Antigenic properties of synthetic fragments of the heavy chain of influenza virus A hemagglutinin

The antigenic properties of the synthetic peptides corresponding to the regions 122-133, 136-147, 154-164 of the virus A/Aichi/2/68 hemagglutinin heavy chain have been studied. The 122-133 and 136-147 peptides comprise together almost whole antigenic determinant A, while the 154-164 peptide is a part of determinant B. Rabbits immunized by the peptides conjugated with carrier-protein BSA gave the high immune response to hapten-peptides. Each antiserum reacted only with homologous conjugate. All the antipeptide serums reacted with the virus A/Aichi/2/68 fixed on the base. Conjugate of the 136-147 peptide reacted with the rabbit antiserum against the virus A/Aichi/2/68 rendering the direct evidence to location of at least one hemagglutinin antigenic determinant in the region 136-147.     

Peptide mapping of the monoclonal antibodies against the heavy chain hemagglutinin from influenza virus H3N2

Interaction of the synthetic peptides corresponding to the regions 122-133, 136-147, 154-164 and 314-328 of the virus A/Aichi/2/68 hemagglutinin heavy chain with monoclonal antibodies specific for this hemagglutinin was assayed in a variety of tests, e.g., ELISA, competition RIA, hemagglutinin-inhibition and virus-neutralization assays. The monoclonal antibody 152 reacted with the area 136-147 (epitope A), three monoclonal antibodies 3, 19 and 63 reacted exclusively with the area (154-164) Glu (epitope B). Mapping of two monoclonal antibodies IV A1 and IV G6 specific for the influenza virus A/Dunedin/ 4/73 hemagglutinin heavy chain and cross-reacting with a number of the H3 subtype viruses was carried out. The specificity of the interaction of the conservative peptide H3(314-328) with monoclonal antibodies IV A1 and IV G6 was confirmed by competition RIA and by competition hemagglutinin inhibition and virus neutralization.     

Synthesis of peptide fragments of influenza virus A/Aichi/2/68 (H3N2) hemagglutinins

Peptides corresponding to sequences 122-133, 136-147, and 154-164 of the heavy chain of hemagglutinin of the A/Aichi/2/68 (H3N2) influenza virus have been synthesized by stepwise elongation of the peptide chain with Boc-amino acid activated esters or by condensation of peptide blocks by DCC/HOBt-method. A coloured C-protecting group, 2-[4-(phenylazo)-benzylsulfonyl]ethyl (PSE), was used, which is convenient in purification of synthetic peptides. After removal of terminal N-and C-protecting groups the side-protecting residues were cleaved off with 1 M trifluoromethanesulfonic acid in trifluoroacetic acid containing 10% thioanisole. Crude products were purified by preparative reversed-phase liquid chromatography. Synthesized peptides were conjugated with BSA.     

Amino acid sequence and oligosaccharide distribution of the haemagglutinin from an early Hong Kong influenza virus variant A/Aichi/2/68 (X-31).

The amino acid sequence and oligosaccharide distribution for the haemagglutinin from the early Hong Kong influenza virus A/Aichi/2/68 (X-31) was investigated. The two polypeptide chains, HA1 and HA2, were fragmented by CNBr and enzymic digestion, and the amino acid sequence of each small peptide was deduced by comparing its chromatographic behaviour, electrophoretic mobility, amino acid composition and N-terminus with that of the corresponding peptide of the haemagglutinin of known structure from the influenza-virus variant A/Memphis/102/72. Those peptides in which changes were detected were sequenced fully. The complete amino acid sequence of the haemagglutinin HA1 chain (328 residues) and 188 of the 221 residues of the HA2 chain were established by this approach, and revealed only twelve differences between the amino acid sequences of variant-A/Aichi/68 and -A/Memphis/72 haemagglutinins. These occurred at positions 2, 3, 122, 144, 155, 158, 188, 207, 242 and 275 in the HA1 chain and 150 and 216 in the HA2 chain. The highly aggregated hydrophobic region (residues 180-121) near the C-terminal end of the HA2 chain was not resolved by peptide sequencing. The oligosaccharide distribution in variant-A/Aichi/68 haemagglutinin was identical with that found in that of A/Memphis/72, with sugar units attached at asparagine residues 8, 22 38, 81, 165 and 285 in the HA1 chain and 154 on the HA2 chain. The monosaccharide compositions of the individual carbohydrate units on variant-A/Aichi/68 haemagglutinin differed from those of the corresponding units in variant-A/Memphis/72 haemagglutinin, and evidence was found for heterogeneity in the oligosaccharide units attached at single glycosylation sites.     

Heptapeptide ligands against receptor-binding sites of influenza hemagglutinin toward anti-influenza therapy

The initial attachment of influenza virus to cells is the binding of hemagglutinin (HA) to the sialyloligosaccharide receptor; therefore, the small molecules that inhibit the sugar–protein interaction are promising as HA inhibitors to prevent the infection. We herein demonstrate that sialic acid-mimic heptapeptides are identified through a selection from a primary library against influenza virus HA. In order to obtain lead peptides, an affinity selection from a phage-displayed random heptapeptide library was performed with the HAs of the H1 and H3 strains, and two kinds of the HA-binding peptides were identified. The binding of the peptides to HAs was inhibited in the presence of sialic acid, and plaque assays indicated that the corresponding N-stearoyl peptide strongly inhibited infections by the A/Aichi/2/68 (H3N2) strain of the virus. Alanine scanning of the peptides indicated that arginine and proline were responsible for binding. The affinities of several mutant peptides with single-amino-acid substitutions against H3 HA were determined, and corresponding docking studies were performed. A Spearman analysis revealed a correlation between the affinity of the peptides and the docking study. These results provide a practicable method to design of peptide-based HA inhibitors that are promising as anti-influenza drugs.     

Genetic basis of influenza virus virulence: gene composition and virulence of reassortants between mouse-adapted and nonadapted strains from different subtypes

Reassortment analysis of the pneumovirulence for mice marker of influenza virus has been performed. The original A/USSR/90/77 (H1H1) influenza virus strain or its mouse-adapted variant were crossed with a variant of A/Aichi/2/68 (H3N2) influenza virus highly virulent for mice. The reassortant having HA gene of the original A/USSR/90/77 virus and the other genes of the highly virulent A/Aichi/2/68 strain was avirulent for mice, whereas a similar reassortant possessing HA gene of the mouse-adapted A/USSR/90/77 strain was as virulent as A/Aichi/2/68 parent virus. The reasortant having HA and M genes of A/Aichi/2/68 and other genes of the mouse-adapted A/USSR/90/77 was moderately virulent, resembling in this respect the latter parent. The data indicates that changes in the different genes in course of viral adaptation to mice result in a differential acquisition of virulence for mice.     

甲3型流感病毒早期分离株的抗原特点

目前认为,1968年甲3型流感发生时,至少有二种H3N2亚型的变异株同时存在。一种是1968年7月在香港分离的A/HK/1/68;另一种是1968年8月在日本分离的A/Aichi/2/68。Webster等用一组抗A/Mem/1/77(H3N2)血凝素(HA)的单克隆抗体证实,二种变异株至少有一个反应部位不同。这可能是H3N2亚型有二种不同的世系(lineage),     

Accumulation of amino acid substitutions promotes irreversible structural changes in the hemagglutinin of human influenza AH3 virus during evolution

In order to clarify the effect of an accumulation of amino acid substitutions on the hemadsorption character of the influenza AH3 virus hemagglutinin (HA) protein, we introduced single-point amino acid changes into the HA1 domain of the HA proteins of influenza viruses isolated in 1968 (A/Aichi/2/68) and 1997 (A/Sydney/5/97) by using PCR-based random mutation or site-directed mutagenesis. These substitutions were classified as positive or negative according to their effects on the hemadsorption activity. The rate of positive substitutions was about 50% for both strains. Of 44 amino acid changes that were identical in the two strains with regard to both the substituted amino acids and their positions in the HA1 domain, 22% of the changes that were positive in A/Aichi/2/68 were negative in A/Sydney/5/97 and 27% of the changes that were negative in A/Aichi/2/68 were positive in A/Sydney/5/97. A similar discordance rate was also seen for the antigenic sites. These results suggest that the accumulation of amino acid substitutions in the HA protein during evolution promoted irreversible structural changes and therefore that antigenic changes in the H3HA protein may not be limited.     

Fine mapping of T-cell determinants of bovine β-lactoglobin

T-cell recognition sites, i.e. T-cell determinants, of bovine β-lactoglobulin, a major allergen in milk, were analyzed in detail. For this purpose, we prepared primary cultures of lymph node cells from three strains of mice, C57BL/6 (H-2^b), C3H/HeN (H-2^k), and BALB/c (H-2^d), and examined the proliferative response of these cells to a complete set of overlapping 15-mer peptides which covered the entire sequence of β-lactoglobulin by shifting in single amino acid steps. We were able to determine the putative core sequence of each T-cell determinant and estimate its relative importance. In the case of C57BL/6 mice, dominant, subdominant, and minor determinants were identified as residues 122–130, 16–26, and 108–122, respectively, as represented by their core sequences. Each determinant peptide induced the production of interferon-γ, the amount of which showed a correlation with the intensity of the proliferative response induced by each determinant. In the case of C3H/HeN mice, a dominant determinant comprised of residues 140–148 was identified together with three subdominant and two minor determinants. Dominant T-cell determinants recognized in BALB/c mice were identified as residues 67–75, 71–79, and 80–88, and six other regions were identified as subdominant determinants. Comparisons between our results and the determinants predicted from relevant MHC-binding motifs reported to date revealed the inadequacy of the motifs in predicting even the dominant determinants. The information obtained by complete mapping of T-cell determinants as done in this study is expected to be helpful in establishment and evaluation of new prediction methods and also may contribute to the development of a new approach to control immune responses by manipulation of the T-cell determinants of allergens. This revised version was published online in June 2006 with corrections to the Cover Date.     

Genetic control and fine specificity of the immune response to a synthetic peptide of influenza virus hemagglutinin.

The immune response to a synthetic peptide, H3 HA1(305-328), representing the C'-terminal 24 amino acid residues of the HA1 chain of the hemagglutinin of the H3 subtype of influenza virus is controlled by genes in the I region of the major histocompatibility complex. Mice of the H-2d haplotype are high responders and produce antibody for several months after a single injection of peptide without carrier. Mice of the H-2b, H-2k, and H-2q haplotypes are low antibody responders. Investigation of recombinant and congenic mouse strains revealed that high responsiveness requires the genes that encode the I-Ed molecule. Immunoassays, involving direct binding to analogs of this peptide and inhibition by both these analogs and synthetic epitopes, were used to analyze the specificity of the polyclonal response. In BALB/c mice, the primary antibody response is directed principally against the antigenic site 314-LKLAT-318, whereas the secondary response after a boost is predominantly directed to a distinct site, 320-MRNVPEKQT-328. The T-cell response to the peptide H3 HA1(305-328), as measured by antigen-induced proliferation of primed T cells in vitro, is also I-Ed restricted in high-responder H-2d mice and is directed against an antigenic site that does not require the four C-terminal residues unique to the H3 influenza subtype. A different epitope appears to be recognized by T cells from CBA (H-2k) mice, which proliferate to a moderate extent on exposure to the peptide but, nevertheless, do not provide help for an antibody response.     

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.     

Complete nucleotide sequence of the haemagglutinin gene from a human influenza virus of the Hong Kong subtype.

The complete nucleotide sequence has been determined for a cloned double-stranded DNA copy of the haemagglutinin gene from the human influenza strain A/NT/60/68/29C, a laboratory-isolated variant of A/NT/60/68, an early strain of the Hong Kong subtype. The gene is 1765 nucleotides long and contains information sufficient to code for a protein of 566 amino acids, which includes a hydrophobic leader peptide (16 residues), HA1 (328), HA2 (221) and an arginine residue which joins the HA subunits. Comparison of the predicted amino acid sequence for 29C haemagglutinin with protein sequence data available for HA from other influenza strains shows that no potential coding information is lost by processing of the mRNA. A comparison of the amino acid sequences predicted from the gene sequences for 29C and fowl plague virus haemagglutinins, (1) indicates the extent to which changes can occur in the primary sequence of different regions of the protein, while maintaining essential structure and function.     

Class II-restricted T-cell clones to a synthetic peptide of influenza virus hemagglutinin differ in their fine specificities and in the ability to respond to virus.

Fifteen T-cell clones were derived from BALB/c or DBA/2 mice immunized with a synthetic peptide corresponding to the C-terminal 24 residues (residues 305 to 328) of the HA1 chain of H3 subtype influenza virus hemagglutinin. All of the clones proliferated when the peptide was presented in association with I-Ed. By using shorter homologs, it was shown that the T-cell response was focused predominantly on the region at the N-terminal end of the peptide encompassed by residues 306 to 319. Individual clones recognizing this region differed in their absolute requirements for residues at the extremities of the site and also in their patterns of efficiency of recognition of shorter homologs. One particular clone defined another site of T-cell recognition within residues 314 to 328. The response of the clones to peptide analogs identified certain residues within the sites that were critical for recognition, with the substitution Gln-311----Ser having a differential effect on clones responding to the N-terminal site. Only one of the clones responded well to influenza virus itself. This clone also required relatively low concentrations of the parent peptide for optimum stimulation and was suppressed by higher concentrations. The data demonstrate striking heterogeneity in the T-cell response even to a short synthetic peptide, with different T-cell clones recognizing slightly different but overlapping areas of the molecule.     

Enhanced Immunogenicity of Stabilized Trimeric Soluble Influenza Hemagglutinin

Background

The recent swine-origin H1N1 pandemic illustrates the need to develop improved procedures for rapid production of influenza vaccines. One alternative to the current egg-based manufacture of influenza vaccine is to produce a hemagglutinin (HA) subunit vaccine using a recombinant expression system with the potential for high protein yields, ease of cloning new antigenic variants, and an established safety record in humans.

Methodology/Principal Findings

We generated a soluble HA (sHA), derived from the H3N2 virus A/Aichi/2/68, modified at the C-terminus with a GCN4pII trimerization repeat to stabilize the native trimeric structure of HA. When expressed in the baculovirus system, the modified sHA formed native trimers. In contrast, the unmodified sHA was found to present epitopes recognized by a low-pH conformation specific monoclonal antibody. We found that mice primed and boosted with 3 µg of trimeric sHA in the absence of adjuvants had significantly higher IgG and HAI titers than mice that received the unmodified sHA. This correlated with an increased survival and reduced body weight loss following lethal challenge with mouse-adapted A/Aichi/2/68 virus. In addition, mice receiving a single vaccination of the trimeric sHA in the absence of adjuvants had improved survival and body weight loss compared to mice vaccinated with the unmodified sHA.

Conclusions/Significance

Our data indicate that the recombinant trimeric sHA presents native trimeric epitopes while the unmodified sHA presents epitopes not exposed in the native HA molecule. The epitopes presented in the unmodified sHA constitute a “silent face” which may skew the antibody response to epitopes not accessible in live virus at neutral pH. The results demonstrate that the trimeric sHA is a more effective influenza vaccine candidate and emphasize the importance of structure-based antigen design in improving recombinant HA vaccines.     

Antigen-specific inhibition of CD4+ T-cell responses to β-lactoglobulin by its single amino acid-substituted mutant form through T-cell receptor antagonism

T cell responses can be antagonized by some single amino acid-substituted analogs of a peptide ligand for T-cell receptors (TCR), and these are called TCR antagonists. In this study, we addressed the question of whether TCR antagonism can be elicited by a whole protein antigen carrying a mutated T-cell determinant region corresponding to a TCR antagonist peptide. To clarify this, we examined the ability of a single amino acid-substituted mutant form of bovine β-lactoglobulin (β-Lg) to inhibit three CD4⁺ T-cell clones recognizing a peptide corresponding to an immunodominant determinant region 119-133 of β-Lg (p119-133). First, we identified pD129A, an analog of p119-133 with a substitution of Ala for ¹²⁹Asp, as an antagonist which can inhibit the response of two of the three T-cell clones. Then, using a yeast expression system, we prepared a mutant β-Lg (mutD129A) with the same substitution of Ala for ¹²⁹Asp as that in pD129A. This mutant protein could inhibit the proliferation of the two T-cell clones in a manner similar to the effect of pD129A. From these results we can demonstrate that TCR antagonism can be elicited by peptides naturally processed from a single-substituted mutant protein as well as by the corresponding peptides added exogenously. This revised version was published online in June 2006 with corrections to the Cover Date.     

Reactivity of human convalescent sera with influenza virus hemagglutinin protein mutants at antigenic site A

How the antibodies of individual convalescent human sera bind to each amino acid residue at the antigenic sites of hemagglutinin (HA) of influenza viruses, and how the antigenic drift strains of influenza viruses are selected by human sera, is not well understood. In our previous study, it was found by a binding assay with a chimeric HA between A/Kamata/14/91 (Ka/91) and A/Aichi/2/68 that convalescent human sera, following Ka/91 like (H3N2) virus infection, bind to antigenic site A of Ka/91 HA. Here using chimeric HAs possessing single amino acid substitutions at site A, it was determined how those human sera recognize each amino acid residue at antigenic site A. It was found that the capacity of human sera to recognize amino acid substitutions at site A differs from one person to another and that some amino acid substitutions result in all convalescent human sera losing their binding capacity. Among these amino acid substitutions, certain ones might be selected by chance, thus creating successive antigenic drift. Phylogenetic analysis of the drift strains of Ka/91 showed amino acid substitutions at positions 133, 135 and 145 were on the main stream of the phylogenetic tree. Indeed, all of the investigated convalescent sera failed to recognize one of them.     

The structure of an antigenic determinant in a protein

The immunogenic and antigenic determinants of a synthetic peptide and the corresponding antigenic determinants in the parent protein have been elucidated. Four determinants have been defined by reactivity of a large panel of antipeptide monoclonal antibodies with short, overlapping peptides (7-28 amino acids), the immunizing peptide (36 amino acids), and the intact parent protein (the influenza virus hemagglutinin, HA). The majority of the antipeptide antibodies that also react strongly with the intact protein recognize one specific nine amino acid sequence. This immunodominant peptide determinant is located in the subunit interface in the HA trimeric structure. The relative inaccessibility of this site implies that antibody binding to the protein is to a more unfolded HA conformation. This antigenic determinant differs from those previously described for the hemagglutinin and clearly demonstrates the ability of synthetic peptides to generate antibodies that interact with regions of the protein not immunogenic or generally accessible when the protein is the immunogen.     

Induction of human cytotoxic T lymphocytes that preferentially recognise tumour cells bearing a conformational p53 mutant

 The tumour-suppressor gene p53 is pivotal in the regulation of apoptosis, and point mutations within p53 are the commonest genetic alterations in human cancers. Cytotoxic T lymphocytes (CTL) recognise peptide-MHC complexes on the surface of tumour cells and bring about lysis. Therefore, p53-derived peptides are potential candidates for immunisation strategies designed to induce antitumour CTL in patients. Conformational changes in the p53 protein, generated as a result of point mutations, frequently expose the 240 epitope, RHSVV (amino acids 212–217), which may be processed differently from the wild-type protein resulting in an altered MHC-associated peptide repertoire recognised by tumour-specific CTL. In this study 42 peptides (37 overlapping nonameric peptides, from amino acids 193–237 and peptides 186–194, 187–197, 188–197, 263–272, 264–272, possessing binding motifs for HLA-A2) derived from the wild-type p53 protein sequence were assayed for their ability to stabilise HLA-A2 molecules in MHC class I stabilisation assays. Of the peptides tested, 24 stabilised HLA-A2 molecules with high affinity (fluorescence ratio>1.5) at 26 °C, and five (187–197, 193–200, 217–224, 263–272 and 264–272) also stabilised the complexes at 37 °C. Peptides 188–197, 196–203 and 217–225 have not previously been identified as binders of HLA-A2 molecules and, of these, peptide 217–225 stabilised HLA-A2 molecules with the highest fluorescence ratio. Peptide 217–225 was chosen to generate HLA-A2-restricted CTL in vitro; peptide 264–272 was used as a positive control. The two primary CTL thus generated (CTL-217 using peptide 217–225; and CTL-264 using peptide 264–272) were capable of specifically killing peptide-pulsed T2 or JY cells. In order to determine whether these peptides were endogenously processed and to test the hypothesis that mutants expressing different protein conformations would generate an alternative peptide repertoire at the cell surface, a panel of target cells was generated. HLA-A2⁺ SaOs-2 cells were transfected with p53 cDNA containing point mutations at either position 175 (R → H) or 273 (R → H) (SaOs-2/175 and SaOs-2/273). Two HLA-A2-negative cell lines, A431 and SKBr3, naturally expressing p53 mutations at positions 273 and 175 respectively, were transfected with a cDNA encoding HLA-A2. The results showed that primary CTL generated in response to both peptides were capable of killing SaOs-2/175 and SKBr3-A2 cells, which possess the same mutation, but not SaOs-2/273, A431-A2 or SKBr3 cells transfected with control vector. This suggests that these peptides are presented on the surface of SaOs-2/175 and SKBr3-A2 cells in a conformation-dependent manner and represent potentially useful target peptides for immunotherapy. Received: 23 March 2000 / Accepted: 22 June 2000     

Adjustment of receptor-binding and neuraminidase substrate specificties in avian–human reassortant influenza viruses

Balanced action of hemagglutinin (HA) and neuraminidase (NA) is an important condition of influenza virus efficient replication, but a role of HA and NA specificities at oligosaccharide level in maintaining such a balance remains poorly studied. Avian virus HA binds exclusively and NA digests efficiently α2–3-sialylated carbohydrate chains, while human virus HA interacts with α2–6 chains and low-active NA cleaves both α2–3- and α2–6-sialosides. Reassortment between viruses leading to appearance of avian virus HA and human virus NA on the virion surface often resulted in decreasing the replicative potential of the formed variants because of disturbance of a functional balance between “alien” HA and NA. A restoration of the reassortant productivity happened due to the appearance of amino acid substitutions in HA and, sometimes, NA. Here, a role of NA and HA oligosaccharide specificities in a restoration of HA–NA functional balance in high-yield passage variants was studied. Postreassortment changes in HA receptor-binding and NA substrate specificities for three reassortant/passage variant virus pairs towards 3′SiaLac, 3′SiaLacNAc, SiaLe^c, SiaLe^a, SiaLe^x, 6′SiaLac, and 6′SiaLacNAc were determined. Selection of the high-yield variants of the human-avian reassortants led either to twofold decrease in the affinity of HA for most α2–3-sialosides and the appearance of affinity for α2–6-sialosides (H3N2 reassortant), or to decreasing the HA affinity for SiaLe^c and SiaLe^a (H3N1 reassortant), or to enhancing the ability of NA to discriminate between α2–3/2–6 substrates (H4N1 reassortant). Thus, all postreassortment changes in oligosaccharide specificities of “alien” HA and NA were directed towards their adjustment to each other, but by different manner.