Immunogenicity of loop-structured short synthetic peptides mimicking the antigenic site A of influenza virus hemagglutinin

In order to assess the relevance of conformation for the antigenic site A of the hemagglutinin of influenza virus we synthesized two peptides, comprising two variant sequences of the central part of site A (amino acids 140 - 146 of subunit HA1) inserted into an artificial peptide skeleton, which imposes a loop-like structure on the respective sequence stretch. Assuming that the loop structure in the synthetic peptides would roughly approximate to the structure of the cognate protein sequence we tried to raise protein-reactive anti-peptide antibodies. The antibodies obtained indeed showed reactivity against influenza virus, although the discriminating specificity with regard to a mutation at position 144 was lost for virus binding in contrast to the highly specific peptide binding. Considering the failures in raising anti-hemagglutinin antibodies against the site A by immunization with short flexible peptide our results support the hypothesis that conformation makes a major contribution to the immunogenic and antigenic characteristics of site A in influenza hemagglutinin.     

Elucidation of discontinuous linear determinants in peptides.

Synthetic peptides, made by the method of simultaneous multiple peptide synthesis, were coupled to the protein carrier keyhole limpet hemocyanin and used to raise mAb. Omission and substitution analogs of the original peptides were tested by ELISA to characterize their reactivity with the respective mAb. Linear antigenic determinants were located for 18 different peptides by using omission analogs. The length of the antigenic determinants ranged from 2 to 8 residues, with an average of 6 residues. The three aromatic amino acids, phenylalanine, tryptophan, and tyrosine, the charged hydrophilic amino acids, aspartic acid and lysine, and the neutral amino acid alanine were found to occur most often in the determinant region of the peptides tested, whereas asparagine, cysteine, and histidine occurred the least often. Alanine substitution analogs provided more information than omission analogs by enabling the determination of which side chain groups of the antigenic determinant residues were not critical for binding to the mAb. Detailed, "fingerprint" information about the interaction of the peptide, GASPYPNLSNQQT, and its mAb was obtained by synthesizing a complete series of analogs with individual substitutions for each position of the antigenic determinant, PYPNLS, with the 19 other amino acids. These results suggest that, at the amino acid level, all antigenic determinants of synthetic peptides defined by mAb can be considered discontinuous linear determinants.     

Use of the multipin peptide synthesis technique for the generation of antipeptide sera

The multipin peptide synthesis technique has been used to map antigenic sites of proteins (1,2). Antibodies raised to the whole protein are screened on pin-synthesized overlapping octapeptides homologous with the protein of interest, and the peptides that bind antibodies clearly identify the epitopes. What is described in this study is a method using pin-synthesized peptides to generate specific antibodies to many peptides. Cleavable linkers have been developed (3) that, used together with the multipin peptide synthesis technique, allow the synthesis and cleavage of many thousands of peptides into aqueous solutions at physiological pH. This technique is useful for assays requiring peptides in solution, e.g., mapping of T-cell determinants. A technique has been developed for the cleavage of many peptides from pins and simultaneous coupling to immunogenic carriers (4). The conjugates produced are suitable for the generation of antipeptide antibodies. This procedure is illustrated using several 15 amino acid long peptides (15-mers), homologous with the sequence of a model antigen, myohemerythrin (MHr). The resulting antipeptide sera generated were tested by ELISA for titer and specificity on pinsynthesized peptides and β-amide peptides and the protein antigen coated to microtiter plates.     

Lipid-induced recognition of a conformational determinant (residues 65 to 83) in myelin basic protein

The precipitation by antibodies to intact myelin basic protein (BP) and to synthetic peptides containing a sequence based on the region 65 to 83 of bovine BP, S82, S81, S79, and S24, of intact BP in solution or bound to lipid vesicles was compared, using 125I-BP or 14C-DPPC-labeled lipid-BP vesicles. The antipeptide antibodies were shown earlier to recognize conformational determinants which are not expressed in the intact protein in solution. Several anti-BP antibodies precipitated more of the BP free in solution than when bound to lipid vesicles, suggesting that some of the determinants recognized by these antibodies were either sequestered in the bilayer or were altered in conformation. In contrast, one anti-peptide antisera, which had a high titer for the conformational determinant in two of these peptides, S82 and S81, precipitated the protein to a significant degree when it was bound to PG vesicles, even though it did not react with the intact protein in solution. These results indicated that PG was able to confer on the protein the unique peptide conformation recognized by this antibody. PS was less effective, and other lipids were ineffective at conferring this conformation on the protein, supporting earlier results which showed that the conformation of the protein is influenced by the lipid composition of its environment. None of the other anti-peptide antibodies studied bound to the protein either in solution or in lipid vesicles. These results indicate that the lipid environment can sequester or alter the conformation of some antigenic determinants, preventing recognition by some anti-BP antibodies, and can expose or generate other conformational determinants, allowing recognition by an anti-peptide antiserum.     

Use of the multipin peptide synthesis technique for the generation of antipeptide sera.

The multipin peptide synthesis technique has been used to map antigenic sites of proteins (1,2). Antibodies raised to the whole protein are screened on pin-synthesized overlapping octapeptides homologous with the protein of interest, and the peptides that bind antibodies clearly identify the epitopes. What is described in this study is a method using pin-synthesized peptides to generate specific antibodies to many peptides. Cleavable linkers have been developed (3) that, used together with the multipin peptide synthesis technique, allow the synthesis and cleavage of many thousands of peptides into aqueous solutions at physiological pH. This technique is useful for assays requiring peptides in solution, e.g., mapping of T-cell determinants. A technique has been developed for the cleavage of many peptides from pins and simultaneous coupling to immunogenic carriers (4). The conjugates produced are suitable for the generation of antipeptide antibodies. This procedure is illustrated using several 15 amino acid long peptides (15-mers), homologous with the sequence of a model antigen, myohemerythrin (MHr). The resulting antipeptide sera generated were tested by ELISA for titer and specificity on pin-synthesized peptides and beta-amide peptides and the protein antigen coated to microtiter plates.     

Isolation and characterization of a CNBr cleavage peptide of influenza viral hemagglutinin stimulatory for mouse cytolytic T lymphocytes

A polypeptide fragment obtained by CNBr cleavage of the hemagglutinin from A/JAPAN/305/57 influenza virus has been purified by using high performance liquid chromatography. The first five N-terminal amino acids as determined by sequential Edman degradations have localized this peptide to the HA2 subunit of the hemagglutinin between residues 103 and 123. This peptide, denoted HA2(103-23), can generate both proliferative and cytolytic responses from spleen cells of BALB/c mice previously immunized with A/JAPAN/305/57. These results demonstrate that a single nonglycosylated fragment of the influenza hemagglutinin as small as 21 amino acid residues is capable of being recognized as an antigenic determinant to generate influenza CTL from primed precursors.     

Use of synthetic peptides to map the antigenic determinants of glycoprotein D of herpes simplex virus.

The predictive algorithm Surfaceplot (J.M.R. Parker, D. Guo, and R.S. Hodges, Biochemistry 25:5425-5432, 1986) was used to examine glycoprotein D of herpes simplex virus type 1 (HSV-1) for amino acid residues with a high probability of being exposed on the molecular surface. Based on these data, 11 different peptides corresponding to 10-residue segments in the primary sequence of glycoprotein D and one 20-residue segment were synthesized, conjugated to carrier proteins, and used to generate specific antisera in rabbits. Two synthetic peptides predicted not to be on the surface of glycoprotein D were included as negative controls. The polyclonal antisera against individual synthetic peptide conjugates were in turn evaluated for their ability to recognize both isolated glycoprotein D and intact HSV-1 virions in an enzyme-linked immunosorbent assay. Based on Surfaceplot predictions, eight linear antigenic sites on glycoprotein D were thereby defined from the 12 antipeptide antisera prepared. Four of these sites contained epitopes to which complement-independent neutralizing antibodies could be generated. The latter sites corresponded to sequences 12 to 21, 267 to 276, 288 to 297, and 314 to 323 of the mature protein. An additional peptide sequence, 2 to 21, was found to generate antisera which had potent virus-neutralizing capacity in the presence of complement. Identification of a neutralizing epitope in the sequence 314 to 323 makes it likely that the membrane-spanning region of glycoprotein D is within the subsequent sequence, 323 to 339. Antipeptide antisera prepared in this study from 12 synthetic peptides contained 13 surface sites predicted by Surfaceplot, of which 7 were not predicted by the parameters of Hopp and Woods (Proc. Natl. Acad. Sci. USA 78:3824-3828, 1981). Of these seven sites not predicted by the Hopp and Woods plot, all generated antipeptide antibodies that bound to HSV-1 virions and three of these seven sites generated neutralizing antibodies. In total, 8 of 12 synthetic peptides containing surface regions produced antipeptide antibodies that bound to HSV-1 virions and 5 of these generated neutralizing antibodies. These results suggest the advantages of Surfaceplot in mapping antigenic determinants in proteins.     

Human helper T-cell clones that recognize different influenza hemagglutinin determinants are restricted by different HLA-D region epitopes

Human T-lymphocyte clones (TLCs) were generated against the hemagglutinin (HA) of A/Texas/1/77 influenza virus by limiting dilution. TLCs were then screened for antigen specificity on chemically synthesized peptides representing the HA1 molecule. It has been hypothesized that different T cells that recognize the identical antigenic determinant are controlled by (restricted by) the same class II epitope. Two TLCs, HA1.4 and HA1.7, both recognized the same HA peptide and in proliferation studies exhibited identical restriction patterns. Two other clones, HA 1.9 and HA 2.43, recognized different HA determinants and also had distinct restriction patterns. Proliferation inhibition studies with monoclonal antibodies against human class II molecules demonstrated three unique patterns of blocking with the clones, suggesting that clones may be restricted to a unique class II epitope depending on the HA determinant recognized. These data can be interpreted as supporting the argument that human immune responses to influenza hemagglutinin are under Ir gene control exerted at the level of the viral antigenic determinant recognized in association with particular D-region restricting elements. The determinant selection and clonal deletion theories are compared for their capacity to best explain these findings.Abbreviations used in this paper ³HTdR tritiated methyl thymidine - MHC major histocompatibility complex - HLA human MHC - PBLs peripheral blood lymphocytes - APCs antigen-presenting cells - TLCs T-lymphocyte clones - TCGF T-cell growth factor - MoAbs monoclonal antibodies     

Monoclonal antibodies distinguish synthetic peptides that differ in one chemical group

By using human calcitonin (hCT), human calcitonin-gene-related peptide (hCGRP), and a synthetic peptide with a sequence analogous to the 34 C-terminal amino acids of human preprocalcitonin (designated as PQN-34) as haptens in the generation of monoclonal antibodies, we assessed the role of amido and amino groups in paratope-epitope binding. By using peptide inhibition experiments and solid-phase immunoassays, monoclonal anti-hCT antibody CT07 and monoclonal anti-hCGRP antibody CGR01 were found to bind to an antigenic determinant located in the C-terminal segment of the hormones. These epitopes comprise the seven C-terminal amino acids of the hormones, and the presence of the hormone-ending carboxamide group was found to be essential for antibody binding. The corresponding heptapeptides, either bearing a carboxyl group or else linked to a glycine residue at their C-terminal part, failed to react with the antibodies. Moreover, these monoclonal antibodies did not bind to synthetic peptides analogous to the C-terminal region of the hormone precursor molecules that comprised the epitope site flanked by a peptide sequence. In an attempt to assess whether amido groups when present on the side-chain of amino acids may also modulate antibody binding, a monoclonal antibody referred to as QPO1 was produced and was found to recognize an antigenic determinant localized in the N-terminal region of the PQN-34 peptide bearing a glutamine residue as the N-terminal amino acid. The epitope was found to correspond to a topographic assembled site, and binding of QPO1 was found to be substantially dependent on the presence of the free amino and the side-chain amido groups borne by the N-terminal glutamine residue of this peptide PQN-34. In contrast to these findings, an antigenic determinant located in the internal sequence of calcitonin and recognized by monoclonal anti-hCT antibody CT08 was found to be expressed on the mature form of the hormone, as well as on synthetic peptides with sequence mimicking that of preprocalcitonin. These data should guide the choice of synthetic peptide haptens for the production of anti-protein antibodies.     

Identification of an immunodominant neutralizing and protective epitope from measles virus fusion protein by using human sera from acute infection.

Polyclonal sera obtained from African children with acute measles were used to screen a panel of 15-mer overlapping peptides representing the sequence of measles virus (MV) fusion (F) protein. An immunodominant antigenic region from the F protein (p32; amino acids 388 to 402) was found to represent an amino acid sequence within the highly conserved cysteine-rich domain of the F protein of paramyxoviruses. Epitope mapping of this peptide indicated that the complete 15-amino-acid sequence was necessary for high-affinity interaction with anti-MV antibodies. Immunization of two strains of mice with the p32 peptide indicated that it was immunogenic and could induce antipeptide antibodies which cross-reacted with and neutralized MV infectivity in vitro. Moreover, passive transfer of antipeptide antibodies conferred significant protection against fatal rodent-adapted MV-induced encephalitis in susceptible mice. These results indicate that this epitope represents a candidate for inclusion in a future peptide vaccine for measles.     

Identification of an HSV-1/HSV-2 cross-reactive T cell determinant.

The results from a number of studies have documented that the HSV glycoprotein gD is an important target for neutralizing antibodies. In contrast, little is known about the Th cell determinants present on HSV that are required for anti HSV gD antibody production. In our study we have immunized BALB/c mice with a recombinant source of HSV-1 gD lacking the carboxyl-terminal 93 amino acids. T cell hybridomas produced from the immunized animals recognized a single antigenic peptide (amino acids 246-261) in the context of I-Ad. The determinant expressed by gD peptide 246-261 was generated and presented by both HSV-1 and HSV-2 infected APC. Fine specificity analysis using truncated synthetic gD peptides revealed that the minimal amino acids recognized by the T hybrids were identical between HSV-1 and HSV-2. In addition, the minimal peptide-I-Ad binding analysis demonstrated that the minimal peptide sequence required for the binding to I-Ad and for T cell recognition contained two prolines. Thus, this important HSV antigenic determinant would not be expected to form an amphipathic alpha-helix and could therefore be missed by algorithms currently used to predict which amino acid sequences would be antigenic based on the propensity to form helices.     

Immunogenic structure of the influenza virus hemagglutinin

We chemically synthesized 20 peptides corresponding to 75% of the HA1 molecule of the influenza virus. Antibodies to the majority (18) of these peptides were capable of reacting with the hemagglutinin molecule. These 18 peptides are not confined to the known antigenic determinants of the hemagglutinin molecule, but rather are scattered throughout its three-dimensional structure. In contrast, antibody raised to intact hemagglutinin did not react with any of the 20 peptides. Taken together these results suggest that the immunogenicity of an intact protein molecule is not the sum of the immunogenicity of its pieces.     

Role of receptor-binding activity of the viral hemagglutinin molecule in the presentation of influenza virus antigens to helper T cells.

The concentration of antigen required to stimulate influenza virus-specific helper T cells was observed to be dependent upon the antigenic form bearing the relevant determinant: intact, nonreplicative virus was needed only in picomolar amounts, while denatured proteins, protein fragments, or synthetic peptides were required in micromolar concentrations for a threshold level of stimulation. Antigenic efficiency of intact virus was found to result from the attachment of virus to sialic acid residues on the surface of the antigen-presenting cell since spikeless viral particles lacking the hemagglutinin molecule were much less efficient antigens for helper T cells and continuous presence of hemagglutination-inhibiting antihemagglutinin antibodies reduced efficiency of stimulation by intact virus approximately 100-fold for both hemagglutinin and internal virion proteins. Influenza virus associated rapidly with antigen-presenting cells; less than 10 min at 20 degrees C was sufficient to introduce virus for a maximal level of T-cell stimulation. This rapid attachment was blocked by antibodies to the hemagglutinin or by pretreatment of the antigen-presenting cells with neuraminidase to remove the cellular virus receptor. Following viral adsorption by antigen-presenting cells, a lag period of 30 min at 37 degrees C was required for the expression of helper T-cell determinants. One early event identified was the movement of the virus to a neuraminidase-insensitive compartment, which can occur at 10 degrees C, but which was not equivalent to expression of helper T-cell determinants. Preincubation of cells with virus at 10 degrees C for 4 h reduced the lag period of helper T-cell determinant expression to 15 min when these cells were shifted to 37 degrees C, suggesting that transition of the virus to a neuraminidase-resistant state is a required step in presentation of T-cell antigenic determinants.     

Fine specificity of murine class II-restricted T cell clones for synthetic peptides of influenza virus hemagglutinin. Heterogeneity of antigen interaction with the T cell and the Ia molecule

We have previously demonstrated diversity in the specificity of murine, H-2k class II-restricted, T cell clones for the hemagglutinin (HA) molecule of H3N2 influenza viruses and have mapped two T cell determinants, defined by synthetic peptides, to residues 48-68 and 118-138 of HA1. In this study we examine the nature of the determinant recognized by six distinct P48-68-specific T cell clones by using a panel of truncated synthetic peptides and substituted peptide analogs. From the peptides tested, the shortest recognized were the decapeptides, P53-62 and P54-63, which suggests that the determinant was formed from the 9 amino acids within the sequence 54-62. Asn54 was critical for recognition since P49-68 (54S) was not recognized by the T cell clones. Furthermore this peptide analog was capable of competing with P48-68 for Ag presentation, thereby suggesting that residue 54 is not involved in Ia interaction and may therefore be important for TCR interaction. Residue substitutions at position 63 also affected T cell recognition, but in a more heterogeneous fashion. Peptide analogs or mutant viruses with a single amino acid substitution at position 63 (Asp to Asn or Tyr) reduced the responses of the T cell clones to variable extents, suggesting that Asp63 may form part of overlapping T cell determinants. However since the truncated peptide P53-62 was weakly recognized, then Asp63 may not form part of the TCR or Ia interaction site, but may affect recognition through a steric or charge effect when substituted by Asn or Tyr. Ag competition experiments with the two unrelated HA peptides, P48-68 and P118-138, recognized by distinct T cell clones in the context of the same restriction element (I-Ak), showed that the peptides did not compete for Ag presentation to the relevant T cell clones, whereas a structural analog of P48-68 was a potent inhibitor. This finding is discussed in relation to the nature of the binding site for peptide Ag on the class II molecule.     

Recognition of HLA class I molecules by antisera directed to synthetic peptides corresponding to different regions of the HLA-B7 heavy chain

Antisera have been prepared in rabbits and in mice against different peptides corresponding to four hydrophilic and variable regions of HLA-B7 heavy chain (65-82, 99-118, 138-157, and 164-187). Specific antipeptide sera have been obtained with all synthetic peptides; for three of them which were more than 20 amino acids long, highly potent sera were elicited by injection of the free peptide. Three overlapping peptides included in region 138-157 have been used, and two different antigenic sites were detected in this region. HLA molecules solubilized in nonionic detergent were precipitated by antipeptide sera directed against regions 65-82, 138-157, and 164-187, but not by antipeptide serum directed against the less hydrophilic region 99-118. Analysis by two-dimensional electrophoresis of the isolated molecules confirmed the anti-HLA specificity of the antipeptide 65-82 and 138-157 sera. Variable numbers of HLA-related spots were found according to the antisera used. Antipeptide 138-157 serum precipitated numerous HLA molecules and therefore probably reacted with monomorphic determinants whereas antipeptide 65-82 appeared specific for a more limited number of HLA antigens. Such reagents directed against well-defined regions of the HLA class I heavy chain are of considerable interest, notably for the mapping of antigenic epitopes on the molecule and for the study of relationships between structure and function.     

Immunogenic peptide comprising a mouse hepatitis virus A59 B-cell epitope and an influenza virus T-cell epitope protects against lethal infection.

The coronavirus spike protein S is responsible for important biological activities including virus neutralization by antibody, cell attachment, and cell fusion. Recently, we have elucidated the amino acid sequence of an S determinant common in murine coronaviruses (W. Luytjes, D. Geerts, W. Posthumus, R. Meloen, and W. Spaan, J. Virol. 63:1408-1412, 1989). A monoclonal antibody directed to this determinant (MAb 5B19.2) protected mice against acute fatal infection. In this study, BALB/c mice were immunized with a synthetic peptide of 13 amino acids corresponding to the binding site of MAb 5B19.2, which was either extended with an amino acid sequence of influenza virus hemagglutinin or conjugated to keyhole limpet hemocyanin. Both immunogens induced S-specific antibodies in mice, but only the hemagglutinin-peptide construct protected them against lethal challenge. In contrast to mouse hepatitis virus type 4 (MHV-4), MHV-A59 was not neutralized in vitro by MAb 5B19.2. Neither MHV-A59 nor MHV-4 was neutralized in vitro by antibodies comprising by the synthetic peptides. Our results demonstrated that antibodies elicited with a synthetic peptide comprising a B-cell epitope and a T-helper cell determinant can protect mice against an acute fetal mouse hepatitis virus infection.     

Mapping of dominant B-cell epitopes of a human zona pellucida protein (ZP1)

Zona pellucida (ZP) glycoproteins contain numerous antigenic determinants including carbohydrate, protein, and conformational epitopes; and the immunogenicity of these complex glycoproteins varies in different mammalian hosts. Studies have now shown that antibodies from primates immunized with a cDNA-expressed recombinant rabbit ZP protein (the homologue of the human ZP1 [hZP1]) inhibit sperm binding to the ZP without altering ovarian function, unlike immunization with ZP3 and ZP2 protein families. The ZP1 protein or peptides derived from it (recombinant or synthetic) are therefore primary candidates for use in designing safe and reversible human and animal contraceptive vaccines. In order to define peptide epitope(s) that may be critical for eliciting an immune response sufficient to effect immunological contraception without causing any adverse effects on ovarian physiology, studies have been carried out to identify immunodominant B-cell epitopes of the ZP1 protein. The amino acid sequence of the hZP1 was used to design a set of 94 (15-mer) biotinylated peptides having an overlap of 9 amino acids. Using these peptides in a modified enzyme-linked immunoassay, antibodies in sera from rabbits or baboons immunized with native porcine ZP protein were screened for ZP1 peptide recognition. These studies demonstrate that there are a limited number of peptides recognized by primate antibodies but that the overlapping peptides sharing the sequence GPLTLELQI are recognized by both rabbit and baboon antibodies regardless of the adjuvant system used to induce the immune response. This peptide is 100% conserved in amino acid sequence between the human and pig, although the rabbit protein has two conserved amino acid substitutions (100% similar, 77% identical). Because this peptide is immunogenic as well as antigenic in primates, it could play a major role in the development of human contraceptive vaccines.     

Mapping of homologous, amino-terminal neutralizing regions of human T-cell lymphotropic virus type I and II gp46 envelope glycoproteins.

Twelve synthetic peptides containing hydrophilic amino acid sequences of human T-cell lymphotropic virus type I (HTLV-I) envelope glycoprotein were coupled to tetanus toxoid and used to raise epitope-specific antisera in goats and rabbits. Low neutralizing antibody titers (1:10 to 1:20) raised in rabbits to peptides SP-2 (envelope amino acids [aa] 86 to 107), SP-3 (aa 176 to 189), and SP-4A (aa 190 to 209) as well as to combined peptide SP-3/4A (aa 176 to 209) were detected in the vesicular stomatitis virus-HTLV-I pseudotype assay. Higher-titered neutralizing antibody responses to HTLV-I (1:10 to 1:640) were detected with pseudotype and syncytium inhibition assays in four goats immunized with a combined inoculum containing peptides SP-2, SP-3, and SP-4A linked to tetanus toxoid. These neutralizing anti-HTLV-I antibodies were type specific in that they did not inhibit HTLV-II syncytium formation. Neutralizing antibodies in sera from three goats could be absorbed with peptide SP-2 (aa 86 to 107) as well as truncated peptides containing envelope aa 90 to 98, but not with equimolar amounts of peptides lacking envelope aa 90 to 98. To map critical amino acids that contributed to HTLV-I neutralization within aa 88 to 98, peptides in which each amino acid was sequentially replaced by alanine were synthesized. The resulting 11 synthetic peptides with single alanine substitutions were then used to absorb three neutralizing goat antipeptide antisera. Both asparagines at positions 93 and 95 were required for adsorption of neutralizing anti-HTLV-I antibodies from all three sera. Peptide DP-90, containing the homologous region of HTLV-II envelope glycoprotein (aa 82 to 97), elicited antipeptide neutralizing antibodies to HTLV-II in goats that were type specific. In further adsorption experiments, it was determined that amino acid differences between homologous HTLV-I and HTLV-II envelope sequences at HTLV-I aa 95 (N to Q) and 97 (G to L) determined the type specificity of these neutralizing sites. Thus, the amino-terminal regions of HTLV-I and -II gp46 contain homologous, linear, neutralizing determinants that are type specific.     

Screening of random peptide library of hemagglutinin from pandemic 2009 A(H1N1) influenza virus reveals unexpected antigenically important regions

The antigenic structure of the membrane protein hemagglutinin (HA) from the 2009 A(H1N1) influenza virus was dissected with a high-throughput screening method using complex antisera. The approach involves generating yeast cell libraries displaying a pool of random peptides of controllable lengths on the cell surface, followed by one round of fluorescence-activated cell sorting (FACS) against antisera from mouse, goat and human, respectively. The amino acid residue frequency appearing in the antigenic peptides at both the primary sequence and structural level was determined and used to identify "hot spots" or antigenically important regions. Unexpectedly, different antigenic structures were seen for different antisera. Moreover, five antigenic regions were identified, of which all but one are located in the conserved HA stem region that is responsible for membrane fusion. Our findings are corroborated by several recent studies on cross-neutralizing H1 subtype antibodies that recognize the HA stem region. The antigenic peptides identified may provide clues for creating peptide vaccines with better accessibility to memory B cells and better induction of cross-neutralizing antibodies than the whole HA protein. The scheme used in this study enables a direct mapping of the antigenic regions of viral proteins recognized by antisera, and may be useful for dissecting the antigenic structures of other viral proteins.     

Epitopes of an influenza viral peptide recognized by antibody at single amino acid resolution

Antibodies raised against the synthetic peptide corresponding to the carboxy-terminal 24 amino acids (305-328) of the heavy chain of the hemagglutinin molecule of influenza virus A/X-31 (H3) bind this peptide at three antigenic sites. These sites were identified by assaying binding of polyclonal BALB/c mouse antipeptide sera to the complete set of all possible di-, tri, tetra-, penta-, hexa-, hepta-, and octapeptides homologous with the 24-residue sequence. Individual epitopes were defined and essential residues identified by testing the binding of monoclonal antibodies to sets of peptide analogues in which every one of the homologous residues was replaced in turn by each of the 19 alternative genetically coded amino acids. The immunodominant epitope was shown to be a linear sequence of five amino acids, 314LKLAT318. Replacement of any one of these residues with any other amino acid resulted in loss of antibody binding, indicating that all five are essential to the interaction and that they are probably contact residues. Another antigenic site contains at least two overlapping epitopes: polyclonal sera recognize predominantly an epitope or epitopes encompassed by the linear sequence 320MRNVPEKQT328, whereas the epitope defined by a particular monoclonal antibody comprises the seven amino acids 322NVPEKQT328, of which N322, E325, and Q327 were implicated as contact residues.