Identification and physical mapping of a polymorphic human T cell receptor V beta gene with a frequent null allele

CD4+ and CD8+ T-cell skewness in classic Kaposi sarcoma

It is widely accepted that a deranged immune system plays a key role in the onset and evolution of classic Kaposi sarcoma (CKS). Nevertheless, the usage of the T-cell receptor (TCR) β-variable (BV) chain repertoire expressed by peripheral blood lymphocytes in patients with CKS is still unknown. With the aim of providing some further insights into the complex role of the immune system in CKS pathogenesis, we performed an extensive analysis of the TCR BV repertoire in both CD4(+) and CD8(+) T cells in 30 human herpesvirus 8-positive Sardinian patients with CKS and an equal number of age-matched healthy controls. We used a panel of monoclonal antibodies covering approximately 70% of human BV subfamilies and third complementarity determining region (CDR3) spectratyping. Patients with CKS showed an increased frequency of BV expansions in both CD4(+) and CD8(+) lymphocytes, with no prevalent clones. On spectratyping analysis, most of the 720 BV CDR3 profiles obtained from both CD4(+) and CD8(+) T cells in patients with CKS were skewed. In particular, the surprising increase of BV skewing observed in CD4(+) lymphocytes mimics the pattern of progressive TCR BV narrowing described in responses to persistent viral antigen stimulations. Our findings support the hypothesis that CKS evolution is associated with inadequate activation rather than impairment of the immune system.

TCRBV20S1 polymorphism does not influence the susceptibility to type 1 diabetes and multiple sclerosis in the Sardinian population

Among the different T-cell receptor (TCR) BV20S1 polymorphisms, nucleotide substitution at position 524 results in the introduction of a stop codon, whose potential functional relevance is still unknown. We have recently showed in Sardinian subjects the most elevated allele frequency ever reported worldwide for this "null allele" (0.44). As this variant generates a gap in the TCR repertoire, this preliminary finding prompted us to further analyze the role of this polymorphism in the susceptibility to type 1 diabetes (T1D) and multiple sclerosis (MS), which are extremely common in this population. With this aim, we evaluated the influence of the TCRBV20S1 polymorphism by assessing it with the transmission disequilibirum test (TDT) in 652 T1D and 616 MS families, without detecting any significant difference. We conclude that the high frequency of this null allele in Sardinia is not directly related to the high incidence of these autoimmune diseases observed in this founder population.

High frequency of the TCRBV20S1 null allele in the Sardinian population

Single nucleotide polymorphisms (SNPs) in the T-cell receptor (TCR) gene segments might play a role in shaping the TCR repertoire. Three polymorphisms have been described for the TCRBV20S1 gene segment, one of which is responsible for a nucleotide substitution at position 524, resulting in the introduction of a stop codon. Individuals homozygous for this inactivating polymorphism ("null allele") are unable to express TCRBV20 gene products. Using DNA restriction digestion analysis, we investigated the frequency of this polymorphism in 111 healthy Sardinian subjects. Inhabitants of the Mediterranean island of Sardinia are considered to represent a genetically isolated population. Our analyses revealed an incidence of 19.8% of homozygosity for the null allele, corresponding to an allele frequency of 0.45. Such an incidence, significantly higher than the one detected in 83 non-Sardinian Caucasians (6%), is the most elevated so far reported in the literature. BV20 is a single member subfamily and the null allele produces a gap in the potential TCR repertoire. Therefore, it is possible that an undetermined selective pressure could have played a role in determining the high frequency of this inactivating polymorphism in Sardinians. Alternatively, this finding could be related to a founder effect in this ancient island population.

Variability in TRBV haplotype frequency and composition in Caucasian, African American, Western African and Chinese populations

The polymorphic T-cell receptor Vbeta (TRBV) genes encode much of the variable region of the T-cell receptor beta chain. Analysis of allele frequencies of three closely linked polymorphic TRBV genes, TRBV7-3, TRBV9 and TRBV6-4, was undertaken in several populations. The frequencies of these alleles are not significantly different in populations of Caucasians, African Americans and Western Africans. However, Chinese population is extremely homogenous at all three loci. The current study identifies the existence of haplotypic relationships between alleles of these genes in the Caucasian population. The ORF allele TRBV7-3*A3 is found exclusively on chromosomes bearing TRBV9*A2 and TRBV6-4*A2 in this cohort. In contrast, TRBV7-3*A1 and the null allele TRBV7-3*A2 are associated only with TRBV9*A1 and TRBV6-4*A1. This pattern of linkage disequilibrium (LD) is altered in the African American and Western African populations. In these cohorts, there is a marked reduction in LD between alleles of TRBV7-3 and TRBV9. This study is consistent with previous population genetic studies wherein African-derived samples have a greater level of genetic diversity compared to Caucasians. These data also demonstrate that patterns of LD are not consistent across the entire TRBV locus.

The T-cell receptor in primates: identifying and sequencing new owl monkey TRBV gene sub-groups

The New World primate Aotus nancymaae (owl monkey) has been shown to be an excellent experimental model when studying malarial parasites. Characterising the T-cell receptor (TR) alphabeta repertoire by means of the different variable beta (TRBV) genes displayed contributes to a better understanding of these lymphocytes' role in the response against several malarial antigens. This study describes identifying and characterising eleven new TRBV gene sub-groups in cDNA from Aotus nancymaae's peripheral blood lymphocytes; these 11 gene sequences displayed homology to the previously reported human TRBV3, TRBV10, TRBV11, TRBV14, TRBV18, TRBV19, TRBV20, TRBV25, TRBV27, TRBV29 and TRBV30 sub-groups, resulting in 83% overall homology at the amino acid level. An additional Aotus sequence was found having similarity with the human TRBJ-2-7*01 gene. Evolutionary relationships amongst these sequences and the homologous genes from both New and Old World primates have shown that the TRBV repertoire has been maintained in the species being studied, displaying varying association patterns and substitution rates, depending on the sub-group being studied. The degree of identity observed when comparing human and Aotus genes suggests that these species might have a similar TRBV repertoire.

T-Cell and chemokine receptor variation in South Amerindian populations

The immune response of relatively small, endogamous populations is of special interest, because they may differ from those of large, ethnically diverse, urban groups. As a contribution to this area of investigation, we tested 99 individuals from two Brazilian native populations for two T-cell receptor gene segments (TCRBV3S1 and TCRBV18) and 241 subjects from eight tribes of this ethnic group in relation to the chemokine receptor CCR5delta32 allele. Differences in TCRBV3S1 and TCRBV18 prevalences of the Amerindians in relation to European- and African-derived individuals were not marked. We confirmed the absence of the CCR5delta32 allele in most groups, its presence in the Mura and Kaingang, probably because of European gene introgression.

T-cell receptor BV gene segment polymorphisms in healthy elderly individuals from the south of Brazil

The ageing of the immune system (immunosenescence) is believed to be involved in both morbidity and mortality in elderly humans due to a higher incidence of infections, autoimmune diseases, cancers and other pathological situations. As any specific immune response involves recognition of antigens by T cells, the ability to develop a given immune response is also dependent on the T-cell repertoire available at a given time point. Different T-cell receptor beta variable segment (BV) (TCRBV) gene segment alleles have been associated with diseases in various human populations. In the present work we analysed the allelic frequencies of four biallelic polymorphisms in TCRBV gene segments (TCRBV3S1, TCRBV13S5, TCRBV13S6 and TCRBV18) in healthy elderly human subjects (80 years old or more) from the south of Brazil, where life expectancies reach similar levels to those observed in developed countries. Except for allele 2 of the TCRBV13S6 polymorphism, which was more frequent in elderly than in young individuals (P = 0.0105), there were no differences in allele or genotype frequencies between young and elderly individuals. The data suggest that there is no direct correlation between the TCRBV3S1, TCRBV13S5 and TCRBV18 polymorphisms analysed and healthy senescence in this particular group of elderly individuals. The higher frequency of TCRBV13S6 allele 2 in healthy elderly individuals should be confirmed in other samples to establish the significance of this finding.

Analysis of two T-cell receptor BV gene segment polymorphisms in caucasoid Brazilian patients with rheumatoid arthritis

Considering the role of T-lymphocytes in rheumatoid arthritis (RA) and a possible involvement of the TCR in the pathology of this disease we analyzed allelic and genotypic frequencies of variants of two TCRBV gene segments (TCRBV3S1 and TCRBV18) in RA. A total of 95 caucasoid South Brazilian RA patients were genotyped for both TCRBV gene segment variants by restriction fragment length polymorphism preceded by PCR (PCR-RFLP) and the obtained frequencies were compared to those from healthy individuals. Allelic frequencies for the TCRBV3S1 gene segment were, respectively, for RA patients and controls, 0.447 and 0.545 (allele 1) and 0.553 and 0.455 (allele 2). Allelic frequencies for the TCRBV18 gene segment were, respectively, for RA patients and controls, 0.824 and 0.806 (allele 1) and 0.176 and 0.194 (allele 2). Neither allelic frequencies nor genotypic frequencies differ among RA and healthy individuals, suggesting that there is not a direct association among the TCRBV allelic variants studied and the development of RA and thus excluding the possibility of use of these gene segment polymorphisms as RA susceptibility markers.

Diversity and linkage of genes in the self-incompatibility gene family in Arabidopsis lyrata

We report studies of seven members of the S-domain gene family in Arabidopsis lyrata, a member of the Brassicaceae that has a sporophytic self-incompatibility (SI) system. Orthologs for five loci are identifiable in the self-compatible relative A. thaliana. Like the Brassica stigmatic incompatibility protein locus (SRK), some of these genes have kinase domains. We show that several of these genes are unlinked to the putative A. lyrata SRK, Aly13. These genes have much lower nonsynonymous and synonymous polymorphism than Aly13 in the S-domains within natural populations, and differentiation between populations is higher, consistent with balancing selection at the Aly13 locus. One gene (Aly8) is linked to Aly13 and has high diversity. No departures from neutrality were detected for any of the loci. Comparing different loci within A. lyrata, sites corresponding to hypervariable regions in the Brassica S-loci (SLG and SRK) and in comparable regions of Aly13 have greater replacement site divergence than the rest of the S-domain. This suggests that the high polymorphism in these regions of incompatibility loci is due to balancing selection acting on sites within or near these regions, combined with low selective constraints.

T-cell receptor repertoire in healthy Sardinian subjects

The T-cell receptor (TCR) Vbeta gene usage of CD4+ and CD8+ T-cell subpopulations was evaluated by flow cytometric analysis and by CDR3 spectratyping in healthy subjects belonging to Sardinian population, which is ethnically homogeneous and genetically distant from all other Italian and Caucasoid groups. As described in healthy Caucasian subjects, we found a nonrandom Vbeta gene usage and in some Vbeta families a significant skewed reactivity toward CD4+ T cells. Moreover, different subjects showed expansions in some Vbeta subfamilies, mainly in the CD8+ T cells. By CDR3 spectratyping analysis we found a significantly higher degree of skewness in the TCR Vbeta repertoire of CD8+ than in that of CD4+ T cells. The similarity found in the TCR Vbeta gene usage between the population examined and other Caucasoid groups suggest that the shape of the TCR repertoire is more influenced by rearrangement processes than ethnic background. However, genetic polymorphisms may condition the expression levels of some Vbetas, determining the variability of the TCR repertoire between different populations. Finally, the profound perturbations evidenced in the CD8+ T cell subpopulation could be related to a different response to the antigenic stimulation between CD8+ and CD4+ T lymphocytes.

Sequence variation in the human T-cell receptor loci

Identifying common sequence variations known as single nucleotide polymorphisms (SNPs) in human populations is one of the current objectives of the human genome project. Nearly 3 million SNPs have been identified. Analysis of the relative allele frequency of these markers in human populations and the genetic associations between these markers, known as linkage disequilibrium, is now underway to generate a high-density genetic map. Because of the central role T cells play in immune reactivity, the T-cell receptor (TCR) loci have long been considered important candidates for common disease susceptibility within the immune system (e.g., asthma, atopy and autoimmunity). Over the past two decades, hundreds of SNPs in the TCR loci have been identified. Most studies have focused on defining SNPs in the variable gene segments which are involved in antigenic recognition. On average, the coding sequence of each TCR variable gene segment contains two SNPs, with many more found in the 5', 3' and intronic sequences of these segments. Therefore, a potentially large repertoire of functional variants exists in these loci. Association between SNPs (linkage disequilibrium) extends approximately 30 kb in the TCR loci, although a few larger regions of disequilibrium have been identified. Therefore, the SNPs found in one variable gene segment may or may not be associated with SNPs in other surrounding variable gene segments. This suggests that meaningful association studies in the TCR loci will require the analysis and typing of large marker sets to fully evaluate the role of TCR loci in common disease susceptibility in human populations.

TCRBV3S1 and TCRBV18 gene segment polymorphisms in Brazilian Caucasoid and Black populations

The T-cell receptor (TCR) repertoire plays an important role in shaping specific immune responses. Genetic polymorphisms at the TCR locus, in both constant and variable regions, seem to represent an important mechanism for generating inter-individual and inter-population differences. Considering the scarcity of immune parameters characterized for normal human populations, we decided to determine the frequency of two TCRBV polymorphisms (located in the TCRBV3S1 and TCRBV18 gene segments) in two ethnically distinct groups of the general Brazilian population. Both polymorphisms are related to the expression of these segments at the T-cell surface and can consequently modulate the T-cell repertoire, potentially modifying the capacity of a given individual to develop an immune response. These DNA polymorphisms were analysed in material obtained from adult, normal South-American Caucasoid and Black individuals. A total of 139 individuals were analysed for the TCRBV3S1 and 141 for the TCRBV18 gene segment polymorphisms. The data indicated statistically significant differences in allelic frequencies for the two ethnic groups analysed, suggesting that any correlation between TCR usage or T-cell repertoire and development of a given disease should take in account the ethnic origin of the population studied.

Sequence variation and linkage disequilibrium in the human T-cell receptor beta (TCRB) locus

The T-cell receptor (TCR) plays a central role in the immune system, and > 90% of human T cells present a receptor that consists of the alpha TCR subunit (TCRA) and the beta subunit (TCRB). Here we report an analysis of 63 variable genes (BV), spanning 553 kb of TCRB that yielded 279 single-nucleotide polymorphisms (SNPs). Samples were drawn from 10 individuals and represent four populations-African American, Chinese, Mexican, and Northern European. We found nine variants that produce nonfunctional BV segments, removing those genes from the TCRB genomic repertoire. There was significant heterogeneity among population samples in SNP frequency (including the BV-inactivating sites), indicating the need for multiple-population samples for adequate variant discovery. In addition, we observed considerable linkage disequilibrium (LD) (r(2) > 0.1) over distances of approximately 30 kb in TCRB, and, in general, the distribution of r(2) as a function of physical distance was in close agreement with neutral coalescent simulations. LD in TCRB showed considerable spatial variation across the locus, being concentrated in "blocks" of LD; however, coalescent simulations of the locus illustrated that the heterogeneity of LD we observed in TCRB did not differ markedly from that expected from neutral processes. Finally, examination of the extended genotypes for each subject demonstrated homozygous stretches of >100 kb in the locus of several individuals. These results provide the basis for optimization of locuswide SNP typing in TCRB for studies of genotype-phenotype association.

Human T-cell receptor BV6 gene polymorphism in relation to expression level and CD4/CD8 skewness

Using 50 samples of umbilical cord blood lymphocytes from Japanese donors, we analysed two human T-cell receptor beta variable (TCRBV) genes, BV6S4 and BV6S5, for their polymorphism, usage frequencies and CD4/CD8 skewness. They showed contrasting CD4/CD8 skewness, BV6S4 to CD8+ T cells and BV6S5 to CD4+ T cells. Genotyping of the BV6S4 alleles (A1, A2 and A3) revealed two of the six possible BV6S4 genotypes, A1/A2 and A2/A2. Among the two BV6S4 genotypes, no significant difference was detected in usage frequency or CD4/CD8 skewness. On the other hand, genotyping of the BV6S5 alleles (A1 and A2) revealed all three possible BV6S5 genotypes, A1/A1, A1/A2 and A2/A2, and the gene usage frequency was high, in the order A1/A1 > A1/A2 > A2/A2. These results indicate that the amino acid substitutions in BV6S5 (S36R and G70E) are in some way associated with the expression level of this gene. In the analysis of CD4/CD8 skewness, the three BV6S5 genotypes had similar skewness, indicating that A1 alleles are expressed more frequently than A2 alleles in both CD4+ and CD8+ T-cell populations. Although BV6S5 exhibits marked skewness to CD4+ T cells, our results indicate that the higher expression of A1 alleles is not associated with the increased ratio of CD4+ T cells.

Identification of seven new TCRBV subfamilies in cattle (Bos taurus)

In cattle, the repertoire of TCRBV genes that encode the variable region of T-cell receptor beta-chains has not been fully characterized. In this study, cattle TCRBV genes were amplified from mRNA by anchored polymerase chain reaction and sequenced. Eleven new TCRBV gene sequences were found, and classified into seven subfamilies distinct from those previously identified.

Low CD4 counts rather than superantigenic-like effects account for differences in expressed T-cell receptor (TCR) repertoires between HIV-1 seropositive long-term non-progressors and individuals with progressive disease

Analysis of HIV-infected individuals who have stable CD4 counts many years after seroconversion may provide an insight as to how the host's immune system can successfully control HIV infection. In this study we analysed the T-cell receptor (TCR) Vbeta repertoire in 13 HIV+ individuals, seven of whom were classed as long-term non-progressors (LTNP), using a technique which couples anchor PCR (AnPCR) amplification of beta-chain cDNA to differential probe hybridization with non-radioactively labelled Vbeta family specific oligonucleotide probes. There were no significant differences in the expressed TCR repertoires between the LTNP group and the other HIV-infected individuals. However, there was a statistically significant inverse correlation between CD4 count and the number of Vbeta family-specific perturbations in the recent seroconverters (SC) and those with progressive infection (PI), consistent with other shared features of clinical disease progression (Th1/Th2 switch and high frequency of viral isolation). We conclude that long-term clinical non-progression in HIV-1 infection is not associated with the loss or expansion of a particular Vbeta family; instead, low CD4 count in the PI and SC individuals was correlated with increased number of Vbeta family-specific perturbations relative to the LTNP group and that it is hence unlikely that HIV encodes a superantigen.

Immune system genes in multiple sclerosis: genetic association and linkage analyses on TCR beta, IGH, IFN-gamma and IL-1ra/IL-1 beta loci

The role of genetic factors in the etiology of multiple sclerosis (MS) has been clearly demonstrated but the loci determining susceptibility to this disease remain largely unidentified. A contribution from several immune system genes has been suggested based on animal models and association/linkage analyses on MS patients and families. With the exception of the findings from the HLA complex, studies on candidate immune system genes have provided controversial results. Here we have performed genetic association and linkage analyses on four chromosomal regions containing immune system genes. A possible role for each of these loci in MS has been previously suggested. In data-sets derived from the Finnish population we found no evidence for contribution of the T-cell receptor beta chain (TCR beta chromosome 7q35), immunoglobulin heavy chain (IGH chromosome 14q32), interferon-gamma (IFN-gamma chromosome 12q14-q15) or interleukin-1 receptor antagonist/interleukin-1 beta (IL-1ra/IL-1 beta chromosome 2q14-q21) loci in the genetic susceptibility to MS.

The human immunoglobulin V(H) gene repertoire is genetically controlled and unaltered by chronic autoimmune stimulation

The factors controlling immunoglobulin (Ig) gene repertoire formation are poorly understood. Studies on monozygotic twins have helped discern the contributions of genetic versus environmental factors on expressed traits. In the present experiments, we applied a novel anchored PCR-ELISA system to compare the heavy chain V gene (V(H)) subgroup repertoires of mu and gamma expressing B lymphocytes from ten pairs of adult monozygotic twins, including eight pairs who are concordant or discordant for rheumatoid arthritis. The results disclosed that the relative expression of each Ig V(H) gene subgroup is not precisely proportional to its relative genomic size. The monozygotic twins had more similar IgM V(H) gene repertoires than did unrelated subjects. Moreover, monozygotic twins who are discordant for RA also use highly similar IgM V(H) gene-subgroup repertoires. Finally, the V(H) gene repertoire remained stable over time. Collectively, these data reveal that genetic factors predominantly control V(H) gene repertoire formation.

Allelic variants of human TCR BV17S1 defined by restriction fragment length polymorphism, single strand conformation polymorphism, and amplification refractory mutation system analyses

Several human TCR BV gene subfamilies, including BV3, BV14, and BV17S1, are single member genes but are overutilized among activated CD4+ synovial T cells in the rheumatoid arthritis (RA). To define the role of these TCR BV genes in the pathogenesis of disease, it is critical to characterize the genomic organization and the allelic variations of these genes. In this study we describe allelic variations of BV17S1 defined by restriction fragment length polymorphism (RFLP), single strand conformation polymorphism (SSCP), and amplification refractory mutation system (ARMS) analyses. A single nucleotide replacement (C/T) results in an amino acid substitution (F/L) in the leader and distinguishes BV17S1*1 from BV17S1*2. This nucleotide substitution was found to create a BsmAI restriction enzyme recognition site in BV17S1*2. Therefore genotypic analyses can be performed either by the SSCP or RFLP method. The analyses of 75 unrelated individuals show that the frequency for allele BV17S1*1 is 52.7% and for allele BV17S1*2 is 47.3%. Both alleles are functionally expressed and are distributed within CD4+/CD8+ T cell subsets. Another point mutation in the CDR2 region of BV17S1, which results in the amino acid replacement of Gln by His, originally identified form a cDNA clone, has now been confirmed as an allele by ARMS analysis using genomic DNA preparations and designated to as BV17S1*3. Screening of this CDR2 related variant among normal populations indicates that this is a rare allele (1 of 75). Although this variant may be of functional significance, the genotypic analysis and functional studies are difficult due to the low frequency of BV17S1*3. In an attempt to define a correlation between BV17S1 allelic usage and susceptibility to RA, the germline distribution of BV17S1 alleles *1 and *2 has been examined in a small number of RA patients and no skewed usage has been identified.

Quantitative assessment of the human TCRBV repertoire by competitive PCR

A novel quantitative protocol was developed for the measurement of the relative expression levels of the human TCRBV genes based on reverse transcription (RT) and subsequent competitive polymerase chain reaction (cPCR). Competitor DNA templates for the analysis of 24 different TCRBV families were generated by a simple and rapid one-step PCR procedure with a special PCR primer, which introduces a deletion in the constant region gene segment. A defined amount of TCRBV family-specific competitor DNA and the reverse transcribed cDNA of interest were amplified in the same tube with the same primer pair in a competitive way. The resulting fragments were separated on agarose gels and the densitometrical values were evaluated directly without the requirement for additional hybridization steps. For all of the 24 different TCRBV family-specific cPCRs equal amplification efficiencies were demonstrated by titration experiments for wild-type and competitor templates. For TCRBV repertoire studies, a short form of the cPCR assay was performed, requiring only one cPCR for quantitation of each TCRBV family. The exact initial amount of wild-type template in each cPCR was interpolated from TCRBV family-specific reference calibration curves. The RT-cPCR assay was applied for the quantitative assessment of the TCRBV repertoire of CD4+ and CD8+ T cell subsets in unstimulated PBMC and compared to flow cytometric analyses with a panel of monoclonal antibodies specific for TCRBV determinants. The RT-cPCR experiments revealed a differential expression of several BV families in either the CD4+ or the CD8+ fraction. The TCRBV family-specific cPCR assay presented here combines the simplicity and speed of conventional TCRBV family-specific PCR with the quantitative features of competitive PCR. TCRBV family-specific RT-cPCR has a broad application for all kinds of quantitative T cell repertoire studies and could be easily adapted for the usage with different BV-specific primer sets.

The complete 685-kilobase DNA sequence of the human beta T cell receptor locus

The human beta T cell receptor (TCR) locus, comprising a complex family of genes, has been sequenced. The locus contains two types of coding elements--TCR elements (65 variable gene segments and two clusters of diversity, joining, and constant segments) and eight trypsinogen genes --that constitute 4.6 percent of the DNA. Genome-wide interspersed repeats and locus-specific repeats span 30 and 47 percent, respectively, of the 685-kilobase sequence. A comparison of the germline variable elements with their approximately 300 complementary DNA counterparts reveals marked differential patterns of variable gene expression, the importance of exonuclease activity in generating TCR diversity, and the predominant tendency for only functional variable elements to be present in complementary DNA libraries.

TCR gene polymorphisms and autoimmune disease

Autoimmunity may result from abnormal regulation within the immune system. As the T cell is the principal regulator of the immune system and its normal function depends on immune recognition or self/non-self discrimination, abnormalities of the idiotypic T-cell receptor (TCR) may be one cause of autoimmune disease. The TCR is a clonally distributed, cell-surface heterodimer which binds peptide antigen when complexed with HLA molecules. In order to recognize the variety of antigens it may possibly encounter, the TCR, by necessity, is a diverse structure. As with immunoglobulin, it is the variable domain of the TCR which interacts with antigen and exhibits the greatest amount of amino acid variability. The underlying genetic basis for this structural diversity is similar to that described for immunoglobulin, with TCR diversity relying on the somatic recombination, in a randomly imprecise manner, of smaller gene segments to form a functional gene. There are a large number of gene segments to choose from (particularly the TCRAV, TCRAJ and TCRBV gene segments) and some of these also exhibit allelic variation. Finally, polymorphisms in non-coding regions of TCR genes, leading to biased recombination or expression, are also beginning to be recognized. All these factors contribute to the polymorphic nature of the TCR, in terms of both structure and repertoire formation. It follows that inherited abnormalities in either coding or regulatory regions of TCR genes may predispose to aberrant T-cell function and autoimmune disease. This review will outline the genomic organization of the TCR genes, the genetic mechanisms responsible for the generation of diversity, and the results of investigations into the association between germline polymorphisms and autoimmune disease.

Human T-cell receptor variable gene segment families

Multiple DNA and protein sequence alignments have been constructed for the human T-cell receptor alpha/delta, beta, and gamma (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 delta and V alpha, one at a site that in VH contacts the constant region, the other at the interface between immunoglobulin VH and VL. This site may be responsible for restricted pairing between certain V delta and V gamma chains. On the other hand, V beta and V gamma appear to be related by the fact that their CDR2 length is increased by four residues as compared with that of V alpha/delta peptides.

The influence of non-HLA genes on the human T-cell receptor repertoire

We previously demonstrated a central role for HLA genes in determining the T-cell receptor (TCR) repertoire. However, these studies also suggested that other genetic factors might also play a role in the development of this repertoire. In order to assess the role of non-HLA genes in the development of the TCR repertoire, we have analysed and compared the TCR repertoires of individuals in three families consisting of both monozygotic twins as well as an HLA-identical sib. TCR repertoire analysis was performed with both V-segment-specific MoAb and the polymerase chain reaction using TCRBV-segment-specific oligonucleotide primers. We observed that in every case the TCR repertoires of identical twins were more similar to each other than to their HLA-identical sib. Furthermore, in one family we were able to show by genotype analysis that most of the differences in repertoire between the identical twins and their HLA-identical sib were caused by polymorphisms in the TCR genes that influence expression levels. These studies document an important role for non-HLA genes in determining the TCR repertoire in man and raise the possibility that such TCR polymorphisms may play a significant role in determining disease susceptibility.

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

There are at least 63 tandemly arranged human T-cell receptor (Tcr) beta-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.

Environmental and genetic factors shape the human T-cell receptor repertoire

Both environmental and genetic factors combine to shape the TCR repertoire as measured by V gene usage. These factors may result in dramatic shifts in normal subjects, which cannot be discounted when studies are performed in patients with disease. Future studies need to explore further examples of genetic and environmental factors that shape the TCR repertoire to understand the full extent of variation in a normal population and the mechanisms involved. Some of these mechanisms may also apply to TCRG, TCRD, and immunoglobulin loci. Certainly variations in the efficiency of V(D)J rearrangement could affect any rearranging multigene locus. Eventually such studies will lead to better designed clinical studies of the repertoire in disease, through the selection of control populations matched for environmental exposure and genetic background. In this respect, family studies will be most useful.

TCRBV12 genes are polymorphic but the protein products encoded by each gene are conserved

The human TCRBV gene complex contains three BV12 genes and all are polymorphic. There are two alleles of BV12S4; one allele contains a stop codon in the coding region which precludes its expression. There are four alleles of BV12S2 and two alleles of BV12S3 genes; however, the substitutions present in both genes are conservative. Although allelic variants exist for each of the three BV12 genes, only one protein product is encoded by each gene.

Relative size and evolution of the germline repertoire of T-cell receptor beta-chain gene segments in nonhuman primates

The mammalian T-cell receptor (TCR) gene complexes exist as multiple tandemly arrayed gene segments that have apparently arisen by gene duplication mechanisms. A study of the number of TCR germline gene segments in several primate species might provide insight into the relative rate and patterns of gene duplication and deletion within these gene complexes. DNA probes from the TCR beta-chain variable (TCRBV) region gene segment subfamilies 1 through 25 and the constant region gene segment were sequentially hybridized under low stringency to Southern blots containing genomic DNA of human, gorilla, orangutan, and pig-tailed macaque. The number of gene members in each subfamily was estimated from the number of hybridizing DNA fragments. The results show apparent examples of both TCRB V gene duplication and deletion since speciation of the Hominoids from Cercopithecoid (Old World) primates. For one putative duplication/deletion event involving six TCRBV gene segments, derivation and comparison of germline DNA sequence from macaque and human as well as Southern blot analysis of additional primates demonstrated that this event was a duplication that occurred after the divergence of the family Pongidae (Greater Apes) from Hylobatidae (Lesser Apes). Southern blot analysis of multiple pig-tailed macaques and their offspring suggests a degree of DNA sequence variability in these gene segments similar to that observed in humans. An appreciation of the size and variability of each TCRBV subfamily will be useful when considering the DNA primers and probes necessary to measure the relative usage of these TCRBV genes as part of the immune response in these nonhuman primates.

Identification of a novel human T-cell receptor V beta subfamily by genomic cloning

Although a large number of human TCRBV gene segment sequences have been reported, the extent of the germline repertoire is still not precisely known. Most TCRBV gene segments have been identified in cDNA clones. However, genes expressed on only a small number of peripheral T cells may be more easily detectable by analysis of genomic DNA. In the present study, screening of cosmid clones containing the BV24S1 gene segment revealed the presence of a novel TCRBV gene segment defining a new subfamily, BV25S1. The nucleotide sequence of the gene contained a single open reading frame and encoded structurally important amino acids at correct positions. Southern blot analysis indicated that the BV25 subfamily contained only this single member. A single nucleotide polymorphism was identified by nucleotide sequencing of the gene from multiple individuals. Amplification of rearranged BV25S1 genes from cDNA derived from PBLs confirmed that the BV25S1 gene segment was capable of normal rearrangement and transcription.

Genetic control of the human V beta 13.2 T cell repertoire: importance of allelic variation outside the coding regions of the TCRBV13S2 gene

In humans, the T cell repertoire is influenced by HLA, T cell receptor null alleles and antigen. Here, we describe a novel mechanism, independent of superantigen or T cell receptor structure which influences the T cell repertoire in a V beta-dependent manner. We have identified a biallelic locus, the TCRBV13S2 T cell receptor gene, where allelic differences predominate in the non-coding regions including transitions, transversions and frameshift deletions. The expressed protein is non-polymorphic at this locus. The TCRBV13S2 genotype profoundly influences the circulating levels of V beta 13.2 CD4 T cells but does not affect T cell receptor expression or function.

The human T-cell receptor variable gene segment TCRBV6S1 has two null alleles

The extent of polymorphism in TCRBV6S1 was examined by screening 203 individuals of diverse ethnic backgrounds by using SSCP. Three alleles were detected, including two that were described previously (TCRBV6S1*1 and *2P). The third allele (TCRBV6S1*3P), identified in these studies, is a pseudogene because, similar to allele *2P, it contains a substitution of a highly conserved cysteine residue near CDR3. Among a panel of 126 Caucasian donors, alleles *1, *2P, and *3P were observed to have frequencies of 0.72, 0.12, and 0.16, respectively. The extent of this survey suggests that it is unlikely for there to be additional common variants of TCRBV6S1. The approach used here enables rapid typing for polymorphism in a TCRBV gene that results in an allelically determined hole in the TCR repertoire.

Genetic analysis of low V beta 3 expression in humans

While studying the T cell receptor (TCR) repertoire of normal individuals, we found that more than 20% of adults have low levels of circulating V beta 3.1+ T cells in both CD4 and CD8 populations. A similar frequency was found in fetal cord blood samples, suggesting that in most cases, the V beta 3.1low phenotype is inherited. In support of this conclusion, children expressing low levels were only found in families where one of the parents expressed this phenotype. In two large families, genetic studies showed that low expression was a recessive trait and dependent on inheritance of particular TCR VB gene complexes. Family members with the low phenotype, however, expressed VB3.1 genes with normal sequences and expressed normal levels of receptor per cell. Results from these families suggest that up to 50% of normal individuals may carry a VB3.1 allele that is defective in its ability to rearrange effectively. In another large family, low expression in one individual was shown not to be determined by genes within the TCR VB gene or major histocompatibility complexes, suggesting a different mechanism for low V beta 3.1+ T cells. Overall, our results describe novel mechanisms that result in low levels of V beta 3.1+ T cells in a relatively large subset of the normal human population.

Level of human TCRBV3S1 (V beta 3) expression correlates with allelic polymorphism in the spacer region of the recombination signal sequence

One of the causes of variations in the expressed human T cell receptor (TCR) BV (V beta) repertoire is genetic variation in the germline DNA. Herein evidence is provided that allelic polymorphism may affect recombination frequency for a specific V gene. Two alleles of the TCR BV3 differ only at a single nucleotide position (C/T) within the 23-bp spacer region of the recombination signal sequence. These alleles are associated with variable percentages of BV3 cells in the peripheral blood, as shown in families and in unrelated normal donors. Individuals homozygous for allele 2 have a mean of 8.1% BV3 cells, heterozygous individuals have a mean of 4.7% BV3 cells, and homozygotes for allele 1 have a mean of 1.2% BV3 cells in CD3+ CD4+ peripheral blood T cells. Since the correlation is tight in unrelated individuals and other genetic differences were not found in the vicinity of BV3, we suggest that the spacer region sequence itself modifies recombination efficiency. This allelic system provides an example of a novel mechanism by which cis-acting genetic elements may affect recombination in a natural in vivo system.

The human T cell antigen receptor repertoire: skewed use of V beta gene families by CD8+ T cells

The TCR repertoire of human CD8+ peripheral blood lymphocytes has been determined using MoAbs to the V beta 2, 3, 5.1, 5.2/5.3, 6.7, 8, 12 and 19(17)V beta gene families. The CD8T cell repertoire for V beta 2 and V beta 3 is shown to be skewed, with an excess of individuals having higher values than are consistent with a normal distribution. A significant majority of these individuals are over the age of 40. High values of V beta CD8+ cells were found for each V beta family studied except for 6.7a. Individual high values are stable for at least 12 months. In addition, the total percentage of CD4 and CD8 cells reacting with this panel of reagents was determined. There is a significant excess of V beta + CD4+ cells (33%) over CD8+V beta + cells (21.9%). Thus the human CD8 V beta repertoire differs from the human CD4 repertoire in a number of important ways.

Bimodal distribution of V beta 2+CD4+ T cells in human peripheral blood

The distribution of T cells using the V beta 2 gene was studied in a group of 99 humans. The distribution of V beta 2+CD4+ levels was bimodal. Twelve individuals had levels of V beta 2+CD4+ less than 2% and 86 others had values greater than 5%. Only one individual had a value between 2% and 5%. The V beta 2 low (mean 1.3 +/- 0.49) and V beta 2 high (mean 8.2 +/- 1.65) phenotypes were stable. The V beta 2 low phenotype is inherited and not limited to HLA or T cell receptor V beta gene complexes. The CD8V beta 2 levels of CD4V beta 2 low individuals are also low. The residual V beta 2+ T cells in V beta 2 low individuals were not anergic to V beta 2-specific stimulation. These data are compatible with the effects of an endogenous superantigen.

Frequent recombination in the human T-cell receptor beta gene complex

Although individual TCRVBV gene segments exhibit limited polymorphism, human T-cell receptor beta (TCRB) haplotypes are characterized by multiple different combinations of allelic markers. This observation suggests that genetic recombination may have played a role in the generation of these haplotypes. Meiotic recombination in a region spanning approximately 250 kilobases (kb) at the 3' end of the TCRB gene complex was investigated by extended family studies and by analysis of single sperm. Segregation patterns of polymorphic TCRB markers in families allowed the assignment of TCRB alleles to parental haplotypes and detection of recombinants among the offspring. Among the 178 informative paternal meioses, four (approximately 2%) were recombinant, whereas no recombinants were found in the 199 maternal meioses. In addition, segregation of two allelic markers was examined in a total of 1101 individual sperm from two heterozygous donors to detect exchange events in this region. The results revealed a similar rate of recombination, approximately 1.3%, which, along with the family data, suggests that at, least in males, meiotic recombination in this 250 kb region may be six times higher than the "average" rate of 1% per 10(6) bases that has been estimated for the human genome.

Polymorphism detection and sequence analysis of human T-cell receptor V alpha-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 alpha 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 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 germline repertoire encodes at least 63 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.

T-cell receptor polymorphisms in Tlingit Indians with rheumatoid arthritis

Rheumatoid arthritis (RA) develops as a result of the interaction of both genetic and environmental factors. Among the genes in humans that have been suggested as candidate susceptibility genes in RA are those encoding the T cell receptor for antigen (TCR). A high prevalence and early age of onset of RA has previously been reported in Alaskan Tlingit Indians. In this study, the frequency of seven different restriction fragment length polymorphisms (RFLPs) in the TCR alpha and beta gene complexes were measured in a population of Alaskan Tlingit Indians. No statistically significant differences were noted when the frequencies of these RFLPs were compared between Tlingits with RA and healthy controls (p > 0.05). These results do not support the hypothesis of an RA-susceptibility allele in the vicinity of these TCR alpha or beta genes. Since TCR RFLPs have not been extensively studied in native American populations, TCR polymorphism frequencies in the Tlingits were also compared to the frequencies observed in a second control group of healthy Caucasians. Statistically significant differences were observed in these comparisons implying a different distribution of individuals in these populations with different TCR repertoires.

Analysis of a T-cell receptor V beta segment implicated in susceptibility to rheumatoid arthritis: V beta 2 germline polymorphism does not encode susceptibility

OBJECTIVES

The assessment of allelic polymorphism of the T cell receptor gene segment, TCRBV2S1, in rheumatoid arthritis.

METHODS

A total of 136 patients with rheumatoid arthritis (RA) (ACR criteria) and 150 controls were TCRBV2S1 genotyped using a nested PCR amplification strategy followed by single-strand conformation polymorphism (SSCP) analysis.

RESULTS

The SSCP typing method detected two previously unknown alleles of the TCRBV2S1 gene segment. The TCRBV2S1 allele, genotype and inferred phenotype frequencies were similar in the RA patients and controls. No differences were apparent after the RA patients had been partitioned according to their HLA-DR genotypes.

CONCLUSIONS

SSCP analysis is a rapid and efficient method of typing T cell receptor germline polymorphisms. Allelic polymorphism of the T cell receptor variable segment, TCRBV2S1, does not influence susceptibility to RA.

Reduced expression of a human V beta 6.1 T-cell receptor allele

We have previously described an allelic polymorphism in the V beta 6.1 T-cell receptor gene. The V beta 6.1B allele is associated with disease in a subgroup of patients with juvenile rheumatoid arthritis. Limited sequence data demonstrated nucleotide differences that resulted in two amino acid changes between the two alleles in positions predicted to be important in major histocompatibility complex/antigen recognition. The present study demonstrates substantially reduced expression of mRNA from the disease-associated allele (V beta 6.1B) in peripheral blood and thymic tissue. The complete genomic sequence of both alleles revealed two additional amino acid changes in the V beta 6.1B gene as well as nucleotide differences in the promoter and intron. A cysteine-to-arginine substitution at position 92 in the disease-associated allele makes this a non-functional beta chain, since this conserved cysteine is involved with disulfide bonding to cysteine-23 to form an immunoglobulin-like domain structure, thus resulting in a potential hole in the T-cell receptor repertoire.