Structure,diversity, and evolution of the T-cell receptor VB gene repertoire in primates

AB T-cell receptors (TCR) that recognize major histocompatibility complex (MHC)/peptide antigen complexes regulate humoral and cellular arms of the adaptive immune response. Antigen binding sites of MHC and immunoglobulin heavy chain variable regions(Igh-V) are subject to diversity enhancing selection. We sought to establish whether positive Darwinian selection has driven diversity of TCRBV chains in the primate lineage by sequencing rearranged TCR from rhesus monkeys and chimpanzees and comparing them with those of humans. Rates of synonymous (silent) and nonsynonymous (replacement) substitutions indicate selection against amino acid replacements in TCRBV frameworks, and relaxation of these constraints in putative MHC/peptide contact sites. The lack of positive selection for variability in likely ligand contact sites suggests that mechanisms generating somatic diversity in TCR junctional regions have relaxed the pressure for selection of variability in the TCR V region encoded in the germline.     

Isolation of monotreme T-cell receptor α and β chains

Monotremes are an ancient mammalian lineage that last shared a common ancestor with the marsupial and eutherian (placental) mammals about 170 million years ago. Characterization of their immune genes is allowing us to gain insights into the evolutionary processes that lead to the mammalian immune response. Here we describe the characterization of the first cDNA clones encoding T-cell receptors from a monotreme. Two TCR -chain cDNAs (TCRA) from the short-beaked echidna, Tachyglossus aculeatus, containing complete variable, joining and constant regions were isolated. The echidna TCRA constant region shares approximately 37% amino acid identity with other mammalian TCRA constant region sequences. The two variable regions belong to the TCRAV group C, which also contains V genes from humans, mice, cattle and chickens. One echidna TCR -chain cDNA (TCRB) containing the entire constant region was isolated and sequenced. It shares about 63% identity with other mammalian TCRB constant region sequences. The echidna TCRBV belongs to TCRBV group A, which also contains V genes from various eutherian species. Southern blot analysis indicates that, like in other mammalian species, there is only one TCRA constant region copy in the echidna genome, but at least two TCRB constant regions.     

Human T-cell receptor variable gene segment families

Multiple DNA and protein sequence alignments have been constructed for the human T-cell receptor /, , and (TCRA/D, B, and G) variable (V) gene segments. The traditional classification into subfamilies was confirmed using a much larger pool of sequences. For each sequence, a name was derived which complies with the standard nomenclature. The traditional numbering of V gene segments in the order of their discovery was continued and changed when in conflict with names of other segments. By discriminating between alleles at the same locus versus genes from different loci, we were able to reduce the number of more than 150 different TCRBV sequences in the database to a repertoire of only 47 functional TCRBV gene segments. An extension of this analysis to the over 100 TCRAV sequences results in a predicted repertoire of 42 functional TCRAV gene segments. Our alignment revealed two residues that distinguish between the highly homologous V and V, one at a site that in V_H contacts the constant region, the other at the interface between immunoglobulin V_H and V_L. This site may be responsible for restricted pairing between certain V and V chains. On the other hand, V and V appear to be related by the fact that their CDR2 legnth is increased by four residues as compared with that of V/ peptides.The alignment data reported in this paper have been submitted to the EMBL nucleotide sequence database and have been assigned the aligmment number DS23485. The data are available by the EBI FTP server and file serverCorrespondence with corrections or new information concerning the TCRV sequences is strongly encouraged.     

Different TCRBV genes generate biased patterns of V-D-J diversity in human T cells

The aim of this work was to assess whether each T-cell receptor (TCR) BV segment generates a random pattern of junctional diversity or if, alternatively, biased patterns of V-D-J rearrangements limit the number of available TCR specificities. Detailed molecular analysis of T-cell receptors expressed by lymphocytes was obtained by generating a large number of junctional regions sequences from TCRBV3, TCRBV4, TCRBV5S1, TCRBV12, TCRBV13S2, TCRBV17, TCRBV20, and TCRBV22 variable genes. The > 800 sequences analyzed have allowed the characterization of the recombination frequencies of each germline-encoded V,D, and J segments, as well as of the magnitude of exonucleolytic nibbling and of the number of N nucleotides inserted for each group of TCRB segments. The data obtained indicate that the extent of junctional diversity varies considerably depending on the TCRBV gene implicated in the recombination event, due to the occurrence of skewed patterns of J and D region usage. Furthermore, our results show that illegitimate rearrangements occur with unexpectedly high incidence, specifically at the level of TCRBD to TCRBJ joining. These findings provide additional information for a more accurate estimation of the size of the TCRBV repertoire and for understanding the well-established biased pattern of TCRBV expression in humans.The nucleotide sequence data reported in this paper have been submitted to the EMBL nucleotide sequence database and have been assigned the accession number DS 19973     

Diversity of TCRAV and TCRBV sequences used by human T-cell clones specific for a minimal epitope of Bet v 1, the major birch pollen allergen

T-cell clones (TCC) were raised from the peripheral blood of patients suffering from tree pollen allergy. All TCC were restricted by HLA-DR molecules. In order to investigate possible intervention targets in Type I allergic diseases, we examined T-cell receptor (TCR) and chain nucleotide sequences of five allergen-reactive human CD4⁺ TCC specific for a C-terminal epitope (BV 144) of Bet v 1, the major birch pollen allergen. Proliferation assays using synthetic peptides revealed the 10-mer LRAVESYLLA as minimal epitope for three TCC; two TCC also displayed reactivity with the nonapeptide LRAVESYLL. Two TCC expressed TCRBV2S3, all other BV144-specific TCC used diverse TCRAV and TCRBV gene segments. Moreover, the junctional regions encoding the third complementary determining regions (CDR3) of the TCR showed a striking heterogeneity in length and amino acid composition. Nevertheless, all TCC showed an arginine residue in the N-terminal region of their TCRBV CDR3 loops. Therefore, therapeutical strategies aimed at the clonal deletion of allergen-specific T-cell clones, providing help for IgE synthesis, will not be feasible. Our results cast a doubt on the theory that the CDR3 exclusively provides the primary contact with the peptide bound in the major histocompatibility (MHC) groove, and suggest additional interaction with MHC class II.The nucleotide sequence data reported in this paper have been submitted to the EMBL nucleotide sequence database and have been assigned the accession numbers Z47366-Z47376     

Physical mapping of the human T-cell receptor beta gene complex,using yeast artificial chromosomes

Yeast artificial chromosomes (YACs) were used to construct a physical map of the germline human T-cell chain gene complex (TCRB). Variable region genes (BV) for the 25 known subfamilies were used as probes to screen the ICRF AM4x YAC library. Of the five positive YACs identified, one YAC designated B3, 820 kilobase pairs (kbp) in size, scored positive for all 25 TCRBV subfamilies plus the constant region genes (BC) when analyzed by pulse field gel electrophoresis. Restriction enzyme mapping of B3 located TCRBV and TCRBC gene regions to 4 Sfi I fragments of 280 110, 90, and 125 kbp and was in accordance with published data. In addition comparison of hybridization results of Sfi I-restricted B3 and genomic DNA from the parental cell line GM1416B revealed identical banding patterns. The data thus showed YAC B3 encoded a complete and unrearranged TCRB gene locus of some 600–620 kbp. The map was further resolved by locating restriction sites for Sal I and Bss HII on B3, giving more precise localization of the individual TCRBV gene families. Flourescent in situ hybridization of B3 to spreads of human metaphase chromosomes localized B3 to 7q35. However, two additional signals were obtained; one attributable to the TCRBV orphon cluster on 9p21, the second to the long arm of chromosome 2. Polymerase chain reaction amplification of a chromosome 2 somatic cell hybrid, using primers for all 25 TCRBV gene families, revealed that the signal was not attributable to a second orphon cluster. It is suggested that B3 is a chimeric YAC with an intact TCRB locus flanked by chromosome 2 sequences.     

The human T-cell receptor β-chain repertoire: longitudinal fluctuations and assessment in MHC matched populations

The influence of the environment and of the major histocompatibility complex (MHC) in shaping the human T-cell receptor -chain variable region (TCRBV) repertoire has not been systematically studied. Here, expression of TCRBV gene families was estimated by a sensitive polymerase chain reaction (PCR)-based method. Serial studies of peripheral blood, performed at 2-week intervals over a 3-month period, revealed that fluctuation in the expression of many TCRBV genes occurred in healthy individuals and in the absence of clinically evident infections. Fluctuation of TCRBV4, TCRBV5.2, TCRBV9, and TCRBV13.1 genes were present in all subjects. Additional TCRBV genes fluctuated in some but not in other individuals. Comparison of the TCRBV repertoire between these unrelated individuals indicated differences in the mean expression of TCRBV5.1, TCRBV9, TCRBV11, TCRBV15, TCRBV17, and TCRBV20 genes. For any TCRBV gene, intersubject differences were generally of a magnitude of twofold or less. Larger differences characterized the TCRBV repertoire of CD4 compared to CD8 cells. Some differences, for example over-representation of TCRBV2 and TCRBV5.1 on CD4, and TCRBV10, TCRBV14, and TCRBV16 on CD8 cells, were present in most subjects. Individuals homozygous for DR2- or DR3-bearing extended MHC haplotypes displayed similar individual variability of TCRBV expression. These data indicate that the circulating TCRBV repertoire in humans is both dynamic and diverse. Both environment and MHC effects contribute to the diversity of TCRBV expression.     

Polymorphism detection and sequence analysis of human T-cell receptor Vα-chain-encoding gene segments

The T-cell receptor (Tcr) provides specificity for antigen recognition by its variable domain, primarily consisting of two germline encoded variable (V) region gene segments. Thus it has been suggested that inherited polymorphisms in the TCRV gene segments could contribute to differential immune responsiveness (e.g., autoimmunity) in human populations. In the present study, we have sought potentially functional polymorphisms in the germline TCRAV gene segments. Using denaturing gradient gel electrophoresis on polymerase chain reaction (PCR)-amplified products from the pooled DNA of many individuals, we identified polymorphisms in the TCRAV2S1, AV4S1, AV7S1, and AV8S1 gene segments. A complete DNA sequence analysis of these PCR products identified polymorphisms that affected amino acids in the predicted antigen-binding regions of the Tcr chain, as well as polymorphisms in the introns. Genotype analysis of all nine DNA point mutations showed a 5%–50% range (averaging 35%) of minor allele frequencies, often resulting in individuals homozygous for the alternate allele forms. All possible haplotype combinations of the amino acid-affecting polymorphisms were found, indicating that in human populations there are a large number of different germline haplotypes encoding V gene segment alleles. These TCRAV coding region polymorphisms provide the rationale for, and allow the direct testing of, hypotheses concerning inherited polymorphisms within the T-cell receptor genes that may contribute to autoimmune susceptibility.The nucleotide sequence data reported in this paper have been submitted to the Genbank nucleotide sequence database and have been assigned the accession numbers L11159–L11162.     

Analysis of T cell receptor β and γ genes from peripheral blood,regional lymph node and tumor-infiltrating lymphocyte clones from melanoma patients

Summary A total of 199 T cell clones from two melanoma patients were derived from progenitor T cells from recurrent melanoma, regional lymph nodes (either involved or uninvolved with malignancy) and peripheral blood by inoculating single cells directly into the wells of microtiter plates before in vitro expansion. The surface marker phenotype of most clones was CD4⁺CD8^–, although some were CD4^–CD8⁺. Genomic DNA prepared from all clones was analyzed by Southern blot hybridization using T cell receptor (TCR) and gene probes, seeking clones with identical TCR gene rearrangement patterns as direct evidence for in vivo progenitor T cell clonal amplification. ProbingHindIII-digested DNA with TCR and TCR probes revealed several clones with identical TCR gene rearrangement patterns. These clones had subsequent probing ofBamHI-digested DNA with TCR and TCR probes, which showed all but 2 clones to have distinct rearrangement patterns. These analyses provide clear molecular evidence for in vivo polyclonal CD4⁺ T cell populations in each of several separate immune compartments in these patients.This investigation was supported by National Institutes of Health, National Research Service Award CA-08 397 from the National Cancer Institute as well as NIH CA-32 685, CA-30 688, DOE FG028 760 502 and American Cancer Society Grant ACS CH-237     

Characterization of horse (Equus caballus) T-cell receptor beta chain genes

Genes encoding the horse (Equus caballus) T-cell receptor beta chain (TCRB) were cloned and characterized. Of 33 cDNA clones isolated from the mesenteric lymph node, 30 had functionally rearranged gene segments, and three contained germline sequences. Sixteen unique variable segments (TCRBV), 14 joining genes (TCRBJ), and two constant region genes (TCRBC) were identified. Horse TCRBV were grouped into nine families based on similarity to human sequences. TCRBV2 and TCRBV12 were the most commonly represented horse families. Analysis of predicted protein structure revealed the presence of conserved regions similar to those seen in TCRB of other species. A decanucleotide promoter sequence homologous to those found in humans and mice was located in the 5 untranslated region of one horse gene. Germline sequences included the 5 region of the TCRBD2 gene with flanking heptamer/nonamer recombination signals and portions of the TCRBJ-C2 intron. Southern blot hybridizations demonstrated restriction fragment length polymorphisms at the TCRBC locus among different horse breeds.     

PCR-based genotyping and haplotype analysis of human TCRBV gene segment polymorphisms

There are at least 63 tandemly arranged human T-cell receptor (Tcr) -chain variable region (BV) gene segments, which have presumably arisen by repeated gene duplication events. The 5-most half of the TCRBV gene loci is particularly complex in organization due to the presence of multiple interspersed members of the largest BV subfamilies, BV5, BV6, and BV13. Polymorphism and linkage relationships among these genes has been poorly characterized in part due to the high similarity of these duplicands. Germline DNA polymorphisms were specifically examined in the exons and introns of these and other BV gene segments distributed across 240 kilobases (kb) in this 5-most region. Polymerase chain reaction restriction enzyme-based assays were used to genotype ten point mutations in seven of the BV gene segments. Eight of these polymorphisms altered an amino acid of the BV gene segment. In addition, length polymorphisms due to simple sequence repeats were noted in the introns of six BV6 subfamily members. Approximately 250 unrelated haplotypes were constructed by segregation analyses of fifteen of these TCRBV polymorphisms. Linkage disequilibrium analyses indicated that haplotypic relationships are not detectable over a distance of more than 55 kb in this genomic region. These TCRBV polymorphisms, and the haplotypic analysis, provide important resources and guidance for future attempts to associate Tcr germline DNA differences in the human population with immune response differences, such as might occur in some autoimmune diseases.     

Rapid cloning of any rearranged mouse immunoglobulin variable genes

Immunoglobulins (Ig) have been the focus of extensive study for several decades and have become an important research area for immunologists and molecular biologist. The use of polymerase chain reaction (PCR) technology has accelerated the cloning, sequencing, and characterization of genes of the immune system. However, cloning and sequencing the Ig variable (V) genes using the PCR technology has been a challenging task, primarily due to the very diverse nature of Ig V region genes. We have developed a simple, rapid, and reproducible PCR-based technique to clone any rearranged mouse Ig heavy or light chain genes. A close examination of all Ig heavy and light chain V gene families has resulted in the design of 5 and 3 universal primers from regions that are highly conserved across all heavy or light chain V gene families, and the joining or constant regions, respectively. We present our strategy for designing universal primers for Ig V gene families. These primers were able to rapidly amplify the rearranged Ig V genes, belonging to diverse Ig V gene families from very different cell lines, i.e., J558, MOPC-21, 36–60, and a chicken ovalbumin specific B-cell hybridoma. In addition, the present study provides the complete alignment of nucleotide sequences of all heavy and light chain variable gene families. This powerful method of cloning Ig V genes, therefore, allows rapid and precise analysis of B-cell hybridomas, B-cell repertoire, and B-cell ontogeny.The nucloetide sequence data reported in this paper have been submitted to the EMBL/GenBank nucleotide sequence database and have been assigned the accession number U32111     

Effect of dexamethasone on T-cell receptor/CD3 expression

Glucocorticoid hormones (GCH) are anti-inflammatory and immunosuppressive agents that inhibit T-cell growth and activation. Since the T-cell receptor (TCR)/CD3 complex mediates T-lymphocyte activation, we studied the effect of in vitro dexamethasone (DEX), a synthetic GCH, on TCR/CD3 expression.DEX-treatment of a hybridoma T-cell line and normal un-transformed T-cell clones induced a decrease of the TCR/CD3 membrane expression after 4 days. After 4 weeks, TCR/CD3 was undetectable. However, the amount of mRNAs coding TCR/CD3 chains, including TCR, TCR, CD3, CD3 and CD3, as well as the amount of CD3 protein, a major component of the complex, were unaltered. By contrast, a decrease of the mRNAs deriving from the TCR gene locus, as well as of the TCR protein which is responsible for the membrane expression of the TCR/CD3 complex, was induced.These data suggest that the down-modulation of TCR expression is due to the diminution of TCR gene products in DEX-treated cells. (Mol Cell Biochem 167: 135-144, 1997)     

The extent of the human germline T-cell receptor V beta gene segment repertoire

An assessment of the size of the human TCRBV gene segment repertoire based on the identification of TCRBV gene segments in genomic DNA was undertaken. PCR amplification from cloned and uncloned genomic DNA sources, nucleotide sequencing, Southern blot hybridization, and cosmid cloning were used to identify TCRBV gene segments in multiple unrelated individuals. The key advantages to this approach were: (1) TCRBV gene segments which are expressed only at very low levels in cDNA libraries were still detectable, and (2) it was possible to discriminate between alleles at the same locus vs products of different loci. A total of 63 unique TCRBV gene segments were identified and sequenced. Six of these TCRBV gene segments had not been previously described. Thirty-four cosmid clones containing 51 of the 63 identified TCRBV gene segments were isolated and screened for the presence of additional novel TCRBV subfamily members. These results, obtained by a variety of complementary approaches, indicate that the human TCRBV gene segments of which 52 are functional. The availability of the majority of these TCRBV gene segments on cosmid clones should facilitate further investigation of germline TCRBV gene segment polymorphism and putative disease associations.     

Mapping of antibody specificities to V H gene families

V _H gene segments represent the products of the repeated duplication and subsequent diversification of a primordial V gene element. It is widely assumed that natural selection, operating via pathogens, has played the dominant role in this process. Here, we screen some 3.7 × 10⁴ C ⁺ colonies of mitogen-activated B cells for the production of antibodies specific for phosphorylcholine or hen egg lysozyme and expression of the V _H X-24, S107, Q52, or J558 gene families. These gene families were expressed at frequencies proportional to their genomic complexity among both unselected and antigen-specific C ⁺ colonies. Thus, the capacity to encode equivalent antibody-combining sites is dispersed uniformly among V _Hfamilies. This result suggests that individual V _H genes have not evolved to address specific antigens.     

Molecular genotyping of human T-cell antigen receptor variable gene segments

The gene complex encoding the chain of the T-cell antigen receptor (Tcr) in man was previously reported to contain a restriction fragment length polymorphism (RFLP) involving a single Bgl II site adjacent to the second constant region gene. This RFLP allowed assignment of Tcr genotypes in certain human families. In the present study, two different RFLP in a V gene family were detected using the murine probe V8.1 in genomic DNA samples digested with the restriction endonucleases Hind III and Bam HI. Use of these RFLP to mark the V gene complex allowed complete haplotype assignment in four of seven families studied and provided support for linkage of the V gene complex to the constant region genes. Different combinations of the C and two V region markers can result in eight possible distinct haplotypes. The observation of all but one of the eight possible haplotypes in parents of the families studied suggests that recombination events occur between the C and V region and among members of the V region subfamily marked by the V8.1 probe. These markers can be used for mapping studies of the V gene complex in man and will allow an appraisal of possible associations between Tcr genes and disease susceptibility.Abbreviations used in this paper: Tcr T-cell antigen receptor - RFLP restriction fragment length polymorphism - C2 second Tcr constant region gene - V Variable - C constant - J joining - D diversity     

Evolution of the variable gene segments and recombination signal sequences of the human T-cell receptor α/δ locus

The T-cell receptor (TCR) and loci are particularly interesting because of their unique genomic structure, in that the gene segments for each locus are interspersed. The origin of this remarkable gene segment arrangement is obscure. In this report, we investigated the evolution of the TCR and variable loci and their respective recombination signal sequences (RSSs). Our phylogenetic analyses divided the and variable gene segments into two major groups each with distinguishing motifs in both the framework and complementarity determining regions (CDRs). Sequence analyses revealed that TCR variable segments share similar CDR2 sequences with immunoglobulin light chain variable segments, possibly revealing similar evolutionary histories. Maximum likelihood analysis of the region on Chromosome 14q11.2 containing the loci revealed two possible ancestral TCR / variable segments, TRDV2 and TRAV1-1/1-2, respectively. Maximum parsimony revealed different evolutionary patterns between the variable segment and RSS of the same variable gene arguing for dissimilar evolutionary origins. Two models could account for this difference: a V(D)J recombination activity involving embedded heptamer-like motifs in the germline genome, or, more plausibly, an unequal sister chromatid crossing-over. Either mechanism would have resulted in increased diversity for the adaptive immune system.     

Cytotoxic activity and T cell receptor repertoire in tumor-infiltrating lymphocytes of adrenal cell carcinomas

The cytotoxic activity and T cell receptor (TCR) V repertoire in tumor-infiltrating lymphocytes (TIL) of three primary adrenal cell carcinomas were analyzed. Fresh, non-cultured TIL from two of the three tumors showed low but significant lysis of the autologous tumor, and for one of the patients this activity was strongly enhanced upon culture in interleukin-2. An allogeneic adrenal cell carcinoma line and the K562 or Daudi targets included as controls were not killed. Phenotypic analysis of freshly isolated TIL demonstrated that the cells from the two patients that demonstrated cytolytic capacity mainly consisted of CD45RO⁺ T cells. In vitro cultured TIL lines from these patients demonstrated a high percentage of CD8⁺ cells expressing either the V6 gene or the V8 gene product, as measured with a panel of mAb specific for TCR V and V gene products. Analysis of the TCR V gene mRNA expression in freshly isolated non-cultured TIL, using a polymerase-chain-reaction-assisted cDNA-amplification assay, confirmed the strong expression of the genes coding for the TCR V6 or the V8. This assay also demonstrated a more restricted TCR V gene usage in the TIL as compared to peripheral blood lymphocytes from the same patient.This study was supported by the Swedish Cancer Society and by the Cancer Society in Stockholm     

Allelic polymorphism of T-cell receptor constant domains is widespread in fishes

T-cell receptor chains contain membrane-proximal constant domains of the immunoglobulin superfamily that are relatively invariant in mammalian species. In contrast, recent studies in the bicolor damselfish have demonstrated surprising allelic polymorphism in the TCR alpha (A) and TCR beta (B) constant (C) domain genes. This report extends these initial observations beyond Perciformes to two other orders of teleost fishes. Studies in both the Atlantic cod and zebrafish show high levels of polymorphism in the TCRA constant genes. Levels of 13% and 15% amino acid nonidentity were found within cod and zebrafish, respectively. Evolutionary analysis of codon usage suggests that positive selection maintains the high number of TCRAC alleles in these fish populations. Additionally, investigation of a TCRB constant gene from the Beau Gregory, a sister species of the bicolor damselfish, shows no evidence of transpecies maintenance of constant region alleles. These data argue that the T-cell receptor constant domain is being employed by many vertebrates in a manner inconsistent with our current understanding, and may indicate unheralded complexity in signal transduction through the TCR/CD3 complex.Electronic Supplementary Material Supplementary material is available in the online version of this article at M.F. Criscitiello and N.E. Wermenstam contributed equally to this workNucleotide sequence data reported here are available in the GenBank database under the accession numbers AJ439464–AJ439499 and AY476721–AY476734.