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.     

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.     

Characterization of TCR gene rearrangements during adult murine T cell development

Development of the alphabeta and gammadelta T cell lineages is dependent upon the rearrangement and expression of the TCRalpha and beta or gamma and delta genes, respectively. Although the timing and sequence of rearrangements of the TCRalpha and TCRbeta loci in adult murine thymic precursors has been characterized, no similar information is available for the TCRgamma and TCRdelta loci. In this report, we show that approximately half of the total TCRdelta alleles initiate rearrangements at the CD44highCD25+ stage, whereas the TCRbeta locus is mainly in germline configuration. In the subsequent CD44lowCD25+ stage, most TCRdelta alleles are fully recombined, whereas TCRbeta rearrangements are only complete on 10-30% of alleles. These results indicate that rearrangement at the TCRdelta locus can precede that of TCRbeta locus recombination by one developmental stage. In addition, we find a bias toward productive rearrangements of both TCRdelta and TCRgamma genes among CD44highCD25+ thymocytes, suggesting that functional gammadelta TCR complexes can be formed before the rearrangement of TCRbeta. These data support a model of lineage commitment in which sequential TCR gene rearrangements may influence alphabeta/gammadelta lineage decisions. Further, because TCR gene rearrangements are generally limited to T lineage cells, these analyses provide molecular evidence that irreversible commitment to the T lineage can occur as early as the CD44highCD25+ stage of development.     

Diversity, rearrangement, and expression of murine T cell gamma genes

Although the T cell gamma genes are similar in many respects to T cell receptor alpha and beta genes, earlier studies suggested that only a single gamma variable (V gamma) gene is expressed in mature T cells. We report the isolation and characterization of three new rearranged V gamma genes from murine fetal thymocytes. Although each of the new V gamma gene rearrangements is present in fetal thymocytes, two of them are undetectable in mature T cells. The levels of mRNA corresponding to each type of V gamma gene rearrangement in mature T cells are dramatically diminished compared with those in fetal thymocytes, although the abundance of two of the rearranged genes is increased in mature T cells. Our results demonstrate that there is significant expressed variability of gamma genes in immature T cells. Furthermore, the dynamics of gamma gene rearrangement and expression support the idea that gamma genes function in immature T cells.     

T cell receptor genes and T cell development in virus-transformed early T cell lines

We have derived T cell lines from mice inoculated with Gross leukemia virus, which appear to represent early T cell developmental stages and to reflect normal T cell development. These cell lines may provide a breakthrough in the study of T cell development as Abelson transformants have done for the study of B cell development. Analysis of the TCR gene expression in these cell lines reveals that the sequence of rearrangement and expression of each TCR gene is not strictly ordered. Expression of RNA for the TCR alpha and -beta genes appears to be coordinated with rearrangement at the alpha and beta loci. This is not the case for gamma gene expression. Availability of the homogeneous populations of cells represented in these cells lines allows for a more detailed molecular analysis of T cell development than was previously possible.     

Human T cell gamma-chain gene rearrangements in acute lymphoid and nonlymphoid leukemia: comparison with the T cell receptor beta-chain gene

Rearrangement of germ-line genes coding for T and B cell antigen receptor molecules is an early event in lymphoid development which eventually leads to the generation of clonal diversity in receptor-positive lymphocytes. Three T cell-associated rearranging genes have been described. Two, T alpha and T beta, code for the two polypeptide chains that form the T cell receptor heterodimer. The function of the third gene, the gamma-gene (T gamma), is not known. To learn more about the behavior of T gamma during lymphoid ontogeny, we compared rearrangement of T gamma and T beta genes in leukemic cells arrested at varied stages of lymphoid and myeloid development. We analyzed 38 fresh cell lines and 15 established cell lines from a total of 53 leukemic patients. Cells were immunophenotyped with a panel of monoclonal antibodies recognizing T-, B-, or myeloid-associated surface markers. Sixteen T-lineage cases were studied; 15 displayed both T beta and T gamma rearrangements. The exception (germ-line for T beta and T gamma) was an immature CD2(T11)+, CD3(T3)-, CD7(3A1)+, CD1(T6)+, CD5(T101)+ phenotype. Fourteen non-T non-B leukemias were analyzed; eight were germ-line for both T beta and T gamma, four had rearrangements involving both T beta and T gamma, and two were germ-line for T beta and rearranged to T gamma. Four cases with acute biphenotypic leukemia were studied; two had rearrangements of T beta and T gamma, and two were germ-line for both genes. Cells from nonlymphocytic leukemias were studied in 19 cases. All were found to be germ-line for both T beta and T gamma. Fifty-one of 53 genomic DNA samples were concordant for T gamma and T beta rearrangement. These results indicate that rearrangement of T gamma can occur in leukemic cells of B cell as well as T cell precursor origin, as has been reported previously for T beta.     

Allelic exclusion at the TCR delta locus and commitment to gamma delta lineage: different modalities apply to distinct human gamma delta subsets

Expression of a beta-chain, as a pre-TCR, in T cell precursors prevents further rearrangements on the alternate beta allele through a strict allelic exclusion process and enables precursors to undergo differentiation. However, whether allelic exclusion applies to the TCR delta locus is unknown and the role of the gamma delta TCR in gamma delta lineage commitment is still unclear. Through the analysis of the rearrangement status of the TCR gamma, delta, and beta loci in human gamma delta T cell clones, expressing either the TCR V delta 1 or V delta 2 variable regions, we show that the rate of partial rearrangements at the delta locus is consistent with an allelic exclusion process. The overrepresentation of clones with two functional TCR gamma chains indicates that a gamma delta TCR selection process is required for the commitment of T cell precursors to the gamma delta lineage. Finally, while complete TCR beta rearrangements were observed in several V delta 2 T cell clones, these were seldom found in V delta 1 cells. This suggests a competitive alpha beta/gamma delta lineage commitment in the former subset and a precommitment to the gamma delta lineage in the latter. We propose that these distinct behaviors are related to the developmental stage at which rearrangements occur, as suggested by the patterns of accessibility to recombination sites that characterize the V delta 1 and V delta 2 subsets.     

The unfolding story of T cell receptor gamma

Antigen-specific, major histocompatibility complex-restricted recognition by classical T cells is mediated by a T cell receptor (TCR) consisting of a disulfide-linked alpha beta heterodimer. During the search for the genes encoding the alpha and beta proteins, a third immunoglobulin-like gene, termed gamma, was uncovered. Like the TCR alpha and beta genes, the TCR gamma gene consists of variable and constant segments that rearrange during T cell development in the thymus. Although the physiological role of TCR gamma remains an enigma, much has been learned with the recent identification of the protein products of this gene family in both mice and humans. The gamma chain is associated with a partner chain, termed delta. The gamma delta heterodimer is associated with an invariant T3 complex, very similar to that associated with the alpha beta heterodimer, and appears predominantly, if not exclusively, on cells with a CD4-, CD8- phenotype both in the thymus and in the periphery. TCR gamma delta is the first T3-associated receptor to appear during thymocyte development and defines a separate T cell lineage distinct from alpha beta-bearing cells. Although TCR alpha beta-bearing cells and TCR gamma delta-bearing cells follow parallel developmental pathways, the diversity of expressed gamma delta receptors is extremely limited relative to that of alpha beta receptors.     

Inhibition of T-cell receptor beta-chain gene rearrangement by overexpression of the non-receptor protein tyrosine kinase p56lck.

The variable region genes of the T cell receptor (TCR) alpha and beta chains are assembled by somatic recombination of separate germline elements. During thymocyte development, gene rearrangements display both an ordered progression, with beta chain formation preceding alpha chain, and allelic exclusion, with each cell containing a single functional beta chain rearrangement. Although considerable evidence supports the view that the individual loci are regulated independently, signaling molecules that may participate in controlling TCR gene recombination remain unidentified. Here we report that the lymphocyte-specific protein tyrosine kinase p56lck, when overexpressed in developing thymocytes, provokes a reduction in V beta--D beta rearrangement while permitting normal juxtaposition of other TCR gene segments. Our data support a model in which p56lck activity impinges upon a signaling process that ordinarily permits allelic exclusion at the beta-chain locus.     

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.     

The chromosomal location of T-cell receptor genes and a T cell rearranging gene: possible correlation with specific translocations in human T cell leukaemia.

We have examined the chromosomal location of human T cell-specific genes which are involved in antigen recognition and of a gene which specifically rearranges in T cells. The genes encoding both the variable and constant region segments of the T cell receptor alpha chain are found on chromosome 14 while the delta chain gene of the T cell receptor-associated T3 complex is localised to chromosome 11. Further, the two tandemly arranged T cell-specific rearranging genes, designated gamma, were mapped to chromosome 7, but apparently not closely linked to the previously mapped T cell receptor beta-chain gene. The locations of the three different genes, which undergo rearrangement in T cells, may correlate with the chromosomal breakpoints known to be involved in translocations within abnormal human T cells.     

Comparison of T cell receptor gene rearrangements in patients with large granular T cell leukemia and Felty's syndrome

Felty's syndrome (FS) refers to the occurrence of rheumatoid arthritis, splenomegaly, and neutropenia. A subset of these patients has recently been described with a chronic T cell leukemia of large granular lymphocytes (LGCL). To examine the spectrum of lymphocyte abnormalities in FS and LGCL, we examined phenotypic and genotypic properties of lymphocytes from eight FS patients. In two of these FS patients, we observed an elevated proportion of T cells with an unusual phenotype (CD3+/Leu-7+/Leu-8-/CR3+) (46 +/- 5% of mononuclear cells). The FS lymphocytes had large granular morphology on Wright-Giemsa stain and were active in antibody-dependent cellular cytotoxic activity. This phenotype, morphology, and activity was similar to LGCL patients except that the latter T cells additionally expressed the Fc-IgG receptor recognized by monoclonal antibody Leu-11 (CD 15). In the remaining six FS patients, the proportion of CD3+/Leu-7+/CR 3+ T cells was only 10 +/- 8%, which was not significantly different from age-matched normal subjects (6.6 +/- 2.2%). To determine the clonality of T lymphocytes in FS and LGCL, we examined DNA for rearrangements of the T cell antigen receptor beta-chain (Ti beta) and gamma-chain (Ti gamma) genes by using Southern blotting techniques. We found a clonal rearrangement of the Ti beta 1 and Ti gamma genes in both LGCL patients. In contrast, no clonal rearrangements of Ti beta or Ti gamma genes were detected in lymphocytes from the FS patients. These results indicate that FS patients are heterogeneous in their phenotype and that one subset exhibits polyclonal expansion of an unusual lymphocyte subset.     

T cell antigen receptor--structure, expression and function

T cell receptor complex is composed of at least 7 different polypeptides and is one of the most sophisticated receptor. There are two types of T cell receptor (TCR); alpha beta and gamma delta, both of which are composed of a heterodimer and associated with invariant CD3 complexes on the cell surface. T cells expressing alpha beta dimer recognize antigen-peptides in the context of self-MHC molecules, whereas the specificity and function of gamma delta T cells are largely unknown. Gene organization of alpha beta and gamma delta indicates the difference of mechanism to generate diversity. Whereas alpha and beta genes have a large number of V genes, those of gamma and delta genes are limited. However, especially for delta gene, the repertoire is largely produced by junctional diversity. There are increasing data showing new TCR heterodimers; such as beta delta heterodimer in human, beta homodimer in mouse and unknown new heterodimer in chicken, which are expressed on the cell surface in the association with CD3 complex. The characterization of these new receptor dimers and the function of cells expressing these receptors have to be determined. Among CD3 complex, zeta and eta chains are most important for signal transduction after antigen-recognition by TCR. eta gene is recently cloned and now found to be produced by an alternative splicing of a common gene with zeta chains gene. Tyrosine++ phosphorylation of zeta chain seems to be one of the earliest events of T cell activation. Since fyn, one of src oncogene family possessing tyrosine++ kinase function, is co-precipitated with TCR-CD3 complex, fyn seems to be involved in early phosphorylation for T cell activation. Positive and negative selection of thymocytes has been shown to occur via TCR using TCR-transgenic mice model. Molecular mechanism of the selection should be determined.     

A T cell clone expresses two T cell receptor alpha genes but uses one alpha beta heterodimer for allorecognition and self MHC-restricted antigen recognition

All of the T cell receptor alpha- and beta-chain rearrangements present in a dual reactive T cell clone were characterized. This clone exhibits allelic exclusion of its beta-chain genes in that only one of the two alleles is productively rearranged. Unexpectedly, it displays two productive V alpha-gene rearrangements, which are both transcribed into 1.5 kb mRNA. The contribution of each of the two productive alpha genes to the dual recognition was analyzed by gene transfer. To this end, each of the two alpha genes was separately transfected with the single productively rearranged beta gene. Transfer of only one of the two alpha beta combinations restored both allogeneic MHC recognition and self MHC-restricted antigen recognition. Thus, T cell dual recognition results from the cross-reactive recognition of an allo-MHC product by a single antigen-specific and MHC-restricted alpha beta T cell receptor. Furthermore, the presence of two productively rearranged alpha-chain genes in a T cell clone raises questions concerning the level at which allelic exclusion operates in T cells.