Rearranged beta T cell receptor genes in a helper T cell clone specific for lysozyme: no correlation between V beta and MHC restriction

The helper T cell clone 3H.25 is specific for hen egg white lysozyme and the class II MHC molecule I-Ab. This TH cell has three rearrangements in the beta-chain gene family-a V beta-D beta-J beta 1 and a D beta 2-J beta 2 rearrangement on one homolog and a D beta 1-J beta 2 rearrangement on the other. These observations demonstrate that this functional T lymphocyte expresses only a single V beta gene segment and, accordingly, exhibits allelic exclusion of beta-chain gene expression. The rearranged 3H.25 V beta gene segment is the same as that expressed in a T helper cell specific for cytochrome c and an I-Ek MHC molecule. Thus, there is no simple correlation between the V beta gene segment and antigen specificity or MHC restriction.     

Regulation of V(D)J recombination by transcriptional promoters

Enhancer elements potentiate the rearrangement of antigen receptor loci via changes in the accessibility of gene segment clusters to V(D)J recombinase. Here, we show that enhancer activity per se is insufficient to target T-cell receptor beta miniloci for DbetaJbeta recombination. Instead, a promoter situated 5' to Dbeta1 (PDbeta) was required for efficient rearrangement of chromosomal substrates. A critical function for promoters in regulating gene segment accessibility was further supported by the ability of heterologous promoters to direct rearrangement of enhancer-containing substrates. Importantly, activation of a synthetic tetracycline-inducible promoter (Ptet) positioned upstream from the Dbeta gene segment was sufficient to target recombination of miniloci lacking a distal enhancer element. The latter result suggests that DNA loops, generated by interactions between flanking promoter and enhancer elements, are not required for efficient recognition of chromosomal gene segments by V(D)J recombinase. Unexpectedly, the Ptet substrate exhibited normal levels of rearrangement despite its retention of a hypermethylated DNA status within the DbetaJbeta cluster. Together, our findings support a model in which promoter activation, rather than intrinsic properties of enhancers, is the primary determinant for regulating recombinational accessibility within antigen receptor loci.     

T cell migration during development: homing is not related to TCR V beta 1 repertoire selection.

T cell precursors enter the chick thymus in three waves during embryonic life. Each wave of thymocyte precursors colonizing the thymus gave rise to a similar TCR V beta repertoire in thymus, spleen and intestine both in terms of V beta 1 and J beta usage as well as in the length of V beta-D beta-J beta junctions. Seventeen V beta 1s were utilized, and a new J beta segment was found. In the progeny of the third wave, more nucleotides were deleted at the 5' end of the J beta segment, but the overall size of the CDR3 was conserved by a concomitant increase of N nucleotide addition at the V beta-D beta-J beta junctions during rearrangement. This CDR3 modification was observed in the spleen but not in the intestine, implying that progeny of the third wave migrate preferentially to the spleen, a possibility that was confirmed by adoptive cell transfers into congenic chickens. Very low frequencies of non-productive rearrangements in the intestine suggested that negative selection may occur in this organ. The present analysis indicates that V beta 1+ T cells in spleen and intestine are primarily of thymic origin, this colonization of both organs occurs in waves and is not characterized by preselection of the TCR V beta 1 repertoire.     

Molecular involvement of the pvt-1 locus in a gamma/delta T-cell leukemia bearing a variant t(8;14)(q24;q11) translocation.

A highly malignant human T-cell receptor (TCR) gamma/delta+ T-cell leukemia was shown to have a productive rearrangement of the TCR delta locus on one chromosome 14 and a novel t(8;14)(q24;q11) rearrangement involving the J delta 1 gene segment on the other chromosome 14. Chromosome walking coupled with pulsed-field gel electrophoretic (PFGE) analysis determined that the TCR J delta 1 gene fragment of the involved chromosome was relocated approximately 280 kb downstream of the c-myc proto-oncogene locus found on chromosome band 8q24. This rearrangement was reminiscent of the Burkitt's lymphoma variants that translocate to a region identified as the pvt-1 locus. Sequence comparison of the breakpoint junctions of interchromosomal rearrangements in T-cell leukemias involving the TCR delta-chain locus revealed novel signal-like sequence motifs, GCAGA(A/T)C and CCCA(C/G)GAC. These sequences were found on chromosome 8 at the 5' flanking site of the breakpoint junction of chromosome 8 in the TCR gamma/delta leukemic cells reported here and also on chromosome 1 in T-cell acute lymphocytic leukemia patients carrying the t(1;14)(p32;q11) rearrangement. These results suggest that (i) during early stages of gamma delta T-cell ontogeny, the region 280 kb 3' of the c-myc proto-oncogene on chromosome 8 is fragile and accessible to the lymphoid recombination machinery and (ii) rearrangements to both 8q24 and 1p32 may be governed by novel sequence motifs and be subject to common enzymatic mechanisms.     

T cell receptor beta gene sequences in the circular DNA of thymocyte nuclei: direct evidence for intramolecular DNA deletion in V-D-J joining

We have identified circular DNA containing T cell receptor (TCR) beta gene sequences in mouse thymocytes, thereby providing direct evidence for the intramolecular DNA deletion model of V-D-J joining in TCR beta genes. Two types of excision products of V-D-J joining have been identified. Type I, a circular reciprocal recombinant of normal V-D or D-J joining, contains a 7mer-7mer head-to-head structure expected from an excised product of normal V-D or D-J joining. Type II contains a D beta 2-J beta 1 structure on the circular DNA; the recombination event producing this molecule occurs between an upstream J and a downstream D segment, probably leaving the reciprocal 7mer-7mer structure on the chromosome. Some type I molecules seem to represent excision products of secondary joining after formation of the first D-J or V-D-J structure. The recombination mechanism that generates the circular DNA is discussed.     

In vivo transposition mediated by V(D)J recombinase in human T lymphocytes

The rearrangement of immunoglobulin (Ig) and T-cell receptor (TCR) genes in lymphocytes by V(D)J recombinase is essential for immunological diversity in humans. These DNA rearrangements involve cleavage by the RAG1 and RAG2 (RAG1/2) recombinase enzymes at recombination signal sequences (RSS). This reaction generates two products, cleaved signal ends and coding ends. Coding ends are ligated by non-homologous end-joining proteins to form a functional Ig or TCR gene product, while the signal ends form a signal joint. In vitro studies have demonstrated that RAG1/2 are capable of mediating the transposition of cleaved signal ends into non-specific sites of a target DNA molecule. However, to date, in vivo transposition of signal ends has not been demonstrated. We present evidence of in vivo inter-chromosomal transposition in humans mediated by V(D)J recombinase. T-cell isolates were shown to contain TCRalpha signal ends from chromosome 14 inserted into the X-linked hypo xanthine-guanine phosphoribosyl transferase locus, resulting in gene inactivation. These findings implicate V(D)J recombinase-mediated transposition as a mutagenic mechanism capable of deleterious genetic rearrangements in humans.     

Chimeric gamma-delta signal joints. Implications for the mechanism and regulation of T cell receptor gene rearrangement.

Rearrangement of Ag receptor genes requires recognition by the lymphocyte recombinase of heptamer-nonamer signal sequences followed by two endonucleolytic cleavages and two DNA ligations to form the coding and signal joints. The phenomenon of trans-rearrangement, in which Ag receptor gene segments located on different chromosomes recombine to yield chimeric products, provides an in vivo system in which to investigate the ability of the recombinase to carry out each of these functions in trans. Trans-rearrangements between TCRG and TCRD loci, similar in structure and frequency to those observed previously in human lymphoid tissues, were demonstrated in normal mouse thymus by PCR with crossed V gamma/J delta and V delta/J gamma primer pairs. A simple mechanistic model for trans-rearrangement was then tested. This model posits an ability of the recombinase to catalyze the formation of both coding and signal joints in trans and therefore predicts that trans-rearrangements will generate chimeric signal joints. In adult thymus, chimeric D delta 2-J gamma 1 and D delta 2-J gamma 2 signal joints, containing fused heptamer-nonamer sequences, could be detected by PCR and were each present at frequencies sufficient to account for a large proportion of the corresponding TCRG/TCRD trans-rearrangements. In agreement with the predictions of the model, chimeric signal joints were found as both linear chromosomal and circular episomal DNA. The results provide a framework for understanding the formation of chromosomal translocations in normal and neoplastic lymphoid cells and support the possibility of a looping mechanism for standard gene rearrangement. To test the form of regulation of TCRG rearrangement, the frequencies of specific signal joints from standard and trans-rearrangements were compared. Although J gamma 1 and J gamma 2 segments participated with equal frequency in trans-rearrangement with D delta 2, only the J gamma 1 segment participated in standard rearrangement with V gamma 5. The results suggest that V-J recombination in the TCRG locus is regulated directly at the DNA level by cis-acting constraints which do not affect the accessibility of individual TCRG gene segments to recombination in trans.     

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.     

Characterization of the human laminin beta2 chain locus (LAMB2): linkage to a gene containing a nonprocessed, transcribed LAMB2-like pseudogene (LAMB2L) and to the gene encoding glutaminyl tRNA synthetase (QARS).

The laminin beta2 chain is an important constituent of certain kidney and muscle basement membranes. We have generated a detailed physical map of a 110-kb genomic DNA segment surrounding the human laminin beta2 chain gene (LAMB2) on chromosome 3p21.3-->p21.2, a region paralogous with the chromosome 7q22-->q31 region that contains the laminin beta1 chain gene locus (LAMB1). Several CpG islands and a novel polymorphic microsatellite marker (D3S4594) were identified. The 3' end of LAMB2 lies 16 kb from the 5' end of the glutaminyl tRNA synthetase gene (QARS). About 20 kb upstream of LAMB2 we found a gene encoding a transcribed, non-processed LAMB2-like pseudogene (LAMB2L). The sequence of 1.75 kb of genomic DNA at the 3' end of LAMB2L was similar to exons 8-12 of the laminin beta2 chain gene. The LAMB2L-LAMB2-QARS cluster lies telomeric to the gene encoding the laminin-binding protein dystroglycan (DAG1).     

T cell receptor gene segment usage in a panel of hen-egg white lysozyme specific, I-Ak-restricted T helper hybridomas

We have studied the relationship between MHC-restricted, Ag-specific recognition and TCR structure in a panel of seven Th-hybridomas specific for the foreign protein Ag, hen egg-white lysozyme, and the I-Ak class II MHC molecule. The fine specificity of these Th cells had been determined previously by their reactivity to a panel of APC lines bearing mutant I-Ak molecules and to proteolytic fragments of HEL. TCR gene segment composition was determined by cDNA cloning and DNA sequencing. A heterogeneous, yet repetitive usage of gene segments was observed within the panel. The same V alpha C10-J alpha MD13 rearrangement was used in three of the hybridomas, two with identical Ag and MHC-restriction fine specificities. The prevalent usage of the V beta 14 gene segment and members of J beta 2 cluster was noted. Inasmuch as gene segment usage did not correlate with MHC-restriction or Ag fine specificity alone, these results favor an interactive Ag model of T-cell recognition, in which Ag and MHC are recognized as a bimolecular complex.     

Organization and nucleotide sequence of the rat T cell receptor beta-chain complex.

We have characterized four overlapping genomic clones containing the DA rat TCR C beta complex, which span a total of 23 kb and bear two closely related complexes of gene segments. The D beta 1-J beta 1-C beta 1 and the D beta 2-J beta 2-C beta 2 complexes each contain a single diversity segment, six joining segments and four exons that encode the C region. All gene segments appear to be functional except J beta 2.5, which has a 5-bp frame-shifting deletion. This organizational pattern is identical to that of the mouse, and the homologous rat and mouse coding regions share about 92% nucleotide sequence identity. Our sequence comparisons indicate that a localized gene correction event has homogenized the sequences of the first exons of C beta 1 and C beta 2 in the evolutionary time since rats and mice became separate species. We have identified three repetitive elements, each flanked by short direct repeats, present in the region "brain-specific" identifier (ID) sequences, another is a truncated member of the LINE I class of repetitive elements, and the third is a member of the Alu type 2 family. The insertion of at least two, and probably all, of these elements has occurred since the time of rat/mouse divergence. We have identified a substantial number of "cryptic" rearrangement signals (heptamer/nonamer) in the C beta locus, which match the consensus sequence as well or better than authentic signals, and may represent sites of nonfunctional rearrangements.     

Immature and advanced patterns of T cell receptor gene rearrangement among lymphocytes in splenic culture

Bulk populations and 39 hybridomas from splenic Con A cultures were analyzed for rearrangements among TCR genes: alpha, beta, gamma, and delta. Patterns were categorized to reveal general rules governing gene rearrangement within the activated adult peripheral population. Many patterns of gene rearrangement were consistent with previous studies of T cell lines. Additional points of interest were the following: 1) A large proportion of Con A-stimulated splenic cells bore no TCR gene rearrangements. 2) One splenic hybridoma exhibited an unusual gene pattern, with rearrangements, at alpha and beta, but not J gamma 1 or J gamma 2 loci. 3) Multiple gamma rearrangements were noted other than V1.2-J2 and V2-J1. 4) One hybridoma exhibited TCR gene rearrangements typical of day 14 to 15 fetal thymocytes, as well as rearrangements at immunoglobulin gene loci. 5) Among hybridomas with J alpha rearrangements, homologous chromosomes exhibited rearrangements at similar positions along the J alpha locus.     

SV40 recombinants carrying a functional RNA splice junction and polyadenylation site from the chromosomal mouse beta maj globin gene.

We have introduced a fragment of the chromosomal mouse beta major globin gene into SV40 and used the resultant hybrid virus to infect cultured monkey kidney cells. The mouse DNA fragment, which contains an intervening sequence and a poly(A) addition site, has been inserted in both possible orientations relative to the SV40 late region promoter. While the fragment is transcribed regardless of orientation, the RNA splice signal and poly(A) addition site are utilized only when the fragment is inserted in the "sense" orientation. Thus genomic mouse signals for both splicing and polyadenylation are recognized across species boundaries. Furthermore, since only an 18 bp segment was included on the 5' border of the intervening sequence, we can define a maximum length for this splice signal.