Silencing of immunodominant epitopes by contiguous sequences in complex synthetic peptides.

We have previously shown that the T cell response to the synthetic peptide cI12-26:NP365-380 (covalently linked epitopes of lambda repressor (cI) and influenza A nucleoprotein (NP) polypeptides) requires amino acid sequences located in the junctional region between the cI12-26 and NP365-380 epitopes in the H-2d and H-2k haplotypes. In this study, we show that the dominant epitope of cI12-26:NP365-380 in H-2b mice is also located within the junctional region of the peptide, indicating that the same amino acid sequence is immunodominant in three different H-2 haplotypes. Based on results using fixed APC, there was no qualitative difference in epitope recognition due to antigen processing. In addition, antigen presentation by APC expressing mutant I-A molecules constructed by hemiexon shuffling of regions of the molecule containing primarily beta sheet or alpha helix showed that many different substitutions were permissive for at least one of the T hybridomas. More importantly, however, when the junctional sequences are covalently linked in composite synthetic peptides containing additional previously defined T cell epitopes, antigenicity of the immunodominant junctional region was silenced and a new epitope assumed immunodominance. Thus, immunodominance does not correlate with the primary amino acid sequence of the potential epitope. Instead, the immunodominant epitope is determined by complex interactions among the epitopes, which most likely depend on the structural conformation of the composite peptide.     

T cell recognition of allopeptides in context of syngeneic MHC.

We have analyzed the ability of T cells to recognize peptides corresponding in sequence to an allogeneic HLA-DR molecule, in context of syngeneic MHC. PBMC from a responder with the HLA-DR beta 1*1101/DR beta 1*1201 genotype were stimulated in vitro with a mixture of four synthetic peptides derived from the first domain of the DR beta 1*0101 chain (amino acid residue 1-20, 21-42, 43-62, and 66-90). An alloreactive T cell line, TCL-LS, which proliferates only in response to peptide 21-42 presented by HLA-DR beta 1*1101, was obtained. The blastogenic response of the line was inhibited by anti-HLA-DR and CD4 antibodies but was not affected by antibodies to HLA-DQ, HLA-DP, HLA-ABC, and CD8. In the presence of irradiated, autologous APC, TCL-LS displayed specific proliferative responses to stimulating cells obtained from individuals carrying the DR beta 1*0101 allele. In the absence of autologous APC, TCL-LS recognized HLA-DR1 on allogeneic cells only when expressed together with HLA-DR beta 1*1101, the restrictive element. This indicates that TCL-LS recognizes processed HLA-DR1 molecule presented as nominal Ag. Study of TCR-V beta gene repertoire expressed by TCL-LS showed that only two V beta genes were used (V beta 13.2 and V beta 12). Two T cell clones (TCC) derived from this line, TCC-A5 and B4, exhibited a similar pattern of reactivity and expressed V beta 13.2. These results indicate that T cells recognizing peptides, which are derived from the breakdown of allogeneic MHC class II proteins and are presented by self-HLA-DR molecules, participate in allorecognition.     

Selection of the same major T cell determinants of influenza nucleoprotein after vaccination or exposure to infectious virus.

In the present study, we have compared the T cell antigenic determinants on nucleoprotein (NP) of influenza A/NT/60/68 virus recognized by BALB/c mice (H-2d) after vaccination using several different vehicles with the determinants recognized after exposure to infectious virus. Mice were immunized s.c. with: 1) purified recombinant NP with three different adjuvants--alum, saponin, or CFA; 2) whole inactivated A/Okuda virus in PBS or saponin; or 3) live attenuated Salmonella typhimurium AroA- vector expressing NP. A series of overlapping synthetic peptides that cover more than 90% of the amino acid sequence of NP were used to map the Th cell epitopes. The results showed that the same limited number of major epitopes were recognized after each of the different immunization regimes. Secondary in vivo boosting using the same vehicles as for the primary immunization did not increase the number of different T cell sites recognized. The T cell responses after intranasal infection with infectious A/NT/60/68 or A/PR/8/34 virus also showed a similar pattern of recognition of the major CD4-positive T cell epitopes. The only exception was that the region corresponding to residues 401-419 was only recognized after exposure to NP from A/NT/60/68 but not A/PR/8/34. This is probably because the two viruses differ in amino acid sequence at positions 408 and 411 within this part of the NP molecule. In contrast to the results observed with CD4-positive T cell epitopes, the major determinant recognized by CD8-positive T cells was only presented after live viral infection. The results in this study have important implications for vaccine design, inasmuch as they indicate that the same dominant CD4 T cell determinants on NP presented by vaccination with NP are also recognized by T cells from mice exposed to infectious virus.     

Human T cell clones present antigen

Two human T cells clones are described which react with influenza virus hemagglutinin type H3 and synthetic peptides of H3 when presented by PBMC APC. Both T cell clones also responded to peptide Ag in the absence of additional APC suggesting that T cells can simultaneously present and respond to Ag. T cell clones could only present peptide Ag and not an appropriate strain of inactivated whole influenza virus thus indicating an inability to process Ag conventionally. Peptide presentation by T cells was dose dependent, restricted by MHC class II Ag and was dependent on the number of Ag presenting T cells per culture. Experiments with nested peptides showed that the same epitope was recognized in the presence and absence of PBMC APC. No Ag or IL-2 from the propagation procedure was carried over into assays and two-color fluorescence-activated cell sorter analysis of each clone detected no contaminating cells with the phenotype of monocytes, macrophages or B cells; in each T cell clone, all cells expressing MHC class II Ag co-expressed CD3. These date therefore provide strong evidence that human T cell clones can simultaneously present and respond to appropriate forms of Ag.     

Role of APC in the selection of immunodominant T cell epitopes

Following antigenic challenge, MHC-restricted T cell responses are directed against a few dominant antigenic epitopes. Here, evidence is provided demonstrating the importance of APC in modulating the hierarchy of MHC class II-restricted T cell responses. Biochemical analysis of class II:peptide complexes in B cells revealed the presentation of a hierarchy of peptides derived from the Ig self Ag. Functional studies of kappa peptide:class II complexes from these cells indicated that nearly 20-fold more of an immunodominant epitope derived from kappa L chains was bound to class II DR4 compared with a subdominant epitope from this same Ag. In vivo, T cell responses were preferentially directed against the dominant kappa epitope as shown using Ig-primed DR4 transgenic mice. The bias in kappa epitope presentation was not linked to differences in class II:kappa peptide-binding affinity or epitope editing by HLA-DM. Rather, changes in native Ag structure were found to disrupt presentation of the immunodominant but not the subdominant kappa epitope; Ag refolding restored kappa epitope presentation. Thus, Ag tertiary conformation along with processing reactions within APC contribute to the selective presentation of a hierarchy of epitopes by MHC class II molecules.     

Prediction and identification of T cell epitopes in the H5N1 influenza virus nucleoprotein in chicken

T cell epitopes can be used for the accurate monitoring of avian influenza virus (AIV) immune responses and the rational design of vaccines. No T cell epitopes have been previously identified in the H5N1 AIV virus nucleoprotein (NP) in chickens. For the first time, this study used homology modelling techniques to construct three-dimensional structures of the peptide-binding domains of chicken MHC class Ι molecules for four commonly encountered unique haplotypes, i.e., B4, B12, B15, and B19. H5N1 AIV NP was computationally parsed into octapeptides or nonapeptides according to the peptide-binding motifs of MHC class I molecules of the B4, B12, B15 and B19 haplotypes. Seventy-five peptide sequences were modelled and their MHC class I molecule-binding abilities were analysed by molecular docking. Twenty-five peptides (Ten for B4, six for B12, two for B15, and seven for B19) were predicted to be potential T cell epitopes in chicken. Nine of these peptides and one unrelated peptide were manually synthesized and their T cell responses were tested in vitro. Spleen lymphocytes were collected from SPF chickens that had been immunised with a NP-expression plasmid, pCAGGS-NP, and they were stimulated using the synthesized peptides. The secretion of chicken IFN-γ and the proliferation of CD8(+) T cells were tested using an ELISA kit and flow cytometry, respectively. The significant secretion of chicken IFN-γ and proliferation of CD8(+) T lymphocytes increased by 13.7% and 11.9% were monitored in cells stimulated with peptides NP(89-97) and NP(198-206), respectively. The results indicate that peptides NP(89-97) (PKKTGGPIY) and NP(198-206) (KRGINDRNF) are NP T cell epitopes in chicken of certain haplotypes. The method used in this investigation is applicable to predicting T cell epitopes for other antigens in chicken, while this study also extends our understanding of the mechanisms of the immune response to AIV in chicken.     

Immunodominance: intramolecular competition between T cell epitopes.

We have used an approach of linking previously characterized T cell epitopes into immunologically complex synthetic peptides in order to investigate the mechanism of immunodominance. Our results show that first, cI12-26 is highly dominant following immunization with the lambda repressor (cI) protein, but is a minor epitope in the context of the cI:NP peptide. In contrast, the dominant epitope in response to the cI:NP peptide is a new junctional epitope, which is composed of sequences derived from both the cI and influenza nucleoprotein (NP) segments of the composite peptide. Second, T cell recognition of cI:NP is not significantly altered by Ag processing, based on results from glutaraldehyde-fixed APC. Third, the relative affinities of cI and cI:NP for MHC binding are similar, based on in vitro competition, excluding competition at the level of MHC binding as the determinant of immunodominance. Taken together, these results are consistent with the hypothesis that immunodominance of cI:NP is determined by peptide conformation, which affects the configuration of peptide binding to MHC, thus altering T cell recognition. In conclusion, immunodominance is not simply a function of the primary amino acid sequence, but is a function of the context of the epitope within the protein molecule.     

Comparative study of the T cell response to two allelic forms of a malarial vaccine candidate protein.

T cell responses to two allelic forms of the merozoite surface Ag 2 (MSA2) of Plasmodium falciparum were mapped in mice using the rMSA2 proteins, Ag 1609 which has the sequence of the FCQ27/PNG strain and Ag 1615 which has the sequence of the Indochina 1 strain. Lymph node cells of BL/10 and B10.BR mice immunized with either Ag 1609 or Ag 1615 responded to both Ag in in vitro proliferation assays. Lymph node cells of BALB/c mice did not respond. The T cell determinants recognized by the responder strains were mapped to conserved and variant regions of these Ag using overlapping synthetic peptides. The determinants recognized by each mouse strain were distinct. Marked difference in sequence between the central regions of the two rMSA2 proteins did not affect antigenic processing of the conserved N and C terminal regions. Hence lymph node cells of BL/10 mice immunized with either Ag 1615 or Ag 1609 recognized an immunodominant T cell determinant at the highly conserved N terminal end within the sequence YSNTFINNAYNMSIR (peptide 3b) and B10.BR mice similarly immunized recognized an immunodominant determinant at the highly conserved C terminal within the sequence CTDGNKENCGAATSL (peptide 23). Several peptides identified as containing immunodominant T cell determinants specific to BL/10 mice induced peptide-specific T cells in both BL/10 and B10.BR mouse strains when used as immunogens. However, the ability of the peptide-primed T cells to proliferate in response to the rMSA2 proteins was confined to BL/10 mice. An example of this was observed with peptides 3b and N (KNESKYSNTFINNAYNMSIRRSMAN). Peptide N was able to prime B10.BR and BL/10 mice for an enhanced antibody response when these mice were subsequently immunized with Ag 1615 even though Ag 1615-specific T cell proliferation was not detected in B10.BR mice primed with N. The study concluded that 1) conserved sequences such as peptide N when used in vaccines may give rise to MSA2-specific memory Th cells amenable to boosting by subsequent exposure to all parasite strains and 2) peptide priming may be a useful pathway for inducing defined memory Th cells in a wider population and for preferentially inducing T dependent over T independent responses to some malarial Ag.     

Diversity in MHC class II ovalbumin T cell epitopes generated by distinct proteases.

It is generally accepted that a limited number of T cell epitopes are generated by APC from an immunogenic protein. To ascertain the number of determinants on OVA recognized in the context of the H-2s haplotype, we generated 19 T-T hybridomas against OVA and H-2s and we synthesized 46 overlapping peptides spanning the entire protein. Eighteen T-T hybrids were stimulated by eight different peptides. The peptide recognized by one T cell hybrid was not identified. The effect of four protease inhibitors on the processing and presentation of OVA by the LS.102.9 B cell hybridoma seemed to implicate several groups of proteases in the processing of this Ag. Alkylation of cysteine residues with iodoacetic acid showed in a few cases a dramatic decrease in the capacity of OVA to stimulate T-T hybrids recognizing cysteine-free peptides. In contrast, two T-T hybrids recognizing cysteine containing peptides were not affected by the alkylation, suggesting that alkylation inhibited the processing of OVA without affecting peptide interaction with class II MHC molecules. These data demonstrate that the repertoire of peptides generated by APC from OVA is not limited to one or few immunodominant peptides, and results from the activity of several endopeptidases and/or exopeptidases. In addition, the structure of the Ag (native or denatured) was shown to affect the efficiency with which different epitopes are generated.     

Structural model of HLA-DR1 restricted T cell antigen recognition

Two human helper T cell determinants in influenza have been identified, one in the hemagglutinin and the other in the matrix protein (M1). Both were shown to be DR1 restricted by using transfected L cells to present antigen. Comparison of the sequences of the two peptides revealed a similar pattern that could account for their DR1 specificity if the peptides adopt a helical conformation. The model was supported by the demonstration that hybrid peptides, composed of the amino acids that interact with DR1 from one determinant and the residues that interact with the T cell receptor from the other, were recognized by each clone. The generality of the motif was confirmed by the finding that DR1 individuals respond to a ragweed peptide containing the defined pattern.     

Purified HLA class II peptide complexes can induce adherence and activation of peptide-specific human T cell clones.

An initial event in T cell activation is the specific adherence of T cells via their T cell receptor to the MHC peptide complex. We have studied this adherence by incubating T cells with preformed HLA DR4Dw4 peptide complexes attached to a solid support. Adherence of sodium 51Cr-labeled T cell clones specific for the influenza hemagglutinin peptide, HA 307-319, was maximal after 15 min and was specific for the HLA DR4Dw4-HA 307-319 complex. The binding was temperature dependent and could be blocked with azide or protein kinase C inhibitors, indicating that for adherence the T cells need to be metabolically active and have a functioning protein kinase C pathway. The adherence could be blocked with CD4- or CD3-reactive murine mAb, suggesting that the TCR and CD4 molecules work in concert to induce strong adherence to the HLA DR4Dw4-HA 307-319 complex. A subsequent event in T cell activation is proliferation, which is thought to need additional proteins such as IL-1 or other adhesion molecules. MHC peptide complexes coated on microtiter plates also induced proliferation in the human T cell clones. Removal of any monocytes by treatment of human T cell clones with anti-CD14 in conjunction with C, followed by purification over a nylon wool column, did not abrogate proliferation. After prolonged culture of the T cell clones in plates coated with peptide-pulsed HLA DR4Dw4 in the presence of IL-2, the T cell clones continued to proliferate in response to peptide. These results suggest that human T cell clones do not require a second signal from a monocyte or other APC to proliferate.     

Vaccination with an acidic polymerase epitope of influenza virus elicits a potent antiviral T cell response but delayed clearance of an influenza virus challenge

The mechanisms underlying epitope selection and the potential impact of immunodominance hierarchies on peptide-based vaccines are not well understood. Recently, we have shown that two immunodominant MHC class I-restricted epitopes, NP(366-374)/D(b) (nucleoprotein (NP)) and PA(224-233)/D(b) (acidic polymerase (PA)), which drive the CD8(+) T cell response to influenza virus infection in C57BL/6 mice, are differentially expressed on infected cells. Whereas NP appears to be strongly expressed on all infected cells, PA appears to be strongly expressed on dendritic cells but only weakly expressed on nondendritic cells. Thus, the immune response to influenza virus may involve T cells specific for epitopes, such as PA, that are poorly expressed at the site of infection. To examine the consequences of differential Ag presentation on peptide vaccination, we compared the kinetics of the T cell response and influenza virus clearance in mice vaccinated with the NP or PA peptide. Vaccination with either the NP or PA peptide resulted in accelerated and enhanced Ag-specific T cell responses at the site of infection following influenza virus challenge. These T cells were fully functional in terms of their ability to produce IFN-gamma and TNF-alpha and to mediate cytolytic activity. Despite this enhancement of the Ag-specific T cell response, PA vaccination had a detrimental effect on the clearance of influenza virus compared with unvaccinated or NP-vaccinated mice. These data suggest that differential Ag presentation impacts the efficacy of T cell responses to specific epitopes and that this needs to be considered for the development of peptide-based vaccination strategies.     

Myasthenia gravis. T epitopes on the delta subunit of human muscle acetylcholine receptor.

Autoimmune T cell lines specific for muscle nicotinic acetylcholine receptor (AChR) were propagated from the blood of three myasthenia gravis patients by the use of a pool of synthetic peptides (delta-pool) corresponding to the complete sequence of the delta-subunit of human muscle AChR. Propagation of AChR-specific T cell lines was attempted unsuccessfully from four other myasthenia gravis patients and from four healthy controls. The lines had CD3+, CD4+, CD8- phenotype, strongly recognized the delta-pool, and cross-reacted vigorously with non-denatured AChR purified from mammalian muscle. They did not cross-react detectably with pools of similar overlapping synthetic peptides corresponding to the complete sequences of the alpha- and gamma-subunits of human muscle AChR. The sequence segments of the delta-subunit that contain T epitopes were identified by investigating the response of the three CD4+ T cell lines to the individual synthetic peptides forming the delta-pool. Each line had an individual pattern of peptide recognition. Although no immunodominant region, recognized in association with different DR haplotypes, could be identified, the sequence segments most strongly recognized by the CD4+ T cell lines were clustered within residues 121-290. One of the peptides more strongly recognized by the T cells corresponded to a sequence segment with high predicted propensity to form an amphipathic alpha-helix, a structural motif proposed to be typical of T epitopes.     

Identification of residues necessary for clonally specific recognition of a cytotoxic T cell determinant.

The residues in an influenza nucleoprotein (NP) cytotoxic T cell determinant necessary for cytotoxic T cell (CTL) recognition, were identified by assaying the ability of hybrid peptides to sensitize a target cell to lysis. The hybrid peptides were formed by substituting amino acids from one determinant (influenza NP 147-158) for the corresponding residues of a second peptide (HLA CW3 171-182) capable of binding to a common class I protein (H-2Kd). Six amino acids resulted in partial recognition; however, the presence of a seventh improved the potency of the peptide. Five of the six amino acids were shown to be required for recognition. The spacing of the six amino acids was consistent with the peptide adopting a helical conformation when bound. The importance of each amino acid in CTL recognition and binding to the restriction element was investigated further by assaying the ability of peptides containing point substitutions either to sensitize target cells or to compete with the natural NP sequence for recognition by CTL. The T cell response was much more sensitive to substitution than the ability of the peptide to bind the restriction element. Collectively the separate strategies identified an approximate conformation and orientation of the peptide when part of the complex and permitted a potential location in the MHC binding site to be identified. The model provides a rationalization for analogues which have previously been shown to exhibit greater affinity for the class I molecule and suggests that the binding site in major histocompatibility complex (MHC) class I molecules might have greater steric constraints that the corresponding area of class II proteins.     

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.     

Competition between unrelated peptides recognized by H-2-Kd restricted T cells

P815 (H-2d) target cells incubated with synthetic peptides corresponding to region 170-182 of HLA or to region 141-161 of influenza nucleoprotein (NP) are lysed by DBA/2 derived cytolytic T cells (CTL) specific for HLA or by BALB/c derived CTL-specific for NP, respectively. Both peptide Ag are recognized in the context of Kd. We show herein that these unrelated, nonhomologous peptides clearly compete reciprocally for recognition by the appropriate Kd restricted CTL. In contrast, different NP peptides that are recognized by other CTL restricted by HLA-B37, H-2-Db or KK, either failed to compete or were much less efficient as competitors than NP peptides recognized in the context of Kd. The efficiency of a peptide as a competitor correlated with its potency as an Ag. The most efficient competitor was a variant peptide of NP 147-158 with R156 deleted, which had been previously shown to be 1,000 times more efficient as an Ag than its natural homolog. Our results suggest that peptides recognized by CTL in the context of the same MHC class I restriction element may bind to the same or interdependent site(s) on the restriction molecule.     

Antigen analog-major histocompatibility complexes act as antagonists of the T cell receptor.

A novel mechanism for inhibition of T cell responses is described. Using the recognition of the influenza hemagglutinin (HA) 307-319 peptide in the context of DR1 class II major histocompatibility complex molecules, we have found that nonstimulatory analogs of the HA peptide preferentially inhibit HA-specific T cells in inhibition of antigen presentation assays. This antigen-specific effect could be generalized to another DR1-restricted peptide, Tetanus toxoid 830-843. Direct binding and cellular experiments indicated that the mechanism responsible was distinct from competition for binding to DR1 molecules. Likewise, negative signaling and induction of T cell tolerance could also be excluded as effector mechanisms. Thus, the most likely mechanism for this effect is engagement of antigen-specific T cell receptors by DR1-peptide analog complexes, which results in antigen-specific competitive blocking of T cell responses by virtue of their capacity to compete with DR1-antigen complexes for binding to the T cell receptor.     

T cell recognition of HIV synthetic peptides in a natural infection

Because T cell responses are critical for defense against viral infections, a series of synthetic peptides derived from the predicted sequence for HIV-1 proteins gp41, pg120, gag, and viral polymerase were used to test the T cell proliferative response of HIV-1 seropositive individuals. Of HIV-1-infected donors from various clinical categories 90% (27/30) had sensitized cells that proliferated in response to at least one of 21 HIV peptides tested. Cells from HIV seronegative controls did not proliferate (0/9) in response to these HIV peptides. Individuals with fewer clinical manifestations of HIV-1 disease responded to a greater number of peptides (average for asymptomatic seropositives = 8.1 peptides; AIDS patients averaged 2.0). The number of peptides recognized also correlated with absolute number of CD4+ cells, but not with delayed cutaneous hypersensitivity to a (non-HIV) battery of Ag. However, clinical stage at no time correlated with the response to any particular peptide. Response patterns differed considerably among individuals, and some peptides stimulated proliferation in many (48%) HIV-infected donors (peptides gp41-2 and pol-3), whereas another peptide elicited no T cell response in any donor tested (peptide gp120-8). We have also begun to investigate the basis for individual heterogeneity of T lymphocyte proliferative responses of HIV-infected donors to the 21 HIV synthetic peptides. Peptide structure and HLA class II determinants both influenced patterns of lymphocyte responses. Reactivity correlated with peptide size, the presence of alpha and beta secondary structure and lack of reverse turn potential. Hydropathy and charge had no predictive value. Peptides derived from HIV sequences that vary highly among strains tended to be recognized less frequently. HIV-infected lymphocyte donors were HLA typed to examine the influence of the MHC on T lymphocyte proliferation. Analysis of the frequencies of individuals reacting to specific peptides, when compared to the allele frequencies in the population at large, indicated association of some responses to DR alleles. More DR association was observed with peptides that showed "moderate" reactivity than with those that were "highly" reactive. We suggest that highly reactive peptides are capable of forming a structure closer to an "ideal" T cell epitope that can associate with many DR alleles. In contrast, "moderately" reactive determinants have less favorable structures for interaction, are more limited in their ability to interact and therefore show more restriction to specific class II alleles.     

Genetic variability in HIV-1 gp120 affects interactions with HLA molecules and T cell receptor

The propensity of HIV-1 to undergo sequence variation, particularly in the envelope glycoprotein gp120, complicates vaccine development and may enable the virus to evade ongoing immune responses in infected individuals. We present here a molecular analysis of the effects of this variability on human T cell recognition of HIV-1 gp120. Synthetic peptides representing a defined CD4+ human T cell epitope in gp120 were used to survey gp120 molecules from various HIV-1 strains for the capacity to be recognized in the context of a single human MHC molecule, DR4. Variation affected recognition at two levels. For some strains, variation in this epitope was sufficient to alter the interaction of Ag receptors on gp120-specific human T cell clones with peptide-DR4 complexes on APC. In the case of two strains, the natural variation was sufficient to prevent the critical initial interaction between the relevant gp120 peptides and DR4 on the APC. However, these strains were highly divergent from the reference strain. Thus it is encouraging to note that the range of natural sequence variation in this T cell epitope falls, for the most part, within the range of peptide sequences that can be accommodated by the relevant human MHC molecule.     

Identification and characterization of T helper epitopes in the nucleoprotein of influenza A virus

By using a series of overlapping synthetic peptides that cover more than 95% of the amino acid sequence of nucleoprotein (NP) of influenza A/NT/60/68 virus, five Th cell epitopes in B10.S (H-2s), BALB/c (H-2d), CBA (H-2k), and B6 (H-2b) mice have been identified. The specificity of Th cell recognition of epitopes is largely dependent on the H-2 haplotype of the responding mouse strain. However, two out of the five Th epitopes defined could be recognized by mice of more than one haplotype, implying that the primary sequence of protein antigens could also influence the selection of dominant T cell epitopes by the immune system. Immunization of B10.S mice with peptide 260-283 generated strong Th cell response against type A influenza viruses. In the other three strains of mice tested, priming with helper peptides induced a stronger antipeptide than antiviral T cell response. However, the low responsiveness to virus in these mice could be partially overcome by immunization with a mixture of several helper peptides. The Th epitopes are defined by the ability of the peptides to stimulate class II MHC restricted CD4+ T cells to proliferate and to produce IL-2 in vitro. When compared with the known epitopes on NP recognised by class I restricted CD8+ cytotoxic T cells, it appears that Th and cytotoxic T cell epitopes are nonoverlapping. The AMPHI and Motifs methods were employed to analyze the sequence of NP and predict the potential dominant sites in the molecule. The predictions are compared with the experimental data obtained and the implications discussed.