Characterization of an avian (Gallus gallus domesticus) TCR alpha delta gene locus.

Mammalian TCR delta genes are located in the midst of the TCR alpha gene locus. In the chicken, one large V delta gene family, two D delta gene segments, two J delta gene segments, and one C delta gene have been identified. The TCR delta genes were deleted on both alleles in alpha beta T cell lines, thereby indicating conservation of the combined TCR alpha delta locus in birds. V alpha and V delta gene segments were found to rearrange with one, both or neither of the D delta segments and either of the two J delta segments. Exonuclease activity, P-addition, and N-addition during VDJ delta rearrangement contributed to TCR delta repertoire diversification in the first embryonic wave of T cells. An unbiased V delta 1 repertoire was observed at all ages, but an acquired J delta 1 usage bias occurred in the TCR delta repertoire. The unrestricted combinatorial diversity of relatively complex TCR gamma and delta loci may contribute to the remarkable abundance of gamma delta T cells in this avian representative.     

Characterization of excised DNA intermediates associated with V(D)J recombination at the T-cell receptor delta locus.

Lymphocyte development requires the assembly of antigen receptor genes through the specialized process of V(D)J recombination. This process is initiated by cleavage at the junction between coding segments (V, D, and J) and the recombination signal sequences that border these segments, resulting in generation of double-strand break intermediates. We have used a two-dimensional gel system to characterize broken molecules arising from V(D)J recombination at the T-cell receptor (TCR) delta locus and have identified linear species excised by Ddelta1-Ddelta2 and V-Ddelta2 rearrangement in thymus DNA. Relatively few (approximately 10) V-Ddelta2-excised linear species were detected in DNA from fetal thymocytes. The sizes of these species corresponded to the estimated distances between Ddelta2 and the V gene segments utilized by gammadelta T cells and indicated that both Ddelta2-proximal and -distal V gene segments are targeted for V-Ddelta2 rearrangement. Similar-sized species were observed in DNA from thymocytes of scid mice in which T-cell development is arrested prior to TCR expression. Since previous studies suggest that the TCR alpha/delta locus encodes more than 100 V gene segments, our results indicate that a few select V gene segments are predominantly targeted for rearrangement to Ddelta2, and this primarily accounts for the restricted Vdelta gene repertoire of gammadelta T cells.     

Excision products of the T cell receptor gene support a progressive rearrangement model of the alpha/delta locus.

We have cloned extrachromosomal circular DNAs containing T cell receptor (TCR) delta gene segments in adult mouse thymocytes and splenocytes. We find that the frequency of circular DNA clones carrying germline delta sequences is lower than that of J alpha probe-positive clones, possibly related to increasing 5' distance from the most upstream J alpha segment. This suggests that the TCR alpha/delta locus is successively rearranged from within and that the delta-containing excision products are progressively diluted out by the subsequent cell division which includes further alpha gene rearrangements. In addition, examination of delta gene excision products revealed newly identified V delta subfamilies, the reciprocal joining of two D delta elements, J delta 2 usage in thymocytes and novel sequences homologous to the human delta-gene deleting elements.     

Dissecting microregulation of a master regulatory network

Background

All jawed-vertebrates have four T cell receptor (TCR) chains: alpha (TRA), beta (TRB), gamma (TRG) and delta (TRD). Marsupials appear unique by having an additional TCR: mu (TRM). The evolutionary origin of TRM and its relationship to other TCR remain obscure, and is confounded by previous results that support TRM being a hybrid between a TCR and immunoglobulin locus. The availability of the first marsupial genome sequence allows investigation of these evolutionary relationships.

Results

The organization of the conventional TCR loci, encoding the TRA, TRB, TRG and TRD chains, in the opossumMonodelphis domesticaare highly conserved with and of similar complexity to that of eutherians (placental mammals). There is a high degree of conserved synteny in the genomic regions encoding the conventional TCR across mammals and birds. In contrast the chromosomal region containing TRM is not well conserved across mammals. None of the conventional TCR loci contain variable region gene segments with homology to those found in TRM; rather TRM variable genes are most similar to that of immunoglobulin heavy chain genes.

Conclusion

Complete genomic analyses of the opossum TCR loci continue to support an origin of TRM as a hybrid between a TCR and immunoglobulin locus. None of the conventional TCR loci contain evidence that such a recombination event occurred, rather they demonstrate a high degree of stability across distantly related mammals. TRM, therefore, appears to be derived from receptor genes no longer extant in placental mammals. These analyses provide the first genomic scale structural detail of marsupial TCR genes, a lineage of mammals used as models of early development and human disease.     

A delta T-cell receptor deleting element transgenic reporter construct is rearranged in alpha beta but not gamma delta T-cell lineages.

T cells can be divided into two groups on the basis of the expression of either alpha beta or gamma delta T-cell receptors (TCRs). Because the TCR delta chain locus lies within the larger TCR alpha chain locus, control of the utilization of these two receptors is important in T-cell development, specifically for determination of T-cell type: rearrangement of the alpha locus results in deletion of the delta coding segments and commitment to the alpha beta lineage. In the developing thymus, a relative site-specific recombination occurs by which the TCR delta chain gene segments are deleted. This deletion removes all D delta, J delta, and C delta genes and occurs on both alleles. This delta deletional mechanism is evolutionarily conserved between mice and humans. Transgenic mice which contain the human delta deleting elements and as much internal TCR delta chain coding sequence as possible without allowing the formation of a complete delta chain gene were developed. Several transgenic lines showing recombinations between deleting elements within the transgene were developed. These lines demonstrate that utilization of the delta deleting elements occurs in alpha beta T cells of the spleen and thymus. These recombinations are rare in the gamma delta population, indicating that the machinery for utilization of delta deleting elements is functional in alpha beta T cells but absent in gamma delta T cells. Furthermore, a discrete population of early thymocytes containing delta deleting element recombinations but not V alpha-to-J alpha rearrangements has been identified. These data are consistent with a model in which delta deletion contributes to the implementation of a signal by which the TCR alpha chain locus is rearranged and expressed and thus becomes an alpha beta T cell.     

Genomic organization of the mouse T cell receptor V alpha family.

Based on the analysis of V alpha gene segment deletions in a panel of T lymphomas, we have constructed a map of the mouse T cell receptor alpha/delta region and assigned the relative position of 72 distinct V gene segments. Three major observations have emerged from such studies. First, members of a given V alpha subfamily are not organized in discrete units along the chromosome but largely interspersed with members of other V alpha subfamilies. Second, analysis of the deletion map suggests the existence of repetitive patterns (V alpha clusters) in the chromosomal distribution of the V alpha gene segments. Third, the present-day organization of the V alpha/delta region may be readily explained by a series of sequential duplications involving three ancestral V alpha clusters. Direct evidence for the existence of these unique structural features has been gained by cloning approximately 370 kb of DNA and positioning 26 distinct V alpha gene segments belonging to six different subfamilies. Finally, the relationships existing between the V alpha/delta gene segment organization and usage are discussed in terms of position-dependent models.     

A conserved sequence block in the murine and human TCR J alpha region: assessment of regulatory function in vivo

Temporal control of rearrangement at the TCR alpha/delta locus is crucial for development of the gamma delta and alpha beta T cell lineages. Because the TCR delta locus is embedded within the alpha locus, rearrangement of any V alpha-J alpha excises the delta locus, precluding expression of a functional gamma delta TCR. Approximately 100 kb spanning the C delta-C alpha region has been sequenced from both human and mouse, and comparison has revealed an unexpectedly high degree of conservation between the two. Of interest in terms of regulation, several highly conserved sequence blocks (> 90% over > 50 bp) were identified that did not correspond to known regulatory elements such as the TCR alpha and delta enhancers or to coding regions. One of these blocks lying between J alpha 4 and J alpha 3, which appears to be conserved in other vertebrates, has been shown to augment TCR alpha enhancer function in vitro and differentially bind factors from nuclear extracts. To further assess a plausible regulatory role for this element, we have created mice in which this conserved sequence block is either deleted or replaced with a neomycin resistance gene driven by the phosphoglycerate kinase promoter (pgk-neor). Deletion of this conserved sequence block in vivo did have a local effect on J alpha usage, echoing the in vitro data. However, its replacement with pgk-neor had a much more dramatic, long range effect, perhaps underscoring the importance of maintaining overall structure at this locus.     

A novel type of aberrant T cell receptor alpha-chain gene rearrangement. Implications for allelic exclusion and the V-J recombination process

In the process of analyzing the contribution of nonproductive alpha- and beta-chain gene rearrangements to the allelic exclusion of TCR gene expression, we have found a novel type of aberrant alpha-gene rearrangement. In one alpha-allele of the mouse KB5-C20 T cell clone, a J alpha gene segment has been abutted precisely to a sequence that does not display any homology to known V and D gene segment. The appended sequence originates from within the V alpha locus and is located, in the germ-line, 1 kb upstream of a member of the V alpha 2-gene segment subfamily. No recombination signal sequences have been found contiguous to the recombination point. These observations indicate that in normal T lymphocytes, TCR alpha-genes may be affected by aberrant rearrangements similar to those that predominate in human T cell tumors containing chromosome 14 inversion or translocation. Furthermore, compilation of published data and cloning and sequencing of three additional alpha-alleles has allowed us to examine the status of alpha-loci in nine mouse T cell clones expressing functional alpha beta-heterodimers. Interestingly, in contrast to the situation observed at the beta-locus, only 1 of 18 analyzed alpha-alleles has retained a germ-line unrearranged configuration. In addition, in each T cell clone, alpha-rearrangements on homologous chromosomes were unevenly distributed over the J alpha region and shown to generally involve neighboring J alpha gene segments.     

Structural analysis of the gene for the beta chain of the antigen-specific receptor of mammalian T-lymphocytes

The antigen specific receptor of T cells (TCR) is composed of alpha and beta chains and is normally present on the T cell surface complexed with the components which make up T3. In the case of beta chain, multiple somatic DNA rearrangements bring together V beta (variable), D beta (diversity) and J beta (joining) gene segments before a mature messenger RNA can be transcribed. So far beta chain genes have been extensively studied in the human and in the mouse system and we have very little information on other mammals. Our aims were to obtain information that may provide a structural basis for understanding developmental as well as evolutionary aspects of the TCR gene system in mammals. In this study we compare the hybridization pattern between a human cDNA probe coding for the beta chain constant region and restricted genomic DNA extracted from lymphocytes deriving from human as well as from rat and lamb. The comparison of the hybridization data represent a first piece of information about the variation of the structure of the TCR beta chain genes in mammals.     

Organization of the human T-cell receptor genes

T lymphocytes recognize antigens through their membrane bound T-cell receptors. Whereas the conventional T-cell receptors are heterodimers of alpha and beta chains, expressed at the surface of CD3+ CD4+ and CD3+ CD8+ T lymphocytes, the gamma delta T-cell receptors are found at the surface of a subset of T-lymphocytes of phenotype CD3+ CD4- CD8-. The synthesis of the T-cell receptor chains results from the junction (or rearrangement) of DNA segments: Variable (V) gene and joining (J) segment for the alpha and gamma chains, V gene, D (diversity) and J segments for the beta and delta chains. In this review, we summarize the recent findings on the genomic organization of the alpha, beta, gamma and delta T-cell receptor loci in human.     

Evolutionary comparison of murine and human delta T-cell receptor deleting elements

The gene for the T-cell antigen receptor (TCR) delta chain is a gene within a gene, being located in the TCR alpha chain gene in both mice and humans. The human delta locus is flanked by delta deleting elements that undergo preferential rearrangement in the thymus, resulting in deletion of internal delta coding segments. The mouse has conserved analogous elements, m delta Rec and m phi J alpha, which separate delta from alpha and undergo a m delta Rec/m phi J alpha rearrangement in polyclonal thymus. The 5' element, m delta Rec, which is an isolated heptamer-spacer-nonamer (h-s-n), lies within 200 kb of D delta 1, and displays two areas of nearly 80% homology to human delta Rec. The downstream element, m phi J alpha, lies 12.5 kb 3' to C delta, lacks the consensus amino acids for J alpha, and retains 80% homology to human phi J alpha. Cells from murine neonatal thymus show three prominent m delta Rec rearrangements consisting of the m delta Rec/m phi J alpha recombination, a delta Rec/D delta 1/D delta 2/J delta 1 recombination, and two hybrid recombinations. A consequence of the m delta Rec/M phi J alpha rearrangement is a deletion of internal D delta and J delta coding segments that would prevent their incorporation into alpha TCR products. The conservation of noncoding deleting elements flanking the delta TCR in mice and humans is similar to the evolutionarily preserved kappa deleting element of the B-cell lineage and argues for an important role in receptor utilization.     

The T cell receptor beta locus of the channel catfish,Ictalurus punctatus,reveals unique features

Previously, a series of clonal alloantigen-dependent T cell lines established from the channel catfish revealed distinctly different TCR beta rearrangements. Here, a follow-up study of the junctional diversity of these TCR gene rearrangements focuses on characterization of the genomic organization of the TCRB locus. Surprisingly, a total of 29 JB genes and two substantially different CB genes were identified downstream of a single DB gene. This is in contrast to the situation in mammals, where two clusters of a DB gene, six or seven JB genes, and a CB gene are found in tandem. The catfish CB genes are approximately 36% identical at the amino acid level. All 29 catfish JB gene segments appear functional. Thirteen were used in the 19 cDNAs analyzed, of these eight were used by the 11 catfish clonal alloantigen-dependent T cell lines. As might be expected, CDR3 diversity is enhanced by N-nucleotide additions as well as nucleotide deletions at the V-D and D-J junctions. Taken together, compared with that in mammals, genomic sequencing of the catfish TCR DB-JB-CB region reveals a unique locus containing a greater number of JB genes and two distinct CB genes.     

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

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

A possible basis for major histocompatibility complex-restricted T-cell recognition

Four distinct T-cell antigen-receptor gene loci have now been identified and partly characterized: alpha, beta, gamma and delta. All of these loci can rearrange in an immunoglobulin-like fashion and express polypeptides that contribute to either alpha:beta or gamma:delta T-cell receptor-CD3 complexes. Surprisingly, the T-cell receptor (TCR) delta coding regions are located entirely, or almost entirely, within the TCR alpha locus and share at least some of the V region gene segments, thus at least partly linking the two different types of receptor heterodimers. Analysis of potential T-cell receptor diversity, particularly that of the delta chain, indicates a striking concentration of somatic polymorphism in the V-J junctional region of the two heterodimers, four to six orders of magnitude higher than similar calculations for immunoglobulin light- and heavy-chain combinations. In contrast, the number of possible V region combinations in T-cell receptors is one hundredth to one thousandth that of immunoglobulins. TCR alpha: beta heterodimers are known to recognize many possible fragments of antigens embedded in the peptide-binding clefts of a relatively small number of major histocompatibility complex (MHC) molecules. Thus it is attractive to speculate that the V-J junctional portions of both types of T-cell receptor contact peptide antigens, whereas the remaining diversity regions contact the MHC. This contention is supported by molecular modelling studies and has interesting implications for the evolution of antigen-receptor genes.     

A Model for the Evolution of the Mammalian T-cell Receptor α/δ and μ Loci Based on Evidence from the Duckbill Platypus

The specific recognition of antigen by T cells is critical to the generation of adaptive immune responses in vertebrates. T cells recognize antigen using a somatically diversified T-cell receptor (TCR). All jawed vertebrates use four TCR chains called α, β, γ, and δ, which are expressed as either a αβ or γδ heterodimer. Nonplacental mammals (monotremes and marsupials) are unusual in that their genomes encode a fifth TCR chain, called TCRμ, whose function is not known but is also somatically diversified like the conventional chains. The origins of TCRμ are also unclear, although it appears distantly related to TCRδ. Recent analysis of avian and amphibian genomes has provided insight into a model for understanding the evolution of the TCRδ genes in tetrapods that was not evident from humans, mice, or other commonly studied placental (eutherian) mammals. An analysis of the genes encoding the TCRδ chains in the duckbill platypus revealed the presence of a highly divergent variable (V) gene, indistinguishable from immunoglobulin heavy (IgH) chain V genes (VH) and related to V genes used in TCRμ. They are expressed as part of TCRδ repertoire (VHδ) and similar to what has been found in frogs and birds. This, however, is the first time a VHδ has been found in a mammal and provides a critical link in reconstructing the evolutionary history of TCRμ. The current structure of TCRδ and TCRμ genes in tetrapods suggests ancient and possibly recurring translocations of gene segments between the IgH and TCRδ genes, as well as translocations of TCRδ genes out of the TCRα/δ locus early in mammals, creating the TCRμ locus.