Complexity of human T-cell antigen receptor beta-chain constant- and variable-region genes

Immune systems of vertebrates function via two types of effector cells, B and T cells, which are capable of antigen-specific recognition. The immunoglobulins, which serve as antigen receptors on B cells, have been well characterized with respect to gene structure, unlike the T-cell receptors. Recently, cDNA clones thought to correspond to the beta-chain locus of the human and mouse T-cell receptor have been described. The presumptive beta-chain clones detect gene rearrangement specifically in T-cell DNA and show homology with immunoglobulin light chains. The similarity of the T-cell beta-chain gene system to the immunoglobulin genes has been further demonstrated by the recent observation of variable- and constant-region gene segments as well as joining segments and putative diversity segments. We report here the characterization of cDNA and genomic clones encoding human T-cell receptor beta-chain genes. There are two constant-region genes (C beta 1 and C beta 2), each capable of rearrangement and expression as RNA. The gene arrangement, analogous to that of mouse beta-chain genes, shows strong evolutionary conservation of the dual C beta gene system in these two species.     

The gene encoding the T-cell receptor alpha-chain maps close to the Np-2 locus on mouse chromosome 14

Serological and molecular genetic analyses of T-cell clones have shown that the T-cell antigen receptor apparently comprises two glycosylated, disulphide-linked polypeptide chains (alpha and beta), both of which span the cell membrane. Cloning of the genes encoding the two chains from mouse and human DNA has shown that the alpha- and beta-chains are composed of variable (V) and conserved (C) regions in agreement with peptide mapping data. Gene segments encoding variable and conserved domains of the beta-chain have been identified and undergo rearrangements during T-cell differentiation. The genes encoding the alpha-chain, so far described at the level of complementary DNA clones, also identify DNA rearrangements. Thus, the genes encoding the T-cell receptor show the same structure and dynamic behaviour as immunoglobulin genes, indicating that the two gene families belong to the same supergene family; this evolutionary relationship is supported by the fact that the genes encoding the beta-chain of the T-cell receptor are closely linked to immunoglobulin kappa light-chain genes on chromosome 6 in mouse. In man, however, the beta genes map to chromosome 7 (ref. 14) whereas the kappa-chain genes are located on chromosome 2, indicating that linkage between the two gene families is not needed for proper expression. Here we describe genomic clones encoding the constant portion of the T-cell receptor alpha-chain and map the gene to chromosome 14 in mouse, close to the gene for purine nucleoside phosphorylase (Np-2) which, in man, has been associated with T-cell immunodeficiencies.     

Immunoglobulin-like nature of the alpha-chain of a human T-cell antigen/MHC receptor

Although the receptor with which T cells bind specific antigen can, like immunoglobulin, distinguish between antigens which differ only slightly in structure, it is unique in recognizing antigen only in conjunction with one of the self proteins of the major histocompatibility complex (MHC restriction). The receptor was identified and characterized in mouse and man by using monoclonal antibodies to receptor idiotypes, and consists of two disulphide-linked polypeptides, and acidic alpha-chain and a neutral to slightly basic beta-chain. Peptide maps have shown that, like immunoglobulin, both chains vary for receptors of different specificities. T-cell-derived cDNA clones have recently been identified in mouse and man encoding immunoglobulin-like molecules. These were identified as derived from beta-chain genes through a partial N-terminal protein sequence of the beta-chain isolated from a human T-cell tumour. We have now purified the alpha- and beta-chains of the receptor of the human T-cell leukaemia line HPB-MLT, and have determined the amino acid sequence of several tryptic peptides derived from each chain. Our results further confirm that the previously reported cDNA clones encode beta-chains. The sequence of the alpha-chain peptides identify this as another immunoglobulin-like polypeptide chain. Particularly striking was an alpha-chain peptide with high homology to the conserved portion of the immunoglobulin J segment and T-cell receptor beta-chains. Surprisingly, the alpha-chain peptides show little similarity to the sequence predicted by two overlapping putative murine alpha-chain cDNA clones.     

Primary structure of human T-cell receptor alpha-chain

The T-cell receptor has been studied intensely over the past 10 years in an effort to understand the molecular basis for major histocompatibility complex (MHC) restricted antigen recognition. The use of anti-receptor monoclonal antibodies to isolate and characterize the receptor from human and murine T-cell clones has shown that the protein consists of two disulphide-linked glycopeptides, alpha and beta, distinct from known immunoglobulin light and heavy chains. Like immunoglobulin light and heavy chains, however, both the alpha- and beta-chains are composed of variable and constant regions. Molecular cloning has revealed that the beta-chain is evolutionarily related to immunoglobulins, and is encoded in separate V (variable), D (diversity), J (joining) and C (constant) segments that are rearranged in T cells to produce a functional gene. We report here cDNA clones encoding the alpha-chain of the receptor of the human T-cell leukaemia line HPB-MLT. Using these cDNA probes, we find that expression of alpha-chain mRNA and rearrangement of an alpha-chain V-gene segment occur only in T cells. The protein sequence predicted by these cDNAs is homologous to T-cell receptor beta-chains and to immunoglobulin heavy and light chains, particularly in the V and J segments.     

Genomic organization of the genes encoding mouse T-cell receptor alpha-chain

The vertebrate immune system uses two kinds of antigen-specific receptors, the immunoglobulin molecules of B cells and the antigen receptors of T cells. T-cell receptors are formed by a combination of two different polypeptide chains, alpha and beta (refs 1-3). Three related gene families are expressed in T cells, those encoding the T-cell receptor, alpha and beta, and a third, gamma (refs 4-6), whose function is unknown. Each of these polypeptide chains can be divided into variable (V) and constant (C) regions. The V beta regions are encoded by V beta, diversity (D beta) and joining (J beta) gene segments that rearrange in the differentiating T cell to generate V beta genes. The V gamma regions are encoded by V gamma, J gamma and, possibly, D gamma gene segments. Studies of alpha complementary DNA clones suggest that alpha-polypeptides have V alpha and C alpha regions and are encoded by V alpha and J alpha gene segments and a C alpha gene. Elsewhere in this issue we demonstrate that 18 of 19 J alpha sequences examined are distinct, indicating that the J alpha gene segment repertoire is much larger than those of the immunoglobulin (4-5) or beta (14) gene families. Here we report the germline structures of one V alpha and six J alpha mouse gene segments and demonstrate that the structures of the V alpha and J alpha gene segments and the alpha-recognition sequences for DNA rearrangement are similar to those of their immunoglobulin and beta-chain counterparts. We also show that the J alpha gene-segment organization is strikingly different from that of the other immunoglobulin and rearranging T-cell gene families. Eighteen J alpha gene segments map over 60 kilobases (kb) of DNA 5' to the C alpha gene.     

Aberrant rearrangement of the kappa light-chain locus involving the heavy-chain locus and chromosome 15 in a mouse plasmacytoma

The creation of a functional antibody gene requires the precise recombination of gene segments initially separated on the chromosome. Frequently errors occur in the process, resulting in the formation of a non-functional gene. The non-functional genes can be generated by incomplete rearrangements, frameshifts, or the use of pseudo V or J joining segments. It is likely that these aberrant rearrangements arise by the same mechanism as is used in generating functional genes, a process which we have suggested may involve unequal sister chromatid exchange. Aberrant rearrangements of immunoglobulin genes occur in normal lymphocytes and play a major part in allelic exclusion. However, it has recently been suggested that aberrant rearrangements involving immunoglobulin and non-immunoglobulin genes may be involved in tumorigenesis. This suggestion has been stimulated by the frequent occurrence of translocations involving chromosomes known to carry immunoglobulin genes in B-cell malignancies. The rearrangement of non-immunoglobulin DNA to the heavy-chain locus has recently been reported. Some aberrant rearrangements of the kappa locus appear to be due to rearrangements to sites that do not include the conventional sequence for V gene segment joining. Here we describe an aberrant kappa rearrangement that has led to the joining of DNA from chromosomes 15, 6 and 12, and so appears to be the result of chromosomal translocations or transpositions. As 15/6 or 15/12 translocations have frequently been found in mouse plasmacytomas (as have analogous translocations in human lymphocyte tumours) this aberrant kappa rearrangement may be unique to the plasmacytoma from which it was isolated.     

Identification of reciprocal translocation sites within the c-myc oncogene and immunoglobulin mu locus in a Burkitt lymphoma

The association between certain human tumours and characteristic chromosomal abnormalities has led to the hypothesis that specific cellular oncogenes may be involved and consequently 'activated' in these genetic recombinations. This hypothesis has found strong support in the recent findings that some cellular homologues of retroviral onc genes are located in chromosomal segments which are affected by specific tumour-related abnormalities (see ref. 4 for review). In the case of human undifferentiated B-cell lymphoma (UBL) and mouse plasmacytomas, cytogenetic and chromosomal mapping data have identified characteristic chromosomal recombinations directly involving different immunoglobulin genes and the c-myc oncogene (for review see refs 5, 6). In UBLs carrying the t(8:14) translocation it has been shown that the human c-myc gene is located on the region of chromosome 8 (8q24) which is translocated to the immunoglobulin heavy-chain locus (IHC) on chromosome 14. Although it is known that the chromosomal breakpoints can be variably located within or outside the c-myc locus and within the IHC mu (refs 9, 11) or IHC gamma locus, the recombination sites have not been exactly identified and mapped in relation to the functional domains of these loci. We report here the identification and characterization of two reciprocal recombination sites between c-myc and IHC mu in a Burkitt lymphoma. Nucleotide sequencing of the cross-over point joining chromosomes 8 and 14 on chromosome 14q--shows that the onc gene is interrupted within its first intron and joined to the heavy-chain mu switch region. This recombination predicts that the translocated onc gene would code for a rearranged mRNA but a normal c-myc polypeptide.     

Two tandemly organized human genes encoding the T-cell gamma constant-region sequences show multiple rearrangement in different T-cell types

The recent detailed analysis of genes that undergo rearrangement in T cells has shown that the T-cell receptor genes encoding alpha- and beta-chains are involved in specific alterations in T-cell DNA analogous to the immunoglobulin genes. A third type of gene, designated gamma, has been isolated from mouse cytotoxic T lymphocytes, and evidence suggest that the mouse displays very limited diversity in this gene system, having only three variable-region (V) genes and three constant-region (C) genes. The function of the so-called T-cell gamma gene is unknown. We have isolated genomic genes encoding the human homologue of the mouse T-cell gamma gene; as there is no evidence that this T-cell rearranging gene is anything to do with the T3 molecule, we have designated the human T-cell rearranging gene as TRG gamma (ref. 13), to avoid confusion with the T3 gamma-chain, and have shown that the gene locus maps to chromosome 7 in humans. We now report that human DNA contains two tandemly arranged TRG gamma constant-region genes about 16 kilobases apart. These two genes show multiple rearrangement patterns in a variety of T cells, including helper and cytotoxic/suppressor type, as well as in all forms of T-cell leukaemia. Our results indicate variability of this T-cell gene system in man compared with the analogous system in mouse.     

Unusual organization and diversity of T-cell receptor alpha-chain genes

T lymphocytes recognize cell-bound antigens in the molecular context of the self major histocompatibility complex (MHC) gene products through the surface T-cell receptor(s). The minimal component of the T-cell receptor is a heterodimer composed of alpha and beta subunits, each of relative molecular mass (Mr) approximately 45,000 (refs 1-3). Recently, complementary DNA clones encoding these subunits have been isolated and characterized along with that of a third subunit of unknown function, termed gamma (refs 4-9). These studies revealed a primary structure for each subunit that was clearly similar to that of immunoglobulin and indicated a somatic rearrangement of corresponding genes that are also immunoglobulin-like. Recently, the analysis of the sequence organization of the T-cell receptor beta-chain and T-cell-specific gamma-chain gene families has been reported. We now present an initial characterization of the murine T-cell receptor alpha-chain gene family, and conclude that although it is clearly related to the gene families encoding immunoglobulins, T-cell receptor beta-chains and also T-cell gamma-chains, it shows unique characteristics. There is only a single constant (C) region gene segment, which is an exceptionally large distance (approximately 20-40 kilobases (kb) in the cases studied here) from joining (J) gene segments. In addition, the J cluster and the variable (V) segment number seen to be very large. Finally, in the case studied here, a complete alpha-chain gene shows no somatic mutation and can be assembled directly from V alpha, J alpha and C alpha segments without inclusion of diversity (D alpha) segments.     

Human gamma-chain genes are rearranged in leukaemic T cells and map to the short arm of chromosome 7

Three gene families that rearrange during the somatic development of T cells have been identified in the murine genome. Two of these gene families (alpha and beta) encode subunits of the antigen-specific T-cell receptor and are also present in the human genome. The third gene family, designated here as the gamma-chain gene family, is rearranged in murine cytolytic T cells but not in most helper T cells. Here we present evidence that the human genome also contains gamma-chain genes that undergo somatic rearrangement in leukaemia-derived T cells. Murine gamma-chain genes appear to be encoded in gene segments that are analogous to the immunoglobulin gene variable, constant and joining segments. There are two closely related constant-region gene segments in the human genome. One of the constant-region genes is deleted in all three T-cell leukaemias that we have studied. The two constant-region gamma-chain genes reside on the short arm of chromosome 7 (7p15); this region is involved in chromosomal rearrangements identified in T cells from individuals with the immunodeficiency syndrome ataxia telangiectasia and observed only rarely in routine cytogenetic analyses of normal individuals. This region is also a secondary site of beta-chain gene hybridization.     

Breakpoints in the human T-cell antigen receptor alpha-chain locus in two T-cell leukaemia patients with chromosomal translocations

Specific chromosomal translocations have been observed in several human and animal tumours and are believed to be important in tumorigenesis. In many of these translocations the breakpoints lie near cellular homologues of transforming genes, suggesting that tumour development is partly due to the activation of these genes. The best-characterized example of such a translocation occurs in mouse plasmacytoma and human B-cell lymphoma, where c-myc, the cellular homologue of the viral oncogene myc, is brought into close proximity with either the light- or heavy-chain genes of the immunoglobulin loci, resulting in a change in the regulation of the myc gene. T-cell malignancies also have characteristic chromosomal abnormalities, many of which seem to involve the 14q11-14q13 region. This region has recently been found to contain the alpha-chain genes of the human T-cell antigen receptor. Here we determine more precisely the chromosome breakpoints in two patients whose leukaemic T cells contain reciprocal translocations between 11p13 and 14q13. Segregation analysis of somatic cell hybrids demonstrates that in both patients the breakpoints occur between the variable (V) and constant (C) region genes of the T-cell receptor alpha-chain locus, resulting in the translocation of the C-region gene from chromosome 14 to chromosome 11. As the 11p13 locus has been implicated in the development of Wilms' tumour, it is possible that either the Wilms' tumour gene or a yet unidentified gene in this region is involved in tumorigenesis and is altered as a result of its translocation into the T-cell receptor alpha-chain locus.     

Rearrangement of two distinct T-cell gamma-chain variable-region genes in human DNA

Selective cloning procedures for T-cell-specific complementary DNAs have revealed the existence of a gene designated gamma as well as the main antigen receptor alpha- and beta-chain genes. The gamma-chain genes undergo rearrangement during T-cell differentiation but the patterns and complexity of such rearrangements differ markedly in mouse and human. In mouse, a panel of cytotoxic T-lymphocyte clones exhibit the same rearrangement pattern with a gamma-chain gene probe and a set of three gamma-chain variable (V) genes have been identified in the DNA. Clonal diversity in mouse seems to be confined to V-J (joining) regions. In contrast, human T-cell lines exhibit diverse rearrangements suggestive of a family of differing V gamma genes variously rearranging to the two gamma-chain constant (C) region genes. Here we report the cloning of two very different V gamma genes rearranged to J segments upstream of the two human C gamma genes. Both V gamma genes are rearranged productively but nucleotide sequence comparison shows that they possess very little homology with each other. This shows that human T-cell V gamma genes exist which differ significantly from each other at the nucleotide level and that such diverse genes can be usefully rearranged in different T cells.     

T-cell-specific deletion of T-cell receptor transgenes allows functional rearrangement of endogenous alpha- and beta-genes

In B cells the loci encoding immunoglobulin chains usually show allelic exclusion; a given B cell transcribes and translates only one productively rearranged allele of the heavy and light chain loci. This ensures that each B cell expresses only one antigen receptor. The loci encoding T-cell receptor (TCR) alpha- and beta-genes may behave similarly. We have previously reported that the expression of a transgenic TCR beta-chain prevents functional and nonfunctional V beta rearrangements in the endogenous beta-chain loci but not D beta J beta rearrangements. We have also been unable to detect the expression of the TCR gamma-chain locus in thymocytes of these mice (unpublished observations). To study the mechanisms involved in forming a mature T-cell repertoire further, we have constructed mice expressing alpha- and beta-TCR transgenes derived from a cytotoxic T-cell clone that is specific for the male antigen H-Y in the context of H-2Db MHC molecules. Here we show that in these mice rearrangement of endogenous alpha-chain loci is also suppressed, although to a lesser extent than rearrangement of beta-chain loci. In addition, in male alpha beta TCR transgenic mice we observed T-cell clones which had deleted both transgenic alpha- and beta-chain genes and expressed endogenous alpha- and beta-chain TCR genes. These cells are presumably derived from rare thymocytes that leave the male thymus because their TCR no longer recognizes self antigen. The vast majority of CD4+8+ nonmature thymocytes expressing alpha- and beta-transgenes are deleted in the male thymus.     

Variant (6 ; 15) translocation in a murine plasmacytoma occurs near an immunoglobulin kappa gene but far from the myc oncogene

Chromosome translocations in B-lymphoid tumours are providing intriguing insights and puzzles regarding the role of immunoglobulin genes in the activation of the myc oncogene (reviewed in refs 1, 2). The 15 ; 12 translocations found in most murine plasmacytomas and the analogous 8 ; 14 translocation in human Burkitt's lymphomas involve scissions of murine chromosome 15 (human chromosome 8) near the 5' end of the c-myc gene and subsequent fusion near an immunoglobulin heavy-chain gene. The less well characterized 'variant' translocations found in about 15% of such tumours also involve the myc-bearing chromosome band, but exchange occurs with a chromosome bearing an immunoglobulin light-chain locus--in mice, the kappa-chain locus bearing chromosome 6 (refs 3-5) and, in man, chromosome 2 (or 22), at the same band at which the kappa (or lambda) locus lies (reviewed in ref. 1). The Burkitt variant translocations involve scissions 3' of c-myc; one 8 ; 22 translocation placed the C lambda locus just 3' of c-myc, but usually the chromosome 8 breakpoint is a greater, but unknown, distance away from c-myc, more than 20 kilobases (kb) in one 8 ; 2 translocation involving the C kappa gene. Little is known about the murine 6 ; 15 translocations, although a C kappa gene cloned from one plasmacytoma (PC7183) is linked, via chromosome 12 sequences, to an unidentified region of chromosome 15 (ref. 11). We describe here the chromosome fusion region from plasmacytoma ABPC4, which displays the typical reciprocal 6;15 translocations. We find that the chromosome 6 breakpoint is near C kappa but, unlike those in the heavy-chain locus, not at a position where immunoglobulin genes normally recombine. Moreover, the chromosome 15 sequences involved in the ABPC4 translocation are not derived from the vicinity of c-myc.     

A chromosome 14 inversion in a T-cell lymphoma is caused by site-specific recombination between immunoglobulin and T-cell receptor loci

Specific chromosomal aberrations are associated with specific types of cancer (for review see ref. 1). The distinctiveness of each association has led to the belief that these chromosomal aberrations are clues to oncogenic events or to the state of differentiation in the malignant cell type. Malignancies of T lymphocytes demonstrate such an association characterized most frequently by structural translocations or inversions of chromosomes 7 and 14 (refs 7-9). Analyses of these chromosomally marked tumours at the molecular level may therefore provide insight into the aetiology of the cancers as well as the mechanisms by which chromosomes break and rejoin. Here we report such an analysis of the tumour cell line SUP-T1 derived from a patient with childhood T-cell lymphoma carrying an inversion of one chromosome 14 between bands q11.2 and q32.3, that is, inv(14) (q11.2; q32.2). These are the same chromosomal bands to which the T-cell receptor alpha-chain (14q11.2) and the immunoglobulin heavy-chain locus (14q32.3) have been assigned. Our analysis reveals that this morphological inversion of chromosome 14 was mediated by a site-specific recombination event between an immunoglobulin heavy-chain variable region (Ig VH) and a T-cell receptor (TCR) alpha-chain joining segment (TCR J alpha). S1 nuclease analysis shows that this hybrid gene is transcribed into poly(A)+ RNA.     

Preferential expression of a defined T-cell receptor beta-chain gene in hapten-specific cytotoxic T-cell clones

A multitude of different antigens can be recognized by T cells through specific receptors. Both the alpha- and beta-chains of the T-cell receptor contribute to the antigen recognition portion. The repertoire of beta-chain variable region (V beta) gene segments is limited to some 20 elements which seem to be used randomly in different T cells. Diversity at the beta-chain level can be created in several ways: a multiplicity of germline gene segments; combinatorial diversity by rearranging different V, diversity (D), joining (J) and constant (C) region elements; junctional diversity by joining gene segments at different sites; N-region diversity, that is, insertion of random nucleotides at junctional sites; and somatic mutation. However, the major sources and the extent of diversity of the T-cell receptor are unclear. To address this issue, 42 H-2Kb-restricted, 2,4,6-trinitrophenyl (TNP)-specific cytotoxic T-cell (Tc) clones from C57BL/6 mice were characterized with respect to expression of different beta-chain gene segments in messenger RNA using specific oligonucleotide probes. We report here that nearly half of the Tc clones use identical elements for productive beta-chain gene rearrangement. Thus, there is a restriction in the use of beta-chain gene segments in this panel of Tc clones which favours a particular V beta--D beta--J beta--C beta combination with a defined D beta element.     

Isolation of an excision product of T-cell receptor alpha-chain gene rearrangements

The genes for the T-cell receptor, like the immunoglobulin genes, are rearranged as DNA. The mechanism of this rearrangement is not clear; unequal crossover between chromosomes and the looping-out and excision of the excess DNA have both been suggested. We isolated small polydisperse circular (spc) DNAs from mouse thymocytes and cloned them into a phage vector. Of the 56 clones we analysed, nine contained sequences homologous to T-cell receptor alpha-chain joining (J alpha) segments. We have characterized one of these clones; it contains one J alpha segment, and the product out of the recombination of a variable region of the alpha-chain gene (V alpha) with a J alpha gene segment. This is the first demonstration of the presence in extrachromosomal DNA of a reciprocal recombination product of any rearranging immunoglobulin or T-cell receptor gene. The finding verifies that V alpha-J alpha joining can occur by the looping-out and excision of chromosomal DNA.