Universally immunogenic T cell epitopes: promiscuous binding to human MHC class II and promiscuous recognition by T cells

To understand the effect of human MHC class II polymorphism on antigen recognition, we analyzed the memory T cell response to three tetanus toxin epitopes defined by three short synthetic peptides (p2, p4 and p30). We found that p2 and p30 are universally immunogenic, since they are recognized by all primed donors, irrespective of their MHC haplotypes. The analysis of specific clones indicates that both peptides are very promiscuous in their capacity to bind to class II. p30 can be recognized in association with DRw11(5), 7, 9 and with DPw2 and DPw4, while p2 can be recognized in association with DR1, DRw15(2), DRw18 (3), DR4Dw4, DRw11(5), DRw13(w6), DR7, DRw8, DR9, DRw52a and DRw52b. On the contrary, the third peptide, p4, can be recognized by only half of the donors in association with only DRw52a and DRw52c. Analysis of truncated peptides shows that p30 contains three distinct epitopes, each recognized in association with different class II molecules. Therefore, the restriction specificity is already set at the level of the peptide-MHC complex and, in all cases, T cells discriminate p30 bound to different class II molecules. On the contrary, p2 contains only one epitope, which is recognized in association with all DR molecules. In this case we found two different restriction patterns. Some clones are monogamous, since they recognize the peptide in association with one DR allele, while others are promiscuous, since they recognize by peptide in association with several different DR molecules. Thus, in this case, the restriction specificity is also set at the level of the T cell receptor. We suggest that both the promiscuous binding of peptides and the promiscuous recognition by T cells are dependent on the particular structure of the DR molecules, having a monomorphic alpha chain associated with a polymorphic beta chain.     

DR αβ dimers released from complexes with invariant chain fail to stimulate alloreactive T cell clones

To demonstrate that DR αβ dimers still complexed to invariant chain (Ii) have not yet acquired peptides recognized by alloreactive T cells, complexes between DR molecules and Ii isolated from Epstein-Barr-virus (EBV)-transformed B cells were analyzed by affinity chromatography and gel filtration. First, it was shown that DR/Ii complexes inserted into artificial planar membranes (PM) failed to stimulate proliferative response of five alloreactive T cell clones and a polyclonal alloreactive Tcell line, while PM bearing mature DR αβ dimers from the same EBV-B cells were stimulatory for the Tcell clones and the Tcell line. These findings indicate that either Ii inhibits binding of peptides to DR molecules or Ii hinders T cells recognition of peptide/DR complexes. Second, to discriminate between these two possibilities, DR αβ dimers, which were artificially released from complexes between DR molecules and Ii, were inserted into PM. These DR αβ dimers were devoid of alloreactive stimulatory capacity while fully capable of binding and presenting a tetanus toxin synthetic peptide to a specific Tcell clone, indicating that DR molecules released from complexes with Ii are empty. This study, by showing that DR molecules bound to Ii do not bear peptides recognized by alloreactive T cells, supports the notion that association of Ii with class II major histocompatibility complex (MHC) molecules prevents premature peptide loading and hence favors encounter with peptides derived from proteins of the extracellular compartment. Since allogeneic class II MHC molecules released from complexes with Ii were not stimulatory for five out of five alloreactive Tcell clones and a polyclonal alloreactive Tcell line, these data also indicate that, in most cases, alloreactive T cells recognize ligands constituted by complexes between allogeneic class II MHC molecules and specific peptides which derive from the antigen-presenting cells themselves or serum proteins.     

The majority of HLA-DR3 alloreactive T cells is peptide specific, but does not recognize known DR3-bound sequences

Abstract: Rejection of transplants is frequently caused by activation of alloreactive T cells that recognize HLA/peptide differences between patient and graft. This T-cell response can be directed towards the HLA molecule, the HLA-bound peptide or towards a combination. More insight in the involvement of peptides in this process may help to find ways to avoid rejection using for example antagonist peptides. In recent years many naturally processed HLA-bound peptides have been identified. This raises the question of whether these, presumably abundant, peptides are involved in class ri-specific allorecognition. To investigate this, we first determined the proportion of peptide-specific alloreactive T cells in the alloresponse against HLA-DR3. For this purpose we have tested a panel of DR3-specific alloreactive T-cell clones against a DM-mutant (i.e. peptide loading deficient) cell line. We found that 59 out of 64 alloreactive T-cell clones were dependent upon the presence of DM for an optimal response. However, only 2 DM-dependent T-cell clones recognize known peptide sequences. Thus we conclude that most DR3-specific alloreactive T-cell clones are peptide specific and that the currently known DR3-bound peptides are not the main target for allorecognitioa Finally, we identified 4 T-cell clones that recognized the DM-mutant better than the wild-type cell line. The response against the wild-type cell line could not be restored with invariant chain derived peptides (CLIP). This provides additional evidence that DM can negatively select self-peptides other than CLIP, which can result in selection against peptides involved in allorecognition.     

Position 71 in the α helix of the DRβ domain is predicted to influence peptide binding and plays a central role in allorecognition

Despite all the structural and functional data that have been accumulated regarding major histocompatibility complex (MHC) class II molecules during recent years, the relative contribution of putative T cell receptor (TcR)-contacting residues and peptide-binding MHC polymorphisms to MHC-restricted and allospecific T cell responses remains a point of contention. Some authors emphasize the importance of direct interaction between the allospecific TcR and polymorphic MHC residues whereas other emphasize the role of naturally processed MHC-bound peptides. We have previously described a new HLA-DRB1 allele: DR BON (DRB1*0103). This gene differs from DRB1*0101 by six base pairs clustered in the third variable region of the second exon leading to three amino acid changes at positions 67, 70 and 71 of the β chain of the HLA-DR molecule. To define the respective role of these residues in allorecognition, we have performed site-directed mutagenesis on the DRB1*0103 allele to create six mutants which are intermediary between the DR BON and the DR1 alleles. These mutant cDNA were expressed in mouse fibroblasts and the transfectants with the highest expression of class II molecules were used as stimulators for a panel of ten anti-DR BON and five anti-DR1 alloreactive T cell clones. We demonstrate that the residue at the peptide-binding position 71 is of paramount importance in the alloresponse of these clones. In addition some clones were sensitive to amino acid substitution at the TcR-contacting position 70, while substitution at position 67 affects very few clones. The dominance of residue 71 was also observed with an influenza hemagglutinin-specific HLA-DR BON-restricted T cell line.     

Antigen-processing organelles from DRB1*1101 and DRB1*1104 B cell lines display a differential degradation activity

We have developed an in vitro assay for tetanus toxin (tt) C fragment (C-fr) degradation. Purified endosomes (abbreviated endosomes 1101 or 1104) and lysosomes (abbreviated lysosomes 1101 or 1104) from the DRB1*1101 (Gly 86) and DRB1*1104 (Val 86) B cell lines were used to degrade ¹²⁵I-labeled C-fr in vitro. Using three distinct methods of analysis, we show that the capacity of endosomes and lysosomes to degrade the tt C-fr or tt synthetic Y-P30 peptide differed. Using sodium dodecylsulfate-polyacrylamide gel electrophoresis, ¹²⁵I-labeled C-fr degradation patterns observed either with endosomes 1101/1104 or lysosomes 1101/1104 are distinct both in terms of the number of fragments and the kinetics of generation of the fragments. These results were confirmed by high-performance liquid chromatography analysis, where we observed that the elution profiles of the ¹²⁵I-labeled Y-P30 peptide digested by endosomes 1101/1104 were different compared to those obtained with lysosomes 1101/1104. Furthermore, the kinetics of degradation of ¹²⁵I-labeled Y-P30 were faster with lysosomes 1104 than with lysosomes 1101. This difference in activity of the 1101 and 1104 organelles was also found in a functional assay where we showed that the activation capacity of the P30 peptide was diminished when digested by lysosome 1104, regardless of the antigen-presenting cell (APC) used, whereas endosomes 1101 or lysosomes 1101 modified P30 peptide in a form that discriminated between presentation by 1101 or 1104 APC. Taken together, these results suggest that the differential processing and presentation displayed by the DRB1*1101 and DRB1*1104 APC is due partly to a different enzymatic content and partly to the dimorphism at position DRβ86.     

DR4Dw4/DR53 molecules contain a peptide from the autoantigen calreticulin

Abstract: Rheumatoid arthritis (RA) occurs more frequently in HLA-DR4⁺ individuals than in those who do not express this MHC class II molecule. Although the role of this genetic factor in the immunopathology of this autoimmune disease is unclear, the association of RA with HLA-DR4 may indicate that DR4 molecules present autoantigen(s) to T cells. Here we report the analysis of naturally processed peptides, eluted from a mixture of HLA-DR4Dw4 (DRB1*0401) and DR53 (DRB4* 0101) molecules isolated from an RA patient-derived EBV-transformed B cell line. Several (size variants of) self-peptides originating from the autologous molecules HLA-A2, HLA-Cw9, HLA-B62, HLA-DR4Dw4 and HLA-DR53, were identified. We also found a sequence that has no homology to any protein in the SwissProt protein sequence databank, and a peptide identical to an internal fragment of the autoantigen calreticulin. The association of the identified peptides with cells expressing HLA-DR4Dw4/DR53 was confirmed by peptide binding analysis. In agreement with previously described peptide binding motifs for DR4Dw4, most peptides contained an aromatic residue (Phe, Tyr, Trp) at relative position i and a small hydroxyl-containing residue (Ser, Thr) at i+5. Our findings indicate that in RA patient-derived EBV-transformed B cells DR4Dw4/ DR53 molecules present a peptide from the autoantigen calreticulin. Interestingly, autoantibodies against calreticulin have been found in various rheumatic diseases, including rheumatoid arthritis. Thus, the analysis of HLA class II-bound peptides can lead to the identification of putative T helper epitopes, which might be involved in the immunopathology of autoimmune diseases.     

Sharing of Four DR-β Sequence Motifs Between HLA-DRB1*1601 and DRB1*1101 Correlates with Frequent Degenerate T-Cell Recognition of HA306–320 Peptide Complexed to these Two Molecules

This paper shows that the seven HA306–320 specific T-cell clones isolated from one individual recognize the peptide complexed to both autologous HLA–DRB1*1101 and allogeneic HLA-DRB1*1601 (or DRB5*0201) molecules. For each T-cell clone, a single T-cell receptor (TCR) is involved in the recognition of these two different peptide-DR complexes as evidenced by cold target competition experiments. Yet, the seven T-cell clones express several different TCRs as judged by Vβ-Jβ usage and fine specificities. Furthermore, one representative clone has the same fine specificity for HA306–320 analogues mutated at epitopic residues irrespective of the use of DR1101 or DR1601 APC. These results suggest that structural differences between DRB1*1101 and DRB1*1601 (or DRB5*0201) do not dramatically influence the orientation of HA306–320 in the grooves such that most residues interacting with TCRs are conserved. In another individual, the same pattern of restriction, i.e. DR1101 + DR1601, was found for several HA306–320 specific clones. Two additional patterns, DR1101 + DR0801 and DR1101 + DR0801 + DR1601, were identified. By comparing DR sequences the authors found that DRB1*1101 and DRB1*1601 share four important motifs, i.e. β85–86, β67–71, β57 and β28–31 supposed to line three distinct HLA-DR pockets. Three of these motifs are also shared with DRB1*0801. All the results further support that the motif similarities allow the peptide to adopt very similar orientations in the cross-reacting DR molecules.     

Human monoclonal antibody with T-cell-like specificity recognizes MHC class I self-peptide presented by HLA-DR1 on activated cells

Abstract: Alloreactive T cells recognize peptides presented in the binding groove of major histocompatibility complex molecules (MHCs), whereas B cells mainly recognize the MHCs independent of bound peptides. Here, we demonstrate that the human B-cell repertoire comprises B cells which can be stimulated during pregnancy to produce antibodies reacting with MHCs in a way similar to T cells. The human monoclonal antibody UL-5A1 recognizes DR1PRA/DRB1*0101) molecules on lymphoblastoid cell lines only if they co-express HLA-A2 or if they have been loaded with HLA-A2-derived peptides. The effect of the HLA-A2 peptide 105–117 on UL-5A1 reactivity was specific, time and dose-dependent Reactivity increased when naturally processed peptides were removed from DR1 molecules before the HLA-A2 peptide 105–117 was loaded. UL-5A1 reacted specifically with cells that had been activated. The results imply a role of activation of cells in peptide processing and/or loading.     

Identification and HLA restriction of naturally derived Th1-cell epitopes from the secreted Mycobacterium tuberculosis antigen 85B recognized by antigen-specific human CD4(+) T-cell lines

Antigen 85B (Ag85B/MPT59) is a major secreted protein from Mycobacterium tuberculosis which is a promising candidate antigen for inclusion in novel subunit vaccines against tuberculosis (TB). The present study was undertaken to map naturally derived T-cell epitopes from M. tuberculosis Ag85B in relation to major histocompatibility complex (MHC) class II restriction. Antigen-specific CD4(+) T-cell lines were established from HLA-typed TB patients and Mycobacterium bovis BCG vaccinees by stimulation of peripheral blood mononuclear cells with purified Ag85B in vitro. The established T-cell lines were then tested for proliferation and gamma interferon (IFN-gamma) secretion in response to 31 overlapping synthetic peptides (18-mers) covering the entire sequence of the mature protein. The results showed that the epitopes recognized by T-cell lines from TB patients were scattered throughout the Ag85B sequence whereas the epitopes recognized by T-cell lines from BCG vaccinees were located toward the N-terminal part of the antigen. The T-cell epitopes represented by peptides p2 (amino acids [aa] 10 to 27), p3 (aa 19 to 36), and p11 (aa 91 to 108) were frequently recognized by antigen-specific T-cell lines from BCG vaccinees in both proliferation and IFN-gamma assays. MHC restriction analysis demonstrated that individual T-cell lines specifically recognized the complete Ag85B either in association with one of the self HLA-DRB1, DRB3, or DRB4 gene products or nonspecifically in a promiscuous manner. At the epitope level, panel studies showed that peptides p2, p3, and p11 were presented to T cells by HLA-DR-matched as well as mismatched allogeneic antigen-presenting cells, thus representing promiscuous epitopes. The identification of naturally derived peptide epitopes from the M. tuberculosis Ag85B presented to Th1 cells in the context of multiple HLA-DR molecules strongly supports the relevance of this antigen to subunit vaccine design.     

Prediction and identification of an HLA-DR-restricted T cell determinant in the 19-kDa protein of Mycobacterium tuberculosis

An allele-specific motif has been identified in the sequence of several peptides which are recognized by T cells in association with HLA-DR1. In order to test the predictive values of such a motif we analyzed the 19-kDa antigen from Mycobacterium tuberculosis and identified a sequence containing a pattern characteristic of DR1 restriction. Peripheral blood mononuclear leukocytes from every DR1 and 4 individual tested responded to the corresponding synthetic peptide. Nine other donors, constituting seven different DR alleles, failed to recognize this sequence. Recognition of the peptide in association with DR1 and DR4 was confirmed using T cell clones and transfected murine L cell lines expressing DR molecules.     

Cross-reactive recognition of human and primate cytomegalovirus sequences by human CD4 cytotoxic T lymphocytes specific for glycoprotein B and H

Although the importance of CD4+ T cell responses to human cytomegalovirus (HCMV) has recently been recognized in transplant and immunosuppressed patients, the precise specificity and nature of this response has remained largely unresolved. In the present study we have isolated CD4+ CTL which recognize epitopes from HCMV glycoproteins gB and gH in association with two different HLA-DR antigens, DRA1*0101/DRB1*0701 (DR7) and DRA1*0101/DRB1*1101 (DR11). Comparison of amino acid sequences of HCMV isolates revealed that the gB and gH epitope sequences recognized by human CD4+ T cells were not only conserved in clinical isolates from HCMV but also in CMV isolates from higher primates (chimpanzee, rhesus and baboon). Interestingly, these epitope sequences from chimpanzee, rhesus and baboon CMV are efficiently recognized by human CD4+ CTL. More importantly, we show that gB-specific T cells from humans can also efficiently lyse peptide-sensitized Patr-DR7+ cells from chimpanzees. These findings suggest that conserved gB and gH epitopes should be considered while designing a prophylactic vaccine against HCMV. In addition, they also provide a functional basis for the conservation of MHC class II lineages between humans and Old World primates and open the possibility for the use of such primate models in vaccine development against HCMV.     

Identification of single amino acid substitutions in the staphylococcal nuclease protein that enhance and diminish T cell clone recognition of naturally processed peptides.

It has been inferred that residue changes that affect T cell recognition of synthetic peptides will have a similar effect in the intact protein. However, since small peptides do not require antigen processing it is possible that residue changes in synthetic peptides will not have an equivalent effect in the intact protein. Mutant proteins of staphylococcal nuclease (Nase) and 15mer synthetic peptides with corresponding substitutions were compared to determine if residue changes within an immunodominant epitope have an effect on the generation of naturally processed peptides. Five different substitutions in the synthetic peptide resulted in loss of reactivity of individual Nase-specific clones. When the same single amino acid changes were made in the intact protein, the naturally-processed peptides were also unable to stimulate the Nase-specific clones. However, two other substitutions in the synthetic peptide were stimulatory for a T cell clone even though the same changes in the intact protein were non-stimulatory. These results suggest that certain residue changes affect recognition of the naturally processed peptide but not the synthetic peptide with the same amino acid change. In addition, these results demonstrate that the effects of amino acid substitutions in synthetic peptides on T cell recognition may not always reflect the effects of these substitutions in the intact protein. Substitutions located outside Nase-specific T cell epitopes were also examined. Thirty different mutant proteins were all stimulatory. Moreover, a number of these mutants proteins were 50- to 100-fold more efficient in their stimulatory capacity than the native Nase protein.(ABSTRACT TRUNCATED AT 250 WORDS)     

T cell epitopes encompassing the mutational hot spot position 61 of p21 ras. Promiscuity in ras peptide binding to HLA

Activated ras carry a point mutation either in codon 12, 13 or 61 which is tumor specific. Peptides derived from this oncoprotein are therefore potential tumor antigens. Essential for the feasibility of using ras-derived peptides in therapy of cancer is whether p21 ras-derived peptides can be processed, bind to human histocompatibility leukocyte antigen (HLA) and be recognized by T cells. Here we report the fine specificity and HLA restriction of several T lymphocyte clones (TLC) specific for a peptide which is derived from the second mutational hot spot in ras encoding residue 61. These TLC were generated from memory T cells present in the blood of a cancer patient and recognized a ras-derived peptide carrying Leu instead of Gln at residue 61. By sequencing of the T cell receptor (TcR) genes three sets of “sister” TLC carrying highly different TcR were identified. Two of the TLC recognized a peptide carrying the 61 Leu mutation presented by HLA-DQ8 and one recognized the same peptide presented by HLA-DQ4. By using truncated peptides derived from residues 51 to 69 of p21 ras, partially overlapping minimal epitopes could be defined. All three TLC recognized the corresponding recombinant mutant p21 ras oncoprotein carrying Leu at residue 61 presented by autologous B-lymphoblastoid cell lines (B-LCL). This demonstrates that naturally derived ras peptides from this region of p21 ras encompass the three epitopes recognized by the TLC. These results indicate that immunogenic ras-derived peptides may be used in immunotherapy of cancer where transforming ras oncoproteins are involved.     

Identification of a promiscuous HLA DR-restricted T-cell epitope derived from the inhibitor of apoptosis protein survivin

The inhibitor of apoptosis protein survivin is a promising tumor-associated antigen specifically recognized by CD8+ cytotoxic effector T-lymphocytes (CTL). To improve current vaccines that aim to induce survivin-specific CTL, it is necessary to study the role of CD4+ T-helper (TH) and CD4+ T-regulatory (Treg) cells. Because both TH and Treg cells recognize antigens in the context of HLA-class II molecules, identification of HLA class II-associated peptide epitopes from survivin is required. Here, we analyzed T-cell responses against survivin using synthetic peptides predicted to serve as HLA-DR-restricted epitopes. Six peptides were shown to induce CD4+ T-cell responses, restricted by HLA-DR molecules. For one peptide epitope, SVN10, T-cell clones were demonstrated to be capable of recognizing naturally processed antigen. SVN10-specific T cells could be stimulated from the blood of healthy individuals and cancer patients with multiple HLA-DR genotypes. Thus the identified SVN10 epitope can be used to study the role of CD4+ TH and Treg cells in immune responses and possibly be included in a multivalent peptide vaccine against survivin.     

Different types of allospecific CTL clones identified by their ability to recognize peptide loading-defective target cells

Allospecific immune responses against the MHC of another individual are remarkably strong, due t a high number of responding T cell clones. Although it has been demonstrated that some allospecific cytotoxic T lymphocytes (CTL) recognize peptides presented by allogeneic MHC class I molecules, it has remained unclear whether MHC molecules can be recognized directly. We used the H-2b-derived murine lymphoma mutant RMA-S, which has a defect affecting peptide loading of class I molecules, to test whether recognition by allospecific CTL always requires the presence of peptides. Three types of anti-H-2Kb CTL clones can be distinguished by their ability to lyse RMA-S target cells. Type A CTL clones efficiently lyse these target cells, the lysis by type B CTL clones is inefficient, and type C clones fail to lyse RMA-S. Up-regulation of the levels of H-2Kb density improved lysis by type B clones, but did not lead to lysis by type C clones. Some type A and B CTL clones apparently can recognize class I molecules devoid of peptides, while others are likely to recognize peptides which are not affected by the presentation defect of RMA-S. We suggest that type C clones are specific for peptides which are not presented by the mutant cells. The results show that the majority of alloreactive CTL recognize peptide/MHC complexes, while some CTL behave as if they can recognize class I molecules in the absence of MHC-bound peptides.     

HLA-DRβ chain residue 86 controls DRαβ dimer stability

Major histocompatibility complex class II molecules exist in two forms, which can be distinguished on the basis of their stability in sodium dodecyl sulfate (SDS) as SDS-stable and SDS-unstable αβ dimers. The ratio of stable vs. unstable αβ dimers varies between murine H-2 alleles and isotypes, but the molecular basis for this observation is unknown. Here we show that for the human HLA-DRB1 and HLA-DRB3 gene products this ratio is controlled by the valine/glycine dimorphism at position 86. Haplotypes coding for DRβ chains with a valine at position 86 express higher numbers of stable dimers compared to similar haplotypes expressing DRβ chains with a glycine at that position. Reverse-phase high-performance liquid chromatography analysis of iodinated peptides, which were eluted from DR dimers with either a DRB1*1101 or a DRB1*1104 β chain which differ only at position 86, indicated that these DR dimers contain (partially) distinct sets of peptides. The valine/glycine dimorphism is highly conserved, present in most HLA-DR alleles and influences peptide-binding. Analysis of the occurrence of theVal⁸⁶ and the Gly⁸⁶ gene products revealed that these are not equally present in the population. Depending on the DR specificity either the Val⁸⁶ of Gly⁸⁶ allelic variant is favored. Thus, the natural, highly conserved dimorphism at HLA-DR β chain position 86 influences peptide selection. The dimorphism is therefore likely to influence antigen presentation and forms the molecular basis for the observed differences in stability of Val⁸⁶- and Gly⁸⁶-containing DR dimers in the presence of SDS.     

Identification of tumor-associated MHC class I ligands by a novel T cell-independent approach

Specific immunotherapy of cancer utilizes tumor-directed cytotoxic T lymphocytes (CTL) that lyse tumor cells presenting MHC class I-associated peptides derived from tumor-associated proteins. Many tumor-associated gene products are known, but corresponding T cell epitopes are only known for relatively few of these. The most commonly used approaches to identify such antigens require pre-existing CTL lines or clones. By using a CTL-independent high performance liquid chromatography mass spectrometry (HPLC MS)-based approach we identified HLA-A2-presented peptides from carcinoembryonic antigen and wild-type p53 with a copy number as low as eight molecules per cell. Potential epitopes were predicted from the sequences of known tumor antigens and the corresponding synthetic peptides were analyzed by nanocapillary HPLC MS. In parallel, peptides were extracted from fresh, solid tumor tissue or tumor cell lines and analyzed in the same way. Upon co-elution of a natural peptide with a predicted peptide of the same mass, the peptide sequence was confirmed by on-line tandem MS. This approach allows rapid screening of large numbers of tumor-associated gene products for naturally processed peptides presented by different MHC class I molecules as a prerequisite for efficient epitope identification and rapid transfer to therapeutic vaccine trials.     

An HLA-DRB α-helix motif shared by DR11 and DR8 alleles is implicated in the pluriallelic restriction of peptide-specific T-cell lines

The T-cell recognition of HLA-DR-peptide complexes is generally restricted by the polymorphism of the DRB molecules but pluriallelic restriction has been described. The molecular basis of restriction and promiscuity of such peptide-specific responses is poorly understood. We isolated a panel of T-cell lines specific for the tetanus toxin peptide p2 (TT830-843) exhibiting pluriallelic restriction by DR11 and DR8 alleles. Fine restriction specificity of the T-cell lines was examined in functional assays against DR oligotyped APCs expressing different variants of DR11 and DR8 alleles. Our results show that (a) polymorphisms between serologically related alleles are relevant in terms of restriction of the peptide-specific T-cell response; in some instances, a single amino acid substitution can determine the restriction of a T-cell line; (b) different patterns of restriction are not the result of specific differences in DR-p2 binding as p2 peptide binds to all DR11 and DR8 alleles tested (DRB1^* 1101, -1102, -1103, -1104, 110X, -0801, -0802, -0803, and -0806); and (c) pluriallelic restriction of the peptide-specific T-cell responses correlates with the presence of a DRB1 α-helix motif (67-71-86) shared by some DR11 and DR8 alleles. Possible implications of pluriallelic restriction of peptide-specific T-cell response in autoimmune disorders associated with DR11 and DR8 are discussed.     

Different requirements of ICAM-1/LFA-1 adhesion in allorecognition and self-restricted antigen recognition by class II-specific T cell clones

We have analyzed the influence of non-antigen-specific interactions between ICAM-1 and LFA-1 in target recognition by allospecific and antigen-specific Tcells at the clonal level, using human and mouse fibroblasts transfected with HLA-DR1 or DR2 with or without co-expression of ICAM-1, as antigen-presenting cells. The results show a great heterogeneity in the requirements for ICAM-1/LFA-1 interactions for antigen-specific and alloreactive T cell responses and this requirement may depend on the avidity of any particular interaction. The data also show that for most alloreactive clones, ICAM-1/LFA-1 adhesion is not sufficient to facilitate efficient T cell recognition of its target molecule. HLA class II recognition by a large proportion of the DR1- and DR2-specific alloreactive clones studied was different for class II molecules expressed on murine or human fibroblasts compared to human lymphoid cells, and was independent of ICAM-1 expression on the stimulator cells. The inability of some T cell clones to recognize HLA-class II expressed on non-lymphoid cells suggests the absence of specific epitopes and could be due to the lack of the relevant peptides, either because they are derived from species-specific proteins or to differences in processing of endogenous antigen in the transfected stimulator cells.     

Evidence that HLA class II-restricted human CD4+ T cells specific to p53 self peptides respond to p53 proteins of both wild and mutant forms

By stimulating peripheral blood mononuclear cells of four healthy donors with a mixture of overlapping peptides representing the core domain of p53, we established two CD4+ α β T cell clones and four lines that recognized wild-type and mutant p53 proteins as well as p53 self peptides in an HLA class II-restricted fashion. Two T cell lines established from two unrelated donors reacted to the p53 peptide (p)153 – 166 and p108 – 122, respectively, in the context of DP5 molecules. Two T cell clones established from two other unrelated donors were specific for p193 – 204 in the context of DRB1*1401 and for p153 – 165 in the context of DP5, respectively. These two T cell clones responded almost equally to both wild-type and four mutant recombinant p53 proteins. The proliferative responses of these T cell clones to p53 recombinant proteins were augmented by heat denaturing, thereby suggesting that altered conformation of the protein facilitates proteolytic processing to produce antigenic peptides. The DRB1*1401-restricted T cell clone specific for p193 – 204 killed a B lymphoblastoid cell line homozygous for HLA-DRB1*1401 when the cell line was pre-pulsed with p53 protein as well as peptide. These results indicate that CD4+ T cells reactive to p53 do exist in healthy individuals and the epitopes are probably ignored by the immune system under physiological conditions. It is suggested that such epitopes stimulate T cells to induce anti-p53 antibody production in cancer patients as previously reported by others. The possible involvement of p53-reactive T cells in anti-tumor immunity is discussed.