Expansion of murine T cells bearing a unique T cell receptor beta-chain in Friend virus-induced tumor in situ.

Heterogeneity of V alpha 1+ and V beta 10+ TCR alpha beta-chains, which are predominantly used in anti-FBL-3 CTL clones established in vitro, was investigated at a nucleotide level in FBL-3 tumor-infiltrating lymphocytes (TIL) in vivo. The majority (90%) of V beta 10+ beta-chains dominated in TIL used homogeneous V beta 10D beta 2.1 sequences identical to that used in the T cell clones with cytotoxic functions. The homogeneous TCR beta-chain expression was dominant and found to be about 10% of the total TCR beta-chains in the TIL population, which was a greater than 300-to 900-fold increase than in the regional lymph nodes. This is in good agreement with the in vitro data showing that about 11% CTL clones used the homogeneous V beta 10D beta 2.1+ beta-chain. However, the J beta segment does not seem to contribute greatly to the recognition and selection of this TCR because some of homogeneous VD+ beta-chains were associated with J beta segments other than J beta 2.7 of the CTL clones. The frequency of the V alpha 1J alpha 112-2+ alpha-chain expression of the CTL type was much less (3- to 80-fold increase compared to that of lymph node) and also varied in sample materials, indicating the lower contribution of the alpha-chain for the oligoclonality of the TCR. The results were also confirmed by quantitative PCR and RNase protection assays. This suggests that the dominant expression of the homogeneous TCR beta-chain is due to the expansion of the particular anti-FBL-3 CTL in the tumor in situ. Also, the TCR beta-chain, especially the V beta D beta region, rather than alpha-chain is more important for the recognition and selection of the anti-FBL-3 TIL with cytotoxic functions.     

T cell receptor gene segment utilization by HLA-DR1-alloreactive T cell clones.

Transplantation of histoincompatible tissues leads to allograft rejection, which involves recognition of allogeneic MHC molecules by Ag-specific receptors expressed on T cells. The interaction of these molecules is highly specific yet poorly understood. We have investigated the relationship between TCR gene utilization and allo-MHC restriction patterns by using a one-way polymerase chain reaction to amplify the alpha- and beta-chain mRNA from a panel of 10 HLA-DR1-alloreactive T lymphocyte clones. Two previously unreported V alpha and five J alpha gene sequences were obtained. Although a few V alpha, V beta, and J alpha genes were utilized more than once, no correlation between TCR gene usage and DR1 alloreactivity was identified. At the sequence level, the presumed TCR alpha- and beta-chain CDR1 and CDR2 regions displayed limited diversity, whereas the CDR3 or junctional sequences were highly variable. Although most TCR probably interact with subtly different surface features of the DR1 alloantigen, we predict that TCR with similar CDR1 and CDR2 sequences would contact essentially identical regions of the DR1 molecule. The lack of sequence conservation in the junctional regions suggests that different endogenous peptides also may be recognized. Thus, alloreactive T cells may recognize not only allogeneic MHC molecules but perhaps also bound endogenous peptides.     

Fine specificity of HLA-B27 cellular allorecognition. HLA-B27f is a functional variant distinguishable by cytolytic T cell clones

Three HLA-B27 allospecific cytolytic T lymphocyte (CTL) clones were isolated by limiting dilution of HLA-B27-negative responder cells stimulated with HLA-B27.1-positive lymphoblastoid cells. These clones displayed three distinct reaction patterns when tested for their lytic ability against target cells expressing various structurally defined HLA-B27 subtypes. One of the clones was specific for HLA-B27.1; a second CTL clone reacted only with B27.1 and, less efficiently, with B27.2; the third clone recognized both B27.1 and B27f targets but not cells expressing any other B27 subtype. These results indicate that HLA-B27f is a functional variant amenable to differential recognition by alloreactive CTL. A correlation of the structure of the HLA-B27 subtypes with the reactivity of these clones revealed that multiple B27-specific alloreactive CTL are activated against epitopes of the HLA-B27.1 molecule sharing common structural features. This illustrates the complexity and fine specificity of the allogeneic CTL response against class I HLA antigens and suggests that their immunodominant regions are those which are capable of eliciting a diverse polyclonal response against each of these regions, rather than inducing the selective expansion of a single T cell clone.     

Restricted V-(D)-J junctional regions in the T cell response to lambda-repressor. Identification of residues critical for antigen recognition.

The T cell response to lambda-repressor is directed to a 15 amino acid peptide (P12-26) of the protein in A/J mice. Previous studies have demonstrated a preferential use of V alpha 2 and V beta 1 amongst the T cell hybridomas specific for P12-26 in the context of I-Ek. By using the polymerase chain reaction, the sequences of a panel of the T cells using V alpha 2 and V beta 1 were determined. A highly conserved alpha-chain V-J junctional sequence was found in six of the eight T cell hybrids. This consensus alpha-chain VJ sequence may be combined with different members of V alpha 2, indicating a more restricted selection on the junctional region than on the V element in these T cells. In contrast, greater diversities were found on the V-D-J region of beta-chains despite the same V beta 1 and J beta 2.1 were used. However, a highly conserved glutamic acid residue was found at the same position of beta-chains where a similar conservation was identified in cytochrome c-specific T cells. The correlation of the TCR sequence with the fine specificities of these T cells suggests that a single amino acid deletion in the V alpha-J alpha region may reduce the P12-26 response and abolish the recognition of an altered peptide [Phe22] P12-26. In addition, three amino acid difference in the V-D-J region of the beta-chain also determine the P12-26 reactivity. Thus the V(D)J junctional regions of both alpha- and beta-chains may be critical for the recognition of the peptide Ag presented by the specific MHC molecule.     

Predominant T cell receptor gene elements in TNP-specific cytotoxic T cells.

H-2b class I-restricted, TNP-specific CTL clones were obtained by limiting dilution cloning of either short term polyclonal CTL lines or spleen cells of TNP-immunized mice directly ex vivo. Sequence analyses of mRNA coding for TCR alpha- and beta-chains of 11 clones derived from CTL lines from individual C57BL/6 mice revealed that all of them expressed unique but clearly nonrandom receptor structures. Five alpha-chains (45%) employed V alpha 10 gene elements, and four of those (36%) were associated with J beta 2.6-expressing beta-chains. The alpha-chains from these four TCR, moreover, contained an acidic amino acid in position 93 of their N or J region-determined sequences. Clones isolated directly from spleen cells carried these types of receptors at lower frequency, 27% V alpha 10 and 19% J beta 2.6, indicating that bulk in vitro cultivation on Ag leads to selection for these particular receptors. However, even in TNP-specific CTL cloned directly ex vivo, V alpha 10 usage was increased about fivefold over that in Ag-independently activated T cells in H-2b mice (4 to 5%). The selection for V alpha 10/J beta 2.6-expressing cells was obtained repeatedly in other TNP-specific CTL lines from C57BL/6 mice but not in FITC-specific CTL from the same strain or in TNP-specific CTL lines from B10.BR (H-2k) or B10.D2 (H-2d) mice. We conclude from this (a) that the selection for V alpha 10/J beta 2.6+ T cells is driven by the complementarity of these receptors to a combination of TNP and MHC epitopes and (b) that predominant receptor structures reflect the existence of a surprisingly limited number of "T cell-relevant" hapten determinants on the surface of covalently TNP-modified cells.     

Affinity enhancement and transmembrane signaling are associated with distinct epitopes on the CD8 alpha beta heterodimer.

CD8 is a heterodimeric membrane glycoprotein on MHC class I-restricted T lymphocytes that cooperates with the alpha beta CD3 TCR in the recognition of MHC class I molecules presenting antigenic peptides. Co-operation has two components: enhancement of the affinity of MHC/peptide-TCR interaction, and signal transduction through the T cell membrane. The cytolytic function of CTL is primarily dependent on the affinity-enhancement component of CD8-TCR cooperation whereas activation of resting CD8+ T cells is primarily dependent on transmembrane signaling. Using a panel of mAb, two to the alpha-chain and three to the beta-chain of CD8, we investigated the relationships between epitopes and functional regions of the CD8 molecule. Two of the antibodies, one to the alpha-chain and one to the beta-chain of CD8, inhibit the cytolytic function of CTL but not the generation of CTL from resting T cells. Another two antibodies, also one to the alpha- and one to the beta-chain, inhibited the generation of CTL while enhancing the cytolytic function of CTL. These results suggest that both the alpha- and beta-chain of CD8 possess two distinct regions, one involved in affinity enhancement and the other in transmembrane signaling. The former may be the MHC class I-binding region whereas the latter may associate with the alpha beta CD3 TCR. The data can explain the apparent functional equivalence of CD8 alpha alpha homodimers and alpha beta heterodimers.     

Conservation and alteration of HLA-B27-specific T cell epitopes on mouse cells. Implications for peptide-mediated alloreactivity.

Alloreactive CTL responses generate a great variety of clonal specificities. Such diversity may be related to recognition of multiple peptides constitutively bound to any given MHC alloantigen. Among human alloreactive CTL, only a fraction of the clones lyse mouse P815 cells expressing class I HLA proteins. In this study the fine specificity of HLA-B27 allorecognition on human or mouse cells by five human HLA-B27-specific CTL clones was comparatively analyzed. This was done to examine what degree of variation in epitope structure is compatible with recognition of HLA Ag on mouse cells. Nine site-specific HLA-B27 mutants were expressed on both human and mouse cells, after DNA-mediated gene transfer, to construct two analogous series of target cells. The reaction patterns of four of the five CTL clones with these cell panels were compatible with conservation of their corresponding epitopes upon expression of HLA-B27 on mouse cells. The reaction pattern of the fifth clone was different with either cell panel, indicating that its epitope was structurally altered on mouse cells. It also suggested a selectively increased expression of the determinant on these cells. The results suggest that most of the epitopes recognized by allospecific CTL clones reacting across species are either independent of any bound peptide or involve identical peptides from both cell types. However, some of these clones recognize alloantigen-bound peptides that are somewhat different in structure depending on the cell type, and may be expressed at the mouse cell surface in greater amounts. Such peptides could arise from related proteins in both species, and be polymorphic as a result of phylogenetic divergence.     

Conformational dimorphism of self-peptides and molecular mimicry in a disease-associated HLA-B27 subtype

An interesting property of certain peptides presented by major histocompatibility complex (MHC) molecules is their acquisition of a dual binding mode within the peptide binding groove. Using x-ray crystallography at 1.4 A resolution, we show here that the glucagon receptor-derived self-peptide pGR ((412)RRRWHRWRL(420)) is presented by the disease-associated human MHC class I subtype HLA-B*2705 in a dual conformation as well, with the middle of the peptide bent toward the floor of the peptide binding groove of the molecule in both binding modes. The conformations of pGR are compared here with those of another self-peptide (pVIPR, RRKWRRWHL) that is also displayed in two binding modes by HLA-B*2705 antigens and with that of the viral peptide pLMP2 (RRRWRRLTV). Conserved structural features suggest that the N-terminal halves of the peptides are crucial in allowing cytotoxic T lymphocyte (CTL) cross-reactivity. In addition, an analysis of T cell receptors (TCRs) from pGR- or pVIPR-directed, HLA-B27-restricted CTL clones demonstrates that TCR from distinct clones but with comparable reactivity may share CDR3alpha but not CDR3beta regions. Therefore, the cross-reactivity of these CTLs depends on TCR-CDR3alpha, is modulated by TCR-CDR3beta sequences, and is ultimately a consequence of the conformational dimorphism that characterizes binding of the self-peptides to HLA-B*2705. These results lend support to the concept that conformational dimorphisms of MHC class I-bound peptides might be connected with the occurrence of self-reactive CTL.     

T cell receptor genes in an alloreactive CTL clone: implications for rearrangement and germline diversity of variable gene segments.

Both cDNA and genomic clones of the T cell receptor (TCR) alpha- and beta-chain genes of the alloreactive cytotoxic T lymphocyte (CTL) clone F3 were examined. Two distinct rearrangement events, one functional and one non-functional, were found for both the alpha and beta loci. Thus only a single functional TCR alpha beta heterodimer could be defined, consistent with allelic exclusion in the TCR genes. The V alpha gene employed by F3 is part of a six-member V alpha subfamily. Genomic clones containing each member of this subfamily were isolated and the V alpha nucleotide sequences determined. Five of these six genes are functional; these genes differ from each other by 7-14% at the amino acid level. A single dominant hypervariable region was defined within this subfamily, in contrast to the pattern of variability seen between V alpha genes in general.     

Marked differences in the efficiency of expression of distinct alpha beta T cell receptor heterodimers

Ag recognition by most T lymphocytes is mediated by clonally distributed alpha beta heterodimeric receptors. A major fraction of TCR diversity is believed to be due to the random coexpression in individual T cells of the products of independently rearranging alpha- and beta-genes (combinatorial diversity). However, analysis of cell surface receptors on transfected T hybridoma cells synthesizing various sets of alpha- and beta-chains revealed marked differences in the efficiency of expression of certain alpha beta-pairs. Specifically, using the functionally rearranged gene products of the 2B4 cytochrome c specific T hybridoma (V beta 3, V alpha 11.2) and BW5147 parent lymphoma (V beta 1, V alpha BW), a hierarchy of expression efficiency relative to indirectly measured precursor chain levels in the cell was shown to be 2B4 alpha-BW beta greater than 2B4 alpha - 2B4 beta greater than BW alpha - BW beta greater than BW alpha - 2B4 beta. The estimated difference between the best expressed and worst expressed pairs is on the order of 50-fold. For the beta-chain, the primary determinant of expression efficiency with a given alpha-chain appears to be the V segment, as a second V beta 1-chain with distinct D and J regions from BW beta was expressed with the same pattern. These data imply that alpha- and beta-chains do not form well-expressed TCR in a random manner and that limitations on the useful combinatorial association of these chains may significantly affect the functional T cell repertoire.     

Structurally interdependent and independent regions of allelic polymorphism in class II MHC molecules. Implications for Ia function and evolution.

Possible interactions between regions of allelic polymorphism in the alpha- and beta-chains of class II MHC molecules were examined by measuring the efficiency of surface expression and the reactivity with mAb of wild-type and recombinant A alpha A beta-chain pairs from the b, d, and k haplotypes. These studies revealed regions of polymorphism within the alpha- and beta-chains that interact with complementary regions in the other chain. Unexpectedly, almost all the variable segments of both the class II MHC alpha- and beta-chains either directly contributed to or were near sites of interchain interactions. The exception was the beta HV3 (hypervariable (HV] segment (residues 61-71), which appeared to neither participate in nor be affected by interchain interactions. This division of the MHC molecule into interacting vs independent regions of allelic structural variation suggests that mutagenesis experiments involving the beta HV3 segment can be analyzed in a straightforward manner, as such mutations appear unlikely to alter the conformation of other molecular segments. Furthermore, functions attributed to the beta HV3 segment either experimentally or by population analysis should have a high probability of transfer by beta HV3 exchange (either experimentally or evolutionarily), because epitopes assigned to this region of the molecule are not affected by sequences outside this segment. This is of special importance because of the apparent involvement of this region in defining a potential site of interaction with antigenic peptides and TCR. In contrast, almost all other variable segments of the MHC molecule appear to have the capacity to contribute to interactions involving at least one other variable segment. This suggests not only that the experimental analysis of the contributions of these regions to various functions requires a consideration of inter- and intrachain interaction, but also that the transfer of function by genetic exchange of these structurally dependent regions is unpredictable. Selection must therefore operate on these interacting HV segments in the context of the complete alpha beta heterodimer. These results support our earlier arguments for cis-co-evolution of alpha- and beta-chain polymorphism and the absence of selection for F1 (hybrid) class II molecules. Finally, asymmetries observed in the contributions of particular pairs of HV segments to the efficient expression of Ia alpha beta heterodimers provide a basis for understanding mechanistically how cis-co-evolution may have occurred.     

Hapten addition to an MHC class I-binding peptide causes substantial adjustments of the TCR structure of the responding CD8(+) T cells

T cell responses against hapten-modified peptides play an important role in the pathogenesis of certain diseases, including contact dermatitis and allergy. However, the structural features of TCRs recognizing bulky, potentially mobile hapten groups remain poorly defined. To analyze the structural basis of TCR recognition of defined hapten-modified peptides, the immunodominant octapeptide derived from vesicular stomatitis virus nucleoprotein (VSV8) was modified with a trinitrophenyl (TNP) group at the primary TCR contact residues (position 4 or 6) and used for immunization of mice carrying either the TCR alpha- or beta-chain of a VSV8 (unmodified)/H-2K(b)-specific CTL clone as a transgene. Such mice allow independent analysis of one TCR chain by maintaining the other fixed. The TCR V gene usage of the responding T cell population was specifically altered depending upon the presence of the TNP group and its position on the peptide. The CDR3 sequences of the TNP-modified peptide-specific TCRs showed a preferential J region usage in both the CDR3alpha and beta loops, indicating that the J regions of both CDR3s are critical for recognition of TNP-modified peptides. In contrast to our previous observations showing the prime importance of CDR3beta residues encoded by D-segment or N-addition nucleotides for recognition of position 6 of unmodified VSV8, our studies of TNP-modified peptides demonstrate the importance of the Jbeta region, while the Jalpha region was crucial for recognizing both TNP-modified and unmodified peptides. These data suggest that different structural strategies are utilized by the CDR3alpha and beta loops to allow interaction with a haptenated peptide.     

Restricted V-segment usage in T-cell receptors from cytotoxic T lymphocytes specific for a major epitope of lymphocytic choriomeningitis virus.

Cytotoxic T lymphocytes (CTL) play an important role in recovery from a number of viral infections. They are also implicated in virus-induced immunopathology as best demonstrated in lymphocytic choriomeningitis virus (LCMV) infection of adult immunocompetent mice. In the present study, the structure of the T-cell receptor (TCR) in LCMV-specific CTL in C57BL/6 (B6) mice was investigated. Spleen T cells obtained from LCMV-infected mice were cultured in vitro with virus-infected stimulator cells and then stained with anti-TCR V beta antibodies. A skewing of V beta usage was noticeable in T cells enriched for their reactivity to LCMV, suggesting that particular V segments are important for the recognition of LCMV T-cell epitopes in B6 mice. To gain more detailed information on the structure of the TCR specific for LCMV epitopes, we studied CTL clones. It has been shown that approximately 90% of LCMV-reactive CTL clones generated in H-2b mice are specific for a short peptide fragment of the LCMV glycoprotein, residues 278 to 286, recognized in the context of the class I major histocompatibility complex molecule, Db. Four CTL clones possessing the specificity were randomly selected from a collection of clones, and their TCR genes were isolated by cDNA cloning or by the anchored polymerase chain reaction. All four clones were found to use V alpha gene segments belonging to the V alpha 4 subfamily. By RNA blot analysis, two more clones with the same specificity were also shown to express the V alpha 4 mRNA. In contrast, three different V beta gene segments were used among the four clones examined. J beta 2.1 was used by three of the clones. Although amino acid sequences in the V(D)J junctional regions were dissimilar, aspartic acid was found in the V alpha J alpha and/or V beta D beta J beta junctions of all four of these clones, suggesting that this residue is involved in binding the LCMV fragment. Restricted usage of V alpha and possibly J beta segments in the CTL response to a major T-cell epitope of LCMV raises the possibility that immunopathology in LCMV infection can be treated with antibodies directed against such TCR segments. Thus, similar analysis of the TCR in other virus infections is warranted and may lead to therapeutic strategies for immunopathology due to virus infections.     

Delineation of determinants on HLA-B7 and HLA-B27 that are necessary for cytolytic T cell recognition by using inter- and intra-domain recombinants

We have used bulk culture HLA-B7 and HLA-B27 specific CTL lines derived from 11 donors, and a series of rHLA-B7/HLA-B27 genes transfected into and expressed on the surface of the murine cell P815, to determine the amino acid residues on these HLA class I molecules that are critical for allospecific CTL recognition. The results obtained indicate that for four of six HLA-B7-specific CTL lines the alpha-1 domain for CTL recognition. Furthermore, we found that residues 77 and/or 80 had a critical effect on recognition for all of the CTL lines tested. The region 97-156 in the alpha-2 domain was also important for some of these CTL lines. Furthermore, by using five bulk culture HLA-B27-specific CTL lines we were able to show that residues 77 and/or 80 and residue 152 are also essential for recognition of HLA-B27 by HLA-B27-specific CTL. The strong influence exerted by these residues is discussed in terms of the three-dimensional structure of class I molecules. Finally, a selection was regularly observed in the bulk cultures such that the CTL that were preferentially influenced by either the alpha-1 or the alpha-2 domain were lost after 4 to 7 wk of culture resulting in CTL cell lines which were extremely sensitive to sequence modifications of HLA-B7 or HLA-B27. The possible reasons for this selection, which we have previously observed with both anti-HLA-A2 and anti-HLA-A3 cell lines and is therefore not unique to HLA-B7 or HLA-B27, are discussed.     

T cell receptor junctional regions and the MHC molecule affect the recognition of antigenic peptides by T cell clones.

Nine independent pigeon cytochrome c-specific T cell clones were analyzed by using a panel of antigenic peptide analogs presented in association with three allelic IE-encoded MHC glycoproteins. Eight of the T cell clones expressed a TCR composed of a unique alpha- and beta-chain amino acid sequence, and concordantly, each of these T cell clones exhibited a unique Ag specificity. This was true for several clones which differed only in TCR V-J junctional regions. Interestingly, for a given clone, the response to some of the peptide analogs depended to a large extent on the allelic form of the presenting MHC molecule. A simple interpretation of these data would suggest that certain positions of the peptide Ag are most important for Ag-MHC molecule interactions, and that these specific interactions can influence the antigenic epitope recognized by the TCR. We suggest that an antigenic peptide binds to an MHC glycoprotein in a distinct way, but may retain a measure of flexibility.     

CTL recognition of a bulged viral peptide involves biased TCR selection

MHC class I molecules generally present peptides of 8-10 aa long, forming an extended coil in the HLA cleft. Although longer peptides can also bind to class I molecules, they tend to bulge from the cleft and it is not known whether the TCR repertoire has sufficient plasticity to recognize these determinants during the antiviral CTL response. In this study, we show that unrelated individuals infected with EBV generate a significant CTL response directed toward an HLA-B*3501-restricted, 11-mer epitope from the BZLF1 Ag. The 11-mer determinant adopts a highly bulged conformation with seven of the peptide side chains being solvent-exposed and available for TCR interaction. Such a complex potentially creates a structural challenge for TCR corecognition of both HLA-B*3501 and the peptide Ag. Surprisingly, unrelated B*3501 donors recognizing the 11-mer use identical or closely related alphabeta TCR sequences that share particular CDR3 motifs. Within the small number of dominant CTL clonotypes observed, each has discrete fine specificity for the exposed side chain residues of the peptide. The data show that bulged viral peptides are indeed immunogenic but suggest that the highly constrained TCR repertoire reflects a limit to TCR diversity when responding to some unusual MHC peptide ligands.     

Structure and diversity of HLA-B27-specific T cell epitopes. Analysis with site-directed mutants mimicking HLA-B27 subtype polymorphism.

HLA-B27 subtype polymorphism is amenable to differential recognition by CTL. Site-directed mutagenesis was used to construct a series of HLA-B27 mutants reproducing most of the changes occurring in the natural subtypes. The reactivity of 21 anti-HLA-B27 CTL clones was examined with these mutants to address three issues concerning the alloreactive response against HLA-B27: 1) diversity of clonotypic specificities, 2) structural features of the epitopes recognized by these clones, and 3) role of individual positions in the differential recognition of HLA-B27 subtypes. Virtually all CTL clones displayed unique reaction patterns with the mutants, indicating a corresponding diversity of epitopes. However, these share some molecular features, such as certain amino acid residues and related locations. Individual mutations induced complex effects on multiple B27-specific CTL epitopes, revealing some of their very precise stereochemical constrains. An important feature of HLA-B27 subtype polymorphism is that every individual change was relevant, altering recognition by many CTL clones. Although the specific set affected by each mutation was partially different, the global number of clones affected by most changes was very similar. This suggests that the antigenic profile of any given subtype is not dominated by one particular change but is uniquely defined by its corresponding set of changes. An exception was the change at position 152, which totally abrogated recognition by all 20 anti-B*2705 CTL clones. This effect decisively influences the profound differences in T cell recognition between B*2705 and the two subtypes, B*2704 and B*2706, carrying this change. The results are compatible with the idea that HLA-B27 allorecognition may involve multiple peptides bound to the alloantigen on the cell surface.     

Predominant use of a T-cell receptor V beta gene family in simian immunodeficiency virus Gag-specific cytotoxic T lymphocytes in a rhesus monkey.

To explore the structural basis for AIDS virus recognition by CD8+ lymphocytes, we sought to determine whether there is a diverse or restricted usage of T-cell receptors (TCR) by simian immunodeficiency virus of macaques (SIVmac) Gag-specific cytotoxic T lymphocytes (CTL) in the rhesus monkey. Six Gag-specific CTL clones were independently generated from an SIVmac-infected rhesus monkey. All six CTL clones recognized a single SIVmac Gag peptide in association with a single major histocompatibility complex class I gene product, Mamu-A*01. TCR alpha-chain sequences from these six CTL clones employed four different V alpha families and five different J alpha gene segments. In contrast, five of the six CTL clones expressed V beta genes that were members of the same family, a human V beta 23 homolog. Furthermore, only one J beta gene was expressed by four of the six CTL clones. These results indicate that TCR of SIVmac Gag-specific CTL from a rhesus monkey can exhibit a restricted usage of V beta gene families and J beta genes.     

The human T cell receptor beta-chain gene complex contains at least 57 variable gene segments. Identification of six V beta genes in four new gene families.

The human TCR beta-chain gene complex includes at least 57 variable (V) gene segments, a number estimated using a combination of Southern blots of conventional and pulsed field gels, sequence analysis of cDNA clones, and from the analysis of genomic cosmid and phage clones. This number includes six TCR beta-chain V genes in four new families identified here by sequence analysis of clones derived from a human TCR beta-chain specific cDNA library. Comparison of the sequences of the new V beta genes with previously reported V beta sequences reveals predicted similarities but less than 75% nucleic acid identity that establishes them as new V beta families. One of the new V beta gene families includes three genes and the other three are single member families. Identification of these six new V beta genes falling into four V beta families brings the total number of transcribed human V beta families to 24 and makes it possible to refine the estimate of the total number of human TCR V beta genes to 57.