Antigenic stimulation induces recombination activating gene 1 and terminal deoxynucleotidyl transferase expression in a murine T-cell hybridoma

Secondary rearrangements of the T cell receptor (TCR) represent a genetic correction mechanism which changes T cell specificity by re-activating V(D)J recombination in peripheral T cells. Murine T-cell hybridoma A1.1 was employed to investigate whether antigenic stimulation induced re-expression of recombinase genes and altered TCR Vβ expression. Following repeated antigenic stimulation, A1.1 cells were induced to re-express recombination activating gene (RAG)1 and terminal deoxynucleotidyl transferase (TdT) which are generally considered prerequisite to TCR gene rearrangement. Accompanied with the significant changes in TCR mRNA levels over time, it is suggested that secondary rearrangements may be induced in A1.1 cells, which represent a mature T cell clone capable of re-expressing RAG genes and possesses the prerequisite for secondary V(D)J rearrangement.     

Structure of extrachromosomal circular DNAs excised from T-cell antigen receptor alpha and delta-chain loci

Small polydisperse circular (spc) DNA was isolated from mouse thymocytes, fragmented by HindIII digestion and cloned into the vector. Sixty DNA clones were randomly selected from the 10,400 phage library. The average size of insert was one-fifth of the original circular molecule. Twenty spc-DNA clones were homologous to DNA probes derived from T-cell antigen receptor (TCR) alpha-chain loci. We have characterized nine clones by DNA sequencing; they contain new germline sequences of the TCR alpha-chain variable (V alpha) and joining (J alpha) gene segments and the products out of the recombination of a V alpha with a J alpha gene segment. An additional four spc-DNA clones carried a new rearranging gene of the TCR delta-chain that is located between V alpha and J alpha genes. At least nine of 60 DNA clones carried the recombination junction of a heptamer-heptamer head-to-head structure expected from an excised product of V-J joining. This shows that most extrachromosomal circular DNAs in the thymus are formed by a sequence-dependent recombination mechanism. We suggest that a functional T-cell receptor V alpha gene can be constructed by somatic random rearrangements through successive looping-out, excision and deletion.     

The joining of germ-line V alpha to J alpha genes replaces the preexisting V alpha-J alpha complexes in a T cell receptor alpha, beta positive T cell line

To determine whether T cell receptor genes follow the same principle of allelic exclusion as B lymphocytes, we have analyzed the rearrangements and expression of TCR alpha and beta genes in the progeny of the CD3+, CD4-/CD8- M14T line. Here, we show that this line can undergo secondary rearrangements that replace the pre-existing V alpha-J alpha rearrangements by joining an upstream V alpha gene to a downstream J alpha segment. Both the productively and nonproductively rearranged alleles in the M14T line can undergo secondary rearrangements while its TCR beta genes are stable. These secondary recombinations are usually productive, and new forms of TCR alpha polypeptides are expressed in these cells in association with the original C beta chain. Developmental control of this V alpha-J alpha replacement phenomenon could play a pivotal role in the thymic selection of the T cell repertoire.     

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.     

Nonrandom rearrangement of T cell receptor J alpha genes in bone marrow T cell differentiation cultures

TCR J alpha genes span a distance of approximately 65 kb on mouse chromosome 14. Due to the existence of 50 to 100 discrete J genes, a potential for great diversity exists within the V-J-C alpha gene products and within the ultimate repertoire of alpha beta TCR. We have prepared hybridomas from an in vitro system that supports T cell differentiation among bone marrow cells. We have examined the J alpha genes among these cells and categorized rearrangements according to their location within the J alpha locus. It was found that alpha rearrangements were always present among the hybridomas bearing beta gene rearrangements. When two bone marrow-derived alpha-bearing chromosomes could be demonstrated in these hybridomas, both were always rearranged and rearrangements on homologous chromosomes were shown to reside in similar regions of the J alpha locus. Most surprisingly, when hybridomas were categorized by the culture from which they derived, cells from the same culture (designated as a set) demonstrated a skewing of alpha rearrangements to restricted segments of J alpha genes. In one hybridoma, rearrangements on homologous chromosomes involved J alpha genes that were either identical or situated within a 1-kb segment of DNA. The skewing within sets could not be due to clonal identity between hybridomas as the beta and gamma rearrangements in all hybridomas were different. Results suggested that skewing of J alpha gene rearrangements occurred during the course of T cell development in vitro. Should the same situation occur in vivo, the number of distinct TCR J alpha sequences available for expression in early development may be far less than that predicted by gene number alone.     

TCR beta and TCR alpha gene enhancers confer tissue- and stage-specificity on V(D)J recombination events.

We describe transgenic mice carrying germline variable gene segments associated with either the T cell receptor (TCR) beta or alpha gene enhancers (E beta or E alpha). Transgenic constructs underwent high rates of site-specific rearrangements predominantly in T cells from independent mice. Rearrangements of the E beta-containing transgenes began at different stages of T cell differentiation in embryonic and adult thymus than did the E alpha-containing ones, with a pattern superimposable upon the patterns of TCR beta or TCR alpha gene expression, respectively. We demonstrate that sequences within the TCR beta and TCR alpha gene enhancers confer tissue- and stage-specificity upon the V(D)J recombination events affecting adjacent gene segments. The patterns of transgene expression also gave information on developmental events and lineage relationships (gamma delta versus alpha beta) during T cell development.     

Analysis of a monoclonal rat antibody directed to the alpha-chain variable region (V alpha 3) of the mouse T cell antigen receptor

Three rat mAb, RR3-15, RR3-16, and RR3-18, were established by fusing spleen cells from a rat immunized with the male Ag-specific cytolytic T cell clone, OH6, to mouse myeloma cells. The mAb was identified by their capacity to focus the cytolytic activity of the OH6 CTL clone on nonspecific target cells via FcR-FcR interaction. That all three mAb recognized the OH6 TCR was confirmed by immunoprecipitation studies in which each antibody precipitated a 90 kDa disulfide-linked heterodimer characteristic of the TCR. Surface immunofluorescence staining of a panel of T cell lines and splenic T cell populations showed that RR3-16 reacted not only to the OH6 T cell clone but also to a minor fraction of normal T cells. This reactivity was found to be due to the expression of a gene in the V alpha 3 family. However, RR3-16 did not react with all T cell lines and clones known to express genes from the V alpha 3 family. cDNA sequences of three independent RR3-16+ T cell hybridomas analyzed by polymerase chain reaction were identical to the previously published V alpha 3 sequence of the CTL clone C9. Thus, the mAb RR3-16 is specific for a single member of the TCR V alpha 3 gene family. Analysis of the expression of RR3-16+ TCR in CD4+ and CD8+ subsets of peripheral T cells demonstrated preferential expression on CD8+ T cells, suggesting regulated expression of this particular TCR V alpha gene.     

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.     

T cell receptor gamma gene status of human alpha/beta+ and gamma/delta+ T cell clones: absence of V9JP rearrangements in alpha/beta+ clones is not a result of a lack of rearrangements involving more 5' J gamma segments

T cell receptor (TCR) gamma gene rearrangements were examined in panels of human T cell clones expressing TCR alpha/beta or gamma/delta heterodimers. Over half of the alpha/beta+ clones had both chromosomes rearranged to C gamma 2 but this was the case for only 20% of the gamma/delta+ clones. While more than half of the gamma/delta+ clones showed a V9JP rearrangement, this configuration was absent from all 49 alpha/beta+ clones analysed. However, this was not a result of all rearrangements being to the more 3' J gamma genes as 11 alpha/beta+ clones had rearrangement(s) to JP1, the most 5' J gamma gene segment. Both alpha/beta+ and gamma/delta+ clones showed a similar pattern of V gamma gene usage in rearrangements to J gamma 1 or J gamma 2 with a lower proportion of the more 3' genes being rearranged to J gamma 2 than for the more 5' genes. Several alpha/beta+ and several gamma/delta+ clones had noncoordinate patterns of rearrangement involving both C gamma 1 and C gamma 2. Eleven out of fourteen CD8+ clones tested had both chromosomes rearranged to C gamma 2 whereas all clones derived from CD4-8- cells and having unconventional phenotypes (CD4-8- or CD4+8+) had at least one C gamma 1 rearrangement. Twelve out of twenty-seven CD4+ clones also had this pattern, suggesting that CD4-8+ clones had a tendency to utilize more 3' J gamma gene segments than CD4+ clones. There was some evidence for interdonor variation in the proportions of TCR gamma rearrangements to C gamma 1 or C gamma 2 in alpha/beta+ clones as well as gamma/delta+ clones. The results illustrate the unique nature of the V9JP rearrangement in gamma/delta+ clones and the possible use of a sequential mechanism of TCR gamma gene rearrangements during T cell differentiation is discussed.     

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.     

Nonencephalitogenic CD4-CD8- V alpha 2V beta 8.2+ anti-myelin basic protein rat T lymphocytes inhibit disease induction.

Recently there has been a number of reports suggesting that CD4-CD8- T cells participate in the processes of inflammatory reaction. In an attempt to delineate the distinctive functions of double negative (DN) T lymphocytes in an autoimmune-induced disease, we isolated and cloned such T cells, along with control CD4+ cells, from Lewis rats immunized with guinea-pig myelin basic protein in CFA. Both clones proliferated in response to the guinea-pig myelin basic protein and its synthetic encephalitogenic peptide, and expressed the same TCR V genes homologous to the mouse V alpha 2 and V beta 8.2 families that appear to be the defining entity of experimental autoimmune encephalomyeltis (EAE). Moreover, the TCR D and J region gene products of the DN cell were found to be similar to another encephalitogenic rat T cell clone. The two T clones did not differ markedly in their ability to produce TNF and IL-2 and to adhere to vascular wall-derived extracellular matrix- and laminin-coated plates. Surprising, therefore, was the finding that, although the CD4+ T lymphocytes were capable of inducing EAE, the DN cells did not elicit disease but rather inhibited subsequent EAE induction. Thus, TCR V alpha 2V beta 8.2 and its junctional region gene products are not the only prerequisite segment for a T cell to become encephalitogenic. We suggest that the important determinants of the T cell ability to induce disease are features of the T cell, other than or in addition to, the T cell receptor.     

TCR delta gene rearrangements revealed by fine structure of the recombination junction in mice

The standard products of V(D)J recombination of immunoglobulin and T cell receptor genes are two kinds of DNA junction, a coding joint and a signal joint. TCR delta V-D and D-D signal joints in adult mouse thymocytes were sequenced following PCR amplification. We observed differential nucleotide insertions at the V delta-D delta signal joints, depending on the V delta and D delta gene usage in the developmental stage. Nucleotide insertions at the V delta-D delta 1 signal joints were less frequent for the V delta 4, 5 genes preferentially utilized in adult thymocytes than for the V delta 3, 6 genes, infrequently rearranged to D delta 1. In addition to standard signal joints, unexpectedly, novel nonstandard products, "replacement joints" of D delta 1 substituted downstream by the recombination signal sequence of V delta were also found. However, no D delta 2-associated replacement joints other than V delta 5 were found. The other replacement joints of D delta 1-D delta 2 recombination were also observed. The mutation in TCR beta gene affected the frequency of nucleotide insertions at the V delta-D delta signal joints and inhibited the formation of replacement joint. Recombination mechanism generating the replacement joint and the possible role of TCR beta in up-regulation of TCR delta gene rearrangements are discussed.     

Mouse T cell antigen receptor: Structure and organization of constant and joining gene segments encoding the β polypeptide

The germ-line joining (J) gene segments and constant (C) genes encoding the β chain of the mouse T cell antigen receptor have been isolated on a single cosmid clone. There are two constant genes, C_β1 and C_β2, each associated with a cluster of J_β gene segments. The nucleotide sequences of the C_β2 gene and of the J_β2 cluster gene segments have been determined. The coding sequence of the C_β2 gene is very similar to the sequence of a cDNA clone encoded by the C_β1 gene. The C_β2 gene has four exons; exon-intron structure does not obviously correspond to the functional domains of the protein. The J_β2 gene segment cluster contains six functional J gene segments. We have isolated specific probes for the C_β1, C_β2, J_β1, and J_β2 regions to examine DNA rearrangements in T lymphocytes. DNA rearrangements can occur in both J_β gene segment clusters, and both C_β genes appear functional.     

The human T cell antigen receptor is encoded by variable, diversity, and joining gene segments that rearrange to generate a complete V gene

A cDNA clone YT35 , synthesized from poly(A)+ RNA of the human T cell tumor Molt 3, exhibits homology to the variable (V), joining (J), and constant (C) regions of immunoglobulin genes. We have isolated and sequenced the germ-line V and J gene segment counterparts to YT35 from a human cosmid library, and these failed to encode 14 nucleotides of the cDNA clone between the V and J regions. We postulate that these 14 nucleotides are encoded by a third gene segment analogous to the diversity (D) gene segments of immunoglobulin heavy chain genes. This T cell antigen receptor V gene appears to be assembled from three gene segments, V, D, and J, and accordingly most closely resembles immunoglobulin heavy chain V genes.     

Cutting edge: TCR delta gene is frequently rearranged in adult B lymphocytes

TCR gene rearrangement generates diversity of T lymphocytes by V(D)J recombination. Ig genes are rearranged in B cells using the same enzyme machinery. Physiologically, TCR gene is postulated to rearrange exclusively in T lineage, but malignant B precursor lymphoblasts contain rearranged TCR genes in most patients. Several mechanisms by which malignant cells break the regulation of V(D)J recombination have been proposed. In this study we show that incomplete TCR delta rearrangements V2-D3 and D2-D3 occur each in up to 16% alleles in B lymphocytes of all healthy donors studied, but complete VDJ rearrangement was negative at the sensitivity limit of 1%. Data are based on real-time quantitative PCR validated by PAGE and sequencing of the cloned products. Therefore, TCR genes rearrange not exclusively in T lineage. This study opens up further questions regarding the exact extent of the "cross-lineage" TCR or Ig rearrangements in normal lymphocytes, specific subsets in which the cross-lineage rearrangements occur, and the physiological importance of these rearrangements.