DC) capable of presenting the peptide to a T-cell.

[0363] Adjuvants are any substance whose admixture into a vaccine composition increases or otherwise modifies the immune response to an antigen. Carriers can be scaffold structures, for example a polypeptide or a polysaccharide, to which an antigen, is capable of being associated. Optionally, adjuvants are conjugated covalently or non-covalently.

[0364] The ability of an adjuvant to increase an immune response to an antigen is typically manifested by a significant or substantial increase in an immune-mediated reaction, or reduction in disease symptoms. For example, an increase in humoral immunity is typically manifested by a significant increase in the titer of antibodies raised to the antigen, and an increase in T-cell activity is typically manifested in increased cell proliferation, or cellular cytotoxicity, or cytokine secretion. An adjuvant may also alter an immune response, for example, by changing a primarily humoral or Th response into a primarily cellular, or Th response.

[0365] Suitable adjuvants include, but are not limited to 1018 ISS, alum, aluminium salts, Amplivax, AS15, BCG, CP-870,893, CpG7909, CyaA, dSLIM, GM-CSF, IC30, IC31, Imiquimod, ImuFact IMP321, IS Patch, ISS, ISCOMATRIX, JuvImmune, LipoVac, MF59, monophosphoryl lipid A, Montanide IMS 1312, Montanide ISA 206, Montanide ISA 50V, Montanide ISA-51, OK-432, OM-174, OM-197-MP-EC, ONTAK, PepTel vector system, PLG microparticles, resiquimod, SRL172, Virosomes and other Virus-like particles, YF-17D, VEGF trap, R848, beta-glucan, Pam3Cys, Aquila's QS21 stimulon (Aquila Biotech, Worcester, Mass., USA) which is derived from saponin, mycobacterial extracts and synthetic bacterial cell wall mimics, and other proprietary adjuvants such as Ribi's Detox. Quil or Superfos. Adjuvants such as incomplete Freund's or GM-CSF are useful. Several immunological adjuvants (e.g., MF59) specific for dendritic cells and their preparation have been described previously (Dupuis M, et al., Cell Immunol. 1998; 186(1):18-27; Allison A C; Dev Biol Stand. 1998; 92:3-11). Also cytokines can be used. Several cytokines have been directly linked to influencing dendritic cell migration to lymphoid tissues (e.g., TNF-alpha), accelerating the maturation of dendritic cells into efficient antigen-presenting cells for T-lymphocytes (e.g., GM-CSF, IL-1 and IL-4) (U.S. Pat. No. 5,849,589, specifically incorporated herein by reference in its entirety) and acting as immunoadjuvants (e.g., IL-12) (Gabrilovich D I, et al., J Immunother Emphasis Tumor Immunol. 1996 (6):414-418).

[0366] CpG immunostimulatory oligonucleotides have also been reported to enhance the effects of adjuvants in a vaccine setting. Other TLR binding molecules such as RNA binding TLR 7, TLR 8 and/or TLR 9 may also be used.

[0367] Other examples of useful adjuvants include, but are not limited to, chemically modified CpGs (e.g. CpR, Idera), Poly(I:C)(e.g. polyi:CI2U), non-CpG bacterial DNA or RNA as well as immunoactive small molecules and antibodies such as cyclophosphamide, sunitinib, bevacizumab, celebrex, NCX-4016, sildenafil, tadalafil, vardenafil, sorafinib, XL-999, CP-547632, pazopanib, ZD2171, AZD2171, ipilimumab, tremelimumab, and SC58175, which may act therapeutically and/or as an adjuvant. The amounts and concentrations of adjuvants and additives can readily be determined by the skilled artisan without undue experimentation. Additional adjuvants include colony-stimulating factors, such as Granulocyte Macrophage Colony Stimulating Factor (GM-CSF, sargramostim).

[0368] A vaccine composition can comprise more than one different adjuvant. Furthermore, a therapeutic composition can comprise any adjuvant substance including any of the above or combinations thereof. It is also contemplated that a vaccine and an adjuvant can be administered together or separately in any appropriate sequence.

[0369] A carrier (or excipient) can be present independently of an adjuvant. The function of a carrier can for example be to increase the molecular weight of in particular mutant to increase activity or immunogenicity, to confer stability, to increase the biological activity, or to increase serum half-life. Furthermore, a carrier can aid presenting peptides to T-cells. A carrier can be any suitable carrier known to the person skilled in the art, for example a protein or an antigen presenting cell. A carrier protein could be but is not limited to keyhole limpet hemocyanin, serum proteins such as transferrin, bovine serum albumin, human serum albumin, thyroglobulin or ovalbumin, immunoglobulins, or hormones, such as insulin or palmitic acid. For immunization of humans, the carrier is generally a physiologically acceptable carrier acceptable to humans and safe. However, tetanus toxoid and/or diphtheria toxoid are suitable carriers. Alternatively, the carrier can be dextrans for example Sepharose.

[0370] Cytotoxic T-cells (CTLs) recognize an antigen in the form of a peptide bound to an MHC molecule rather than the intact foreign antigen itself. The MHC molecule itself is located at the cell surface of an antigen presenting cell. Thus, an activation of CTLs is possible if a trimeric complex of peptide antigen, MHC molecule, and APC is present. Correspondingly, it may enhance the immune response if not only the peptide is used for activation of CTLs, but if additionally APCs with the respective MHC molecule are added. Therefore, in some embodiments a vaccine composition additionally contains at least one antigen presenting cell.

[0371] Antigens can also be included in viral vector-based vaccine platforms, such as vaccinia, fowlpox, self-replicating alphavirus, marabavirus, adenovirus (See, e.g., Tatsis et al., Adenoviruses, Molecular Therapy (2004) 10, 616-629), or lentivirus, including but not limited to second, third or hybrid second/third generation lentivirus and recombinant lentivirus of any generation designed to target specific cell types or receptors (See, e.g., Hu et al., Immunization Delivered by Lentiviral Vectors for Cancer and Infectious Diseases, Immunol Rev. (2011) 239(1): 45-61, Sakuma et al., Lentiviral vectors: basic to translational, Biochem J. (2012) 443(3):603-18, Cooper et al., Rescue of splicing-mediated intron loss maximizes expression in lentiviral vectors containing the human ubiquitin C promoter, Nucl. Acids Res. (2015) 43 (1): 682-690, Zufferey et al., Self-Inactivating Lentivirus Vector for Safe and Efficient In Vivo Gene Delivery, J. Virol. (1998) 72 (12): 9873-9880). Dependent on the packaging capacity of the above mentioned viral vector-based vaccine platforms, this approach can deliver one or more nucleotide sequences that encode one or more antigen peptides. The sequences may be flanked by non-mutated sequences, may be separated by linkers or may be preceded with one or more sequences targeting a subcellular compartment (See, e.g., Gros et al., Prospective identification of neoantigen-specific lymphocytes in the peripheral blood of melanoma patients, Nat Med. (2016) 22 (4):433-8, Stronen et al., Targeting of cancer neoantigens with donor-derived T cell receptor repertoires, Science. (2016) 352 (6291):1337-41, Lu et al., Efficient identification of mutated cancer antigens recognized by T cells associated with durable tumor regressions, Clin Cancer Res. (2014) 20(13):3401-10). Upon introduction into a host, infected cells express the antigens, and thereby stimulate a host immune (e.g., CTL) response against the peptide(s). Vaccinia vectors and methods useful in immunization protocols are described in, e.g., U.S. Pat. No. 4,722,848. Another vector is BCG (Bacille Calmette Guerin). BCG vectors are described in Stover et al. (Nature 351:456-460 (1991)). A wide variety of other vaccine vectors useful for therapeutic administration or immunization of antigens, e.g., Salmonella typhi vectors, and the like will be apparent to those skilled in the art from the description herein.

[0372] V.A. Antigen Cassette

[0373] The methods employed for the selection of one or more antigens, the cloning and construction of a “cassette” and its insertion into a viral vector are within the skill in the art given the teachings provided herein. By “antigen cassette” or “cassette” is meant the combination of a selected antigen or plurality of antigens (e.g., antigen-encoding nucleic acid sequences) and the other regulatory elements necessary to transcribe the antigen(s) and express the transcribed product. The selected antigen or plurality of antigens can refer to distinct epitope sequences, e.g., an antigen-encoding nucleic acid sequence in the cassette can encode an epitope-encoding nucleic acid sequence (or plurality of epitope-encoding nucleic acid sequences) such that the epitopes are transcribed and expressed. An antigen or plurality of antigens can be operatively linked to regulatory components in a manner which permits transcription. Such components include conventional regulatory elements that can drive expression of the antigen(s) in a cell transfected with the viral vector. Thus the antigen cassette can also contain a selected promoter which is linked to the antigen(s) and located, with other, optional regulatory elements, within the selected viral sequences of the recombinant vector. A cassette can have one or more antigen-encoding nucleic acid sequences, such as a cassette containing multiple antigen-encoding nucleic acid sequences each independently operably linked to separate promoters and/or linked together using other multicistonic systems, such as 2A ribosome skipping sequence elements (e.g., E2A, P2A, F2A, or T2A sequences) or Internal Ribosome Entry Site (IRES) sequence elements. A linker can also have a cleavage site, such as a TEV or furin cleavage site. Linkers with cleavage sites can be used in combination with other elements, such as those in a multicistronic system. In a non-limiting illustrative example, a furin protease cleavage site can be used in conjuction with a 2A ribosome skipping sequence element such that the furin protease cleavage site is configured to facilitate removal of the 2A sequence following translation. In a cassette containing more than one antigen-encoding nucleic acid sequences, each antigen-encoding nucleic acid sequence can contain one or more epitope-encoding nucleic acid sequences (e.g., an antigen-encoding nucleic acid sequence encoding concatenated T cell epitopes). In illustrative examples of multicistronic formats, cassettes encoding SARS-CoV-2 antigens are configured as follows: (1) endogenous 26S promoter—Spike protein—T2A—Membrane protein, or (2) endogenous 26S promoter—Spike protein—26S promoter—concatenated T cell epitopes.

[0374] Useful promoters can be constitutive promoters or regulated (inducible) promoters, which will enable control of the amount of antigen(s) to be expressed. For example, a desirable promoter is that of the cytomegalovirus immediate early promoter/enhancer [see, e.g., Boshart et al, Cell, 41:521-530 (1985)]. Another desirable promoter includes the Rous sarcoma virus LTR promoter/enhancer. Still another promoter/enhancer sequence is the chicken cytoplasmic beta-actin promoter [T. A. Kost et al, Nucl. Acids Res., 11(23):8287 (1983)]. Other suitable or desirable promoters can be selected by one of skill in the art.

[0375] The antigen cassette can also include nucleic acid sequences heterologous to the viral vector sequences including sequences providing signals for efficient polyadenylation of the transcript (poly(A), poly-A or pA) and introns with functional splice donor and acceptor sites. A common poly-A sequence which is employed in the exemplary vectors of this invention is that derived from the papovavirus SV-40. The poly-A sequence generally can be inserted in the cassette following the antigen-based sequences and before the viral vector sequences. A common intron sequence can also be derived from SV-40, and is referred to as the SV-40 T intron sequence. An antigen cassette can also contain such an intron, located between the promoter/enhancer sequence and the antigen(s). Selection of these and other common vector elements are conventional [see, e.g., Sambrook et al, “Molecular Cloning. A Laboratory Manual.”, 2d edit., Cold Spring Harbor Laboratory, New York (1989) and references cited therein] and many such sequences are available from commercial and industrial sources as well as from Genbank.

[0376] An antigen cassette can have one or more antigens. For example, a given cassette can include 1-10, 1-20, 1-30, 10-20, 15-25, 15-20, 1, 2, 3, 4, 5, 6, 7, 8, 9, 10, 11, 12, 13, 14, 15, 16, 17, 18, 19, 20, or more antigens. Antigens can be linked directly to one another. Antigens can also be linked to one another with linkers. Antigens can be in any orientation relative to one another including N to C or C to N.

[0377] As described elsewhere, the antigen cassette can be located in the site of any selected deletion in the viral vector backbone, such as the site of the E1 gene region deletion or E3 gene region deletion of a ChAd-based vector or the deleted structural proteins of a VEE backbone, among others which may be selected.

[0378] The antigen encoding sequence (e.g., cassette or one or more of the nucleic acid sequences encoding an immunogenic polypeptide in the cassette) can be described using the following formula to describe the ordered sequence of each element, from 5′ to 3′:

P.sub.a-(L5.sub.b-N.sub.c-L3.sub.d).sub.X-(G5.sub.e-U.sub.f).sub.Y-G3.sub.g

wherein P comprises the second promoter nucleotide sequence, where a=0 or 1, where c=1, N comprises one of the SARS-CoV-2 derived nucleic acid sequences described herein, optionally wherein each N encodes a polypeptide sequence as set forth in Table A, Table B, and/or Table C, L5 comprises the 5′ linker sequence, where b=0 or 1, L3 comprises the 3′ linker sequence, where d=0 or 1, G5 comprises one of the at least one nucleic acid sequences encoding a GPGPG amino acid linker (SEQ ID NO: 56), where e=0 or 1, G3 comprises one of the at least one nucleic acid sequences encoding a GPGPG amino acid linker (SEQ ID NO: 56), where g=0 or 1, U comprises one of the at least one MHC class II epitope-encoding nucleic acid sequence, where f=1, X=1 to 400, where for each X the corresponding N.sub.c is a SARS-CoV-2 derived nucleic acid sequence, and Y=0, 1, or 2, where for each Y the corresponding U.sub.f is a (1) universal MHC class II epitope-encoding nucleic acid sequence, optionally wherein the at least one universal sequence comprises at least one of Tetanus toxoid and PADRE, or (2) a MHC class II SARS-CoV-2 derived epitope-encoding nucleic acid sequence. In some aspects, for each X the corresponding N.sub.c is a distinct SARS-CoV-2 derived nucleic acid sequence. In some aspects, for each Y the corresponding U.sub.f is a distinct universal MHC class II epitope-encoding nucleic acid sequence or a distinct MHC class II SARS-CoV-2 derived epitope-encoding nucleic acid sequence. The above antigen encoding sequence formula in some instances only describes the portion of an antigen cassette encoding concatenated epitope sequences, such as concatenated T cell epitopes. For example, in cassettes encoding concatenated T cell epitopes and one or more full-length SARS-CoV-2 proteins, the above antigen encoding sequence formula describes the concatenated T cell epitopes and separately the cassette encodes one or more full-length SARS-CoV-2 proteins that are linked optionally using a multicistonic system, such as 2A ribosome skipping sequence elements (e.g., E2A, P2A, F2A, or T2A sequences), a Internal Ribosome Entry Site (IRES) sequence elements, and/or independently operably linked to a separate promoter.

[0379] In one example, elements present include where b=1, d=1, e=1, g=1, h=1, X=18, Y=2, and the vector backbone comprises a ChAdV68 vector, a=1, P is a CMV promoter, the at least one second poly(A) sequence is present, wherein the second poly(A) sequence is an exogenous poly(A) sequence to the vector backbone, and optionally wherein the exogenous poly(A) sequence comprises an SV40 poly(A) signal sequence or a BGH poly(A) signal sequence, and each N encodes a MHC class I epitope 7-15 amino acids in length, a MHC class II epitope, an epitope capable of stimulating a B cell response, or combinations thereof, L5 is a native 5′ linker sequence that encodes a native N-terminal amino acid sequence of the epitope, and wherein the 5′ linker sequence encodes a peptide that is at least 3 amino acids in length, L3 is a native 3′ linker sequence that encodes a native C-terminal amino acid sequence of the epitope, and wherein the 3′ linker sequence encodes a peptide that is at least 3 amino acids in length, and U is each of a PADRE class II sequence and a Tetanus toxoid MHC class II sequence. The above antigen encoding sequence formula in some instances only describes the portion of an antigen cassette encoding concatenated epitope sequences, such as concatenated T cell epitopes.

[0380] In one example, elements present include where b=1, d=1, e=1, g=1, h=1, X=18, Y=2, and the vector backbone comprises a Venezuelan equine encephalitis virus vector, a=0, and the antigen cassette is operably linked to an endogenous 26S promoter, and the at least one polyadenylation poly(A) sequence is a poly(A) sequence of at least 80 consecutive A nucleotides (SEQ ID NO: 27940) provided by the backbone, and each N encodes a MHC class I epitope 7-15 amino acids in length, a MHC class II epitope, an epitope capable of stimulating a B cell response, or combinations thereof, L5 is a native 5′ linker sequence that encodes a native N-terminal amino acid sequence of the epitope, and wherein the 5′ linker sequence encodes a peptide that is at least 3 amino acids in length, L3 is a native 3′ linker sequence that encodes a native C-terminal amino acid sequence of the epitope, and wherein the 3′ linker sequence encodes a peptide that is at least 3 amino acids in length, and U is each of a PADRE class II sequence and a Tetanus toxoid MHC class II sequence.

[0381] The antigen encoding sequence can be described using the following formula to describe the ordered sequence of each element, from 5′ to 3′:

(P.sub.a-(L5.sub.b-N.sub.c-L3.sub.d).sub.X).sub.Z-(P2.sub.h-(G5.sub.e-U.sub.f).sub.Y).sub.W-G3.sub.g

wherein P and P2 comprise promoter nucleotide sequences, N comprises one of the SARS-CoV-2 derived nucleic acid sequences described herein (e.g., N encodes a polypeptide sequence as set forth in Table A, Table B, Table C, and/or Table 10), L5 comprises a 5′ linker sequence, L3 comprises a 3′ linker sequence, G5 comprises a nucleic acid sequences encoding an amino acid linker, G3 comprises one of the at least one nucleic acid sequences encoding an amino acid linker, U comprises an MHC class II epitope-encoding nucleic acid sequence, where for each X the corresponding N.sub.c is a SARS-CoV-2 derived nucleic acid sequence, where for each Y the corresponding U.sub.f is a (1) universal MHC class II epitope-encoding nucleic acid sequence, optionally wherein the at least one universal sequence comprises at least one of Tetanus toxoid and PADRE, or (2) a MHC class II SARS-CoV-2 derived epitope-encoding nucleic acid sequence. The composition and ordered sequence can be further defined by selecting the number of elements present, for example where a=0 or 1, where b=0 or 1, where c=1, where d=0 or 1, where e=0 or 1, where f=1, where g=0 or 1, where h=0 or 1, X=1 to 400, Y=0, 1, 2, 3, 4 or 5, Z=1 to 400, and W=0, 1, 2, 3, 4 or 5.

[0382] In one example, elements present include where a=0, b=1, d=1, e=1, g=1, h=0, X=10, Y=2, Z=1, and W=1, describing where no additional promoter is present (e.g. only the promoter nucleotide sequence provided by the vector backbone, such as an RNA alphavirus backbone, is present), 10 epitopes are present, a 5′ linker is present for each N, a 3′ linker is present for each N, 2 MHC class II epitopes are present, a linker is present linking the two MHC class II epitopes, a linker is present linking the 5′ end of the two MHC class II epitopes to the 3′ linker of the final MHC class I epitope, and a linker is present linking the 3′ end of the two MHC class II epitopes to the to the vector backbone. Examples of linking the 3′ end of the antigen cassette to the vector backbone include linking directly to the 3′ UTR elements provided by the vector backbone, such as a 3′ 19-nt CSE. Examples of linking the 5′ end of the antigen cassette to the vector backbone include linking directly to a promoter or 5′ UTR element of the vector backbone, such as a 26S promoter sequence, an alphavirus 5′ UTR, a 51-nt CSE, or a 24-nt CSE of an alphavirus vector backbone.

[0383] Other examples include: where a=1 describing where a promoter other than the promoter nucleotide sequence provided by the vector backbone is present; where a=1 and Z is greater than 1 where multiple promoters other than the promoter nucleotide sequence provided by the vector backbone are present each driving expression of 1 or more distinct MHC class I epitope encoding nucleic acid sequences; where h=1 describing where a separate promoter is present to drive expression of the MHC class II epitope-encoding nucleic acid sequences; and where g=0 describing the MHC class II epitope-encoding nucleic acid sequence, if present, is directly linked to the vector backbone.

[0384] Other examples include where each MHC class I epitope that is present can have a 5′ linker, a 3′ linker, neither, or both. In examples where more than one MHC class I epitope is present in the same antigen cassette, some MHC class I epitopes may have both a 5′ linker and a 3′ linker, while other MHC class I epitopes may have either a 5′ linker, a 3′ linker, or neither. In other examples where more than one MHC class I epitope is present in the same antigen cassette, some MHC class I epitopes may have either a 5′ linker or a 3′ linker, while other MHC class I epitopes may have either a 5′ linker, a 3′ linker, or neither.

[0385] In examples where more than one MHC class II epitope is present in the same antigen cassette, some MHC class II epitopes may have both a 5′ linker and a 3′ linker, while other MHC class II epitopes may have either a 5′ linker, a 3′ linker, or neither. In other examples where more than one MHC class II epitope is present in the same antigen cassette, some MHC class II epitopes may have either a 5′ linker or a 3′ linker, while other MHC class II epitopes may have either a 5′ linker, a 3′ linker, or neither.

[0386] Other examples include where each antigen that is present can have a 5′ linker, a 3′ linker, neither, or both. In examples where more than one antigen is present in the same antigen cassette, some antigens may have both a 5′ linker and a 3′ linker, while other antigens may have either a 5′ linker, a 3′ linker, or neither. In other examples where more than one antigen is present in the same antigen cassette, some antigens may have either a 5′ linker or a 3′ linker, while other antigens may have either a 5′ linker, a 3′ linker, or neither.

[0387] The promoter nucleotide sequences P and/or P2 can be the same as a promoter nucleotide sequence provided by the vector backbone, such as a RNA alphavirus backbone. For example, the promoter sequence provided by the vector backbone, Pn and P2, can each comprise a 26S subgenomic promoter or a CMV promoter. The promoter nucleotide sequences P and/or P2 can be different from the promoter nucleotide sequence provided by the vector backbone, as well as can be different from each other.

[0388] The 5′ linker L5 can be a native sequence or a non-natural sequence. Non-natural sequence include, but are not limited to, AAY, RR, and DPP. The 3′ linker L3 can also be a native sequence or a non-natural sequence. Additionally, L5 and L3 can both be native sequences, both be non-natural sequences, or one can be native and the other non-natural. For each X, the amino acid linkers can be 2, 3, 4, 5, 6, 7, 8, 9, 10, 11, 12, 13, 14, 15, 16, 17, 18, 19, 20, 21, 22, 23, 24, 25, 26, 27, 28, 29, 30, 31, 32, 33, 34, 35, 36, 37, 38, 39, 40, 41, 42, 43, 44, 45, 46, 47, 48, 49, 50, 51, 52, 53, 54, 55, 56, 57, 58, 59, 60, 61, 62, 63, 64, 65, 66, 67, 68, 69, 70, 71, 72, 73, 74, 75, 76, 77, 78, 79, 80, 81, 82, 83, 84, 85, 86, 87, 88, 89, 90, 91, 92, 93, 94, 95, 96, 97, 98, 99, 100 or more amino acids in length. For each X, the amino acid linkers can be also be at least 3, at least 4, at least 5, at least 6, at least 7, at least 8, at least 9, at least 10, at least 11, at least 12, at least 13, at least 14, at least 15, at least 16, at least 17, at least 18, at least 19, at least 20, at least 21, at least 22, at least 23, at least 24, at least 25, at least 26, at least 27, at least 28, at least 29, or at least 30 amino acids in length.

[0389] The amino acid linker G5, for each Y, can be 2, 3, 4, 5, 6, 7, 8, 9, 10, 11, 12, 13, 14, 15, 16, 17, 18, 19, 20, 21, 22, 23, 24, 25, 26, 27, 28, 29, 30, 31, 32, 33, 34, 35, 36, 37, 38, 39, 40, 41, 42, 43, 44, 45, 46, 47, 48, 49, 50, 51, 52, 53, 54, 55, 56, 57, 58, 59, 60, 61, 62, 63, 64, 65, 66, 67, 68, 69, 70, 71, 72, 73, 74, 75, 76, 77, 78, 79, 80, 81, 82, 83, 84, 85, 86, 87, 88, 89, 90, 91, 92, 93, 94, 95, 96, 97, 98, 99, 100 or more amino acids in length. For each Y, the amino acid linkers can be also be at least 3, at least 4, at least 5, at least 6, at least 7, at least 8, at least 9, at least 10, at least 11, at least 12, at least 13, at least 14, at least 15, at least 16, at least 17, at least 18, at least 19, at least 20, at least 21, at least 22, at least 23, at least 24, at least 25, at least 26, at least 27, at least 28, at least 29, or at least 30 amino acids in length.

[0390] The amino acid linker G3 can be 2, 3, 4, 5, 6, 7, 8, 9, 10, 11, 12, 13, 14, 15, 16, 17, 18, 19, 20, 21, 22, 23, 24, 25, 26, 27, 28, 29, 30, 31, 32, 33, 34, 35, 36, 37, 38, 39, 40, 41, 42, 43, 44, 45, 46, 47, 48, 49, 50, 51, 52, 53, 54, 55, 56, 57, 58, 59, 60, 61, 62, 63, 64, 65, 66, 67, 68, 69, 70, 71, 72, 73, 74, 75, 76, 77, 78, 79, 80, 81, 82, 83, 84, 85, 86, 87, 88, 89, 90, 91, 92, 93, 94, 95, 96, 97, 98, 99, 100 or more amino acids in length. G3 can be also be at least 3, at least 4, at least 5, at least 6, at least 7, at least 8, at least 9, at least 10, at least 11, at least 12, at least 13, at least 14, at least 15, at least 16, at least 17, at least 18, at least 19, at least 20, at least 21, at least 22, at least 23, at least 24, at least 25, at least 26, at least 27, at least 28, at least 29, or at least 30 amino acids in length.

[0391] For each X, each N can encode a MHC class I epitope, a MHC class II epitope, an epitope capable of stimulating a B cell response, or a combination thereof. For each X, N can encode a combination of a MHC class I epitope, a MHC class II epitope, and an epitope capable of stimulating a B cell response. For each X, N can encode a combination of a MHC class I epitope and a MHC class II epitope. For each X, N can encode a combination of a MHC class I epitope and an epitope capable of stimulating a B cell response. For each X, N can encode a combination of a MHC class II epitope and an epitope capable of stimulating a B cell response. For each X, each N can encode a MHC class I epitope 7-15 amino acids in length. For each X, each N can also encodes a MHC class I epitope 5, 6, 7, 8, 9, 10, 11, 12, 13, 14, 15, 16, 17, 18, 19, 20, 21, 22, 23, 24, 25, 26, 27, 28, 29, or 30 amino acids in length. For each X, each N can also encodes a MHC class I epitope at least 5, at least 6, at least 7, at least 8, at least 9, at least 10, at least 11, at least 12, at least 13, at least 14, at least 15, at least 16, at least 17, at least 18, at least 19, at least 20, at least 21, at least 22, at least 23, at least 24, at least 25, at least 26, at least 27, at least 28, at least 29, or at least 30 amino acids in length. For each X, each N can encode a MHC class II epitope. For each X, each N can encode an epitope capable of stimulating a B cell response.

[0392] The cassette encoding the one or more antigens can be 700 nucleotides or less. The cassette encoding the one or more antigens can be 700 nucleotides or less and encode 2 distinct epitope-encoding nucleic acid sequences (e.g., encode 2 distinct SARS-CoV-2 derived nucleic acid sequence encoding an immunogenic polypeptide). The cassette encoding the one or more antigens can be 700 nucleotides or less and encode at least 2 distinct epitope-encoding nucleic acid sequences. The cassette encoding the one or more antigens can be 700 nucleotides or less and encode 3 distinct epitope-encoding nucleic acid sequences. The cassette encoding the one or more antigens can be 700 nucleotides or less and encode at least 3 distinct epitope-encoding nucleic acid sequences. The cassette encoding the one or more antigens can be 700 nucleotides or less and include 1-10, 1-5, 1, 2, 3, 4, 5, 6, 7, 8, 9, 10, or more antigens.

[0393] The cassette encoding the one or more antigens can be between 375-700 nucleotides in length. The cassette encoding the one or more antigens can be between 375-700 nucleotides in length and encode 2 distinct epitope-encoding nucleic acid sequences. The cassette encoding the one or more antigens can be between 375-700 nucleotides in length and encode at least 2 distinct epitope-encoding nucleic acid sequences. The cassette encoding the one or more antigens can be between 375-700 nucleotides in length and encode 3 distinct epitope-encoding nucleic acid sequences. The cassette encoding the one or more antigens be between 375-700 nucleotides in length and encode at least 3 distinct epitope-encoding nucleic acid sequences. The cassette encoding the one or more antigens can be between 375-700 nucleotides in length and include 1-10, 1-5, 1, 2, 3, 4, 5, 6, 7, 8, 9, 10, or more antigens.

[0394] The cassette encoding the one or more antigens can be 600, 500, 400, 300, 200, or 100 nucleotides in length or less. The cassette encoding the one or more antigens can be 600, 500, 400, 300, 200, or 100 nucleotides in length or less and encode 2 distinct epitope-encoding nucleic acid sequences. The cassette encoding the one or more antigens can be 600, 500, 400, 300, 200, or 100 nucleotides in length or less and encode at least 2 distinct epitope-encoding nucleic acid sequences. The cassette encoding the one or more antigens can be 600, 500, 400, 300, 200, or 100 nucleotides in length or less and encode 3 distinct epitope-encoding nucleic acid sequences. The cassette encoding the one or more antigens can be 600, 500, 400, 300, 200, or 100 nucleotides in length or less and encode at least 3 distinct epitope-encoding nucleic acid sequences. The cassette encoding the one or more antigens can be 600, 500, 400, 300, 200, or 100 nucleotides in length or less and include 1-10, 1-5, 1, 2, 3, 4, 5, 6, 7, 8, 9, 10, or more antigens.

[0395] The cassette encoding the one or more antigens can be between 375-600, between 375-500, or between 375-400 nucleotides in length. The cassette encoding the one or more antigens can be between 375-600, between 375-500, or between 375-400 nucleotides in length and encode 2 distinct epitope-encoding nucleic acid sequences. The cassette encoding the one or more antigens can be between 375-600, between 375-500, or between 375-400 nucleotides in length and encode at least 2 distinct epitope-encoding nucleic acid sequences. The cassette encoding the one or more antigens can be between 375-600, between 375-500, or between 375-400 nucleotides in length and encode 3 distinct epitope-encoding nucleic acid sequences. The cassette encoding the one or more antigens can be between 375-600, between 375-500, or between 375-400 nucleotides in length and encode at least 3 distinct epitope-encoding nucleic acid sequences. The cassette encoding the one or more antigens can be between 375-600, between 375-500, or between 375-400 nucleotides in length and include 1-10, 1-5, 1, 2, 3, 4, 5, 6, 7, 8, 9, 10, or more antigens.

[0396] V.B. Additional Considerations for Vaccine Design and Manufacture

[0397] After all of the above antigen filters are applied, more candidate antigens may still be available for vaccine inclusion than the vaccine technology can support. Additionally, uncertainty about various aspects of the antigen analysis may remain and tradeoffs may exist between different properties of candidate vaccine antigens. Thus, in place of predetermined filters at each step of the selection process, an integrated multi-dimensional model can be considered that places candidate antigens in a space with at least the following axes and optimizes selection using an integrative approach. [0398] 1. Risk of auto-immunity or tolerance (risk of germline) (lower risk of auto-immunity is typically preferred) [0399] 2. Probability of sequencing artifact (lower probability of artifact is typically preferred) [0400] 3. Probability of immunogenicity (higher probability of immunogenicity is typically preferred) [0401] 4. Probability of presentation (higher probability of presentation is typically preferred) [0402] 5. Gene expression (higher expression is typically preferred) [0403] 6. Coverage of HLA genes (larger number of HLA molecules involved in the presentation of a set of antigens may lower the probability that an infected cell will escape immune attack via downregulation or mutation of HLA molecules) [0404] 7. Coverage of HLA classes (covering both HLA-I and HLA-II may increase the probability of therapeutic response and decrease the probability of infectious disease escape)

[0405] Additionally, optionally, antigens can be deprioritized (e.g., excluded) from the vaccination if they are predicted to be presented by HLA alleles lost or inactivated in either all or part of the patient's infected cell. HLA allele loss can occur by either somatic mutation, loss of heterozygosity, or homozygous deletion of the locus. Methods for detection of HLA allele somatic mutation are well known in the art, e.g. (Shukla et al., 2015). Methods for detection of somatic LOH and homozygous deletion (including for HLA locus) are likewise well described. (Carter et al., 2012; McGranahan et al., 2017; Van Loo et al., 2010). Antigens can also be deprioritized if mass-spectrometry data indicates a predicted antigen is not presented by a predicted HLA allele.

[0406] V.C. Self-Amplifying RNA Vectors

[0407] In general, all self-amplifying RNA (SAM) vectors contain a self-amplifying backbone derived from a self-replicating virus. The term “self-amplifying backbone” refers to minimal sequence(s) of a self-replicating virus that allows for self-replication of the viral genome. For example, minimal sequences that allow for self-replication of an alphavirus can include conserved sequences for nonstructural protein-mediated amplification (e.g., a nonstructural protein 1 (nsP1) gene, a nsP2 gene, a nsP3 gene, a nsP4 gene, and/or a polyA sequence). A self-amplifying backbone can also include sequences for expression of subgenomic viral RNA (e.g., a 26S promoter element for an alphavirus). SAM vectors can be positive-sense RNA polynucleotides or negative-sense RNA polynucleotides, such as vectors with backbones derived from positive-sense or negative-sense self-replicating viruses. Self-replicating viruses include, but are not limited to, alphaviruses, flaviviruses (e.g., Kunjin virus), measles viruses, and rhabdoviruses (e.g., rabies virus and vesicular stomatitis virus). Examples of SAM vector systems derived from self-replicating viruses are described in greater detail in Lundstrom (Molecules. 2018 Dec. 13; 23(12). pii: E3310. doi: 10.3390/molecules23123310), herein incorporated by reference for all purposes.

[0408] V.C.1. Alphavirus Biology

[0409] Alphaviruses are members of the family Togaviridae, and are positive-sense single stranded RNA viruses. Members are typically classified as either Old World, such as Sindbis, Ross River, Mayaro, Chikungunya, and Semliki Forest viruses, or New World, such as eastern equine encephalitis, Aura, Fort Morgan, or Venezuelan equine encephalitis virus and its derivative strain TC-83 (Strauss Microbrial Review 1994). A natural alphavirus genome is typically around 12 kb in length, the first two-thirds of which contain genes encoding non-structural proteins (nsPs) that form RNA replication complexes for self-replication of the viral genome, and the last third of which contains a subgenomic expression cassette encoding structural proteins for virion production (Frolov RNA 2001).

[0410] A model lifecycle of an alphavirus involves several distinct steps (Strauss Microbrial Review 1994, Jose Future Microbiol 2009). Following virus attachment to a host cell, the virion fuses with membranes within endocytic compartments resulting in the eventual release of genomic RNA into the cytosol. The genomic RNA, which is in a plus-strand orientation and comprises a 5′ methylguanylate cap and 3′ polyA tail, is translated to produce non-structural proteins nsP1-4 that form the replication complex. Early in infection, the plus-strand is then replicated by the complex into a minus-stand template. In the current model, the replication complex is further processed as infection progresses, with the resulting processed complex switching to transcription of the minus-strand into both full-length positive-strand genomic RNA, as well as the 26S subgenomic positive-strand RNA containing the structural genes. Several conserved sequence elements (CSEs) of alphavirus have been identified to potentially play a role in the various RNA replication steps including; a complement of the 5′ UTR in the replication of plus-strand RNAs from a minus-strand template, a 51-nt CSE in the replication of minus-strand synthesis from the genomic template, a 24-nt CSE in the junction region between the nsPs and the 26S RNA in the transcription of the subgenomic RNA from the minus-strand, and a 3′ 19-nt CSE in minus-strand synthesis from the plus-strand template.

[0411] Following the replication of the various RNA species, virus particles are then typically assembled in the natural lifecycle of the virus. The 26S RNA is translated and the resulting proteins further processed to produce the structural proteins including capsid protein, glycoproteins E1 and E2, and two small polypeptides E3 and 6K (Strauss 1994). Encapsidation of viral RNA occurs, with capsid proteins normally specific for only genomic RNA being packaged, followed by virion assembly and budding at the membrane surface.

[0412] V.C.2. Alphavirus as a Delivery Vector

[0413] Alphaviruses (including alphavirus sequences, features, and other elements) can be used to generate alphavirus-based delivery vectors (also be referred to as alphavirus vectors, alphavirus viral vectors, alphavirus vaccine vectors, self-replicating RNA (srRNA) vectors, or self-amplifying RNA (samRNA) vectors). Alphaviruses have previously been engineered for use as expression vector systems (Pushko 1997, Rheme 2004). Alphaviruses offer several advantages, particularly in a vaccine setting where heterologous antigen expression can be desired. Due to its ability to self-replicate in the host cytosol, alphavirus vectors are generally able to produce high copy numbers of the expression cassette within a cell resulting in a high level of heterologous antigen production. Additionally, the vectors are generally transient, resulting in improved biosafety as well as reduced induction of immunological tolerance to the vector. The public, in general, also lacks pre-existing immunity to alphavirus vectors as compared to other standard viral vectors, such as human adenovirus. Alphavirus based vectors also generally result in cytotoxic responses to infected cells. Cytotoxicity, to a certain degree, can be important in a vaccine setting to properly illicit an immune response to the heterologous antigen expressed. However, the degree of desired cytotoxicity can be a balancing act, and thus several attenuated alphaviruses have been developed, including the TC-83 strain of VEE. Thus, an example of an antigen expression vector described herein can utilize an alphavirus backbone that allows for a high level of antigen expression, stimulates a robust immune response to antigen, does not stimulate an immune response to the vector itself, and can be used in a safe manner. Furthermore, the antigen expression cassette can be designed to stimulate different levels of an immune response through optimization of which alphavirus sequences the vector uses, including, but not limited to, sequences derived from VEE or its attenuated derivative TC-83.

[0414] Several expression vector design strategies have been engineered using alphavirus sequences (Pushko 1997). In one strategy, a alphavirus vector design includes inserting a second copy of the 26S promoter sequence elements downstream of the structural protein genes, followed by a heterologous gene (Frolov 1993). Thus, in addition to the natural non-structural and structural proteins, an additional subgenomic RNA is produced that expresses the heterologous protein. In this system, all the elements for production of infectious virions are present and, therefore, repeated rounds of infection of the expression vector in non-infected cells can occur.

[0415] Another expression vector design makes use of helper virus systems (Pushko 1997). In this strategy, the structural proteins are replaced by a heterologous gene. Thus, following self-replication of viral RNA mediated by still intact non-structural genes, the 26S subgenomic RNA provides for expression of the heterologous protein. Traditionally, additional vectors that expresses the structural proteins are then supplied in trans, such as by co-transfection of a cell line, to produce infectious virus. A system is described in detail in U.S. Pat. No. 8,093,021, which is herein incorporated by reference in its entirety, for all purposes. The helper vector system provides the benefit of limiting the possibility of forming infectious particles and, therefore, improves biosafety. In addition, the helper vector system reduces the total vector length, potentially improving the replication and expression efficiency. Thus, an example of an antigen expression vector described herein can utilize an alphavirus backbone wherein the structural proteins are replaced by an antigen cassette, the resulting vector both reducing biosafety concerns, while at the same time promoting efficient expression due to the reduction in overall expression vector size.

[0416] V.C.3. Self-Amplifying Virus Production In Vitro

[0417] A convenient technique well-known in the art for RNA production is in vitro transcription (IVT). In this technique, a DNA template of the desired vector is first produced by techniques well-known to those in the art, including standard molecular biology techniques such as cloning, restriction digestion, ligation, gene synthesis, and polymerase chain reaction (PCR).

[0418] The DNA template contains a RNA polymerase promoter at the 5′ end of the sequence desired to be transcribed into RNA (e.g., SAM). Promoters include, but are not limited to, bacteriophage polymerase promoters such as T3, T7, KI1, or SP6. Depending on the specific RNA polymerase promoter sequence chosen, additional 5′ nucleotides can transcribed in addition to the desired sequence. For example, the canonical T7 promoter can be referred to by the sequence TAATACGACTCACTATAGG (SEQ ID NO: 118), in which an IVT reaction using the DNA template TAATACGACTCACTATAGGN (SEQ ID NO: 119) for the production of desired sequence N will result in the mRNA sequence GG-N. In general, and without wishing to be bound by theory, T7 polymerase more efficiently transcribes RNA transcripts beginning with guanosine. In instances where additional 5′ nucleotides are not desired (e.g., no additional GG), the RNA polymerase promoter contained in the DNA template can be a sequence the results in transcripts containing only the 5′ nucleotides of the desired sequence, e.g., a SAM having the native 5′ sequence of the self-replicating virus from which the SAM vector is derived. For example, a minimal T7 promoter can be referred to by the sequence TAATACGACTCACTATA (SEQ ID NO: 120), in which an IVT reaction using the DNA template TAATACGACTCACTATAN (SEQ ID NO: 121) for the production of desired sequence N will result in the mRNA sequence N. Likewise, a minimal SP6 promoter referred to by the sequence ATTTAGGTGACACTATA (SEQ ID NO: 122) can be used to generate transcripts without additional 5′ nucleotides. In a typical IVT reaction, the DNA template is incubated with the appropriate RNA polymerase enzyme, buffer agents, and nucleotides (NTPs).

[0419] The resulting RNA polynucleotide can optionally be further modified including, but limited to, addition of a 5′ cap structure such as 7-methylguanosine or a related structure, and optionally modifying the 3′ end to include a polyadenylate (polyA) tail. In a modified IVT reaction, RNA is capped with a 5′ cap structure co-transcriptionally through the addition of cap analogues during IVT. Cap analogues can include dinucleotide (m.sup.7G-ppp-N) cap analogues or trinucleotide (m.sup.7G-ppp-N-N) cap analogues, where N represents a nucleotide or modified nucleotide (e.g., ribonucleosides including, but not limited to, adenosine, guanosine, cytidine, and uradine). Exemplary cap analogues and their use in IVT reactions are also described in greater detail in U.S. Pat. No. 10,519,189, herein incorporated by reference for all purposes. As discussed, T7 polymerase more efficiently transcribes RNA transcripts beginning with guanosine. To improve transcription efficiency in templates that do not begin with guanosine, a trinucleotide cap analogue (m.sup.7G-ppp-N-N) can be used. The trinucleotide cap analogue can increase transcription efficiency 2, 3, 4, 5, 6, 7, 8, 9, 10, 11, 12, 13, 14, 15, 16, 17, 18, 19, 20-fold or more relative to an IVT reaction using a dinucleotide cap analogue (m.sup.7G-ppp-N).

[0420] A 5′ cap structure can also be added following transcription, such as using a vaccinia capping system (e.g., NEB Cat. No. M2080) containing mRNA 2′-O-methyltransferase and S-Adenosyl methionine.

[0421] The resulting RNA polynucleotide can optionally be further modified separately from or in addition to the capping techniques described including, but limited to, modifying the 3′ end to include a polyadenylate (polyA) tail.

[0422] The RNA can then be purified using techniques well-known in the field, such as phenol-chloroform extraction.

[0423] V.C.4. Delivery Via Lipid Nanoparticle

[0424] An important aspect to consider in vaccine vector design is immunity against the vector itself (Riley 2017). This may be in the form of preexisting immunity to the vector itself, such as with certain human adenovirus systems, or in the form of developing immunity to the vector following administration of the vaccine. The latter is an important consideration if multiple administrations of the same vaccine are performed, such as separate priming and boosting doses, or if the same vaccine vector system is to be used to deliver different antigen cassettes.

[0425] In the case of alphavirus vectors, the standard delivery method is the previously discussed helper virus system that provides capsid, E1, and E2 proteins in trans to produce infectious viral particles. However, it is important to note that the E1 and E2 proteins are often major targets of neutralizing antibodies (Strauss 1994). Thus, the efficacy of using alphavirus vectors to deliver antigens of interest to target cells may be reduced if infectious particles are targeted by neutralizing antibodies.

[0426] An alternative to viral particle mediated gene delivery is the use of nanomaterials to deliver expression vectors (Riley 2017). Nanomaterial vehicles, importantly, can be made of non-immunogenic materials and generally avoid stimulating immunity to the delivery vector itself. These materials can include, but are not limited to, lipids, inorganic nanomaterials, and other polymeric materials. Lipids can be cationic, anionic, or neutral. The materials can be synthetic or naturally derived, and in some instances biodegradable. Lipids can include fats, cholesterol, phospholipids, lipid conjugates including, but not limited to, polyethyleneglycol (PEG) conjugates (PEGylated lipids), waxes, oils, glycerides, and fat soluble vitamins.

[0427] Lipid nanoparticles (LNPs) are an attractive delivery system due to the amphiphilic nature of lipids enabling formation of membranes and vesicle like structures (Riley 2017). In general, these vesicles deliver the expression vector by absorbing into the membrane of target cells and releasing nucleic acid into the cytosol. In addition, LNPs can be further modified or functionalized to facilitate targeting of specific cell types. Another consideration in LNP design is the balance between targeting efficiency and cytotoxicity. Lipid compositions generally include defined mixtures of cationic, neutral, anionic, and amphipathic lipids. In some instances, specific lipids are included to prevent LNP aggregation, prevent lipid oxidation, or provide functional chemical groups that facilitate attachment of additional moieties. Lipid composition can influence overall LNP size and stability. In an example, the lipid composition comprises dilinoleylmethyl-4-dimethylaminobutyrate (MC3) or MC3-like molecules. MC3 and MC3-like lipid compositions can be formulated to include one or more other lipids, such as a PEG or PEG-conjugated lipid, a sterol, or neutral lipids.

[0428] Nucleic-acid vectors, such as expression vectors, exposed directly to serum can have several undesirable consequences, including degradation of the nucleic acid by serum nucleases or off-target stimulation of the immune system by the free nucleic acids. Therefore, encapsulation of the alphavirus vector can be used to avoid degradation, while also avoiding potential off-target effects. In certain examples, an alphavirus vector is fully encapsulated within the delivery vehicle, such as within the aqueous interior of an LNP. Encapsulation of the alphavirus vector within an LNP can be carried out by techniques well-known to those skilled in the art, such as microfluidic mixing and droplet generation carried out on a microfluidic droplet generating device. Such devices include, but are not limited to, standard T-junction devices or flow-focusing devices. In an example, the desired lipid formulation, such as MC3 or MC3-like containing compositions, is provided to the droplet generating device in parallel with the alphavirus delivery vector and other desired agents, such that the delivery vector and desired agents are fully encapsulated within the interior of the MC3 or MC3-like based LNP. In an example, the droplet generating device can control the size range and size distribution of the LNPs produced. For example, the LNP can have a size ranging from 1 to 1000 nanometers in diameter, e.g., 1, 10, 50, 100, 500, or 1000 nanometers. Following droplet generation, the delivery vehicles encapsulating the expression vectors can be further treated or modified to prepare them for administration.

[0429] V.D. Chimpanzee Adenovirus (ChAd)

[0430] V.D.1. Viral Delivery with Chimpanzee Adenovirus

[0431] Vaccine compositions for delivery of one or more antigens (e.g., via an antigen cassette) can be created by providing adenovirus nucleotide sequences of chimpanzee origin, a variety of novel vectors, and cell lines expressing chimpanzee adenovirus genes. A nucleotide sequence of a chimpanzee C68 adenovirus (also referred to herein as ChAdV68) can be used in a vaccine composition for antigen delivery (See SEQ ID NO: 1). Use of C68 adenovirus derived vectors is described in further detail in U.S. Pat. No. 6,083,716, which is herein incorporated by reference in its entirety, for all purposes.

[0432] In a further aspect, provided herein is a recombinant adenovirus comprising the DNA sequence of a chimpanzee adenovirus such as C68 and an antigen cassette operatively linked to regulatory sequences directing its expression. The recombinant virus is capable of infecting a mammalian, preferably a human, cell and capable of expressing the antigen cassette product in the cell. In this vector, the native chimpanzee E1 gene, and/or E3 gene, and/or E4 gene can be deleted. An antigen cassette can be inserted into any of these sites of gene deletion. The antigen cassette can include an antigen against which a primed immune response is desired.

[0433] In another aspect, provided herein is a mammalian cell infected with a chimpanzee adenovirus such as C68.

[0434] In still a further aspect, a novel mammalian cell line is provided which expresses a chimpanzee adenovirus gene (e.g., from C68) or functional fragment thereof.

[0435] In still a further aspect, provided herein is a method for delivering an antigen cassette into a mammalian cell comprising the step of introducing into the cell an effective amount of a chimpanzee adenovirus, such as C68, that has been engineered to express the antigen cassette.

[0436] Still another aspect provides a method for stimulating an immune response in a mammalian host. The method can comprise the step of administering to the host an effective amount of a recombinant chimpanzee adenovirus, such as C68, comprising an antigen cassette that encodes one or more antigens from the infection against which the immune response is targeted.

[0437] Still another aspect provides a method for stimulating an immune response in a mammalian host to treat or prevent a disease in a subject, such as an infectious disease. The method can comprise the step of administering to the host an effective amount of a recombinant chimpanzee adenovirus, such as C68, comprising an antigen cassette that encodes one or more antigens, such as from the infectious disease against which the immune response is targeted.

[0438] Also disclosed is a non-simian mammalian cell that expresses a chimpanzee adenovirus gene obtained from the sequence of SEQ ID NO: 1. The gene can be selected from the group consisting of the adenovirus E1A, E1B, E2A, E2B, E3, E4, L1, L2, L3, L4 and L5 of SEQ ID NO: 1.

[0439] Also disclosed is a nucleic acid molecule comprising a chimpanzee adenovirus DNA sequence comprising a gene obtained from the sequence of SEQ ID NO: 1. The gene can be selected from the group consisting of said chimpanzee adenovirus E1A, E1B, E2A, E2B, E3, E4, L1, L2, L3, L4 and L5 genes of SEQ ID NO: 1. In some aspects the nucleic acid molecule comprises SEQ ID NO: 1. In some aspects the nucleic acid molecule comprises the sequence of SEQ ID NO: 1, lacking at least one gene selected from the group consisting of E1A, E1B, E2A, E2B, E3, E4, L1, L2, L3, L4 and L5 genes of SEQ ID NO: 1.

[0440] Also disclosed is a vector comprising a chimpanzee adenovirus DNA sequence obtained from SEQ ID NO: 1 and an antigen cassette operatively linked to one or more regulatory sequences which direct expression of the cassette in a heterologous host cell, optionally wherein the chimpanzee adenovirus DNA sequence comprises at least the cis-elements necessary for replication and virion encapsidation, the cis-elements flanking the antigen cassette and regulatory sequences. In some aspects, the chimpanzee adenovirus DNA sequence comprises a gene selected from the group consisting of E1A, E1B, E2A, E2B, E3, E4, L1, L2, L3, L4 and L5 gene sequences of SEQ ID NO: 1. In some aspects the vector can lack the E1A and/or E1B gene.

[0441] Also disclosed herein is a adenovirus vector comprising: a partially deleted E4 gene comprising a deleted or partially-deleted E4orf2 region and a deleted or partially-deleted E4orf3 region, and optionally a deleted or partially-deleted E4orf4 region. The partially deleted E4 can comprise an E4 deletion of at least nucleotides 34,916 to 35,642 of the sequence shown in SEQ ID NO:1, and wherein the vector comprises at least nucleotides 2 to 36,518 of the sequence set forth in SEQ ID NO:1. The partially deleted E4 can comprise an E4 deletion of at least a partial deletion of nucleotides 34,916 to 34,942 of the sequence shown in SEQ ID NO:1, at least a partial deletion of nucleotides 34,952 to 35,305 of the sequence shown in SEQ ID NO:1, and at least a partial deletion of nucleotides 35,302 to 35,642 of the sequence shown in SEQ ID NO:1, and wherein the vector comprises at least nucleotides 2 to 36,518 of the sequence set forth in SEQ ID NO:1 The partially deleted E4 can comprise an E4 deletion of at least nucleotides 34,980 to 36,516 of the sequence shown in SEQ ID NO:1, and wherein the vector comprises at least nucleotides 2 to 36,518 of the sequence set forth in SEQ ID NO:1. The partially deleted E4 can comprise an E4 deletion of at least nucleotides 34,979 to 35,642 of the sequence shown in SEQ ID NO:1, and wherein the vector comprises at least nucleotides 2 to 36,518 of the sequence set forth in SEQ ID NO:1. The partially deleted E4 can comprise an E4 deletion of at least a partial deletion of E4Orf2, a fully deleted E4Orf3, and at least a partial deletion of E4Orf4. The partially deleted E4 can comprise an E4 deletion of at least a partial deletion of E4Orf2, at least a partial deletion of E4Orf3, and at least a partial deletion of E4Orf4. The partially deleted E4 can comprise an E4 deletion of at least a partial deletion of E4Orf1, a fully deleted E4Orf2, and at least a partial deletion of E4Orf3. The partially deleted E4 can comprise an E4 deletion of at least a partial deletion of E4Orf2 and at least a partial deletion of E4Orf3. The partially deleted E4 can comprise an E4 deletion between the start site of E4Orf1 to the start site of E4Orf5. The partially deleted E4 can be an E4 deletion adjacent to the start site of E4Orf1. The partially deleted E4 can be an E4 deletion adjacent to the start site of E4Orf2. The partially deleted E4 can be an E4 deletion adjacent to the start site of E4Orf3. The partially deleted E4 can be an E4 deletion adjacent to the start site of E4Orf4. The E4 deletion can be at least 50, at least 100, at least 200, at least 300, at least 400, at least 500, at least 600, at least 700, at least 800, at least 900, at least 1000, at least 1100, at least 1200, at least 1300, at least 1400, at least 1500, at least 1600, at least 1700, at least 1800, at least 1900, or at least 2000 nucleotides. The E4 deletion can be at least 700 nucleotides. The E4 deletion can be at least 1500 nucleotides. The E4 deletion can be 50 or less, 100 or less, 200 or less, 300 or less, 400 or less, 500 or less, 600 or less, 700 or less, 800 or less, 900 or less, 1000 or less, 1100 or less, 1200 or less, 1300 or less, 1400 or less, 1500 or less, 1600 or less, 1700 or less, 1800 or less, 1900 or less, or 2000 or less nucleotides. The E4 deletion can be 750 nucleotides or less. The E4 deletion can be at least 1550 nucleotides or less.

[0442] Also disclosed herein is a host cell transfected with a vector disclosed herein such as a C68 vector engineered to expression an antigen cassette. Also disclosed herein is a human cell that expresses a selected gene introduced therein through introduction of a vector disclosed herein into the cell.

[0443] Also disclosed herein is a method for delivering an antigen cassette to a mammalian cell comprising introducing into said cell an effective amount of a vector disclosed herein such as a C68 vector engineered to expression the antigen cassette.

[0444] Also disclosed herein is a method for producing an antigen comprising introducing a vector disclosed herein into a mammalian cell, culturing the cell under suitable conditions and producing the antigen.

[0445] V.D.2. E1-Expressing Complementation Cell Lines

[0446] To generate recombinant chimpanzee adenoviruses (Ad) deleted in any of the genes described herein, the function of the deleted gene region, if essential to the replication and infectivity of the virus, can be supplied to the recombinant virus by a helper virus or cell line, i.e., a complementation or packaging cell line. For example, to generate a replication-defective chimpanzee adenovirus vector, a cell line can be used which expresses the E1 gene products of the human or chimpanzee adenovirus; such a cell line can include HEK293 or variants thereof. The protocol for the generation of the cell lines expressing the chimpanzee E1 gene products (Examples 3 and 4 of U.S. Pat. No. 6,083,716) can be followed to generate a cell line which expresses any selected chimpanzee adenovirus gene.

[0447] An AAV augmentation assay can be used to identify a chimpanzee adenovirus E1-expressing cell line. This assay is useful to identify E1 function in cell lines made by using the E1 genes of other uncharacterized adenoviruses, e.g., from other species. That assay is described in Example 4B of U.S. Pat. No. 6,083,716.

[0448] A selected chimpanzee adenovirus gene, e.g., E1, can be under the transcriptional control of a promoter for expression in a selected parent cell line. Inducible or constitutive promoters can be employed for this purpose. Among inducible promoters are included the sheep metallothionine promoter, inducible by zinc, or the mouse mammary tumor virus (MMTV) promoter, inducible by a glucocorticoid, particularly, dexamethasone. Other inducible promoters, such as those identified in International patent application WO95/13392, incorporated by reference herein can also be used in the production of packaging cell lines. Constitutive promoters in control of the expression of the chimpanzee adenovirus gene can be employed also.

[0449] A parent cell can be selected for the generation of a novel cell line expressing any desired C68 gene. Without limitation, such a parent cell line can be HeLa [ATCC Accession No. CCL 2], A549 [ATCC Accession No. CCL 185], KB [CCL 17], Detroit [e.g., Detroit 510, CCL 72] and WI-38 [CCL 75] cells. Other suitable parent cell lines can be obtained from other sources. Parent cell lines can include CHO, HEK293 or variants thereof, 911, HeLa, A549, LP-293, PER.C6, or AE1-2a.

[0450] An E1-expressing cell line can be useful in the generation of recombinant chimpanzee adenovirus E1 deleted vectors. Cell lines constructed using essentially the same procedures that express one or more other chimpanzee adenoviral gene products are useful in the generation of recombinant chimpanzee adenovirus vectors deleted in the genes that encode those products. Further, cell lines which express other human Ad E1 gene products are also useful in generating chimpanzee recombinant Ads.

[0451] V.D.3. Recombinant Viral Particles as Vectors

[0452] The compositions disclosed herein can comprise viral vectors, that deliver at least one antigen to cells. Such vectors comprise a chimpanzee adenovirus DNA sequence such as C68 and an antigen cassette operatively linked to regulatory sequences which direct expression of the cassette. The C68 vector is capable of expressing the cassette in an infected mammalian cell. The C68 vector can be functionally deleted in one or more viral genes. An antigen cassette comprises at least one antigen under the control of one or more regulatory sequences such as a promoter. Optional helper viruses and/or packaging cell lines can supply to the chimpanzee viral vector any necessary products of deleted adenoviral genes.

[0453] The term “functionally deleted” means that a sufficient amount of the gene region is removed or otherwise altered, e.g., by mutation or modification, so that the gene region is no longer capable of producing one or more functional products of gene expression. Mutations or modifications that can result in functional deletions include, but are not limited to, nonsense mutations such as introduction of premature stop codons and removal of canonical and non-canonical start codons, mutations that alter mRNA splicing or other transcriptional processing, or combinations thereof. If desired, the entire gene region can be removed.

[0454] Modifications of the nucleic acid sequences forming the vectors disclosed herein, including sequence deletions, insertions, and other mutations may be generated using standard molecular biological techniques and are within the scope of this invention.

[0455] V.D.4. Construction of the Viral Plasmid Vector

[0456] The chimpanzee adenovirus C68 vectors useful in this invention include recombinant, defective adenoviruses, that is, chimpanzee adenovirus sequences functionally deleted in the Ela or E1b genes, and optionally bearing other mutations, e.g., temperature-sensitive mutations or deletions in other genes. It is anticipated that these chimpanzee sequences are also useful in forming hybrid vectors from other adenovirus and/or adeno-associated virus sequences. Homologous adenovirus vectors prepared from human adenoviruses are described in the published literature [see, for example, Kozarsky I and II, cited above, and references cited therein, U.S. Pat. No. 5,240,846].

[0457] In the construction of useful chimpanzee adenovirus C68 vectors for delivery of an antigen cassette to a human (or other mammalian) cell, a range of adenovirus nucleic acid sequences can be employed in the vectors. A vector comprising minimal chimpanzee C68 adenovirus sequences can be used in conjunction with a helper virus to produce an infectious recombinant virus particle. The helper virus provides essential gene products required for viral infectivity and propagation of the minimal chimpanzee adenoviral vector. When only one or more selected deletions of chimpanzee adenovirus genes are made in an otherwise functional viral vector, the deleted gene products can be supplied in the viral vector production process by propagating the virus in a selected packaging cell line that provides the deleted gene functions in trans.

[0458] V.D.5. Recombinant Minimal Adenovirus

[0459] A minimal chimpanzee Ad C68 virus is a viral particle containing just the adenovirus cis-elements necessary for replication and virion encapsidation. That is, the vector contains the cis-acting 5′ and 3′ inverted terminal repeat (ITR) sequences of the adenoviruses (which function as origins of replication) and the native 5′ packaging/enhancer domains (that contain sequences necessary for packaging linear Ad genomes and enhancer elements for the E1 promoter). See, for example, the techniques described for preparation of a “minimal” human Ad vector in International Patent Application WO96/13597 and incorporated herein by reference.

[0460] V.D.6. Other Defective Adenoviruses

[0461] Recombinant, replication-deficient adenoviruses can also contain more than the minimal chimpanzee adenovirus sequences. These other Ad vectors can be characterized by deletions of various portions of gene regions of the virus, and infectious virus particles formed by the optional use of helper viruses and/or packaging cell lines.

[0462] As one example, suitable vectors may be formed by deleting all or a sufficient portion of the C68 adenoviral immediate early gene Ela and delayed early gene E1b, so as to eliminate their normal biological functions. Replication-defective E1-deleted viruses are capable of replicating and producing infectious virus when grown on a chimpanzee adenovirus-transformed, complementation cell line containing functional adenovirus E1a and E1b genes which provide the corresponding gene products in trans. Based on the homologies to known adenovirus sequences, it is anticipated that, as is true for the human recombinant E1-deleted adenoviruses of the art, the resulting recombinant chimpanzee adenovirus is capable of infecting many cell types and can express antigen(s), but cannot replicate in most cells that do not carry the chimpanzee E1 region DNA unless the cell is infected at a very high multiplicity of infection.

[0463] As another example, all or a portion of the C68 adenovirus delayed early gene E3 can be eliminated from the chimpanzee adenovirus sequence which forms a part of the recombinant virus.

[0464] Chimpanzee adenovirus C68 vectors can also be constructed having a deletion of the E4 gene. Still another vector can contain a deletion in the delayed early gene E2a.

[0465] Deletions can also be made in any of the late genes L1 through L5 of the chimpanzee C68 adenovirus genome. Similarly, deletions in the intermediate genes IX and IVa2 can be useful for some purposes. Other deletions may be made in the other structural or non-structural adenovirus genes.

[0466] The above discussed deletions can be used individually, i.e., an adenovirus sequence can contain deletions of E1 only. Alternatively, deletions of entire genes or portions thereof effective to destroy or reduce their biological activity can be used in any combination. For example, in one exemplary vector, the adenovirus C68 sequence can have deletions of the E1 genes and the E4 gene, or of the E1, E2a and E3 genes, or of the E1 and E3 genes, or of E1, E2a and E4 genes, with or without deletion of E3, and so on. As discussed above, such deletions can be used in combination with other mutations, such as temperature-sensitive mutations, to achieve a desired result.

[0467] The cassette comprising antigen(s) be inserted optionally into any deleted region of the chimpanzee C68 Ad virus. Alternatively, the cassette can be inserted into an existing gene region to disrupt the function of that region, if desired.

[0468] V.D.7. Helper Viruses

[0469] Depending upon the chimpanzee adenovirus gene content of the viral vectors employed to carry the antigen cassette, a helper adenovirus or non-replicating virus fragment can be used to provide sufficient chimpanzee adenovirus gene sequences to produce an infective recombinant viral particle containing the cassette.

[0470] Useful helper viruses contain selected adenovirus gene sequences not present in the adenovirus vector construct and/or not expressed by the packaging cell line in which the vector is transfected. A helper virus can be replication-defective and contain a variety of adenovirus genes in addition to the sequences described above. The helper virus can be used in combination with the E1-expressing cell lines described herein.

[0471] For C68, the “helper” virus can be a fragment formed by clipping the C terminal end of the C68 genome with SspI, which removes about 1300 bp from the left end of the virus. This clipped virus is then co-transfected into an E1-expressing cell line with the plasmid DNA, thereby forming the recombinant virus by homologous recombination with the C68 sequences in the plasmid.

[0472] Helper viruses can also be formed into poly-cation conjugates as described in Wu et al, J. Biol. Chem., 264:16985-16987 (1989); K. J. Fisher and J. M. Wilson, Biochem. J., 299:49 (Apr. 1, 1994). Helper virus can optionally contain a reporter gene. A number of such reporter genes are known to the art. The presence of a reporter gene on the helper virus which is different from the antigen cassette on the adenovirus vector allows both the Ad vector and the helper virus to be independently monitored. This second reporter is used to enable separation between the resulting recombinant virus and the helper virus upon purification.

[0473] V.D.8. Assembly of Viral Particle and Infection of a Cell Line

[0474] Assembly of the selected DNA sequences of the adenovirus, the antigen cassette, and other vector elements into various intermediate plasmids and shuttle vectors, and the use of the plasmids and vectors to produce a recombinant viral particle can all be achieved using conventional techniques. Such techniques include conventional cloning techniques of cDNA, in vitro recombination techniques (e.g., Gibson assembly), use of overlapping oligonucleotide sequences of the adenovirus genomes, polymerase chain reaction, and any suitable method which provides the desired nucleotide sequence. Standard transfection and co-transfection techniques are employed, e.g., CaPO4 precipitation techniques or liposome-mediated transfection methods such as lipofectamine. Other conventional methods employed include homologous recombination of the viral genomes, plaquing of viruses in agar overlay, methods of measuring signal generation, and the like.

[0475] For example, following the construction and assembly of the desired antigen cassette-containing viral vector, the vector can be transfected in vitro in the presence of a helper virus into the packaging cell line. Homologous recombination occurs between the helper and the vector sequences, which permits the adenovirus-antigen sequences in the vector to be replicated and packaged into virion capsids, resulting in the recombinant viral vector particles.

[0476] The resulting recombinant chimpanzee C68 adenoviruses are useful in transferring an antigen cassette to a selected cell. In in vivo experiments with the recombinant virus grown in the packaging cell lines, the E1-deleted recombinant chimpanzee adenovirus demonstrates utility in transferring a cassette to a non-chimpanzee, preferably a human, cell.

[0477] V.D.9. Use of the Recombinant Virus Vectors

[0478] The resulting recombinant chimpanzee C68 adenovirus containing the antigen cassette (produced by cooperation of the adenovirus vector and helper virus or adenoviral vector and packaging cell line, as described above) thus provides an efficient gene transfer vehicle which can deliver antigen(s) to a subject in vivo or ex vivo.

[0479] The above-described recombinant vectors are administered to humans according to published methods for gene therapy. A chimpanzee viral vector bearing an antigen cassette can be administered to a patient, preferably suspended in a biologically compatible solution or pharmaceutically acceptable delivery vehicle. A suitable vehicle includes sterile saline. Other aqueous and non-aqueous isotonic sterile injection solutions and aqueous and non-aqueous sterile suspensions known to be pharmaceutically acceptable carriers and well known to those of skill in the art may be employed for this purpose.

[0480] The chimpanzee adenoviral vectors are administered in sufficient amounts to transduce the human cells and to provide sufficient levels of antigen transfer and expression to provide a therapeutic benefit without undue adverse or with medically acceptable physiological effects, which can be determined by those skilled in the medical arts. Conventional and pharmaceutically acceptable routes of administration include, but are not limited to, direct delivery to the liver, intranasal, intravenous, intramuscular, subcutaneous, intradermal, oral and other parental routes of administration. Routes of administration may be combined, if desired.

[0481] Dosages of the viral vector will depend primarily on factors such as the condition being treated, the age, weight and health of the patient, and may thus vary among patients. The dosage will be adjusted to balance the therapeutic benefit against any side effects and such dosages may vary depending upon the therapeutic application for which the recombinant vector is employed. The levels of expression of antigen(s) can be monitored to determine the frequency of dosage administration.

[0482] Recombinant, replication defective adenoviruses can be administered in a “pharmaceutically effective amount”, that is, an amount of recombinant adenovirus that is effective in a route of administration to transfect the desired cells and provide sufficient levels of expression of the selected gene to provide a vaccinal benefit, i.e., some measurable level of protective immunity. C68 vectors comprising an antigen cassette can be co-administered with adjuvant. Adjuvant can be separate from the vector (e.g., alum) or encoded within the vector, in particular if the adjuvant is a protein. Adjuvants are well known in the art.

[0483] Conventional and pharmaceutically acceptable routes of administration include, but are not limited to, intranasal, intramuscular, intratracheal, subcutaneous, intradermal, rectal, oral and other parental routes of administration. Routes of administration may be combined, if desired, or adjusted depending upon the immunogen or the disease. For example, in prophylaxis of rabies, the subcutaneous, intratracheal and intranasal routes are preferred. The route of administration primarily will depend on the nature of the disease being treated.

[0484] The levels of immunity to antigen(s) can be monitored to determine the need, if any, for boosters. Following an assessment of antibody titers in the serum, for example, optional booster immunizations may be desired

VI. Therapeutic and Manufacturing Methods

[0485] Also provided is a method of inducing an infectious disease organism-specific (e.g. a SARS-CoV-2 specific) immune response in a subject, vaccinating against an infectious disease organism, treating and/or alleviating a symptom of an infection associated with an infectious disease organism in a subject by administering to the subject one or more antigens such as a plurality of antigens identified using methods disclosed herein.

[0486] In some aspects, a subject has been diagnosed with an infection or is at risk of an infection (e.g. Covid-19 due to a SARS-CoV-2 infection), such as age, geographical/travel, and/or work-related increased risk of or predisposition to an infection, or at risk to a seasonal and/or novel disease infection.

[0487] An antigen can be administered in an amount sufficient to stimulate a CTL response. An antigen can be administered in an amount sufficient to stimulate a T cell response. An antigen can be administered in an amount sufficient to stimulate a B cell response.

[0488] An antigen can be administered alone or in combination with other therapeutic agents. Therapeutic agents can include those that target an infectious disease organism, such as an anti-viral or antibiotic agent.

[0489] The optimum amount of each antigen to be included in a vaccine composition and the optimum dosing regimen can be determined. For example, an antigen or its variant can be prepared for intravenous (i.v.) injection, sub-cutaneous (s.c.) injection, intradermal (i.d.) injection, intraperitoneal (i.p.) injection, intramuscular (i.m.) injection. Methods of injection include s.c., i.d., i.p., i.m., and i.v. Methods of DNA or RNA injection include i.d., i.m., s.c., i.p. and i.v. Other methods of administration of the vaccine composition are known to those skilled in the art.

[0490] A vaccine can be compiled so that the selection, number and/or amount of antigens present in the composition is/are tissue, infectious disease, and/or patient-specific. For instance, the exact selection of peptides can be guided by expression patterns of the parent proteins in a given tissue or guided by mutation or disease status of a patient. The selection can be dependent on the specific infectious disease (e.g. the specific SARS-CoV-2 isolate the subject is infected with or at risk for infection by), the status of the disease, the goal of the vaccination (e.g., preventative or targeting an ongoing disease), earlier treatment regimens, the immune status of the patient, and, of course, the HLA-haplotype of the patient. Furthermore, a vaccine can contain individualized components, according to personal needs of the particular patient. Examples include varying the selection of antigens according to the expression of the antigen in the particular patient or adjustments for secondary treatments following a first round or scheme of treatment.

[0491] A patient can be identified for administration of an antigen vaccine through the use of various diagnostic methods, e.g., patient selection methods described further below. Patient selection can involve identifying mutations in, or expression patterns of, one or more genes. Patient selection can involve identifying the infectious disease of an ongoing infection (e.g. the presence of a SARS-CoV-2 infection and/or the specific SARS-CoV-2 isolate). Patient selection can involve identifying risk of an infection by an infectious disease. In some cases, patient selection involves identifying the haplotype of the patient. The various patient selection methods can be performed in parallel, e.g., a sequencing diagnostic can identify both the mutations and the haplotype of a patient. The various patient selection methods can be performed sequentially, e.g., one diagnostic test identifies the mutations and separate diagnostic test identifies the haplotype of a patient, and where each test can be the same (e.g., both high-throughput sequencing) or different (e.g., one high-throughput sequencing and the other Sanger sequencing) diagnostic methods.

[0492] For a composition to be used as a vaccine for an infectious disease, antigens with similar normal self-peptides that are expressed in high amounts in normal tissues can be avoided or be present in low amounts in a composition described herein. On the other hand, if it is known that the infected cell of a patient expresses high amounts of a certain antigen, the respective pharmaceutical composition for treatment of this infection can be present in high amounts and/or more than one antigen specific for this particularly antigen or pathway of this antigen can be included.

[0493] Compositions comprising an antigen can be administered to an individual already suffering from an infection. In therapeutic applications, compositions are administered to a patient in an amount sufficient to stimulate an effective CTL response to the infectious disease organism antigen and to cure or at least partially arrest symptoms and/or complications. An amount adequate to accomplish this is defined as “therapeutically effective dose.” Amounts effective for this use will depend on, e.g., the composition, the manner of administration, the stage and severity of the disease being treated, the weight and general state of health of the patient, and the judgment of the prescribing physician. It should be kept in mind that compositions can generally be employed in serious disease states, that is, life-threatening or potentially life threatening situations, especially when the infectious disease organism has induced organ damage and/or other immune pathology. In such cases, in view of the minimization of extraneous substances and the relative nontoxic nature of an antigen, it is possible and can be felt desirable by the treating physician to administer substantial excesses of these compositions.

[0494] For therapeutic use, administration can begin at the detection or treatment of an infection. This can be followed by boosting doses until at least symptoms are substantially abated and for a period thereafter.

[0495] The pharmaceutical compositions (e.g., vaccine compositions) for therapeutic treatment are intended for parenteral, topical, nasal, oral or local administration. A pharmaceutical compositions can be administered parenterally, e.g., intravenously, subcutaneously, intradermally, or intramuscularly. The compositions can be administered to target specific infected tissues and/or cells of a subject. Disclosed herein are compositions for parenteral administration which comprise a solution of the antigen and vaccine compositions are dissolved or suspended in an acceptable carrier, e.g., an aqueous carrier. A variety of aqueous carriers can be used, e.g., water, buffered water, 0.9% saline, 0.3% glycine, hyaluronic acid and the like. These compositions can be sterilized by conventional, well known sterilization techniques, or can be sterile filtered. The resulting aqueous solutions can be packaged for use as is, or lyophilized, the lyophilized preparation being combined with a sterile solution prior to administration. The compositions may contain pharmaceutically acceptable auxiliary substances as required to approximate physiological conditions, such as pH adjusting and buffering agents, tonicity adjusting agents, wetting agents and the like, for example, sodium acetate, sodium lactate, sodium chloride, potassium chloride, calcium chloride, sorbitan monolaurate, triethanolamine oleate, etc.

[0496] Antigens can also be administered via liposomes, which target them to a particular cells tissue, such as lymphoid tissue. Liposomes are also useful in increasing half-life. Liposomes include emulsions, foams, micelles, insoluble monolayers, liquid crystals, phospholipid dispersions, lamellar layers and the like. In these preparations the antigen to be delivered is incorporated as part of a liposome, alone or in conjunction with a molecule which binds to, e.g., a receptor prevalent among lymphoid cells, such as monoclonal antibodies which bind to the CD45 antigen, or with other therapeutic or immunogenic compositions. Thus, liposomes filled with a desired antigen can be directed to the site of lymphoid cells, where the liposomes then deliver the selected therapeutic/immunogenic compositions. Liposomes can be formed from standard vesicle-forming lipids, which generally include neutral and negatively charged phospholipids and a sterol, such as cholesterol. The selection of lipids is generally guided by consideration of, e.g., liposome size, acid lability and stability of the liposomes in the blood stream. A variety of methods are available for preparing liposomes, as described in, e.g., Szoka et al., Ann. Rev. Biophys. Bioeng. 9; 467 (1980), U.S. Pat. Nos. 4,235,871, 4,501,728, 4,501,728, 4,837,028, and 5,019,369.

[0497] For targeting to the immune cells, a ligand to be incorporated into the liposome can include, e.g., antibodies or fragments thereof specific for cell surface determinants of the desired immune system cells. A liposome suspension can be administered intravenously, locally, topically, etc. in a dose which varies according to, inter alia, the manner of administration, the peptide being delivered, and the stage of the disease being treated.

[0498] For therapeutic or immunization purposes, nucleic acids encoding a peptide and optionally one or more of the peptides described herein can also be administered to the patient. A number of methods are conveniently used to deliver the nucleic acids to the patient. For instance, the nucleic acid can be delivered directly, as “naked DNA”. This approach is described, for instance, in Wolff et al., Science 247: 1465-1468 (1990) as well as U.S. Pat. Nos. 5,580,859 and 5,589,466. The nucleic acids can also be administered using ballistic delivery as described, for instance, in U.S. Pat. No. 5,204,253. Particles comprised solely of DNA can be administered. Alternatively, DNA can be adhered to particles, such as gold particles. Approaches for delivering nucleic acid sequences can include viral vectors, mRNA vectors, and DNA vectors with or without electroporation.

[0499] The nucleic acids can also be delivered complexed to cationic compounds, such as cationic lipids. Lipid-mediated gene delivery methods are described, for instance, in 9618372WOAWO 96/18372; 9324640WOAWO 93/24640; Mannino & Gould-Fogerite, BioTechniques 6(7): 682-691 (1988); U.S. Pat. No. 5,279,833 Rose U.S. Pat. No. 5,279,833; 9106309WOAWO 91/06309; and Felgner et al., Proc. Natl. Acad. Sci. USA 84: 7413-7414 (1987).

[0500] Antigens can also be included in viral vector-based vaccine platforms, such as vaccinia, fowlpox, self-replicating alphavirus, marabavirus, adenovirus (See, e.g., Tatsis et al., Adenoviruses, Molecular Therapy (2004) 10, 616-629), or lentivirus, including but not limited to second, third or hybrid second/third generation lentivirus and recombinant lentivirus of any generation designed to target specific cell types or receptors (See, e.g., Hu et al., Immunization Delivered by Lentiviral Vectors for Cancer and Infectious Diseases, Immunol Rev. (2011) 239(1): 45-61, Sakuma et al., Lentiviral vectors: basic to translational, Biochem J. (2012) 443(3):603-18, Cooper et al., Rescue of splicing-mediated intron loss maximizes expression in lentiviral vectors containing the human ubiquitin C promoter, Nucl. Acids Res. (2015) 43 (1): 682-690, Zufferey et al., Self-Inactivating Lentivirus Vector for Safe and Efficient In Vivo Gene Delivery, J. Virol. (1998) 72 (12): 9873-9880). Dependent on the packaging capacity of the above mentioned viral vector-based vaccine platforms, this approach can deliver one or more nucleotide sequences that encode one or more antigen peptides. The sequences may be flanked by non-mutated sequences, may be separated by linkers or may be preceded with one or more sequences targeting a subcellular compartment (See, e.g., Gros et al., Prospective identification of neoantigen-specific lymphocytes in the peripheral blood of melanoma patients, Nat Med. (2016) 22 (4):433-8, Stronen et al., Targeting of cancer neoantigens with donor-derived T cell receptor repertoires, Science. (2016) 352 (6291):1337-41, Lu et al., Efficient identification of mutated cancer antigens recognized by T cells associated with durable tumor regressions, Clin Cancer Res. (2014) 20(13):3401-10). Upon introduction into a host, infected cells express the antigens, and thereby stimulate a host immune (e.g., CTL) response against the peptide(s). Vaccinia vectors and methods useful in immunization protocols are described in, e.g., U.S. Pat. No. 4,722,848. Another vector is BCG (Bacille Calmette Guerin). BCG vectors are described in Stover et al. (Nature 351:456-460 (1991)). A wide variety of other vaccine vectors useful for therapeutic administration or immunization of antigens, e.g., Salmonella typhi vectors, and the like will be apparent to those skilled in the art from the description herein.

[0501] A means of administering nucleic acids uses minigene constructs encoding one or multiple epitopes. To create a DNA sequence encoding the selected CTL epitopes (minigene) for expression in human cells, the amino acid sequences of the epitopes are reverse translated. A human codon usage table is used to guide the codon choice for each amino acid. These epitope-encoding DNA sequences are directly adjoined, creating a continuous polypeptide sequence. To optimize expression and/or immunogenicity, additional elements can be incorporated into the minigene design. Examples of amino acid sequence that could be reverse translated and included in the minigene sequence include: helper T lymphocyte, epitopes, a leader (signal) sequence, and an endoplasmic reticulum retention signal. In addition, MHC presentation of CTL epitopes can be improved by including synthetic (e.g. poly-alanine) or naturally-occurring flanking sequences adjacent to the CTL epitopes. The minigene sequence is converted to DNA by assembling oligonucleotides that encode the plus and minus strands of the minigene. Overlapping oligonucleotides (30-100 bases long) are synthesized, phosphorylated, purified and annealed under appropriate conditions using well known techniques. The ends of the oligonucleotides are joined using T4 DNA ligase. This synthetic minigene, encoding the CTL epitope polypeptide, can then cloned into a desired expression vector.

[0502] Purified plasmid DNA can be prepared for injection using a variety of formulations. The simplest of these is reconstitution of lyophilized DNA in sterile phosphate-buffer saline (PBS). A variety of methods have been described, and new techniques can become available. As noted above, nucleic acids are conveniently formulated with cationic lipids. In addition, glycolipids, fusogenic liposomes, peptides and compounds referred to collectively as protective, interactive, non-condensing (PINC) could also be complexed to purified plasmid DNA to influence variables such as stability, intramuscular dispersion, or trafficking to specific organs or cell types.

[0503] Also disclosed is a method of manufacturing a vaccine, comprising performing the steps of a method disclosed herein; and producing a vaccine comprising a plurality of antigens or a subset of the plurality of antigens.

[0504] Antigens disclosed herein can be manufactured using methods known in the art. For example, a method of producing an antigen or a vector (e.g., a vector including at least one sequence encoding one or more antigens) disclosed herein can include culturing a host cell under conditions suitable for expressing the antigen or vector wherein the host cell comprises at least one polynucleotide encoding the antigen or vector, and purifying the antigen or vector. Standard purification methods include chromatographic techniques, electrophoretic, immunological, precipitation, dialysis, filtration, concentration, and chromatofocusing techniques.

[0505] Host cells can include a Chinese Hamster Ovary (CHO) cell, NSO cell, yeast, or a HEK293 cell. Host cells can be transformed with one or more polynucleotides comprising at least one nucleic acid sequence that encodes an antigen or vector disclosed herein, optionally wherein the isolated polynucleotide further comprises a promoter sequence operably linked to the at least one nucleic acid sequence that encodes the antigen or vector. In certain embodiments the isolated polynucleotide can be cDNA.

VII. Antigen Use and Administration

[0506] A vaccination protocol can be used to dose a subject with one or more antigens. A priming vaccine and a boosting vaccine can be used to dose the subject.

[0507] Immune monitoring can be performed before, during, and/or after vaccine administration. Such monitoring can inform safety and efficacy, among other parameters.

[0508] To perform immune monitoring, PBMCs are commonly used. PBMCs can be isolated before prime vaccination, and after prime vaccination (e.g. 4 weeks and 8 weeks). PBMCs can be harvested just prior to boost vaccinations and after each boost vaccination (e.g. 4 weeks and 8 weeks).

[0509] T cell responses can be assessed as part of an immune monitoring protocol. For example, the ability of a vaccine composition described herein to stimulate an immune response can be monitored and/or assessed. As used herein, “stimulate an immune response” refers to any increase in a immune response, such as initiating an immune response (e.g., a priming vaccine stimulating the initiation of an immune response in a naïve subject) or enhancement of an immune response (e.g., a boosting vaccine stimulating the enhancement of an immune response in a subject having a pre-existing immune response to an antigen, such as a pre-existing immune response initiated by a priming vaccine). T cell responses can be measured using one or more methods known in the art such as ELISpot, intracellular cytokine staining, cytokine secretion and cell surface capture, T cell proliferation, MHC multimer staining, or by cytotoxicity assay. T cell responses to epitopes encoded in vaccines can be monitored from PBMCs by measuring induction of cytokines, such as IFN-gamma, using an ELISpot assay. Specific CD4 or CD8 T cell responses to epitopes encoded in vaccines can be monitored from PBMCs by measuring induction of cytokines captured intracellularly or extracellularly, such as IFN-gamma, using flow cytometry. Specific CD4 or CD8 T cell responses to epitopes encoded in the vaccines can be monitored from PBMCs by measuring T cell populations expressing T cell receptors specific for epitope/MHC class I complexes using MHC multimer staining. Specific CD4 or CD8 T cell responses to epitopes encoded in the vaccines can be monitored from PBMCs by measuring the ex vivo expansion of T cell populations following 3H-thymidine, bromodeoxyuridine and carboxyfluoresceine-diacetate-succinimidylester (CFSE) incorporation. The antigen recognition capacity and lytic activity of PBMC-derived T cells that are specific for epitopes encoded in vaccines can be assessed functionally by chromium release assay or alternative colorimetric cytotoxicity assays.

[0510] B cell responses can be measured using one or more methods known in the art such as assays used to determine B cell differentiation (e.g., differentiation into plasma cells), B cell or plasma cell proliferation, B cell or plasma cell activation (e.g., upregulation of costimulatory markers such as CD80 or CD86), antibody class switching, and/or antibody production (e.g., an ELISA).

VIII. Isolation and Detection of HLA Peptides

[0511] Isolation of HLA-peptide molecules was performed using classic immunoprecipitation (IP) methods after lysis and solubilization of the tissue sample (55-58). Examples and methods are described in more detail in international patent application publication WO/2018/208856, herein incorporated by reference, in its entirety, for all purposes.

IX. Presentation Model

[0512] Presentation models can be used to identify likelihoods of peptide presentation in patients. Various presentation models are known to those skilled in the art, for example the presentation models described in more detail in U.S. Pat. No. 10,055,540, US Application Pub. No. US20200010849A1 and US20110293637, and international patent application publications WO/2018/195357, WO/2018/208856, and WO2016187508, each herein incorporated by reference, in their entirety, for all purposes.

X. Training Module

[0513] Training modules can be used to construct one or more presentation models based on training data sets that generate likelihoods of whether peptide sequences will be presented by MHC alleles associated with the peptide sequences. Various training modules are known to those skilled in the art, for example the presentation models described in more detail in U.S. Pat. No. 10,055,540, US Application Pub. No. US20200010849A1, and international patent application publications WO/2018/195357 and WO/2018/208856, each herein incorporated by reference, in their entirety, for all purposes. A training module can construct a presentation model to predict presentation likelihoods of peptides on a per-allele basis. A training module can also construct a presentation model to predict presentation likelihoods of peptides in a multiple-allele setting where two or more MHC alleles are present.

XI. Prediction Module

[0514] A prediction module can be used to receive sequence data and select candidate antigens in the sequence data using a presentation model. Specifically, the sequence data may be DNA sequences, RNA sequences, and/or protein sequences extracted from infected cells patients or infectious disease organisms themselves (e.g., SARS-CoV-2). A prediction module may identify candidate antigens that are pathogen-derived peptides (e.g., SARS-CoV-2 derived), such as by comparing sequence data extracted from normal tissue cells of a patient with the sequence data extracted from infected cells of the patient to identify portions containing one or more infectious disease organism associated antigens. A prediction module may identify candidate antigens that are expressed in an infected cell or infected tissue in comparison to a normal cell or tissue by comparing sequence data extracted from normal tissue cells of a patient with the sequence data extracted from infected tissue cells of the patient to identify expressed candidate antigens (e.g., identifying expressed polynucleotides and/or polypeptides specific to an infectious disease).

[0515] A presentation module can apply one or more presentation model to processed peptide sequences to estimate presentation likelihoods of the peptide sequences. Specifically, the prediction module may select one or more candidate antigen peptide sequences that are likely to be presented on infected cell HLA molecules by applying presentation models to the candidate antigens. In one implementation, the presentation module selects candidate antigen sequences that have estimated presentation likelihoods above a predetermined threshold. In another implementation, the presentation model selects the N candidate antigen sequences that have the highest estimated presentation likelihoods (where N is generally the maximum number of epitopes that can be delivered in a vaccine). A vaccine including the selected candidate antigens for a given patient can be injected into the patient to stimulate immune responses.

[0516] XI.B. Cassette Design Module

[0517] XI.B.1 Overview

[0518] A cassette design module can be used to generate a vaccine cassette sequence based on selected candidate peptides for injection into a patient. For example, a cassette design module can be used to generate a sequence encoding concatenated epitope sequences, such as concatenated T cell epitopes. Various cassette design modules are known to those skilled in the art, for example the cassette design modules described in more detail in U.S. Pat. No. 10,055,540, US Application Pub. No. US20200010849A1, and international patent application publications WO/2018/195357 and WO/2018/208856, each herein incorporated by reference, in their entirety, for all purposes.

[0519] A set of therapeutic epitopes may be generated based on the selected peptides determined by a prediction module associated with presentation likelihoods above a predetermined threshold, where the presentation likelihoods are determined by the presentation models. However it is appreciated that in other embodiments, the set of therapeutic epitopes may be generated based on any one or more of a number of methods (alone or in combination), for example, based on binding affinity or predicted binding affinity to HLA class I or class II alleles of the patient, binding stability or predicted binding stability to HLA class I or class II alleles of the patient, random sampling, and the like.

[0520] Therapeutic epitopes may correspond to selected peptides themselves. Therapeutic epitopes may also include C- and/or N-terminal flanking sequences in addition to the selected peptides. N- and C-terminal flanking sequences can be the native N- and C-terminal flanking sequences of the therapeutic vaccine epitope in the context of its source protein. Therapeutic epitopes can represent a fixed-length epitope Therapeutic epitopes can represent a variable-length epitope, in which the length of the epitope can be varied depending on, for example, the length of the C- or N-flanking sequence. For example, the C-terminal flanking sequence and the N-terminal flanking sequence can each have varying lengths of 2-5 residues, resulting in 16 possible choices for the epitope.

[0521] A cassette design module can also generate cassette sequences by taking into account presentation of junction epitopes that span the junction between a pair of therapeutic epitopes in the cassette. Junction epitopes are novel non-self but irrelevant epitope sequences that arise in the cassette due to the process of concatenating therapeutic epitopes and linker sequences in the cassette. The novel sequences of junction epitopes are different from the therapeutic epitopes of the cassette themselves.

[0522] A cassette design module can generate a cassette sequence that reduces the likelihood that junction epitopes are presented in the patient. Specifically, when the cassette is injected into the patient, junction epitopes have the potential to be presented by HLA class I or HLA class II alleles of the patient, and stimulate a CD8 or CD4 T-cell response, respectively. Such reactions are often times undesirable because T-cells reactive to the junction epitopes have no therapeutic benefit, and may diminish the immune response to the selected therapeutic epitopes in the cassette by antigenic competition..sup.76

[0523] A cassette design module can iterate through one or more candidate cassettes, and determine a cassette sequence for which a presentation score of junction epitopes associated with that cassette sequence is below a numerical threshold. The junction epitope presentation score is a quantity associated with presentation likelihoods of the junction epitopes in the cassette, and a higher value of the junction epitope presentation score indicates a higher likelihood that junction epitopes of the cassette will be presented by HLA class I or HLA class II or both.

[0524] In one embodiment, a cassette design module may determine a cassette sequence associated with the lowest junction epitope presentation score among the candidate cassette sequences.

[0525] A cassette design module may iterate through one or more candidate cassette sequences, determine the junction epitope presentation score for the candidate cassettes, and identify an optimal cassette sequence associated with a junction epitope presentation score below the threshold.

[0526] A cassette design module may further check the one or more candidate cassette sequences to identify if any of the junction epitopes in the candidate cassette sequences are self-epitopes for a given patient for whom the vaccine is being designed. To accomplish this, the cassette design module checks the junction epitopes against a known database such as BLAST. In one embodiment, the cassette design module may be configured to design cassettes that avoid junction self-epitopes.

[0527] A cassette design module can perform a brute force approach and iterate through all or most possible candidate cassette sequences to select the sequence with the smallest junction epitope presentation score. However, the number of such candidate cassettes can be prohibitively large as the capacity of the vaccine increases. For example, for a vaccine capacity of 20 epitopes, the cassette design module has to iterate through ˜10.sup.18 possible candidate cassettes to determine the cassette with the lowest junction epitope presentation score. This determination may be computationally burdensome (in terms of computational processing resources required), and sometimes intractable, for the cassette design module to complete within a reasonable amount of time to generate the vaccine for the patient. Moreover, accounting for the possible junction epitopes for each candidate cassette can be even more burdensome. Thus, a cassette design module may select a cassette sequence based on ways of iterating through a number of candidate cassette sequences that are significantly smaller than the number of candidate cassette sequences for the brute force approach.

[0528] A cassette design module can generate a subset of randomly or at least pseudo-randomly generated candidate cassettes, and selects the candidate cassette associated with a junction epitope presentation score below a predetermined threshold as the cassette sequence. Additionally, the cassette design module may select the candidate cassette from the subset with the lowest junction epitope presentation score as the cassette sequence. For example, the cassette design module may generate a subset of ˜1 million candidate cassettes for a set of 20 selected epitopes, and select the candidate cassette with the smallest junction epitope presentation score. Although generating a subset of random cassette sequences and selecting a cassette sequence with a low junction epitope presentation score out of the subset may be sub-optimal relative to the brute force approach, it requires significantly less computational resources thereby making its implementation technically feasible. Further, performing the brute force method as opposed to this more efficient technique may only result in a minor or even negligible improvement in junction epitope presentation score, thus making it not worthwhile from a resource allocation perspective. A cassette design module can determine an improved cassette configuration by formulating the epitope sequence for the cassette as an asymmetric traveling salesman problem (TSP). Given a list of nodes and distances between each pair of nodes, the TSP determines a sequence of nodes associated with the shortest total distance to visit each node exactly once and return to the original node. For example, given cities A, B, and C with known distances between each other, the solution of the TSP generates a closed sequence of cities, for which the total distance traveled to visit each city exactly once is the smallest among possible routes. The asymmetric version of the TSP determines the optimal sequence of nodes when the distance between a pair of nodes are asymmetric. For example, the “distance” for traveling from node A to node B may be different from the “distance” for traveling from node B to node A. By solving for an improved optimal cassette using an asymmetric TSP, the cassette design module can find a cassette sequence that results in a reduced presentation score across the junctions between epitopes of the cassette. The solution of the asymmetric TSP indicates a sequence of therapeutic epitopes that correspond to the order in which the epitopes should be concatenated in a cassette to minimize the junction epitope presentation score across the junctions of the cassette. A cassette sequence determined through this approach can result in a sequence with significantly less presentation of junction epitopes while potentially requiring significantly less computational resources than the random sampling approach, especially when the number of generated candidate cassette sequences is large. Illustrative examples of different computational approaches and comparisons for optimizing cassette design are described in more detail in U.S. Pat. No. 10,055,540, US Application Pub. No. US20200010849A1, and international patent application publications WO/2018/195357 and WO/2018/208856, each herein incorporated by reference, in their entirety, for all purposes.

[0529] A cassette design module can also generate cassette sequences by taking into account additional protein sequences encoded in the vaccine. For example, a cassette design module used to generate a sequence encoding concatenated T cell epitopes can take into account T cell epitopes already encoded by additional protein sequences present in the vaccine (e.g., full-length protein sequences), such as by removing T cell epitopes already encoded by the additional protein sequences from the list of candidate sequences.

[0530] A cassette design module can also generate cassette sequences by taking into account the size of the sequences. Without wishing to be bound by theory, in general, increased cassette size can negatively impact vaccine aspects, such as vaccine production and/or vaccine efficacy. In one example, the cassette design module can take into account overlapping sequences, such as overlapping T cell epitope sequences. In general, a single sequence containing overlapping T cell epitope sequences (also referred to as a “frame”) is more efficient than separately linking individual T cell epitope sequences as it reduces the sequence size needed to encode the multiple peptides. Accordingly, in an illustrative example, a cassette design module used to generate a sequence encoding concatenated T cell epitopes can take into account the cost/benefit of extending a candidate T cell epitope to encode one or more additional T cell epitopes, such as determining the benefit gained in additional population coverage for an MHC presenting the additional T cell epitope versus the cost of increasing the size of the sequence.

[0531] A cassette design module can also generate cassette sequences by taking into account the magnitude of stimulation of an immune response generated by validated epitopes.

[0532] A cassette design module can also generate cassette sequences by taking into account presentation of encoded epitopes across a population, for example that at least one immunogenic epitope is presented by at least one HLA across a proportion of a population, for example by at least 85%, 90%, or 95% of a population (e.g., HLA-A, HLA-B and HLA-C genes over four major ethnic groups, namely European (EUR), African American (AFA), Asian and Pacific Islander (APA) and Hispanic (HIS)). As an illustrative non-limiting example, a cassette design module can also generate cassette sequences such that at least one HLA is present at least across 85%, 90%, or 95% of a population that presents at least one validated epitope or presents at least 4, 5, 6, or 7 predicted epitopes.

[0533] A cassette design module can also generate cassette sequences by taking into account other aspects that improve potential safety, such as limiting encoding or the potential to encode a functional protein, functional protein domain, functional protein subunit, or functional protein fragment potentially presenting a safety risk. In some cases, a cassette design module can limit sequence size of encoded peptides such that are less than 50%, less than 49%, less than 48%, less than 47%, less than 46%, less than 45%, less than 45%, less than 43%, less than 42%, less than 41%, less than 40%, less than 39%, less than 38%, less than 37%, less than 36%, less than 35%, less than 34%, or less than 33% of the translated, corresponding full-length protein. In some cases, a cassette design module can limit sequence size of encoded peptides such that a single contiguous sequence is less than 50% of the translated, corresponding full-length protein, but more than one sequence may be derived from the same translated, corresponding full-length protein and together encode more than 50%. In an illustrative example, if a single sequence containing overlapping T cell epitope sequences (“frame”) is larger than 50% of the translated, corresponding full-length protein, the frame can be split into multiple frames (e.g., f1, f2 etc.) such that each frame is less than 50% of the translated, corresponding full-length protein. A cassette design module can also limit sequence size of encoded peptides such that a single contiguous sequence is less than 49%, less than 48%, less than 47%, less than 46%, less than 45%, less than 45%, less than 43%, less than 42%, less than 41%, less than 40%, less than 39%, less than 38%, less than 37%, less than 36%, less than 35%, less than 34%, or less than 33% of the translated, corresponding full-length protein. Where multiple frames from the same gene are encoded, the multiple frames can have overlapping sequences with each other, in other words each separately encode the same sequence. Where multiple frames from the same gene are encoded, the two or more nucleic acid sequences derived from the same gene can be ordered such that a first nucleic acid sequence cannot be immediately followed by or linked to a second nucleic acid sequence if the second nucleic acid sequence follows, immediately or not, the first nucleic acid sequence in the corresponding gene. For example, if there are 3 frames within the same gene (f1,f2,f3 in increasing order of amino acid position): [0534] The following cassette orderings are not allowed: [0535] f1 immediately followed by f2 [0536] f2 immediately followed by f3 [0537] f1 immediately followed by f3 [0538] The following cassette orderings are allowed: [0539] f3 immediately followed by f2 [0540] f2 immediately followed by f1

XIII. Example Computer

[0541] A computer can be used for any of the computational methods described herein. One skilled in the art will recognize a computer can have different architectures. Examples of computers are known to those skilled in the art, for example the computers described in more detail in U.S. Pat. No. 10,055,540, US Application Pub. No. US20200010849A1, and international patent application publications WO/2018/195357 and WO/2018/208856, each herein incorporated by reference, in their entirety, for all purposes.

XIV. Examples

[0542] Below are examples of specific embodiments for carrying out the present invention. The examples are offered for illustrative purposes only, and are not intended to limit the scope of the present invention in any way. Efforts have been made to ensure accuracy with respect to numbers used (e.g., amounts, temperatures, etc.), but some experimental error and deviation should, of course, be allowed for.

[0543] The practice of the present invention will employ, unless otherwise indicated, conventional methods of protein chemistry, biochemistry, recombinant DNA techniques and pharmacology, within the skill of the art. Such techniques are explained fully in the literature. See, e.g., T. E. Creighton, Proteins: Structures and Molecular Properties (W.H. Freeman and Company, 1993); A. L. Lehninger, Biochemistry (Worth Publishers, Inc., current addition); Sambrook, et al., Molecular Cloning: A Laboratory Manual (2nd Edition, 1989); Methods In Enzymology (S. Colowick and N. Kaplan eds., Academic Press, Inc.); Remington's Pharmaceutical Sciences, 18th Edition (Easton, Pennsylvania: Mack Publishing Company, 1990); Carey and Sundberg Advanced Organic Chemistry 3.sup.rd Ed. (Plenum Press) Vols A and B(1992).

[0544] XIV.A. SARS-CoV-2 MHC Epitope Prediction and Vaccine Cassette Construction

[0545] The SARS-CoV-2 belongs to the coronavirus family and its reference genome is a single-stranded RNA sequence of 29,903 base pairs. The genome contains at least 14 open reading frames (ORF) as shown in FIG. 1. Among the encoded genes, the essential genes are replicase ORF1ab, spike (S), envelope (E), membrane (M) and nucleocapsid (N). The replicase ORF1ab (position 266-21555) encode two proteins namely orf1a and orf1b, the latter is translated by a ribosomal frameshift by −1 at position 13468. The two proteins together contain 16 non-structure proteins (nsp1-nsp16), as depicted in FIG. 2, that is, the ORF1a and ORF1b are cleaved into 16 nsps. The spike protein is thought to bind to the ACE2 receptor of the human cell, allowing the virus to enter the human cell to use its replication machinery to produce and disseminate more copies of the virus.

[0546] Because RNA viruses are known to have high mutation rates, a large number of SARS-CoV-2 genomes were analyzed to identify regions in the proteome that are variable. Over 8000 SARS-CoV-2 complete genomes deposited into the GISAID database [www.gisaid.org] as of Apr. 19, 2020 were obtained. Pairwise global alignment of each of the genomes to the SARS-CoV-2 reference genome (Genbank Accession number NC_045512; SEQ ID NO:76) was performed. Sequences on these genomes that are aligned to coding regions of the reference genome were specifically located the. These sequences were then translated to obtain the protein sequences of these SARS-CoV-2. These protein sequences wee then aligned to the respective reference protein sequences to identify variants.

[0547] The analysis identified 20 sites on the protein sequences that have a variant rate greater than 1%. These sites are shown in Table 1. In selecting T-cell epitopes, candidate epitopes that cross these variable sites were excluded.

[0548] CD8+ epitopes were predicted using our machine learning EDGE platform (see U.S. Pat. No. 10,055,540, herein incorporated by reference for all purposes), which was shown to be best-in-class [Bulik-Sullivan et al. (2018). Deep learning using tumor HLA peptide mass spectrometry datasets improves neoantigen identification. Nature Biotechnology 2018, 37(1), herein incorporated by reference for all purposes]. The model for predicting class I epitopes was recently trained on 507,502 peptides presented in Mass Spectrometry across 398 samples and covers 116 identified alleles, of which 112 alleles (Table 2, FIG. 7) are represented in the haplotype distribution dataset described below.

[0549] In order to generate a list of candidate CD8+ T-cell epitopes, the orf1ab protein was split at the cleavage sites shown in FIG. 2. Studies show that the spike protein harbors a furin-like cleavage motif at position 681-684, where the cleavage event occurs following position 684 [Wrapp et al. (2020). Cryo-EM structure of the 2019-nCoV spike in the prefusion conformation. Science, 367(6483), 1260-1263, Ou et al. (2020). Characterization of spike glycoprotein of SARS-CoV-2 on virus entry and its immune cross-reactivity with SARS-CoV. Nature Communications, 11(1), 1620]. The cleavage of the spike protein into S1 and S2 is thought to facilitate the cell entry contributing to the transmissibility of the virus. Accordingly, the Spike protein was split at the furin cleavage site for generating candidate CD8+ T-cell epitopes. All 8-11mer peptides were then generated from the cleaved proteins and the other proteins, flanked by their native N-terminal and C-terminal 5-mers.

[0550] The EDGE machine learning model was run on these candidate epitopes for each HLA class I allele. That is, the presentation score of a candidate epitope is given an EDGE score for each HLA allele. Generally, the probability of a peptide being presented is influenced by the family of the protein containing the peptide, and the expression level of the protein. The EDGE model was also trained on human peptidome datasets. Given there is no equivalent protein family for SARS-CoV-2, for predicting the presentation of a given Sar-CoV-2 peptide, a random protein family was assigned to all peptides. Assigning the same protein family, albeit random, will have the same effect on all SARS-CoV-2 peptides. A high level of expression was also used (tpm=10). A list of candidate epitopes with the EDGE score of 0.001 and above for an HLA allele are shown in Table A, as well as cognate HLA alleles with a predicted EDGE score greater than 0.001, with each cognate pairing ranked as H (EDGE score>0.1), M (EDGE score between 0.01 and 0.1), and L (EDGE score<0.01).

[0551] In order to account for the different levels of expression of SARS-CoV-2 genes, the ratio of reported T-cell responses among genes from SARS-CoV-2 genome [Li et al. (2008) T Cell Responses to Whole SARS Coronavirus in Humans. The Journal of Immunology, 181(8), 5490-5500] was used as a proxy for the ratio of gene expression levels. The score of all epitopes from a SARS-CoV-2 gene was then scaled so that the ratio between the 99.sup.th percentile of the epitopes in the selected gene and the 99.sup.th percentile of the epitopes in the Spike gene followed the ratio reported in [Li et al. (2008). T Cell Responses to Whole SARS Coronavirus in Humans. The Journal of Immunology, 181(8), 5490-5500].

[0552] A set of candidate CD8+ epitopes was then selected by choosing those with the scaled EDGE score greater than or equal to a threshold of t=0.01. The threshold was selected from analysis of an HIV LANL dataset (data not shown) so that PPV for T-cell epitopes estimated to be 0.2 and recall is 0.5. The set sequences that are >=90% homologous to known SARs-Cov T-cell epitopes reported in IEDB [Vita et al. (2019). The Immune Epitope Database (IEDB): 2018 update. Nucleic Acids Research, 47(D1), D339-D343.] was also included similar to the approach described in Grifoni et al. [(2020). A Sequence Homology and Bioinformatic Approach Can Predict Candidate Targets for Immune Responses to SARS-CoV-2. Cell Host & Microbe, 27(4), 671-680.e2].

[0553] The set of candidate epitopes excluded those sequences that contained at least one of the sites that have a variable rate greater than 0.01, as mentioned above and shown in Table 1.

[0554] In order to maximize the coverage of the vaccine over the world population, allele frequencies of HLA-A, HLA-B and HLA-C genes over four major ethnic groups, namely European (EUR), African American (AFA), Asian and Pacific Islander (APA) and Hispanic (HIS) were obtained from the publicly available National Marrow Donor Program dataset [www.bioinformatics.bethematchclinical.org/hla-resources/haplotype-frequencies/high-resolution-hla-alleles-and-haplotypes-in-the-us-population]. Simulations were then performed to estimate the frequencies of the haplotypes made up by combination of these HLA alleles.

[0555] Cassette optimization proceeded as follows:

Epitope Selection Definitions

[0556] Candidate epitope set E: set of candidate CD8+ epitopes with scaled EDGE score greater than or equal to a threshold of t=0.01 [0557] Population coverage criteria P: For each of the four ethnicity groups as described above (EUR/AFA/APA/HIS), 95% of the simulated people in that ethnic group have at least 30 candidate epitopes presented in their diplotype [0558] Solution frame set F—all amino acid ranges in the current solution encapsulating the added candidate epitopes [0559] For each epitope added to the solution, the epitope and 5 flanking native amino acids on each end must be fully contained in a frame of F [0560] Each frame spans only protein region (including individual NSPs in orf1ab)

Epitope Selection Method

[0561] Population coverage criteria P starts as calculated with all epitopes in the whole gene(s) initially added [0562] If the population coverage criteria P is not satisfied, continually choose the amino acid frame f across SARS-CoV-2 proteome that most efficiently maximizes progress to P [0563] Defined as the highest ratio of additional population coverage C/additional amino acid bases added AA. (C/AA). [0564] All candidate frames are either a new 25aa frame (AA=25), or can overlap with frames in the existing solution F—in which case it can add any amount less than 25aa (AA<25) [0565] Additional population coverage C is the increase in epitope count from E for haplotypes with <20 covered epitopes, weighted(multiplied) by the haplotype's population frequency summed across all four ethnic groups [0566] 20 epitopes per haplotype is determined (experimentally chosen) to be an efficient proxy towards reaching the overall coverage criteria of 30 candidate epitopes per diplotype [0567] Add f to solution frame set F. Remove from E, candidate epitopes within f. [0568] After frames are chosen, create the final set F: [0569] First merge overlapping frames, yielding contiguous sequences (i.e. epitope “hotspots”) [0570] Next ensure all frames are less than 50% of that frame's overall gene size. If frames are larger than this size, divide them into smaller (potentially overlapping) frames that are each smaller than this requirement. Additional more stringent size limitations can be tested [0571] To illustrates the marginal value of larger cassette sizes, frame selection can continue past when P is satisfied—but does not affect the composition of the chosen cassette for the criteria P.

Cassette Ordering

[0572] The frames in solution frame set F are ordered to minimize the EDGE score of junction epitopes (unintended epitopes not part of the solution, created by adjacent frames). Successive frames within a gene are also forbidden to immediately follow each other in the cassette (intra-gene restriction). In other words, intra-gene restriction requires that if there are two or more SARS-CoV-2 derived nucleic acid sequences encoding epitopes derived from the same SARS-CoV-2 gene, the two sequences are ordered such that a first nucleic acid sequence cannot be immediately followed by or linked to a second nucleic acid sequence if the second nucleic acid sequence follows first nucleic acid sequence in the corresponding SARS-CoV-2 gene. For example, if there are 3 frames within the same gene (f1,f2,f3 in increasing order of amino acid position) [0573] The following cassette orderings are impossible: [0574] f1 immediately followed by f2 [0575] f2 immediately followed by f3 [0576] f1 immediately followed by f3 [0577] The following cassette orderings are possible: [0578] f3 immediately followed by f2 [0579] f2 immediately followed by f1

Cassette Ordering Method

[0580] Google optimization routing tools [www.developers.google.com/optimization/routing] are used to perform a traveling salesman optimization route, where the distance between each pair of frames in F is: [0581] Infinite, if the frames are not allowed to follow each other in this order, according to the above intra-gene restriction [0582] Otherwise the sum of junction epitope EDGE scores across all alleles, weighted by allele frequency in population

[0583] Route finding of the minimal path distance yields the optimal ordering of the frames in the cassette to minimize junctional epitopes and avoid successive frames within a gene.

Results

[0584] The population coverage criteria P was calculated with all initial epitopes provided by the SARS-CoV-2 Spike protein (SEQ ID NO:59) split into S1 and S2. Applying the optimization algorithms above yielded a 594 amino acid cassette sequence having 18 epitope-encoding frames, as shown in Table 3A. Table C presents each of the additional epitopes contained in the cassette (not including the epitopes derived from the Spike protein). Empirically, the optimal frame set F was produced when the size threshold for all frames was set to less than 42% of that frame's overall gene size. The coverage of the designed cassette over four populations is shown in FIG. 5, with the first column providing the number of SARS-CoV-2 epitopes predicted to be presented and the second column providing the expected number of presented epitopes, based on a 0.2 PPV. Each row shows the protection coverage of each population if a certain number of epitopes is used.

[0585] Potential HLA-DRB, HLA-DQ, and HLA-DP MHC class II epitopes from the SARS-CoV-2 proteome were also predicted. The method described for generating candidate CD8/MHC class I epitopes was used to generate peptides with sizes between 9 and 20 amino acids. EDGE model was run for class II to compute EDGE score of each of these peptides against each identifiable allele (see, e.g., U.S. application Ser. No. 16/606,577 and international patent application PCT/US2020/021508, each herein incorporated by reference in their entirety for all purposes). The list of CD4 epitopes with EDGE score greater than 0.001 are presented in Table B, as well as cognate HLA alleles with a predicted EDGE score greater than 0.001, with each cognate pairing ranked as H (EDGE score>0.1), M (EDGE score between 0.01 and 0.1), and L (EDGE score<0.01). HLA-DQ and HLA-DP are referred to by their alpha and beta chains used in the analysis, while HLA-DR is referred to by its beta chain as the alpha chain is generally invariable in the human population, with HLA-DR peptide contact regions particularly invariant.

[0586] The peptides receiving a score of >0.02 contained in the optimized MHC I cassette frames determined above were then identified. The threshold of 0.02 was chosen because the model prediction has the PPV of 0.2 in predicting Mass Spectrometry data with prevalence ratio positive vs negatives of 1:100. FIG. 6A illustrates the number of predicted epitopes presented by each MHC class II allele examined. FIG. 6B shows the population coverage of MHC class II at the diploid level.

[0587] Additional cassettes are designed using the epitope prediction and frame ordering algorithms described above where the initial population coverage criteria P is calculated with all initial epitopes provided by SARS-CoV-2 Membrane (SEQ ID NO:61), SARS-CoV-2 Nucleocapsid (SEQ ID NO:62), SARS-CoV-2 Envelope (SEQ ID NO:63), or combinations (including combinations with SARS-CoV-2 spike) or sequence variants thereof.

TABLE-US-00001 TABLE 1 Identified SARS-CoV-2 Mutations (>1%) Reference Alternate Variable Gene Position Amino Acid Amino Acid Rate orf1ab 265 T I 0.12474 orf1ab 378 V I 0.022349 orf1ab 392 G D 0.015073 orf1ab 448 D deletion 0.030146 orf1ab 739 I V 0.011435 orf1ab 765 P S 0.012474 orf1ab 876 A T 0.015073 orf1ab 3353 K R 0.023909 orf1ab 3606 L F 0.130977 orf1ab 4715 P L 0.448025 orf1ab 5828 P L 0.193867 orf1ab 5865 Y C 0.199584 S 614 D G 0.439815 ORF3a 57 Q H 0.150943 ORF3a 251 G V 0.086003 M 3 D G 0.013508 M 175 T M 0.051416 ORF8 84 L S 0.267563 N 203 R K 0.124507 N 204 G R 0.124068

TABLE-US-00002 TABLE 2 List of Identifiable Class I alleles HLA-A*01:01 HLA-A*25:01 HLA-A*68:01 HLA-B*15:13 HLA-B*40:06 HLA-B*55:02 HLA-C*07:02 HLA-A*02:01 HLA-A*26:01 HLA-A*68:02 HLA-B*18:01 HLA-B*41:02 HLA-B*56:01 HLA-C*07:04 HLA-A*02:02 HLA-A*26:02 HLA-A*74:01 HLA-B*27:02 HLA-B*42:01 HLA-B*57:01 HLA-C*07:27 HLA-A*02:03 HLA-A*26:03 HLA-B*07:02 HLA-B*27:05 HLA-B*44:02 HLA-B*57:03 HLA-C*08:01 HLA-A*02:04 HLA-A*29:01 HLA-B*07:04 HLA-B*35:01 HLA-B*44:03 HLA-B*58:01 HLA-C*08:02 HLA-A*02:05 HLA-A*29:02 HLA-B*07:05 HLA-B*35:02 HLA-B*44:05 HLA-B*58:02 HLA-C*08:03 HLA-A*02:06 HLA-A*30:01 HLA-B*08:01 HLA-B*35:03 HLA-B*45:01 HLA-C*01:02 HLA-C*12:02 HLA-A*02:07 HLA-A*30:02 HLA-B*13:01 HLA-B*35:08 HLA-B*46:01 HLA-C*02:02 HLA-C*12:03 HLA-A*02:11 HLA-A*31:01 HLA-B*13:02 HLA-B*35:12 HLA-B*48:01 HLA-C*03:02 HLA-C*12:05 HLA-A*03:01 HLA-A*32:01 HLA-B*14:01 HLA-B*37:01 HLA-B*49:01 HLA-C*03:03 HLA-C*14:02 HLA-A*03:02 HLA-A*33:01 HLA-B*14:02 HLA-B*38:01 HLA-B*50:01 HLA-C*03:04 HLA-C*14:03 HLA-A*11:01 HLA-A*33:03 HLA-B*15:01 HLA-B*38:02 HLA-B*51:01 HLA-C*04:01 HLA-C*15:02 HLA-A*11:02 HLA-A*34:01 HLA-B*15:02 HLA-B*39:01 HLA-B*52:01 HLA-C*04:03 HLA-C*15:05 HLA-A*23:01 HLA-A*34:02 HLA-B*15:03 HLA-B*39:06 HLA-B*53:01 HLA-C*05:01 HLA-C*16:01 HLA-A*24:02 HLA-A*36:01 HLA-B*15:10 HLA-B*40:01 HLA-B*54:01 HLA-C*06:02 HLA-C*16:04 HLA-A*24:07 HLA-A*66:01 HLA-B*15:11 HLA-B*40:02 HLA-B*55:01 HLA-C*07:01 HLA-C*17:01

TABLE-US-00003 TABLE 3A Cassette Epitope Frames in Conjunction with Spike Protein Amino Acid Frame Gene Gene Start Gene End Length 1 M 172 204 33 2 orf1ab 4154 4178 25 3 N 301 345 45 4 N 151 175 25 5 N 71 95 25 6 ORF3a 106 130 25 7 orf1ab 4419 4443 25 8 N 259 283 25 9 orf1ab 5371 5395 25 10 M 85 140 56 11 N 352 393 42 12 orf1ab 2580 2604 25 13 ORF3a 1 47 47 14 M 34 60 27 15 ORF3a 53 86 34 16 orf1ab 2794 2818 25 17 ORF3a 199 255 57 18 E 44 71 28

[0588] XIV.B. SARS-CoV-2 Vaccine Design

[0589] A series of vaccines against SARS-CoV-2 were designed to produce a balanced immune response inducing both neutralizing antibodies (from B cells) as well as effector and memory CD8+ T cell responses for maximum efficacy. In general, neutralizing antibodies to viral surface proteins can serve to prevent viral entry into cells and virus epitope-specific CD8+ T cells kill virally-infected cells. In addition, vaccines against SARS-CoV-2 were designed to maximize the coverage of the vaccine across the world population, i.e., target most individuals (e.g., >95%) receive a large number (e.g., >=30) of candidate CD8+ epitopes across all major ancestry groups while minimizing our cassette sequence footprint.

Antigens and Cassettes

[0590] Vaccines are constructed encoding the MHC epitope-encoding cassettes designed using the epitope prediction and frame ordering algorithms described above. An exemplary cassette (herein referred to as the Concatenated EDGE predicted SARS-CoV-2 MHC Class I Epitope Cassette or EDGE Predicted Epitopes (EPE)) was generated where the initial population coverage criteria P was calculated with all initial epitopes provided by SARS-CoV-2 Spike, as described above.

[0591] Vaccines are also designed encoding various full-length proteins, either alone or in combination, generally for the purposes of stimulating a B cell response. Full-length proteins include SARS-CoV-2 Spike (SEQ ID NO:59), SARS-CoV-2 Membrane (SEQ ID NO:61), SARS-CoV-2 Nucleocapsid (SEQ ID NO:62), and SARS-CoV-2 Envelope (SEQ ID NO:63), sequences of which are shown in Table 3B.

[0592] With respect to the Spike protein, initial analysis of prevalent SARS-CoV-2 variants (as described above, see Table 1) identified a Spike protein variant present in almost 44% of genomes. Subsequent analysis of the over 8000 SARS-CoV-2 complete genomes identified a dominant variant at position 614 where the wildtype amino acid aspartic (D) is mutated to glycine (G). The mutation, denotated as D614G, is found on 60.05% of genomes sequenced worldwide, and 70.46% and 58.49% of the sequences in Europe and North America, respectively (FIG. 4). Accordingly, Spike proteins are used that contain the prevalent D614G Spike variant, with reference to the reference Spike protein (SEQ ID NO:59). In addition, a modified Spike protein was engineered to bias the Spike protein to remain in a predominantly prefusion state, as the prefusion Spike state may be a better target for antibody-mediated neutralization of the virus. The following mutations were selected: R682V to disrupt the Furin cleavage site; R815N to disrupt cleavage site within S2, and K986P and V987P to interfere with the secondary structure of Spike. Accordingly, “modified” Spike proteins are used that contain one or more of the following mutations, with reference to the reference Spike protein (SEQ ID NO:59): a D614G mutation, a R682V mutation, a R815N mutation, a K986P mutation, or a V987P mutation. For reference, a modified Spike proving having all of the Spike mutations is shown in SEQ ID NO:60.

[0593] Various vaccine designs and their respective cassette nucleotide sequences are presented in more detail in Table 4. For SAM based vaccines, promoter and/or poly(A) signal sequences can be removed given cassettes are generally operably linked to the endogenous 26S promoter and poly(A) sequence provided by the vector backbone. Depending on the cassette features and configuration, translated proteins (e.g., those in Table 3B) may also include an additional sequence(s) related to the particular expression strategy, such as a 2A ribosome skipping sequence elements (or fragments thereof following translation) and additional 26S promoter sequences.

TABLE-US-00004 TABLE 3B SARS-COV-2 Proteins SEQ ID Peptide Amino Acid Sequence NO:  Concatenated TSRTLSYYKLGASQRVAGDSGFAAYSRYRIGNYCAAGTTQTACTDDN 57 EDGE predicted ALAYYNTTKGGWPQIAQFAPSASAFFGMSRIGMEVTPSGTWLTYTGA SARS-COV-2 IKLDDKDPNPANNAAIVLQLPQGTTLPKGFYAEGGVPINTNSSPDDQI MHC Class I GYYRRATRRIRLYLYALVYFLQSINFVRIIMRLWLCSTDVVYRAFDIY Epitope Cassette NDKVAGFAKFLKTRQKRTATKAYNVTQAFGRRGPEQTQPYVCNAPG CDVTDVTQLYLGGMSYYACLVGLMWLSYFIASFRLFARTRSMWSFN PETNILLNVPLHGTILTRPLLESELVILLNKHIDAYKTFPPTEPKKDKKK KADETQALPQRQKKQQTVTVGDSAEVAVKMFDAYVNTFSSTFNVM DLFMRIFTIGTVTLKQGEIKDATPSDFVRATATIPIQASLPFGWLILLQF AYANRNRFLYIIKLIFLWLLWPVLAVFQSASKIITLKKRWQLALSKGV HFVCNLLLLHVMSKHTDFSSEIIGYKAIDGGVTRDCVVLHSYFTSDYY QLYSTQLSTDTGVEHVTFFIYNKIVDEPEEHVQIHTIDGSSGVCNIVNV SLVKPSFYVYSRVKNLNSSRVP Concatenated MAGTSRTLSYYKLGASQRVAGDSGFAAYSRYRIGNYCAAGTTQTAC 58 EDGE predicted TDDNALAYYNTTKGGWPQIAQFAPSASAFFGMSRIGMEVTPSGTWLT SARS-COV-2 YTGAIKLDDKDPNPANNAAIVLQLPQGTTLPKGFYAEGGVPINTNSSP MHC Class I DDQIGYYRRATRRIRLYLYALVYFLQSINFVRIIMRLWLCSTDVVYRA Epitope Cassette FDIYNDKVAGFAKFLKTRQKRTATKAYNVTQAFGRRGPEQTQPYVC with N-term NAPGCDVTDVTQLYLGGMSYYACLVGLMWLSYFIASFRLFARTRSM leader (bold) and WSFNPETNILLNVPLHGTILTRPLLESELVILLNKHIDAYKTFPPTEPKK C-term DKKKKADETQALPQRQKKQQTVTVGDSAEVAVKMFDAYVNTFSSTF Universal MHC NVMDLFMRIFTIGTVTLKQGEIKDATPSDFVRATATIPIQASLPFGWLI Class II with LLQFAYANRNRFLYIIKLIFLWLLWPVLAVFQSASKIITLKKRWQLALS GPGPG linkers KGVHFVCNLLLLHVMSKHTDFSSEIIGYKAIDGGVTRDCVVLHSYFTS (SEQ ID NO:  DYYQLYSTQLSTDTGVEHVTFFIYNKIVDEPEEHVQIHTIDGSSGVCNI 56) (bold italic) VNVSLVKPSFYVYSRVKNLNSSRVP SARS-COV-2 MFVFLVLLPLVSSQCVNLTTRTQLPPAYTNSFTRGVYYPDKVFRSSVL 59 Spike HSTQDLFLPFFSNVTWFHAIHVSGTNGTKRFDNPVLPFNDGVYFASTE KSNIIRGWIFGTTLDSKTQSLLIVNNATNVVIKVCEFQFCNDPFLGVYY HKNNKSWMESEFRVYSSANNCTFEYVSQPFLMDLEGKQGNFKNLRE FVFKNIDGYFKIYSKHTPINLVRDLPQGFSALEPLVDLPIGINITRFQTLL ALHRSYLTPGDSSSGWTAGAAAYYVGYLQPRTFLLKYNENGTITDAV DCALDPLSETKCTLKSFTVEKGIYQTSNFRVQPTESIVRFPNITNLCPFG EVFNATRFASVYAWNRKRISNCVADYSVLYNSASFSTFKCYGVSPTK LNDLCFTNVYADSFVIRGDEVRQIAPGQTGKIADYNYKLPDDFTGCVI AWNSNNLDSKVGGNYNYLYRLFRKSNLKPFERDISTEIYQAGSTPCN GVEGFNCYFPLQSYGFQPTNGVGYQPYRVVVLSFELLHAPATVCGPK KSTNLVKNKCVNFNFNGLTGTGVLTESNKKFLPFQQFGRDIADTTDA VRDPQTLEILDITPCSFGGVSVITPGTNTSNQVAVLYQDVNCTEVPVAI HADQLTPTWRVYSTGSNVFQTRAGCLIGAEHVNNSYECDIPIGAGICA SYQTQTNSPRRARSVASQSIIAYTMSLGAENSVAYSNNSIAIPTNFTISV TTEILPVSMTKTSVDCTMYICGDSTECSNLLLQYGSFCTQLNRALTGIA VEQDKNTQEVFAQVKQIYKTPPIKDFGGFNFSQILPDPSKPSKRSFIED LLFNKVTLADAGFIKQYGDCLGDIAARDLICAQKFNGLTVLPPLLTDE MIAQYTSALLAGTITSGWTFGAGAALQIPFAMQMAYRENGIGVTQNV LYENQKLIANQFNSAIGKIQDSLSSTASALGKLQDVVNQNAQALNTL VKQLSSNFGAISSVLNDILSRLDKVEAEVQIDRLITGRLQSLQTYVTQQ LIRAAEIRASANLAATKMSECVLGQSKRVDFCGKGYHLMSFPQSAPH GVVFLHVTYVPAQEKNFTTAPAICHDGKAHFPREGVFVSNGTHWFVT QRNFYEPQIITTDNTFVSGNCDVVIGIVNNTVYDPLQPELDSFKEELDK YFKNHTSPDVDLGDISGINASVVNIQKEIDRLNEVAKNLNESLIDLQEL GKYEQYIKWPWYIWLGFIAGLIAIVMVTIMLCCMTSCCSCLKGCCSC GSCCKFDEDDSEPVLKGVKLHYT SARS-COV-2 MFLVLLPLVSSQCVNLTTRTQLPPAYTNSFTRGVYYPDKVFRSSVL 60 Modified Spike HSTQDLFLPFFSNVTWFHAIHVSGTNGTKRFDNPVLPFNDGVYFASTE (Potential KSNIIRGWIFGTTLDSKTQSLLIVNNATNVVIKVCEFQFCNDPFLGVYY mutations in HKNNKSWMESEFRVYSSANNCTFEYVSQPFLMDLEGKQGNFKNLRE Bold italic FVFKNIDGYFKIYSKHTPINLVRDLPQGFSALEPLVDLPIGINITRFQTLL lowercase. ALHRSYLTPGDSSSGWTAGAAAYYVGYLQPRTFLLKYNENGTITDAV modifications DCALDPLSETKCTLKSFTVEKGIYQTSNFRVQPTESIVRFPNITNLCPFG may be in EVFNATRFASVYAWNRKRISNCVADYSVLYNSASFSTFKCYGVSPTK separate or LNDLCFTNVYADSFVIRGDEVRQIAPGQTGKIADYNYKLPDDFTGCVI combined AWNSNNLDSKVGGNYNYLYRLFRKSNLKPFERDISTEIYQAGSTPCN constructs) GVEGFNCYFPLQSYGFQPTNGVGYQPYRVVVLSFELLHAPATVCGPK KSTNLVKNKCVNFNFNGLTGTGVLTESNKKFLPFQQFGRDIADTTDA VRDPQTLEILDITPCSFGGVSVITPGTNTSNQVAVLYQ VNCTEVPVAI HADQLTPTWRVYSTGSNVFQTRAGCLIGAEHVNNSYECDIPIGAGICA SYQTQTNSPvRARSVASQSIIAYTMSLGAENSVAYSNNSIAIPTNFTISV TTEILPVSMTKTSVDCTMYICGDSTECSNLLLQYGSFCTQLNRALTGIA VEQDKNTQEVFAQVKQIYKTPPIKDFGGFNFSQILPDPSKPSK SFIEDL LFNKVTLADAGFIKQYGDCLGDIAARDLICAQKFNGLTVLPPLLTDEM IAQYTSALLAGTITSGWTFGAGAALQIPFAMQMAYRENGIGVTQNVL YENQKLIANQFNSAIGKIQDSLSSTASALGKLQDVVNQNAQALNTLV KQLSSNFGAISSVLNDILSRLD EAEVQIDRLITGRLQSLQTYVTQQLI RAAEIRASANLAATKMSECVLGQSKRVDFCGKGYHLMSFPQSAPHG VVFLHVTYVPAQEKNFTTAPAICHDGKAHFPREGVFVSNGTHWFVTQ RNFYEPQUITTDNTFVSGNCDVVIGIVNNTVYDPLQPELDSFKEELDKY FKNHTSPDVDLGDISGINASVVNIQKEIDRLNEVAKNLNESLIDLQELG KYEQYIKWPWYIWLGFIAGLIAIVMVTIMLCCMTSCCSCLKGCCSCGS CCKFDEDDSEPVLKGVKLHYT SARS-COV-2 MADSNGTITVEELKKLLEQWNLVIGFLFLTWICLLQFAYANRNRFLYI 61 Membrane IKLIFLWLLWPVTLACFVLAAVYRINWITGGIAIAMACLVGLMWLSYF IASFRLFARTRSMWSFNPETNILLNVPLHGTILTRPLLESELVIGAVILR GHLRIAGHHLGRCDIKDLPKEITVATSRTLSYYKLGASQRVAGDSGFA AYSRYRIGNYKLNTDHSSSSDNIALLVQ SARS-COV-2 MSDNGPQNQRNAPRITFGGPSDSTGSNQNGERSGARSKQRRPQGLPN 62 Nucleocapsid NTASWFTALTQHGKEDLKFPRGQGVPINTNSSPDDQIGYYRRATRRIR GGDGKMKDLSPRWYFYYLGTGPEAGLPYGANKDGIIWVATEGALNT PKDHIGTRNPANNAAIVLQLPQGTTLPKGFYAEGSRGGSQASSRSSSR SRNSSRNSTPGSSRGTSPARMAGNGGDAALALLLLDRLNQLESKMSG KGQQQQGQTVTKKSAAEASKKPRQKRTATKAYNVTQAFGRRGPEQT QGNFGDQELIRQGTDYKHWPQIAQFAPSASAFFGMSRIGMEVTPSGT WLTYTGAIKLDDKDPNFKDQVILLNKHIDAYKTFPPTEPKKDKKKKA DETQALPQRQKKQQTVTLLPAADLDDFSKQLQQSMSSADSTQA SARS-COV-2 MYSFVSEETGTLIVNSVLLFLAFVVFLLVTLAILTALRLCAYCCNIVNV 63 Envelope SLVKPSFYVYSRVKNLNSSRVPDLLV

TABLE-US-00005 TABLE 4 SARS-CoV-2 Vaccine Designs Vector Insert SEQ ID NO: EDGE Predicted Epitopes (EPE): Concatenated EDGE 64 predicted SARS-CoV-2 MHC Class I Epitope Cassette with 5′ expression leader (bold) and 3′ Universal MHC Class II with GPGPG linkers (SEQ ID NO: 56) (bold italic) CMV-EPE-BGH 65 CMV-Spike (IDT)-T2A-membrane protein-SV40 66 CMV-Spike (IDT)-T2A-membrane protein-BGH 67 CMV-Spike (IDT)-SV40-CMV-EPE-BGH 68 CMV-Spike (IDT)-SV40 69 CMV-Modified Spike (IDT)-SV40 70 CMV-Spike (IDT)-T2A-Envelope-SV40-CMV- 71 nucleocapsid-T2A-membrane protein-SV40 CMV-Spike (IDT)-SV40 -CMV-nucleocapsid-T2A- 72 membrane protein-BGH CMV-Spike (IDT)-T2A-envelope protein-T2A- 73 membrane protein-SV40 CMV-Spike (IDT)-T2A-envelope protein-T2A- 74 membrane protein-SV40-CMV-EPE-BGH

SAM Vectors

[0594] A RNA alphavirus backbone for the antigen expression system was generated from a self-replicating Venezuelan Equine Encephalitis (VEE) virus (Kinney, 1986, Virology 152: 400-413) by deleting the structural proteins of VEE located 3′ of the 26S sub-genomic promoter (VEE sequences 7544 to 11,175 deleted; numbering based on Kinney et al 1986; SEQ ID NO:6). To generate the self-amplifying mRNA (“SAM”) vector, the deleted sequences are replaced by antigen sequences. A representative SAM vector containing 20 model antigens is “VEE-MAG25mer” (SEQ ID NO:4). The vectors featuring the antigen cassettes described having the MAG25mer cassette can be replaced by the SARS-CoV-2 cassettes and/or full-length proteins described herein.

In Vitro Transcription to Generate SAM

[0595] For in vivo studies: SAM vectors were generated as “AU-SAM” vectors. A modified T7 RNA polymerase promoter (TAATACGACTCACTATA; SEQ ID NO: 120), which lacks the canonical 3′ dinucleotide GG, was added to the 5′ end of the SAM vector to generate the in vitro transcription template DNA (SEQ ID NO:77; 7544 to 11,175 deleted without an inserted antigen cassette). Reaction conditions are described below: [0596] 1× transcription buffer (40 mM Tris-HCL [pH7.9], 10 mM dithiothreitol, 2 mM spermidine, 0.002% Triton X-100, and 27 mM magnesium chloride) using final concentrations of 1× T7 RNA polymerase mix (E2040S); 0.025 mg/mL DNA transcription template (linearized by restriction digest); 8 mM CleanCap Reagent AU (Cat. No. N-7114) and 10 mM each of ATP, cytidine triphosphate (CTP), GTP, and uridine triphosphate (UTP) [0597] Transcription reactions were incubated at 37° C. for 2 hr and treated with final 2 U DNase I (AM2239)/0.001 mg DNA transcription template in DNase I buffer for 1 hr at 37° C. [0598] SAM was purified by RNeasy Maxi (QIAGEN, 75162)

[0599] Alternatively to co-transcriptional addition of a 5′ cap structure, a 7-methylguanosine or a related 5′ cap structure can be enzymatically added following transcription using a vaccinia capping system (NEB Cat. No. M2080) containing mRNA 2′-O-methyltransferase and S-Adenosyl methionine.

Adenoviral Vectors

[0600] A modified ChAdV68 vector (“chAd68-Empty-E4deleted” SEQ ID NO:75) for the antigen expression system was generated based on AC_000011.1 with E1 (nt 577 to 3403), E3 (nt 27,125-31,825), and E4 region (nt 34,916 to 35,642) sequences deleted and the corresponding ATCC VR-594 (Independently sequenced Full-Length VR-594 C68 SEQ ID NO:10) nucleotides substituted at five positions. The full-length ChAdV68 AC_000011.1 sequence with corresponding ATCC VR-594 nucleotides substituted at five positions is referred to as “ChAdV68.5WTnt” (SEQ ID NO:1). Antigen cassettes under the control of the CMV promoter/enhancer are inserted in place of deleted E1 sequences.

Adenoviral Production in 293F Cells

[0601] ChAdV68 virus production are performed in 293F cells grown in 293 FreeStyle™ (ThermoFisher) media in an incubator at 8% CO.sub.2. On the day of infection cells are diluted to 10.sup.6 cells per mL, with 98% viability and 400 mL are used per production run in 1 L Shake flasks (Corning). 4 mL of the tertiary viral stock with a target MOI of >3.3 is used per infection. The cells are incubated for 48-72 h until the viability was <70% as measured by Trypan blue. The infected cells are then harvested by centrifugation, full speed bench top centrifuge and washed in 1×PBS, re-centrifuged and then re-suspended in 20 mL of 10 mM Tris pH7.4. The cell pellet is lysed by freeze thawing 3× and clarified by centrifugation at 4,300×g for 5 minutes.

Adenoviral Purification by CsCl Centrifugation

[0602] Viral DNA is purified by CsCl centrifugation. Two discontinuous gradient runs are performed. The first to purify virus from cellular components and the second to further refine separation from cellular components and separate defective from infectious particles.

[0603] 10 mL of 1.2 (26.8g CsCl dissolved in 92 mL of 10 mM Tris pH 8.0) CsCl is added to polyallomer tubes. Then 8 mL of 1.4 CsCl (53g CsCl dissolved in 87 mL of 10 mM Tris pH 8.0) is carefully added using a pipette delivering to the bottom of the tube. The clarified virus is carefully layered on top of the 1.2 layer. If needed more 10 mM Tris is added to balance the tubes. The tubes are then placed in a SW-32Ti rotor and centrifuged for 2h 30 min at 10° C. The tube are then removed to a laminar flow cabinet and the virus band pulled using an 18 gauge needle and a 10 mL syringe. Care is taken not to remove contaminating host cell DNA and protein. The band is then diluted at least 2× with 10 mM Tris pH 8.0 and layered as before on a discontinuous gradient as described above. The run is performed as described before except that this time the run is performed overnight. The next day the band is pulled with care to avoid pulling any of the defective particle band. The virus is then dialyzed using a Slide-a-Lyzer™ Cassette (Pierce) against ARM buffer (20 mM Tris pH 8.0, 25 mM NaCl, 2.5% Glycerol). This is performed 3×, 1 h per buffer exchange. The virus is then aliquoted for storage at −80° C.

Adenoviral Viral Assays

[0604] VP concentration is performed by using an OD 260 assay based on the extinction coefficient of 1.1×10.sup.12 viral particles (VP) is equivalent to an Absorbance value of 1 at OD260 nm. Two dilutions (1:5 and 1:10) of adenovirus are made in a viral lysis buffer (0.1% SDS, 10 mM Tris pH 7.4, 1 mM EDTA). OD is measured in duplicate at both dilutions and the VP concentration/mL is measured by multiplying the OD260 value X dilution factor X 1.1×10.sup.12VP.

[0605] An infectious unit (IU) titer is calculated by a limiting dilution assay of the viral stock. The virus is initially diluted 100× in DMEM/5% NS/1×PS and then subsequently diluted using 10-fold dilutions down to 1×10.sup.−7. 100 μL of these dilutions are then added to 293A cells that were seeded at least an hour before at 3e5 cells/well of a 24 well plate. This is performed in duplicate. Plates are incubated for 48h in a CO2 (5%) incubator at 37° C. The cells are then washed with 1×PBS and are then fixed with 100% cold methanol (−20° C.). The plates are then incubated at −20° C. for a minimum of 20 minutes. The wells are washed with 1×PBS then blocked in 1×PBS/0.1% BSA for 1 h at room temperature. A rabbit anti-Ad antibody (Abcam, Cambridge, MA) is added at 1:8,000 dilution in blocking buffer (0.25 ml per well) and incubated for 1 h at room temperature. The wells are washed 4× with 0.5 mL PBS per well. A HRP conjugated Goat anti-Rabbit antibody (Bethyl Labs, Montgomery Texas) diluted 1000× is added per well and incubated for 1h prior to a final round of washing. 5 PBS washes are performed and the plates were developed using DAB (Diaminobenzidine tetrahydrochloride) substrate in Tris buffered saline (0.67 mg/mL DAB in 50 mM Tris pH 7.5, 150 mM NaCl) with 0.01% H.sub.2O.sub.2. Wells are developed for 5 min prior to counting. Cells are counted under a 10× objective using a dilution that gave between 4-40 stained cells per field of view. The field of view that is used was a 0.32 mm.sup.2 grid of which there are equivalent to 625 per field of view on a 24 well plate. The number of infectious viruses/mL can be determined by the number of stained cells per grid multiplied by the number of grids per field of view multiplied by a dilution factor 10. Similarly, when working with GFP expressing cells florescent can be used rather than capsid staining to determine the number of GFP expressing virions per mL.

[0606] XIV.C. Vaccine Efficacy Evaluation in Mice using ChAdV68 Vectors

[0607] Efficacy of vaccines containing cassettes encoding SARS-CoV-2 Spike was evaluated for a high and low dose. Efficacy was assessed through monitoring T cell responses.

Immunizations

[0608] For ChAdV68 vaccines in Balb/c mice, 5×10.sup.8 or 1×10.sup.10 viral particles (VP) in 100 uL volume were administered as a bilateral intramuscular injection (50 uL per leg).

Splenocyte Dissociation

[0609] Splenocytes were isolated 14 days post-immunization. Spleens for each mouse were pooled in 3 mL of complete RPMI (RPMI, 10% FBS, penicillin/streptomycin). Mechanical dissociation was performed using the gentleMACS Dissociator (Miltenyi Biotec), following manufacturer's protocol. Dissociated cells were filtered through a 40 micron filter and red blood cells were lysed with ACK lysis buffer (150 mM NH.sub.4Cl, 10 mM KHCO.sub.3, 0.1 mM Na.sub.2EDTA). Cells were filtered again through a 30 micron filter and then resuspended in complete RPMI. Cells were counted on the Cytoflex LX (Beckman Coulter) using propidium iodide staining to exclude dead and apoptotic cells. Cell were then adjusted to the appropriate concentration of live cells for subsequent analysis.

Ex Vivo Enzyme-Linked Immunospot (ELISpot) Analysis

[0610] ELISPOT analysis was performed according to ELISPOT harmonization guidelines {DOI: 10.1038/nprot.2015.068} with the mouse IFNg ELISpotPLUS kit (MABTECH). 5×10.sup.4 splenocytes were stimulated ex vivo with 10 uM of overlapping peptide pools (15 aa long, 11 aa overlap) spanning the Spike antigen for 16 hours in 96-well IFNg antibody coated plates. Spots were developed using alkaline phosphatase. The reaction was timed for 10 minutes and was terminated by running plate under tap water. Spots were counted using an AID vSpot Reader Spectrum. For ELISPOT analysis, wells with saturation>50% were recorded as “too numerous to count”. Samples with deviation of replicate wells>10% were excluded from analysis. Spot counts were then corrected for well confluency using the formula: spot count+2×(spot count×% confluence/[100%−% confluence]). Negative background was corrected by subtraction of spot counts in the negative peptide stimulation wells from the antigen stimulated wells. Finally, wells labeled too numerous to count were set to the highest observed corrected value, rounded up to the nearest hundred.

Results

[0611] Mice were immunized with modified ChAdV68 vector (vector backbone based on chAd68-Empty-E4deleted” SEQ ID NO:75) containing a cassette encoding the SARS-CoV-2 Spike protein (“CMV-Spike-SV40” SEQ ID NO:69; Spike protein sequence-optimized using IDT algorithm; nb, the initial experimental cassette contained a single D1153G missense mutation) Efficacy was assessed by IFNγ ELISpot for T cell responses to two peptide pools spanning the Spike protein. As shown in FIG. 8A, compared to splenocytes from naïve mice, immunization with the Spike encoding ChAdV68 vector demonstrated a dose-dependent increased T cell response to Spike peptides (left panel—SFCs per 10.sup.6 splenocytes for each separate peptide pool; right panel—SFCs per 10.sup.6 splenocytes for summed response across both peptide pools).

[0612] XIV.D. Vaccine Efficacy Evaluation in Mice using SAM Vectors

[0613] Efficacy of vaccines containing cassettes encoding SARS-CoV-2 MHC epitope-encoding cassettes and/or full-length SARS-CoV-2 proteins (e.g., see Table 4) was evaluated. Efficacy was assessed through monitoring T cell and/or B cell responses.

Immunizations

[0614] For SAM vaccines, 1 or 10 ug of RNA-LNP complexes in 100 uL volume were administered as a bilateral intramuscular injection (50 uL per leg).

[0615] Study arms are described in Table 5A below.

TABLE-US-00006 TABLE 5A Murine SARS-CoV-2 Study Arms for SAM Evaluation Strain and Number Treatment SAM Vectors of Animals Dose Schedule Immune Readouts SAM-Spike BALB/c 1 ug Day 0 Sera at day 0, 14, 28, 41, SAM-Spike-Membrane N = 10/group and 56, 70: anti-Spike and SAM-Spike-T cell epitopes 5 male, 5 female 10 ug anti-Membrane IgG (ELISA) and Spike nAb SAM-Spike Spleen harvest at day 12- SAM-Spike-Membrane 14: T-cell response by SAM-Spike-T cell epitopes ELISpot and ICS with OLP to Spike and Membrane SAM-Spike-T cell epitopes HLA-A2/A11 10 ug Day 0 Spleen harvest at day 12- SAM- T cell epitopes transgenic mice 14: T-cell response by N = 6/group ELISpot and ICS with OLP to Spike and T cell epitopes

Splenocyte Dissociation

[0616] Splenocytes were isolated 2 weeks and 10 weeks post-immunization. Spleens for each mouse are pooled in 3 mL of complete RPMI (RPMI, 10% FBS, penicillin/streptomycin). Mechanical dissociation was performed using the gentleMACS Dissociator (Miltenyi Biotec), following manufacturer's protocol. Dissociated cells were filtered through a 40 micron filter and red blood cells were lysed with ACK lysis buffer (150 mM NH.sub.4Cl, 10 mM KHCO.sub.3, 0.1 mM Na.sub.2EDTA). Cells were filtered again through a 30 micron filter and then resuspended in complete RPMI. Cells were counted on the Cytoflex LX (Beckman Coulter) using propidium iodide staining to exclude dead and apoptotic cells. Cells were then adjusted to the appropriate concentration of live cells for subsequent analysis.

Ex Vivo Enzyme-Linked Immunospot (ELISpot) Analysis

[0617] ELISPOT analysis was performed according to ELISPOT harmonization guidelines {DOI: 10.1038/nprot.2015.068} with the mouse IFNg ELISpotPLUS kit (MABTECH). 5×10.sup.4 splenocytes were incubated with 10 uM of overlapping peptide pools (“OLP”; 15mers, 11aa overlap) spanning the entire antigen of interest for 16 hours in 96-well IFNg antibody coated plates. Spots were developed using alkaline phosphatase. The reaction was timed for 10 minutes and was terminated by running plate under tap water. Spots were counted using an AID vSpot Reader Spectrum. For ELISPOT analysis, wells with saturation>50% are recorded as “too numerous to count”. Samples with deviation of replicate wells>10% were excluded from analysis. Spot counts were then corrected for well confluency using the formula: spot count+2×(spot count×% confluence/[100%−% confluence]). Negative background was corrected by subtraction of spot counts in the negative peptide stimulation wells from the antigen stimulated wells. Finally, wells labeled too numerous to count were set to the highest observed corrected value, rounded up to the nearest hundred.

Ex Vivo Intracellular Cytokine Staining (ICS) and Flow Cytometry Analysis

[0618] Freshly isolated lymphocytes at a density of 2-5×10.sup.6 cells/mL were incubated with 10 uM of overlapping peptide pools (15mers, 11aa overlap) spanning the entire antigen of interest for 2 hours. After two hours, brefeldin A was added to a concentration of 5 ug/ml and cells were incubated with stimulant for an additional 4 hours. Following stimulation, viable cells were labeled with fixable viability dye eFluor780 according to manufacturer's protocol and stained with anti-CD8 APC (clone 53-6.7, BioLegend) at 1:400 dilution. Anti-IFNg PE (clone XMG1.2, BioLegend) was used at 1:100 for intracellular staining. Cells were also stained for CD4, TNFα, IL-2, IL-4, IL-10, and Granzyme-B. Samples were collected on an Cytoflex LX (Beckman Coulter). Flow cytometry data was plotted and analyzed using FlowJo. To assess degree of antigen-specific response, the percent of stained cells was calculated in response to each peptide pool.

Antibody Titers

[0619] For antibody response monitoring, blood was collected every two weeks. Antibody titers in the sera were determined as described in J. Yu et al. (Science 10.1126/science. Abc6284 (2020), herein incorporated by reference for all purposes.

Results

[0620] Mice were immunized with SAM vectors containing a cassette encoding the SARS-CoV-2 Spike protein (SEQ ID NO:59, IDT optimized sequence), Membrane protein (SEQ ID NO:61), and/or a SARS-CoV-2 MHC epitope-encoding cassette (SEQ ID NO:58). Efficacy was assessed by IFNγ ELISpot for T cell responses to two peptide pools spanning the Spike protein. As shown in FIG. 8B and FIG. 8C (quantified in Table 7), compared to splenocytes from naïve mice, immunization with the Spike encoding SAM vector demonstrated a dose-dependent increased T cell response to Spike peptides (FIG. 8A—SFCs per 10.sup.6 splenocytes for each separate peptide pool; FIG. 8B—SFCs per 10.sup.6 splenocytes for combined response across both peptide pools). In addition, as demonstrated in Table 8 below, immunization with SAM-Spike demonstrated an increase in antibody titers, and specifically neutralizing antibody (“Nab”). Notably, Nab titers were comparable in magnitude to Nab titers in a cohort of 27 covalescent humans (median titer 93) who had recovered from SARS-CoV-2 [J. Yu et al. (Science 10.1126/science. Abc6284 (2020)]. Thus, the results indicate vaccination with SAM vectors encoding SARS-CoV-2 derived antigens, and in particular SARS-CoV-2 Spike, demonstrated a T cell and B cell immune response.

TABLE-US-00007 TABLE 7 Cellular immune responses in SAM vaccinated mice Mean SFCs SAM-SARS- Mouse Dose per 1 × 10.sup.6 CoV-2 Vaccine strain (ug) OLP Splenocytes SD SAM-Spike BALB/c 10 Spike 8560 1195 SAM-Spike BALB/c 1 Spike 7734 2079 SAM-Spike BALB/c 10 Spike 25033 8722 SAM-Spike BALB/c 1 Spike 8605 1861 SAM-Spike- BALB/c 10 Spike 19741 5141 Membrane SAM-Spike- BALB/c 1 Spike 8212 2093 Membrane SAM-Spike- BALB/c 10 Membrane 93 42 Membrane SAM-Spike- BALB/c 1 Membrane 129 56 Membrane SAM-Spike BALB/c 10 Spike 9798 5434 SAM-Spike BALB/c 1 Spike 3578 1881 SAM-Spike-T BALB/c 10 Spike 3484 1849 cell epitopes SAM-Spike-T BALB/c 1 Spike 1529 466 cell epitopes SAM-Spike-T HLA-A2 10 Spike 8273 2351 cell epitopes SAM-Spike-T HLA-A11 10 Spike 7175 734 cell epitopes SAM-Spike-T HLA-A2 10 T cell 2717 443 cell epitopes epitopes SAM-Spike-T HLA-A11 10 T cell 2621 664 cell epitopes epitopes SAM-T cell HLA-A2 10 T cell 1474 836 epitopes epitopes SAM-T cell HLA-A11 10 T cell 748 371 epitopes epitopes

TABLE-US-00008 TABLE 8 Humoral immune responses in SAM vaccinated mice SAM-SARS- Sera Median CoV-2 Mouse Dose collection Median end pseudovirus Vaccine strain (ug) time (week) point titer Nab titer SAM-Spike BALB/c 10 4 26380 96.5 SAM-Spike BALB/c 10 6 22953 129 SAM-Spike- BALB/c 10 4 6849 43 Membrane SAM-T cell BALB/c 10 4 2555 26 epitopes

[0621] XIV.E.1 Vaccine Efficacy Evaluation in Mice PP31T

[0622] Efficacy of vaccines containing cassettes encoding SARS-CoV-2 MHC epitope-encoding cassettes and/or full-length SARS-CoV-2 proteins (e.g., see Table 4) is evaluated. Efficacy is assessed through monitoring T cell and/or B cell responses.

Immunizations

[0623] For SAM vaccines in Balb/c mice, 1 or 10 ug of RNA-LNP complexes in 100 uL volume, bilateral intramuscular injection (50 uL per leg).

[0624] For ChAdV68 vaccines in Balb/c mice, 5×10.sup.8 or 1×10.sup.10 viral particles (VP) in 100 uL volume is administered as a bilateral intramuscular injection (50 uL per leg).

[0625] Mice receive an initial priming dose and a subsequent boosting dose at week 6. Mice are immunized either with a homologous SAM vaccination strategy, a homologous ChAdV68 vaccination strategy, or a heterologous ChAdV68/SAM vaccination strategy (ChAdV68 prime; SAM boost).

[0626] Representative study arms are described in Table 5B below.

TABLE-US-00009 TABLE 5B Murine SARS-CoV-2 Study Arms Strain and Number Treatment Vector of Animals Dose Schedule Immune Readouts ChAd-Spike Balb/C 1 × 10.sup.10 vp Day 0 Sera at day 0, 14, 28: ChAd-Spike-Membrane N = 10/group and anti-Spike and anti- ChAd-Spike-T cell epitopes 5 male, 5 female 5 × 10.sup.8 vp Membrane IgG (ELISA) and Spike nAb ChAd-Spike Spleen harvest at day 12: ChAd-Spike-Membrane T-cell response by ChAd-Spike-T cell epitopes ELISpot and ICS with OLP to Spike and Membrane ChAd-Spike-Membrane Aged Balb/c 1 × 10.sup.10 vp Day 0 Sera at day 0 and 14: ChAd-Spike-T cell epitopes (12 to 14 months) anti-Spike and anti- N = 10/group Membrane IgG (ELISA) 5 male, 5 female and Spike nAb ChAd-Spike-Membrane Spleen harvest at day 12: ChAd-Spike-T cell epitopes T-cell response by ELISpot and ICS with OLP to Spike and Membrane

Splenocyte Dissociation

[0627] Splenocytes are isolated 2 weeks and 8 weeks post-immunization. Spleens for each mouse are pooled in 3 mL of complete RPMI (RPMI, 10% FBS, penicillin/streptomycin). Mechanical dissociation is performed using the gentleMACS Dissociator (Miltenyi Biotec), following manufacturer's protocol. Dissociated cells are filtered through a 40 micron filter and red blood cells are lysed with ACK lysis buffer (150 mM NH.sub.4Cl, 10 mM KHCO.sub.3, 0.1 mM Na.sub.2EDTA). Cells are filtered again through a 30 micron filter and then resuspended in complete RPMI. Cells are counted on the Cytoflex LX (Beckman Coulter) using propidium iodide staining to exclude dead and apoptotic cells. Cell are then adjusted to the appropriate concentration of live cells for subsequent analysis.

Ex Vivo Enzyme-Linked Immunospot (ELISpot) Analysis

[0628] ELISPOT analysis is performed according to ELISPOT harmonization guidelines {DOI: 10.1038/nprot.2015.068} with the mouse IFNg ELISpotPLUS kit (MABTECH). 5×10.sup.4 splenocytes are incubated with 10 uM of overlapping peptide pools (15mers, 11aa overlap) spanning the entire antigen of interest for 16 hours in 96-well IFNg antibody coated plates. Spots are developed using alkaline phosphatase. The reaction is timed for 10 minutes and is terminated by running plate under tap water. Spots are counted using an AID vSpot Reader Spectrum. For ELISPOT analysis, wells with saturation>50% are recorded as “too numerous to count”. Samples with deviation of replicate wells>10% are excluded from analysis. Spot counts are then corrected for well confluency using the formula: spot count+2×(spot count×% confluence/[100%−% confluence]). Negative background is corrected by subtraction of spot counts in the negative peptide stimulation wells from the antigen stimulated wells. Finally, wells labeled too numerous to count are set to the highest observed corrected value, rounded up to the nearest hundred.

Ex Vivo Intracellular Cytokine Staining (ICS) and Flow Cytometry Analysis

[0629] Freshly isolated lymphocytes at a density of 2-5×10.sup.6 cells/mL are incubated with 10 uM of overlapping peptide pools (15mers, 11aa overlap) spanning the entire antigen of interest for 2 hours. After two hours, brefeldin A is added to a concentration of 5 ug/ml and cells are incubated with stimulant for an additional 4 hours. Following stimulation, viable cells are labeled with fixable viability dye eFluor780 according to manufacturer's protocol and stained with anti-CD8 APC (clone 53-6.7, BioLegend) at 1:400 dilution. Anti-IFNg PE (clone XMG1.2, BioLegend) was used at 1:100 for intracellular staining. Cell are also stained for CD4, TNFα, IL-2, IL-4, IL-10, and Granzyme-B. Samples are collected on an Cytoflex LX (Beckman Coulter). Flow cytometry data is plotted and analyzed using FlowJo. To assess degree of antigen-specific response, the percent of stained cells is calculated in response to each peptide pool.

Antibody Titers

[0630] For antibody response monitoring, blood is collected every two weeks. Antibody titers in the sera (IgG, IgM) are determined for Spike and Membrane proteins. IgG1/IgG2 isotypes are determine to assess Th1 polarization. Antibody-mediated neutralization is also assessed.

Aged Mouse Model

[0631] An aged mouse model used in SARS-CoV-1 evaluation (Bolles 2011) is used to assess T cell immunogenicity, B cell responses, and antibody-mediated neutralization. For ChAdV68 vaccines in Balb/c mice, 1×10.sup.10 viral particles (VP) in 100 uL volume is administered as a bilateral intramuscular injection (50 uL per leg). For SAM vaccines in aged BALB/c mice, 10 ug of SAM-LNP in 100 uL volume is administrated as a bilateral intramuscular injection (50 uL per leg).

Results

[0632] Mice are immunized, as described above. The efficacy study in mice is illustrated in FIG. 9. Vaccines containing cassettes encoding SARS-CoV-2 MHC epitope-encoding cassettes and/or full-length SARS-CoV-2 proteins demonstrate both T cell and B cell immune responses according to the vaccine design. CD4, CD8, Th1, and Th2 polarizations are also determined.

[0633] XIV.E.2 Vaccine Efficacy Evaluation in Non-Human Primates

[0634] Efficacy and safety of vaccines containing cassettes encoding SARS-CoV-2 MHC epitope-encoding cassettes and/or full-length SARS-CoV-2 proteins (e.g., see Table 4) is evaluated. Efficacy is assessed through monitoring T cell and/or B cell responses.

Immunizations

[0635] For SAM vaccines in Mamu-A*01 Indian rhesus macaques, SAM is administered as bilateral intramuscular injections into the quadriceps muscle at a dose of 1 mg total per animal in 1 mL per leg.

[0636] For ChAdV68 vaccines in Mamu-A*01 Indian rhesus macaques, ChAdV68 is administered bilaterally with 1×10.sup.12 viral particles (5×10.sup.11 viral particles per injection).

Immune Monitoring in Rhesus

[0637] For immune monitoring, 10-20 mL of blood is collected into vacutainer tubes containing heparin and maintained at room temperature until isolation. PBMCs are isolated by density gradient centrifugation using lymphocyte separation medium (LSM) and Leucosep separator tubes. PBMCs are stained with propidium iodide and viable cells counted using the Cytoflex LX (Beckman Coulter). Samples are then resuspended at 4×10.sup.6 cells/mL in RPMI complete (10% FBS).

[0638] IFNγ ELISPOT assays are performed using pre-coated 96-well plates (MAbtech, Monkey IFNγ ELISPOT PLUS, ALP (Kit Lot #36, Plate Lot #19)) following manufacturer's protocol. For each sample and stimuli, 1×10.sup.5 PBMCs per well are plated in triplicate with 10 ug/mL peptide stimuli (GenScript) and incubated overnight in complete RPMI. Samples are incubated overnight with overlapping peptide pools to Spike, Membrane or T-cell epitopes, or DMSO only. Overlapping pools (GenScript) consist of 15 amino acid long peptides, with 11 amino acid overlap, spanning each protein (Spike, Membrane, Nucleocapsid) or EDGE determined stretch of epitopes. Each pool is divided into minipools of up to 60 peptides each. DMSO only is used as a negative control for each sample. Plates are washed with PBS and incubated with anti-monkey IFNγ MAb biotin (MAbtech) for two hours, followed by an additional wash and incubation with Streptavidin-ALP (MAbtech) for one hour. After final wash, plates are incubated for ten minutes with BCIP/NBT (MAbtech) to develop the immunospots and dried overnight at 37° C. Spots are imaged and enumerated using AID reader (Autoimmun Diagnostika).

[0639] Samples with replicate well variability (Variability=Variance/[median+1]) greater than 10 and median greater than 10 are excluded. Spot values are adjusted based on the well saturation according to the formula: AdjustedSpots=RawSpots+2*(RawSpots*Saturation/[100-Saturation]). Wells with well saturation greater than 33% are considered “too numerous to count” (TNTC) and excluded. Background correction for each sample is performed by subtracting the average value of the negative control peptide wells. Data is normalized to spot forming colonies (SFC) per 1×10.sup.6 PBMCs by multiplying the corrected spot number by 1×10.sup.6/Cell number plated. For overall summary analysis calculated values generated by plating cells at 1×10.sup.5 cells/well are utilized, except when samples are TNTC, in which case values generated from plating cells at 2.5×10.sup.4 cells are used for that specific sample/stimuli/timepoint. Data processing as performed using the R programming language.

[0640] Intracellular cytokine assays are also performed. PBMCs are distributed at 1×10.sup.6 cells per well into v-bottom 96-well plates. Cells are pelleted and resuspended in 100 l of complete RPMI containing the overlapping peptide pools described above, to either Spike, Membrane, or the EDGE predicted T-cell epitopes. DMSO is used as a negative control for each sample. Brefeldin A (Biolegend) is added to a final concentration of 5 μg/mL after 1 hour and cells incubated overnight. Following viability stain, extracellular staining is performed in FACS buffer (PBS+2% FBS+2 mM EDTA). Cells are washed, fixed and permeabilized with the eBiosciences Fixation/Permeabilization Solution Kit. Intracellular staining is performed. Samples are assessed for viability, CD3, CD4, CD8, IFNγ, TNFa, IL-2, Perforin, CD107a, CCR7, and CD45RA.

[0641] Serum cytokine markers are also monitored. Serum cytokine and chemokine levels are measured with standard multiplex assays. Serum is collected and marker analysis is performed at 0 hours (baseline), 2 hours, 8 hours, and 48 hours following vaccination. Cytokines assessed are Interleukin-1 beta (IL-1β), Interleukin-1 (IL-10), Interleukin-6 (IL-6), Tumor necrosis factor alpha (TNF-α), Interferon gamma (IFN-γ), Granulocyte-macrophage colony-stimulating factor (GM-CSF), Interferon gamma-induced protein 10 (IP-10), Monocyte chemoattractant protein-1 (MCP-1), Macrophage inflammatory protein 1 beta (MIP-1β), and IFN-alpha (IFN-α2a).

[0642] Serum antibody titers and neutralizing antibody titers are determined.

Results

[0643] NHPs are immunized, as described above. Vaccines containing cassettes encoding SARS-CoV-2 MHC epitope-encoding cassettes and/or full-length SARS-CoV-2 proteins demonstrate both T cell and B cell immune responses according to the vaccine design. The vaccine strategies also result in neutralizing antibody production.

[0644] XIV.F. Spike Protein Sequence Optimization

[0645] Various sequence-optimized nucleotide sequences encoding the Spike protein were evaluated in ChAdV68 vaccine vectors.

Sequence-Optimization of Spike Sequence

[0646] The Spike nucleotide sequence from Wuhan Hu/1 (SEQ ID NO:78) was sequence-optimized by substituting synonymous codons such that the amino acid sequence was unaffected. An IDT algorithm was used for enhanced expression in humans and for reduced complexity to aid synthesis (see, e.g., SEQ ID NOs:66-74). The Spike sequence was additionally sequence-optimized using two additional algorithms; (1) a single sequence (SEQ ID NO:87) generated using SGI DNA (La Jolla, CA); (2) 6 sequences designated CT1, CT20, CT56, CT83, CT131, and CT 199 (SEQ ID NOs:79-84) generated using COOL (COOL algorithm generates multiple sequences and 6 were selected). The sequences of each are presented in Table 6.

[0647] Splicing events were identified in cDNA from 293A cells infected with ChAdV68 viruses or transfected with ChAdV68 genomic DNA. Specifically, total RNA from 10e5-10e6 cells was purified using Qiagen's RNeasy columns. Residual DNA was removed by DNAse treatment, and cDNA was produced using SuperScriptIV reverse transcriptase (Thermo). Subsequently, primers specific for the 5′ UTR and 3′ UTR of the Gritstone ChAdV68 cassette were used to generate PCR products, analyzed by agarose gel electrophoresis, gel-purified, and Sanger-sequenced to identify regions deleted by splicing.

[0648] Splice donor sites were removed by site-directed mutagenesis disrupting the nucleotide sequence motif while not disturbing the amino acid sequence. Mutagenesis was accomplished by incorporating above mutations into PCR primers, amplifying several fragments in parallel, and running a Gibson assembly on the fragments (overlapping by 30-60 nt). Optimized clone CT1-2C (SEQ ID NO:85) had Sanger sequence-identified splice donor motifs at NT385 and NT539 mutated, and clone IDT-4C (SEQ ID NO:86) had Sanger sequence-identified splice donor motifs at NT385, NT539, and predicted donor motifs at NT2003, and NT2473 mutated. Additionally, a possible polyadenylation site AATAAA at nt 445 was mutated to AAcAAA in IDT-4C clone.

[0649] The sequences described are presented in Table 6.

TABLE-US-00010 TABLE 6 Sequence-optimized Spike Sequences SEQ Spike ID Sequence Nucleic Acid Sequence NO:  Spike Native; atgtttgtttttcttgttttattgccactagtctctagtcagtgtgttaatcttacaaccagaactcaattaccccctgca 78 NC_045512.2 tacactaattctttcacacgtggtgtttattaccctgacaaagttttcagatcctcagttttacattcaactcaggactt Severe acute gttcttacctttcttttccaatgttacttggttccatgctatacatgtctctgggaccaatggtactaagaggtttgata respiratory accctgtcctaccatttaatgatggtgtttattttgcttccactgagaagtctaacataataagaggctggatttttgg syndrome tactactttagattcgaagacccagtccctacttattgttaataacgctactaatgttgttattaaagtctgtgaatttc coronavirus 2 aattttgtaatgatccatttttgggtgtttattaccacaaaaacaacaaaagttggatggaaagtgagttcagagttt isolate  attctagtgcgaataattgcacttttgaatatgtctctcagccttttcttatggaccttgaaggaaaacagggtaattt Wuhan- caaaaatcttagggaatttgtgtttaagaatattgatggttattttaaaatatattctaagcacacgcctattaatttagt Hu-1 gcgtgatctccctcagggtttttcggctttagaaccattggtagatttgccaataggtattaacatcactaggtttca aactttacttgctttacatagaagttatttgactcctggtgattcttcttcaggttggacagctggtgctgcagcttatt atgtgggttatcttcaacctaggacttttctattaaaatataatgaaaatggaaccattacagatgctgtagactgtg cacttgaccctctctcagaaacaaagtgtacgttgaaatccttcactgtagaaaaaggaatctatcaaacttctaa ctttagagtccaaccaacagaatctattgttagatttcctaatattacaaacttgtgcccttttggtgaagtttttaacg ccaccagatttgcatctgtttatgcttggaacaggaagagaatcagcaactgtgttgctgattattctgtcctatata attccgcatcattttccacttttaagtgttatggagtgtctcctactaaattaaatgatctctgctttactaatgtctatg cagattcatttgtaattagaggtgatgaagtcagacaaatcgctccagggcaaactggaaagattgctgattata attataaattaccagatgattttacaggctgcgttatagcttggaattctaacaatcttgattctaaggttggtggtaa ttataattacctgtatagattgtttaggaagtctaatctcaaaccttttgagagagatatttcaactgaaatctatcag gccggtagcacaccttgtaatggtgttgaaggttttaattgttactttcctttacaatcatatggtttccaacccacta atggtgttggttaccaaccatacagagtagtagtactttcttttgaacttctacatgcaccagcaactgtttgtggac ctaaaaagtctactaatttggttaaaaacaaatgtgtcaatttcaacttcaatggtttaacaggcacaggtgttctta ctgagtctaacaaaaagtttctgcctttccaacaatttggcagagacattgctgacactactgatgctgtccgtgat ccacagacacttgagattcttgacattacaccatgttcttttggtggtgtcagtgttataacaccaggaacaaatac ttctaaccaggttgctgttctttatcaggatgttaactgcacagaagtccctgttgctattcatgcagatcaacttact cctacttggcgtgtttattctacaggttctaatgtttttcaaacacgtgcaggctgtttaataggggctgaacatgtc aacaactcatatgagtgtgacatacccattggtgcaggtatatgcgctagttatcagactcagactaattctcctc ggcgggcacgtagtgtagctagtcaatccatcattgcctacactatgtcacttggtgcagaaaattcagttgctta ctctaataactctattgccatacccacaaattttactattagtgttaccacagaaattctaccagtgtctatgaccaa gacatcagtagattgtacaatgtacatttgtggtgattcaactgaatgcagcaatcttttgttgcaatatggcagtttt tgtacacaattaaaccgtgctttaactggaatagctgttgaacaagacaaaaacacccaagaagtttttgcacaa gtcaaacaaatttacaaaacaccaccaattaaagattttggtggttttaatttttcacaaatattaccagatccatcaa aaccaagcaagaggtcatttattgaagatctacttttcaacaaagtgacacttgcagatgctggcttcatcaaaca atatggtgattgccttggtgatattgctgctagagacctcatttgtgcacaaaagtttaacggccttactgttttgcc acctttgctcacagatgaaatgattgctcaatacacttctgcactgttagcgggtacaatcacttctggttggacctt tggtgcaggtgctgcattacaaataccatttgctatgcaaatggcttataggtttaatggtattggagttacacaga atgttctctatgagaaccaaaaattgattgccaaccaatttaatagtgctattggcaaaattcaagactcactttcttc cacagcaagtgcacttggaaaacttcaagatgtggtcaaccaaaatgcacaagctttaaacacgcttgttaaac aacttagctccaattttggtgcaatttcaagtgttttaaatgatatcctttcacgtcttgacaaagttgaggctgaagt gcaaattgataggttgatcacaggcagacttcaaagtttgcagacatatgtgactcaacaattaattagagctgca gaaatcagagcttctgctaatcttgctgctactaaaatgtcagagtgtgtacttggacaatcaaaaagagttgattt ttgtggaaagggctatcatcttatgtccttccctcagtcagcacctcatggtgtagtcttcttgcatgtgacttatgtc cctgcacaagaaaagaacttcacaactgctcctgccatttgtcatgatggaaaagcacactttcctcgtgaaggt gtctttgtttcaaatggcacacactggtttgtaacacaaaggaatttttatgaaccacaaatcattactacagacaa cacatttgtgtctggtaactgtgatgttgtaataggaattgtcaacaacacagtttatgatcctttgcaacctgaatta gactcattcaaggaggagttagataaatattttaagaatcatacatcaccagatgttgatttaggtgacatctctgg cattaatgcttcagttgtaaacattcaaaaagaaattgaccgcctcaatgaggttgccaagaatttaaatgaatctc tcatcgatctccaagaacttggaaagtatgagcagtatataaaatggccatggtacatttggctaggttttatagct ggcttgattgccatagtaatggtgacaattatgctttgctgtatgaccagttgctgtagttgtctcaagggctgttgtt cttgtggatcctgctgcaaatttgatgaagacgactctgagccagtgctcaaaggagtcaaattacattacacata a Spike CT1 ATGTTTGTCTTCCTGGTCTTGCTGCCGCTGGTGAGCAGCCAGTGCG 79 Optimized TGAATCTCACCACCCGCACCCAGCTTCCACCTGCCTACACTAACAG CTTCACCCGAGGGGTGTATTACCCTGACAAGGTATTCCGGTCCTCC GTCCTCCATAGCACGCAGGACCTTTTTCTGCCCTTCTTCTCAAATGT GACATGGTTCCATGCCATTCACGTGAGCGGCACGAATGGAACGAA GCGCTTTGATAACCCCGTGCTGCCTTTCAATGACGGCGTCTACTTC GCCTCCACTGAAAAGTCAAACATCATCCGGGGCTGGATCTTTGGC ACCACTCTTGATTCAAAGACCCAGTCACTGCTGATTGTGAACAATG CTACAAACGTGGTTATCAAGGTGTGTGAGTTTCAGTTCTGTAACGA TCCATTTTTGGGAGTGTACTACCACAAGAACAACAAGTCCTGGATG GAGTCTGAGTTCAGAGTGTATAGCTCTGCTAACAACTGCACCTTCG AGTACGTGTCCCAGCCTTTCCTTATGGACCTGGAAGGCAAACAGG GCAATTTCAAAAACCTGAGAGAGTTCGTGTTTAAGAACATTGACG GATACTTCAAAATTTATTCTAAGCACACACCAATTAACTTAGTGCG GGACCTACCCCAAGGCTTTAGCGCCCTAGAGCCCCTGGTTGACCTG CCCATTGGGATCAATATAACAAGGTTCCAAACTCTACTGGCTCTGC ATAGAAGTTATCTGACCCCAGGAGACAGCTCTAGTGGTTGGACCG CCGGCGCAGCAGCCTACTATGTCGGGTACTTACAGCCACGCACGTT CCTTCTGAAGTACAATGAGAACGGGACAATCACTGACGCAGTAGA CTGTGCACTGGACCCGCTAAGCGAGACTAAGTGCACACTTAAATC CTTCACGGTGGAGAAAGGCATTTATCAGACCTCTAACTTCAGGGTG CAGCCAACAGAAAGCATTGTGCGATTCCCAAATATTACTAATCTTT GCCCTTTCGGGGAGGTCTTTAATGCAACTAGATTCGCATCAGTCTA TGCGTGGAACCGCAAACGCATTTCCAATTGTGTCGCAGACTACTCA GTGCTGTACAACTCTGCCTCTTTCAGTACGTTCAAGTGTTACGGAG TGTCACCCACTAAACTGAACGACCTGTGCTTTACAAATGTCTACGC TGACTCCTTCGTGATTAGGGGAGACGAGGTGAGACAAATTGCCCC CGGACAGACTGGGAAGATTGCCGACTACAATTATAAGCTTCCTGA TGATTTCACTGGCTGTGTTATTGCCTGGAATAGTAACAATCTGGAT AGCAAGGTGGGAGGCAACTATAACTACTTATATCGACTGTTTAGG AAGAGTAATCTGAAACCATTIGAGCGGGATATTTCCACAGAAATT TACCAGGCCGGGAGCACACCATGTAATGGGGTGGAGGGATTTAAT TGTTACTTCCCACTCCAGAGCTATGGTTTCCAACCCACCAATGGAG TGGGTTACCAGCCCTATAGAGTCGTGGTGCTTAGTTTTGAGCTGCT TCACGCCCCAGCAACCGTCTGCGGTCCCAAAAAGTCGACCAATCT CGTGAAAAACAAATGCGTAAACTTCAACTTTAACGGCTTAACAGG AACCGGCGTGCTCACCGAAAGCAACAAGAAATTCCTTCCATTTCA GCAATTCGGAAGGGACATCGCCGACACAACAGACGCGGTGAGGG ACCCACAGACTCTGGAGATACTGGACATCACTCCTTGTTCGTTTGG GGGCGTCTCGGTCATCACACCCGGGACTAATACTAGTAATCAGGT AGCAGTTTTATATCAAGGCGTCAACTGTACCGAAGTACCTGTGGCC ATACACGCTGATCAGCTAACGCCAACATGGCGAGTCTATTCCACC GGCTCTAACGTTTTTCAGACCAGGGCTGGGTGCCTGATAGGGGCA GAGCACGTCAATAATTCCTATGAGTGTGATATCCCCATAGGTGCGG GGATCTGTGCCAGCTATCAAACCCAAACCAATTCACCAAGGCGAG CACGGTCTGTGGCTTCTCAGAGCATAATTGCATATACAATGTCACT GGGCGCTGAGAATAGCGTTGCATACTCTAATAACAGCATAGCCAT TCCCACGAACTTTACTATCAGTGTGACAACCGAAATATTGCCAGTT TCGATGACCAAAACTAGCGTGGATTGCACGATGTACATCTGTGGA GACTCTACCGAATGCAGCAATCTGCTATTACAATATGGCAGCTTCT GTACACAGTTAAATCGAGCCTTGACAGGCATCGCAGTGGAACAGG ACAAAAATACTCAAGAGGTGTTTGCACAGGTGAAGCAAATCTACA AAACGCCCCCCATTAAAGATTTTGGCGGGTTCAATTTTTCACAAAT TCTCCCCGACCCGTCTAAGCCGAGTAAGCGGTCCTTCATCGAAGAT CTGCTCTTTAACAAAGTAACCCTCGCCGATGCCGGCTTTATTAAGC AGTATGGCGACTGCCTGGGGGATATAGCCGCTCGTGACCTGATTTG CGCCCAGAAGTTCAATGGTCTGACCGTGTTGCCTCCTTTATTGACC GATGAAATGATTGCCCAGTACACTAGTGCCCTGCTGGCCGGCACT ATCACGTCTGGGTGGACCTTCGGAGCTGGTGCCGCCTTGCAGATAC CTTTTGCAATGCAGATGGCCTATAGGTTTAATGGTATCGGAGTGAC TCAGAACGTACTGTACGAGAACCAGAAGCTCATCGCTAATCAATT TAACTCCGCTATCGGAAAAATCCAGGACAGCCTCTCTTCTACAGCT AGCGCTCTGGGCAAACTGCAGGATGTCGTTAATCAGAATGCCCAG GCCCTGAACACCTTGGTTAAACAACTATCTTCCAACTTCGGGGCCA TATCCAGTGTGTTGAATGATATTCTCTCCCGCTTGGATAAGGTGGA AGCTGAGGTGCAGATCGATCGCTTGATCACCGGCAGACTGCAGTC CCTCCAGACATATGTAACTCAGCAGCTGATTAGAGCCGCCGAGAT AAGGGCAAGTGCGAATCTGGCTGCCACCAAGATGAGCGAATGTGT ATTGGGCCAGAGCAAACGAGTTGATTTTTGCGGTAAGGGGTATCA TTTAATGTCTTTCCCTCAATCCGCACCTCATGGCGTAGTTTTCCTGC ATGTGACTTATGTCCCGGCTCAGGAGAAGAATTTTACCACAGCCCC CGCGATCTGCCATGACGGAAAGGCCCACTTCCCCCGGGAAGGCGT GTTTGTATCCAATGGGACTCACTGGTTTGTCACTCAGCGAAATTTT TATGAACCACAGATCATCACCACTGACAACACATTTGTTAGTGGA AACTGCGATGTGGTCATCGGCATCGTGAATAACACTGTCTATGATC CACTGCAACCTGAACTGGATTCTTTTAAAGAGGAACTCGACAAGT ATTTTAAAAACCACACTAGCCCTGACGTGGATCTCGGTGACATTTC TGGCATCAACGCTAGCGTAGTGAACATTCAGAAAGAGATAGATAG ACTTAATGAGGTGGCCAAGAACCTCAACGAAAGTCTGATCGACCT CCAGGAACTGGGGAAATACGAGCAGTACATTAAATGGCCTTGGTA CATATGGCTGGGGTTCATTGCTGGGCTGATCGCAATAGTGATGGTG ACCATAATGCTCTGTTGCATGACTAGCTGCTGCAGCTGCCTGAAGG GCTGCTGTAGTTGTGGGTCATGTTGTAAGTTTGACGAAGATGATAG CGAGCCTGTCCTTAAAGGAGTGAAGCTCCACTACACCTAG Spike CT20 See Sequence Listing 80 Optimized Spike CT56 See Sequence Listing 81 Optimized Spike CT83 See Sequence Listing 82 Optimized Spike CT131 See Sequence Listing 83 Optimized Spike CT199 See Sequence Listing 84 Optimized Spike CT1-2C ATGTTTGTCTTCCTGGTCTTGCTGCCGCTcGTGtctAGCCAGTGCGTG 85 AATCTCACCACCCGCACCCAGCTTCCACCTGCCTACACTAACAGCT TCACCCGAGGGGTGTATTACCCTGACAAGGTATTCCGGTCCTCCGT CCTCCATAGCACGCAGGACCTTTTTCTGCCCTTCTTCTCAAATGTG ACATGGTTCCATGCCATTCACGTGAGCGGCACGAATGGAACGAAG CGCTTTGATAACCCCGTGCTGCCTTTCAATGACGGCGTCTACTTCG CCTCCACTGAAAAGTCAAACATCATCCGGGGCTGGATCTTTGGCAC CACTCTTGATTCAAAGACCCAGTCACTGCTGATTGTGAACAATGCT ACAAACGTGGTTATCAAaGTcTGcGAGTTTCAGTTCTGTAACGATCC ATTTTTGGGAGTGTACTACCACAAGAACAACAAGTCCTGGATGGA GTCTGAGTTCAGAGTGTATAGCTCTGCTAACAACTGCACCTTCGAG TACGTGTCCCAGCCTTTCCTTATGGACCTGGAAGGCAAACAGGGC AATTTCAAAAACCTGAGAGAGTTCGTGTTTAAGAACATTGACGGA TACTTCAAAATTTATTCTAAGCACACACCAATTAACTTAGTGCGGG ACCTACCCCAAGGCTTTAGCGCCCTAGAGCCCCTGGTTGACCTGCC CATTGGGATCAATATAACAAGGTTCCAAACTCTACTGGCTCTGCAT AGAAGTTATCTGACCCCAGGAGACAGCTCTAGTGGTTGGACCGCC GGCGCAGCAGCCTACTATGTCGGGTACTTACAGCCACGCACGTTCC TTCTGAAGTACAATGAGAACGGGACAATCACTGACGCAGTAGACT GTGCACTGGACCCGCTAAGCGAGACTAAGTGCACACTTAAATCCT TCACGGTGGAGAAAGGCATTTATCAGACCTCTAACTTCAGGGTGC AGCCAACAGAAAGCATTGTGCGATTCCCAAATATTACTAATCTTTG CCCTTTCGGGGAGGTCTTTAATGCAACTAGATTCGCATCAGTCTAT GCGTGGAACCGCAAACGCATTTCCAATTGTGTCGCAGACTACTCA GTGCTGTACAACTCTGCCTCTTTCAGTACGTTCAAGTGTTACGGAG TGTCACCCACTAAACTGAACGACCTGTGCTTTACAAATGTCTACGC TGACTCCTTCGTGATTAGGGGAGACGAGGTGAGACAAATTGCCCC CGGACAGACTGGGAAGATTGCCGACTACAATTATAAGCTTCCTGA TGATTTCACTGGCTGTGTTATTGCCTGGAATAGTAACAATCTGGAT AGCAAGGTGGGAGGCAACTATAACTACTTATATCGACTGTTTAGG AAGAGTAATCTGAAACCATTIGAGCGGGATATTTCCACAGAAATT TACCAGGCCGGGAGCACACCATGTAATGGGGTGGAGGGATTTAAT TGTTACTTCCCACTCCAGAGCTATGGTTTCCAACCCACCAATGGAG TGGGTTACCAGCCCTATAGAGTCGTGGTGCTTAGTTTTGAGCTGCT TCACGCCCCAGCAACCGTCTGCGGTCCCAAAAAGTCGACCAATCT CGTGAAAAACAAATGCGTAAACTTCAACTTTAACGGCTTAACAGG AACCGGCGTGCTCACCGAAAGCAACAAGAAATTCCTTCCATTTCA GCAATTCGGAAGGGACATCGCCGACACAACAGACGCcGTcAGGGA CCCACAGACTCTGGAGATACTGGACATCACTCCTTGTTCGTTTGGG GGCGTCTCGGTCATCACACCCGGGACTAATACTAGTAATCAGGTA GCAGTTTTATATCAAGGCGTCAACTGTACCGAAGTACCTGTGGCCA TACACGCTGATCAGCTAACGCCAACATGGCGAGTCTATTCCACCG GCTCTAACGTTTTTCAGACCAGGGCTGGGTGCCTGATAGGGGCAG AGCACGTCAATAATTCCTATGAGTGTGATATCCCCATAGGTGCGGG GATCTGTGCCAGCTATCAAACCCAAACCAATTCACCAAGGCGAGC ACGGTCTGTGGCTTCTCAGAGCATAATTGCATATACAATGTCACTG GGCGCTGAGAATAGCGTTGCATACTCTAATAACAGCATAGCCATT CCCACGAACTTTACTATCAGTGTGACAACCGAAATATTGCCAGTTT CGATGACCAAAACTAGCGTGGATTGCACGATGTACATCTGTGGAG ACTCTACCGAATGCAGCAATCTGCTATTACAATATGGCAGCTTCTG TACACAGTTAAATCGAGCCTTGACAGGCATCGCAGTGGAACAGGA CAAAAATACTCAAGAGGTGTTTGCACAGGTGAAGCAAATCTACAA AACGCCCCCCATTAAAGATTTTGGCGGGTTCAATTTTTCACAAATT CTCCCCGACCCGTCTAAGCCGAGTAAGCGGTCCTTCATCGAAGATC TGCTCTTTAACAAAGTAACCCTCGCCGATGCCGGCTTTATTAAGCA GTATGGCGACTGCCTGGGGGATATAGCCGCTCGTGACCTGATTTGC GCCCAGAAGTTCAATGGTCTGACCGTGTTGCCTCCTTTATTGACCG ATGAAATGATTGCCCAGTACACTAGTGCCCTGCTGGCCGGCACTAT CACGTCTGGGTGGACCTTCGGAGCTGGTGCCGCCTTGCAGATACCT TTTGCAATGCAGATGGCCTATAGGTTTAATGGTATCGGAGTGACTC AGAACGTACTGTACGAGAACCAGAAGCTCATCGCTAATCAATTTA ACTCCGCTATCGGAAAAATCCAGGACAGCCTCTCTTCTACAGCTAG CGCTCTGGGCAAACTGCAGGATGTCGTTAATCAGAATGCCCAGGC CCTGAACACCTTGGTTAAACAACTATCTTCCAACTTCGGGGCCATA TCCAGTGTGTTGAATGATATTCTCTCCCGCTTGGATAAGGTGGAAG CTGAGGTGCAGATCGATCGCTTGATCACCGGCAGACTGCAGTCCCT CCAGACATATGTAACTCAGCAGCTGATTAGAGCCGCCGAGATAAG GGCAAGTGCGAATCTGGCTGCCACCAAGATGAGCGAATGTGTATT GGGCCAGAGCAAACGAGTTGATTTTTGCGGTAAGGGGTATCATTT AATGTCTTTCCCTCAATCCGCACCTCATGGCGTAGTTTTCCTGCATG TGACTTATGTCCCGGCTCAGGAGAAGAATTTTACCACAGCCCCCGC GATCTGCCATGACGGAAAGGCCCACTTCCCCCGGGAAGGCGTGTT TGTATCCAATGGGACTCACTGGTTTGTCACTCAGCGAAATTTTTAT GAACCACAGATCATCACCACTGACAACACATTTGTTAGTGGAAAC TGCGATGTGGTCATCGGCATCGTGAATAACACTGTCTATGATCCAC TGCAACCTGAACTGGATTCTTTTAAAGAGGAACTCGACAAGTATTT TAAAAACCACACTAGCCCTGACGTGGATCTCGGTGACATTTCTGGC ATCAACGCTAGCGTAGTGAACATTCAGAAAGAGATAGATAGACTT AATGAGGTGGCCAAGAACCTCAACGAAAGTCTGATCGACCTCCAG GAACTGGGGAAATACGAGCAGTACATTAAATGGCCTTGGTACATA TGGCTGGGGTTCATTGCTGGGCTGATCGCAATAGTGATGGTGACCA TAATGCTCTGTTGCATGACTAGCTGCTGCAGCTGCCTGAAGGGCTG CTGTAGTTGTGGGTCATGTTGTAAGTTTGACGAAGATGATAGCGAG CCTGTCCTTAAAGGAGTGAAGCTCCACTACACCTAG Spike IDT-4C See Sequence Listing 86 Spike-SGI See Sequence Listing 87

Cloning of Sequence-Optimized Spike Sequences

[0650] Each sequence-optimized Spike sequence was ordered as a set of 3 gBlocks from IDT with each gblock between 1300-1500 bp and overlapping with each other by approximately 100 nucleotides. The gBlocks comprising the 5′ and 3′ ends of the Spike sequence overlapped with the plasmid backbone by 100 nucleotides. The gblocks were assembled by a combination of PCR and Gibson assembly into a linearized pA68-E4d AsisIPmeI backbone to generate pA68-E4-sequence-optimized Spike clones. Clones were screened by PCR and clones of the correct size were then grown for plasmid production and sequencing by either NGS or Sanger sequencing. Once a correct clone was sequence confirmed, large scale plasmid production and purification was performed for transfection.

Vector Production

[0651] pA68-E4-Spike plasmid DNA was digested with PacI and 2 ug DNA was transfected into 293F cells using TransIt Lenti transfection reagent. Five days post transfection, cells and media were harvested and a lysate generated by freeze-thawing at −80C and at 37 C. A fraction of the lysate was used to re-infect 30 mL of 293F cells and incubated for 48-72h before harvesting. Lysate was generated by freeze-thawing at −80C and at 37 C and a fraction of the lysate was used to infect 400 mL of 293F cells seeded at 1e6 cells/mL. Next, 48-72h later cells were harvested, lysed in 10 mM tris pH 8.0/0.1% Triton X-100 and freeze thawed 1× at 37 and −80 C. The lysate was then clarified by centrifugation at 4300×g for 10 min prior to loading on a 1.2/1.4 CsCl gradient. The gradient was run for a minimum of 2h before the bands were harvested diluted 2-4× in Tris and then rerun on a 1.35 CsCl gradient for at least 2h. The viral bands were harvested and then dialyzed 3× in 1× ARM buffer. The virus infectious titer was determined by an immunostaining titer assay and the viral particle measured by Absorbance at A260 nm.

Western Analysis

[0652] Samples for Spike expression analysis were either harvested at designated times post transfection or in the case of purified virus by setting up a controlled infection experiment with a known virus MOI and harvested at a specific time post infection, typically 24 to 48h. 1e6 cells were typically harvested in 0.5 mL of SDS-PAGE loading buffer with 10% Beta-mercaptoethanol. Samples were boiled and run on 4-20% polyacrylamide gels under denaturing and reducing conditions. The gels were then blotted onto a PVDF membrane using a BioRad Rapid transfer device. The membrane was blocked for 2h at room temperature in 5% Skim milk in TBST. The membrane was then probed with an anti-Spike S1 polyclonal (Sino Biologicals) or anti-Spike monoclonal antibody 1A9 (GeneTex; Cat. No. GTX632604) and incubated for 2h. The membrane was then washed in PBST (5×) and the probed with a HRP-linked anti-mouse antibody (Bethyl labs) for 1h. The membrane was washed as described above and then incubated with a chemiluminescent substrate ECL plus (ThermoFisher). The image was then captured using a Chemidoc (BioRad device).

Results

[0653] Expression of Spike S2 protein was assessed during viral production in 293F cells with various Spike-encoding vectors. As shown in FIG. 10A, using vectors encoding IDT sequence-optimized Spike cassettes, Spike S2 protein was detected by Western blot using an anti-Spike S2 antibody (GeneTex) when expressed in a SAM vector (FIG. 10A, last lane) but not when expressed in a ChAdV68 vector (“CMV-Spike (IDT)”; SEQ ID NO:69) at two different MOIs and timepoints (FIG. 10A, lanes 1 and 7). Two clones engineered to express Spike variant D614G (“CMV-Spike (IDT)-D614G” SEQ ID NO:70) also did not express detectable levels of Spike protein by Western using the S2 antibody (FIG. 10A, lanes 2 and 3). Clones engineered to co-express the SARS-CoV-2 Membrane protein together with Spike (“CMV-Spike (IDT)-D614G-Mem” SEQ ID NO:66) or including a R682V mutations to disrupt the Furin cleavage site did not rescue the expression phenotype (FIG. 10A, lanes 4 and 5). In contrast, as shown in FIG. 10B, Spike S1 protein was detected for all IDT constructs, albeit at low levels, with the exception of the Furin R682V mutation in which no Spike S1 protein was detected.

[0654] To deconvolute if the expressions issues with the IDT sequence-optimized clones were specific to the S1 or S2 domains, vectors expressing only the S1 or S2 domains were also evaluated. As shown in FIG. 10C, a ChAdV68 vector encoding the IDT sequence-optimized Spike S1 protein alone demonstrated strong protein expression, in contrast to the lower expression observed with the full-length Spike vector (FIG. 10C, lanes 1 vs 2). As expected, no signal was observed for S1 with the vector encoding the S2 domain alone. In contrast, as shown in FIG. 10D, a ChAdV68 vector encoding the IDT sequence-optimized Spike S2 protein alone did not demonstrate observable protein expression, comparable to the absence of signal observed with the full-length Spike vector (FIG. 10D, lanes 1 and 3). Thus, the data indicate the IDT sequence-optimized Spike S2 exhibited poor expression, including impacting expression of the full-length Spike sequence.

[0655] To address protein expression, the SARS-CoV-2 Spike-encoding nucleotide sequence was sequence-optimized using additional sequence-optimization algorithms; (1) a single sequence (SEQ ID NO:87) generated using SGI DNA (La Jolla, CA); (2) 6 sequences designated CT1, CT20, CT56, CT83, CT131, and CT 199 (SEQ ID NOs:79-84) generated using COOL (COOL algorithm generates multiple sequences and 6 were selected). As shown in FIG. 10A and FIG. 10B, sequence-optimization with the COOL algorithm generated a sequence—CT1 (SEQ ID NO:79)—that demonstrated detectable expression using a ChAdV68 vector as assessed by Western using both an anti-S2 and anti-S1 antibody (FIG. 10A and FIG. 10B, each respective lane 6 “ChAd-Spike CT1-D614G”). The additional sequences generated using the COOL algorithm and the SGI algorithm were also assessed by Western. As shown in FIG. 11, the SGI clone and COOL sequence CT131 also demonstrated detectable levels of Spike protein by Western using an anti-S2 antibody (FIG. 11, lanes 3 and 6), while other COOL generated sequences did not generate detectable signals other than the control CT1 derived sequence (lane 2). Thus, the data indicate that specific sequence-optimizations improved expression of full-length SARS-CoV-2 Spike protein in ChAdV68 vectors.

[0656] SARS-CoV-2 is a cytoplasm-replicating positive-sense RNA virus encoding its own replication machinery, and as such SARS-CoV-2 mRNA are not naturally processed by splicing and nuclear-export machineries. As illustrated in FIG. 12A, to assess the role of splicing in SARS-CoV-2 Spike-encoding mRNA expressed from a ChAdV68 vector, primers were designed to amplify the Spike coding region. In the presence of mRNA splicing, amplicon sizes would be smaller than the expected full-length coding region. As shown in FIG. 12B, while PCR of the plasmid encoding the SARS-CoV-2 Spike cassette demonstrated the expected amplicon size (“Spike Plasmid” left panel, right column), PCR amplification of cDNA from infected 293 cells demonstrated two smaller amplicons indicating splicing of the mRNA transcript (“ChAd-Spike (IDT) cDNA” left panel, left column). In addition, the Spike coding sequence was split into S1 and S2 encoding sequences. As also shown in FIG. 12B, PCR amplification of S1 cDNA from infected 293 cells demonstrated the expected amplicon size (“SpikeS1” right panel, left column) indicating S1 was likely not undergoing undesired splicing while sequences in the S2 region may be influencing splicing.

[0657] The smaller amplicon sequences were analyzed and two splice donor sites were identified by Sanger sequencing. Three additional potential donor sites were predicted by further sequence analysis. The position and identity of the splice motif sequences are presented below (the nt triplets correspond to codons, numbering starts with reference to Spike ATG):

TABLE-US-00011 NT 385-:  AAG GTG TGT .fwdarw. AAa GTc TGc (identified by sequencing) NT 539-:  AA GGT AAG C .fwdarw. Ag GGc AAa C (identified by sequencing) NT 2003-:  CA GGT ATC T .fwdarw. Ct GGa ATC T (predicted) NT 2473-:  AAG GTG ACC .fwdarw. AAa GTc ACC (predicted) NT 3417-:  C CCC CTT CAG CCT GAA CTT GAT TCC (SEQ ID NO: 123) .fwdarw. T CCa CTg CAa CCT GAA CTT GAT agt (SEQ ID NO: 124)

[0658] Selected splice donor sites were removed by site-directed mutagenesis disrupting the nucleotide sequence motif while not disturbing the amino acid sequence. COOL sequence-optimized clone CT1 was used as the reference sequence for clone CT1-2C (SEQ ID NO:85) having the sequence-identified splice donor motifs at NT385 and NT539 mutated. IDT sequence-optimized clone was used as the reference sequence for clone IDT-4C (SEQ ID NO:86) and had both sequence-identified and predicted splice donor motifs at NT385, NT539, NT2003, and NT2473 mutated, as well as a possible polyadenylation site AATAAA at NT445 mutated to AAcAAA. As shown in FIG. 11, Spike protein expression was detected by Western in the clone including the sequence-identified splice donor motifs (“CT1-2C” lane 2). Splicing was further assessed in the constructs by PCR analysis. As shown in FIG. 13, mutating the splice donor motifs and/or a potential polyA site alone did not prevent splicing indicating splicing potentially occurred from sub-dominant splice sites.

[0659] Given the identification of splicing events in the full-length Spike mRNA expressed from ChAdV68 vectors, additional constructs are generated and assessed for improved protein expression. Additional optimizations include constructs featuring exogenous nuclear export signals (e.g., Constitutive Transport Element (CTE), RNA Transport Element (RTE), or Woodchuck Posttranscriptional Regulatory Element (WPRE)) or the addition of an artificial intron through introduction of exogenous splice donor/branch/acceptor motif sequences to bias splicing, such as introducing a SV40 mini-intron (SEQ ID NO:88) between the CMV promoter and the Kozak sequence immediately upstream of the Spike gene. The identified and predicted splice donor motifs are also further evaluated in combination with additional sequence optimizations.

[0660] XIV.G. SARS-CoV-2 Vaccine Efficacy Evaluation

[0661] Various SARS-CoV-2 vaccine designs, constructs, and dosing regimens were evaluated. The vaccines encoded various optimized versions of the Spike protein, selected predicted T cell epitopes (TCE), or a combination of Spike and TCE cassettes.

Mouse Immunizations

[0662] All mouse studies were conducted at Murigenics under IACUC approved protocols. Balb/c mice (Envigo), 6-8 weeks old were used for all studies. Vaccines were stored at −80° C., thawed at room temperature on the day of immunization, and then diluted to 0.1 μg/mL with PBS and filtered through a 0.2 micron filter. Filtered formulations were stored at 4° C. and injected within 4 hours of preparation. All immunizations were bilateral intramuscular to the tibialis anterior, 2 injections of 50 μL each, 100 μL total.

Non-Human Primate Immunizations

[0663] For SAM vaccines in Mamu-A*01 Indian rhesus macaques, SAM was administered as bilateral intramuscular injections into the quadriceps muscle at the indicated doses.

[0664] For ChAdV68 vaccines in Mamu-A*01 Indian rhesus macaques, ChAdV68 was administered bilaterally at the indicated doses (5×10.sup.11 viral particles per injection).

Immune Monitoring in Rhesus

[0665] For immune monitoring, 10-20 mL of blood was collected into vacutainer tubes containing heparin and maintained at room temperature until isolation. PBMCs were isolated by density gradient centrifugation using lymphocyte separation medium (LSM) and Leucosep separator tubes. PBMCs were stained with propidium iodide and viable cells counted using the Cytoflex LX (Beckman Coulter). Samples were then resuspended at 4×10.sup.6 cells/mL in RPMI complete (10% FBS).

Splenocyte Isolation

[0666] For the evaluation of T-cell response, mouse spleens were extracted at various timepoints following immunization. Note that in some studies immunizations were staggered to enable spleens to be collected at the same time and compared. Spleens were collected and analyzed by IFNγ ELISpot and ICS. Spleens were suspended in RPMI complete (RPMI+10% FBS) and dissociated using the gentleMACS Dissociator (Miltenyi Biotec). Dissociated cells were filtered using a 40 μm strainer and red blood cells were lysed with ACK lysing buffer (150 mM NH.sub.4Cl, 10 mM KHCO.sub.3, 0.1 mM EDTA). Following lysis, cells were filtered with a 30 μm strainer and resuspended in RPMI complete.

Serum Collection in Mice

[0667] At various timepoints post immunization 200 μL of blood was drawn. Blood was centrifuged at 1000 g for 10 minutes at room temperature. Serum was collected and frozen at −80° C.

S1 IgG MSD/ELISA

[0668] 96-well QuickPlex plates (Meso Scale Discovery, Rockville, MD) were coated with 50 μL of 1 μg/mL SARS-CoV-2 S1 (ACROBiosystems, Newark, DE), diluted in DPBS (Corning, Corning, NY), and incubated at 4° C. overnight. Wells were washed three times with agitation using 250 μL of PBS+0.05% Tween-20 (Teknova, Hollister, CA) and plates blocked with 150 μL Superblock PBS (Thermo Fisher Scientific, Waltham, MA) for 1 hour at room temperature on an orbital shaker. Test sera was diluted at appropriate series in 10% species-matched serum (Innovative Research, Novi, MI) and tested in single wells on each plate. Starting dilution 1:100, 3-fold dilutions, 11 dilutions per sample. Wells were washed and 50 uL of the diluted samples were added to wells and incubated for 1 hour at room temperature on an orbital shaker. Wells were washed and incubated with 25 μL of 1 μg/mL SULFO-TAG labeled anti-mouse antibody (MSD), diluted in DPBS+1% BSA (Sigma-Aldrich, St. Louis, MO), for 1 hour at room temperature on an orbital shaker. Wells were washed and 150 μL tripropylamine containing read buffer (MSD) added. Plates were run immediately using the QPlex SQ 120 (MSD) ECL plate reader. Endpoint titer is defined as the reciprocal dilution for each sample at which the signal is twice the background value, and is interpolated by fitting a line between the final two values that are greater than twice the background value. The background values is the average value (calculated for each plate) of the control wells containing 10% species-matched serum only.

Antibody Titers

[0669] For antibody response monitoring, antibody titers, including neutralizing antibody titers, in the sera were determined as described in J. Yu et al. (Science 10.1126/science. Abc6284, 2020), herein incorporated by reference for all purposes.

IFNγ ELISpot Analysis

[0670] IFNγ ELISpot assays were performed using pre-coated 96-well plates (MAbtech, Mouse IFNγ ELISpot PLUS, ALP) following manufacturer's protocol. Samples were stimulated overnight with various overlapping peptide pools (15 amino acids in length, 11 amino acid overlap), at a final concentration of 1 μg/mL per peptide. For Spike—eight different overlapping peptide pools spanning the SARS-CoV-2 Spike antigen (Genscript, 36-40 peptides per pool). Splenocytes were plated in duplicate at 1×10.sup.5 cells per well for each Spike pool, and 2.5×10.sup.4 cells per well (mixed with 7.5×10.sup.4 naïve cells) for Spike pools 2, 4, and 7. To measure response to the TCE cassette—one pool spanning Nucleocapsid protein (JPT, NCap-1, 102 peptides), one spanning Membrane protein (JPT, VME-1, 53 peptides), and one spanning the Orf3a regions encoded in the cassette (Genscript, 38 peptides). For TCE peptide pools, splenocytes were plated in duplicate at 2×10.sup.5 cells per well for each pool. Sequences for peptide pools are presented in Table D (SEQ ID NOS. 27180-27495), Table E (SEQ ID NOS. 27496-27603), and Table F (SEQ ID NOS. 27604-27939). A DMSO only control was plated for each sample and cell number. Following overnight incubation at 37° C., plates were washed with PBS and incubated with anti-monkey IFNγ mAb biotin (MAbtech) for two hours, followed by an additional wash and incubation with Streptavidin-ALP (MAbtech) for one hour. After final wash, plates were incubated for ten minutes with BCIP/NBT (MAbtech) to develop the immunospots. Spots were imaged and enumerated using an AID reader (Autoimmun Diagnostika). For data processing and analysis, samples with replicate well variability (Variability=Variance/(median+1)) greater than 10 and median greater than 10 were excluded. Spot values were adjusted based on the well saturation according to the formula:

AdjustedSpots=RawSpots+2*(RawSpots*Saturation/(100−Saturation)

Each sample was background corrected by subtracting the average value of the negative control peptide wells. Data is presented as spot forming colonies (SFC) per 1×10.sup.6 splenocytes. Wells with well saturation values greater than 35% were labeled as “too numerous to count” (TNTC) and excluded. For samples and peptides that were TNTC, the value measured with 2.5×10.sup.4 cells/well was used.

Vaccine Constructs

[0671] The various sequences evaluated are as follows: [0672] “IDTSpike.sub.g”: SARS-CoV-2 Spike protein encoded by IDT optimized sequence (see SEQ ID NO:69) and including a D614G mutation with reference to SEQ ID NO:59 (see corresponding nucleotide mutation in SEQ ID NO:70); also referred to as “Spike VI” [0673] “CTSpike.sub.g”: SARS-CoV-2 Spike protein encoded by Cool Tool optimized sequence version 1 (SEQ ID NO:79) including a D614G mutation with reference to SEQ ID NO:59 (see corresponding nucleotide mutation in SEQ ID NO:70); also referred to as “Spike V2.” In versions referred to as “CTSpike.sub.D” D614 is not altered. [0674] “CTSpikeF2P.sub.g”: SARS-CoV-2 Spike protein encoded by Cool Tool optimized sequence version 1 (SEQ ID NO:79) including a R682V to disrupt the Furin cleavage site (682-685 RRAR [SEQ ID NO: 125] to GSAS [SEQ ID NO: 126]); and K986P and V987P to interfere with the secondary structure of Spike with reference to the reference Spike protein (SEQ ID NO:59). The nucleotide sequence is shown in SEQ ID NO:89 and protein sequnce shown in SEQ ID NO:90 [0675] “TCE5”: Selected CD8+ epitopes predicted by the EDGE platform to be presented on MHC molecules for SARS-CoV-2 proteins other than Spike. The 15 selected epitopes are presented along with their order in the cassette in Table 10. The nucleotide sequence is shown in SEQ ID NO:91 and protein sequence shown in SEQ ID NO:92. FIG. 14 shows the estimated protection across the four indicated populations for TCE5. All populations are estimated to have coverage above 95% up to at least the threshold of 7 epitopes (last column). [0676] The SAM vector SAM-SGP1-TCE5-SGP2-CTSpike.sub.GF2P is shown in SEQ ID NO:93 [0677] The ChAd vector ChAd-CMV-CTSpikeGF2P-CMV-TCE5 (EPE) is shown in SEQ ID NO:114 [0678] Additional vectors and Spike variants were designed for evaluation as shown in SEQ ID NOs:109-113

TABLE-US-00012 TABLE 9 Encoded Spike Variants CTSpikeF2Pg nucleotide (SEQ ID NO: 89); Bold Italic Furin Mutation 682-685 RRAR (SEQ ID NO: 125) to GSAS (SEQ ID NO: 126), Bold Lower Case K986P and V987P ATGTTTGTCTTCCTGGTCTTGCTGCCGCTGGTGAGCAGCCAGTGCGTGAATCTCACCACCCGCACCCA GCTTCCACCTGCCTACACTAACAGCTTCACCCGAGGGGTGTATTACCCTGACAAGGTATTCCGGTCCT CCGTCCTCCATAGCACGCAGGACCTTTTTCTGCCCTTCTTCTCAAATGTGACATGGTTCCATGCCATTC ACGTGAGCGGCACGAATGGAACGAAGCGCTTTGATAACCCCGTGCTGCCTTTCAATGACGGCGTCTA CTTCGCCTCCACTGAAAAGTCAAACATCATCCGGGGCTGGATCTTTGGCACCACTCTTGATTCAAAGA CCCAGTCACTGCTGATTGTGAACAATGCTACAAACGTGGTTATCAAGGTGTGTGAGTTTCAGTTCTGT AACGATCCATTTTTGGGAGTGTACTACCACAAGAACAACAAGTCCTGGATGGAGTCTGAGTTCAGAG TGTATAGCTCTGCTAACAACTGCACCTTCGAGTACGTGTCCCAGCCTTTCCTTATGGACCTGGAAGGC AAACAGGGCAATTTCAAAAACCTGAGAGAGTTCGTGTTTAAGAACATTGACGGATACTTCAAAATTT ATTCTAAGCACACACCAATTAACTTAGTGCGGGACCTACCCCAAGGCTTTAGCGCCCTAGAGCCCCT GGTTGACCTGCCCATTGGGATCAATATAACAAGGTTCCAAACTCTACTGGCTCTGCATAGAAGTTATC TGACCCCAGGAGACAGCTCTAGTGGTTGGACCGCCGGCGCAGCAGCCTACTATGTCGGGTACTTACA GCCACGCACGTTCCTTCTGAAGTACAATGAGAACGGGACAATCACTGACGCAGTAGACTGTGCACTG GACCCGCTAAGCGAGACTAAGTGCACACTTAAATCCTTCACGGTGGAGAAAGGCATTTATCAGACCT CTAACTTCAGGGTGCAGCCAACAGAAAGCATTGTGCGATTCCCAAATATTACTAATCTTTGCCCTTTC GGGGAGGTCTTTAATGCAACTAGATTCGCATCAGTCTATGCGTGGAACCGCAAACGCATTTCCAATT GTGTCGCAGACTACTCAGTGCTGTACAACTCTGCCTCTTTCAGTACGTTCAAGTGTTACGGAGTGTCA CCCACTAAACTGAACGACCTGTGCTTTACAAATGTCTACGCTGACTCCTTCGTGATTAGGGGAGACG AGGTGAGACAAATTGCCCCCGGACAGACTGGGAAGATTGCCGACTACAATTATAAGCTTCCTGATGA TTTCACTGGCTGTGTTATTGCCTGGAATAGTAACAATCTGGATAGCAAGGTGGGAGGCAACTATAAC TACTTATATCGACTGTTTAGGAAGAGTAATCTGAAACCATTTGAGCGGGATATTTCCACAGAAATTTA CCAGGCCGGGAGCACACCATGTAATGGGGTGGAGGGATTTAATTGTTACTTCCCACTCCAGAGCTAT GGTTTCCAACCCACCAATGGAGTGGGTTACCAGCCCTATAGAGTCGTGGTGCTTAGTTTTGAGCTGCT TCACGCCCCAGCAACCGTCTGCGGTCCCAAAAAGTCGACCAATCTCGTGAAAAACAAATGCGTAAAC TTCAACTTTAACGGCTTAACAGGAACCGGCGTGCTCACCGAAAGCAACAAGAAATTCCTTCCATTTC AGCAATTCGGAAGGGACATCGCCGACACAACAGACGCGGTGAGGGACCCACAGACTCTGGAGATAC TGGACATCACTCCTTGTTCGTTTGGGGGCGTCTCGGTCATCACACCCGGGACTAATACTAGTAATCAG GTAGCAGTTTTATATCAAGGCGTCAACTGTACCGAAGTACCTGTGGCCATACACGCTGATCAGCTAA CGCCAACATGGCGAGTCTATTCCACCGGCTCTAACGTTTTTCAGACCAGGGCTGGGTGCCTGATAGG GGCAGAGCACGTCAATAATTCCTATGAGTGTGATATCCCCATAGGTGCGGGGATCTGTGCCAGCTAT CAAACCCAAACCAATTCACCA TCTGTGGCTTCTCAGAGCATAATTGCATATACAATG TCACTGGGCGCTGAGAATAGCGTTGCATACTCTAATAACAGCATAGCCATTCCCACGAACTTTACTAT CAGTGTGACAACCGAAATATTGCCAGTTTCGATGACCAAAACTAGCGTGGATTGCACGATGTACATC TGTGGAGACTCTACCGAATGCAGCAATCTGCTATTACAATATGGCAGCTTCTGTACACAGTTAAATCG AGCCTTGACAGGCATCGCAGTGGAACAGGACAAAAATACTCAAGAGGTGTTTGCACAGGTGAAGCA AATCTACAAAACGCCCCCCATTAAAGATTTTGGCGGGTTCAATTTTTCACAAATTCTCCCCGACCCGT CTAAGCCGAGTAAGCGGTCCTTCATCGAAGATCTGCTCTTTAACAAAGTAACCCTCGCCGATGCCGG CTTTATTAAGCAGTATGGCGACTGCCTGGGGGATATAGCCGCTCGTGACCTGATTTGCGCCCAGAAG TTCAATGGTCTGACCGTGTTGCCTCCTTTATTGACCGATGAAATGATTGCCCAGTACACTAGTGCCCT GCTGGCCGGCACTATCACGTCTGGGTGGACCTTCGGAGCTGGTGCCGCCTTGCAGATACCTTTTGCAA TGCAGATGGCCTATAGGTTTAATGGTATCGGAGTGACTCAGAACGTACTGTACGAGAACCAGAAGCT CATCGCTAATCAATTTAACTCCGCTATCGGAAAAATCCAGGACAGCCTCTCTTCTACAGCTAGCGCTC TGGGCAAACTGCAGGATGTCGTTAATCAGAATGCCCAGGCCCTGAACACCTTGGTTAAACAACTATC TTCCAACTTCGGGGCCATATCCAGTGTGTTGAATGATATTCTCTCCCGCTTGGATccacctGAAGCTGAG GTGCAGATCGATCGCTTGATCACCGGCAGACTGCAGTCCCTCCAGACATATGTAACTCAGCAGCTGA TTAGAGCCGCCGAGATAAGGGCAAGTGCGAATCTGGCTGCCACCAAGATGAGCGAATGTGTATTGG GCCAGAGCAAACGAGTTGATTTTTGCGGTAAGGGGTATCATTTAATGTCTTTCCCTCAATCCGCACCT CATGGCGTAGTTTTCCTGCATGTGACTTATGTCCCGGCTCAGGAGAAGAATTTTACCACAGCCCCCGC GATCTGCCATGACGGAAAGGCCCACTTCCCCCGGGAAGGCGTGTTTGTATCCAATGGGACTCACTGG TTTGTCACTCAGCGAAATTTTTATGAACCACAGATCATCACCACTGACAACACATTTGTTAGTGGAAA CTGCGATGTGGTCATCGGCATCGTGAATAACACTGTCTATGATCCACTGCAACCTGAACTGGATTCTT TTAAAGAGGAACTCGACAAGTATTTTAAAAACCACACTAGCCCTGACGTGGATCTCGGTGACATTTC TGGCATCAACGCTAGCGTAGTGAACATTCAGAAAGAGATAGATAGACTTAATGAGGTGGCCAAGAA CCTCAACGAAAGTCTGATCGACCTCCAGGAACTGGGGAAATACGAGCAGTACATTAAATGGCCTTGG TACATATGGCTGGGGTTCATTGCTGGGCTGATCGCAATAGTGATGGTGACCATAATGCTCTGTTGCAT GACTAGCTGCTGCAGCTGCCTGAAGGGCTGCTGTAGTTGTGGGTCATGTTGTAAGTTTGACGAAGAT GATAGCGAGCCTGTCCTTAAAGGAGTGAAGCTCCACTACACCTAG CTSpikeF2Pg amino acid (SEQ ID NO: 90); Bold Italic Furin Mutation 682-685 RRAR (SEQ ID NO: 125) to GSAS (SEQ ID NO: 126), Bold Lower Case K986P and V987P MFVFLVLLPLVSSQCVNLTTRTQLPPAYTNSFTRGVYYPDKVFRSSVLHSTQDLFLPFFSNVTWFHAIHVS GTNGTKRFDNPVLPFNDGVYFASTEKSNIIRGWIFGTTLDSKTQSLLIVNNATNVVIKVCEFQFCNDPFLGV YYHKNNKSWMESEFRVYSSANNCTFEYVSQPFLMDLEGKQGNFKNLREFVFKNIDGYFKIYSKHTPINLV RDLPQGFSALEPLVDLPIGINITRFQTLLALHRSYLTPGDSSSGWTAGAAAYYVGYLQPRTFLLKYNENGTI TDAVDCALDPLSETKCTLKSFTVEKGIYQTSNFRVQPTESIVRFPNITNLCPFGEVFNATRFASVYAWNRK RISNCVADYSVLYNSASFSTFKCYGVSPTKLNDLCFTNVYADSFVIRGDEVRQIAPGQTGKIADYNYKLPD DFTGCVIAWNSNNLDSKVGGNYNYLYRLFRKSNLKPFERDISTEIYQAGSTPCNGVEGFNCYFPLQSYGF QPTNGVGYQPYRVVVLSFELLHAPATVCGPKKSTNLVKNKCVNFNFNGLTGTGVLTESNKKFLPFQQFG RDIADTTDAVRDPQTLEILDITPCSFGGVSVITPGTNTSNQVAVLYQGVNCTEVPVAIHADQLTPTWRVYS TGSNVFQTRAGCLIGAEHVNNSYECDIPIGAGICASYQTQTNSP SVASQSIIAYTMSLGAENSVAYSN NSIAIPTNFTISVTTEILPVSMTKTSVDCTMYICGDSTECSNLLLQYGSFCTQLNRALTGIAVEQDKNTQEVF AQVKQIYKTPPIKDFGGFNFSQILPDPSKPSKRSFIEDLLFNKVTLADAGFIKQYGDCLGDIAARDLICAQKF NGLTVLPPLLTDEMIAQYTSALLAGTITSGWTFGAGAALQIPFAMQMAYRENGIGVTQNVLYENQKLIAN QFNSAIGKIQDSLSSTASALGKLQDVVNQNAQALNTLVKQLSSNFGAISSVLNDILSRLDppEAEVQIDRLI TGRLQSLQTYVTQQLIRAAEIRASANLAATKMSECVLGQSKRVDFCGKGYHLMSFPQSAPHGVVFLHVT YVPAQEKNFTTAPAICHDGKAHFPREGVFVSNGTHWFVTQRNFYEPQIITTDNTFVSGNCDVVIGIVNNTV YDPLQPELDSFKEELDKYFKNHTSPDVDLGDISGINASVVNIQKEIDRLNEVAKNLNESLIDLQELGKYEQ YIKWPWYIWLGFIAGLIAIVMVTIMLCCMTSCCSCLKGCCSCGSCCKFDEDDSEPVLKGVKLHYT*

TABLE-US-00013 TABLE 10 TCE5 Cassette (Order of Frames as Shown) Start End SEQ ID Frame Gene aa aa NO Amino Acid Sequence  1 ORF3a 102 152  94 EAPFLYLYALVYFLQSINFVRIIMRLWLCWKCRSKNPLLYDANYFLCW HTN  2 ORF3a  53  85  95 LAVFQSASKIITLKKRWQLALSKGVHFVCNLLL  3 ORF3a  13  55  96 VTLKQGEIKDATPSDFVRATATIPIQASLPFGWLIVGVALLAV  4 N  40  94  97 RRPQGLPNNTASWFTALTQHGKEDLKFPRGQGVPINTNSSPDDQIG YYRRATRRI  5 M  84 102  98 MACLVGLMWLSYFIASFRL  6 N 369 408  99 KKDKKKKADETQALPQRQKKQQTVTLLPAADLDDFSKQLQ  7 N 284 338 100 GNFGDQELIRQGTDYKHWPQIAQFAPSASAFFGMSRIGMEVTPSG TWLTYTGAIK  8 ORF3a 169 198 101 ITSGDGTTSPISEHDYQIGGYTEKWESGVK  9 N 233 282 102 KMSGKGQQQQGQTVTKKSAAEASKKPRQKRTATKAYNVTQAFGR RGPEQT 10 M  56  75 103 LLWPVTLACFVLAAVYRINW 11 N 346 375 104 FKDQVILLNKHIDAYKTFPPTEPKKDKKKK 12 N 205 239 105 TSPARMAGNGGDAALALLLLDRLNQLESKMSGKGQ 13 N 100 118 106 KMKDLSPRWYFYYLGTGPE 14 ORF3a 199 254 107 DCVVLHSYFTSDYYQLYSTQLSTDTGVEHVTFFIYNKIVDEPEEHVQIH TIDGSSG 15 N 129 174 108 GIIWVATEGALNTPKDHIGTRNPANNAAIVLQLPQGTTLPKGFYAE

TABLE-US-00014 TCE5 Nucleotide Sequence (SEQ ID NO: 91):  ATGGCTGGCGAGGCCCCCTTCCTTTACCTGTACGCCCTTGTGTATTTCC TGCAGAGCATCAATTTTGTGAGAATCATCATGAGGCTGTGGCTTTGCTG GAAATGTAGGAGCAAGAACCCCCTGTTGTATGACGCCAACTACTTTCTG TGTTGGCACACCAATCTCGCCGTGTTCCAGAGTGCCTCTAAGATCATTA CACTGAAAAAGCGGTGGCAGCTTGCACTTTCTAAGGGAGTGCATTTCGT TTGCAACCTGCTCCTGGTGACACTCAAGCAGGGGGAAATCAAAGACGCC ACCCCTAGCGACTTCGTTAGAGCCACTGCCACAATCCCAATCCAGGCTT CCCTGCCTTTCGGCTGGCTTATCGTGGGTGTGGCACTGTTGGCTGTGCG GAGACCACAGGGACTGCCTAATAATACAGCTAGCTGGTTTACCGCTCTG ACACAGCATGGCAAAGAAGACCTCAAGTTCCCTCGCGGTCAGGGGGTGC CTATTAACACTAATAGCTCTCCAGACGACCAAATTGGGTATTACAGGCG CGCCACAAGACGGATCATGGCCTGCTTAGTGGGGCTGATGTGGCTATCC TATTTTATTGCTAGCTTTCGCCTGAAGAAGGACAAGAAGAAGAAAGCTG ATGAGACCCAGGCACTGCCCCAGCGCCAAAAGAAGCAGCAGACAGTCAC ACTGCTCCCTGCTGCAGACCTGGATGACTTCAGCAAGCAGCTGCAGGGG AACTTTGGCGACCAGGAGCTGATTAGACAGGGGACTGACTATAAGCATT GGCCTCAGATTGCTCAGTTCGCCCCAAGTGCATCCGCCTTCTTCGGGAT GTCACGAATAGGAATGGAAGTGACCCCTTCTGGGACATGGTTGACATAC ACCGGAGCAATCAAGATTACCTCCGGGGACGGTACCACGTCTCCTATTA GCGAACACGATTATCAGATAGGGGGATATACTGAGAAGTGGGAGTCCGG CGTCAAAAAGATGAGTGGGAAAGGCCAGCAGCAACAAGGCCAAACAGTT ACTAAAAAGTCTGCCGCAGAAGCTAGTAAAAAGCCTCGCCAGAAGCGGA CAGCCACCAAAGCTTACAATGTGACTCAGGCCTTCGGCCGCCGGGGGCC TGAACAGACCCTCTTGTGGCCCGTTACCCTCGCATGTTTCGTGCTTGCA GCTGTGTACAGGATCAATTGGTTTAAGGATCAGGTTATCCTGTTGAACA AACATATAGATGCCTATAAGACATTCCCACCCACCGAGCCAAAGAAAGA TAAGAAAAAGAAAACTAGTCCTGCAAGGATGGCCGGCAATGGAGGAGAC GCAGCCTTAGCCCTGCTCTTACTCGACAGGCTGAACCAACTTGAGTCTA AAATGAGCGGTAAAGGGCAGAAGATGAAGGATCTGTCCCCAAGGTGGTA TTTCTACTATCTGGGCACCGGCCCTGAGGATTGTGTCGTCCTCCACTCA TACTTCACTAGCGATTATTACCAGCTGTATAGTACACAATTATCTACCG ACACAGGCGTCGAGCACGTGACCTTCTTTATATACAATAAGATCGTGGA TGAACCAGAGGAGCATGTGCAGATCCACACTATTGATGGCTCTAGCGGG GGCATCATCTGGGTGGCAACAGAAGGAGCCCTCAACACCCCAAAGGACC ATATCGGCACCAGGAATCCAGCCAACAATGCCGCCATTGTTCTGCAGCT CCCTCAGGGCACTACTCTCCCTAAAGGCTTCTATGCTGAGGGACCCGGA CCAGGCGCCAAATTTGTTGCTGCTTGGACACTGAAAGCTGCTGCTGGGC CCGGACCAGGCCAGTACATCAAGGCCAACTCTAAGTTTATCGGCATCAC CGAATTGGGACCTGGACCCGGCTAG TCE5 Amino Acid Sequence (SEQ ID NO: 92):  MAGEAPFLYLYALVYFLQSINFVRIIMRLWLCWKCRSKNPLLYDANYFL CWHTNLAVFQSASKIITLKKRWQLALSKGVHFVCNLLLVTLKQGEIKDA TPSDFVRATATIPIQASLPFGWLIVGVALLAVRRPQGLPNNTASWFTAL TQHGKEDLKFPRGQGVPINTNSSPDDQIGYYRRATRRIMACLVGLMWLS YFIASFRLKKDKKKKADETQALPQRQKKQQTVTLLPAADLDDESKQLQG NFGDQELIRQGTDYKHWPQIAQFAPSASAFFGMSRIGMEVTPSGTWLTY TGAIKITSGDGTTSPISEHDYQIGGYTEKWESGVKKMSGKGQQQQGQTV TKKSAAEASKKPRQKRTATKAYNVTQAFGRRGPEQTLLWPVTLACFVLA AVYRINWFKDQVILLNKHIDAYKTFPPTEPKKDKKKKTSPARMAGNGGD AALALLLLDRLNQLESKMSGKGQKMKDLSPRWYFYYLGTGPEDCVVLHS YFTSDYYQLYSTQLSTDTGVEHVTFFIYNKIVDEPEEHVQIHTIDGSSG GIIWVATEGALNTPKDHIGTRNPANNAAIVLQLPQGTTLPKGFYAEGPG PGAKFVAAWTLKAAAGPGPGQYIKANSKFIGITELGPGPG-

[0679] SAM-SGP1-TCE5-SGP2-CTSpike.sub.GF2P Nucleotide Sequence (SEQ ID NO:93): (NT 1-17: T7 promoter; NT 62-7543: VEEV non-structural protein coding region; NT 7518-7560: SGP1; NT 7582-7587 and 9541-9546: Kozak sequence; NT 7588-9474: TCE5 cassette; NT 9480-9540: SGP2; NT 9547-13368: CTSpike Furin-2P); See Sequence Listing.

[0680] ChAd-CMV-CTSpikeGF2P-CMV-TCE5 (EPE) Nucleotide Sequence (SEQ ID NO:114); See Sequence Listing.

[0681] XIV.G.I SARS-CoV-2 Vaccine Produces Responses to Various Spike Constructs

[0682] ChAd and SAM vaccine platforms encoding various versions of the SARS-CoV-2 Spike protein were assessed.

[0683] Versions of a Spike-encoding cassette featuring different sequence optimizations were assessed: “IDTSpike.sub.g” (SEQ ID NO:69, also referred to as “Spike V1” or “v1”); “CTSpike.sub.g”: (SEQ ID NO:79, also referred to as “Spike V2” or “v2”). As shown in FIG. 15, both ChAd (FIG. 15A) and SAM (FIG. 15B) vaccines produced detectable T cell responses (left panel), Spike-specific IgG antibodies (middle panel) and neutralizing antibodies (right panel). Notably, a ChAd vaccine encoding the CTSpike.sub.g sequence version produced a 3-fold increased T cell response, 100-fold increased IgG production, and 60-fold increase in neutralizing antibody titer. Similarly, a SAM vaccine encoding the CTSpike.sub.g sequence version produced an increased T cell response, 7-fold increase in IgG production, and 4-fold increase in neutralizing antibody titer. Accordingly, the data demonstrate sequence optimization of the Spike cassette produced an increased immune response across the multiple parameters assessed for each vaccine platform examined.

[0684] A version of a Spike-encoding cassette featuring modified Spike that includes removal of a furin site and addition of prolines in S2 domain was assessed: “CTSpikeF2P.sub.g” (SEQ ID NO:89 and SEQ ID NO:90). As shown in FIG. 16, both ChAd (left panel) and SAM (right panel) vaccines encoding the F2P-modified Spike produced 5-fold and 20-fold Spike-specific IgG antibodies, respectively, relative to a corresponding “CTSpike.sub.g” cassette that does not have the referenced modifications. Accordingly, the data demonstrate modification of the Spike cassette produced an increased antibody response for each vaccine platform examined.

[0685] XIV.G.II SARS-CoV-2 Vaccine Produces Responses to T Cell Epitopes

[0686] ChAd and SAM vaccine platforms encoding various a modified SARS-CoV-2 Spike protein and a T cell epitope (TCE) cassette encoding EDGE predicted epitopes (EPE) were assessed.

[0687] Both a modified Spike-encoding only cassette (“CTSpikeF2P.sub.g” (SEQ ID NO:89) and modified Spike together with additional non-Spike T cell epitopes (ChAd SEQ ID NO:114; SAM SEQ ID NO:93; see Table 10 for “TCE5”), and immune responses assessed, as described above. As shown in FIG. 17, both ChAd (FIG. 17A) and SAM (FIG. 17B) each vaccine assessed produced detectable T cell responses to Spike (left panel), while vaccines including the TCE5 cassette also generally produced detectable T cell responses to the encoded T cell epitopes (right panel). Accordingly, the data demonstrate addition of a T cell epitope cassette led to broad T cell responses across the SARS-CoV-2 Genome for each vaccine platform examined.

[0688] XIV.G.III Order of Cassettes in SARS-CoV-2 Vaccine Influences Immune Response

[0689] SAM vaccine platforms encoding various orders of a modified SARS-CoV-2 Spike protein and a T cell epitope (TCE) cassette encoding EDGE predicted epitopes (EPE) were assessed.

[0690] As shown in FIG. 18, T cell responses to Spike (top panel), T cell responses to the encoded T cell epitopes (middle panel), and Spike-specific IgG antibodies (bottom panel) were produced when vaccinated with various constructs. In FIG. 18A, SAM constructs included “IDTSpike.sub.g” (SEQ ID NO:69) alone (left columns), IDTSpike.sub.g expressed from a first subgenomic promoter followed by TCE5 expressed from a second subgenomic promoter (middle columns), or TCE5 expressed from a first subgenomic promoter followed by IDTSpike.sub.g expressed from a second subgenomic promoter (right columns), with immune responses assessed, as described above. In FIG. 18B, SAM constructs included “IDTSpike.sub.g” (SEQ ID NO:69) alone (first column), IDTSpike.sub.g expressed from a first subgenomic promoter followed by TCE6 or TCE7 expressed from a second subgenomic promoter (columns 2 and 4, respectively), or TCE6 or TCE7 expressed from a first subgenomic promoter followed by IDTSpike.sub.g expressed from a second subgenomic promoter (columns 3 and 5, respectively), with immune responses assessed, as described above. In FIG. 18C, SAM constructs included “CTSpike.sub.g” (SEQ ID NO:79) alone (first column), CTSpike.sub.g expressed from a first subgenomic promoter followed by TCE5 or TCE8 expressed from a second subgenomic promoter (columns 2 and 4, respectively), or TCE5 or TCE8 expressed from a first subgenomic promoter followed by CTSpike.sub.g expressed from a second subgenomic promoter (columns 3 and 5, respectively), with immune responses assessed, as described above. Generally, and in particular for Spike, T cell responses were increased when the respective epitopes were expressed from the second subgenomic promoter, including increased Spike-directed T cell responses relative to Spike alone. A similar trend was also observed generally observed with increased Spike-specific IgG titers when the Spike antigen was expressed from the second subgenomic promoter except, for potentially the CTSpike.sub.g constructs. Accordingly, the data demonstrate sequence order of antigen cassettes in vaccine platforms influenced immune responses.

[0691] XIV.G.IV SARS-CoV-2 Vaccine Priming Dose Produces Responses to Spike in Mice

[0692] ChAd and SAM vaccine platforms encoding the SARS-CoV-2 Spike protein were assessed in mice as a single/priming vaccine.

[0693] Mice were immunized with a Spike-encoding cassette featuring “CTSpike.sub.g” (SEQ ID NO:79) and monitored over time, as described above. As shown in FIG. 19, both ChAd (FIG. 19A) and SAM (FIG. 19B) vaccines produced detectable T cell responses across multiple Spike T cell epitope pools (left panel), Spike-specific IgG antibodies up to at least 16 weeks post prime (right panel) and neutralizing antibodies up to at least 6 weeks post prime (right bottom panel) following a single priming dose. Accordingly, the data demonstrate a priming immunization with a vaccine including a Spike cassette produced broad and potent Spike-specific T cells and durable IgG and neutralizing antibody titers for each vaccine platform examined.

[0694] XIV.G.V SARS-CoV-2 Heterologous Prime-Boost Regimen Produces Responses to Spike in Mice

[0695] ChAd and SAM vaccine platforms encoding the SARS-CoV-2 Spike protein were assessed in mice as part of a heterologous prime/boost regimen, as shown in FIG. 20A (top panel).

[0696] Mice were immunized with a ChAd platform priming dose including a Spike-encoding cassette featuring “CTSpike.sub.g” (SEQ ID NO:79) then immunized with a SAM platform boosting dose including a Spike-encoding cassette featuring “IDTSpike.sub.g” (SEQ ID NO:69) and monitored over time, as described above. As shown in FIG. 20, ChAd administration produced, and SAM administration subsequently boosted detectable T cell responses across multiple Spike T cell epitope pools (FIG. 20A, bottom panel), Spike-specific IgG antibodies up to at least 14 weeks post prime (FIG. 20B, left panel) and neutralizing antibodies up to at least 10 weeks post prime (FIG. 20B, right panel). Notably, a SAM boosting vaccine produced a 9-fold increased T cell response (including a Th1 bias as assessed by ICS; ICS data not shown), 100-fold increased IgG production, and 40-fold increase in neutralizing antibody titer 2 weeks following boost administration. Accordingly, the data demonstrate immunization with a vaccine including a Spike cassette produced broad and potent Spike-specific T cells and durable IgG and neutralizing antibody titers in mice, including that a heterologous prime/boost vaccine regimen produced an increased response following boosting dose administration.

[0697] XIV.G.VI SARS-CoV-2 Heterologous Prime-Boost Regimen Produces Responses to Spike in Non-Human Primates

[0698] ChAd and SAM vaccine platforms encoding the SARS-CoV-2 Spike protein were assessed in Indian rhesus macaques as part of a heterologous prime/boost regimen, as shown in FIG. 21A (top panel).

[0699] NHPs were immunized with a ChAd platform priming dose including a Spike-encoding cassette featuring “CTSpike.sub.g” (SEQ ID NO:79) then immunized with a SAM platform boosting dose including a Spike-encoding cassette featuring “IDTSpike.sub.g” (SEQ ID NO:69) and monitored over time, as described above. As shown in FIG. 21, a ChAd/SAM prime/boost vaccine regimen produced detectable peak T cell responses across multiple Spike T cell epitope pools (FIG. 21A, middle and bottom panels), Spike-specific IgG antibodies up to at least 12 weeks post prime (FIG. 21B, top left panel) and neutralizing antibodies up to at least 12 weeks post prime (FIG. 21B, bottom left panel) in all five NHP animals assessed. Notably, peak Spike T cell responses were greater than levels considered protective for SIV and influenza against their respective Spike proteins (FIG. 21A, bottom panel top and bottom dashed lines, respectively). In addition, neutralizing antibody titers were at least 10-fold greater than titers found in convalescent human sera (FIG. 21B, right panel) and greater than levels considered protective against SARS-CoV-2 infection (McMahan et al. Nature 2020). Accordingly, the data demonstrate immunization with a vaccine including a Spike cassette produced broad and potent Spike-specific T cells and durable IgG and neutralizing antibody titers in NHPs as part of a heterologous prime/boost vaccine regimen, including an antibody response generally considered protective.

[0700] XIV.G.VII SARS-CoV-2 Homologous Prime-Boost Regimen Produces Responses to Spike in Mice

[0701] A SAM vaccine platform encoding the SARS-CoV-2 Spike protein was assessed in mice as part of a homologous prime/boost regimen, as shown in FIG. 22A (top panel).

[0702] Mice were immunized with a SAM platform including a Spike-encoding cassette featuring “IDTSpike.sub.D” (SEQ ID NO:69 with exception of D614 not being altered) and monitored over time, as described above. As shown in FIG. 22, SAM administration initially both produced, and re-administration subsequently boosted, detectable T cell responses across multiple Spike T cell epitope pools (FIG. 22A, bottom panel), Spike-specific IgG antibodies up to at least 15 weeks post prime (FIG. 22B, left panel) and neutralizing antibodies up to at least 15 weeks post prime (FIG. 22B, right panel). Notably, a SAM boosting vaccine produced at least a 4-fold increased T cell response 2 weeks following boost administration, 80-fold increased IgG production 7 weeks following boost administration, and 25-fold increase in neutralizing antibody titer 7 weeks following boost administration. Accordingly, the data demonstrate immunization with a vaccine including a Spike cassette produced broad and potent Spike-specific T cells and durable IgG and neutralizing antibody titers in mice, including that a homologous prime/boost vaccine regimen produced an increased response following boosting dose administration.

[0703] XIV.G.VIII SARS-CoV-2 Homologous Prime-Boost Regimen Produces Responses to Spike in Non-Human Primates

[0704] A SAM vaccine platform encoding the SARS-CoV-2 Spike protein was assessed in Indian rhesus macaques as part of a homologous prime/boost regimen, as shown in FIG. 23 (top panel).

[0705] NHPs were immunized with a SAM platform including a Spike-encoding cassette featuring “IDTSpike.sub.g” (SEQ ID NO:69) and monitored over time, as described above. As shown in FIG. 23, SAM administration initially both produced, and re-administration subsequently boosted, Spike-specific IgG antibodies up to at least 12 weeks post prime (FIG. 23, middle panels) and neutralizing antibodies up to at least 10 weeks post prime (FIG. 23, bottom panels). Notably, neutralizing antibody titers were at least 10-fold greater than titers found in convalescent human sera (FIG. 23, bottom right panel) and greater than levels considered protective against SARS-CoV-2 infection (McMahan et al. Nature 2020). In addition, lose-dose (30 μg) SAM administration produced a more robust response than higher-dose (300 μg) SAM administration. Accordingly, the data demonstrate immunization with a vaccine including a Spike cassette produced high durable IgG and neutralizing antibody titers in NHPs, including that a homologous prime/boost vaccine regimen produced an increased response following boosting dose administration, notably in a “low” dose context, as well as an antibody response generally considered protective.

[0706] XIV.H. Additional SARS-CoV-2 Vaccine Constructions

[0707] Vaccines were constructed to maximize the percentage of people getting predicted to achieve a total magnitude of greater than 1000 from validated epitopes. Briefly, magnitude was calculated across all validated epitopes in the starting proteins (e.g., Spike), as well as any added in the TCE cassettes according to the following with an expected approximate upper size limit of 600 amino acids beyond that of Spike: (1) An individual's magnitude is the sum of all epitope magnitudes across their respective diplotype alleles; (2) Each epitopes magnitude=(magnitude of response)×(Frequency of positive response/100), with values found in Tarke et al. (Comprehensive analysis of T cell immunodominance and immunoprevalence of SARS-CoV-2 epitopes in COVID-19 cases. Cell Rep Med. 2021 Feb. 16; 2(2):100204. doi: 10.1016/j.xcrm.2021.100204. Epub 2021 Jan. 26.), herein incorporated by reference for all purposes; (3) epitopes other than those from starting proteins that span mutations with >5% frequency were excluded (see Table 11 for all mutations>1% frequency either overall or in specific strains), though mutations are allowed in flanking regions; and (4) cassette order was chosen to minimize unintended junction epitopes across adjacent frames, as well as minimize consecutive frames in the same protein to reduce chance of functional protein fragments, as described above.

[0708] The following constructions were produced: (A) “TCE10” starting with full Spike protein as the starting point and adding validated epitopes according to the above for a total size of 378 amino acids in addition to Spike (Table 12A, maps of epitopes covered in FIG. 24A-24F); (B) “TCE9” extended TCE10 and adding validated epitopes according to the above only if fully conserved between SARS and SARS-2 (e.g., as a pan-coronavirus vaccine), with certain frames extended (21 additional amino acids across all frames) to include additional predicted epitopes for alleles (i.e., not validated epitopes), for a total size of 556 amino acids in addition to Spike (Table 12B, maps of epitopes covered in FIG. 25A-25G); (C) “TCE11” starting with full Spike and Nucleocapsid proteins as the starting point and adding validated epitopes according to the above for a total size of 616 amino acids (197aa+full N) in addition to Spike (Table 12C, maps of epitopes covered in FIG. 26A-26D). Table 13A and Table 13B presents the magnitude coverage across various populations for each of TCE5, TCE9, TCE10, and TCE11 for SARS-CoV-2 and SARS/SARS-CoV-2 conserved epitopes, respectively. Notably, each of the vaccine constructs cover greater than 89% of each of the indicated populations with a validated response magnitude greater than 1000 and greater than 95% with a validated response magnitude greater than 100, while TCE9 covers greater than 74% of each of the indicated populations with a validated response magnitude greater than 1000 for epitopes conserved between SARS and SARS-2. FIG. 27 presents the percentages of shared candidate 9-mer epitope distribution between SARS-CoV-2 and SARS-CoV (left panel) and between SARS-CoV-2 and MERS (right panel), highlighting the significant number of conserved sequences outside of the Spike protein demonstrating the value of evaluating and including epitopes beyond those simply encoded by Spike, particularly with a goal of constructing a pan-coronavirus vaccine.

TABLE-US-00015 TABLE 11 Mutations > 1% frequency either overall or in specific strains Gene Position Strain Frequency M 70 b117 0.014 M 155 N501Y_early 0.048 M 162 N501Y_early 0.048 N 3 b117 0.999 N 13 N501Y_early 0.016 N 14 N501Y_early 0.016 N 67 0.028 N 80 P1 1 N 81 N501Y_early 0.033 N 151 0.011 N 194 0.056 N 199 0.041 N 203 b117 1 N 204 b117 1 N 205 N501Y_early 1 N 220 0.218 N 234 0.033 N 235 b117 0.999 N 359 N501Y_early 0.016 N 365 0.021 N 373 N501Y_early 0.016 N 376 0.029 N 377 0.018 N 398 0.015 ORF3a 15 b117 0.089 ORF3a 38 0.011 ORF3a 57 N501Y_early 0.982 ORF3a 90 b117 0.02 ORF3a 131 N501Y_early 0.036 ORF3a 171 N501Y_early 0.589 ORF3a 172 0.039 ORF3a 202 0.012 ORF3a 223 0.016 ORF3a 251 0.017 ORF3a 259 N501Y_early 0.018 S 5 0.012 S 18 N501Y_early 0.381 S 54 N501Y_early 0.016 S 69 b117 1 S 70 b117 1 S 80 N501Y_early 1 S 98 0.012 S 144 b117 1 S 215 N501Y_early 1 S 222 0.198 S 241 N501Y_early 1 S 242 N501Y_early 1 S 243 N501Y_early 1 S 246 N501Y_early 0.016 S 262 0.011 S 316 N501Y_early 0.016 S 384 N501Y_early 0.016 S 417 N501Y_early 0.984 S 439 0.017 S 477 0.048 S 484 N501Y_early 1 S 501 b117 1 S 570 b117 1 S 614 b117 1 S 681 b117 1 S 682 cleavage 1 S 683 cleavage 1 S 685 cleavage 1 S 688 N501Y_early 0.016 S 701 N501Y_early 1 S 706 b117 0.018 S 716 b117 1 S 982 b117 1 S 1078 N501Y_early 0.016 S 1117 N501Y_early 0.016 S 1118 b117 1 S 1150 N501Y_early 0.016 nsp12 4577 0.026 nsp12 4646 0.01 nsp12 4715 0.885 nsp12 4815 0.011 nsp12 5112 0.016 nsp12 5168 0.025 nsp13 5542 0.025 nsp13 5585 0.026 nsp13 5614 0.022 nsp13 5784 0.027 nsp13 5922 0.017 nsp14 6054 0.024 nsp14 6426 0.011 nsp15 6485 0.015 nsp16 7014 0.028 nsp2 265 0.132 nsp2 300 0.042 nsp3 1001 0.059 nsp3 1113 0.011 nsp3 1246 0.011 nsp3 1361 0.01 nsp3 1708 0.058 nsp3 2230 0.058 nsp3 2501 0.02 nsp3 2606 0.011 nsp4 3087 0.025 nsp5 3278 0.016 nsp5 3352 0.034 nsp5 3353 0.013 nsp5 3371 0.013 nsp6 3606 0.056 nsp6 3675 0.064 nsp6 3676 0.064 nsp6 3677 0.064 nsp6 3711 0.015 nsp7 3884 0.01 nsp9 4241 0.016

TABLE-US-00016 TABLE 12A TCE10 Cassette (Order of Frames as Shown) Frame Start Frame End SEQ Gene in Gene in Gene Frame sequence ID NO:  N  356  378 HIDAYKTFPPTEPKKDKKKKADE 27944 ORF3a  133  149 CRSKNPLLYDANYFLCW 27945 nsp3 1632 1660 FEYYHTTDPSFLGRYMSALNHTKKWKYPQ 27946 nsp3 1360 1377 ISNEKQEILGTVSWNLRE 27947 M  160  203 DIKDLPKEITVATSRTLSYYKLGASQRVAGDSGFAA 27948 YSRYRIGN ORF3a   29   52 VRATATIPIQASLPFGWLIVGVAL 27949 nsp4 3111 3134 YLTFYLTNDVSFLAHIQWMVMFTP 27950 M   89  109 GLMWLSYFIASFRLFARTRSM 27951 nsp12 4553 4571 DWYDFVENPDILRVYANLG 27952 nsp3 1919 1935 PYPNASFDNFKFVCDNI 27953 nsp12 4806 4826 NFNKDFYDFAVSKGFFKEGSS 27954 nsp12 4728 4745 DGVPFVVSTGYHFRELGV 27955 nsp4 2850 2876 ACPLIAAVITREVGFVVPGLPGTILRT 27956 nsp3 2745 2761 ATTRQVVNVVTTKIALK 27957 N  318  337 SRIGMEVTPSGTWLTYTGAI 27958 M   61   77 TLACFVLAAVYRINWIT 27959 N   96  117 GGDGKMKDLSPRWYFYYLGTGP 27960

TABLE-US-00017 TABLE 12B TCE9 Cassette (Order of Frames as Shown) Frame Start Frame End SEQ Gene in Gene in Gene Frame sequence ID NO:  nsp12 4719 4745 GPLVRKIFVDGVPFVVSTGYHFRELGV 27961 nsp4 3096 3134 PVYSFLPGVYSVIYLYLTFYLTNDVSFLAHIQWMVM 27962 FTP M   89  109 GLMWLSYFIASFRLFARTRSM 27951 nsp12 4888 4905 NNLDKSAGFPFNKWGKAR 27963 nsp3 2745 2761 ATTRQVVNVVTTKIALK 27957 M   61   79 TLACFVLAAVYRINWITGG 27964 nsp3 1919 1935 PYPNASFDNFKFVCDNI 27953 nsp3 2676 2692 TYNKVENMTPRDLGACI 27965 ORF3a   29   52 VRATATIPIQASLPFGWLIVGVAL 27949 nsp12 4806 4826 NFNKDFYDFAVSKGFFKEGSS 27954 N   96  117 GGDGKMKDLSPRWYFYYLGTGP 27960 nsp12 5213 5234 KQGDDYVYLPYPDPSRILGAGC 27966 N  356  378 HIDAYKTFPPTEPKKDKKKKADE 27944 ORF3a  133  149 CRSKNPLLYDANYFLCW 27945 nsp6 3643 3668 SLATVAYFNMVYMPASWVMRIMTWLD 27967 nsp12 4529 4545 GNCDTLKEILVTYNCCD 27968 nsp3 1630 1660 EAFEYYHTTDPSFLGRYMSALNHTKKWKYPQ 27969 nsp3 1360 1377 ISNEKQEILGTVSWNLRE 27947 M  160  203 DIKDLPKEITVATSRTLSYYKLGASQRVAGDSGFAA 27948 YSRYRIGN N  301  337 WPQIAQFAPSASAFFGMSRIGMEVTPSGTWLTYTGAI 27970 nsp12 4553 4571 DWYDFVENPDILRVYANLG 27952 nsp4 2850 2909 ACPLIAAVITREVGFVVPGLPGTILRTTNGDFLHFLPR 27971 VFSAVGNICYTPSKLIEYTDFA

TABLE-US-00018 TABLE 12C TCE11 Cassette (Order of Frames as Shown) Frame Start Frame End Frame sequence SEQ Gene in Gene in Gene ID NO:  nsp12 4896 4826 NVAFQTVKPGNFNKDFYDFAVSKGFFKEGSS 27972 M  182  203 GASQRVAGDSGFAAYSRYRIGN 27973 nsp12 4728 4745 DGVPFVVSTGYHFRELGV 27955 nsp4 3111 3134 YLTFYLTNDVSFLAHIQWMVMFTP 27950 M   89  109 GLMWLSYFIASFRLFARTRSM 27951 nsp3 1632 1660 FEYYHTTDPSFLGRYMSALNHTKKWKYPQ 27946 nsp3 1360 1377 ISNEKQEILGTVSWNLRE 27947 nsp3 2745 2761 ATTRQVVNVVTTKIALK 27957 M   61   77 TLACFVLAAVYRINWIT 27959

TABLE-US-00019 TABLE 13A Population Coverages for SARS-CoV-2 Validated Epitopes (Excluding mutations >5%) Starting Cassette Magnitude Protein(s) AFA API EUR HIS Mean Min Spike 1 S 0.95 0.89 1 0.98 0.95 0.89 S + N + TCE11 1 S, N 0.97 0.95 1 0.99 0.98 0.95 S + TCE10 1 S 0.97 0.95 1 0.99 0.98 0.95 S + TCE9 1 S 0.97 0.95 1 0.99 0.98 0.95 S + TCE5 1 S 0.95 0.95 1 0.98 0.97 0.95 Spike 100 S 0.92 0.86 1 0.96 0.93 0.86 S + N + TCE11 100 S, N 0.95 0.95 1 0.99 0.97 0.95 S + TCE10 100 S 0.95 0.95 1 0.99 0.97 0.95 S + TCE9 100 S 0.95 0.95 1 0.99 0.97 0.95 S + TCE5 100 S 0.92 0.94 1 0.97 0.96 0.92 Spike 1000 S 0.6 0.62 0.91 0.75 0.72 0.6 S + N + TCE11 1000 S, N 0.89 0.92 1 0.96 0.94 0.89 S + TCE10 1000 S 0.9 0.92 1 0.97 0.95 0.9 S + TCE9 1000 S 0.9 0.92 1 0.97 0.95 0.9 S + TCE5 1000 S 0.68 0.7 0.93 0.8 0.78 0.68 Spike 2000 S 0.39 0.49 0.73 0.56 0.54 0.39 S + N + TCE11 2000 S, N 0.66 0.72 0.96 0.82 0.79 0.66 S + TCE10 2000 S 0.72 0.73 0.96 0.85 0.81 0.72 S + TCE9 2000 S 0.76 0.77 0.98 0.9 0.85 0.76 S + TCE5 2000 S 0.49 0.54 0.81 0.66 0.62 0.49

TABLE-US-00020 TABLE 13B Population Coverages for Validated Conserved Epitopes between SARS and SARS-CoV-2 (Excluding mutations >5%) Starting Cassette Magnitude Protein(s) AFA API EUR HIS Mean Min Spike 1 S 0.74 0.82 0.98 0.91 0.87 0.74 S + N + TCE11 1 S, N 0.89 0.93 1 0.97 0.95 0.89 S + TCE10 1 S 0.94 0.93 1 0.97 0.96 0.93 S + TCE9 1 S 0.94 0.93 0.99 0.97 0.96 0.93 S + TCE5 1 S 0.87 0.91 0.99 0.95 0.93 0.87 Spike 100 S 0.74 0.78 0.98 0.89 0.85 0.74 S + N + TCE11 100 S, N 0.89 0.91 0.99 0.95 0.94 0.89 S + TCE10 100 S 0.94 0.93 0.99 0.97 0.96 0.93 S + TCE9 100 S 0.94 0.92 0.99 0.97 0.96 0.92 S + TCE5 100 S 0.86 0.88 0.98 0.93 0.91 0.86 Spike 1000 S 0.18 0.2 0.46 0.27 0.28 0.18 S + N + TCE11 1000 S, N 0.49 0.67 0.76 0.62 0.63 0.49 S + TCE10 1000 S 0.52 0.56 0.71 0.55 0.59 0.52 S + TCE9 1000 S 0.74 0.81 0.92 0.84 0.83 0.74 S + TCE5 1000 S 0.33 0.42 0.62 0.49 0.47 0.33 Spike 2000 S 0.01 0.03 0.08 0.03 0.04 0.01 S + N + TCE11 2000 S, N 0.24 0.2 0.41 0.28 0.28 0.2 S + TCE10 2000 S 0.2 0.15 0.34 0.17 0.21 0.15 S + TCE9 2000 S 0.4 0.37 0.7 0.51 0.49 0.37 S + TCE5 2000 S 0.21 0.11 0.34 0.24 0.22 0.11

[0709] XIV.I. SARS-CoV-2 Convalescent Human PBMCs Demonstrate T Cell Responses to T Cell Epitopes Encoded in Vaccine Constructs

[0710] During a natural infection, T cells are primed and expand within 2-3 weeks after initial exposure, and thus need several weeks to effectively start clearing infected cells. In contrast, vaccine-induced T cell responses are able to rapidly expand upon exposure, and are hence likely to prevent (severe) infection in instances where vaccine-induced antibody titers are no longer sufficient to prevent infection. Accordingly, PBMC samples from convalescent SARS-CoV-2 subjects were analyzed for the presence of functional and cytotoxic memory T cell responses to Spike and T cell epitope (TCE5) regions to assess whether SARS-CoV-2 antigenic sections included in vaccine cassette constructs stimulated T cell responses similar to those stimulated by natural infection and hence are likely relevant to inducing protective immunity against SARS-CoV-2 infection.

IFNγ ELISpot Assay

[0711] Detection of IFNγ-producing T cells was performed by ELISpot assay [S. Janetzki, J. H. Cox, N. Oden, G. Ferrari, Standardization and validation issues of the ELISPOT assay. Methods Mol Biol 302, 51-86 (2005)]. Briefly, cells were harvested, counted and re-suspended in media at 4×10.sup.6 cells/ml (ex vivo PBMCs) or 2×10.sup.6 cells/ml (IVS-expanded cells) and cultured in the presence of DMSO (VWR International), Phytohemagglutinin-L (PHA-L; Sigma-Aldrich, Natick, MA, USA), or SARS-CoV-2 Spike overlapping peptide pools (Table D), TCE5-encoded overlapping peptide pools (Table E), or TCE5-encoded minimal epitope peptide pools (Table F) in ELISpot Multiscreen plates (EMD Millipore) coated with anti-human IFNγ capture antibody (Mabtech, Cincinnati, OH, USA). Peptide pools were further subdivided into smaller pools categorized by SARS-CoV-2 protein source, EDGE-predicted, and/or previously reported/validated (“validated”) in the literature (for example, as in Nelde et al. [Nature Immunology volume 22, pages 74-85 2021], Tarke et al. 2021, or Schelien et al. [bioRxiv 2020.08.13.249433]). Following 18h incubation in a 5% CO.sub.2, 37° C., humidified incubator, supernatants were collected, cells were removed from the plate, and membrane-bound IFNγ was detected using anti-human IFNγ detection antibody (Mabtech), Vectastain Avidin peroxidase complex (Vector Labs, Burlingame, CA, USA) and AEC Substrate (BD Biosciences, San Jose, CA, USA). Plates were imaged and enumerated on an AID iSpot reader (Autoimmun Diagnostika). Data are presented as spot forming units (SFU) per million cells. PBMCs were either purchased (Tissue Solutions; “Cohort 1”) or obtained from a second source (“Cohort 2”).

In vitro Stimulation (IVS) Cultures

[0712] SARS-CoV-2-reactive T cells from convalescent patient PBMC samples were expanded in the presence of overlapping peptide pools covering Spike (Table D) and T cell epitope (TCE) regions (Table E) and low-dose IL-2 as described previously [B. Bulik-Sullivan et al., Deep learning using tumor HLA peptide mass spectrometry datasets improves neoantigen identification. Nat Biotechnol, (2018)]. Briefly, thawed PBMCs were rested overnight and stimulated in the presence of combined Spike or total TCE_OLP overlapping peptide pools (4-5 μg/ml/peptide) in ImmunoCult™-XF T Cell Expansion Medium (IC media; STEMCELL Technologies) with 10 IU/ml rhIL-2 (R&D Systems Inc., Minneapolis, MN) for 14 days in 48- or 24-well tissue culture plates. Cells were seeded at 1-2×10.sup.6 cells/well and fed every 2-3 days by replacing ⅔ of the culture media with rhIL-2. CD4+ and CD8+ T cell depletions after IVS stimulation and prior to ELISpot assay were performed using CD4+ or CD8+ T cell isolation kits from Miltenyi (Miltenyi Biotech Inc., Auburn, CA) according to the manufacturer's instructions.

IncuCyte Killing Assays

[0713] HLA-expressing A375 cells (A*01:01, A*02:01, A*03:01, A*11:01 and A*30:01) transduced with Red lentivirus were seeded in a 96-well plate at a concentration of 2.5×10.sup.4 cells per well or in a 48 well plate at a concentration of 3.5×10.sup.4 cells per well in DMEM with 10% heat inactivated FBS. The plates were placed in the Incucyte® S3 (Essen Biosciences) and 24h after the seeding, the effector cells were plated at a concentration of 2.5×10.sup.5 cells well in a 96-well plate or 3.5×10.sup.5 cells per well in a 48 well plate for an effector to target ratio of 10:1. Minimal epitope peptide pools were added to the treated wells for a final concentration of 4 μg/mL and DMSO was used for the control wells. The plates were imaged with the Incucyte® for 2-4 days total after which the data was analyzed using the Incucyte® S3 2018 analysis software. Viability of the A375 was assessed by red cell count and relative target count was calculated from time of effector addition (0h) relative to DMSO co-culture control wells.

Results

[0714] T cell responses to Spike and TCE5-encoded epitopes were assessed by IFNγ ELISpot. As shown in FIG. 28 and quantified in Table 14, small but detectable epitope-specific responses were observed across the various indicated Spike peptide pools and TCE5-encoded peptide pools for PBMCs tested directly ex vivo (i.e., without IVS expansion). As shown in FIG. 29 and quantified in Table 15, IVS-expanded PBMCs (Cohort 1) demonstrated robust epitope-specific responses across the various indicated Spike peptide pools and TCE5-encoded peptide pools examined. As shown in FIG. 30 and quantified in Table 16, IVS-expanded PBMCs (Cohort 2) demonstrated robust epitope-specific responses across the various indicated Spike peptide pools and TCE5-encoded peptide pools examined, including responses above the upper limit of quantification (ULOQ). Shown in FIG. 31 is a selection of samples from IVS-expanded PBMCs (both Cohort 1 and Cohort 2; see FIG. 29 and FIG. 30) demonstrating robust epitope-specific responses across the various indicated minimal TCE5-encoded peptide pools examined, both validated and EDGE predicted, including responses above the upper limit of quantification (ULOQ). The results demonstrate both Spike and the selected T cell epitopes for inclusion in TCE5 stimulated broad and robust T cell responses similar to those stimulated by natural infection indicating the potential to provide protective immunity against SARS-CoV-2 infection when administered as a vaccine.

[0715] T cell responses to TCE5-encoded epitopes were further examined to characterize the T cell response. As shown in FIG. 32 and quantified in Table 17, IVS-expanded PBMCs (Cohort 1) demonstrated robust epitope-specific responses across the various indicated TCE5-encoded peptide pools examined (column 1). CD8-depletion of PBMCs generally resulted in a reduced but still detectable T cell response (bottom panel, column 3), while CD4-depletion of PBMCs had a variable effect across the various pools and donor sources (column 2). The results demonstrate the selected T cell epitopes for inclusion in TCE5 stimulated a mixed CD4/CD8 T cell response.

[0716] T cell responses to TCE5-encoded epitopes were further examined to assess functional killing of target cells. As shown in FIG. 33A-L and quantified in Tables 18A-L, target cell killing was observed in a peptide and effector T cell-specific manner (open squares) for each of the HLA allele-expressing target cells across the various indicated TCE5-encoded peptide pools examined. The results demonstrate the selected T cell epitopes for inclusion in TCE5 promoted T cell-mediated killing by T cells produced during a natural infection indicating the potential to promote protective immunity against SARS-CoV-2 infection when administered as a vaccine.

TABLE-US-00021 TABLE 14 T cell responses to Spike and TCE5-encoded epitopes (IFNγ ELISpot; ex vivo) 20% H2O PHA 80% DMSO (positive Min EDGE Min EDGE Min PBMC ID (vehicle) control) Nuc ORF3a validated OLP Mem OLP Nuc OLP ORF3a 111120AT 15 10 4355 6500 30 15 0 0 30 5 0 15 90 115 35 50 120820C 0 0 5150 4865 10 0 0 0 15 10 55 55 35 70 50 15 111120AR 10 0 5410 5470 45 15 0 0 25 15 20 20 5 10 25 10 112020E 90 80 4345 4410 175 240 80 80 135 110 95 75 215 290 100 45 120820F 5 20 5685 5910 65 200 5 0 45 45 10 10 100 130 30 20 121520C 90 35 5460 5870 90 125 60 130 80 70 65 50 230 150 115 65 112020C 15 40 4695 4670 45 45 30 35 15 0 10 15 30 10 5 5 112020D 80 45 6090 6160 75 130 100 70 90 110 55 60 240 50 20 65 120820A 0 0 3515 4210 60 60 0 0 5 10 20 15 90 70 121520A 25 90 5720 5605 35 150 65 90 65 60 50 50 415 360 90 145 120820D 0 0 5245 5675 240 290 5 5 10 0 5 5 300 315 35 10 101420B 10 10 4845 5450 25 35 5 15 10 25 10 5 40 45 15 30 121120C 60 95 5845 5755 80 115 105 75 75 130 105 85 165 130 150 125 121120F 10 10 5160 5555 100 30 20 15 45 35 35 10 105 80 0 5 Min EDGE Min EDGE Min Sp-Wu Sp-Wu Sp-Wu Sp-Wu PBMC ID Nuc Expl. ORF3a Expl. Sette 1_2 3_4 5_6 7_8 111120AT 50 35 10 10 60 15 65 70 120820C 5 0 5 15 10 0 145 80 85 110 90 70 100 110 111120AR 25 10 20 5 15 112020E 155 95 45 95 30 45 175 55 200 170 85 90 100 75 120820F 25 35 85 130 40 35 121520C 110 60 80 112020C 20 35 10 15 0 15 20 40 20 20 5 5 112020D 75 65 60 30 45 25 30 85 95 132 125 115 45 60 120820A 121520A 170 110 135 195 160 220 110 135 120820D 275 230 5 20 190 255 225 180 55 70 150 100 45 50 101420B 15 20 10 30 25 5 35 40 45 30 45 20 50 25 121120C 125 165 90 80 55 80 300 310 330 340 220 285 135 115 121120F 25 35 20 15 10 20 30 35 50 75 50 25 25 10 Spot forming units (SFU) per 1e6 cells (technical replicates)

TABLE-US-00022 TABLE 15 T cell responses to TCE5-encoded epitopes - Cohort 1 PBMCs (IFNγ ELISpot; post IVS) 20% H2O 80% PHA TCE OLP OLP OLP PBMC ID DMSO (vehicle) (positive control) OLP Mem Nuc ORF3a 121520C 360 640 6960 6650 5640 5840 980 830 5950 6280 2930 2850 111120AR 110 190 6510 6330 4970 4630 1010 560 4630 5590 1230 2250 120820F 290 300 5760 6470 5020 4770 380 180 4840 5430 1990 1690 121520A 400 100 6370 6340 2040 2140 80 140 1940 2020 510 960 121520A 10 0 6550 6430 160 120 121520A 200 130 4600 5620 3520 4280 121520A 280 110 6760 6550 2210 4760 Min Min EDGE Min EDGE Min EDGE Min EDGE Min PBMC ID validated Nuc ORF3a Nuc Expl. ORF3a Expl. Sette 121520C 5210 5510 6290 6510 480 690 111120AR 5720 7010 1660 1190 120 320 120820F 6310 7010 4030 3760 570 580 4750 6480 1920 2460 2740 2330 121520A 1740 1100 2690 2950 110 120 4940 2970 340 50 3780 3720 121520A 121520A 5730 3960 3750 3450 121520A 730 920 140 180 Spot forming units (SFU) per 1e6 cells (technical replicates)

TABLE-US-00023 TABLE 16 T cell responses to TCE5-encoded epitopes - Cohort 2 (IFNγ ELISpot; post IVS) 20% H2O 80% PHA TCE OLP OLP PBMC ID DMSO (vehicle) (positive control) OLP Mem Nuc 169923 910 870 13000 13000 13000 13000 2100 2070 13000 13000 169923 0 980 30 251227 40 30 6530 6620 140 180 0 20 180 120 425053 1430 1390 13000 13000 13000 13000 3220 3380 13000 13000 425053 30 70 5450 4990 5000 4330 548367 120 60 13000 13000 13000 13000 170 110 13000 548367 160 100 10270 9750 3390 3400 60 70 5000 5500 579992 1470 1510 13000 13000 13000 13000 4840 4670 13000 13000 579992 430 380 6590 6530 7110 6840 450 670 5860 6360 592571 220 210 13000 13000 7030 7220 1760 2010 6850 6760 592571 1640 1710 13000 13000 13000 13000 4020 3670 13000 13000 711280 70 100 9930 9950 1530 1470 60 90 1710 1810 711280 70 80 11710 11380 4750 4840 60 80 6210 6010 270554 0 10 3830 3540 10 40 20 10 270554 1060 1200 7650 7120 5730 5890 2610 2700 4620 4580 277045 300 40 8270 10150 4180 4090 277045 20 30 6420 1050 1210 306916 1910 2340 13000 13000 13000 13000 2190 1960 3190 3460 306916 130 30 13000 13000 4290 4180 130 317737 250 13000 6860 5770 5790 6180 6120 317737 650 960 13000 13000 7150 7130 2470 2550 5850 5760 383468 60 30 10 383468 1690 1780 13000 13000 13000 13000 5500 5360 13000 13000 389341 490 720 13000 13000 5510 5570 1120 1170 4940 4680 389341 680 630 13000 13000 4560 4850 1340 1340 3850 3980 849884 610 830 13000 13000 13000 13000 3520 3520 13000 13000 849884 390 5700 1260 907902 430 260 5170 13000 3410 3490 900 1280 4500 4510 907902 480 220 13000 13000 7300 7660 1400 1570 7690 7500 627934 390 310 13000 13000 3490 3440 1060 1070 3580 3570 627934 480 190 13000 13000 4540 4610 1120 1190 5000 4600 865452 570 510 6800 7040 5580 5680 630 570 13000 13000 865452 410 270 13000 13000 4690 4860 620 410 4310 4750 602232 30 0 5400 5620 3740 4200 20 70 6160 6680 602232 180 240 5830 5870 2500 2650 260 320 3970 4200 646382 20 20 3650 3670 640 600 50 40 320 300 646382 0 0 6290 6680 5140 5830 10 30 7070 7100 941176 670 420 6780 6640 5860 5990 710 810 4850 5230 OLP Min Min EDGE Min EDGE PBMC ID ORF3a validated Nuc ORF3a 169923 7280 7320 13000 13000 13000 13000 6280 3250 169923 10 251227 10 10 2210 425053 8240 8360 13000 13000 7190 7430 7850 7820 425053 548367 380 548367 390 490 5940 6020 1840 2050 2890 2970 579992 7130 7240 13000 13000 13000 13000 6210 3560 579992 6040 6050 6850 6830 6650 6630 7180 7460 592571 5520 5510 4270 4560 7180 7710 4650 4570 592571 7970 7750 13000 13000 7110 7140 7060 7080 711280 330 230 2470 2400 520 640 120 210 711280 380 390 7200 7450 3550 3390 1040 1350 270554 270554 3790 4200 5760 1570 1050 277045 277045 306916 13000 13000 3570 3710 13000 13000 2820 2770 306916 317737 2960 2990 5680 3370 2530 317737 6780 6690 2560 2410 1340 1160 7360 7070 383468 383468 5150 5140 6850 7410 4810 5040 5830 6020 389341 4180 4510 4600 389341 4760 4180 4300 4320 5430 5380 1940 2410 849884 13000 13000 13000 13000 5210 4930 13000 13000 849884 907902 960 1620 1350 1340 470 780 2890 3080 907902 7510 7210 13000 13000 6610 7400 7520 7670 627934 1670 1810 3950 4040 1680 1680 790 660 627934 2950 3230 5430 5090 1500 1490 2680 2670 865452 1440 1630 850 730 5450 5640 660 830 865452 2100 2140 1000 1150 4150 3940 470 450 602232 30 30 13000 13000 30 30 40 30 602232 210 160 5890 5910 300 180 190 200 646382 550 700 1440 1370 250 180 1130 970 646382 500 660 13000 13000 240 150 1050 1030 941176 5530 5280 7250 7070 6880 7040 6660 6410 Spot forming units (SFU) per 1e6 cells (technical replicates)

TABLE-US-00024 TABLE 17 T cell responses to TCE5-encoded epitopes CD4/CD8 Depletion - Cohort 1 (IFNγ ELISpot; ex vivo) 20% H2O 80% PHA TCE OLP PBMC ID Condition DMSO (vehicle) (positive control) OLP Mem 121120C PBMCs 440 350 5950 6270 2590 1540 310 400 121120C CD4-depleted 100 140 5520 5980 910 910 260 180 121120F PBMCs 330 150 6190 6090 3720 3810 180 230 121120F CD4-depleted 320 310 4680 4730 2760 2650 290 360 121120F CD8-depleted 230 230 5810 5250 1270 1570 220 210 OLP OLP Min Min EDGE Min EDGE PBMC ID Nuc ORF3a validated Nuc ORF3a 121120C 1010 1060 650 670 1250 1280 1990 3440 900 1200 121120C 910 880 250 190 1030 1050 1990 1890 710 680 121120F 3870 3640 510 120 3450 3690 1620 1420 840 1180 121120F 3780 4090 520 310 6130 5620 1560 1870 1250 1070 121120F 2510 2490 300 280 1820 1920 720 530 410 380 Spot forming units (SFU) per 1e6 cells (technical replicates)

TABLE-US-00025 TABLE 18A Killing Assay (A*03:01 targets; Cohort 2 donor 169923; Validated Pool) Relative target cell count Elapsed DMSO + Min_validated + Min_validated + DMSO + time (h) Targets Targets 10:1 E:T 10:1 E:T 0 0 0 0 0 0 0 0 0 4 −0.01324 −0.06020 0.01030 −0.04000 0.00821 −0.00603 0 0 8 0.05701 0.04465 0.12453 0.08240 0.00841 −0.01194 0 0 12 0.13986 0.17088 0.28847 0.26613 −0.04966 −0.05472 0 0 16 0.34307 0.38717 0.49053 0.47554 −0.03273 −0.13508 0 0 20 0.50381 0.62799 0.67542 0.74838 −0.13429 −0.18802 0 0 24 0.72815 0.86933 0.96280 1.05832 −0.28017 −0.31067 0 0 28 0.96880 1.15188 1.19516 1.32867 −0.37962 −0.44843 0 0 32 1.20932 1.50413 1.47961 1.68586 −0.48409 −0.51295 0 0 36 1.47688 1.94340 1.89230 2.19941 −0.59226 −0.65697 0 0 40 1.77778 2.33481 2.25071 2.65348 −0.77473 −0.81342 0 0 44 1.99233 2.65702 2.57367 3.23976 −0.95032 −0.99916 0 0 48 2.12635 2.89103 2.94382 3.81998 −1.16628 −1.24008 0 0 52 2.11070 3.01152 3.06229 4.30811 −1.46616 −1.47099 0 0 56 1.95512 3.05273 3.15095 4.66875 −1.75737 −1.70104 0 0 60 1.70074 2.93234 2.98756 4.82178 −2.06228 −2.01444 0 0 64 1.45363 2.72321 2.83818 4.97395 −2.27938 −2.27634 0 0 68 1.04123 2.36000 2.56926 4.88298 −2.52690 −2.57086 0 0

TABLE-US-00026 TABLE 18B Killing Assay (A*02:01 targets; Cohort 2 donor 389341; ORF3a Pool) Relative target cell count Elapsed DMSO + Min_ORF3a + Min_ORF3a + DMSO + time (h) Targets Targets 10:1 E:T 10:1 E:T 0 0 0 0 0 0 0 0 0 4 0.01813 0.02413 0.00988 −0.01350 −0.00427 0.00992 0 0 8 0.08048 0.06653 0.04010 0.02566 −0.00763 −0.03750 0 0 12 0.17361 0.10990 0.11690 0.05167 −0.01070 −0.10823 0 0 16 0.31379 0.20136 0.22194 0.13147 −0.04211 −0.20612 0 0 20 0.53036 0.37716 0.40752 0.28054 −0.09218 −0.32701 0 0 24 0.76710 0.55804 0.58343 0.42801 −0.19155 −0.47142 0 0 28 0.95779 0.74903 0.71718 0.56596 −0.32093 −0.62224 0 0 32 1.19255 0.98206 0.88543 0.69975 −0.43939 −0.76130 0 0 36 1.39711 1.17513 0.99709 0.82011 −0.57471 −0.88468 0 0 40 1.52634 1.28181 1.04170 0.87370 −0.71506 −1.04042 0 0 44 1.61547 1.38534 1.02950 0.89848 −0.86036 −1.16624 0 0 48 1.64176 1.45046 0.97523 0.87336 −0.99708 −1.27647 0 0 52 1.59635 1.46211 0.84139 0.83014 −1.16652 −1.35229 0 0 56 1.54683 1.48783 0.70914 0.77852 −1.26086 −1.39289 0 0 60 1.45560 1.45470 0.57591 0.66815 −1.34735 −1.45718 0 0 64 1.33675 1.40186 0.41942 0.58206 −1.41787 −1.46087 0 0 68 1.23903 1.40829 0.22741 0.52066 −1.48594 −1.41489 0 0 72 1.07091 1.35932 0.02513 0.37378 −1.49870 −1.42231 0 0

TABLE-US-00027 TABLE 18C Killing Assay (A*02:01 targets; Cohort 2 donor 941176; Validated Pool) Relative target cell count Elapsed DMSO + Min_validated + Min_validated + DMSO + time (h) Targets Targets 10:1 E:T 10:1 E:T 0 0 0 0 0 0 0 0 0 4 0.01532 0.05102 0.01980 0.07975 0.01998 −0.00068 0 0 8 0.05280 0.04899 0.07623 0.06806 0.01093 −0.02192 0 0 12 0.10320 0.10773 0.11381 0.11013 −0.03526 −0.07110 0 0 16 0.20356 0.14613 0.22404 0.17072 −0.07934 −0.14204 0 0 20 0.26641 0.21665 0.29396 0.19666 −0.17641 −0.22310 0 0 24 0.41793 0.26733 0.38457 0.26444 −0.28684 −0.34405 0 0 28 0.45493 0.30914 0.50778 0.34286 −0.42130 −0.44097 0 0 32 0.53945 0.42156 0.64327 0.42477 −0.52726 −0.56755 0 0 36 0.67100 0.48433 0.76177 0.48536 −0.69071 −0.69946 0 0 40 0.79428 0.56346 0.89700 0.53973 −0.84661 −0.83568 0 0 44 0.92184 0.70204 1.07137 0.62367 −0.95901 −0.94594 0 0 48 1.02424 0.79970 1.20774 0.70555 −1.06150 −0.98164 0 0 52 1.10741 0.89832 1.25933 0.74321 −1.17078 −1.04230 0 0 56 1.19650 1.00048 1.36889 0.80313 −1.22608 −1.06541 0 0 60 1.30822 1.07780 1.46006 0.78342 −1.26770 −1.08377 0 0 64 1.39824 1.22429 1.56200 0.86895 −1.24641 −1.05659 0 0 68 1.50965 1.34178 1.64143 0.95012 −1.24737 −1.04084 0 0 72 1.60292 1.43251 1.73939 1.00085 −1.23876 −1.01696 0 0

TABLE-US-00028 TABLE 18D Killing Assay (A*02:01 targets; Cohort 2 donor 941176; ORF3a Pool) Relative target cell count Elapsed DMSO + Min_ORF3a + Min_ORF3a + DMSO + time (h) Targets Targets 10:1 E:T 10:1 E:T 0 0 0 0 0 0 0 0 0 4 0.01532 0.05102 0.01368 0.03929 −0.01362 0.02079 0 0 8 0.05280 0.04899 0.03835 0.05745 −0.01528 −0.00445 0 0 12 0.10320 0.10773 0.07735 0.07435 −0.04046 −0.04591 0 0 16 0.20356 0.14613 0.13914 0.11389 −0.06285 −0.06571 0 0 20 0.26641 0.21665 0.20388 0.18453 −0.13547 −0.15319 0 0 24 0.41793 0.26733 0.29916 0.23321 −0.19915 −0.22668 0 0 28 0.45493 0.30914 0.36812 0.28277 −0.25720 −0.30765 0 0 32 0.53945 0.42156 0.45725 0.37443 −0.32992 −0.38155 0 0 36 0.67100 0.48433 0.55619 0.42135 −0.44857 −0.44952 0 0 40 0.79428 0.56346 0.64631 0.44819 −0.51089 −0.51524 0 0 44 0.92184 0.70204 0.72227 0.51756 −0.53635 −0.53062 0 0 48 1.02424 0.79970 0.79836 0.57155 −0.56778 −0.54288 0 0 52 1.10741 0.89832 0.83831 0.56846 −0.61847 −0.52513 0 0 56 1.19650 1.00048 0.86442 0.56057 −0.60504 −0.46411 0 0 60 1.30822 1.07780 0.91177 0.56276 −0.63331 −0.40439 0 0 64 1.39824 1.22429 0.96549 0.60834 −0.57249 −0.30643 0 0 68 1.50965 1.34178 1.05166 0.64282 −0.51845 −0.24072 0 0 72 1.60292 1.43251 1.07900 0.65671 −0.51894 −0.17774 0 0

TABLE-US-00029 TABLE 18E Killing Assay (A*02:01 targets; Cohort 2 donor 941176; Nucleocapsid Pool) Relative target cell count Elapsed DMSO + Min_Nuc + Min_Nuc + DMSO + time (h) Targets Targets 10:1 E:T 10:1 E:T 0 0 0 0 0 0 0 0 0 4 0.01532 0.05102 0.06988 0.06566 0.04388 0.03412 0 0 8 0.05280 0.04899 0.10368 0.08263 0.02480 0.01346 0 0 12 0.10320 0.10773 0.16203 0.14887 −0.03506 −0.01521 0 0 16 0.20356 0.14613 0.27849 0.20725 −0.06824 −0.03866 0 0 20 0.26641 0.21665 0.35316 0.29750 −0.15670 −0.09212 0 0 24 0.41793 0.26733 0.46095 0.37671 −0.26481 −0.15582 0 0 28 0.45493 0.30914 0.52183 0.46726 −0.37496 −0.22656 0 0 32 0.53945 0.42156 0.65115 0.57861 −0.49673 0.29697 0 0 36 0.67100 0.48433 0.74409 0.66137 −0.59813 −0.37287 0 0 40 0.79428 0.56346 0.82654 0.71687 −0.74050 −0.44543 0 0 44 0.92184 0.70204 0.93208 0.80231 −0.79674 −0.46168 0 0 48 1.02424 0.79970 0.99082 0.89097 −0.84785 −0.41341 0 0 52 1.10741 0.89832 0.98485 0.89494 −0.91387 −0.39943 0 0 56 1.19650 1.00048 1.03040 0.90153 −0.93826 −0.34660 0 0 60 1.30822 1.07780 1.03495 0.92227 −0.92267 −0.23926 0 0 64 1.39824 1.22429 1.08957 0.94305 −0.86242 −0.10813 0 0 68 1.50965 1.34178 1.15787 0.95883 −0.79271 −0.00004 0 0 72 1.60292 1.43251 1.15891 1.00420 −0.71833 0.10316 0 0

TABLE-US-00030 TABLE 18F Killing Assay (A*01:01 targets; Cohort 2 donor 941176; Validated Pool) Relative target cell count Elapsed DMSO + Min_validated + Min_validated + DMSO + time (h) Targets Targets 10:1 E:T 10:1 E:T 0 0 0 0 0 0 0 0 0 4 −0.00284 0.01628 0.01164 0.02806 −0.00481 −0.00230 0 0 8 0.01606 0.04954 0.02006 0.04011 −0.03412 −0.02824 0 0 12 0.03544 0.06344 0.03761 0.03133 −0.10772 −0.10357 0 0 16 0.03345 0.09939 0.05219 0.03391 −0.21493 −0.20084 0 0 20 0.04076 0.15370 0.05645 0.07571 −0.33537 −0.32725 0 0 24 0.05222 0.17418 0.04442 0.04639 −0.48362 −0.49250 0 0 28 0.04138 0.15250 0.03472 0.01965 −0.65441 −0.69972 0 0 32 0.03916 0.20562 0.00387 −0.01295 −0.80356 −0.88981 0 0 36 −0.00388 0.21695 −0.05668 −0.07407 −0.97688 −1.08562 0 0 40 0.00534 0.21979 −0.08429 −0.14606 −1.13143 −1.30116 0 0 44 −0.05556 0.19879 −0.20322 −0.26276 −1.33045 −1.56024 0 0 48 −0.14279 0.18486 −0.33548 −0.33312 −1.47928 −1.74150 0 0

TABLE-US-00031 TABLE 18G Killing Assay (A*01:01 targets; Cohort 2 donor 941176; ORF3a Pool) Relative target cell count Elapsed DMSO + Min_ORF3a + Min_ORF3a + DMSO + time (h) Targets Targets 10:1 E:T 10:1 E:T 0 0 0 0 0 0 0 0 0 4 −0.00284 0.01628 −0.00216 0.00098 −0.02567 −0.02000 0 0 8 0.01606 0.04954 0.01839 0.02279 −0.06198 −0.03657 0 0 12 0.03544 0.06344 0.01086 0.01999 −0.12803 −0.08670 0 0 16 0.03345 0.09939 0.03392 0.02923 −0.24304 −0.19017 0 0 20 0.04076 0.15370 0.07146 0.07884 −0.37250 −0.26712 0 0 24 0.05222 0.17418 0.05489 0.03191 −0.52066 −0.42126 0 0 28 0.04138 0.15250 0.04243 −0.00206 −0.67981 −0.57430 0 0 32 0.03916 0.20562 0.04402 −0.03128 −0.85585 −0.72448 0 0 36 −0.00388 0.21695 −0.02876 −0.09311 −1.05716 −0.93759 0 0 40 0.00534 0.21979 −0.04476 −0.16798 −1.20532 −1.10825 0 0 44 −0.05556 0.19879 −0.18976 −0.31475 −1.40741 −1.29687 0 0 48 −0.14279 0.18486 −0.30639 −0.43802 −1.57375 −1.45681 0 0

TABLE-US-00032 TABLE 18H Killing Assay (A*30:01 targets; Cohort 2 donor 627934; Validated Pool) Relative target cell count Elapsed DMSO + Min_validated + Min_validated + DMSO + time (h) Targets Targets 10:1 E:T 10:1 E:T 0 0 0 0 0 0 0 0 0 4 0.14476 0.09327 0.16433 0.06812 −0.02616 −0.11036 0 0 8 0.26109 0.24031 0.29409 0.21405 −0.00841 −0.12349 0 0 12 0.41641 0.38357 0.46022 0.33232 −0.04628 −0.17861 0 0 16 0.57109 0.55916 0.64263 0.47700 −0.06324 −0.19195 0 0 20 0.71596 0.74668 0.82375 0.65480 −0.07662 −0.19019 0 0 24 0.85929 0.90606 0.97835 0.77732 −0.10886 −0.24283 0 0 28 0.98584 1.04005 1.13307 0.89219 −0.12589 −0.29120 0 0 32 0.98799 1.14837 1.26068 0.95485 −0.16668 −0.32411 0 0 36 1.07778 1.22604 1.15367 1.00185 −0.19570 −0.40280 0 0 40 0.94477 1.30988 1.28494 0.92435 −0.22909 −0.45282 0 0 44 1.16094 1.37581 1.37739 0.94905 −0.25701 −0.50637 0 0 48 1.19754 1.42495 1.42641 0.95483 −0.28341 −0.56072 0 0 52 1.24927 1.46355 1.46869 0.95714 −0.32908 −0.60275 0 0 56 1.26951 1.51115 1.48650 0.98242 −0.35821 −0.62717 0 0 60 1.29201 1.52120 1.46502 0.93525 −0.40945 −0.66624 0 0 64 1.32653 1.52998 1.49070 0.92126 −0.42804 −0.66927 0 0 68 1.30790 1.53903 1.44162 0.89081 −0.49563 −0.69120 0 0 72 1.27679 1.54121 1.40280 0.88028 −0.53668 −0.68332 0 0

TABLE-US-00033 TABLE 18I Killing Assay (A*30:01 targets; Cohort 2 donor 627934; Nucleocapsid Pool) Relative target cell count Elapsed DMSO + Min_Nuc + Min_Nuc + DMSO + time (h) Targets Targets 10:1 E:T 10:1 E:T 0 0 0 0 0 0 0 0 0 4 0.14476 0.09327 0.15397 0.10632 −0.06036 −0.07382 0 0 8 0.26109 0.24031 0.30186 0.22025 −0.11788 −0.05358 0 0 12 0.41641 0.38357 0.44388 0.34536 −0.14901 −0.08479 0 0 16 0.57109 0.55916 0.62546 0.51887 −0.19338 −0.11071 0 0 20 0.71596 0.74668 0.80756 0.69603 −0.20924 −0.06784 0 0 24 0.85929 0.90606 0.96860 0.83152 −0.23543 −0.09405 0 0 28 0.98584 1.04005 1.09160 0.94415 −0.27641 −0.09959 0 0 32 0.98799 1.14837 1.18284 1.01868 −0.32138 −0.13529 0 0 36 1.07778 1.22604 1.26497 0.93323 −0.40293 −0.20220 0 0 40 0.94477 1.30988 1.31387 0.99957 −0.45485 −0.23347 0 0 44 1.16094 1.37581 1.33523 1.02328 −0.47735 −0.25642 0 0 48 1.19754 1.42495 1.35208 1.01466 −0.51604 −0.30221 0 0 52 1.24927 1.46355 1.33143 1.00554 −0.55506 −0.33146 0 0 56 1.26951 1.51115 1.29058 1.00229 −0.60007 −0.33969 0 0 60 1.29201 1.52120 1.23831 0.97154 −0.64282 −0.35910 0 0 64 1.32653 1.52998 1.19719 0.95325 −0.66688 −0.35434 0 0 68 1.30790 1.53903 1.08141 0.94658 −0.70861 −0.33438 0 0 72 1.27679 1.54121 0.96905 0.91293 −0.74903 −0.31328 0 0

TABLE-US-00034 TABLE 18J Killing Assay (A*03:01 targets; Cohort 2 donor 627934; Validated Pool) Relative target cell count Elapsed DMSO + Min_validated + Min_validated + DMSO + time (h) Targets Targets 10:1 E:T 10:1 E:T 0 0 0 0 0 0 0 0 0 4 0.08781 0.05963 0.11622 0.08086 0.04206 −0.05415 0 0 8 0.14332 0.10822 0.16564 0.13178 0.00529 −0.11096 0 0 12 0.27527 0.18187 0.27835 0.24878 0.01055 −0.15157 0 0 16 0.40269 0.20477 0.42135 0.35832 −0.01181 −0.19062 0 0 20 0.49504 0.35270 0.55662 0.48411 −0.01763 −0.21009 0 0 24 0.60978 0.43822 0.67126 0.58290 −0.02953 −0.26287 0 0 28 0.72247 0.47024 0.78706 0.68684 −0.05697 −0.32551 0 0 32 0.80966 0.53925 0.79661 0.76714 −0.05774 −0.35916 0 0 36 0.91979 0.54476 0.87868 0.75431 −0.13110 −0.47610 0 0 40 0.82506 0.59488 0.85789 0.81567 −0.15046 −0.52954 0 0 44 0.89624 0.61217 0.93873 0.71403 −0.18150 −0.57730 0 0 48 0.94128 0.63571 0.99012 0.75434 −0.19083 −0.62099 0 0 52 0.95310 0.65967 1.00391 0.77013 −0.23838 −0.68264 0 0 56 0.97468 0.68263 1.00001 0.78528 −0.26245 −0.72252 0 0 60 0.97790 0.74183 1.00772 0.79326 −0.28918 −0.69767 0 0 64 0.99431 0.75242 1.02235 0.79916 −0.31783 −0.79814 0 0 68 1.01182 0.73655 1.04129 0.80057 −0.30320 −0.78695 0 0 72 1.00329 0.70559 1.07602 0.75102 −0.29658 −0.81701 0 0

TABLE-US-00035 TABLE 18K Killing Assay (A*03:01 targets; Cohort 2 donor 627934; Nucleocapsid Pool) Relative target cell count Elapsed DMSO + Min_Nuc + Min_Nuc + DMSO + time (h) Targets Targets 10:1 E:T 10:1 E:T 0 0 0 0 0 0 0 0 0 4 0.08781 0.05963 0.13557 0.09417 0.04270 0.00347 0 0 8 0.14332 0.10822 0.19202 0.18754 −0.03953 −0.01646 0 0 12 0.27527 0.18187 0.34927 0.29990 −0.04551 −0.04730 0 0 16 0.40269 0.20477 0.51671 0.45493 −0.08229 −0.07810 0 0 20 0.49504 0.35270 0.69613 0.60546 −0.08281 −0.09829 0 0 24 0.60978 0.43822 0.83645 0.75879 −0.13127 −0.13499 0 0 28 0.72247 0.47024 0.98696 0.91143 −0.15017 −0.16452 0 0 32 0.80966 0.53925 1.12928 1.00969 −0.17858 −0.17565 0 0 36 0.91979 0.54476 1.02635 1.08915 −0.23553 −0.23020 0 0 40 0.82506 0.59488 1.19327 1.15912 −0.25960 −0.25894 0 0 44 0.89624 0.61217 1.26278 1.23350 −0.29894 −0.28136 0 0 48 0.94128 0.63571 1.36362 1.27188 −0.30640 −0.31069 0 0 52 0.95310 0.65967 1.39987 1.27689 −0.36619 −0.36053 0 0 56 0.97468 0.68263 1.41729 1.29205 −0.38330 −0.35798 0 0 60 0.97790 0.74183 1.45720 1.37160 −0.41308 −0.29853 0 0 64 0.99431 0.75242 1.48982 1.17613 −0.48758 −0.30734 0 0 68 1.01182 0.73655 1.53320 1.20548 −0.44282 −0.32877 0 0 72 1.00329 0.70559 1.54367 1.18132 −0.44307 −0.34385 0 0

TABLE-US-00036 TABLE 18L Killing Assay (A*11:01 targets; Cohort 2 donor 602232; Validated Pool) Relative target cell count Elapsed DMSO + Min_validated + Min_validated + DMSO + time (h) Targets Targets 10:1 E:T 10:1 E:T 0 0 0 0 0 0 0 0 0 4 0.14476 0.09327 0.15397 0.10632 −0.06036 −0.07382 0 0 8 0.26109 0.24031 0.30186 0.22025 −0.11788 −0.05358 0 0 12 0.41641 0.38357 0.44388 0.34536 −0.14901 −0.08479 0 0 16 0.57109 0.55916 0.62546 0.51887 −0.19338 −0.11071 0 0 20 0.71596 0.74668 0.80756 0.69603 −0.20924 −0.06784 0 0 24 0.85929 0.90606 0.96860 0.83152 −0.23543 −0.09405 0 0 28 0.98584 1.04005 1.09160 0.94415 −0.27641 −0.09959 0 0 32 0.98799 1.14837 1.18284 1.01868 −0.32138 −0.13529 0 0 36 1.07778 1.22604 1.26497 0.93323 −0.40293 −0.20220 0 0 40 0.94477 1.30988 1.31387 0.99957 −0.45485 −0.23347 0 0 44 1.16094 1.37581 1.33523 1.02328 −0.47735 −0.25642 0 0 48 1.19754 1.42495 1.35208 1.01466 −0.51604 −0.30221 0 0 52 1.24927 1.46355 1.33143 1.00554 −0.55506 −0.33146 0 0 56 1.26951 1.51115 1.29058 1.00229 −0.60007 −0.33969 0 0 60 1.29201 1.52120 1.23831 0.97154 −0.64282 −0.35910 0 0 64 1.32653 1.52998 1.19719 0.95325 −0.66688 −0.35434 0 0 68 1.30790 1.53903 1.08141 0.94658 −0.70861 −0.33438 0 0 72 1.27679 1.54121 0.96905 0.91293 −0.74903 −0.31328 0 0

[0717] XIV.J. SARS-CoV-2 Prime-Boost Regimens Featuring Spike Proteins from Different Isolates Produces Responses to Spike in Non-Human Primates

[0718] ChAd and SAM vaccine platforms encoding different isolates of the SARS-CoV-2 Spike protein were assessed in Indian rhesus macaques as part of homologous or heterologous prime/boost regimens, as shown in FIG. 34 and presented in Table 19.

TABLE-US-00037 TABLE 19 NHP Study Design for SARS-CoV-2 Isolate Vaccine Regimens Group # Prime (week 0) Boost 1 (week 6 or 8) Boost 2 (week 30) 1 SAM-S.sub.D614G; 300 ug SAM-S.sub.D614G; 300 ug ChAd-S.sub.B1351-TCE5; 5e11 vp 2 SAM-S.sub.D614G; 30 ug SAM-S.sub.D614G; 30 ug SAM-TCE5-S.sub.B1351; 30 ug 5 ChAd-S.sub.D614G; 1e12 vp SAM-S.sub.D614G; 100 ug SAM-TCE5-S.sub.B1351; 30 ug 6 ChAd.S.sub.D614G; 5e10 vp SAM-S.sub.D614G; 100 ug ChAd-S.sub.B1351-TCE5; 5e11 vp Prime: ChAdV - “CTSpike.sub.g” (SEQ ID NO: 79); SAM - “IDTSpike.sub.g” (SEQ ID NO: 69) Boost 1: SAM - “IDTSpike.sub.g” (SEQ ID NO: 69) Boost 2: all CT-F2P versions of Spike variant B.1.351; TCE5 see Table 10

[0719] NHPs were first immunized with a priming dose of either a ChAd platform including a Spike-encoding cassette featuring “ChAd-S.sub.D614G; CT” (SEQ ID NO:79) or a SAM platform including a Spike-encoding cassette featuring “SAM-S.sub.D614G; IDT” (SEQ ID NO:69) at the indicated doses. NHPs were then administered a first boost at weeks 6 or 8 with the SAM platform including a Spike-encoding cassette featuring “SAM-S.sub.D614G; IDT” at the indicated doses. NHPs were then administered a second boost at week 30 with either a ChAd platform including a B.1.351 Spike variant-encoding cassette featuring Cool Tool sequence optimization (“CT”) and the F2P modification described herein (“F2P”) [SEQ ID NO:112] or a SAM platform including the same B.1.351 Spike variant (each platform also included the TCE5 T cell epitope cassette, see Table 10, in the orientation shown). The ChAdV antigen cassette is shown in SEQ ID NO:113. NHPs were monitored over time, as described herein.

[0720] As shown in FIGS. 35A, 35B, 35C, and 35D, the various vaccine regimens (Groups 1, 2, 5, and 6, respectively) produced T cell responses across multiple Spike T cell epitope pools (top panels). T cell responses for individual NHPs directed to a single large Spike T cell epitope pool was heterogenous (middle panels and summarized in FIG. 36 top panel), with each boost generally producing an increased T cell response, including production of a robust response in some (e.g., two NHPs in Group 1 following Boost 2). Spike-specific IgG antibody titers were detected and increased following each boost (bottom panels and summarized in FIG. 36 bottom panel) in all five NHP animals assessed. T cell responses to the TCE5-encoded epitopes, though generally small, trended upwards following Boost 2 (the first administration of a vaccine including TCE5), with generally stronger responses with administration of the ChAdV platform vaccine (FIG. 36 middle panel). Accordingly, the data demonstrate a vaccine regimen including a boost with a Spike variant encoding vaccine produced T cell and antibody responses.

[0721] Antibody responses were further assessed for neutralizing antibody production to both the D614G pseudovirus and B.1.351 pseudovirus. As shown in FIG. 37, neutralizing antibody (Nab) titers against the D614G pseudovirus were detected following Boost 1 across the four groups, with Nab titers generally the same following Boost 2 (left panels). Following Boost 1, cross-neutralizing antibody titers against the B.1.351 pseudovirus, while detected, were distinctly lower than the Nab titer against the D614G pseudovirus (right panel, column 1). However, following administration of Boost 2 encoding the B.1.351 spike variant, Nab titers against the B.1.351 pseudovirus were noticeably increased (right panels, column 2), notably with similar Nab titer levels to that against the D614G pseudovirus following Boost 1. These results are further demonstrated in FIG. 38, comparing the relative Nab titer levels against each of the pseudoviruses illustrating the reduced cross-neutralizing capacity against the B.1.351 pseudovirus following Boost 1 (top panels) and rescuing of the same following Boost 2 (bottom panels) across each of the vaccine regimens assessed.

[0722] The data demonstrate the various vaccine regimens produced both T cell and antibody responses against the encoded antigens in NHPs, notably demonstrating subsequent immunization with Spike variant encoding vaccines noticeably improved Nab titers against the respective variant pseudovirus.

[0723] XIV.K. SARS-CoV-2 Vaccine Clinical Assessment in Human Subjects

[0724] A phase 1, open-label, dose escalation, non-randomized study of homologous and heterologous prime-boost vaccination schedules to examine safety, tolerability, and immunogenicity of investigational Chimpanzee Adenovirus serotype 68 (ChAd) and self-amplifying mRNA (SAM) vectors expressing either Severe Acute Respiratory Syndrome Coronavirus 2 (SARS-CoV-2) spike alone, or spike plus additional SARS-CoV-2 T cell epitopes (TCE), such as epitopes presented in Tables A-F or T cell epitope cassettes described in Tables 10, 12A, 12B, or 12C, in healthy adult subjects is conducted. Stage 1 compares ChAd and SAM vaccines encoding only the spike protein in a 2-group dose escalation trial in subjects 18-60 years old, and a 3-group dose escalation trial in subjects over 60 years old, focusing on heterologous ChAd prime/SAM boost and homologous SAM prime/SAM boost regimens including sentinels, and staggered enrollment for dose escalation. Stage 2 compares optimal doses of ChAd and SAM vaccines (determined in Stage 1) encoding both spike and TCE, in subjects 18 years and older enrolled into up to 6 groups simultaneously to receive homologous SAM prime/SAM boost, homologous ChAd prime/ChAd boost and heterologous ChAd prime/SAM boost combinations. Up to 70 (Stage 1) and up to 70 (Stage 2) males and non-pregnant females>/=18 years of age who are in good health, do not have high risks for SARS-CoV-2 infection or for severe Coronavirus Disease 2019 (COVID-19) disease progression, and meet all eligibility criteria will be enrolled. Subjects will be enrolled at one of at least 4 distinct US-based Infectious Diseases Clinical Research Consortium (IDCRC) sites into different groups based on their age (18-60 and >60 years old). The primary objective of this study is to assess the safety and tolerability of different doses of ChAd-S (or ChAd-S-TCE) and SAM-S (or SAM-S-TCE) when administered as prime and/or boost in healthy adult subjects including older adult subjects.

[0725] ChAdV68-S: Chimpanzee Adenovirus serotype 68—Spike (ChAdV68-S) is a replication-defective, E1, E3 E4Orf2-4 deleted adenoviral vector based on chimpanzee adenovirus 68 (C68, 68/SAdV-25, originally designated as Pan 9), which belongs to the sub-group E adenovirus family. A single 0.5 mL or 1.0 mL intramuscular injection (depending on dose level) is administered in the deltoid muscle. When possible, the prime vaccine and boost vaccine is administered in different arms.

[0726] SAM-LNP-S: Self-Amplifying mRNA—Lipid Nanoparticles—Spike (SAM-LNP-S) is a SAM vector based on Venezuelan Equine Encephalitis Virus (VEEV). A single 0.5 mL intramuscular injection is administered in the deltoid muscle. When possible, the prime vaccine and boost vaccine is administered in different arms.

[0727] ChAdV68-S-TCE: Chimpanzee Adenovirus 68—Spike plus additional SARS-CoV-2 T cell epitopes (ChAdV68-S-TCE) is a replication-defective, E1, E3 E4Orf2-4 deleted adenoviral vector based on chimpanzee adenovirus 68 (C68, 68/SAdV-25, originally designated as Pan 9), which belongs to the sub-group E adenovirus family. A single 0.5- or 1.0-mL intramuscular injection will be administered in the deltoid muscle. When possible, the prime vaccine and boost vaccine should be administered in different arms.

[0728] SAM-LNP-S-TCE: Self-Amplifying mRNA—Lipid Nanoparticles—Spike plus additional SARS-CoV-2 T cell epitopes (SAM-S-TCE) is a SAM vector based on Venezuelan Equine Encephalitis Virus (VEEV). A single 0.5 mL intramuscular injection will be administered in the deltoid muscle. When possible, the prime vaccine and boost vaccine should be administered in different arms.

[0729] The diluent used for this study is 0.9% Sodium Chloride Injection, USP, and is a sterile, nonpyrogenic, isotonic solution of sodium chloride and water for injection. Each milliliter (mL) contains sodium chloride 9 mg. It contains no bacteriostat, antimicrobial agent or added buffer and is supplied only in single-dose containers to dilute or dissolve drugs for injection. 0.308 mOsmol/mL (calc.). 0.9% Sodium Chloride Injection, USP contains no preservatives.

[0730] The following groups are assessed: [0731] Stage 1 Group 1: 5×10{circumflex over ( )}10 viral particles of ChAdV68-S administered through 0.5 mL intramuscular injection in the deltoid muscle on Day 1 and 30 mcg of SAM-LNP-S administered through 0.5 mL intramuscular injection in the deltoid muscle on Day 29 in participants from 18 to 60 years of age. N=10 [0732] Stage 1 Group 2: 1×10{circumflex over ( )}11 viral particles of ChAdV68-S administered through 0.5 mL intramuscular injection in the deltoid muscle on Day 1 and 30 mcg of SAM-LNP-S administered through 0.5 mL intramuscular injection in the deltoid muscle on Day 29 in participants from 18 to 60 years of age. N=10 [0733] Stage 1 Group 3: 30 mcg of SAM-LNP-S administered through 0.5 mL intramuscular injection in the deltoid muscle on Day 1 and Day 29 in participants from 18 to 60 years of age. N=10 [0734] Stage 1 Group 4: 100 mcg of SAM-LNP-S administered through 0.5 mL intramuscular injection in the deltoid muscle on Day 1 and Day 29 in participants from 18 to 60 years of age. N=10 [0735] Stage 1 Group 5: 5×10{circumflex over ( )}10 viral particles of ChAdV68-S administered through 0.5 mL intramuscular injection in the deltoid muscle on Day 1 and 30 mcg of SAM-LNP-S administered through 0.5 mL intramuscular injection in the deltoid muscle on Day 29 in participants older than 60 years of age. N=10 [0736] Stage 1 Group 6: 1×10{circumflex over ( )}11 viral particles of ChAdV68-S administered through 0.5 mL intramuscular injection in the deltoid muscle on Day 1 and 30 mcg of SAM-LNP-S administered through 0.5 mL intramuscular injection in the deltoid muscle on Day 29 in participants older than 60 years of age. N=10 [0737] Stage 1 Group 7: 5×10{circumflex over ( )}11 viral particles of ChAdV68-S administered through 1.0 mL intramuscular injection in the deltoid muscle on Day 1 and 30 mcg of SAM-LNP-S administered through 0.5 mL intramuscular injection in the deltoid muscle on Day 29 in participants older than 60 years of age. N=10 [0738] Stage 2 Group 8: 5×10{circumflex over ( )}10 viral particles of ChAdV68-S-TCE OR 1×10{circumflex over ( )}11 viral particles of ChAdV68-S-TCE administered through 0.5 mL intramuscular injection in the deltoid muscle on Day 1 and 30 mcg of SAM-LNP-S-TCE administered through 0.5 mL intramuscular injection in the deltoid muscle on Day 57 in participants from 18 to 60 years of age. N=10 [0739] Stage 2 Group 9: 5×10{circumflex over ( )}10 viral particles of ChAdV68-S-TCE OR 1×10{circumflex over ( )}11 viral particles of ChAdV68-S-TCE OR 5×10{circumflex over ( )}11 viral particles of ChAdV68-S-TCE administered through 0.5 mL or 1.0 mL (for 5×10{circumflex over ( )}11 viral particles) intramuscular injection in the deltoid muscle on Day 1 and 30 mcg of SAM-LNP-S-TCE administered through 0.5 mL intramuscular injection in the deltoid muscle on Day 57 in participants older than 60 years of age. N=10 [0740] Stage 2 Group 10: 1×10{circumflex over ( )}11 viral particles of ChAdV68-S-TCE administered through 0.5 mL intramuscular injection in the deltoid muscle on Day 1 and Day 113 in participants from 18 to 60 years of age. N=10 [0741] Stage 2 Group 11: 1×10{circumflex over ( )}11 viral particles of ChAdV68-S-TCE administered through 0.5 mL intramuscular injection in the deltoid muscle on Day 1 and Day 113 OR 5×10{circumflex over ( )}11 viral particles of ChAdV68-S-TCE administered through 1.0 mL intramuscular injection in the deltoid muscle on Day 1 and Day 113 in participants older than 60 years of age. N=10 [0742] Stage 2 Group 12: 10 mcg of SAM-LNP-S-TCE administered through 0.5 mL intramuscular injection in the deltoid muscle on Day 1 and Day 57 in participants from 18 years of age or older. N=10. [0743] Stage 2 Group 13: 30 mcg of SAM-LNP-S-TCE administered through 0.5 mL intramuscular injection in the deltoid muscle on Day 1 and Day 57 in participants from 18 years of age and older. N=10 [0744] Stage 2 Group 14: 100 mcg of SAM-LNP-S-TCE administered through 0.5 mL intramuscular injection in the deltoid muscle on Day 1 and Day 57 in participants from 18 years of age and older. N=10

[0745] The following primary outcomes are assessed: [0746] Frequency by grade of solicited local reactogenicity adverse events (AEs) [Time Frame: Through 7 days post each vaccination] [0747] Frequency by grade of solicited systemic reactogenicity adverse events (AEs) [Time Frame: Through 7 days post each vaccination] [0748] Frequency by grade of unsolicited adverse events (AEs) [Time Frame: Through 28 days post each vaccination] [0749] Frequency of Adverse Events of Special Interest (AESIs) [Time Frame: Day 1 through Day 478]. Including potentially immune-mediated medical conditions (PIMMCs), medically attended adverse events (MAAEs), and new onset chronic medical conditions (NOCMCs) [0750] Frequency of clinical safety laboratory adverse events by severity grade [Time Frame: Through 7 days post each vaccination]. Parameters to be evaluated include: white blood cell count (WBC), hemoglobin (HgB), platelets (PLT), alanine aminotransferase (ALT), aspartate aminotransferase (AST), alkaline phosphatase (ALP), total bilirubin (T Bili), creatine kinase (CK), and creatinine (Cr) [0751] Frequency of Serious Adverse Events (SAEs) [Time Frame: Day 1 through Day 478]

[0752] The following secondary outcomes are assessed: [0753] Geometric mean fold rise from baseline in titer measured by a SARS-CoV-2 neutralization assay, for wild-type virus and emergent viral strains [Time Frame: Day 1 through Day 478] [0754] Geometric mean fold rise from baseline in titer of receptor-binding domain (RBD) specific Immunoglobulin G (IgG) [Time Frame: Day 1 through Day 478]. Measured by an Enzyme-Linked Immunosorbent Assay (ELISA), for RBD from wild-type virus and emergent viral strains [0755] Geometric mean fold rise from baseline in titer of Spike-specific Immunoglobulin G (IgG) [Time Frame: Day 1 through Day 478]. Measured by an Enzyme-Linked Immunosorbent Assay (ELISA), for spike protein from wild-type virus and emergent viral strains [0756] Geometric mean titer measured by a SARS-CoV-2 neutralization assay, for wild-type virus and emergent viral strains [Time Frame: Day 1 through Day 478] [0757] Geometric mean titer of receptor-binding domain (RBD) specific Immunoglobulin G (IgG) [Time Frame: Day 1 through Day 478]. Measured by an Enzyme-Linked Immunosorbent Assay (ELISA), for RBD from wild-type virus and emergent viral strains [0758] Geometric mean titer of Spike-specific Immunoglobulin G (IgG) [Time Frame: Day 1 through Day 478]. Measured by an Enzyme-Linked Immunosorbent Assay (ELISA), for spike protein from wild-type virus and emergent viral strains [0759] Percent of cells expressing a cytokine by cell type (CD4+ or CD8+), cytokine set (Th1 or Th2 cytokine for CD4+ and CD8+ cytokine for CD8+ or other combinations of interest) and peptide pool (covering spike and T cell epitope regions) [Time Frame: Day 1 through Day 478]. As determined by ICS [0760] Percentage of subjects who seroconverted, for RBD from wild-type virus and emergent viral strains [Time Frame: Day 1 through Day 478]. Seroconversion defined as a 4-fold change in receptor-binding domain (RBD) specific IgG from baseline measured by ELISA. Including against emergent viral strains, e.g., B.1.1.7., as assessed by a range of assays measuring total Spike-specific Immunoglobulin G (IgG) (Enzyme-Linked Immunosorbent Assay (ELISA)-based) and function (neutralization, receptor-binding domain (RBD) binding, or similar) in serum [0761] Percentage of subjects who seroconverted, for spike protein from wild-type virus and emergent viral strains [Time Frame: Day 1 through Day 478]. Seroconversion defined as a 4-fold change in Spike-specific Immunoglobulin G (IgG) from baseline measured by an Enzyme-Linked Immunosorbent Assay (ELISA). Including against emergent viral strains, e.g., B.1.1.7., as assessed by a range of assays measuring total Spike-specific Immunoglobulin G (IgG) (Enzyme-Linked Immunosorbent Assay (ELISA)-based) and function (neutralization, receptor-binding domain (RBD) binding, or similar) in serum [0762] Percentage of subjects who seroconverted, for wild-type virus and emergent viral strains [Time Frame: Day 1 through Day 478]. Seroconversion defined as a 4-fold change in titer from baseline measured by a SARS-CoV-2 neutralization assay. Including against emergent viral strains, e.g., B.1.1.7., as assessed by a range of assays measuring total Spike-specific Immunoglobulin G (IgG) (Enzyme-Linked Immunosorbent Assay (ELISA)-based) and function (neutralization, receptor-binding domain (RBD) binding, or similar) in serum [0763] Rate of spot-forming cell per million cells by peptide pool (covering spike and T cell epitope regions) [Time Frame: Day 1 through Day 478]. As determined by interferon (IFN) gamma Enzyme Linked Immunospot Assay (ELISpot) [0764] Responder status, derived from the intracellular cytokine staining (ICS) cell counts for each set of applicable cytokines and each peptide pool [Time Frame: Day 1 through Day 478]. Covering spike and T cell epitope regions [0765] Responder status, determined by interferon (IFN) gamma Enzyme Linked Immunospot Assay (ELISpot) for each peptide pool [Time Frame: Day 1 through Day 478]. Covering spike and T cell epitope regions [0766] Th1/Th2 cytokine balance of T cell response [Time Frame: Through 28 days post boost vaccination]. By measuring interleukin (IL) 2, tumor necrosis factor (TNF) alpha, IL-4, IL-10, and IL-13 using a multiplexed cytokine assay with Enzyme Linked Immunospot Assay (ELISpot) supernatants in a subset of subjects

Additional Sequences

[0767] Table A

[0768] Refer to Sequence Listing, SEQ ID NOS. 130-8195. Presented is each candidate MHC Class I epitope encoded by SARS-CoV-2 that was predicted to associate with a given HLA allele with an EDGE score>0.001. Each entry includes the candidate epitope sequence and cognate HLA alleles with a predicted EDGE score greater than 0.001, with each cognate pairing ranked as H (EDGE score>0.1), M (EDGE score between 0.01 and 0.1), and L (EDGE score<0.01). For example, the candidate epitope MESLVPGF (SEQ ID NO: 127) is predicted to pair with HLA-B*18:01, HLA-B*37:01, and HLA-B*07:05 with EDGE scores 0.019, 0.032, and 0.008, respectively. Accordingly, the entry for SEQ ID NO: 130 is “MESLVPGF: B18:01M; B37:01M; B07:05L.”

[0769] Table B

[0770] Refer to Sequence Listing, SEQ ID NOS. 8196-26740. Presented is each candidate MHC Class II epitope encoded by SARS-CoV-2 that was predicted to associate with a given HLA allele with an EDGE score>0.001. Each entry includes the candidate epitope sequence and cognate HLA alleles with a predicted EDGE score greater than 0.001, with each cognate pairing ranked as H (EDGE score>0.1), M (EDGE score between 0.01 and 0.1), and L (EDGE score<0.01). For example, the candidate epitope VELVAELEGI (SEQ ID NO: 128) is predicted to pair with HLA-DQA1*03:02-B1*03:03, HLA-DRB1*11:02, HLA-DQA1*05:05-B1*03:19, and HLA-DPA1*01:03-B1*104:01 with EDGE scores 0.003145, 0.00328, 0.041097, and 0.011613, respectively. Accordingly, the entry for SEQ ID NO: 8219 is “VELVAELEGI: DQA1*03:02-B1*03:03L; DRB1*11:02L; DQA1*05:05-B1*03:19M; DPA1*01:03-B1*104:01M.” Only HLA-DQ and HLA-DP are referred to by their alpha and beta chains. HLA-DR is referred to only by its beta chain as the alpha chain is generally invariable in the human population, with HLA-DR peptide contact regions particularly invariant.

[0771] Table C

[0772] Refer to Sequence Listing, SEQ ID NOS. 26741-27179. Presented are additional MHC Class I epitopes, other than those from the Spike protein, encoded within the optimized cassette that were predicted to associate with a given HLA allele with an EDGE score>0.001. The additional epitopes were determined by calculating population coverage criteria P with all initial epitopes provided by the SARS-CoV-2 Spike protein (SEQ ID NO:59) split into S1 and S2 and applying the optimization algorithms described herein.

[0773] Table D

[0774] Refer to Sequence Listing, SEQ ID NOS. 27180-27495, for SARS-CoV-2 Spike overlapping peptide pools. Each entry includes the stimulatory peptide, SARS-CoV-2 protein source, peptide subpool information, and Table. For example, the stimulatory peptide MFVFLVLLPLVSSQC (SEQ ID NO: 27180) is derived from SARS-CoV-2 Spike protein (Wuhan D614G variant), included in subpool S_Wu_1_2, and found in Table D. Accordingly, the entry for SEQ ID NO. 27180 is “MFVFLVLLPLVSSQC: Spike Wuhan D614G; S_Wu_1_2; Table D”.

[0775] Table E

[0776] Refer to Sequence Listing, SEQ ID NOS. 27496-27603, for TCE5-encoded overlapping peptide pools. Each entry includes the stimulatory peptide, SARS-CoV-2 protein source, peptide subpool information, and Table. For example, the stimulatory peptide LLWPVTLACFVLAAV (SEQ ID NO: 27496) is derived from SARS-CoV-2 Membrane protein, included in subpool OLP_Mem, and found in Table E. Accordingly, the entry for SEQ ID NO. 27496 is “LLWPVTLACFVLAAV: Membrane; OLP_Mem; Table E”.

[0777] Table F

[0778] Refer to Sequence Listing, SEQ ID NOS. 27604-27939, for TCE5-encoded minimal epitope peptide pools. Each entry includes the stimulatory peptide, SARS-CoV-2 protein source, peptide subpool information, and Table. For example, the stimulatory peptide ALSKGVHFV (SEQ ID NO: 27604) is derived from SARS-CoV-2 ORF3a protein (frame 52-85), included in subpool Min_validated, and found in Table F. Accordingly, the entry for SEQ ID NO. 27604 is “ALSKGVHFV: ORF3a 52-85; Min_validated; Table F”.

[0779] Certain additional sequences for vectors, cassettes, and antibodies referred to herein are described below and referred to by SEQ ID NO.

TABLE-US-00038 Tremelimumab VL (SEQ ID NO: 16) Tremelimumab VH (SEQ ID NO: 17) Tremelimumab VH CDR1 (SEQ ID NO: 18) Tremelimumab VH CDR2 (SEQ ID NO: 19) Tremelimumab VH CDR3 (SEQ ID NO: 20) Tremelimumab VL CDR1 (SEQ ID NO: 21) Tremelimumab VL CDR2 (SEQ ID NO: 22) Tremelimumab VL CDR3 (SEQ ID NO: 23) Durvalumab (MEDI4736) VL (SEQ ID NO: 24) MEDI4736 VH (SEQ ID NO: 25) MEDI4736 VH CDR1 (SEQ ID NO: 26) MEDI4736 VH CDR2 MEDI4736 VH CDR3 (SEQ ID NO: 28) MEDI4736 VL CDR1 (SEQ ID NO: 29) MEDI4736 VL CDR2 (SEQ ID NO: 30) MEDI4736 VL CDR3 (SEQ ID NO: 31) UbA76-25merPDTT nucleotide (SEQ ID NO: 32) UbA76-25merPDTT polypeptide (SEQ ID NO: 33) MAG-25merPDTT nucleotide (SEQ ID NO: 34) MAG-25merPDTT polypeptide (SEQ ID NO: 35) Ub7625merPDTT_NOSFL nucleotide (SEQ ID NO: 36) Ub7625merPDTT_NoSFL polypeptide (SEQ ID NO: 37) ChAdV68.5WTnt.MAG25mer (SEQ ID NO: 2); AC_000011.1 with E1 (nt 577 to 3403) and E3 (nt 27,125-31,825) sequences deleted; corresponding ATCC VR-594 nucleotides substituted at five positions; model neoantigen cassette under the control of the CMV promoter/enhancer inserted in place of deleted E1; SV40 poly A 3′ of cassette Venezuelan equine encephalitis virus [VEE (SEQ ID NO: 3) GenBank: L01442.2 VEE-MAG25mer (SEQ ID NO: 4); contains MAG-25merPDTT nucleotide (bases 30-1755) Venezuelan equine encephalitis virus strain TC-83 [TC-83(SEQ ID NO: 5) GenBank: L01443.1 VEE Delivery Vector (SEQ ID NO: 6); VEE genome with nucleotides 7544-11175 deleted [alphavirus structural proteins removed TC-83 Delivery Vector(SEQ ID NO: 7); TC-83 genome with nucleotides 7544-11175 deleted [alphavirus structural proteins removed VEE Production Vector (SEQ ID NO: 8); VEE genome with nucleotides 7544-11175 deleted, plus 5′ T7 promoter, plus 3′ restriction sites TC-83 Production Vector(SEQ ID NO: 9); TC-83 genome with nucleotides 7544-11175 deleted, plus 5′ T7- promoter, plus 3′ restriction sites VEE-UbAAY (SEQ ID NO: 14); VEE delivery vector with MHC class I mouse tumor epitopes SIINFEKL (SEQ ID NO: 129) and AH1-A5 inserted VEE-Luciferase (SEQ ID NO: 15); VEE delivery vector with luciferase gene inserted at 7545 ubiquitin (SEQ ID NO: 38) > UbG76 0-228 Ubiquitin A76 (SEQ ID NO: 39) > UbA76 0-228 HLA-A2 (MHC class I) signal peptide (SEQ ID NO: 40) > MHC SignalPep 0-78 HLA-A2 (MHC class I) Trans Membrane domain (SEQ ID NO: 41) > HLA A2 TM Domain 0-201 IgK Leader Seq (SEQ ID NO: 42) > IgK Leader Seq 0-60 Human DC-Lamp (SEQ ID NO: 43) > HumanDCLAMP 0-3178 Mouse LAMP1 (SEQ ID NO: 44) > MouseLamp1 0-1858 Human Lamp1 cDNA (SEQ ID NO: 45) > Human Lamp1 0-2339 Tetanus toxoid nulceic acid sequence (SEQ ID NO: 46) Tetanus toxoid amino acid sequence (SEQ ID NO: 47) PADRE nulceotide sequence (SEQ ID NO: 48) PADRE amino acid sequence (SEQ ID NO: 49) WPRE (SEQ ID NO: 50) > WPRE 0-593 IRES (SEQ ID NO: 51) > eGFP_IRES_SEAP_Insert 1746-2335 GFP (SEQ ID NO: 52) SEAP (SEQ ID NO: 53) Firefly Luciferase (SEQ ID NO: 54) FMDV 2A (SEQ ID NO: 55) GPGPG linker (SEQ ID NO: 56) chAd68-Empty-E4deleted (SEQ ID NO: 75): AC_000011.1 with E1 (nt 577 to 3403), E3 (nt 27,125-31,825), and E4 region (nt 34,916 to 35,642) sequences deleted and the corresponding ATCC VR-594 (Independently sequenced Full-Length VR-594 C68 SEQ ID NO: 10) nucleotides substituted at five positions NC_045512.2 Severe acute respiratory syndrome coronavirus 2 isolate Wuhan-Hu-1, complete genome (SEQ ID NO: 76) SAM in vitro transcription template DNA (SEQ ID NO: 77); VEE genome with nucleotides 7544-11175 deleted, plus minimal 5′ T7-promoter SV40 mini-intron (SEQ ID NO: 88) CMV-CTSpike-FurinMT2P-T2A-E-T2A-M-SV40-CMV-EPE-BGH Nucleotide sequence (SEQ ID NO: 109) VOC 202012/01 B.1.1.7 UK Spike variant Amino Acid Sequence (SEQ ID NO: 110) MFVFLVLLPLVSSQCVNLTTRTQLPPAYTNSFTRGVYYPDKVFRSSVLHSTQDLFLPFFSNVTW FHAISGTNGTKRFDNPVLPFNDGVYFASTEKSNIIRGWIFGTTLDSKTQSLLIVNNATNVVIKVCE FQFCNDPFLGVYHKNNKSWMESEFRVYSSANNCTFEYVSQPFLMDLEGKQGNFKNLREFVFK NIDGYFKIYSKHTPINLVRDLPQGFSALEPLVDLPIGINITRFQTLLALHRSYLTPGDSSSGWTAG AAAYYVGYLQPRTFLLKYNENGTITDAVDCALDPLSETKCTLKSFTVEKGIYQTSNFRVQPTESI VRFPNITNLCPFGEVFNATRFASVYAWNRKRISNCVADYSVLYNSASFSTFKCYGVSPTKLNDL CFTNVYADSFVIRGDEVRQIAPGQTGKIADYNYKLPDDFTGCVIAWNSNNLDSKVGGNYNYLY RLFRKSNLKPFERDISTEIYQAGSTPCNGVEGFNCYFPLQSYGFQPTYGVGYQPYRVVVLSFELL HAPATVCGPKKSTNLVKNKCVNFNFNGLTGTGVLTESNKKFLPFQQFGRDIDDTTDAVRDPQT LEILDITPCSFGGVSVITPGTNTSNQVAVLYQGVNCTEVPVAIHADQLTPTWRVYSTGSNVFQTR AGCLIGAEHVNNSYECDIPIGAGICASYQTQTNSHGSASSVASQSIIAYTMSLGAENSVAYSNNSI AIPINFTISVTTEILPVSMTKTSVDCTMYICGDSTECSNLLLQYGSFCTQLNRALTGIAVEQDKNT QEVFAQVKQIYKTPPIKDFGGFNFSQILPDPSKPSKRSFIEDLLFNKVTLADAGFIKQYGDCLGDI AARDLICAQKFNGLTVLPPLLTDEMIAQYTSALLAGTITSGWTFGAGAALQIPFAMQMAYRFN GIGVTQNVLYENQKLIANQFNSAIGKIQDSLSSTASALGKLQDVVNQNAQALNTLVKQLSSNFG AISSVLNDILARLDPPEAEVQIDRLITGRLQSLQTYVTQQLIRAAEIRASANLAATKMSECVLGQS KRVDFCGKGYHLMSFPQSAPHGVVFLHVTYVPAQEKNFTTAPAICHDGKAHFPREGVFVSNGT HWFVTQRNFYEPQUITTHNTFVSGNCDVVIGIVNNTVYDPLQPELDSFKEELDKYFKNHTSPDV DLGDISGINASVVNIQKEIDRLNEVAKNLNESLIDLQELGKYEQYIKWPWYIWLGFIAGLIAIVM VTIMLCCMTSCCSCLKGCCSCGSCCKFDEDDSEPVLKGVKLHYT* CMV-B117Spike-FurinMT2P-SV40-CMV-EPE-BGH (SEQ ID NO: 111) B.1.351Spike-FurinMt Amino Acid sequence (South African Spike Variant) (SEQ ID NO: 112) MFVFLVLLPLVSSQCVNFTTRTQLPPAYTNSFTRGVYYPDKVFRSSVLHSTQDLFLPFFSNVTWFHAIHVS GTNGTKRFANPVLPFNDGVYFASTEKSNIIRGWIFGTTLDSKTQSLLIVNNATNVVIKVCEFQFCNDPFLGV YYHKNNKSWMESEFRVYSSANNCTFEYVSQPFLMDLEGKQGNFKNLREFVFKNIDGYFKIYSKHTPINLV RGLPQGFSALEPLVDLPIGINITRFQTLHISYLTPGDSSSGWTAGAAAYYVGYLQPRTFLLKYNENGTITDA VDCALDPLSETKCTLKSFTVEKGIYQTSNFRVQPTESIVRFPNITNLCPFGEVFNATRFASVYAWNRKRISN CVADYSVLYNSASFSTFKCYGVSPTKLNDLCFTNVYADSFVIRGDEVRQIAPGQTGNIADYNYKLPDDFT GCVIAWNSNNLDSKVGGNYNYLYRLFRKSNLKPFERDISTEIYQAGSTPCNGVKGFNCYFPLQSYGFQPT YGVGYQPYRVVVLSFELLHAPATVCGPKKSTNLVKNKCVNFNFNGLTGTGVLTESNKKFLPFQQFGRDI ADTTDAVRDPQTLEILDITPCSFGGVSVITPGTNTSNQVAVLYQGVNCTEVPVAIHADQLTPTWRVYSTGS NVFQTRAGCLIGAEHVNNSYECDIPIGAGICASYQTQTNSPGSASSVASQSIIAYTMSLGVENSVAYSNNSI AIPTNFTISVTTEILPVSMTKTSVDCTMYICGDSTECSNLLLQYGSFCTQLNRALTGIAVEQDKNTQEVFAQ VKQIYKTPPIKDFGGFNFSQILPDPSKPSKRSFIEDLLFNKVTLADAGFIKQYGDCLGDIAARDLICAQKFNG LTVLPPLLTDEMIAQYTSALLAGTITSGWTFGAGAALQIPFAMQMAYRFNGIGVTQNVLYENQKLIANQF NSAIGKIQDSLSSTASALGKLQDVVNQNAQALNTLVKQLSSNFGAISSVLNDILSRLDPPEAEVQIDRLITG RLQSLQTYVTQQLIRAAEIRASANLAATKMSECVLGQSKRVDFCGKGYHLMSFPQSAPHGVVFLHVTYV PAQEKNFTTAPAICHDGKAHFPREGVFVSNGTHWFVTQRNFYEPQUITTDNTFVSGNCDVVIGIVNNTVYD PLQPELDSFKEELDKYFKNHTSPDVDLGDISGINASVVNIQKEIDRLNEVAKNLNESLIDLQELGKYEQYIK WPWYIWLGFIAGLIAIVMVTIMLCCMTSCCSCLKGCCSCGSCCKFDEDDSEPVLKGVKLHYT CMV-B.1351Spike-FurinMt-2P-CMV-TCE5-BGH (SEQ ID NO: 113); B.1.351 Spike sequence based on CT1 sequence optimization with relevant variant mutations replaced with COOL codons

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