Coreceptor function of CD4 in response to MHC class I molecule

Specificity of T cell receptor (TCR) and its interaction with coreceptor molecules play decisive role in successful passing of T lymphocytes via check-points during their development and finally determine the efficiency of adaptive immunity. Genes encoding alpha- and beta-chains of TCR hybridoma 1D1 have been cloned. The hybridoma 1D1 was established by the fusion of BWZ.36CD8alpha cell line with CD8+ memory cells specific to MHC class I H-2Kb molecule. Exploiting retroviral transduction of thymoma 4G4 cells with TCR genes and coreceptors CD4 and CD8, variants of this cell line expressing on the surface CD3/TCR complex and coreceptors, separately or simultaneously have been obtained. The main function of CD4 is stabilization of interaction between TCR and MHC class II molecule. Nevertheless, we have found that CD4 could successfully participate in the activation of transfectants via TCR specific to MHC class I molecule H-2Kb. Moreover, coreceptor CD4 dominates CDS, because the response of transfectants CD4+CD8+ is blocked by antibodies to CD4 and MHC Class II Ab molecule but not to coreceptor CD8. The response of CD4+ cells was not due to cross-reaction between TCR 1D1 with MHC class II molecules, because transfectants do not respond to splenocytes of H-2b knockouted mice with impaired assembly of TCR/beta2-microglobulin/peptide complexes resulting in their absence on the cell surphace. The effect of domination was not due to sequestration of kinase p56lck, because truncated CD4 with the loss of binding motif for p56lck remained functional in 4G4 cells. Results obtained can explain the number of features of intrathymic selection and represent experimental basis for development of new methods of cancer gene therapy.     

Immunodominance is altered in T cell receptor (beta-chain) transgenic mice without the generation of a hole in the repertoire.

Despite the tremendous plasticity of the TCR repertoire, T cells recognize a limited number of antigenic sites (frequently a single site, or immunodominant epitope) on a complex protein Ag. Current models suggest that the immunodominant epitope of a complex protein is the processed peptide that binds to the MHC molecule with the highest affinity. Conversely, the inability of the T cell population to recognize a specific epitope, termed a "hole" in the repertoire, can prevent the immunodominance of a peptide despite efficient processing and MHC binding of the peptide. The role of specific TCR alpha- or beta-chains in determining MHC restriction and recognizing specific epitopes is complex and incompletely understood. To evaluate the contribution of each TCR chain to the functional diversity of the T cell repertoire, we investigated in vivo the T cell response to phage lambda-repressor protein in transgenic mice expressing a single rearranged beta-chain gene (C57L beta mice) in association with the complete germline alpha-chain repertoire. Our results demonstrate that expression of the TCR beta-chain transgene alters the immunodominant epitope recognized by T cells. However, after immunization with the appropriate peptide the transgenic mice can also respond to the nonimmunodominant epitope; thus, the expression of the TCR beta-chain transgene does not create a hole in the repertoire. These data indicate that the primary site, or immunodominant epitope, of an Ag recognized by T cells can be altered by the preimmune TCR repertoire independent of antigen processing and MHC affinity.     

Altered peptide ligand-mediated TCR antagonism can be modulated by a change in a single amino acid residue within the CDR3 beta of an MHC class I-restricted TCR

The Ag receptor of cytotoxic CD8+ T lymphocytes recognizes peptides of 8-10 aa bound to MHC class I molecules. This Ag recognition event leads to the activation of the CD8+ lymphocyte and subsequent lysis of the target cell. Altered peptide ligands are analogues derived from the original antigenic peptide that commonly carry amino acid substitutions at TCR contact residues. TCR engagement by these altered peptide ligands usually impairs normal T cell function. Some of these altered peptide ligands (antagonists) are able to specifically antagonize and inhibit T cell activation induced by the wild-type antigenic peptide. Despite significant advances made in understanding TCR antagonism, the molecular interactions between the TCR and the MHC/peptide complex responsible for the inhibitory activity of antagonist peptides remain elusive. To approach this question, we have identified altered peptide ligands derived from the vesicular stomatitis virus peptide (RGYVYQGL) that specifically antagonize an H-2Kb/vesicular stomatitis virus-specific TCR. Furthermore, by site-directed mutagenesis, we altered single amino acid residues of the complementarity-determining region 3 of the beta-chain of this TCR and tested the effect of these point mutations on Ag recognition and TCR antagonism. Here we show that a single amino acid change on the TCR CDR3 beta loop can modulate the TCR-antagonistic properties of an altered peptide ligand. Our results highlight the role of the TCR complementarity-determining region 3 loops for controlling the nature of the T cell response to TCR/altered peptide ligand interactions, including those leading to TCR antagonism.     

Recognition of an MHC class I-restricted antigenic peptide can be modulated by para-substitution of its buried tyrosine residues in a TCR-specific manner

Conformational dependence of TCR contact residues of the H-2Kb molecule on the two buried tyrosine side chains of the vesicular stomatitis virus (VSV)-8 peptide was investigated by systematic substitutions of the tyrosines with phenylalanine, p-fluorophenylalanine (pFF), or p-bromophenylalanine (pBrF). The results of peptide competition CTL assays revealed that all of the peptide variants, except for the pBrF analogues, had near-native binding to the H-2Kb molecule. Epitope-mapped anti-H-2Kb mAbs detected conformational differences among H-2Kb molecules stabilized with these VSV-8 variants on RMA-S cells. Selective recognition of the VSV-8 analogues was displayed by a panel of three H-2Kb-restricted, anti-VSV-8 TCRs. Thus, these substitutions result in an antigenically significant conformational change of the MHC molecular surface structure at both C and D pockets, and the effect of this change on cognate T cell recognition is dependent on the TCR structure. Our results confirm that the structure of buried peptide side chains can determine the surface conformation of the MHC molecule and demonstrate that even a very subtle structural nuance of the buried side chain can be incorporated into the surface conformation of the MHC molecule. The ability of buried residues to modulate this molecular surface augments the number of residues on the MHC-peptide complex that can be recognized as "foreign" by the CD8+ T cell repertoire and allows for a higher level of antigenic discrimination. This may be an important mechanism to expand the total number of TCR specificities that can respond to a single peptide determinant.     

Functional evidence that conserved TCR CDR alpha 3 loop docking governs the cross-recognition of closely related peptide:class I complexes.

The TCR recognizes its peptide:MHC (pMHC) ligand by assuming a diagonal orientation relative to the MHC helices, but it is unclear whether and to what degree individual TCRs exhibit docking variations when contacting similar pMHC complexes. We analyzed monospecific and cross-reactive recognition by diverse TCRs of an immunodominant HVH-1 glycoprotein B epitope (HSV-8p) bound to two closely related MHC class I molecules, H-2K(b) and H-2K(bm8). Previous studies indicated that the pMHC portion likely to vary in conformation between the two complexes resided at the N-terminal part of the complex, adjacent to peptide residues 2-4 and the neighboring MHC side chains. We found that CTL clones sharing TCR beta-chains exhibited disparate recognition patterns, whereas those with drastically different TCRbeta-chains but sharing identical TCRalpha CDR3 loops displayed identical functional specificity. This suggested that the CDRalpha3 loop determines the TCR specificity in our model, the conclusion supported by modeling of the TCR over the actual HSV-8:K(b) crystal structure. Importantly, these results indicate a remarkable conservation in CDRalpha3 positioning, and, therefore, in docking of diverse TCRalphabeta heterodimers onto variant peptide:class I complexes, implying a high degree of determinism in thymic selection and T cell activation.     

Asymmetric selection of T cell antigen receptor alpha- and beta-chains in HLA-B27 alloreactivity.

Endogenous peptides constitutively bind to class I MHC Ag and are thought to be integral parts of allospecific T cell epitopes. However, allospecific TCR can recognize structural features of the alloantigen as foreign. To define some crucial parameters determining HLA-B27 allorecognition, the structure of TCR alpha- and beta-chains from HLA-B27-specific CTL was analyzed. A strategy, based on V alpha and V beta family-specific oligonucleotides, was used for specific amplification and direct sequencing of TCR-alpha and -beta cDNA. We observed nonrandom usage of V beta segments and recurrent structural motifs within beta-chain junctional regions. In contrast, no structural restrictions were apparent among alpha-chains, even from CTL clones of related fine specificity. These results indicate an asymmetric contribution of TCR alpha- and beta-chains to HLA-B27 allospecificity among the CTL clones analyzed. They suggest recognition of multiple peptides and involvement of beta-chain junctional regions in recognizing shared motifs among some of these peptides.     

T cell responses specific for subregions of allogeneic MHC molecules.

The repertoire of C3H (H-2k) CD4+ T cells for I-Ab allopolymorphisms was analyzed by studying the responses of unprimed populations of T cells and of I-Ab-specific T cell clones for recombinant MHC molecules containing combinations of polymorphic subregions of the alpha- and beta-chains from the I-Ab and I-Ak molecules. In this system, polymorphisms in the predicted MHC alpha-helices were more potent than polymorphisms in the beta-strands in stimulating unprimed alloreactive T cells. Similarly, 75% of I-Ab-specific T cell clones responded to recombinants containing b polymorphisms in both the alpha- and beta-chains helices and tolerated the substitution of k polymorphisms in the beta-pleated sheet. Furthermore, 20% of the clones responded to a molecule containing allogeneic b residues in just the beta-chain helix. The results demonstrate that the T cell response to allogeneic MHC molecules consists largely of sets of T cells with overlapping specificities for subregions of the MHC molecule. In addition, they highlight the importance of the alpha-helices in these responses and a diminished role for polymorphisms in the beta-strands when, as in the present case, MHC structure and conformation is tolerant of beta-sheet substitutions. These results sharply contrast with observations made in the analysis of Ag-specific T cells and lead to the suggestion that a subset of alloreactive T cells are not peptide specific and can directly recognize MHC polymorphisms.     

Presentation of antigens internalized through the B cell receptor requires newly synthesized MHC class II molecules

Exogenous Ags taken up from the fluid phase can be presented by both newly synthesized and recycling MHC class II molecules. However, the presentation of Ags internalized through the B cell receptor (BCR) has not been characterized with respect to whether the class II molecules with which they become associated are newly synthesized or recycling. We show that the presentation of Ag taken up by the BCR requires protein synthesis in splenic B cells and in B lymphoma cells. Using B cells transfected with full-length I-Ak molecules or molecules truncated in cytoplasmic domains of their alpha- or beta-chains, we further show that when an Ag is internalized by the BCR, the cytoplasmic tails of class II molecules differentially control the presentation of antigenic peptides to specific T cells depending upon the importance of proteolytic processing in the production of that peptide. Integrity of the cytoplasmic tail of the I-Ak beta-chain is required for the presentation of the hen egg lysozyme determinant (46-61) following BCR internalization, but that dependence is not seen for the (34-45) determinant derived from the same protein. The tail of the beta-chain is also of importance for the dissociation of invariant chain fragments from class II molecules. Our results demonstrate that Ags internalized through the BCR are targeted to compartments containing newly synthesized class II molecules and that the tails of class II beta-chains control the loading of determinants produced after extensive Ag processing.     

How a single T cell receptor recognizes both self and foreign MHC

alphabeta T cell receptors (TCRs) can crossreact with both self- and foreign- major histocompatibility complex (MHC) proteins in an enigmatic phenomenon termed alloreactivity. Here we present the 2.35 A structure of the 2C TCR complexed with its foreign ligand H-2L(d)-QL9. Surprisingly, we find that this TCR utilizes a different strategy to engage the foreign pMHC in comparison to the manner in which it recognizes a self ligand H-2K(b)-dEV8. 2C engages both shared and polymorphic residues on L(d) and K(b), as well as the unrelated QL9 and dEV8 peptide antigens, in unique pair-wise contacts, resulting in greater structural complementarity with the L(d)-QL9 complex. In the structure of an engineered, high-affinity 2C TCR variant bound to H-2L(d)-QL9, the "wild-type" TCR-MHC binding orientation persists despite modified TCR-CDR3alpha interactions with peptide. Thus, a single TCR recognizes two globally similar, but distinct ligands by divergent mechanisms, indicating that receptor-ligand crossreactivity can occur in the absence of molecular mimicry.     

Recognition of a specific self-peptide: self-MHC class II complex is critical for positive selection of thymocytes expressing the D10 TCR

We examined the specificity of positive and negative selection by using transgenic mice carrying a variant of the D10 TCR. We demonstrate that a point mutation at position 51 within the CDR2alpha segment significantly reduces the avidity of this TCR for its cognate ligand, but does not impact recognition of nonself MHC class II molecules. Although structural studies have suggested that this TCR site interacts with the MHC class II beta-chain, the avidity of this TCR for its ligand and the function of the T cell can be reconstituted by a point mutation in the bound antigenic peptide. These data demonstrate that the bound peptide can indirectly alter TCR interactions by influencing MHC structure. Remarkably, reducing the avidity of this TCR for a specific antigenic peptide-MHC ligand has a dramatic impact on thymic selection. Positive selection of thymocytes expressing this TCR is nearly completely blocked, whereas negative selection on allogenic MHC class II molecules remains intact. Therefore, the recognition of self that promotes positive selection of the D10 TCR is highly peptide-specific.     

Antibody specific for the peptide.major histocompatibility complex. Is it T cell receptor-like?

Antibodies recognizing peptide bound to a major histocompatibility complex (MHC) protein usually have a higher affinity for the composite peptide.MHC (pMHC) ligand than T cell receptors (TCR) with the same specificity. Because the solvent-accessible peptide area constitutes only a small portion of the contacting pMHC surface, we hypothesized that the contribution of the MHC moiety to the TCR-pMHC complex stability is limited, ensuring a small increment of the binding energy delivered by the peptide to be distinguishable by the TCR or the peptide-specific antibody. This suggests that the gain in affinity of the antibody-pMHC interaction can be achieved through an increase in the on-rate without a significant change in the off-rate of the interaction. To test the hypothesis, we have analyzed the binding of an ovalbumin peptide (pOV8) and its variants associated with soluble H-2Kb protein to the 25-D1.16 monoclonal antibody and compared it with the binding of the same pMHC complexes to the OT-1 TCR. This comparison revealed a substantially higher on-rate of the antibody-pMHC interaction compared with the TCR-pMHC interaction. In contrast, both the antibody and the TCR-pMHC complexes exhibited comparably fast off-rates. Sequencing of the 25-D1.16 VH and VL genes showed that they have very few somatic mutations and those occur mainly in framework regions. We propose that the above features constitute a signature of the recognition of MHC-bound peptide antigens by TCR and TCR-like antibodies, which could explain why the latter are rarely produced in vivo.     

Molecular modeling of a T-cell receptor bound to a major histocompatibility complex molecule: implications for T-cell recognition.

The main functions of the T-cell receptor (TCR) involve its specific interaction with short and linear antigenic peptides bound to the major histocompatibility complex (MHC) molecules. In the absence of a 3D structure for TCR and for the TCR/peptide/MHC complex, several attempts to characterize the structural components of the TCR/peptide/MHC interaction have been made. However, this subject is still troublesome. In this paper a computer-based 3D model for a TCR/peptide/MHC complex (5C.C7/moth cytochrome c [MCC] peptide 93-103/I-Ek) was obtained. The complex surface shows a high complementarity between the 5C.C7 structure and the peptide/I-Ek molecule. The mapping of residues involved in the TCR/peptide/MHC interaction shows close agreement with mutational experiments (Jorgensen JL, Reay PA, Ehrich EW, Davis MM, 1992b, Annu Rev Immunol 10:835-873). Moreover, the results are consistent with a recent variability analysis of TCR sequences using three variability indexes (Almagro JC, Zenteno-Cuevas R, Vargas-Madrazo E, Lara-Ochoa F, 1995b, Int J Pept Protein Res 45:180-186). Accordingly, the 3D model of the 5C.C7/MCC peptide 93-103/I-Ek complex provides a framework to generate testable hypotheses about TCR recognition. Thus, starting from this model, the role played by each loop that forms the peptide/MHC binding site of the TCR is discussed.     

Single amino acid replacements in an antigenic peptide are sufficient to alter the TCR V beta repertoire of the responding CD8+ cytotoxic lymphocyte population.

Cytotoxic CD8+ T lymphocytes are activated upon the engagement of their Ag-specific receptors by MHC class I molecules loaded with peptides 8-11 amino acids long. T cell responses triggered by certain antigenic peptides are restricted to a limited number of TCR V beta elements. The precise role of the peptide in causing this restricted TCR V beta expansion in vivo remains unclear. To address this issue, we immunized C57BL/6 mice with the immunodominant peptide of the vesicular stomatitis virus (VSV) and several peptide variants carrying single substitutions at TCR-contact residues. We observed the expansion of a limited set of TCR V beta elements responding to each peptide variant. To focus our analysis solely on the TCR beta-chain, we created a transgenic mouse expressing exclusively the TCR alpha-chain from a VSV peptide-specific CD8+ T cell clone. These mice showed an even more restricted TCR V beta usage consequent to peptide immunization. However, in both C57BL/6 and TCR alpha transgenic mice, single amino acid replacements in TCR-contact residues of the VSV peptide could alter the TCR V beta usage of the responding CD8+ T lymphocytes. These results provide in vivo evidence for an interaction between the antigenic peptide and the germline-encoded complementarity-determining region-beta loops that can influence the selection of the responding TCR repertoire. Furthermore, only replacements at residues near the C terminus of the peptide were able to alter the TCR V beta usage, which is consistent with the notion that the TCR beta-chain interacts in vivo preferentially with this region of the MHC/peptide complex.     

Beta-chain broadens range of CD8 recognition for MHC class I molecule.

It is known that the alpha-chain of CD8 binds to a negatively charged loop composed of residues 223 to 229 on MHC class I Ag and that binding of CD8 alpha enhances Ag recognition of T cells. We have recently shown that the mouse CD8 alpha homodimer does not bind to either the HLA class I alpha 3 domain or a mutant of H-2Kb Ag containing a substitution of glutamine for methionine at residue 224, which brings this residue toward the human consensus. Here we report a complementary study of the CD8 beta-chain. The functional role of the CD8 beta-chain was analyzed by using four T cell hybridoma lines expressing mouse CD8 alpha and transfected with the mouse CD8 beta gene. As compared with the lines expressing only CD8 alpha, allorecognition of the chimeric H-2Kb Ag that contains the HLA class I alpha 3 domain was enhanced in lines expressing both CD8 alpha and -beta. This enhancement was blocked by either anti-CD8 mAb or anti-HLA class I alpha 3 domain mAb. In addition, we show that CD8 alpha beta binds the H-2Kb mutant Ag at residue 224. These results suggest that the beta-chain allows the CD8 alpha beta heterodimer to recognize the chimeric H-2Kb Ag. A model for the role of the beta-chain is presented.     

Thymocyte antigens do not induce tolerance in the CD4+ T cell compartment.

Thymocytes fail to tolerize the developing T cell repertoire to self MHC class I (MHC I) Ags because transgenic (CD2Kb) mice expressing H-2Kb solely in lymphoid cell lineages reject skin grafts mismatched only for H-2Kb. In this study, we examined why thymocytes fail to tolerize the T cell repertoire to self MHC I Ags. The ability of CD2Kb mice to reject H-2Kb skin grafts was age dependent because CD2Kb mice older than 20 wk accepted skin grafts. T cells from younger CD2Kb mice proliferated, but did not develop cytotoxic functions in vitro in response to H-2Kb. Proliferative responses were dominated by H-2Kb-specific, CD4+ T cells rather than CD8+ T cells. Representative CD4+ T cell clones from CD2Kb mice were MHC II restricted and recognized processed H-2Kb. TCR transgenic mice were generated from one CD4+ T cell clone (361) to monitor development of H-2Kb-specific immature thymocytes when all thymic cells or lymphoid cell lineages only expressed H-2Kb. Thymocyte precursors were not eliminated and mice were not tolerant to H-2Kb when Tg361 TCR transgenic mice were intercrossed with CD2Kb mice. In contrast, all thymocyte precursors were eliminated efficiently in thymic microenvironments in which all cells expressed H-2Kb. We conclude that self MHC I Ags expressed exclusively in thymocytes do not induce T cell tolerance because presentation of processed self MHC I Ags on self MHC II molecules fails to induce negative selection of CD4+ T cell precursors. This suggests that some self Ags are effectively compartmentalized and cannot induce self-tolerance in the T cell repertoire.     

Determination of structural principles underlying three different modes of lymphocytic choriomeningitis virus escape from CTL recognition

Lymphocytic choriomeningitis virus infection of H-2(b) mice generates a strong CD8(+) CTL response mainly directed toward three immunodominant epitopes, one of which, gp33, is presented by both H-2D(b) and H-2K(b) MHC class I molecules. This CTL response acts as a selective agent for the emergence of viral escape variants. These variants generate altered peptide ligands (APLs) that, when presented by class I MHC molecules, antagonize CTL recognition and ultimately allow the virus to evade the cellular immune response. The emergence of APLs of the gp33 epitope is particularly advantageous for LCMV, as it allows viral escape in the context of both H-2D(b) and H-2K(b) MHC class I molecules. We have determined crystal structures of three different APLs of gp33 in complex with both H-2D(b) and H-2K(b). Comparison between these APL/MHC structures and those of the index gp33 peptide/MHC reveals the structural basis for three different strategies used by LCMV viral escape mutations: 1) conformational changes in peptide and MHC residues that are potential TCR contacts, 2) impairment of APL binding to the MHC peptide binding cleft, and 3) introduction of subtle changes at the TCR/pMHC interface, such as the removal of a single hydroxyl group.     

Alloantigenic sites on class I major histocompatibility complex antigens: 61-69 region in the first domain of the H-2Kb molecule induces specific antibody and T cell responses

The most polymorphic residues in the first domain of class I major histocompatibility complex (MHC) molecules are in the 61-69 region. We have chosen the H-2Kb molecule for determining the role of this region in the induction of alloimmune responses. A synthetic peptide, Glu-Arg-Glu-Thr-Gln-Lys-Ala-Lys-Gly corresponding to this region was synthesized. T cells enriched from the lymph nodes of allostrain mice that were previously primed with H-2Kb containing cells or with the synthetic peptide in complete Freund's adjuvant undergo extensive in vitro proliferation in response to the synthetic (61-69)H-2Kb peptide. The response was dependent on the presentation of the (61-69)H-2Kb peptide by the syngeneic antigen-presenting cells and was blocked by anti-class II MHC monoclonal antibodies. This peptide fragment of class I MHC molecule activates only helper/inducer type T cells that are involved in the primary responses but not the effector cytotoxic T cells. When coupled to a carrier protein, (61-69)H-2Kb peptide induced antibodies in allostrain mice that bind to intact H-2Kb molecule. No antibodies or T cell responses could be induced in syngeneic H-2b mice. The antigenic site on the H-2Kb molecule recognized by two H-2Kb-specific monoclonal antibodies B8 X 3 X 24 and Y-25 was also mapped in the 61-69 region by direct binding to the synthetic peptide. Therefore the 61-69 region on the H-2Kb molecule represents the first defined sequence on a class I molecule that is directly involved in the induction of alloimmune responses.     

Characterization of the ovalbumin-specific TCR transgenic line OT-I: MHC elements for positive and negative selection

The present report provides the first extensive characterization of the OT-I TCR transgenic line, which produces MHC class I-restricted, ovalbumin-specific, CD8+ T cells (OT-I cells). These cells are shown to be positively selected in vivo in H-2b C57BL/6 mice and in bm5 mice, which express the Kbm5 mutant molecule. In contrast, OT-I cells were not selected by mutant Kb molecules in bm1, bm3, bm8, bm10, bm11 or bm23 mice. Interestingly, however, when positive selection was examined in vitro in foetal thymic organ culture (FTOC), bm1 and bm8 were still poorly selective, but the bm3 haplotype now selected as efficiently as B6. The ability to select in vitro correlated with the capacity to present the ovalbumin (OVA) peptide to OT-I cells, as measured by induction of an OVA-specific proliferative response. These results suggest that a lower affinity TCR:MHC interaction may be necessary for positive selection in FTOC compared with selection in situ.     

Binding of longer peptides to the H-2Kb heterodimer is restricted to peptides extended at their C terminus: refinement of the inherent MHC class I peptide binding criteria.

MHC class I molecules usually bind short peptides of 8-10 amino acids, and binding is dependent on allele-specific anchor residues. However, in a number of cellular systems, class I molecules have been found containing peptides longer than the canonical size. To understand the structural requirements for MHC binding of longer peptides, we used an in vitro class I MHC folding assay to examine peptide variants of the antigenic VSV 8 mer core peptide containing length extensions at either their N or C terminus. This approach allowed us to determine the ability of each peptide to productively form Kb/beta2-microglobulin/peptide complexes. We found that H-2Kb molecules can accommodate extended peptides, but only if the extension occurs at the C-terminal peptide end, and that hydrophobic flanking regions are preferred. Peptides extended at their N terminus did not promote productive formation of the trimolecular complex. A structural basis for such findings comes from molecular modeling of a H-2Kb/12 mer complex and comparative analysis of MHC class I structures. These analyses revealed that structural constraints in the A pocket of the class I peptide binding groove hinder the binding of N-terminal-extended peptides, whereas structural features at the C-terminal peptide residue pocket allow C-terminal peptide extensions to reach out of the cleft. These findings broaden our understanding of the inherent peptide binding and epitope selection criteria of the MHC class I molecule. Core peptides extended at their N terminus cannot bind, but peptide extensions at the C terminus are tolerated.     

Frequent contribution of T cell clonotypes with public TCR features to the chronic response against a dominant EBV-derived epitope: application to direct detection of their molecular imprint on the human peripheral T cell repertoire

In an attempt to provide a global picture of the TCR repertoire diversity of a chronic T cell response against a common Ag, we performed an extensive TCR analysis of cells reactive against a dominant HLA-A2-restricted EBV epitope (hereafter referred to as GLC/A2), obtained after sorting PBL or synovial fluid lymphocytes from EBV-seropositive individuals using MHC/peptide multimers. Although TCR beta-chain diversity of GLC/A2+ T cells was extensive and varied greatly from one donor to another, we identified in most cell lines several recurrent Vbeta subsets (Vbeta2, Vbeta4, and Vbeta16 positive) with highly conserved TCRbeta complementarity-determining region 3 (CDR3) length and junctional motifs, which represented from 11 to 98% (mean, 50%) of GLC/A2-reactive cells. While TCR beta-chains expressed by these subsets showed limited CDR1, CDR2, and CDR3 homology among themselves, their TCR alpha-chains comprised the same TCRAV region, thus suggesting hierarchical contribution of TCR alpha-chain vs TCR beta-chain CDR to recognition of this particular MHC/peptide complex. The common occurrence of T cell clonotypes with public TCR features within GLC/A2-specific T cells allowed their direct detection within unsorted PBL using ad hoc clonotypic primers. These results, which suggest an unexpectedly high contribution of public clonotypes to the TCR repertoire against a dominant epitope, have several implications for the follow-up and modulation of T cell-mediated immunity.