Conformational epitopes in respiratory syncytial virus G protein central conserved region

Abstract

X-ray crystallography has defined conformational properties of a key functional region of the G protein of respiratory syncytial virus (RSV). Mimics of these epitopes have utility as immunogens, as tools for discovery of antibodies and other monoclonal binding agents, and as pharmacological agents to modulate activity of the host receptors for this viral protein.

Claims

1. A mutant peptide or peptidomimetic thereof, the mutant peptide or peptidomimetic comprising: (a) amino acid residues 161-197 of respiratory syncytial virus (RSV) G protein, as set forth as SEQ ID NO: 1, with at least one amino acid substitution at amino acid residue 162, 164, 166, 177, 187, 192, or 193 thereof; (b) amino acid residues 162-172 of RSV G protein, as set forth as SEQ ID NO: 2, with at least one amino acid substitution at amino acid residue 162, 164, or 166 thereof; (c) amino acid residues 169-198 of RSV G protein, as set forth as SEQ ID NO: 3, with at least one amino acid substitution at amino acid residue 177, 187, 192, or 193 thereof; (d) amino acid residues 157-197 of RSV G protein, as set forth as SEQ ID NO: 4, with at least one amino acid substitution at amino acid residue 162, 164, 166, 177, 187, 192, or 193 thereof; (e) amino acid residues 148-197 of RSV G protein, as set forth as SEQ ID NO: 5, with at least one amino acid substitution at amino acid residue 162, 164, 166, 177, 187, 192, or 193 thereof; or (f) amino acid residues 161-191 of RSV G protein, as set forth as SEQ ID NO: 6, with at least one amino acid substitution at amino acid residue 162, 164, 166, 177, or 187 thereof; wherein the mutant peptide or peptidomimetic (i) comprises diminished activation of CX3CR1 (chemokine receptor responsive to fractalkine) as compared to the respective unmodified peptide comprising SEQ ID NOS: 1-6, (ii) is immunoreactive with mAb 3D3, and/or 2D10 and/or 3G12, and (iii) is chemically stabilized to maintain its native conformation when binding to mAb 3D3, and/or 2D10 and/or 3G12.

2. The mutant or peptidomimetic of claim 1 which elicits sub-nM affinity antibodies immunoreactive with an epitope of RSV G protein conserved between A and B strains of the virus.

3. The mutant or peptidomimetic of claim 1, wherein the substituted amino acid of (a)-(f) comprises a different charge than the unsubstituted amino acid.

4. The mutant or peptidomimetic of claim 1, wherein the substituted amino acid of (a)-(f) comprises a different size or shape than the unsubstituted amino acid.

5. The mutant or peptidomimetic of claim 1, wherein the substituted amino acid of (a)-(f) comprises a different side chain than the unsubstituted amino acid.

6. The mutant or peptidomimetic of claim 1, wherein the at least one substitution provided in (a)-(f) comprises a tyrosine for histidine at amino acid position 164, a lysine for glutamate at amino acid position 166, a tryptophan for serine at amino acid position 177, or arginine for serine at amino acid position 177, or combination thereof.

7. The mutant or peptidomimetic of claim 1, wherein the at least one substitution provided in (a)-(f) comprises a lysine for glutamate at amino acid position 166 and glutamate for lysine at amino acid position 187.

8. The mutant or peptidomimetic of claim 1, wherein the at least one substitution provided in (a) and (c) comprises a glutamate for lysine at amino acid positions 192 and 193.

9. A pharmaceutical or veterinary composition or vaccine that comprises as active agent the mutant or peptidomimetic of claim 1.

Description

BRIEF DESCRIPTION OF THE DRAWINGS

(1) FIG. 1A-B illustrate the RSV G protein and its central conserved region (CCR). FIG. 1A is a diagram of the prominent location of the CCR at the tip of a folded back structure of the RSV G protein, preceding the heparin binding domain. The CCR structure [residues 161-190] is shown in FIG. 1B at higher resolution, with dotted lines showing non-covalent interactions in the structure, with N and C terminal ends of the region noted.

(2) FIG. 2A-C illustrate the contact regions for mAbs 3D3, 2D10 and 3G12 on the CCR of RSV G protein. FIG. 2A shows front and back views of the CCR as space filling model; black areas are the mAb contact regions. FIG. 2B shows the mAb 3D3 and 2D10 variable domains as ribbon models, and the CCR of RSV G as space filling model. FIG. 2C shows the mAb 3G12 variable domains as ribbon models, and the CCR of RSV G as space filling model. In FIG. 2B-C, the CCRs are aligned at the cysteine noose residues. mAbs 3D3 and 3G12 bind to many of the same amino acids, however the three-dimensional epitopes are very different due to different conformations of the CCR in each structure.

(3) FIG. 3A-C illustrate the structure of fractalkine, the natural ligand for the CX3C chemokine receptor 1. FIG. 3A shows the orientation of fractalkine binding to the receptor. FIG. 3B shows fractalkine, with the CX3C motif in black. FIG. 3C shows a portion of the RSV G protein [residues 161-190] with the CX3C motif in black.

(4) FIGS. 4A and 4B illustrate RSV G CCR (161-197, SEQ ID NO:1). FIG. 4A is a sequence logo showing highly conserved amino acids that may play a role in CX3CR1 binding and activation (height of the single amino acid abbreviations at each residue is proportional to how conserved it is). The location of the CX3C motif is underlined, confirming that the site is not highly conserved by sequence although it does play a significant role in determining the three dimensional conformation. FIG. 4B is a high magnification view of the region bound by mAbs 3D3 and 2D10. Conserved amino acids outside of the mAb epitopes are selected for mutagenesis.

MODES OF CARRYING OUT THE INVENTION

(5) For the first time, high resolution structural data have been obtained for the interaction of high affinity, broadly neutralizing monoclonal antibodies (mAbs) and peptides derived from the conserved central region (CCR) of RSV G protein. These results provide a foundation for rational engineering of an immunogen as has been shown for other viruses {Sharon, J., et al. Immunology (2014) 142(1):1-23}. The novel structures define two neighboring conformational epitopes on RSV G CCR, that include helices, disulfide bonds, and polar and hydrophobic interactions between discontinuous amino acids. These results illuminate why linear RSV G epitope peptides and misfolded RSV G are not likely to be fully effective as antigens; for example, an early attempt to target the CCR of the G protein with a recombinant protein vaccine (BBG2Na) showed only a moderate ability to induce neutralizing antibodies in healthy, young adults and a more recent effort also using recombinant G protein failed to establish efficacy in elderly adults {Rezaee, F., et al. Curr Opin Virol (2017) 24:70-78}. Mapping of sequence conservation onto the RSV G structure defines a large three-dimensional region on the RSV surface that is highly conserved.

(6) These conformational features of the disclosed peptides or mutants can be stabilized by use of chemical crosslinkers or non-natural amino acids {Robinson, J. A. J Pept Sci (2013) 19(3):127-40}.

(7) As shown in Example 5 the Fab of 3D3 complexed to RSV G[162-172](SEQ ID NO:2) was determined to 2.40 A-resolution. The RSV G[162-172] peptide contains a short helix and projects several hydrophobic residues, including Phe163, Phe165, Phe168, Phe170 and Prol72, into a ˜700 Å.sup.2 groove formed by heavy-chain complementarity-determining regions (CDRs) 1, 2, and 3 and light-chain CDRs 1 and 3. Surprisingly, the distal six amino acids of the extended heavy-chain CDR3 formed no molecular contacts with the linear epitope peptide. A larger fragment of RSV G (RSV G[161-197]) (SEQ ID NO:1) was produced in E. coli and the structure of that complex determined to 2.40 Å-resolution. Additional interactions with 3D3 included heavy-chain CDR3 contacts with the RSV G cysteine noose (residues 173-186) as well as additional interactions between heavy-chain CDRs 1 and 2 and RSV G residues 189-190. Altogether, 3D3 binds to RSV G at a discontinuous, conformational epitope comprising ˜1,060 Å2, designated as antigenic site γ1.

(8) The mAb 2D10 also binds RSV G but its epitope could not be characterized by linear epitope mapping. A recombinant single-chain variable fragment (scFv) of 2D10 forms stable complexes with a synthetic RSV G peptide (RSV G[169-198] SEQ ID NO:3), and as also shown in Example 5 the crystal structure of the complex was determined to 1.56 A-resolution. The mAb 2D10 uses a twisted heavy-chain CDR3, heavy-chain CDR2, and light-chain CDR3 to bind to a ˜550 Å.sup.2 epitope on the RSV G cysteine noose. The CX3C chemokine motif, which forms a short helix in the cysteine noose, is buried by 2D10 binding. Although the 2D10 epitope is comprised mainly of residues 177-188, and is thus technically continuous, the cysteine noose comprises two nested disulfide bonds that induce strong conformational character to this epitope, designated as antigenic site γ2.

(9) The three dimensional conformations of the three peptides used for these studies superimpose nearly identically. A diverse set of RSV G sequences was used to map conservation level onto this consensus RSV G structure. Despite overall high variability of full-length RSV G (53% identity between subtypes RSV A and B), the 37 amino acid fragment RSV G[161-197] contains 24 invariant residues (70% identity between subtypes RSV A and B). Notably, in the CX3C motif only one of the three “X” amino acids, Ile185, is highly conserved, implying that this motif alone does not comprise the CX3CR1-binding site, but the invariant cysteines in the CX3C motif stabilize a three-dimensional surface of highly conserved amino acids that form extensive atomic interactions across the entire region. Many aspects of the invention are derived from these findings.

Definitions

(10) Unless defined otherwise, all technical and scientific terms used herein have the same meanings as commonly understood by one of ordinary skill in the art to which this disclosure belongs.

(11) “Protein”, “peptide” and “polypeptide” are used interchangeably and to refer to chains of naturally occurring amino acids coupled through amide bonds such that they can be synthesized by recombinant methods regardless of the length of the chain. “Peptidomimetics” include unnatural or synthetic amino acids, including D and L isomers and amino acid analogs linked by amide linkages or other bonds, e.g., ester, ether, etc. “Peptidomimetics” also include organic molecules not obviously analogous to peptides, including, for example, aptamers.

(12) As used herein, “binding moiety” includes antibodies and alternative non-immunoglobulin binding moieties as set forth hereinbelow. “Antibodies” include immunoreactive fragments of traditional antibodies and their various fragmented forms that still retain immunospecificity such as Fab, F(abab.sub.2, F.sub.v fragments, single-chain antibodies in which the variable regions of heavy and light chain are directly bound without some or all of the constant regions. Also included as “antibodies” are bispecific antibodies which contain a heavy and light chain pair derived from one antibody source and a heavy and light chain pair derived from a different antibody source. Similarly, since light chains are often interchangeable without destroying specificity, antibodies composed of a heavy chain variable region that determines the specificity of the antibody may be combined with a heterologous light chain variable region. Chimeric antibodies with constant and variable regions derived, for example, from different species are also included.

(13) For the variable regions of mAbs, as is well known, the critical amino acid sequences are the CDR sequences arranged on a framework which framework can vary without necessarily affecting specificity or decreasing affinity to an unacceptable level. Definition of these CDR regions is accomplished by art-known methods. Specifically, the most commonly used method for identifying the relevant CDR regions is that of Kabat as disclosed in Wu, T. T., et al., J. Exp. Med. (1970) 132:211-250 and in the book Kabat, E. A., et al. (1983) Sequence of Proteins of Immunological Interest, Bethesda National Institute of Health, 323 pages. Another similar and commonly employed method is that of Chothia, published in Chothia, C., et al., J. Mol. Biol. (1987) 196:901-917 and in Chothia, C., et al., Nature (1989) 342:877-883. An additional modification has been suggested by Abhinandan, K. R., et al., Mol. Immunol. (2008) 45:3832-3839. The mAbs described herein include the CDR regions as defined by any of these systems or other recognized systems known in the art.

(14) The specificities of the binding of mAbs are defined, as noted, by the CDR regions mostly those of the heavy chain, but complemented by those of the light chain as well (the light chains being somewhat interchangeable). Therefore, the mAbs of the invention may contain the three CDR regions of a heavy chain and optionally the three CDR's of a light chain that matches it. Because binding affinity is also determined by the manner in which the CDR's are arranged on a framework, the mAbs may contain complete variable regions of the heavy chain containing the three relevant CDR's as well as, optionally, the complete light chain variable region comprising the three CDR's associated with the light chain complementing the heavy chain in question. This is true with respect to the mAbs that are immunospecific for a single epitope as well as for bispecific antibodies or binding moieties that are able to bind two separate epitopes.

(15) The invention also includes binding moieties that mimic the binding characteristics of mAbs. mAb mimics include aptamers {Yu, Y., et al. Int J Mol Sci (2016) 17(3):358} and protein mimics of antibodies or fragments thereof (alternative scaffolds) such as camelids, anticalins, ankyrin repeat proteins {Azhar A., et al. Int J Biol Macromol (2017) 102:630-641}.

(16) Bispecific binding moieties may be formed by covalently linking two different binding moieties with different specificities. Multiple technologies now exist for making a single antibody-like molecule that incorporates antigen specificity domains from two separate antibodies (bi-specific antibody). Suitable technologies have been described by MacroGenics (Rockville, Md.), Micromet (Bethesda, Md.) and Merrimac (Cambridge, Mass.). (See, e.g., Orcutt, K. D., et al., Protein Eng. Des. Sel. (2010) 23:221-228; Fitzgerald, J., et al., MAbs. (2011) 1:3; Baeuerle, P. A., et al., Cancer Res. (2009) 69:4941-4944). For example, the CDR regions of the heavy and optionally light chain derived from one monospecific mAb may be coupled through any suitable linking means to peptides comprising the CDR regions of the heavy chain sequence and optionally light chain of a second mAb. If the linkage is through an amino acid sequence, the bispecific binding moieties can be produced recombinantly and the nucleic acid encoding the entire bispecific entity expressed recombinantly. As was the case for the binding moieties with a single specificity, the invention also includes the possibility of binding moieties that bind to one or both of the same epitopes as the bispecific antibody or binding entity/binding moiety that actually contains the CDR regions. The invention further includes bispecific constructs which comprise the complete heavy and light chain sequences or the complete heavy chain sequence and at least the CDR's of the light chains or the CDR's of the heavy chains and the complete sequence of the light chains.

(17) In particular, the invention is directed to a mutant or peptidomimetic of a peptide having the amino acid sequence of residues 161-197 of respiratory syncytial virus (RSV) G protein (SEQ ID NO:1) or of positions 169-198 (SEQ ID NO:3), or of positions 157-197 (SEQ ID NO:4), or of positions 148-197 (SEQ ID NO:5), or of positions 161-191 (SEQ ID NO:6) that has diminished activity with respect to activating the chemokine receptor responsive to fractalkine as compared to the respective peptide of SEQ ID NO:1, SEQ ID NO:3, SEQ ID NO:4, SEQ ID NO:5 or SEQ ID NO:6; that binds mAb 3D3, and/or 2D10 and/or 3G12; and/or wherein said mutant or peptidomimetic elicits antibodies immunoreactive with RSV G protein. In some embodiments the elicited antibodies have sub-nM affinity for an epitope of RSV G protein conserved between A and B strains of the virus.

(18) In some embodiments the peptidomimetic or peptide is chemically stabilized to retain the conformation exhibited upon binding to antibody and/or contains at least one substitution for amino acid 162, 164, 166, 177, 187, 192 and/or of 193 the RSV G protein.

(19) In another embodiment the invention includes a mutant or peptidomimetic of peptide of SEQ ID NO:1, SEQ ID NO:3, SEQ ID NO:4, SEQ ID NO:5 or SEQ ID NO:6 that stimulates or inhibits the chemokine receptor responsive to fractalkine as compared to the respective peptide of SEQ ID NO:1, SEQ ID NO:3, SEQ ID NO:4, SEQ ID NO:5 or SEQ ID NO:6. In some embodiments the mutant or peptidomimetic has reduced immunogenicity as compared to the respective peptide of SEQ ID NO:1, SEQ ID NO:3, SEQ ID NO:4, SEQ ID NO:5 or SEQ ID NO:6.

(20) Recombinant Aspects

(21) Any proteins or peptides of the invention may be produced recombinantly using known techniques. The invention also includes nucleic acid molecules comprising nucleotide sequences encoding them, as well as vectors or expression systems that comprise these nucleotide sequences, cells containing expression systems or vectors for expression of these nucleotide sequences and methods to produce the peptides by culturing these cells and recovering the binding moieties produced. Any type of cell typically used in recombinant methods can be employed including prokaryotes, yeast, mammalian cells, insect cells and plant cells. Also included are human cells (e.g., muscle cells or lymphocytes) transformed with one or more recombinant molecules that encode the relevant peptides.

(22) As used herein, “a” or “an” means “at least one” or “one or more.”

(23) Activities Based on the CX3C Chemokine Motif

(24) Although variable overall, RSV G (298 residues) contains a ˜40 amino acid central conserved region (CCR) that is highly conserved, devoid of glycosylation, and has been shown to play key roles in both virus infection and viral pathogenesis. Specifically, RSV G CCR contains a CX3C chemokine motif that facilitates binding to the human chemokine receptor CX3CR1 to promote RSV infection in human airway epithelial cells as well as modulating signaling that affects trafficking of CX3CR1.sup.+immune cells resulting in airway congestion. For example, treatment with mAbs against the CCD of RSV G protein was associated with a reduction in total lung leukocytes in comparison to isotype control treated mice at day 5 post-inoculation, while treatment with anti-F mAb (Synagis) did not reduce total BAL cells {Caidi, H., et al. Antiviral Research (2018) 154:149-157}.

(25) There are no structural or sequence similarities between RSV G and fractalkine/CX3CL1, the only known ligand for CX3CR1, aside from the presence of a CX3C motif and its two disulfide bonds, as diagrammed in FIG. 3A-C. In another aspect of the invention, this structural divergence despite similar functionality provides an opportunity to develop therapies that selectively block this interaction, a strategy that led to an antagonist of the HIV co-receptor CCR5 {Lieberman-Blum, S. S., et al. Clinical Therapeutics (2008) 30:1228-1250}. Examples of diseases for which selective modulation of CX3CR1 would be beneficial include: immune mediated inflammatory diseases such as rheumatoid arthritis {Szekanecz, Z., et al. Neth J Med (2011) 69(9):356-66} and osteoarthritis {Wojdasiewicz, P., et al. Arch Immunol Ther Exp (Warsz) (2014) 62(5):395-403}. Atherosclerosis is also now considered to be an inflammatory disease and in animal models blockade CX3CR1 ameliorates disease severity {Apostolakis, S. and Spandidos, D. Acta Pharmacol Sin. (2013) 34(10):1251-6}. Chemokines in general, and the natural CX3CR1 ligand (fractalkine) in particular, are also implicated in the peripheral neuropathy thought to underlie chronic pain {Montague, K. and Malcangio, M. J Neurochem (2017) 141(4):520-531}. To use the motif as a pharmacological agent, reduced immunogenicity is important to enable repeated administration. De-immunization of the two distinct antibody epitopes thus provides complementary utility to the determination of sites required for pharmacological activity.

(26) Alternatively, enhancement of the activity of the CX3CR1 binding motif can be used to create a novel stimulator of this receptor. This is useful for treating diseases such as ulcerative colitis. In mice, CX3CR1 is implicated in preventing the disease-associated translocation of commensal bacteria to mesenteric lymph nodes. CX3CR1-knockout mice and mice deficient in fractalkine both displayed increased translocation of bacteria and markedly increased disease severity in a model of dextran sulfate sodium (DSS)-induced colitis {Medina-Contreras, O., et al. J Clin Invest (2011) 121(12):4787-95}. In addition, CX3CR1 has been shown to be an important regulator of beta-cell function and insulin secretion {Lee, Y. S., et al. Cell (2013) 153(2):413-425}, and the RSV G protein pharmacological motif mimic could thus also be developed as a therapeutic to treat diabetes.

(27) The ability of the stabilized forms of SEQ ID NOs: 1-6 or the mutants or peptidomimetics thereof and their specially constrained forms can be tested for their ability to activate or inhibit the CX3C receptor using, for example, the chemotaxis assay set forth in Example 4 hereinbelow. However, any suitable method for assay could also be used. For use in therapy, it is advantageous for these entities to have relatively low immunogenicity and this too can be tested, for example, using the assays set forth in Example 3, but any suitable test may be used.

(28) Immunogens

(29) Three design goals dominate optimization of a G protein immunogen, each of which is substantially facilitated by the novel structural information.

(30) First, the pharmacological activity of the G protein is deleterious in the context of RSV infection and it is thus preferable to minimize that activity in the immunogen. As noted above, this activity is centered around the C3XC receptor and successful mutants or peptidomimetics can be assessed using the chemotaxis assay, among other assays. The crystallographic studies described in the present invention permit identification of amino acids whose substitution would be useful in diminishing interaction with the C3XC receptor while retaining immunogenic properties which are the second desirable characteristic of a vaccine. Specifically, it has been found that residues 162, 164, 166, 177 and 187 are present in the CCR region of the RSV G protein and/or either a part of or adjacent to the C3XC motif and are not among the residues that specifically bind the high affinity antibodies described herein. Thus, replacing one or more of these residues with an alternative that will either alter the charge or the size and shape of the side chain will interfere with interaction with the C3XC receptor.

(31) Second, high affinity antibodies are needed to neutralize the deleterious soluble G protein produced by virus infected cells, so antibodies generated by the immunogens should have these properties. Affinity can readily be tested using the ELISA assays described in Example 2 or using one of the many alternative methods known in the art. To test for immunogens that will generate antibodies with desirable affinity and neutralization properties, binding to human mAbs that exhibit such desired properties is assessed. As disclosed in Collarini, et al. (supra) mAbs with affinities varying across 3 orders of magnitude, from low pM to low nM: 3D3 (1.1 pM), 2B11 (10 pM), 3G12 (580 pM), 5D8 (4.4 nM) are available for such assays. Candidate immunogens that do not bind well to a high affinity mAb such as 3D3 or 2B11 or that bind better to mAbs with weaker affinity for the natural conformation of the G protein are unlikely to be able to induce production of the desired high affinity mAbs and vice versa.

(32) Third, since RSV is an important pathogen worldwide, including in countries that lack a refrigerated supply chain for delivery of vaccines, stabilization of the immunogen to allow transport and storage at room temperature (or above) is also desirable. Formalin inactivation of live virus, which is effective in other vaccines, is not acceptable for RSV since the first such vaccine caused disease exacerbation upon subsequent natural infection {Kim, H. W., et al. Am J Epidemiol (1969) 89:422-34}.

(33) With respect to this third aspect, conformational stability, as has been shown for the RSV F protein, stabilization of the structure via mutations chosen based on antibody-antigen high resolution structural data results in achieving high titer more uniformly across immunized subjects than for the parental virus {McClellan, J. S., et al. Science (2013) 340(6136): 1113-1117}. Since the G protein CCR can be made either synthetically or recombinantly, methods well known in the art can be used to systematically mutate this peptide. To facilitate evaluation of a large number of such variants, in vitro assays are needed. Suitable assays are known in the art for mAb binding, for evaluation of thermal stability, and for activation of the CX3CR1 receptor.

(34) In addition to the disadvantage of requirement for refrigeration, the use of flexible peptides as immunogens often elicits antibodies that bind weakly (≥micromolar KD) to conformational epitopes in folded proteins. For that reason, conformationally constrained synthetic epitope mimetics are of particular interest in immunogen design, with examples including efforts addressing HIV, hepatitis C, influenza, and others {Robinson, J. A. J Pept Sci (2013) 19(3):127-40}.

(35) Peptides incorporating non-natural motifs are often quite resistant to proteolytic degradation, which is an advantageous feature unrelated to the mimicry itself. A disadvantage of small molecules (“haptens”) is that they are often not immunogenic themselves; however, they can become effective immunogens when presented to the immune system embedded in virus like particles {Buonaguro, L., et al. Exp. Rev. Vaccines (2011) 10: 1569-1583}.

(36) In particular, the F protein of RSV has been subjected to such mimicry. In this instance, two “staples” (crosslinks) were required to create an effective mimic, which displayed nanomolar potency for inhibition of RSV infection in Hep-2 cells in vitro {Gaillard, V., et al. Antimicrob Agents Chemother. (2017) 61(4) pii: e02241-16}.

(37) In addition, constraining the immunogen's three dimensional structure to preserve the high affinity interaction with 3D3 is thus advantageous and a convenient assay is by ELISA binding. Assays for thermal stability known in the literature include observation of increased fluorescence of a dye when bound to hydrophobic sites exposed as the protein unfolds {Biggar, K. K., et al. BioTechniques (2012) 53:231-238} and observation of secondary structure character by circular dichroism {Kelly, S. M. and Price, N.C. Biochim Biophys Acta (1997) 1338(2):161-185}.

(38) As noted above, methods are available in the art to assess candidate mutants and peptidomimetics for appropriate physiological activity, including evaluation of binding activity and neutralization capability employing antibodies of varying affinity. With respect to constructing candidate mutants and peptidomimetics, the detailed structural information provided by the invention enables targeted mutagenesis to identify the key residues needed for immunogenicity (or for pharmacological activity on the host CX3CR1 receptor noted above to design candidate immunogens). Such “molecular dissection” to separate functions is highly advantageous for identifying product candidates. “De-immunization” (reduction in immunogenicity) has been accomplished for the purpose of enabling repeated administration of a foreign protein {Mazor, R., et al. Oncotarget (2016) 7(21):29916-26}. Purely empirical methods, involving mutating each residue in turn and evaluating the result followed by combinations of such mutations, can be augmented by computational analysis to identify the residues most likely to contribute to immunogenicity and replacements that are most likely to reduce immunogenicity {He, L. and Zhu, J. Curr Opin Virol (2015) 11:103-12}. It is already known that insertion of a single additional amino acid within the CX3CR1 motif reduces pharmacological activity {Boyoglu-Barnum, S., et al. J Virol (2017) 91(10) pii: e02059-16}. Further determination of inactivating sites enables reduction in this deleterious activity while retaining immunogenicity leading to viral neutralization.

(39) Although the crystal structures described herein have revealed the surface shape and complementarity of mAb interfaces with the RSV G protein CCR, the energetically important interactions are not directly readable from the structures. In other examples of protein-protein interfaces, certain residues constitute ‘hot-spots’ that make a disproportionately large contribution to binding energy. These privileged sites can be identified by alanine scanning mutagenesis (i.e. creation of variants in which one residue at a time is replaced by alanine) {Robinson, J. A. J Pept Sci (2013) 19(3):127-40}; based on the high resolution structure, certain sites will benefit from substituting a different amino acid rather than alanine.

(40) The mAbs 3D3, 2D10, and 3G12 bind quite differently to the same region, as diagrammed in FIG. 2A-C. Thus, de-immunization of each site can be carried out independently. The same process can be used to enhance immunogenicity as well. Optimizing immunogenicity of each site potentially enables a vaccine that comprises a fusion of two or three peptides, among those displaying an optimal immunogen for the 3D3 site, an optimal immunogen for the 2D10 site, and an optimal immunogen for the 3G12 site. Such an immunogen can elicit high affinity mAbs while providing increased resistance to viral escape compared to a single immunogenic site; the avidity boost from two mAbs binding to the CCR (on the same or different copies of the molecule at the virus surface) contributes to higher neutralization potency across the diverse human population. Precedents for such multiple antigen vaccines include an RSV F protein vaccine that incorporates both pre- and post-fusion conformationally stabilized antigens {Cimica, V., et al. Clin Vaccine Immunol (2016) 23(6):451-9} and a G protein vaccine that includes residues 131-230 from both A and B strains of RSV {Lee, J. Y. and Chang, J. PLoS One (2017)12:e0175384}. Preserving T cell responses, in addition to B cell responses, is also facilitated by the novel structural data; the major T cell epitope has been mapped to residues 185-193 {Varga, S. M., et al. J Immunol. (2000) 165(11):6487-95}.

(41) An important aspect of the invention is an effective immunogen for inducing mAbs that block the G protein interaction with CX3CR1, wherein that immunogen itself lacks binding to the receptor. Identifying the residues needed for CX3CR1 binding is accomplished using the same library of variants as for identification of key immunogenic epitopes, but assayed for functionality in a cell based assay for CX3CR1 activation as described in Example 4. Additional variants, such as those that are outside of mAb epitopes but are conserved and predicted to reduce or eliminate CX3CR1 binding, are also useful in this regard. Additional variants, such as insertion of an extra residue in the CX3C motif, may also be candidates.

(42) Development of Alternative Binding Moieties

(43) The conformational epitope mimics, whether recombinant peptides or peptidomimetics, enable efficient discovery of homogeneous compositions of non-immunoglobulin binding moieties with activity similar to the known broadly neutralizing mAbs such as aptamers or alternative scaffolds. Such mimics can provide superior stability, lower cost of manufacture (e.g. by expression in bacterial rather than in mammalian cells), and simpler formulation for inhaled delivery. (The epitope mimics can also be used for identification of additional mAbs.) Homology modeling of the epitope mimics for human RSV can be used to develop analogous epitope mimics for generating mAbs useful in veterinary indications, e.g. to treat bovine RSV infections. Although there is only 30% amino acid identity between the bovine and human RSV G proteins, they share similar features in that the G protein of both viruses has a central conserved cysteine noose region flanked by two more variable domains which are heavily glycosylated {Guzman, E. and Taylor, G. Mol Immunol (2015) 66(1):48-56}.

(44) Libraries of such antibody mimics are evaluated by means of competition assays wherein the mimic is used to compete with mAbs such as 3D3, 2D10 or 3G12 for binding to the RSV G protein itself, or more preferably to an epitope mimic that presents the conformational properties in a stable form. Those candidates that successfully compete with the mAb for the epitope are selected as suitable binding agents. Further optimization can be achieved by rank ordering the candidates with regard to binding to epitope mimics that vary in their fidelity to the optimal conformation. As described above with regard to stabilization of epitope mimics, the fidelity of epitope mimics can be determined by measuring relative affinity for mAbs such as 3D3 or mAbs with lower affinity binding to the same general region of RSV G protein. Binding agents are deemed superior if they show stronger affinity for epitope mimics that in turn display high affinity binding to the known mAbs with broadly neutralizing activity.

(45) Applications

(46) The invention is also directed to pharmaceutical and veterinary compositions which comprise as active ingredients the binding moieties, mutants or other peptides or peptidomimetics of the invention. The compositions contain suitable physiologically compatible excipients such as buffers and other simple excipients. The compositions may include additional active ingredients as well, in particular in the case of immunogens immune system stimulants as vaccine adjuvants. The pharmaceutical or veterinary compositions may also contain other formulation excipients, including formulations for intra-nasal or inhaled delivery of mAbs as described in U.S. Pat. No. 9,718,875.

(47) The binding moieties of the invention may also be used in diagnosis.

(48) The immunogens are employed in a method to generate an immune response to RSV, comprising administering formulations containing them to a subject, including a human subject, such as a pregnant woman, an infant, an elderly human, or an immunocompromised subject. The binding moieties of the invention may also be used for therapy or prophylaxis. Infections in other animal species that are related to RSV may also be treated prophylactically or therapeutically by the immunogens or binding moieties of the invention.

(49) Mutants or peptidomimetics that modulate the C3XC receptor are employed in methods to treat other conditions such as rheumatoid arthritis, osteoarthritis, atherosclerosis, diabetes, chronic pain arising from peripheral neuropathy, ulcerative colitis and inflammatory bowel disease.

Example 1: Production of Proteins

(50) A. Production of Fab 3D3 and ScFv 2D10

(51) Recombinant mAbs 3D3 and 2D10 were produced by transient-transfection in CHO cells and purification by immobilized protein A. The CDRs for these mAbs are disclosed in FIG. 5A of U.S. Pat. No. 8,273,354 and single chain Fv sequences are included in those employed in recombinant production as SEQ ID NOs: 9 and 10 respectively.

(52) However, Fab 3D3 was generated from recombinantly produced 3D3 by incubation with immobilized papain, followed by removal of the Fc fragment with immobilized protein A. Fab 3D3 was then purified by Superdex 200 size-exclusion chromatography in 10 mM Tris-HCl pH 8.0 and 150 mM NaCl.

(53) For recombinant scFv 2D10, included in SEQ ID NO:10, a synthetic gene codon-optimized for Drosophila melanogaster encoding 2D10 heavy chain variable region, a (GGGGS)3GGG linker, and 2D10 light chain variable region, was cloned into pMT-puro in-frame with an N-terminal BiP signal sequence and a C-terminal thrombin cleavage site followed by a Twin-Strep purification tag. The resulting scFv 2D10 expression plasmid was used to obtain stably-transfected Schneider 2 (S2) insect cells. Secreted scFv 2D10 was affinity purified on a StrepTrap column, digested with thrombin protease to remove the purification tag, and then purified by Superdex 200 size-exclusion chromatography in 10 mM Tris-HCl pH 8.0 and 150 mM NaCl.

(54) B. Production of Epitopes

(55) A synthetic gene encoding RSV G ectodomain (G[ecto]) P03423) was cloned into pCF in-frame with an N-terminal TPA signal sequence and C-terminal tandem 6-histidine and Twin-Strep purification tags (SEQ ID NO:7 that includes residues 64 to 298, UniProtKB entry). G[ecto] was produced by transient-transfection in CHO cells and secreted G[ecto] was affinity purified on a StrepTrap column.

(56) A synthetic gene codon-optimized for Escherichia coli encoding RSV G residues 161 to 197 (G [161-197]) (SEQ ID NO:1 UniProtKB entry P03423) with a C-terminal 6-histidine purification tag (SEQ ID NO:8) was cloned into pET52b. The peptide was expressed overnight in E. coli BL21(DE3) at 18° C. The cells were then were lysed by ultrasonication in 20 mM Tris-HCl pH 8.0, 150 mM NaCl, and 25 mM imidazole (Buffer A) containing 2 μM MgCl.sub.2, benzonase, and protease inhibitors. RSV G[161-197] was purified from soluble lysates by HisTrap FF affinity chromatography and eluted with a gradient into Buffer B (Buffer A containing 500 mM imidazole). Analogous methods were used to produce related peptides (G [162-172] (SEQ ID NO: 2) and G [169-198] (SEQ ID NO: 3)).

Example 2: ELISA Assays

(57) Purified mAbs at a concentration of 5 pg/mL (150 μL total) were incubated overnight at room temperature in 96-well ELISA microtiter plates. Plates were then washed three times with PBS containing 0.05% TWEEN (polysorbate 20). Wells were blocked by adding 150 μL of 5% BSA in PBS and incubating at room temperature for 1 hr followed by three PBST washes. Recombinant RSV G[ecto] at 5 pg/mL or RSV G[161-197] at 20 pg/mL in 1% BSA in PBS was serially diluted 1:3 with 1% BSA in PBS. Wells were incubated with 150 μL RSV G protein for 1 hr at room temperature and the plates were washed three times with PBST. The plates were then incubated for 1 hr at room temperature with 150 μL HRP-conjugated-HisProbe (ThermoFisher Scientific) diluted 1:5000 in 1% BSA in PBS. Plates were washed three times with PBST and developed by adding peroxidase substrate o-phenylenediamine dihydrochloride (OPD) in 0.05 M phosphate-citrate buffer pH 5.0 and 1.5% hydrogen peroxide for 10 min at room temperature. The reactions were stopped by incubation with 2N sulfuric acid for 10 min at room temperature, and the absorbance was measured at 490 nm. ELISA experiments were performed in biological triplicates.

Example 3: Tests for Immunogenicity

(58) The peptides, mutants and peptidomimetics of the invention are evaluated in a murine model using the following criteria.

(59) TABLE-US-00001 TABLE 1 Immunogenicity Evaluation Criteria Category Score Detailed Criteria RSV titers in lungs: 4 no detectable RSV Based on pfu/g lung tissue at day 5 3 75% reduction of RSV in post-challenge and RT-PCR lungs vs. naïve mice quantitation of viral genomes/g 2 50% reduction of RSV in tissue lungs vs. naïve mice 1 25% reduction of RSV in lungs vs. naïve mice Lung Pathology: 4 No pathology Based on the mean score for each 3 slight parameter, i.e. peribronchiolar, 2 moderate perivascular, interstitial and 1 severe alveolar that involve each lung section evaluated Duration of immunity: 3  >6 months Based on full protection from 2 1-6 months subsequent virus challenge 1  <1 month Weight loss: 3 No weight loss Parameter of morbidity 2 5-19% weight loss 1  ≥20% weight loss Cellular immunity: 3 robust; Th1/Th2 balanced Th1/Th2 assayed by IFNγ and IL-4 2 moderate; Th1/Th2 ELISPOTs or by intracellular balanced cytokine FACS and by ELISA of 1 Unbalanced Th2/Th1 bronchial alveolar lavage fluid from the lungs

Example 4: Chemotaxis Assay

(60) An in vitro assay for RSV G modulation of CX3CR1 measures receptor mediated chemotaxis of human monocyte THP-1 cells {Tripp, R. A. et al. Nature Immunology (2001) 2:732-738}. In this assay, recombinant RSV G[161-197] induced chemotaxis at levels equivalent to the entire RSV G ectodomain, an activity blocked by pre-incubation with 3D3 or 2D10 or 3G12 at a level comparable to that provided by anti-CX3CR1 polyclonal serum. Table 2 provides the results of this analysis with respect to 3D3 and 2D10.

(61) TABLE-US-00002 TABLE 2 Chemotaxis Assay Results Negative Positive RSV Control Control RSV RSV G G[161-197] + (serum free (+10% RSV RSV G[161-197] + G[161-197] + anti- media) FBS) G[ecto] G[161-197] 3D3 2D10 CX3CR1 1.0 5.2 3.9 4.2 1.5 1.0 1.1

(62) In more detail, the assay was performed using a transwell insert plate with an 8 m pore size. Approximately 2 million log-phase THP-1 cells (a human leukemia monocytic cell line) washed twice and suspended in serum-free RPMI 1640 media were added to the upper chamber of the insert plate. Negative control was serum-free media alone to which serum-free media containing 25 nM mAb was added to the lower chamber. As a positive control, media containing 10% FBS was added to the lower chamber. RSV G[ecto] or RSV G[161-197] samples were added to the lower chamber at a final concentration of 5 nM in serum-free media. For samples with RSV G[161-197] and mAbs, RSV G[161-197] was pre-incubated with 5-molar excess mAb for 20 min at room temperature, and then added to serum-free media in the lower chamber, for a final concentration of 5 nM RSV G[161-197] and 25 nM mAb. For samples with anti-CX3CR1 antibody, 2 μL 1 mg/mL anti-CX3CR1 rabbit polyclonal antibody (ThermoFisher Scientific Cat #PA5-19910) was incubated with THP-1 cells for 30 minutes in the upper chamber before being placed into the well. The assembled plates were incubated in a CO2 incubator at 37° C. for 5 h. Cells migrated to the lower chamber were counted, and the chemotactic indices were determined by comparing the fold-increase in cell migration toward the chemoattractant to cell migration toward serum-free media alone. Experiments were performed in at least four biological replicates.

Example 5: Determination of Antibody-Epitope Interfaces by Crystallography

(63) Formation and structure determination of the Fab 3D3-RSV G[162-172] complex. The synthetic peptide of Example 1B encoding RSV G amino acids 162 to 172 (UniProtKB entry P03423) (SEQ ID NO:2) was mixed in 5-molar excess with purified Fab 3D3 of Example 1A at 17.5 mg/ml in 10 mM Tris-HCl pH 8.0 and 150 mM NaCl. Crystals were grown by hanging drop vapor diffusion at 4° C. with a well solution of 23% PEG 3350 and 0.05 M zinc acetate. Crystals were transferred into a cryoprotectant solution of 26% PEG 3350, 0.05 M zinc acetate, and 25% ethylene glycol and flash frozen in liquid nitrogen. Diffraction data were collected at cryogenic temperature at the Advanced Light Source on beamline 8.3.1 using a wavelength of 1.11503 Å. Diffraction data from a single crystal were processed with iMosfim and Aimless. The Fab 3D3-RSV G[162-172] complex structure was solved by molecular replacement with a Fab homology model and the program PHASER, and the structure was refined and manually rebuilt using PHENIX and Coot, respectively. The final Fab 3D3-RSV G[162-172] complex structure (PDB code 5WNB) had the following Ramachandran statistics: 96.5% favored, 3.5% allowed, 0% outliers.

(64) Formation and structure determination of the Fab 3D3-RSV G[161-197] complex. Purified RSV G[161-197] was mixed in 2 molar excess with purified Fab 3D3, dialyzed into 10 mM Tris-HCl pH 8.0 and 150 mM NaCl, and concentrated to 15 mg/mL. Crystals were grown by hanging drop vapor diffusion at 22° C. with a well solution of 21% PEG 3350 and 0.2 M ammonium citrate pH 7.0. Crystals were transferred into a cryoprotectant solution of 25% PEG 3350, 0.2 M ammonium citrate pH 7.0, and 25% glycerol and flash frozen in liquid nitrogen. Diffraction data were collected at cryogenic temperature at the Advanced Light Source beamline 8.3.1 using a wavelength of 1.11582 Å. Diffraction data were collected at cryogenic temperature at the Advanced Light Source on beamline 8.3.1 using a wavelength of 1.11503 Å. Diffraction data from a single crystal were processed with iMosfim and Aimless. The Fab 3D3-RSV G[161-197] complex structure was solved by molecular replacement with Fab 3D3 and the program PHASER, and the structure was refined and manually rebuilt using PHENIX and Coot, respectively. The final Fab 3D3-RSV G[161-197] complex structure (PDB code 5WNA) had the following Ramachandran statistics: 97.6% favored, 2.4% allowed, 0% outliers.

(65) Formation and structure determination of the scFv 2D10-RSV G[169-198] complex. A synthetic peptide encoding RSV G amino acids 169 to 198 (SEQ ID NO: 3) (UniProtKB entry P03423) was mixed in 2-molar excess with purified scFv in 60 mM Tris-HCl pH 8.0 and 230 mM NaCl and concentrated to 15.0 mg/mL. Crystals were grown by hanging drop vapor diffusion at 22° C. with a well solution of 24% PEG 4000, 0.17 M ammonium sulfate, 0.085 M sodium citrate pH 5.6 and 15% glycerol. Crystals were transferred into a cryoprotectant solution of 28% PEG 4000, 0.17 M ammonium sulfate, 0.085 M sodium citrate pH 5.6 and 15% glycerol, and 25% glycerol and flash frozen in liquid nitrogen. Diffraction data were collected at cryogenic temperature at the Advanced Photon Source on beamline 23-ID-D using a wavelength of 1.033 Å. Diffraction data from a single crystal were processed with HKL2000. The scFv 2D10-RSV G[169-198] complex structure was solved by molecular replacement with a scFv homology model and the program PHASER, and the structure was refined and manually rebuilt using PHENIX and Coot, respectively. The final scFv 2D10-RSV G[169-198] complex structure (PDB code 5WN9) had the following Ramachandran statistics: 99.2% favored, 0.8% allowed, 0% outliers.

(66) Formation and structure determination of the Fab 3G12-RSV G[157-197] complex. Purified RSV G[157-197] was mixed in 2 molar excess with purified Fab 3G12 and the complex was purified on a Superdex200 size-exclusion column in 10 mM Tris-HCl pH 8.0 and 150 mM NaCl. The complex was concentrated to 15.0 mg/mL. Crystals were grown by hanging drop vapor diffusion at 22° C. with a well solution of 1.8 M ammonium sulfate and 100 mM sodium acetate trihydrate pH 4.4. Crystals were transferred into a cryoprotectant solution of 2.0 M ammonium sulfate, 100 mM sodium acetate trihydrate pH 4.4, and 25% glycerol and flash frozen in liquid nitrogen. Diffraction data were collected at cryogenic temperature at the Advanced Light Source on beamline 8.3.1 using a wavelength of 1.11582 Å. Diffraction data from a single crystal were processed with iMosflm and Aimless. The Fab 3G12+RSV G.sup.157-197 complex structure was solved by molecular replacement the program PHASER, and the structure was refined and manually rebuilt using PHENIX and Coot, respectively. The final Fab 3G12-RSV G[157-197] complex structure (PDB code 6MKC) had the following Ramachandran statistics: 95.7% favored, 4.3% allowed, 0% outliers.

(67) Table 3 summarizes the crystallographic data (structures deposited in the Worldwide (PDB) Protein Data Bank).

(68) TABLE-US-00003 TABLE 3 Crystallographic data collection and refinement statistics.sup.a 3D3-RSV G 3D3-RSV G 2D10-RSV G 3G12-RSV G [162-172] [161-197] [169-198] [157-197] PDB code 5WNB 5WNA 5WN9 6MKC Data collection.sup.b Space group P 21 21 21 P 1 21 1 P 21 21 21 P 31 2 1 Cell dimensions a, b, c (Å) 68.76, 105.43, 64.62, 135.01, 44.84, 56.39, 139.33, 139.33, 121.82 73.78 126.15 94.7703 α, β, γ (°) 90.00, 90.00, 90.00, 107.45, 90.00, 90.00, 90.00 90.00, 90.00, 120.00 90.00 90.00 Resolution (Å) 48.38-2.40 (2.48-2.40)  48.72-2.40 (2.48-2.40)  50.00-1.55 (1.58-1.55)  74.53-2.90 (3.08-2.90)  R.sub.sym or R.sub.merge 0.122 (0.838) 0.107 (0.763) 0.058 (0.930) 0.097 (0.641) I/σI 13.4 (3.1)  12.3 (2.2)  44.0 (1.4)  9.4 (1.9) Completeness 99.9 (99.8) 99.5 (99.0) 99.9 (99.4) 99.5 (99.5) (%) Redundancy 9.2 (8.3) 6.3 (5.6) 9.6 (6.2) 3.9 (3.8) CC.sub.1/2 0.997 (0.808) 0.996 (0.670) 0.998 (0.751) 0.993 (0.601) Refinement Resolution (Å) 48.38-2.40 48.72-2.40 50.00-1.55 74.53-2.90 No. reflections 35,325 46,869 47,114 23,665 R.sub.work/R.sub.free.sup.c 0.218/0.280 0.192/0.246 0.169/0.185 0.193/0.209 No. atoms Protein 6,586 7,124 3,810 3,595 Ligand/ion 22 None None None Water 90 135 111 None B-factors Protein 50.29 42.02 34.04 66.24 Ligand/ion 63.66 None None None Water 35.5 38.59 37.92 None R.m.s. deviations Bond lengths 0.005 0.006 0.008 0.019 (Å) Bond angles 0.864 0.935 0.968 2.07 (°) .sup.aFor each structure, data from one crystal was used. .sup.bValues in parentheses are for highest-resolution shell. .sup.cR.sub.free was calculated using 5% of data excluded from refinement.

Example 6: Vaccines with Reduced Side Effects

(69) Determination of structures of RSV G CCR protein in complex with the high affinity antibodies 2D10 and 3D3 shown in FIG. 4A-B provide a roadmap to design RSV G immunogens to disable CX3CR1 binding without disrupting the ability to generate high-affinity mAb epitopes. Specifically, six highly conserved amino acids have been identified whose side-chains make no molecular contacts with mAbs 3D3 and 2D10, so they can be substituted without impacting generation of high affinity mAbs similar to these mAbs. These residues are therefore candidates for substitution in order to interfere with binding to CX3CR1. Generally, providing an alteration in charge (charge switch) and/or a change in size or shape resulting in a steric hinderance (steric clash) would be expected to result in a negative impact on such binding. Table 4 shows the results of representative substitutions in these residues in the RSV G CCR protein. Six representative mutants have been tested for their impact on CX3CR1 function as measured by the chemotaxis assay described in Example 4. Table 4 summarizes the results of duplicate assays (with standard deviations) using the standard one letter abbreviations for the amino acid at the indicated residue.

(70) TABLE-US-00004 TABLE 4 CX3CR1 DISRUPTING MUTATIONS. Mechanism of Chemotactic disabling activity RSV G (CCR) variants activity Negative control (PBS) 1.0 Wild type RSV G (CCR) 6.2 (0.7) Steric clash H164.fwdarw.Y 3.8 (0.4) Charge switch E166.fwdarw.K 1.6 (0.7) Steric clash S177.fwdarw.W 1.2 (0.4) Steric clash S177.fwdarw.R 0.9 (0.2) Charge switch E166.fwdarw.K + K187 .fwdarw.E 1.8 (0.1) Charge switch K192.fwdarw.E + K193 .fwdarw.E 2.5 (0.7)

(71) As shown, each of these mutations shows diminished chemotactic activity, the most effective being the substitution of arginine for serine at position 177. Combinations of these mutations are included within the scope of the invention.

Example 7: Stabilization of Epitope Mimics

(72) Chemically synthesized peptide technology, aided by combinatorial chemistry methods for synthesis and assay, now constitutes a mature technology for creating epitope mimics, with new advances enabling construction and screening of very large libraries (billions of compounds) by using DNA tags and next generation sequencing to deconvolute the hits {Chan, A. I., et al. Curr Opin Chem Biol. (2015) 26: 55-61}. For example, helical conformations can be stabilized through the insertion of amino acids with restricted conformational space, such as alpha-methylated amino acids (e.g. Aib), by side-chain cross-linking or ‘stapling’ to stabilize helical epitopes, and by the use of helix caps and hydrogen-bond surrogates. Examples include hydrazone crosslinks as hydrogen bond surrogates, Freidinger-like lactams and pseudoprolines to stabilize turns {Estieu-Gionnet, K. and Guichard, G. Exp. Opin. Drug Discov. (2011) 6: 937-963}.

(73) Further, techniques known in the art for in vitro translation of mRNA into protein allow introduction of non-standard amino acids into proteins and peptides, facilitating formation of crosslinked peptides {Hartman, M. C., et al. PLoS One (2007) 2(10):e972}.

Example 8: Identification of Non-Immunoglobulin Binding Agents

(74) The peptides, mutants and peptidomimetics of the invention can be used to identify effective non-immunoglobulin binding agents.

(75) A variety of non-immunoglobulin protein scaffolds is known in the art that provide equivalent pharmacological activity arising from high affinity, high specificity binding to an epitope similar to one bound by a traditional mAb {Sha, F, et al. Protein Sci. (2017) 26(5):910-924}. Examples include scaffolds based on fibronectin, lipocalin, lens crystallin, tetranectin, ankyrin, Protein A (Ig binding domain). Small peptide families may also have antibody-like affinity and specificity, including avian pancreatic peptides and conotoxins {Josephson, K., et al., J. Am. Chem. Soc.(2005) 127:11727-11725}. Cross-linked peptides similarly provide the ability to generate high affinity binding agents with well-defined specificity. In addition, non-protein based agents such as nucleic acid aptamers can also provide equivalent binding {Sun, H. and Zu, Y. Molecules (2015) 20(7):11959-80}.

(76) Summary of Disclosed Sequences

(77) In the table below, for the listed sequences that state that they include “plus additions” are those wherein the coding sequence of interest is supplemented by aids to expression and/or purification, such as a start codon, a glycine spacer, a histidine tag, or other purification aid such as Twin-Strep {Schmidt, T. G., et al. Protein Expr Purif (2013) 92(1):54-61}. These are provided in more detail in the sequence listing that follows.

(78) TABLE-US-00005 SEQ ID NO Composition (amino acid and encoding nucleic acid) 1 Residues 161-197 of RSVG 2 Residues 162-172 of RSVG 3 Residues 169-198 of RSVG 4 Residues 157-197 of RSVG 5 Residues 148-197 of RSVG 6 Residues 161-195 of RSVG 7 Residues 64-298 of RSVG plus additions 8 Residues 161-197 of RSVG plus additions 9 Residues 157-197 of RSVG plus additions 10 Residues 148-197 of RSVG plus additions 11 Residues 161-195 of RSVG plus additions 12 mAb 303 single chain Fv plus additions 13 mAb 2D10 single chain Fv plus additions
Sequence Listings
SEQ ID NO 1
LENGTH: 37 amino acids
TYPE: PRT
ORGANISM: Artificial Sequence
FEATURE: Immunogen recognized by mAbs 3D3, 2D10 and 3G12
OTHER INFORMATION: RSV G protein [residues 161-197]
SEQUENCE

(79) TABLE-US-00006 NDFHFEVFNFVPCSICSNNPTCWAICKRIPNKKPGKK
SEQ ID NO 2
LENGTH: 11 amino acids
TYPE: PRT
ORGANISM: Artificial Sequence
FEATURE: Immunogen recognized by mAb 3D3 but not mAb 2D10
OTHER INFORMATION: RSV G protein [residues 162-172]
SEQUENCE

(80) TABLE-US-00007 DFHFEVFNFVP
SEQ ID NO 3
LENGTH: 30 amino acids
TYPE: PRT
ORGANISM: Artificial Sequence
FEATURE: Immunogen recognized by mAb 2D10 but not mAb 3D3
OTHER INFORMATION: RSV G protein [residues 169-198]
SEQUENCE

(81) TABLE-US-00008 NFVPCSICSNNPTCWAICKRIPNKKPGKKT
SEQ ID NO 4
LENGTH: 50 amino acids
TYPE: PRT
ORGANISM: Artificial Sequence
FEATURE: Immunogen recognized by mAbs 3D3, 2D10, and 3G12
OTHER INFORMATION: RSV G protein [residues 157-197]
SEQUENCE

(82) TABLE-US-00009 SKPNNDFHFEVFNFVPCSICSNNPTCWAICKRIPNKKPGKK
SEQ ID NO 5
LENGTH: 45 amino acids
TYPE: PRT
ORGANISM: Artificial Sequence
FEATURE: Immunogen recognized by mAbs
OTHER INFORMATION: RSV G protein [residues 148-197]
SEQUENCE

(83) TABLE-US-00010 TKQRQNKPPSKPNNDFHFEVFNFVPCSICSNNPTCWAICKRIPNKKPGKK
SEQ ID NO 6
LENGTH: 31 amino acids
TYPE: PRT
ORGANISM: Artificial Sequence
FEATURE: Immunogen recognized by mAbs
OTHER INFORMATION: RSV G protein [residues 161-191]
SEQUENCE

(84) TABLE-US-00011 NDFHFEVFNFVPCSICSNNPTCWAICKRIPN
SEQ ID NO 7
LENGTH: 295 amino acids
TYPE: PRT
ORGANISM: Artificial Sequence
FEATURE: Immunogen
OTHER INFORMATION: RSV G protein ectodomain [residues 64-298 from RSV strain A2, GenBank KT992094.1, with 2 synonymous mutatations (underlined)] with N terminal TPA secretion signal and C terminal 6His-2Strep tag
SEQUENCE

(85) TABLE-US-00012 MDAMKRGLCCVLLLCGAVFVSPSEFSANHKVTPTTAIIQDATSQIKNTTP TYLTQNPQLGISPSNPSEITSQITTILASTTPGVKSTLQSTTVKTKNTTT TQTQPSKPTTKQRQNKPPSKPNNDFHFEVFNFVPCSICSNNPTCWAICKR IPNKKPGKKTTTKPTKKPTLKTTKKDPKPQTTKSKEVPTTKPTEEPTINT TKTNIITTLLTSNTTGNPELTSQMETFHSTSSEGNPSPSQVSTTSEYPSQ PSSPPNTPRQHHHHHHGWSHPQFEKGGGSGGGSGGGSWSHPQFEK
SEQ ID NO 14
DNA sequence:

(86) TABLE-US-00013 ATGGACGCCATGAAGCGGGGCCTGTGCTGTGTGCTGCTGCTGTGCGGAGC CGTGTTCGTGTCCCCCAGCGAATTCTCGGCAAACCACAAAGTCACACCAA CAACTGCAATCATACAAGATGCAACAAGCCAGATCAAGAACACAACCCCA ACATACCTCACCCAGAATCCTCAGCTTGGAATCAGTCCCTCTAATCCGTC TGAAATTACATCACAAATCACCACCATACTAGCTTCAACAACACCAGGAG TCAAGTCAACCCTGCAATCCACAACAGTCAAGACCAAGAACACAACGACA ACTCAAACACAACCCAGCAAGCCCACCACAAAACAACGCCAAAACAAACC ACCAAGCAAACCCAATAATGATTTTCACTTTGAAGTGTTCAACTTTGTAC CCTGCAGCATATGCAGCAACAATCCAACCTGCTGGGCTATCTGCAAAAGA ATACCAAACAAAAAACCAGGAAAGAAAACCACTACCAAGCCCACAAAAAA ACCAACCCTCAAGACAACCAAAAAAGATCCCAAACCTCAAACCACTAAAT CAAAGGAAGTACCCACCACCAAGCCCACAGAAGAGCCAACCATCAACACC ACCAAAACAAACATCATAACTACACTACTCACCTCCAACACCACAGGAAA TCCAGAACTCACAAGTCAAATGGAAACCTTCCACTCAACTTCCTCCGAAG GCAATCCAAGCCCTTCTCAAGTCTCTACAACATCCGAGTACCCATCACAA CCTTCATCTCCACCCAACACTCCTCGCCAGCACCATCACCACCATCATGG TTGGAGTCATCCACAATTCGAGAAGGGCGGCGGCTCCGGAGGTGGATCAG GAGGTGGTTCCTGGTCACACCCTCAATTCGAGAAGTGA
SEQ ID NO 8
LENGTH: 45 amino acids
TYPE: PRT
ORGANISM: Artificial Sequence
FEATURE: Contains Immunogen
OTHER INFORMATION: RSV G protein [residues 161-197] with N terminal start codon and spacer glycine and C terminal 6His tag
SEQUENCE

(87) TABLE-US-00014 MGNDFHFEVFNFVPCSICSNNPTCWAICKRIPNKKPGKKHHHHHH
SEQ ID NO 15
DNA sequence:

(88) TABLE-US-00015 ATGGGAAACGACTTCCACTTCGAGGTGTTCAACTTCGTTCCGTGCAGCAT TTGCAGCAACAACCCGACCTGCTGGGCGATCTGCAAACGTATCCCGAACA AGAAACCGGGTAAGAAACATCACCATCACCATCACTGA
SEQ ID NO 9
LENGTH: 54 amino acids
TYPE: PRT
ORGANISM: Artificial Sequence
FEATURE: Contains Immunogen
OTHER INFORMATION: RSV G protein [residues 157-197] with N terminal start codon and spacer glycine and C terminal 6His tag
SEQUENCE

(89) TABLE-US-00016 MGSKPNNDFHFEVFNFVPCSICSNNPTCWAICKRIPNKKPGKKHHHHHH
SEQ ID NO 16
DNA sequence:

(90) TABLE-US-00017 ATGGGAAGCAAACCGAACAACGACTTCCACTTCGAGGTGTTCAACTTCGT TCCGTGCAGCATTTGCAGCAACAACCCGACCTGCTGGGCGATCTGCAAAC GTATCCCGAACAAGAAACCGGGTAAGAAACATCACCATCACCATCACTGA
SEQ ID NO 10
LENGTH: 45 amino acids
TYPE: PRT
ORGANISM: Artificial Sequence
FEATURE: Contains Immunogen
OTHER INFORMATION: RSV G protein [residues 148-197] with N terminal start codon and spacer glycine and C terminal 6His tag
SEQUENCE

(91) TABLE-US-00018 MGTKQRQNKSKPNNDFHFEVFNFVPCSICSNNPTCWAICKRIPNKKPGKK HHHHHH
SEQ ID NO 17
DNA sequence:

(92) TABLE-US-00019 ATGGGAACCAAGCAGCGTCAGAACAAGCCGCCGAGCAAACCGAACAACGA CTTCCACTTCGAGGTGTTCAACTTCGTTCCGTGCAGCATTTGCAGCAACA ACCCGACCTGCTGGGCGATCTGCAAACGTATCCCGAACAAGAAACCGGGT AAGAAACATCACCATCACCATCACTGA
SEQ ID NO 11
LENGTH: 39 amino acids
TYPE: PRT
ORGANISM: Artificial Sequence
FEATURE: Immunogen
OTHER INFORMATION: RSV G protein [residues 161-195] with N terminal start codon and spacer glycine and C terminal 6His tag
SEQUENCE

(93) TABLE-US-00020 MGNDFHFEVFNFVPCSICSNNPTCWAICKRIPNHHHHHH
SEQ ID NO 18
DNA sequence:

(94) TABLE-US-00021 ATGGGAAACGACTTCCACTTCGAGGTGTTCAACTTCGTTCCGTGCAGCAT TTGCAGCAACAACCCGACCTGCTGGGCGATCTGCAAACGTATCCCGAACA AGAAACCGGGTCATCACCATCACCATCACTGA
SEQ ID NO 12
LENGTH: 308 amino acids
TYPE: PRT
ORGANISM: Artificial Sequence
FEATURE: Single-chain antibody
OTHER INFORMATION: mAb 3D3 single chain Fv (scFv 3D3) with N terminal Bip signal sequence, internal flexible linker and C terminal thrombin protease cleavage site followed by 6His-2Strep tag
SEQUENCE

(95) TABLE-US-00022 MKLCILLAVVAFVGLSLGRSEEQLVESGGGLVQPGRSLRLSCVGSGLRFE EHAMHWVRQAPGRGLEWVSGISWNSGSVGYADSVKGRFTTSRDNAKDILF LEMNTLRSEDTALYFCAIMVATTKNDFHYYKDVWGKGTTVTVSSGGGGSG GGGSGGGGSQIVLTQSPATLSLSPGERATLSCRASQSVSNHLAWYQQKPG QAPRLLIYETSNRATGIPPRFSGSGSGTDFTLTISSLEPEDFAVYYCQQR NNWYTFGQGTKLEIKASLVPRGSGWSHPQFEKGGGSGGGSGGGSWSHPQF EK
SEQ ID NO 19
DNA sequence:

(96) TABLE-US-00023 ATGAAGTTATGCATATTACTGGCCGTCGTGGCCTTTGTTGGCCTCTCGCT CGGGAGATCTGAAGAGCAACTGGTGGAGAGCGGTGGTGGTCTGGTTCAGC CGGGTCGTTCCCTGCGTCTGTCCTGCGTGGGTAGCGGTCTGCGTTTTGAG GAGCACGCGATGCACTGGGTGCGTCAGGCACCGGGTCGCGGTCTGGAGTG GGTGAGCGGTATCAGCTGGAACAGCGGTAGCGTGGGTTATGCCGACAGCG TGAAGGGCCGTTTCACCACCAGCCGCGACAACGCCAAGGATATCCTGTTC CTGGAGATGAACACCCTGCGTAGCGAGGATACCGCGCTGTACTTCTGCGC GATTATGGTGGCCACCACCAAGAACGACTTCCACTACTACAAGGATGTGT GGGGCAAGGGCACCACCGTGACCGTGAGCAGTGGCGGCGGTGGCAGCGGC GGTGGCGGTAGCGGTGGCGGTGGCAGCCAGATTGTGCTGACCCAGAGCCC GGCAACCCTGAGCCTGAGCCCGGGCGAGCGTGCCACCCTGAGCTGCCGTG CAAGCCAGAGCGTGAGCAACCACCTGGCGTGGTATCAGCAGAAGCCGGGT CAGGCGCCGCGTCTGCTGATCTACGAAACCAGCAACCGTGCCACCGGCAT TCCGCCGCGCTTCAGCGGCAGCGGTAGCGGCACCGACTTCACCCTGACCA TTAGCAGCCTGGAGCCGGAGGATTTCGCCGTGTACTATTGCCAACAGCGT AACAACTGGTACACCTTCGGTCAGGGCACCAAACTGGAAATCAAAGCTAG CCTGGTTCCCCGCGGATCGGGTTGGAGTCATCCACAATTCGAGAAGGGCG GCGGCTCCGGAGGTGGATCAGGAGGTGGTTCCTGGTCACACCCTCAATTC GAGAAGTGA
SEQ ID NO 13
LENGTH: 315 amino acids
TYPE: PRT
ORGANISM: Artificial Sequence
FEATURE: Single-chain antibody
OTHER INFORMATION: mAb 2D10 single chain Fv (scFv 2D10) with N terminal Bip signal sequence, internal flexible linker and C terminal thrombin protease cleavage site followed by 6His-2Strep tag
SEQUENCE

(97) TABLE-US-00024 MKLCILLAVVAFVGLSLGRSQVQLVQSGPEVKKPGASVRLSCKASGYVFT NYGVSWVRQAPGQGLEWMGWSSPYNGNTYYAQKLKARVTMTTDTSTNTAY MELRSLRSDDTAVYYCGRDMLGVVQAVAGPFDSWGQGTLVTVSSASGGGG SGGGGSGGGGSGGGDTPMTQSPSSVSASVGDRVTISCRASQGISNSLAWY QQKLGKAPQLLIYAASSLQSGVPSRFSGSGSGTDFTLTISSLQPEDFATY YCQQTNTFPFTFGPGTKVEVRRASLVPRGSGWSHPQFEKGGGSGGGSGGG SWSHPQFEK
SEQ ID NO 20
DNA sequence:

(98) TABLE-US-00025 ATGAAGTTATGCATATTACTGGCCGTCGTGGCCTTTGTTGGCCTCTCGCT CGGGAGATCTCAGGTGCAGCTGGTGCAGAGCGGCCCGGAAGTGAAAAAGC CGGGCGCAAGCGTGCGTCTGTCTTGCAAAGCATCCGGTTACGTGTTCACC AACTACGGTGTGAGCTGGGTGCGCCAGGCTCCTGGTCAGGGCCTGGAATG GATGGGTTGGAGCAGCCCATACAACGGTAACACCTACTATGCGCAGAAAC TGAAGGCTCGTGTGACCATGACCACCGACACCAGCACCAACACCGCATAC ATGGAGCTGCGTAGCCTGCGCTCTGACGATACCGCCGTGTATTACTGCGG TCGCGATATGCTGGGTGTGGTGCAGGCAGTGGCGGGTCCATTCGACTCCT GGGGTCAGGGCACCCTGGTGACCGTGTCCTCTGCAAGCGGCGGTGGTGGT TCTGGTGGCGGCGGTAGCGGTGGTGGCGGTAGCGGCGGCGGTGACACCCC AATGACCCAGTCTCCGTCCTCTGTGTCTGCTTCCGTGGGCGATCGCGTGA CCATCTCCTGCCGCGCATCTCAGGGCATTAGCAACTCTCTGGCATGGTAT CAGCAGAAACTGGGCAAGGCTCCACAGCTGCTGATCTATGCGGCATCCTC TCTGCAGAGCGGTGTGCCTTCTCGTTTCTCCGGTAGCGGCTCCGGCACCG ATTTCACCCTGACCATCTCCAGCCTGCAGCCAGAGGATTTCGCTACCTAC TATTGCCAGCAGACCAACACCTTCCCATTCACCTTCGGCCCTGGCACCAA AGTGGAAGTGCGTCGCGCTAGCCTGGTTCCCCGCGGATCGGGTTGGAGTC ATCCACAATTCGAGAAGGGCGGCGGCTCCGGAGGTGGATCAGGAGGTGGT TCCTGGTCACACCCTCAATTCGAGAAGTGA