LIVE SELF-DESTRUCTING BACTERIAL ADJUVANTS TO ENHANCE INDUCTION OF IMMUNITY
20230165955 · 2023-06-01
Inventors
Cpc classification
C12N15/74
CHEMISTRY; METALLURGY
A61K39/39
HUMAN NECESSITIES
A61K2039/58
HUMAN NECESSITIES
Y02A50/30
GENERAL TAGGING OF NEW TECHNOLOGICAL DEVELOPMENTS; GENERAL TAGGING OF CROSS-SECTIONAL TECHNOLOGIES SPANNING OVER SEVERAL SECTIONS OF THE IPC; TECHNICAL SUBJECTS COVERED BY FORMER USPC CROSS-REFERENCE ART COLLECTIONS [XRACs] AND DIGESTS
A61K2039/55572
HUMAN NECESSITIES
International classification
Abstract
Disclosed herein are unique adjuvant compositions comprising an attenuated derivative of a self-destructing bacterial pathogen that undergoes lysis in vivo. In exemplary embodiments, the bacterial pathogen is a Salmonella spp. Also disclosed are methods for enhancing an immune response using the adjuvants disclosed herein.
Claims
1. An adjuvant for the enhancement of vaccine efficacy, the adjuvant comprising an attenuated derivative of a bacterial pathogen that undergoes lysis in vivo.
2. The adjuvant of claim 1, wherein the bacterial pathogen is a Salmonella spp.
3. The adjuvant of claim 1 or 2, wherein the adjuvant comprises an attenuated Salmonella typhimurium (S. typhimurium) bacterium, comprising (a) one or more mutations facilitating lysis in vivo, comprising (i) ΔP.sub.murA::TT araC P.sub.araBAD murA or ΔP.sub.murA::TT rhaRS P.sub.rhaBAD murA, (ii) ΔasdA, (iii) ΔP.sub.asdA::TT araC P.sub.araBAD asdA or ΔP.sub.asdA::TT rhaRS P.sub.rhaBAD asdA, (iv) Δalr, (v) ΔdadB, or (vi) ΔP.sub.dadB::TT araC P.sub.araBAD dadB or ΔP.sub.dadB::TT rhaRS P.sub.rhaBAD dadB, or a combination thereof; (b) one or more mutations to enhance recruitment of innate immunity comprising (i) ΔpagP::P.sub.lpp lpxE and/or ΔlpxR::P.sub.lpp lpxF, (ii) ΔpagL or ΔpagP or (iii) ΔlpxR, ΔarnT, ΔeptA, ΔwaaC, ΔwaaG, ΔwaaL, ΔwbaP, Δpmi or Δrfc or a combination thereof; or (iv) ΔP.sub.stc::P.sub.murA stc and ΔstcABCD or ΔP.sub.saf::P.sub.murA saf and ΔsafABCD, or a combination thereof, or (c) a mutation enhancing safety and effective immunogenicity, comprising ΔsifA, ΔsopF, ΔrecA or ΔsopB; or a combination of (a) and with either (b) or (c).
4. The adjuvant of any of claims 1-3, wherein the adjuvant comprises an attenuated Salmonella typhimurium (S. typhimurium) bacterium comprising one or more mutations set forth in Tables 1 or 6
5. The adjuvant of any of claims 1-3, wherein the adjuvant comprises a Salmonella typhimurium (S. typhimurium) bacterium set forth in Tables 4, 5, 8 or 9.
6. The adjuvant of any of claims 1-5, wherein the adjuvant comprises an attenuated Salmonella typhimurium (S. typhimurium) bacterium comprising one or more mutations selected from the group consisting of ΔpagP8, ΔpagL7, ΔlpxR9, ΔarnT6 and ΔeptA4.
7. A composition comprising the adjuvant of any of claims 1-6 and a pharmaceutically acceptable carrier.
8. A method of augmenting induction of protective immunity by a vaccine, the method comprising administering an immune response enhancing amount of the adjuvant of any of claims 1-6.
9. The method of claim 8, wherein the vaccine comprises a subunit, killed, live attenuated, or vectored vaccine.
10. An adjuvant composition, the composition comprising the bacterium of any of claims 3-6.
11. A method of providing an induced protective immunity to a pathogen, comprising co-administering an adjuvant composition, comprising the adjuvant of any of claims 1-6, and co-administering a vaccine composition comprising an antigen to the pathogen.
12. A method of providing an induced protective immunity to a pathogen, comprising administering M. bovis BCG and co-administering an adjuvant composition comprising the adjuvant of any of claims 1-6.
13. The method of claim 12, further comprising co-administering a PIESV strain engineered to deliver one or more Mtb protective antigens.
14. The method of claim 13, wherein the PIESV strain is PIESV χ12068(pYA4891).
15. A method of providing an induced protective immunity to a pathogen, comprising administering M. bovis BCG and co-administering a PIESV strain engineered to deliver one or more Mtb protective antigens, and optionally an adjuvant.
16. The method of claim 15, wherein the PIESV strain engineered is PIESV χ12068(pYA4891).
17. The method of either of claim 15 or 16 further comprising co-administering an adjuvant composition comprising the adjuvant of any of claims 1-6.
18. The method of any of claims 15-17, wherein the adjuvant comprises an attenuated Salmonella typhimurium (S. typhimurium) bacterium, comprising (a) one or more mutations facilitating lysis in vivo, comprising (i) ΔP.sub.murA::TT araC P.sub.araBAD murA or ΔP.sub.murA::TT rhaRS P.sub.rhaBAD murA, (ii) ΔasdA, (iii) ΔP.sub.asdA::TT araC P.sub.araBAD asdA or ΔP.sub.asdA::TT rhaRS P.sub.rhaBAD asdA, (iv) Δalr, (v) ΔdadB, or (vi) ΔP.sub.dadB::TT araC P.sub.araBAD dadB or ΔP.sub.dadB::TT rhaRS P.sub.rhaBAD dadB, or a combination thereof; (b) one or more mutations to enhance recruitment of innate immunity comprising (i) ΔpagP::P.sub.lpp lpxE and/or ΔlpxR::P.sub.lpp lpxF, (ii) ΔpagL or ΔpagP or (iii) ΔlpxR, ΔarnT, ΔeptA, ΔwaaC, ΔwaaG, ΔwaaL, ΔwbaP, Δpmi or Δrfc or a combination thereof; or (iv) ΔP.sub.stc::P.sub.murA stc and ΔstcABCD or ΔP.sub.saf::P.sub.murA saf and ΔsafABCD, or a combination thereof, or (c) a mutation enhancing safety and effective immunogenicity, comprising ΔsifA, ΔsopF, ΔrecA or ΔsopB or a combination of (a) and with either (b) or (c).
19. The method of any of claims 15-17, wherein the adjuvant comprises wherein a Salmonella typhimurium (S. typhimurium) bacterium set forth in Tables 4, 5, 8 or 9.
20. The method of any of claims 15-17, wherein the adjuvant comprises an attenuated Salmonella typhimurium (S. typhimurium) bacterium comprising one or more mutations selected from the group consisting of ΔpagP8, ΔpagL7, ΔlpxR9, ΔarnT6 and ΔeptA4.
21. The adjuvant of any of claims 3-5, wherein the one or more mutations for facilitating lysis in vivo comprise (i) ΔP.sub.murA::TT araC P.sub.araBAD murA or ΔP.sub.murA::TT rhaRS P.sub.rhaBAD murA, (ii) ΔasdA, (iii) ΔP.sub.asdA::TT araC P.sub.araBAD asdA or ΔP.sub.asdA::TT rhaRS P.sub.rhaBAD asdA, (iv) Δalr, (v) ΔdadB, or (vi) ΔP.sub.dadB::TT araC P.sub.araBAD dadB or ΔP.sub.dadB::TT rhaRS P.sub.rhaBAD dadB, or a combination thereof.
22. The adjuvant of any of claims 3-5, wherein the one or more mutations to enhance recruitment of innate immunity comprise (i) ΔpagP::P.sub.lpp lpxE and/or ΔlpxR::P.sub.lpp lpxF, (ii) ΔpagL or ΔpagP or (iii) ΔlpxR, ΔarnT, ΔeptA, ΔwaaC, ΔwaaG, ΔwaaL, ΔwbaP, Δpmi or Δrfc or a combination thereof; or (iv) ΔP.sub.stc::P.sub.murA stc and ΔstcABCD or ΔP.sub.saf::P.sub.murA saf and ΔsafABCD, or a combination thereof.
23. The adjuvant of any of claims 3-5, wherein the one or more mutations for enhancing safety and effective immunogenicity comprise ΔsifA, ΔsopF, ΔrecA or ΔsopB, or a combination thereof.
24. The method of any of claims 15-17, wherein the adjuvant comprises an attenuated Salmonella typhimurium (S. typhimurium) bacterium comprising one or more mutations for facilitating lysis in vivo, the one or more mutations comprising (i) ΔP.sub.murA::TT araC P.sub.araBAD murA or ΔP.sub.murA::TT rhaRS P.sub.rhaBAD murA, (ii) ΔasdA, (iii) ΔP.sub.asdA::TT araC P.sub.araBAD asdA or ΔP.sub.asdA::TT rhaRS P.sub.rhaBAD asdA, (iv) Δalr, (v) ΔdadB, or (vi) ΔP.sub.dadB::TT araC P.sub.araBAD dadB or ΔP.sup.dadB::TT rhaRS P.sub.rhaBAD dadB, or a combination thereof.
25. The method of any of claims 15-17, wherein the adjuvant comprises an attenuated Salmonella typhimurium (S. typhimurium) bacterium comprising one or more mutations to enhance recruitment of innate immunity, the one or more mutations comprising (i) ΔpagP::P.sub.lpp lpxE and/or ΔlpxR::P.sub.lpp lpxF, (ii) ΔpagL or ΔpagP or (iii) ΔlpxR, ΔarnT, ΔeptA, ΔwaaC, ΔwaaG, ΔwaaL, ΔwbaP, Δpmi or Δrfc or a combination thereof; or (iv) ΔP.sub.stc::P.sub.murA stc and ΔstcABCD or ΔP.sub.saf::P.sub.murA saf and ΔsafABCD, or a combination thereof.
26. The method of any of claims 15-17, wherein the adjuvant comprises an attenuated Salmonella typhimurium (S. typhimurium) bacterium comprising one or more mutations for enhancing safety and effective immunogenicity, the one or more mutations comprising ΔsifA, ΔsopF, ΔrecA or ΔsopB, or a combination thereof.
27. The method of any of claims 8, 11-20 and 24-26, wherein the adjuvant is administered by a route of administration comprising oral, intradermal, intravenous, intramuscular, intraocular, intranasal, intrapulmonary, epidermal, subcutaneous, mucosal, or transcutaneous administration.
Description
BRIEF DESCRIPTION OF THE DRAWINGS
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DETAILED DISCLOSURE
[0046] Successful pathogens have evolved to either infect the host in a stealth mode to be undetectable and/or suppress, modulate or circumvent induction of immunity, synthesize subterfuge antigens that induce immune responses that confer no protective immunity and/or devise means to colonize and persist in the host. Salmonella vaccine vectors have been continuously modified to eliminate these means as they are discovered and characterized. In addition, other modifications to enhance an induction of innate immune response in the absence of excess inflammation have been made with Salmonella vaccine vectors. Additionally, because live bacterial vaccines have the potential to persist in the environment if shed, a method to solve this problem has been devised. This method achieves regulated delayed lysis and thereby ensures that viable vaccine cells do not persist in vivo or survive if shed into the environment.
[0047] Based on these attributes and the observation that Salmonella vaccine vector strains with these properties are entirely safe when administered to two-hour old mice or to pregnant mice or to protein-malnourished mice or to immunodeficient SCID mice, Salmonella strains with some of these properties are used herein to design strains with unique attributes to enhance their safety and efficacy when used as adjuvants. These self-destructing attenuated adjuvant Salmonella (SDAAS) strains are designed for use with a diversity of vaccines to augment their abilities to induce protective immunity or have desired abilities to alter physiological functions or combat cancers.
[0048] Vaccines for the prevention of multiple infections caused by many pathogens are nonexistent. Currently existing vaccines often only provide partial protective immunity, or, require repeat vaccinations to provide adequate immunity to a subject. Recombinant attenuated Salmonella vaccine (RASV) vectors for synthesizing and delivering protective antigens encoded by genes from pathogens have been studied. In contrast to the RASV vectors previously described, empty vector control strains which do not deliver a protective antigen invariably but surprisingly provide low levels of protective immunity to a challenge pathogen. While this low level often exceed the level of immunity conferred by buffered saline, this level was significantly less than in animals receiving vaccine strains delivering protective antigens. Consequently, this low-level protective immunity against bacterial, viral and parasitic pathogens occurs as a result of vaccinating animal hosts with empty vector control RASVs.
[0049] Consequently, the discovery of and improvements provided herein of live self-destructing Salmonella strains for serving as potent adjuvants (Sal-Adj) for enhancing induction of protective immunity by subunit and live ineffectual vaccines is paramount for the production of universally effective adjuvant strains. This discovery and the ensuing improvements enable use of Sal-Adj constructs to induce low-level protective immunity to challenge of unvaccinated animals and humans to various bacterial, viral and parasitic pathogens. Because of the principal means by which these Sal-Adj strains exert their beneficial activities (as determined in the studies conducted), they are also referred to as ENhanced Innate Immunity Response Activators (ENIIRAs) and, more recently, as Self-Destructing Attenuated Adjuvant Salmonella (SDAAS) strains. Optimal doses, routes and times of administration to enhance induction of protective immunity against infection and persistence by pathogens will be elucidated herein. In a similar way, the RASV vector strains now improved with features to diminish their abilities to subvert induction of immunity and increasing their immunogenicity by enhancing stimulation of innate immunity are now termed Protective Immunity Enhanced Salmonella Vaccine (PIESV) vectors.
Definitions
[0050] As used herein the specification, “a” or “an” may mean one or more, unless clearly indicated otherwise. As used herein in the claims, when used in conjunction with the word “comprising,” the words “a” or “an” may mean one or more than one.
[0051] As used herein, “codon” means, interchangeably, (i) a triplet of ribonucleotides in an mRNA which is translated into an amino acid in a polypeptide or a code for initiation or termination of translation, or (ii) a triplet of deoxyribonucleotides in a gene whose complementary triplet is transcribed into a triplet of ribonucleotides in an mRNA which, in turn, is translated into an amino acid in a polypeptide or a code for initiation or termination or translation. Thus, for example, 5′-TCC-3′ and 5′-UCC-3′ are both “codons” for serine, as the term “codon” is used herein.
[0052] The terms “comprise,” “have,” and “include” are open-ended linking verbs. Any forms or tenses of one or more of these verbs, such as “comprises,” “comprising,” “has,” “having,” “includes,” and “including,” are also open-ended. For example, any method that “comprises,” “has” or “includes” one or more steps is not limited to possessing only those one or more steps and also covers other unlisted steps.
[0053] The term “consisting essentially of” when used in conjunction with adjuvant containing compositions described herein refers to a composition comprising a Sal-Adj or ENIIRA or SDAAS strain and a pharmaceutical carrier without any other immune response enhancing components.
[0054] The term “agent” as used herein refers to either adjuvant and/or vaccine.
[0055] As used herein, the term “adjuvant” refers to an agent that stimulates and/or enhances an immune response in a subject. An adjuvant can stimulate and/or enhance an immune response in the absence of an antigen and/or can stimulate and/or enhance an immune response in the presence of an antigen. Exemplary embodiments of adjuvants disclosed herein are ENIIRA or SDAAS strains.
[0056] The term “administering” or “administration” of an agent as used herein means providing the agent to a subject using any of the various methods or delivery systems for administering agents or pharmaceutical compositions known to those skilled in the art. Agents described herein may be administered by oral, intradermal, intravenous, intramuscular, intraocular, intranasal, intrapulmonary, epidermal, subcutaneous, mucosal, or transcutaneous administration.
[0057] The term “co-administration” or “co-administering” as used herein refers to the administration of an active agent before, concurrently, or after the administration of another active agent such that the biological effects of either agents overlap.
[0058] The term “gene”, as used herein, refers to a nucleic acid sequence that encodes and expresses a specific protein. In some embodiments, a gene may include a regulatory sequence of a 5′-non-coding sequence and/or a 3′-non-coding sequence.
[0059] An “immune response enhancing amount” is that amount of an adjuvant administered sufficient to enhance an immune response of vaccine administration in a subject compared to vaccine administration without adjuvant administration. An immune response enhancing amount can be administered in one or more administrations.
[0060] As used herein, the term “immunogen” refers to an antigen that is recognized as unwanted, undesired, and/or foreign in a subject.
[0061] As used herein, the term “immune response” includes a response by a subject's immune system to a vaccine. Immune responses include both cell-mediated immune responses (responses mediated by antigen-specific T cells and non-specific cells of the immune system) and humoral immune responses (responses mediated by antibodies present in the plasma lymph, tissue fluids and mucosal secretions). The term “immune response” encompasses both the initial responses to an immunogen as well as memory responses that are a result of “acquired immunity.”
[0062] The term “codon-optimized” as used herein refers to sequences that have been modified from their natural form to incorporate codons that are highly expressed or preferred by the organism in which they are introduced. Oligonucleotide and/or gene syntheses of pathogen specified protective and putative protective antigens may be codon-optimized to enhance translational efficiency in Salmonella by using codons used most frequently by highly expressed Salmonella genes and with codon selection to make the final sequence within about 2-3% of the average 52% GC content of the Salmonella genome. In some instances, codons are also changed to stabilize mRNA by “destroying” RNase E cleavage sites to prolong mRNA half-life. (see McDowall K J, Kaberdin V R, Wu S W, Cohen S N, Lin-Chao S. Site-specific RNase E cleavage of oligonucleotides and inhibition by stem-loops. Nature. 1995; 374(6519):287-90. Epub 1995/03/16. doi: 10.1038/374287a0. PubMed PMID: 7533896 and Lin-Chao S, Wong T T, McDowall K J, Cohen S N. Effects of nucleotide sequence on the specificity of me-dependent and RNase E-mediated cleavages of RNA I encoded by the pBR322 plasmid. J Biol Chem. 1994; 269(14):10797-803. Epub 1994/04/08. PubMed PMID: 7511607) which are incorporated herein by reference. Provided below are preferred codons (1 letter symbol and codon):
[0063] F-tcc
[0064] S-tct
[0065] Y-tac
[0066] C-tgc
[0067] W-tgg
[0068] I-atc
[0069] M-atg
[0070] L-ctg
[0071] P-ccg
[0072] H-cac
[0073] Q-cag
[0074] R-cgt
[0075] V-gtt
[0076] T-acc
[0077] N-aac
[0078] K-aaa
[0079] A-gcg
[0080] D-gat
[0081] E-gaa
[0082] G-ggt
Based on the foregoing list, one or more modifications to the natural sequence may be made to reflect the above codon for the appropriate amino acid.
[0083] As used herein, “nucleic acid” or “nucleic acid sequence” refers to polynucleotides, such as deoxyribonucleic acid (DNA) or ribonucleic acid (RNA), oligonucleotides, fragments generated by the polymerase chain reaction (PCR), and fragments generated by any of ligation, scission, endonuclease action, and exonuclease action. Nucleic acid molecules can be composed of monomers that are naturally-occurring nucleotides (such as DNA and RNA), or analogs of naturally-occurring nucleotides (e.g., a-enantiomeric forms of naturally-occurring nucleotides), or a combination of both. The term “nucleic acid” or “nucleic acid sequence” also pertains to codon optimized nucleic acid sequences as defined herein.
[0084] As used herein, the phrase “stimulating or enhancing an immune response” refers to an increase in an immune response in the subject following administration of a vaccine with an adjuvant of the disclosed embodiments relative to the level of immune response in the subject when a vaccine has been administered without an adjuvant.
[0085] As used herein, the term “vaccine” refers to an immunogen or a composition comprising an immunogen that elicits an endogenous immune response in a subject (e.g., a human or animal). The endogenous immune response may result in, for example, the switching of a Th1 biased immune response to a Th2 biased immune response, the activation or enhancement of T effector cell responses and/or the reduction of T regulatory cell response, the activation of antigen-specific naive lymphocytes that may then give rise to antibody-secreting B cells or antigen-specific effector and memory T cells or both, and/or the direct activation of antibody-secreting B cells.
[0086] The term “pharmaceutically acceptable carrier” as used herein refers to one or more formulation materials suitable for accomplishing or enhancing the successful delivery of the pharmaceutical composition of the Sal-adj or SDAAS strains disclosed herein. As used herein, the term “carrier” refers to a pharmaceutically acceptable solid or liquid filler, diluent or encapsulating material. A water-containing liquid carrier can contain pharmaceutically acceptable additives such as acidifying agents, alkalizing agents, antimicrobial preservatives, antioxidants, buffering agents, chelating agents, complexing agents, solubilizing agents, humectants, solvents, suspending and/or viscosity-increasing agents, tonicity agents, wetting agents or other biocompatible materials. A tabulation of ingredients listed by the above categories, may be found in the U.S. Pharmacopeia National Formulary, 1857-1859, (1990). Examples of liquid carriers include, but are not limited to, water, saline, dextrose, glycerol, ethanol and mixtures thereof.
[0087] The term “protective immunity” as used herein refers to induction of an immune response upon administration of a vaccine sufficient to confer protection against a pathogen or to have a therapeutic effect by arresting a disease such as cancer.
Overview and Preliminary Studies
1. Bacterial Strains for Adjuvant Compositions.
[0088] Many S. Typhimurium strains with individual and combinations of deletion and deletion-insertion mutations have been isolated/constructed and all the suicide vectors for these constructions are available to move these mutations into strains to create new Sal-Adj/ENIIRA/SDAAS strains.
[0089] Table 1 lists the mutations and their associated phenotypic attributes that were used in these studies. Based on our prior results and the considerations discussed above, we began with three parental strains that exhibit lysis in vivo but with different periods of time needed for lysis and will therefore disperse into tissues away from the inoculation site to different extents. All these strains exhibit complete biological containment features being unable to persist in vivo or survive if released into the environment.
[0090] Family A: χ9052 Δalr-3 ΔdadB4 ΔasdA33—requires D-alanine (Salmonella has two alanine racemases) and diaminopimelic acid (DAP) that are unique essential constituents of peptidoglycan that provides the rigid layer of the bacterial cell wall. D-alanine and DAP are only synthesized by bacteria and are totally absent in animal tissues.
[0091] Family B: χ12499 Δalr-3 ΔP.sub.dada66::TT araC P.sub.araBAD dadB ΔP.sub.asdA55::TT araC P.sub.araBAD asd—requires presence of arabinose since synthesis of D-alanine and DAP are totally dependent on arabinose-induced synthesis of the dadB-encoded alanine racemase and the asdA-encoded aspartate semialdehyde dehydrogenase. The second alanine racemase that synthesizes D-alanine is absent due to the Δalr-3 mutation. Arabinose is absent in animal tissues but this strain undergoes several cell divisions in vivo until the dadB- and asdA-encoded enzymes are diluted by cell division so that D-alanine and DAP synthesis are insufficient to maintain peptidoglycan integrity.
[0092] Family C: χ11730 ΔP.sub.murA25::TT araC P.sub.araBAD murA ΔasdA27::TT araC P.sub.araBAD c2 Δ(wza-wcaM)-8 ΔrelA198::araC P.sub.araBAD lacI TT—must be used with a lysis plasmid that also has araC P.sub.araBAD regulation of the murA and asdA genes (see next section) to yield a strain that is totally dependent on arabinose-induced synthesis of the enzymes needed to synthesize DAP and muramic acid (another unique essential constituent of peptidoglycan). Depending on the complementing plasmid copy number used, this strain will disseminate more widely and attain higher titers in animal tissues prior to onset of lysis than strains in Families A and B.
[0093] The various mutations that are being used to conduct studies to determine the optimal means to stimulate innate immunity that is not excessively inflammatory are listed in Table 1 along with the mutations present in the Family A, B and C starting strains.
TABLE-US-00001 TABLE 1 Mutations and associated phenotypes in S. Typhimurium adjuvant strains.sup.a Genotype Phenotype A. Deletion and deletion-insertion mutations to facilitate regulated delayed lysis in vivo ΔP.sub.murA::TT makes synthesis of MurA, the first enzyme in the synthesis araC P.sub.araBAD of muramic acid, dependent on arabinose in growth medium and ceases murA synthesis in vivo due to absence of arabinose (1,2). MurA decreases due to cell division in vivo to ultimately cause lysis and death (2). The murA defect is complemented by MurA.sup.+ plasmid vectors (1). Δmur A mutations are lethal since the product of the gene is phosphorylated that precludes its uptake by Salmonella cells. ΔasdA encodes aspartate semialdehyde dehydrogenase essential for synthesis of diaminopimelic acid (DAP) necessary for peptidoglycan synthesis (3). ΔP.sub.asdA::TT makes synthesis of AsdA dependent on presence of arabinose araC P.sub.araBAD encodes one of two alanine racemases essential for synthesis of D- asdA Δalr alanine necessary for peptidoglycan synthesis (4). ΔdadB encodes one of two alanine racemases essential for synthesis of D- alanine necessary for peptidoglycan synthesis (4). ΔP.sub.dadB66::TT makes synthesis of DadB dependent on presence of arabinose araC P.sub.araBAD dadB eliminates twenty enzymes needed to synthesize several Δ(wza-wcaM) exopolysaccharides that promote biofilm formation facilitating persistence and synthesis of GDP-fucose required for colanic acid synthesis (5), which protects cells undergoing cell wall-less death from lysing (6). These exopolymers are also immunosuppressive. ΔrelA the relA mutation uncouples growth regulation from a dependence on protein synthesis, an important attribute in strains with regulated delayed lysis (7, 8) B. Mutations enabling regulation of genes that might be present on plasmid vectors in conjunction with strains undergoing regulated delayed lysis in vivo P.sub.trc a promoter expressed at high level under both anaerobic and aerobic conditions and repressed by LacI (9, 10) ΔrelA::araC the arabinose-dependent synthesis of the LacI repressor is to P.sub.araBAD lacI TT enable a regulated delayed expression of DNA sequences under the control of P.sub.trc (11) ΔasdA::TT the Asd enzyme is essential for the synthesis of DAP required for araC P.sub.araBAD c2 peptidoglycan synthesis (12). The arabinose-dependent synthesis of the C2 repressor enables a regulated delayed expression of DNA sequences under control of C2 repressed promoters (1). The ΔasdA mutation is complemented by Asd.sup.+ plasmids (13). Phage P22 P.sub.R promoter is repressible by arabinose-dependent synthesis of the C2 repressor (14) C. Mutations altering synthesis of LPS components ΔpagP::P.sub.lpp causes regulated delayed in vivo synthesis of the codon-optimized lpxE mutation lpxE gene from Francisella tularensis to cause synthesis of the non- toxic adjuvant form of LPS lipid A monophosphoryl lipid A (MPLA)(15). The pagP mutation also eliminates a means by which Salmonella alters LPS lipid A in vivo to decrease recruitment of innate immunity by interaction with TLR4 (16) ΔpagL eliminates a means by which Salmonella alters LPS components in vivo to decrease recruitment of innate immunity by interaction with TLR4 (16) ΔlpxR eliminates another means by which Salmonella alters LPS components in vivo to decrease recruitment of innate immunity by interaction with TLR4 (16) ΔarnT eliminates a means by which Salmonella alters LPS lipid A in vivo to decrease recruitment of innate immunity by interaction with TLR4 (51) ΔeptA eliminates a means by which Salmonella alters LPS lipid A in vivo to decrease recruitment of innate immunity by interaction with TLR4 (52) ΔwaaC eliminates an enzyme needed to synthesize LPS core resulting in a deep-rough phenotype and also renders Salmonella totally attenuated (49) ΔwaaG eliminates an enzyme needed to synthesize LPS core resulting in a medium-rough phenotype and also renders Salmonella totally attenuated (49) ΔwaaL eliminated the enzyme that joins the LPS O-antigen chain to the LPS core resulting in a moderate-rough phenotype and also renders Salmonella totally attenuated (49) D. Mutations altering synthesis of flagellar components ΔfliC180 a specific mutation in the fliC gene encoding the Phase I flagellin protein (17) that contains the TLR5 receptor and a CD4 T- cell epitope. The mutation prevents synthesis of flagella. ΔfliC2426 deletes fliC gene to eliminate synthesis of Phase I flagellin (17) ΔfliB217 deletes fljB gene to eliminate synthesis of Phase II flagellin (17) Δ(hin-fljBA) deletes the sequence necessary for phase switching of flagellin synthesis and eliminates synthesis of the phase II flagellin and the repressor of the fliC gene E. Mutations altering synthesis of fimbrial components ΔP.sub.stc::P.sub.murA stc causes constitutive synthesis of the in vivo expressed Stc fimbriae that contribute to immunogenicity (18) ΔstcABCD eliminates synthesis of Stc fimbriae (18) ΔP.sub.saf::P.sub.murA saf causes constitutive synthesis of the in vivo expressed Saf fimbriae that contribute to immunogenicity (18) ΔsafABCD eliminates synthesis of Saf fimbriae (18) F. Mutations eliminating or diminishing effective immunogenicity ΔsifA enables Salmonella to escape the SCV for lysis in cytosol (19) and eliminates a means of immunosuppression (20) ΔsteE G. Mutations leading to degradation of DNA within Salmonella cells ΔrecA enhances rate of DNA digestion in Salmonella cells as a consequence of recombination to liberate DNA fragments with CpG sequences and also renders Salmonella totally attenuated (53) .sup.aΔ = deletion; TT = transcription terminator; P = promoter
Table 2 lists the suicide plasmids used to move the mutations including deletion and deletion-insertion mutations listed and described in Table 1 into the Sal-Adj/ENIIRA strains constructed including the Family A, B and C strains listed above and their derivatives described in following sections and Examples as well as in strains yet to be constructed.
TABLE-US-00002 TABLE 2 Suicide vectors for constructing the mutations in Table 1 Genotype Suicide Vector Marker A. Deletion and deletion-insertion mutations to facilitate regulated delayed lysis in vivo ΔP.sub.murA::TT araC P.sub.araBAD murA pYA4686 Cm ΔasdA pYA3736 Cm ΔP.sub.asdA::TT araC P.sub.araBAD asdA pG8R71 Cm Δalr pYA3667 Cm ΔdadB pYA3668 Cm ΔP.sub.dadB66::TT araC P.sub.araBAD dadB pG8R73 Cm Δ(wza-wcaM) pYA4368 Cm ΔrelA pYA3679 Cm B. Mutations enabling regulation of genes that might be present on plasmid vectors in conjunction with strains undergoing regulated delayed lysis in vivo ΔrelA::araC P.sub.araBAD lacI TT pYA4064 Cm ΔasdA::TT araC P.sub.araBAD c2 pYA4138 Cm C. Mutations altering synthesis of LPS components ΔpagP::P.sub.lpp lpxE pYA4295 Cm ΔpagL pYA4284 Cm ΔlpxR pYA4287 Cm ΔarnT pYA4286 Cm ΔeptA pYA4283 Cm ΔwaaC pYA5473 Cm ΔwaaG pYA4896 Cm ΔwaaL pYA4900 Cm D. Mutations altering synthesis of flagellar components ΔfliC180 pYA3729 Cm ΔfliC2426 pYA3702 Cm ΔfliB217 pYA3548 Tet Δ(hin-fljBA) pG8R306 Cm E. Mutations altering synthesis of fimbrial components ΔP.sub.stc::P.sub.murA stc pYA5053 Cm ΔstcABCD pYA5007 Tet ΔP.sub.saf::P.sub.murA saf pYA5055 Cm ΔsafABCD pYA4586 Tet F. Mutations eliminating or diminishing effective immunogenicity ΔsifA pYA3716 Cm G. Mutations leading to degradation of DNA within Salmonella cells ΔrecA pYA4680 Cm .sup.a Δ = deletion; TT = transcription terminator; P = promoter
[0094] 2. Plasmids for Adjuvant Strains with Regulated Delayed Lysis In Vivo. Family C
[0095] Family C Sal-Adj (SDAAS) strains will be used in conjunction with plasmids conferring a regulated delayed lysis in vivo phenotype (
3. Observations with Unexpected Ability of Empty Vector Control RASV Strains to Confer Low-Level Protective Immunity to Pathogens or Decreased Ability of Pathogens to Multiply in Hosts or Reduce Performance.
[0096] As stated above, we have observed, in developing RASV/PIESV vectored vaccines, that the empty vector control groups (having a vector plasmid not encoding a protective antigen) invariably had higher survival or performance after challenge than the control groups receiving buffered saline (BS). This was especially true with vaccine vector strains that undergo lysis in various cell compartments in vivo. This implied that we might be recruiting innate immunity via activation of internal Nod and TLR9 receptors by release of peptidoglycan components and DNA intracellularly. We present results from some of these studies in Table 3.
TABLE-US-00003 TABLE 3 Empty vector PIESVs and protective immunity* Percent Survival Pathogen RASV Path challenge BS PIESV-Ag PIESV + Ag Influenza PIESV-Flu Influenza 16 29 90 WSN Av (3) Yersinia PIESV-Yp Y pestis (s.c.) 0 38 83 pestis Av (3) S. PIESV-Sp S. pneumoniae 0 5 61 pneumoniae Av (7) M. PIESV-Mtb M. Empty vector control reduced Mtb colonization tuberculosis tuberculosis more than BS (3 comparisons) C. RASV-Cp C. Empty vector reduced lesions & mortality, perfringens perfringens enhanced feed conversion & weight gain more than BS (4 comparisons) E. tenella PIESV- Eimeria Empty vector enhanced feed conversion & Eimeria weight gain more than BS (2 comparisons) *First 4 studies in inbred mice and last 2 studies in outbred chickens The empty vector PIESV strains used for the results presented in Table 3 are very analogous to the Family C ENIIRA/SDAAS strains although some of these strains did not have the regulated delayed lysis in vivo phenotype.
4. Interaction of Family A and B Strains with HEK Cells Displaying TLR and Nod Factors.
[0097] To evaluate the ability of Salmonella strains with differing genotypes to stimulate innate immune responses, we have used HEK293 cells with a NFκB-inducible secreted embryonic alkaline phosphatase (SEAP) reporter gene (InvivoGen) and displaying Nod1, Nod2 and TLR4. We initially determined that all three Family A, B and C strains containing a plasmid encoding GFP were highly invasive into HEK cells. The χ9052 and χ12499 strains were grown in LB broth to maximize expression of the SPI-1 invasion phenotype, sedimented at room temperature and suspended in tissue culture medium. HEK cells at 2×10.sup.5 cells/ml were mixed with bacterial cells at a MOI of 10 in a volume of 200 μl in 96 well plates. Unattached bacteria were removed by washing in tissue culture medium and then plates were incubated at 37° C. in 5% CO2 over 24 h with periodic scanning at 650 nm for production of the blue reagent due to secretion of alkaline phosphatase from the HEK cells.
5. Enhanced NFκB in HEK Cells Displaying TLR5.
[0098] S. typhimurium χ9026 with ΔfljB217 ΔfliC180 mutations that overproduces a truncated FliC flagellin having the receptor for TLR5 stimulates significantly higher levels of IL6 and TNFα production in GALT and MLN cells than the non-flagellated χ9028 strain with ΔfljB217 ΔfliC2426 and also stimulates higher levels of NF-kB production in HEK cells displaying the murine TLR5. Expansion of the data in analyzing interaction of Sal-Adj/ENIIRA strains with HEK cells is presented in the Examples.
EXAMPLES
Example 1. Materials and Methods
Bacterial Strains, Media and Bacterial Growth.
[0099] All Sal-Adj/ENIIRA/SDAAS strains as well as other strains possessing individual mutations used in strain constructions are derived from the highly virulent S. typhimurium UK-1 strain χ3761 (21). LB broth and agar (22) will be used as complex media for propagation and plating of Salmonella strains. Purple broth (PB) (Difco), which is devoid of arabinose (Ara), was also used since LB contains low levels of arabinose. MacConkey agar with 0.5% lactose (Lac) and 0.1% Ara were used to enumerate bacteria recovered from mice. Mycobacterium tuberculosis H37Rv was propagated in Middlebrook 7H9 broth (Difco) supplemented with 10% albumin, dextrose and sodium chloride (ADS). Middlebrook 7H11 agar, supplemented with 10% ADS was used to determine bacterial CFU titers in the lungs and spleens of immunized mice challenged with M. tuberculosis. Bacterial growth was monitored spectrophotometrically and by plating for colony counts. S. typhimurium PIESV strain χ12068 carrying the plasmid pYA4891 was used in two of the experiments described in Example 5. χ12068 has the following genotype: (ΔP.sub.mirA25::TT araC P.sub.araBAD murA ΔasdA27::TT araC P.sub.araBAD c2 Δpmi-2426 Δ(wza-wcaM)-8 ΔrelA197::araC P.sub.araBAD lacI TT ΔrecF126 ΔsifA26 ΔwaaL46 ΔpagL12::TT araC P.sub.araBAD waaL), which has the regulated delayed lysis in vivo phenotype and escapes the SCV to lyse in the cytosol to deliver antigens to the proteosome for class I presentation to induce CD8+, CD17+ and NKT-dependent immune responses. The plasmid pYA4891 is designed for use in regulated delayed lysis in vivo PIESVs and is a derivative of pYA4589, described in
Molecular and Genetic Procedures
[0100] Methods for DNA isolation, restriction enzyme digestion, DNA cloning and use of PCR and real-time PCR for construction and verification of bacterial strains and vectors are standard (23). Defined deletion mutations with and without specific insertions have been constructed for all mutations listed in Table 1 using flanking sequences derived from the S. typhimurium parent χ3761. These mutations are introduced using either phage P22HTint (24, 25) transduction of suicide vectors integrated into the deletion mutation followed by selection for sucrose resistance (26) or by conjugational transfer of suicide vectors using standard methods (27, 28) with the suicide vector donor strains χ7213 and χ7378 (29). Plasmid constructs were evaluated by DNA sequencing and for ability of sugar-regulated sequences to specify synthesis of proteins using gel electrophoresis and western blot analyses (30).
Strain Characterization
[0101] Sal-Adj/ENIIRA/SDAAS strains were fully characterized at each step in their construction. Genetic attributes were confirmed by PCR with appropriate primers. Measurement of LPS core and O-antigen were performed after electrophoresis using silver-stained gels (88). This analysis is done after every step in any strain construction to eliminate possible spontaneous variants if they arise. We also validate the complete sensitivity of all Sal-Adj/ENIIRA/SDAAS strains to all antibiotics that might ever be used to treat Salmonella infections. Metabolic attributes are evaluated using API-20E tests. The presence of the recA mutation is determined by inability to undergo recombination using P22 transduction and extreme sensitivity to UV light.
[0102] Swimming motility was assessed on LB plates solidified with 0.3% agar and supplemented with appropriate supplements (arabinose or DAP or D-alanine). Strains were grown statically overnight in the appropriate media. The next day, 50 μl of this culture was inoculated into 2 ml of the appropriate media and grown with aeration at 37° C. to an optical density at 600 nm (0D600) of 0.8 to 0.85. One milliliter samples of cultures were pelleted at 4,500×g and were resuspended in 1 ml BSG. Five microliter samples of bacterial suspension were spotted onto the middle of the plates, which were then incubated at 37° C. for 7 h.
[0103] Production and secretion of flagellin was determined by shearing appendages from cells in culture using a Waring blender. After removal of cells by centrifugation, proteins in the supernatant were precipitated with TCA and then hydrolyzed by boiling in SDS buffer prior to electrophoresis. Antiserum against FliC and FljB flagellin were used to detect production of the Phase I and Phase II flagellins, respectively, by western blotting.
[0104] Production of fimbrial adhesins is determined using antisera to the Saf and Stc fimbrial subunits by western blot analyses after electrophoresis of precipitated protein fractions obtained after shearing bacterial strains in a blender to remove flagellar and fimbrial appendages (as described above).
[0105] Measurement of growth and lysis after inoculation of bacteria into media not permissive for growth was evaluated spectrophotometry and by dilution and plate counting to determine viable cell titers. For these evaluations we used Purple broth since it totally lacks the sugars arabinose, mannose and rhamnose that are present at very low concentrations in LB broth. We also use un-Purple broth that just lacked the pH indicator dye. In some studies, we also used MOPS minimal media with and without supplements DAP, D-alanine, arabinose and/or rhamnose. Bacterial strains were grown statically overnight in the appropriate media supplemented with 0.1% arabinose and/or 50 μg DAP and/or 20 μg D-alanine. The next day, 50 μl of this culture was inoculated into 2 ml of the appropriate media and grown with aeration at 37° C. to an optical density at 600 nm (0D600) of 0.8 to 0.85. Cells were then centrifuged twice and washed and resuspended in un-Purple broth at a cell density of about 5×10.sup.7 CFU/ml and then grown with rotary aeration at 37° C. Absorbancies at OD.sub.600nm were monitored continuously and dilutions for plate counts on permissive agar medium made at 30 and/or 60 min intervals.
Cell Culture Methods and Use of HEK293 Cells to Monitor Initiation of Innate Immune Responses
[0106] HEK293 cells with the murine TLR1, TLR2, TLR4, TLR4 MD2 CD14, TLRS, TLRS CD14, TLR6, TLRS, TLRS, Nod1 and Nod2 were used with the NF-kB SEAP reporter system to enable read outs at A650 nm. Sal-Adj/ENIIRA/SDAAS strains were grown to maximize their invasiveness and determine bacterial cell attachment to, invasion into and survival in HEK cells and monitor stimulation of NF-kB production by HEK cells over a 24 h period. More specifically, Salmonella strains were grown in LB with appropriate supplements at 37° C. to an optical density at 600 nm (0D600) of 0.8 to 0.9. Bacteria were harvested by centrifugation at 4,500×g at room temperature and were resuspended in endotoxin free water at the densities required to produce the desired dose ENIIRA/SDAAS strain as multiplicity of infection (MOI 10, 1, 01 and 001) relative to HEK cell density in the appropriate volume. Bacterial samples of 20 μl were added per well in a flat-bottom 96-well cell culture plate.
[0107] HEK-Blue™ mTLR4 or HEK-Blue™ mTLR5 or HEK-Blue™ mNOD1 or HEK-Blue™ mNOD2 cells were purchased from InvivoGen, San Diego, Calif., USA. The cells were cultured at 37° C. in 5% CO2 in 25 vented flasks using Eagle's Minimum Essential Medium (EMEM) ATCC® 30-2003™ containing heat-inactivated fetal bovine serum (FBS), penicillin/streptomycin, and Normocin™ (InvivoGen). Cells were grown to 50-70% confluence and were resuspended in HEK-Blue detection media at a cell density 2-5×10.sup.6 viable cells per milliliter. Cell suspensions of 180 μl were added to the previous bacterial samples added to the 96-well cell culture plate. Plates were incubated at 37° C. in 5% CO2 for 24 h. SEAP activity was determined using a spectrophotometer at 650 nm. The response ratios were calculated by dividing the OD at 650 nm for the treated cells by the OD at 650 nm for the untreated cells.
Animal Experimentation to Monitor Safety and Efficacy of Sal-Adj/ENIIRA/SDAAS Constructs Administered by Different Routes to Young Adult Mice
[0108] Ten-fold dilutions (10.sup.4-10.sup.8 CFU) of S. typhimurium χ12517 or χ12518 strains were administered by intravenous (I.V.) or subcutaneous (S.C.) or intranasal (I.N.) routes to 6-week-old female BALB/c mice by following our standard procedures (49). Briefly, adjuvant strains were grown statically overnight in the appropriate media. The next day, 100 μl of each culture was inoculated into 5 ml of the appropriate media and grown with aeration at 37° C. to an optical density at 600 nm (0D600) of 0.8 to 0.85. Cultures were pelleted at 4,500×g at room temperature and were resuspended in BSG at the densities required to produce the desired dose in the appropriate volume. A volume of 20 μl of bacterial suspension containing the appropriate dose was inoculated by the various routes at day 0. Mice were monitored for death twice a day up to 3 weeks.
Animal Experimentation to Monitor Safety and Efficacy of Sal-Adj/ENIIRA/SDAAS Constructs to Augment Immune Responses to Ovalbumin (Ova)
[0109] Imject Alum was purchased from Thermo Scientific (cat #77161) and ova albumin was purchased from Sigma (A2512-1G). Ova albumin was dissolved in BSG with a stock concentration 2 mg/ml. Adjuvant strain χ9052 was grown statically overnight in LB supplemented with DAP and D-alanine. The next day, 100 μl of this culture was inoculated into 5 ml of the appropriate media and grown with aeration at 37° C. to an optical density at 600 nm (0D600) of 0.8 to 0.9. Bacteria were harvested by centrifugation at 4,500×g at room temperature and were resuspended in BSG at the densities required to produce the desired dose in the appropriate volume. Above suspension of 500 μl was emulsified with 500 μl Imject Alum by repeatedly passing through a syringe needle. Each mouse was inoculated subcutaneously with 100 μl of suspension. Six-week-old BALB/c mice were divided into three groups of five mice each named Group-I [Ova (100 μg)+χ9052 (5×10.sup.6)], Group-II [Ova (100 μg)] and Group-III [Ova (100 μg)+Imject Alum (50 μl)]. Animals were immunized subcutaneously. Blood was sampled from immunized mice for antibody determination by ELISA at 2, 4 and 6 weeks post-inoculations.
Animal Studies to Determine Ability of Sal-Adj/ENIIRA/SDAAS Constructs to Augment Level of Protective Immunity Against M. tuberculosis (Mtb) Challenge of BCG Immunized Mice
[0110] C57/BL6 mice of both sexes were given a s.c. dose of 5×10.sup.6 CFU of M. bovis BCG Pasteur (ATCC 35734) on day 0 without and with varying doses in CFU of different Sal-Adj constructs by s.c. (1×10.sup.5 CFU), i.n. (1×10.sup.7 CFU), and i.v. (5×10.sup.4 CFU) routes. On day 28, sera were collected from all mice. In addition, two mice from each group were euthanized, livers and spleens were removed, processed and used for flow cytometric analyses. On day 35 all mice were infected with aerosolized M. tuberculosis H37Rv (50 to 100 bacteria per mouse) using a Glas-Col Inhalation Instrument (31). Six weeks after challenge, mice were euthanized, lungs and spleens removed aseptically, tissues homogenized, homogenates diluted and samples plated on Middlebrook 7H11+10% ADS agar plates (Difco). Plates were incubated at 37° C. for 3-4 weeks to determine the Mtb CFU in these organs.
Monitoring Immune Responses
[0111] Antigen Preparation
[0112] Purified Ova was obtained commercially. M. tuberculosis antigens Ag85A, ESAT-6 and CFP-10 were purified as His-tagged proteins from recombinant E. coli. These antigens were used for immunoassays as described below.
[0113] ELISA
[0114] Serum antibodies were measured in blood collected by submandibular bleeding. We determined the concentrations of IgG and IgA against Ova in μg/ml and the concentrations of IgG against Ag85A, ESAT-6 and CFP-10 in μg/ml. To distinguish between Th1 and Th2 responses, we determined titers of IgG1 and IgG2a for Ova and titers of IgG1 and IgG2b for Ag85A, ESAT-6 and CFP-10. The 96-well plates were coated with 100 ng Ova or with 0.5 to 1 μg of each M. tuberculosis antigen. Free binding sites were blocked with the SEABLOCK Blocking Buffer (Thermo Fisher). Anti-Ova titers or anti-Ag85A, anti-ESAT-6 or anti-CFP-10 titers in the serum (dilution 1:100) were detected with biotinylated goat anti-mouse IgG, IgG1, IgG2a or IgA for Ova and biotinylated goat anti-mouse IgG, IgG1 or IgG2b for Ag85A, ESAT-6 and CFP-10 (Southern Biotechnology) followed by incubation with a streptavidin-alkaline phosphatase conjugate (Southern Biotechnology). Color development (absorbance at 405 nm) with p-nitrophenyl phosphate (Thermo Fisher Scientific) was recorded with an automated ELISA plate reader (EL311SX; Biotek). Unconjugated mouse antibodies (Southern Biotechnology) (IgG, 5 μg/ml to 40 ng/ml; IgG1, IgG2a or IgG2b, 1 μg/ml to 8 ng/ml; IgA 62.5 ng/ml to 0.46 ng/ml) were serially diluted and coated on a 96-well plate in duplicate. Standard curves were generated by plotting the OD.sub.405 values against the representative concentrations of the diluted unconjugated antibody solutions and fitted to a 4-parameter logistic curve (R2≥0.98). The absorbance values of experimental samples were fit into the standard curve to interpolate antibody concentrations. All samples were analyzed in triplicate. We also used ELISPOT assays (32) in initial studies to determine whether antigen-specific IgA and IgG secreting peripheral blood lymphocytes are induced 10 to 15 days after vaccination with Ova and adjuvants.
[0115] Cellular Immune Responses and Flow Cytometry Analyses
[0116] These more detailed evaluations of immune responses induced have been and will be continually used as optimal Sal-Adj/SDAAS constructs are identified and their use evaluated with vaccine constructs and preparations to ultimately be tested.
[0117] Flow Cytometry
[0118] Flow cytometry was used to quantitate populations of antigen-specific CD4.sup.+ and CD8.sup.+ T cells and antigen-specific cytokine-secreting cells in the lungs and spleens of mice immunized with M. bovis BCG in combination with Sal-Adj/SDAAS constructs. Lymphocytes were isolated from homogenized lungs and spleens of immunized or PBS control mice by centrifugation of the cell lysates through Percoll gradients. After washing the purified lymphocytes with PBS, the cells were simulated with 10 μg/ml of purified protein antigens for 24 h. Fc blocking reagent was used to prevent non-specific binding of antibodies to Fc receptors on the lymphocytes. Surface staining using anti-mouse fluorophore-labelled antibodies (Biolegend), followed by fixation of the cells with 4% para-formaldehyde was used to identify subsets of lymphocytes. Gating on both CD4 and CD8 was done on the CD3.sup.+ lymphocyte population to detect the percent of antigen-specific CD4.sup.+ and CD8.sup.+ cells expressing effector KLRG1, PD1 or memory CD62L, CD127 molecules. To detect intracellular cytokines, lymphocytes were stained for surface markers CD3, CD44, CD4 and CD8, followed by treatment with BD Sciences Cytofix/Cytoperm and stained intracellularly with combinations of IFN-γ and TNF-α antibodies. All samples were analyzed in the Department of Infectious Diseases and Immunology Flow Cytometry Core Facility on an 8-color FACSCanto, 18-color FACSFortessa flow cytometer with a SH800Z Cell Sorter. Data analyses and statistical comparisons among the samples from immunized and non-immunized mice was done using the Flow JO software.
Splenomegaly.
[0119] To determine protection against challenge with M. tuberculosis H37Rv, the spleens and lungs are weighed individually after they are removed from the euthanized mice. The number of CFUs determined from plating samples of homogenized lungs and spleens are reported as CFU per gram of tissue. When spleens were removed from mice immunized with ENIIRA/SDAAS strains, it was immediately evident by visual observation, that some spleens were significantly enlarged, compared to the spleens of unimmunized mice or mice immunized with M. bovis BCG or mice immunized with PIESV χ12068(pYA4891).
Statistical Analyses
[0120] All results were analyzed using the most appropriate statistical test from the SAS program to evaluate the relative significance or lack thereof of results obtained.
Example 2. Construction and Characterization of Sal-Adj/ENIIRA/SDAAS Strains
[0121] a. Introduction
[0122] Sal-Adj/ENIIRA/SDAAS strains of the starting genotypes for the Family A, B and C strains were initially compared to determine which most enhances induced immune responses to Ova and protective immunity to M. tuberculosis challenge. This was because it is possible that strains from different families will each be more efficacious in one evaluative test than the other. In these initial studies, the Family A and B strains were found to be most efficacious, in all probability since they invade efficiently and undergo lysis more rapidly. In accord with this, Family C strains that underwent regulated lysis in vivo more rapidly, induced higher innate immune responses than did Family C strains that underwent more cell divisions in vivo prior to lysis. These rates and numbers of cell divisions in vivo prior to commencement of lysis is regulated by altering levels of expression of genes for virulence attributes, synthesis of peptidoglycan precursors and repressors by modification of promoter, SD and start-codon sequences and/or by altering the spacing between these elements and/or by alterations in plasmid copy numbers. Based on these results we are continuing to develop improved Family C strains as the PIESV vector strains as vaccine constructs for protective antigen and DNA vaccine delivery to prevent infectious diseases. Since recruitment and induction of innate immunity initially upon vaccination would be most beneficial in augmenting induction of acquired immunity by a vaccine, we have focused on developing the Family A and B ENIIRA/SDAAS strains to serve as superior adjuvants because they invade host cells and lyse quickly to deliver PAMPs/MAMPs to quickly activate induced innate immune responses.
[0123] Comparative evaluation of the survival of Family A and B strains after growth in Purple broth with arabinose and inoculation into medium without arabinose indicated rapid lysis and death of the Family A strain χ9052 whereas the Family B strain χ12499 increased in cell number for several cell divisions before lysis and death commenced (
b. Sal-Adj/ENIIRA/SDAAS Strains Constructed
[0124] Table 4 lists the strains constructed from the Family A strain χ9052. The properties associated with the mutations present are described in following sections.
TABLE-US-00004 TABLE 4 Family A strain genotypes and derivations Chi number Genotype Parent ϰ9052 Δalr-3 ΔdadB4 ΔasdA33 ϰ8901 ϰ12503 Δalr-3 ΔdadB4 ΔasdA33 ΔfliC180 ϰ9052 ϰ12512 Δalr-3 ΔdadB4 ΔasdA33 ΔfliC180 ΔpagP81::P.sub.lpp lpxE ϰ12503 ϰ12515 Δalr-3 ΔdadB4 ΔasdA33 ΔfliC180 ΔpagP81::P.sub.lpp lpxE ΔpagL7 ϰ12512 ϰ12517 Δalr-3 ΔdadB4 ΔasdA33 ΔfliC180 ΔpagP81::P.sub.lpp lpxE ΔpagL7 ϰ12515 ΔlpxR9 ϰ12553 Δalr-3 ΔdadB4 ΔasdA33 ΔfliC180 Δ(hin-fljBA)-219 ϰ12503 ϰ12554 Δalr-3 ΔdadB4 ΔasdA33 ΔfliC180 ΔpagP81::P.sub.lpp lpxE ΔpagL7 ϰ12517 ΔlpxR9 Δ(hin-fljBA)-219 ϰ12555 Δalr-3 ΔdadB4 ΔasdA33 ΔfliC180 ΔpagP81::P.sub.lpp lpxE ΔpagL7 ϰ12515 ΔwaaC41 ϰ12556 Δalr-3 ΔdadB4 ΔasdA33 ΔfliC180 ΔpagP81::P.sub.lpp lpxE ΔpagL7 ϰ12515 ΔwaaG42 ϰ12557 Δalr-3 ΔdadB4 ΔasdA33 ΔfliC180 ΔpagP81::P.sub.lpp lpxE ΔpagL7 ϰ12515 ΔwaaL46 ϰ12558 Δalr-3 ΔdadB4 ΔasdA33 ΔfliC180 ΔpagP81::P.sub.lpp lpxE ΔpagL7 ϰ12517 ΔlpxR9 ΔwaaC41 ϰ12559 Δalr-3 ΔdadB4 ΔasdA33 ΔfliC180 ΔpagP81::P.sub.lpp lpxE ΔpagL7 ϰ12517 ΔlpxR9 ΔwaaG42 ϰ12560 Δalr-3 ΔdadB4 ΔasdA33 ΔfliC180 ΔpagP81::P.sub.lpp lpxE ΔpagL7 ϰ12517 ΔlpxR9 ΔwaaL46
[0125] Table 5 lists the strains constructed from the Family 2 strain χ12499. The properties associated with the mutations present are described in following sections.
TABLE-US-00005 TABLE 5 Family B strain genotypes and derivations Chi number Genotype Parent ϰ12499 ΔP.sub.asdA55::TT araC P.sub.BAD asd Δalr-3 ΔP.sub.dadB66::TT araC P.sub.BAD dadB ϰ12498 ϰ12504 ΔP.sub.asdA55::TT araC P.sub.BAD asd Δalr-3 AP.sub.dadB66::TT araC P.sub.BAD dadB ϰ12499 ΔfliC180 ϰ12513 ΔP.sub.asdA55::TT araC P.sub.BAD asd Δalr-3 ΔP.sub.dadB66::TT araC P.sub.BAD dadB ϰ12504 ΔfliC180 ΔpagP81::P.sub.lpp lpxE ϰ12516 ΔP.sub.asdA55::TT araC P.sub.BAD asd Δalr-3 AP.sub.dadB66::TT araC P.sub.BAD dadB ϰ12513 ΔfliC180 ΔpagP81::P.sub.lpp lpxE ΔpagL7 ϰ12518 ΔP.sub.asdA55::TT araC P.sub.BAD asd Δalr-3 ΔP.sub.dadB66::TT araC P.sub.BAD dadB ϰ12516 ΔfliC180 ΔpagP81::P.sub.lpp lpxE ΔpagL7 ΔlpxR9 ϰ12542 ΔP.sub.asdA55::TT araC P.sub.BAD asd Δalr-3 ΔP.sub.dadB66::TT araC P.sub.BAD dadB ϰ12518 ΔfliC180 ΔpagP81::P.sub.lpp lpxE ΔpagL7 ΔlpxR9 ΔwaaC41 ϰ12543 ΔP.sub.asdA55::TT araC P.sub.BAD asd Δalr-3 ΔP.sub.dadB66::TT araC P.sub.BAD dadB ϰ12518 ΔfliC180 ΔpagP81::P.sub.lpp lpxE ΔpagL7 ΔlpxR9 ΔwaaG42 ϰ12544 ΔP.sub.asdA55::TT araC P.sub.BAD asd Δalr-3 ΔP.sub.dadB66::TT araC P.sub.BAD dadB ϰ12518 ΔfliC180 ΔpagP81::P.sub.lpp lpxE ΔpagL7 ΔlpxR9 ΔwaaL46 ϰ12545 ΔP.sub.asdA55::TT araC P.sub.BAD asd Δalr-3 ΔP.sub.dadB66::TT araC P.sub.BAD dadB ϰ12504 ΔfliC180 ΔwaaC41 ϰ12546 ΔP.sub.asdA55::TT araC P.sub.BAD asd Δalr-3 ΔP.sub.dadB66::TT araC P.sub.BAD dadB ϰ12504 ΔfliC180 ΔwaaG42 ϰ12547 ΔP.sub.asdA55::TT araC P.sub.BAD asd Δalr-3 ΔP.sub.dadB66::TT araC P.sub.BAD dadB ϰ12504 ΔfliC180 Δ(hin fljBA)-219 ϰ12548 ΔP.sub.asdA55::TT araC P.sub.BAD asd Δalr-3 ΔP.sub.dadB66::TT araC P.sub.BAD dadB ϰ12518 ΔfliC180 ΔpagP81::P.sub.lpp lpxE ΔpagL7 ΔlpxR9 Δ(hin fljBA)-219 ϰ12549 ΔP.sub.asdA55::TT araC P.sub.BAD asd Δalr-3 ΔP.sub.dadB66::TT araC P.sub.BAD dadB ϰ12504 ΔfliC180 ΔwaaL46
c. Construction of Strains with Alterations in LPS Structure
[0126] S. typhimurium is a gram-negative bacterium that contains LPS in its outer membrane. One vital component of LPS is lipid A that has a repeating disaccharide with six attached lipid acyl chains. Lipid A constitutes the potent endotoxin that can cause sepsis and death. The level of sensitivity to this endotoxin varies considerably among animal species with cattle, horses, dogs and humans being far more sensitive than chickens and even mice (34). It is also the lipid A that interacts as an agonist with TLR4 to recruit an innate immune response. However, Salmonella has evolved as a successful pathogen so as to infect more successfully by reducing the ability of its lipid A to trigger innate immunity by modifications that reduce the agonist activity of its lipid A. This is accomplished by decorating the lipid acyl chains with small molecules. Since lysis of ENIIRA/SDAAS strains immediately release the LPS with the lipid A endotoxin, we constructed strains χ12717 (Family A) and χ12518 (Family B) with the ΔpagP81::P.sub.lpp lpxE deletion-insertion mutation so that the strain synthesizes the non-toxic adjuvant mono-phosphoryl lipid A rather than the toxic lipid A while retaining its ability to activate TLR4 via the MD2 (rather than MyD88) pathway (33). Inactivation of the pagP gene is important since its gene product modifies lipid A to reduce its agonist activity. The promoter from the E. coli lipoprotein gene (lpp) is one of the strongest promoters since the lipoprotein synthesized is the most abundant protein in gram negative bacteria. It is used here to drive the constitutive expression of the lpxE gene from Francisella tularensis that eliminates a 4′ phosphate decoration of the lipid A disaccharide that is responsible for endotoxicity. This alteration thus precludes excess inflammation due to release of endotoxin in vivo although release of other cell constituents in Family B strains that undergo several cell divisions in vivo prior to onset of lysis might still be too inflammatory at high doses.
[0127] We therefore evaluated the relative attenuation/virulence of these two strains in mice by delivery of doses of 10.sup.4, 10.sup.5, 10.sup.6 and 10.sup.7 CFU by the i.v. route, doses of 10.sup.5, 10.sup.6, 10.sup.7 and 10.sup.8 CFU by the i.n. and s.c. routes, and 10.sup.9 CFU by the oral route. All mice survived challenge at all doses by all routes when infected with the Family A strain χ12517. However, some mice died when infected with the Family B strain χ12518 at doses above 10.sup.6 CFU by the i.v. and i.n. routes and above 10.sup.7 CFU by the s.c. route, while all mice survived oral inoculation. These results indicated that the several cell divisions in vivo of the Family B strains, due to the regulated delayed lysis in vivo attribute would necessitate animal studies using lower doses and ultimately for the need to introduce additional mutations to preclude excess inflammatory responses leading to mortality.
[0128] The ΔpagL7 and ΔlpxR9 mutations were also included to eliminate two additional means that Salmonella uses to lessen recruitment of innate immunity by reducing the agonist activity of lipid A (15). The benefits of these two mutations to enhancing TLR4 recruitment is demonstrated below in studies with HEK cells displaying the TLR 4 ligand. The eptA and arnT mutations (Table 1) have also been included in some ENIIRA/SDAAS strains as they also encode enzymes that lessen the agonist activity of lipid A.
[0129] Since some of the Family B derived strains administered at high doses by parenteral routes (i.v., s.c.) were too inflammatory, we constructed strains with deletion mutations in the waaC, waaG and waaL genes that eliminate synthesis of the middle LPS core, outer LPS core and LPS O-antigen, respectively, to confer complete attenuation. Since the waaC and waaG mutations reduce synthesis and display of flagella and might possibly reduce secretion of flagellin that is important for recruiting innate immunity via interaction with TLR5, the use of strains with the waaL mutation is preferred. Subsequently, we evaluated SDAAS strains such as χ12626 and χ12649 with the ΔwbaP45 mutation as a different means to block coupling of the LPS O-antigen to the LPS core.
d. Construction of Strains with Alterations in Flagella and Flagellin Release
[0130] A non-flagellated strain χ9028 with the ΔfliC2426 and ΔfljB217 mutations and strain χ9026 in which the ΔfliC2426 mutation is replaced with the ΔfliC180 mutation to result in synthesis and release of a truncated flagellin that activates TLR5 (see Overview/Preliminary studies) were used in initial evaluations. We initially constructed Family A and B strains with the ΔfliC180 mutation since initial results showed that this mutation enhanced production and release of the FliC flagellin that activates TLR5. In addition, the phase-lock mutation Δ(hin-fljBA)-219 was introduced so that the FliC protein is made by all Sal-Adj/ENIIRA/SDAAS cells. The fljB mutation eliminates the ability of these strains to synthesize the Phase II flagellin and the fljA mutation eliminates synthesis of the repressor that would block transcription of the fliC gene that specifies the Phase I flagellin. A further enhancement in flagellin production was achieved, in one embodiment, by introducing another mutation (cfs) that causes constitutive high-level flagellin synthesis.
[0131] As shown in
e. Construction of Strains with Alterations in Display of Fimbriae
[0132] S. typhimurium has 12 operons that specify synthesis of fimbriae (18) and most of these are subject to regulation such that they are only synthesized in certain environments. We recently identified four fimbrial operons using the IVET system to identify in vivo expressed genes that are synthesized in the spleen after oral infection whereas the other eight fimbrial operons were not expressed (18). It was also determined that constitutive synthesis of the in vivo-synthesized Saf and Stc fimbriae significantly enhanced induction of protective immunity of a RASV/PIESV strain (18). Strains will therefore be evaluated for interaction with HEK cells and enhancing Ova immune responses lacking the other fimbrial operons expressed in vivo with either the deletion-insertion mutation ΔP.sub.stc53::P.sub.murA stc or ΔP.sub.saf55::P.sub.murA saf to cause constitutive synthesis of Stc or Saf fimbriae.
f. Other Constructions
[0133] In the initial comparison of the Family A, B and C parental lysis strains, derivatives were compared with the ΔsifA26 mutation that eliminates a means of immunosuppression and enables S. typhimurium cells to escape from the Salmonella-containing vesicle (SCV) such that lysis can occur in the cytosol. In RASV/PIESV strains that undergo regulated delayed lysis in vivo, escape from the SCV enables lysis of some vaccine cells to occur in the cytosol for delivery of protective antigens to the proteosome for Class I presentation and enhanced induction of CD8-dependent cellular immunity. Although individual cells of ENIIRA/SDAAS strains with the regulated delayed in vivo lysis attribute, can lyse prior to invasion into host cells or after invasion into cells whether contained in the SCV or after escape from the SCV (due to a ΔsifA mutation) or after escape from a host cell undergoing pyroptosis, such lysis will release peptidoglycan components, RNA and DNA. Since peptidoglycan components activate Nod1 and Nod2, released RNA can activate TLR8 and CpG containing DNA sequences activate TLR9, the location of the release of these components will impact the level of activation of Nod1, Nod2, TLR8 and TLR9 that are located internally in host cells. On average, ENIIRA/SDAAS strains with the ΔsifA26 mutation would therefore be expected to better activate Nod1, Nod2, TLR8 and TLR9.
[0134] The recA mutation blocks genetic recombination but about 10 percent of cells at each cell division undergo Rec-less cell death since occasional recombination between replicating chromosomes leads to rapid unregulated degradation of DNA. Consequentially, ENIIRA/SDAAS strains with recA mutations should be more efficient in liberating DNA fragments containing CpG sequences to activate TLR9. An additional benefit is that recA mutants of S. typhimurium are totally avirulent and do not induce disease symptoms when administered to animal hosts. We have therefore inserted the ΔrecA62 mutation into candidate ENIIRA/SDAAS strains.
[0135] Some Salmonella pathogenicity island (SPI) 2 genes are effectors that can dampen induction of innate immune responses. The steE gene seems to be in this category such that ENIIRA strains unable to synthesize the steE gene product are investigated for impact on induction of innate immune responses using the HEK cell lines.
g. Characterization of Constructed ENIIRA/SDAAS Strains
[0136] All constructed ENIIRA/SDAAS strains are evaluated for the correctness of the introduced mutations and the phenotypes expected are confirmed using all the methods described in Example 1. In this regard, Family A strains such as χ12517 commence to lyse as they attempt to grow in any medium lacking DAP and D-alanine such that cultures completely lyse within several hours after transfer from a permissive growth medium to a non-permissive growth condition in the absence of DAP and D-alanine (
h. Discussion
[0137] As each of the Sal-Adj/ENIIRA/SDAAS strains described above is constructed its properties are being fully validated. The abilities of these strains in comparison to parent and control strains to stimulate NF-kB production in HEK cells having different TLR and Nod factors were evaluated (Example 3). These results also led to synthesis of strains with combinations of mutations and the conduct of animal studies to determine which combination of mutations yields a Sal-Adj/ENIIRA/SDAAS strain(s) with greatest ability to enhance immune responses to Ova (Example 4) and protection against Mtb (Example 5).
Example 3. Evaluation of Sal-Adj/ENIIRA/SDAAS Strains to Activate Synthesis of NF-kB Production in HEK293 Cells
[0138] Strains constructed in the Example 2 research were initially tested and compared for their ability to interact with and stimulate HEK293 cells with TLR1, TLR2, TLR4 (two types), TLR5 (two types), TLR6, TLR9, Nod1 and Nod2 using methods described in Example 1 M&M. Most evaluations have been with Family A strains since they commence to lyse immediately upon placing in non-permissive conditions in the absence of arabinose (see
[0139] Results observed in evaluation of several Family A and Family B strains in assays of NFκB recruitment in HEK cells displaying TLR4 are presented in
[0140] Results observed in evaluation of several Family A and Family B strains in assays of NFκB recruitment in HEK cells displaying TLR5 are presented in
[0141] As noted above in reference to the
Example 4. Evaluation of Sal-Adj/ENIIRA/SDAAS Strains by s.c., i.n. and Oral Routes with s.c. Administration of Ova Suspended in Buffered Saline or Alum and Monitoring Antibody Responses to Ova
[0142] Because of total avirulence, we concentrated on testing the adjuvant activity of the Family A parental strain χ9052. The results presented in
Example 5. Evaluation of the Ability of ENIIRA/SDAAS Strains to Augment Ability of BCG to Diminish Infection of Mice with M. tuberculosis H37RV (Mtb) and Whether Also Enhances the Ability of a PIESV Construct Delivering Mtb Protective Antigens to Further Protect Against Mtb Infection and Proliferation
[0143] Three experiments have been conducted in which ENIIRA/SDAAS strains have been administered in combination with M. bovis BCG, which is currently the only vaccine approved for human use to prevent infections by M. tuberculosis and development of TB. In all of these experiments, BCG was administered s.c. with 5×10.sup.4 CFU of BCG, either alone or in combination with ENIIRA/SDAAS strains and/or the PIESV χ12068(pYA4891). All immunizations/inoculations were given once. All experiments included a group of mice that were administered 100 μl of phosphate-buffered saline PBS on Day 0; these were unimmunized control mice. Thirty-five days after immunization, all mice were challenged with a low-dose aerosol of virulent M. tuberculosis H37Rv, such that each mouse received 50-100 bacteria per lung. On day 28 in Experiments 15 and 20 (
[0144] In Experiment 14 (
[0145] In Experiment 15 (
[0146] In Experiment 20 (
[0147] The results from the three experiments described above demonstrate that co-administration of BCG with ENIIRA/SDAAS strains plus χ12068(pYA4891) enhances the ability of BCG to protect mice against aerosol challenge with M. tuberculosis and that co-administration enhances both antibody and T-cell responses that is likely to contribute to protection against challenge. If found to be true in humans, the impact will be highly significant. Splenomegaly: In experiments in which mice were immunized subcutaneously with M. bovis BCG alone or in combination with ENIIRA/SDAAS strains or the PIESV χ12068(pYA4891) or both an ENIIRA strain and χ12068(pYA4891), splenomegaly was observed in mice immunized with BCG and an ENIIRA strain. In Experiment 1-1, where the ENIIRA strain was χ12499 (Family B), 2 out of 9 mice immunized with χ12499 (delivered s.c.) alone, 2 out of 10 mice immunized with the combination of BCG+χ12499 (both delivered s.c) and 7 out of 8 mice immunized with the combination of BCG (delivered s.c.)+χ12499 (delivered i.v.) had significantly enlarged spleens, compared to the spleens of control mice (PBS administered s.c) and mice immunized with BCG alone, in which none of the mice had enlarged spleens. In Experiment 15, in which mice were immunized with BCG alone (delivered s.c.) or BCG (delivered s.c.) in combination with the PIESV χ12068(pYA4891) or Family A ENIIRA strain χ12517 or Family B ENIIRA strain χ12518 (each administered i.v), only mice immunized with the combination of BCG+χ12518 had enlarged spleens. In Experiment mice were immunized with BCG alone (delivered s.c.) and in combination with the PIESV χ12068(pYA4891), delivered i.v., the Family B ENIIRA strain χ12518 (delivered i.v.), χ12068(pYA4891) and χ12518 (both delivered i.v.) or χ12068(pYA4891), delivered intranasally, and χ12518, delivered i.v. All groups of mice immunized with χ12518 (which was always administered i.v.) had mice with enlarged spleens. At present, we do not know why some mice in these three experiments developed enlarged spleens.
[0148] However, these results are in accord with other observations that indicate that the Family B strain χ12518 (ΔP.sub.asdA55::TT araC P.sub.BAD asd Δalr-3 ΔP.sub.dadB66::TT araC P.sub.BAD dadB ΔfliC180 ΔpagP81::P.sub.lpp lpxE ΔpagL7 ΔlpxR9) is possibly too inflammatory because it multiplies too many cell divisions prior to lysis. Although this can be addressed by using lower doses, we are now testing the benefits of including the ΔwaaL46 (χ12544), ΔwbaP45 and with or without ΔsifA26 and/or ΔrecA62 mutations on ensuring complete attenuation while retaining and even augmenting the beneficial adjuvant activities.
Example 6. Modification of ENIIRA/SDAAS Strains to Display PAMPS/MAMPs that Activate Innate Immune Receptors Displayed by Diverse Bacterial, Viral, Fungal and Parasite Pathogens
[0149] Our group has displayed capsular polysaccharides specified by genes from gram-negative and gram-positive bacterial species on the surface of Salmonella strains. We have also expressed lipo-proteins and protein appendages encoded by genes from diverse pathogens. In addition, since the ENIIRA/SDAAS strains are designed to lyse, they can liberate plasmids engineered to display single-stranded and double-stranded RNAs as displayed by and serving as PAMPS for RNA viruses and for RNA released by living pathogenic microbes. It is thus possible to modify ENIIRA strains to induce innate immune responses that could differ and be more appropriate and efficacious in enhancing immunity to be induced by a diversity of vaccines targeting prevention of infection by diverse bacterial, viral, fungal and parasite pathogens.
Example 7. Non-Specific Protection Against Infection by Other Pathogens
[0150] It has been found that administration of the Sal-Adj/ENIIRA/SDAAS constructs induces low-level protective immunity to challenge of unvaccinated animals to various bacterial, viral and parasite pathogens as revealed by the data in Table 3 in which the empty vector PIESV strains are representative of Family C ENIIRA strains. These results are impactful in the protection, in some examples, of military personnel and civilians against a biothreat as well as to contend with epidemics. These ENIIRA strains will also have utility in augmenting levels of protective immunity of subunit and killed vaccines and even of attenuated vaccines that do not induce robust protective immunity of long duration, such as BCG (see Example 5). It can also be expected that the level of innate immunity induced by administering ENIIRA strains will be of reasonably long duration. In fact, these strains will probably be effective in inducing memory innate immune responses. The data in Table 3 supports this since the challenge infections to which protection was conferred by vaccination with empty vector PIESV strains were 30 or more days after primary vaccination.
Note: During the course of research to discover and then improve use of live self-destructing Salmonella as adjuvants to enhance recruitment of innate immunity to augment eventual levels of acquired immunity, we simplified terminology from calling these Sal-Adj strains to ENIIRA strains to the simpler and more descriptive Self-Destructing Attenuated Adjuvant Salmonella (SDAAS) strains as used in the following examples.
Example 8. Additional Data Pertaining to Studies Demonstrating Enhancement of Levels of Protection Against Mycobacterium tuberculosis Challenge of Mice Inoculated with Combinations of BCG with SDAAS Strain and a PIESV Delivering Mtb Antigens
[0151] Studies on induction of immunity to M. tuberculosis (Mtb) infections are time-consuming due to the very slow growth of Mtb such that colony counts to determine bacterial densities require 4 weeks or so of incubation to obtain data. Thus, data from Experiments 14, 15 and 20 described in Example 5 continued for several months after the PCT application was filed. Analyses of induced immune responses in mice used in these studies also continued.
[0152] At the time of filing the PCT application, there were no colonies on plating undiluted spleen suspensions from mice inoculated with BCG and the Family B SDAAS strain χ12518 independent of receiving the PIESV strain χ12068(pYA4891). We thought that maybe there was an inhibition in rate of growth due to the inoculation treatments so we only presented data from the lung suspension cultures (
Example 9. Further Modifications of Family A and B SDAAS Strains to Investigate Effects of Additional Mutational Alterations to Enhance Safety and Effectiveness of Adjuvant Activities
[0153] As described in Example 5, inoculation of the Family B SDAAS strain χ12518 at a dose of 5×10.sup.4 CFU i.v. caused significant splenomegaly that was not observed with oral or s.c inoculation and at lower doses by the i.v. route. As a consequence, we commenced to construct derivatives of the Family A strain χ12517 and the Family B strain χ12518 with additional mutations to enhance recruitment of innate immunity while reducing potential toxicity upon lysis of the strains in vivo. Many of these SDAAS strains with such modifications were listed in Tables 4 and 5 in Example 2 and additional SDAAS strains were constructed after filing of the PCT application. These newer AAS strains are included in Table 8 with the new mutations and their associated genotypes and phenotypes described in Table 6. Table 7 lists the suicide vectors used to generate the new AAS strains whose properties are presented and discussed in the following Examples.
Table 6. Additional Mutations with Associated Phenotypes Enhancing Adjuvant Activity and/or safety of AAS strains
A. Deletion and Deletion-Insertion Mutations to Facilitate Regulated Delayed Lysis In Vivo
[0154] ΔP.sub.asdA::TT rhaRS P.sub.rhaBAD asdA and ΔP.sub.asdA::TT P.sub.rhaBAD asdA make synthesis of AsdA dependent on presence of rhamnose.
[0155] ΔP.sub.dadB::TT rhaRS P.sub.rhaBAD dadB and ΔP.sub.dadB::TT P.sub.rhaBAD dadB make synthesis of DadB dependent on presence of rhamnose.
[0156] In one case the repression-activation of the P.sub.rhaBAD promoter can use the encoded E. coli rhaRS gene products or the endogenous Salmonella rhaRS gene products whereas in the case in which the E. coli rhaRS genes were excluded from the inserted regulatory cassette, the P.sub.rhaBAD is subject to control by only the Salmonella rhaRS gene products.
C. Mutations Altering Synthesis of LPS Components
[0157] ΔlpxR::P.sub.lpp lpxF mutation causes regulated delayed in vivo synthesis of the codon-optimized lpxF gene from Francisella tularensis to cause synthesis of the non-toxic adjuvant form of LPS lipid A that lacks the 4′ phosphate on lipid A. The lpxR mutation eliminates a means by which Salmonella alters
[0158] LPS lipid A in vivo to decrease recruitment of innate immunity by interaction with TLR4 (16) [0159] Δpmi eliminates gene for phosphomannose isomerase such that LPS O-antigen synthesis is dependent on presence of non-phosphorylated mannose in growth medium (47) [0160] Δrfc eliminates an enzyme that couples units of LPS O-antigen composed of 4 or 5 sugars to result in long-chain LPS O-antigen polymers (48) [0161] ΔwbaP eliminates an enzyme needed to couple the first LPS O-antigen subunit onto the LPS core (49)
H. Mutations Enhancing Adjuvant Activity and Safety of Strains
[0162] ΔsopB decreases induction of inflammatory response for strains delivered on a mucosal surface (43) and increases induction of mucosal immunity (44)
ΔsopF enables Salmonella to escape the SCV (45) [0163] ΔsseL decreases induction of pyroptosis (46) [0164] ΔtlpA decreases induction of pyroptosis (46) [0165] ΔpurA imposes an obligate requirement for non-phosphorylated adenine that is essential and absent in animal tissues; is thus totally attenuating (50)
The suicide vectors used to introduce the mutations listed in Table 6 into new AAS strains are listed in Table 7.
The new SDAAS strains constructed are listed in Table 8.
TABLE-US-00006 TABLE 7 Suicide vectors for constructing SDAAS strains with mutations listed in Table 6 A. Deletion and deletion-insertion mutations to facilitate regulated delayed lysis in vivo ΔP.sub.dadB66::TT rhaRS P.sub.rhaBAD2 dadB pG8R340 Cm ΔP.sub.dadB66::TT rhaRS P.sub.rhaBAD1 dadB pG8R352 Cm ΔP.sub.dadB66::TT P.sub.rhaBAD1 dadB pG8R353 Cm ΔP.sub.asdA55::TT rhaRS P.sub.rhaBAD1 asdA pG8R354 Cm ΔP.sub.asdA55::TT P.sub.rhaBAD1 asdA pG8R355 Cm C. Mutations altering synthesis of LPS components ΔlpxR:P.sub.lpp lpxF pYA4289 Cm Δpmi pYA3546 Tet Δrfc pYA4717 Cm ΔwbaP pYA4899 Cm H. Mutations enhancing adjuvant activity and safety of strains ΔsopB pYA3733 Cm ΔsopF ΔsseL pYA4621 Cm ΔtlpA pYA4620 Cm ΔpurA pG8R126 Cm
TABLE-US-00007 TABLE 8 Newly constructed AAS strains Family A strains (genotypes and derivations) ϰ12565 Δalr-3 ΔdadB4 ΔasdA33 ΔfliC180 ΔpagP81::P.sub.lpp lpxE ΔpagL7 ΔlpxR9 ϰ12517 ΔrecA62 ϰ12606 Δalr-3 ΔdadB4 ΔasdA33 ΔfliC180 Δ(hin-fljBA)-219 ΔpagP8 ϰ12553 ϰ12608 Δalr-3 ΔdadB4 ΔasdA33 ΔfliC180 ΔpagP81::P.sub.lpp lpxE ΔpagL7 ΔlpxR9 ϰ12517 ΔsifA26 ϰ12625 Δalr-3 ΔdadB4 ΔasdA33 ΔfliC180 Δ(hin-fljBA)-219 ΔpagP8 ΔlpxR9 ϰ12606 ϰ12629 Δalr-3 ΔdadB4 ΔasdA33 ΔfliC180 Δ(hin-fljBA)-219 ΔpagP8 ΔlpxR9 ϰ12625 ΔpagL7 ϰ12638 Δalr-3 ΔdadB4 ΔasdA33 ΔfliC180 Δ(hin-fljBΔ)-219 ΔpagP8 ΔlpxR9 ϰ12629 ΔpagL7 ΔeptA4 ϰ12640 Δalr-3 ΔdadB4 ΔasdA33 ΔfliC180 Δ(hin-fljBA)-219 ΔpagP8 ΔlpxR9 ϰ12638 ΔpagL7 ΔeptA4 ΔarnT6 ϰ12650 Δalr-3 ΔdadB4 ΔasdA33 ΔfliC180 Δ(hin-fljBA)-219 ΔpagP8 ΔlpxR9 ϰ12640 ΔpagL7 Δepta4 ΔarnT6 Δsifa26 ϰ12661 Δalr-3 ΔdadB4 Δasda33 ΔfliC180 Δ(hin-fljBa)-219 ΔpagP8 ΔlpxR9 ϰ12650 ΔpagL7 Δepta4 ΔarnT6 Δsifa26 ΔrecA62 Family B strains (genotypes and derivations) ϰ12564 Δalr-3 ΔP.sub.dadB66::TT araC P.sub.araBAD dadB ΔP.sub.asdA55::TT araC P.sub.araBAD asdA ϰ12504 ΔfliC180 Δreca62 ϰ12566 Δalr-3 ΔP.sub.dadB66::TT araC P.sub.araBAD dadB ΔP.sub.asdA55::TT araC P.sub.araBAD asdA ϰ12518 ΔfliC180 ΔpagP81::P.sub.lpp lpxE ΔpagL7 ΔlpxR9 ΔrecA62 ϰ12567 Δalr-3 ΔP.sub.dadB66::TT araC P.sub.araBAD dadB ΔP.sub.asdA55::TT araC P.sub.araBAD asdA ϰ12544 ΔfliC180 ΔpagP81::P.sub.lpp lpxE ΔpagL7 ΔlpxR9 ΔwaaL46 ΔrecA62 ϰ12568 Δalr-3 ΔP.sub.dadB66::TT araC P.sub.araBAD dadB ΔP.sub.asdA55::TT araC P.sub.araBAD asdA ϰ12549 ΔfliC180 ΔwaaL46 ΔrecA62 ϰ12570 Δalr-3 ΔP.sub.dadB66::TT araC P.sub.araBAD dadB ΔP.sub.asdA55::TT araC P.sub.araBAD asdA ϰ12518 ΔfliC180 ΔpagP81::P.sub.lpp lpxE ΔpagL7 ΔlpxR9 ΔarnT6 ϰ12571 Δalr-3 ΔP.sub.dadB66::TT araC P.sub.araBAD dadB ΔP.sub.asdA55::TT araC P.sub.araBAD asdA ϰ12548 ΔfliC180 ΔpagP81::P.sub.lpp lpxE ΔpagL7 ΔlpxR9 Δ(hin-fljBA)-219 ΔarnT6 ϰ12583 Δalr-3 ΔP.sub.dadB66::TT araC P.sub.araBAD dadB Δ.sub.PasdA55::TT araC P.sub.araBAD asdA ϰ12518 ΔfliC180 ΔpagP81::P.sub.lpp lpxE ΔpagL7 ΔlpxR9 ΔeptA4 ϰ12584 Δalr-3 ΔP.sub.dadB66::TT araC P.sub.araBAD dadB ΔP.sub.asdA55::TT araC P.sub.araBAD asdA ϰ12548 ΔfliC180 ΔpagP81::P.sub.lpp lpxE ΔpagL7 ΔlpxR9 Δ(hin-fljBA)-219 ΔeptA4 ϰ12585 Δalr-3 ΔP.sub.dadB66::TT araC P.sub.araBAD dadB ΔP.sub.asdA55::TT araC P.sub.araBAD asdA ϰ12571 ΔfliC180 ΔpagP81::P.sub.lpp lpxE ΔpagL7 ΔlpxR9 Δ(hin-fljBA)-219 ΔarnT6 ΔeptA4 ϰ12586 Δalr-3 ΔP.sub.dadB66::TT araC P.sub.araBAD dadB ΔP.sub.asdA55::TT araC P.sub.araBAD asdA ϰ12570 ΔfliC180 ΔpagP81::P.sub.lpp lpxE ΔpagL7 ΔlpxR9 ΔarnT6 ΔeptA4 ϰ12603 Δalr-3 ΔP.sub.dadB66::TT araC P.sub.araBAD dadB ΔP.sub.asdA55::TT araC P.sub.araBAD asdA ϰ12547 ΔfliC180 Δ(hin-fljBΔ)-219 ΔpagP8 ϰ12604 Δalr-3 ΔP.sub.dadB66::TT araC P.sub.araBAD dadB ΔP.sub.asdA55::TT araC P.sub.araBAD asdA ϰ12548 ΔfliC180 ΔpagP8 ΔpagL7 ΔlpxR9 Δ(hin-fljBΔ)-219 ϰ12605 Δalr-3 ΔP.sub.dadB66::TT araC P.sub.araBAD dadB ΔP.sub.asdA55::TT araC P.sub.araBAD asdA ϰ12603 ΔfliC180 Δ(hin-fljBA)-219 ΔpagP8 ΔpagL7 ϰ12609 ΔP.sub.asdA55::TT araC P.sub.araBAD asd Δalr-3 ΔP.sub.dadB66::TT araC P.sub.araBAD dadB ϰ12518 ΔfliC180 ΔpagP81::P.sub.lpp lpxE ΔpagL7 ΔlpxR9 ΔsifA26 ϰ12610 ΔP.sub.asdA55::TT araC P.sub.araBAD asd Δalr-3 ΔP.sub.dadB66::TT araC P.sub.araBAD dadB ϰ12604 ΔfliC180 ΔpagP8 ΔpagL7 ΔlpxR9 Δ(hin-fljBA)-219 ΔsifA26 ϰ12611 ΔP.sub.asdA55::TT araC P.sub.araBAD asd Δalr-3 ΔP.sub.dadB66::TT araC P.sub.araBAD dadB ϰ12504 ΔfliC180 ΔsifA26 ϰ12612 ΔP.sub.asdA55::TT araC P.sub.araBAD asd Δalr-3 ΔP.sub.dadB66::TT araC P.sub.araBAD dadB ϰ12585 ΔfliC180 ΔpagP81::P.sub.lpp lpxE ΔpagL7 ΔlpxR9 Δ(hin-fljBA)-219 ΔarnT6 ΔeptA4 ΔsifA26 ϰ12620 ΔP.sub.asdA55::TT araC P.sub.araBAD asd Δalr-3 ΔP.sub.dadB66::TT araC P.sub.araBAD dadB ϰ12612 ΔfliC180 ΔpagP81::P.sub.lpp lpxE ΔpagL7 ΔlpxR9 Δ(hin-fljBA)-219 ΔarnT6 ΔeptA4 ΔsifA26 Δpmi-2426 ϰ12621 ΔP.sub.asdA55::TT araC P.sub.araBAD asd Δalr-3 ΔP.sub.dadB66::TT araC P.sub.araBAD dadB ϰ12612 ΔfliC180 ΔpagP81::P.sub.lpp lpxE ΔpagL7 ΔlpxR9 Δ(hin-fljBA)-219 ΔarnT6 ΔeptA4 ΔsifA26 Δrfc-112 ϰ12623 Δalr-3 ΔP.sub.dadB66::TT araC P.sub.araBAD dadB ΔP.sub.asdA55::TT araC P.sub.araBAD asdA ϰ12604 ΔfliC180 ΔpagP8 ΔpagL7 ΔlpxR9 Δ(hin-fljBA)-219 ΔeptA4 ϰ12626 ΔP.sub.asdA55::TT araC P.sub.araBAD asd Δalr-3 ΔP.sub.dadB66::TT araC P.sub.araBAD dadB ϰ12612 ΔfliC180 ΔpagP81::P.sub.lpp lpxE ΔpagL7 ΔlpxR9 Δ(hin-fljBA)-219 ΔarnT6 ΔeptA4 ΔsifA26 ΔwbaP45 ϰ12639 Δalr-3 ΔP.sub.dadB66::TT araC P.sub.araBAD dadB ΔP.sub.asdA55::TT araC P.sub.araBAD asdA ϰ12623 ΔfliC180 ΔpagP8 ΔpagL7 ΔlpxR9 Δ(hin-fljBA)-219 ΔeptA4 ΔarnT6 ϰ12641 ΔP.sub.asdA55::TT araC P.sub.araBAD asd Δalr-3 ΔP.sub.dadB66::TT araC P.sub.araBAD dadB ϰ12612 ΔfliC180 ΔpagP81::P.sub.lpp lpxE ΔpagL7 ΔlpxR9 Δ(hin-fljBA)-219 ΔarnT6 ΔeptA4 ΔsifA26 ΔwaaL46 ϰ12648 ΔP.sub.asdA55::TT araC P.sub.araBAD asd Δalr-3 ΔP.sub.dadBxx::TT rhaSR P.sub.rhaBAD dadB ϰ12612 ΔfliC180 ΔpagP81::P.sub.lpp lpxE ΔpagL7 ΔlpxR9 Δ(hin-fljBA)-219 ΔarnT6 ΔeptA4 ΔsifA26 ϰ12649 ΔP.sub.asdA55::TT araC P.sub.araBAD asd Δalr-3 ΔP.sub.dadBxx::TT rhaSR P.sub.rhaBAD dadB ϰ12626 ΔfliC180 ΔpagP81::P.sub.lpp lpxE ΔpagL7 ΔlpxR9 Δ(hin-fljBA)-219 ΔarnT6 ΔeptA4 ΔsifA26 ΔwbaP45 ϰ12668 ΔP.sub.asdA55::TT araC P.sub.araBAD asd Δalr-3 ΔP.sub.dadB66::TT araC P.sub.araBAD dadB ϰ12612 ΔfliC180 ΔpagP81::P.sub.lpp lpxE ΔpagL7 ΔlpxR9 Δ(hin-fljBA)-219 ΔarnT6 ΔeptA4 ΔsifA26 ΔrecA62 ϰ12669 ΔP.sub.asdA55::TT araC P.sub.araBAD asd Δalr-3 ΔP.sub.dadB66::TT araC P.sub.araBAD dadB ϰ12626 ΔfliC180 ΔpagP81::P.sub.lpp lpxE ΔpagL7 ΔlpxR9 Δ(hin-fljBA)-219 ΔarnT6 ΔeptA4 ΔsifA26 ΔwbaP45 ΔrecA62
Example 10. Maximizing Synthesis and Delivery of a FliC Flagellin Subunit to Interact with TLR5 to Activate Induction of Innate Immunity
[0166] The FliC180 flagellin subunit was derived by an internal deletion in the fliC gene that eliminated 180 amino acids with retention of the TLR5 binding domain. Also, this FliC180 subunit is secreted by the flagellar type 3 secretion system and since it does not polymerize into flagella, is available for interaction with cell-surface localized TLR5 molecules. It should be emphasized that it is flagellin and not flagella with capability of interacting with TLR5. Thus, SDAAS strains synthesizing and secreting the FliC180 subunit are more active in activating NF-κB in HEK cells displaying TLR5 than are wild-type strains synthesizing flagella (see
[0167]
Example 11. Modifications in Synthesis of LPS Components Including Modifications of the Lipid a Endotoxin to Enhance Recruitment of Innate Immune Responses and Reduce Toxicity
[0168] In Example 3 we noted that waaC and waaG mutations that eliminate the LPS O-antigen and truncate the LPS core enhance the ability of the Family B SDAAS strain χ12518 to exhibit enhanced abilities to activate NF-κB synthesis in HEK cells displaying TLR4 (
[0169]
TABLE-US-00008 TΔBLE 9 S. Typhimurium mutant strains evaluated for levels of endotoxicity 1. ϰ9429 ΔeptA4 2. ϰ9432 ΔarnT6 3. ϰ9486 ΔarnT ΔeptA 4. ϰ9883 ΔpagL7 ΔpagP8 ΔlpxR9 ΔarnT6 5. ϰ9904 ΔpagL7 ΔpagP8 ΔlpxR9 ΔamT6 ΔeptA4 6. ϰ9430 ΔpagL7 7. ϰ9433 ΔlpxR9 8. ϰ9434 ΔpagP8 9. ϰ3761 wild-type UK-1 parent
[0170] For these assays, strains were grown in LB broth overnight at 37° C. with aeration (180 rpm) and then diluted 1:10 into prewarmed LB broth and grown with continued aeration to an OD600 of 1.0 (˜1×10.sup.9 CFU/ml). Bacterial cells were harvested by centrifugation, resuspended in endotoxin free water and disrupted by sonication. Cell lysates were diluted, distributed in 96 well plates and the successive reactions conducted according to the instructions provided with the Pierce Kit. Reactions were stopped and the results evaluated in a microplate absorbance reader at 405 nm. The results are presented in
Example 12. Properties Associated with Constructed SDAAS Strains that should Further Enhance Adjuvant Activities and Safety Attributes
[0171] The ΔsifA26 mutation enables Salmonella to escape the Salmonella containing vesicle (SCV) also termed the endosome and this enables all the SDAAS strains with programed abilities to undergo lysis in vivo to escape from the SCV to lyse in the cytosol. This lysis then liberates peptidoglycan constituents and DNA to interact with Nod1, Nod2, TLR8 and TLR9 that are located on internal cell surfaces (and are not available if lysis occurs within the SCV). It would thus be expected that Family A SDAAS strain χ12608, χ12650 and χ12661 (Table 8) and the Family B SDAAS strains χ12609, χ12610, χ12611, χ12612, χ12620, χ12621, χ12626, χ12641, χ12648, χ12649, χ12668 and χ12669 (Table 8) that all possess the ΔsifA26 mutation would exhibit an enhanced ability to activate NF-κB synthesis compared to SDAAS strains without this mutation. An added benefit is that S. typhimurium strains with the ΔsifA26 mutation are more than 10,000 times less virulent when orally administered to mice compared to the wild-type parent. It is also possible that addition of a ΔsopF mutation (Table 6) in place of or in addition to the ΔsifA26 mutation will also be beneficial since the ΔsopF mutation also enables Salmonella to escape from the SCV to lyse in the cytosol.
[0172] The ΔrecA62 mutation eliminates the ability of Salmonella to carry out genetic recombination and results in increased sensitivity to UV and other stresses. The mutation also renders Salmonella more than 10,000 times less virulent than the wild-type parent after oral inoculation into mice. Importantly, genetic recombination is lethal with approximately 10% of the cells in the population degrading their entire DNA content as a consequence of progeny strand recombination. If this occurs in lysing AAS cells after escape from the SCV, there should be an increased release of CpG sequences targeting the internal TLR9 to activate NF-κB synthesis. This ΔrecA62 mutation has thus been introduced into the Family A SDAAS strain χ12565 and χ12661 the Family B SDAAS strains χ12566, χ12567, χ12568, χ12668 and χ12669 (Table 8) to enable testing of these expectations.
[0173] As stated in Example 10 and depicted in
[0174] Although we observed that inability to synthesize the LPS O-antigen and part of the LPS core increased interaction with TLR4 (
[0175] If desired, further safety can be provided by replacing a mutation for the arabinose-dependent expression of either the asdA or dadB genes with either the rhaRS P.sub.rhaBAD or P.sub.rhaBAD cassette which makes gene expression dependent on rhamnose as a second required sugar for AAS strain viability and survival.
[0176] The final outcome of these constructions and evaluations should result in SDAAS strains with maximal abilities to stimulate innate immunity by multiple pathways that will be completely attenuated (avirulent) and non-toxic (non-reactogenic) and thus enhance the immunogenicity of a diversity of subunit and live attenuated or live vectored vaccines to induce protective immunity.
Example 13. Evaluation of Family B Strains with Improvements Based on Inclusion of Mutations to Alter LPS Synthesis, Escape from SCV and Recombination Proficiency and DNA Stability
[0177] In evaluating Family B strains with mutations altering LPS structure, we observed that strains χ12542 (ΔwaaC41) and χ12543 (ΔwaaG42) interacted with TLR4 on HEK cells at higher levels than their parent strain χ12518 (
[0178] We next evaluated all these strains (including the Family A strains with the ΔpagP8, ΔlpxR9 and ΔpagL7 mutations) for interaction with TLR4 on HEK cells. In this study (
[0179] The Family B and A strains evaluated in the studies generating the data in
[0180] For the studies to investigate activation of NFκB synthesis in HEK cells with TLR8 and TLR9, we selected Family A strains that rapidly lyse during infection of cells rather than Family B strains that display regulated delayed lysis features such that they will not lyse during the first 24 h after entry into host cells. As reveled by the results depicted in
Example 14. Selection of Family A and B Strains to Thoroughly Evaluate Adjuvant Activities in Animal Studies
[0181] We have selected the Family A strain χ12661 (Δalr-3 ΔdadB4 ΔasdA33 ΔfliC180 Δ(hin-fljBA)-219 ΔpagP8 ΔlpxR9 ΔpagL7 ΔeptA4 ΔarnT6 ΔsifA26 ΔrecA62) and the Family B strain χ12669 (ΔP.sub.asdA55::TT araC P.sub.araBAD asd Δalr-3 ΔP.sub.dadB66::TT araC P.sub.araBAD dadB ΔfliC180 ΔpagP81::P.sub.lpp lpxE ΔpagL7 ΔlpxR9 Δ(hin-fljBA)-219 ΔarnT6 ΔeptA4 ΔsifA26 ΔwbaP45 ΔrecA62) for the conduct of a diversity of animal studies analogous to those described in Examples 4 and 5 as well as other studies on enhancement of immune responses dependent on genotypes of PIESV vector strains comparing strains not lysing versus strains with rapid versus a much slower rate of in vivo regulated delayed lysis. We are also considering altering the Family B strain χ12669 to replace either the ΔP.sub.asdA55::TT araC P.sub.araBAD asd or the ΔP.sub.dadB66::TT araC P.sub.araBAD dadB mutation with a rhamnose regulated rhaRS P.sub.rhaBAD or P.sub.rhaBAD construction, respectively, using the suicide vectors pG8R340, pG8R352, pG8R353, pG8R354 or pG8R355 (Table 7). This will constitute an additional safety feature due to a requirement for two sugars for growth and infectivity not present in animal tissues.
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