Rearrangement and expression of T cell antigen receptor and gamma genes during thymic development

Developmentally regulated fetal thymic and extrathymic T-cell receptor gamma delta gene expression

The gamma delta T-cell receptor (TCR) is the first TCR to be expressed in ontogeny in all vertebrates in which it has been examined thoroughly. Murine gamma delta cell-surface protein is detected by the fourteenth day of gestation. In this work, the activation of gamma delta RNA has been studied. Data indicate that the first TCR protein to appear in the thymus is encoded by gamma genes that are activated after cells colonize the thymus. However, the sequential appearance of different gamma delta TCR proteins during thymic ontogeny cannot be readily explained by differential temporal activation of V gamma genes in the thymus. There are distinct patterns of gamma and delta gene expression during fetal liver development and in the fetal gut (or tissue associated with it). Cells apparent in the liver of mice at birth express gamma delta cell-surface protein, but they disappear from the liver very soon afterward. One V gamma gene is rearranged and expressed prethymically. In addition, gamma gene expression is detectable in the livers of newborn athymic mice. Together, these observations indicate a thymic-independent pathway of activation of TCR genes.

Genotypic analysis in large cell lymphomas expressing a restricted set of differentiation antigens

Immunophenotyping and immunogenotyping were performed in a series of 8 large cell lymphomas exhibiting anaplastic or "histiocytic" morphology and displaying an uncertain phenotype due to a restricted number of differentiation antigens. 6 cases expressed the Ki-1 antigen. 4 cases expressed one or two B-cell markers and contained rearrangements of the immunoglobulin genes. One of them also exhibited a T-cell receptor (TCR) beta gene rearrangement. 3 cases expressed a single T-cell differentiation antigen. Among them, only 1 displayed both gamma and beta TCR gene rearrangement; 1 only contained a gamma TCR gene rearrangement and 1 completely lacked clonal rearrangements. The eight cases expressed an inconclusive immunophenotype due to an abundant population of reactive cells but showed an immunoglobulin gene rearrangement. In conclusion, 5 out of the 8 unusual lymphomas studied here could be characterized by immunogenotyping. This approach was, however, inconclusive in the 3 remaining cases, whose lineage and differentiation stage remain poorly defined.

Characterization of gamma/delta T cell clones isolated from human fetal liver and thymus

The origin and development of T cells bearing gamma/delta T cells receptors (TcR) has been extensively studied in the mouse. By contrast, little is known about development patterns and diversity of the human gamma/delta T cell lineage. To study the repertoire of human gamma/delta+ T cells during T cell ontogeny, we have isolated clonal populations of gamma/delta+ T cells from 14-week fetal thymus and liver and characterized the molecular composition of their TcR. The technique of in situ hybridization was used to identify cells expressing TcR genes in fetal liver and thymus. A panel of clones representative of developing T cell populations found in vivo was subsequently isolated from both tissues and clones expressing cell surface gamma/delta receptors were identified. Although both the liver-derived gamma/delta+ T cell clone, L2, and the thymus-derived gamma/delta+ T cell clone, T6, had similar cell surface phenotypes, namely CD3+, CD7+, CD45+ and CD8-, their reactivity with anti-CD2 and -CD4 antibodies was different. L2 was CD2high, CD4- whereas T6 was CD2low, CD4low. Both clones possessed effector functions similar to those of adult T cells as demonstrated by the synthesis and secretion of cytokines in response to stimulation through the CD3/TcR complex. Analysis of the TcR composition of the fetal clones showed both clones to possess similar or identical gamma chain components, C gamma 1, J gamma 1/2, V gamma 8, and both utilize V delta gene segments other than V delta 1. This TcR genotype has not been previously reported in the analysis of adult gamma/delta+ T cells. Our studies have identified a unique population of human gamma/delta+ T cells that may be derived extrathymically and appear to be preferentially and perhaps transiently expressed during fetal life.

Selective expansion of a specific anti-tumor CD8+ cytotoxic T lymphocyte clone in the bulk culture of tumor-infiltrating lymphocytes from a melanoma patient: cytotoxic activity and T cell receptor gene rearrangements

In vitro culture of metastatic melanoma fragments with 150 units of recombinant interleukin 2 resulted in the successive expansion of CD4+ and then CD8+ tumor-infiltrating lymphocytes (TIL) throughout a 2-month period. TIL cultured for 43 days and consisting of 95% CD8+ and 10% CD4+ T lymphocytes were cloned by limiting dilution (LD). Thirteen CD8+ and thirty-one CD4+ clones were obtained, indicating that the frequency of clonogenic CD8+ proliferative T lymphocytes was much lower than that of their CD4+ homologues. When LD was performed in the presence of autologous melanoma cells the frequency of CD8+ clones was increased by factor 4. The DNA from TIL of day 43 bulk culture and of six CD8+ clones was hybridized with T cell receptor (TcR) beta and gamma probes. Identical configuration of the nonfunctional gamma and functional beta TcR genes was found in "bulk culture" and cloned TIL. The CD8+ clones therefore derived from a clonal population of CD8+ cells which had expanded in vitro before the LD. All the CD8+ clones tested were strongly cytotoxic for autologous melanoma cells but did not kill autologous fibroblasts or concanavalin A blasts, or any of the 10 allogeneic tumor targets tested, including 5 melanomas, 2 breast cell lines, 1 neuroblastoma, K-562 and the Epstein-Barr virus-transformed cell line used as a feeder. Furthermore, specific killing was inhibited by monoclonal antibodies against CD3, CD8, TcR alpha/beta and against class I major histocompatibility complex antigens indicating that these cytotoxic T lymphocyte clones recognized autologous tumor cells through the TcR, in an HLA class I-restricted manner. These data show that it is feasible to obtain tumor-specific cytotoxic T lymphocytes from melanoma TIL with a simple culture technique and that a single clone could be expanded to more than 10(10) cells which should allow testing of immunotherapeutic potential of these cells by adoptive transfer into melanoma patients.

Phorbol ester regulation of terminal deoxynucleotidyl transferase, proliferation, and TcR alpha in a pre-T cell line

Terminal deoxynucleotidyl transferase (TdT) is a template-independent DNA polymerase that is transiently expressed during the normal development of T and B lymphocytes. Phorbol 12-myristate 13-acetate (PMA) has been reported to induce maturation-like changes, including the loss of TdT, in many leukemic cell lines. We investigated the mechanism of TdT repression by PMA in an early thymocyte-like cell line, RPMI 8402. At a concentration of 8 nM, PMA caused both repression of TdT synthesis and arrest of proliferation. At greater concentrations of PMA, these same changes initially occurred, but then cell proliferation resumed, and TdT was reexpressed. At both 8 and 160 nM PMA, TdT biosynthesis and TdT mRNA became undetectable within 8 hours, while cell proliferation and DNA synthesis were not significantly reduced until 16 hours. Growth arrest induced by serum starvation did not result in a similar reduction of TdT RNA even after 48 hours. With 160 nM PMA, TdT mRNA could be detected again by 24 hours, and proliferation resumed. Transcription run-off assays indicated that TdT RNA synthesis ceased within 1 hour after exposure to both 8 and 160 nM PMA. T cell receptor alpha (TcR alpha) RNA was induced when TdT RNA was repressed. TcR beta RNA levels were unchanged, and TcR gamma RNA was up-regulated. TdT gene repression and modulation of cell proliferation as well as induction of TcR gene expression are normal events during intrathymic T cell maturation. This cell model provides a system for analyzing the molecular regulation of these significant developmental events.

T-cell receptor gene rearrangements and the diagnosis of human T-cell neoplasms

The rearranging antigen receptor genes of lymphoid cells serve as unique clonal markers of lymphoid neoplasms. Gene rearrangement analysis is a highly sensitive and reproducible tool which is useful in the diagnosis and classification of malignant lymphoma/leukemia. Although clonality can often be determined among B cell neoplasms by virtue of immunoglobulin isotype analysis, no such phenotypic marker of clonality exists for T cells. Therefore, clonality of T lymphoproliferative processes is most readily determined by rearrangement analysis of the T cell antigen receptor genes. The alpha, beta, gamma, and delta genes of the T cell receptor gene family encode heterodimeric surface antigen receptors and undergo rearrangement early in T cell differentiation. Identification of rearrangement of T cell antigen receptor genes provides valuable diagnostic information concerning cellular lineage, clonality and classification of T cell neoplasms. This molecular approach is applicable to the diagnosis of occult disease, relapse, and resolution of diagnostic dilemmas in any type of tissue sample including fluids and needle aspirations.

Thymic dendritic cells and B cells: isolation and function

The thymus is the primary organ in which T cells undergo rearrangement of T cell receptor alpha and beta genes, positive selection for affinity to self MHC products, and elimination (negative selection) of reactivity to self antigens. These events require an interaction of the developing T cell with other cell types in the thymus. The latter include epithelial cells, macrophages, dendritic cells, and the recently described thymic B cells the majority of which are CD5+. Here we review the identification and isolation of thymic dendritic cells and CD5+ B cells. We consider phenotype, ontogeny, and function, including possible contributions to the induction of self tolerance. Thymic dendritic cells are similar to spleen dendritic cells, but are larger and exhibit a few differences in phenotype. Dendritic cells from both organs are equally potent accessory cells for the MLR and lectin-induced, T cell proliferation. Thymic dendritic cells have higher levels of Fc receptors and support anti-CD3 dependent mitogenesis. Thymic CD5+ B cells share phenotypic features with peritoneal CD5+ B cells. However thymic B cells neither proliferate nor form antibody producing cells in response to the stimulation with LPS or anti-IgM plus IL-4, but do respond to stimulation with MHC class II-restricted helper T cells. Thymic dendritic cells and CD5+ B cells both appear at a similar time in ontogeny, about 14 d of gestation, which is the time T cell differentiation begins to take place. Dendritic cells from spleen, which are potent activators for peripheral T cells, are also potent inactivators for thymic-derived cytotoxic T cells. A correlation between reactivity to MIs products and the expression of TCR-V beta genes is well documented, and B cells are the primary APC for this antigen. Therefore, thymic CD5+ B cells may be a good tool for the investigation of tolerance to M1s products.

Molecular analyses of in vivo hprt mutations in human T-lymphocytes. III. Longitudinal study of hprt gene structural alterations and T-cell clonal origins

The hprt clonal assay detects mutations occurring in vivo in the hypoxanthine-guanine phosphoribosyltransferase (hprt) gene of human T-lymphocytes. Analysis of 94 wild-type and 326 hprt mutant clones from 3 normal males was performed using Southern blotting with hprt and T-cell receptor (TCR) gene probes. Gross structural alterations of the hprt gene occurred in approximately 14% of the in vivo derived mutants. Breakpoints were randomly distributed across the gene with one possible mutational "hot spot" observed. Most hprt mutants were independent as judged by TCR gene rearrangement patterns indicating that the measured hprt mutant frequency is a good measure of the actual hprt mutation frequency. However, sibling mutants (generally doublets and triplets except for one nonamer) were detected. Information on the timing in vivo of the hprt mutational events and the persistence in vivo of sibling mutants was also obtained.

Alpha beta lineage-specific expression of the alpha T cell receptor gene by nearby silencers

T cells expressing either the alpha beta or gamma delta antigen receptor (TCR) are distinct cell lineages. The single locus encoding the TCR alpha and delta genes requires special regulation to avoid alpha gene expression in gamma delta T cells. We show here that the minimal alpha enhancer is active in the gamma delta T cell lineage but gains alpha beta lineage specificity through negative cis-acting elements 3' of the C alpha gene that silence the enhancer in gamma delta T cells. The negative elements at the C alpha locus consist of several silencers that work in an orientation- and distance-independent fashion. These silencers also act on a retroviral enhancer that is normally ubiquitously expressed, restricting its activity to alpha beta cells. The alpha silencers are active in non-T cell lines, suggesting that the decision of a cell to differentiate into the alpha beta T cell lineage may involve specific relief from these silencers. Silencers are likely to be as important as enhancers in establishing lineage-specific gene expression in many systems.

T cell receptor gene trans-rearrangements: chimeric gamma-delta genes in normal lymphoid tissues

Joining of V-, D-, and J-region gene segments during DNA rearrangements within all antigen receptor genes involves recognition of the same highly conserved heptamernonamer sequences flanking each segment. In order to investigate the possibility that recognition of these conserved sequences may sometimes permit intergenic joining of segments among different antigen receptor genes, DNA of normal human lymphoid tissues was examined by polymerase chain reaction amplification for the presence of chimeric gamma-delta T cell receptor gene rearrangements. These studies detected V gamma-(D delta)-J delta and V delta-(D delta)-J gamma rearrangements in thymus, peripheral blood, and tonsil. Analysis of thymus RNA indicated that many of these rearrangements are expressed as V gamma-(D delta)-J delta-C delta and V delta-(D delta)-J gamma-C gamma transcripts. Most transcripts (19 of 20 complementary DNA clones studied) are appropriately spliced and show correct open translational reading frames across the V-(D)-J junctions. Thus, chimeric antigen receptor genes are generated in a subset of normal lymphoid cells, probably as a result of chromosomal translocations, and such genes may possibly contribute to increased diversity within the antigen receptor repertoire.

A novel subset of CD2-, CD3/T cell receptor alpha/beta+ human peripheral blood T cells. Phenotypic and functional characterization of interleukin 2-dependent CD2-CD3+ T cell clones

It is generally believed that CD2 (T11, sheep erythrocyte receptor) is expressed on all human T cells. In the present study we have identified and characterized a minor subset of CD2- CD3/TCR alpha/beta+ T cells in the peripheral blood of healthy individuals. CD2-CD3+ T cells were enriched in PBMC depleted of plastic-adherent macrophages, E-rosetting (i.e., CD2+) T cells and surface Ig+ B cells. CD2-CD3+ T cells accounted for 0.1-0.8% of PBMC in six individuals. IL-2-dependent long-term clones of CD2-CD3+ T cells neither reacted with a panel of anti-CD2 mAbs nor expressed detectable levels of CD2 mRNA by Northern blot analysis. These clones, however, expressed a full-length TCR C beta mRNA and reacted with mAbs against TCR-alpha/beta, CD3, and CD4, and thus were mature T cells. CD2-CD3/TCR+ T cell clones could be triggered into proliferation, IL-2 production, and cytotoxic effector activity by anti-CD3 and anti-TCR mAbs. We conclude that (a) a minor subset of CD2-, CD3/TCR-alpha/beta+ T cells is present in normal peripheral blood; and (b) expression of CD2 at the level of protein and/or mRNA is not required for T cell signaling via the CD3/TCR molecular complex.

Generation of syngeneic anti-tumour double negative cells (CD4- CD8-), with cytotoxic activity against clones of different MHC class I expression

In vivo immunization and secondary culture techniques were used to generate cytotoxic T lymphocytes against a tumour cell clone obtained from a methylcholantrene-induced fibrosarcoma. Our CTLs differed from classical CTLs (Ly2+ and MHC restricted) in that our lymphocytes exhibited a non-MHC restricted cytotoxic activity directed to the original tumour and to other MCA-induced tumours, but have failed to demonstrate any killing activity against a wide range of tumour cell lines of diverse origin (including NK sensitive targets). Depletion and phenotypic studies demonstrated that these cells bear the Thyl.2 antigen but are negative for both Ly2 and L3T4 antigens. These CTLs may belong to a double negative subset (CD4-, CD8-) involved in the anti-tumour response.

Novel primary thymic defect with T lymphocytes expressing gamma delta T cell receptor

Flow cytometric analysis of the peripheral blood mononuclear cells in a six year old girl with a primary cellular immune deficiency showed a normal fraction of CD3 positive T cells. Most (70%) of the CD3 positive cells, however, expressed the gamma delta and not the alpha beta T cell receptor. Immunoprecipitation and sodium dodecyl sulphate-polyacrylamide gel electrophoresis (SDS-PAGE) showed that most of the gamma delta T cell receptors existed as disulphide-linked heterodimers. Proliferative responses to mitogens were severely reduced, but specific antibody responses after vaccination could be detected. A thymic biopsy specimen showed severe abnormalities of both the thymic lymphoid and epithelial component with abortive medullary differentiation and almost an entire lack of Hassall's corpuscles. This patient represents a case of primary immune deficiency syndrome not previously described. Thymic deficiency associated with a high proportion of T cells expressing the gamma delta T cell receptor has been described in nude mice, and it is suggested that the immune deficiency of this patient may represent a human analogue.

Identification of pre-T cells in human peripheral blood. Extrathymic differentiation of CD7+CD3- cells into CD3+ gamma/delta+ or alpha/beta+ T cells

CD7+CD3- cells purified (greater than 99.99%) by FACS from the peripheral blood of healthy adults include precursors for mature T cells that have the capacity to differentiate into TCR-1+ or TCR-2+ CD3+ cells. Extrathymic differentiation was demonstrable from all eight healthy donors in the presence of a high concentration of IL-2, mitogenic levels of PHA, and irradiated blood mononuclear feeder cells, after a lag of approximately 40 d in vitro. The extrathymic T (ET) cells were predominantly TCR-1+, although TCR-2+ cells were also derived. ET TCR-1+ cells were CD4-CD8-, CD4-CD8DIM+, and CD4+CD8-, and were distinguished from natural T TCR-2+ cells by a variety of cell surface markers. The ET cells had phenotypes generally displayed by normal mature T cells, although the CD5DIM+ on ET cells was more typical of thymocytes. Acquisition of CD3 on purified CD7+CD3- cells was not due to antigenic modulation or growth of contaminants, and ET cells could be demonstrated at the clonal level. Studies in athymic mice and bone marrow recipients support the view that extrathymic maturation does occur in vivo. Whether the CD7+CD3- cell population was unexposed to the thymus, or exposed but not processed, is unknown. In any case, unusual or "forbidden" autoreactive specificities are predicted since ET cells differentiate without thymic selection of the TCR.

Interleukin 3 (IL-3) induces transcription from nonrearranged T cell receptor gamma loci in IL-3-dependent cell lines

The expression of the murine TCR-gamma genes was examined in a series of IL-3-dependent and growth factor-independent cell lines. All of the IL-3-dependent cell lines, but none of the IL-3-independent lines, expressed high levels of one or more of the gamma genes but did not express the TCR-beta genes. None of the cell lines expressing the gamma loci contained detectable genomic gamma gene rearrangements. Sequencing of cDNA clones from two of the cell lines demonstrated that transcription was from nonrearranged gamma loci based on the presence of sequences in the cDNAs that are found immediately 5' of the J gamma 4 and J gamma 2 genes. The expression of gamma transcripts was dependent upon IL-3 and no transcripts were detectable within 6-8 h after the removal of IL-3. Readdition of IL-3, but not granulocyte CSF, resulted in the reappearance of gamma transcripts within 30 min. The results demonstrate that IL-3 regulates the expression of nonrearranged gamma loci. Since expression is required for rearrangement, it can be hypothesized that IL-3 may influence the ability of lymphoid/myeloid progenitors to commit to the T cell lineage.

Expression of T-cell receptor alpha-chain genes in transgenic mice

To examine the influences responsible for shaping the T-cell repertoire in vivo, we have introduced T-cell receptors of defined specificity into mice. In this report, we analyze transgenic mice carrying a T-cell receptor alpha-chain gene from a pigeon cytochrome c-reactive T-cell line. A variant of this construct, which has the immunoglobulin heavy-chain enhancer inserted into the JC intron, was also introduced into mice. Addition of the enhancer increased the steady-state level of transgene-encoded mRNA three- to fivefold in cultured T cells, leading to a two- to threefold increase in surface expression. In vivo, the difference between these two constructs was even more significant, increasing the number of transgene-positive cells from approximately 5 to 70% and the T-cell receptor surface density two- to threefold. Surprisingly, while surface expression of either type of transgene was limited to T cells, we found little tissue specificity with respect to transcription. In T cells expressing the alpha chain from the enhancer-containing construct, immunoprecipitation with a 2B4 alpha-specific monoclonal antibody revealed the expected disulfide-linked dimer. Costaining of these T cells with the 2B4 alpha-specific monoclonal antibody versus anti-CD3 indicated that expression of the transgene-encoded alpha chain precludes expression of endogenous alpha chains on the majority of cells; in contrast, 2B4 alpha-chain expression from the construct lacking the enhancer is inefficient at suppressing endogenous alpha-chain expression. In mice of the enhancer lineage, Southern blot analysis indicated suppression of endogenous alpha-chain rearrangements in T-cell populations, consistent with the observed allelic exclusion at the cellular level. Interestingly, newborn, but not adult, mice of this lineage also showed an increase in retention of unrearranged delta-chain loci in thymocyte DNA, presumably resulting from the suppression of alpha-chain rearrangements. This observation indicates that at least a fraction of alpha:beta-positive T cells have never attempted to produce functional delta rearrangements, thus suggesting that alpha:beta and gamma:delta T cells may be derived from different T-cell compartments (at least during the early phases of T-cell differentiation).

Developmental biology of T cell receptors

T cell receptors are the antigen-recognizing elements found on the effector cells of the immune system. Two isotypes have been discovered, TCR-gamma delta and TCR-alpha beta, which appear in that order during ontogeny. The maturation of prothymocytes that colonize the thymic rudiment at defined gestational stages occurs principally within the thymus, although some evidence for extrathymic maturation also exists. The maturation process includes the rearrangement and expression of the T cell receptor genes. Determination of these mechanisms, the lineages of the cells, and the subsequent thymic selection that results in self-tolerance is the central problem in developmental immunology and is important for the understanding of autoimmune diseases.

Rearrangements of T-cell antigen receptor gamma and delta chain genes are detected in the long-term cultured bone marrow cells of athymic nude mice but not in those of euthymic mice

We have previously shown that extrathymic rearrangements of T-cell receptor (TcR) gamma and delta chain genes occur in the peripheral lymphoid tissues of athymic nude mice. To further determine where the TcR gene rearrangements occur in nude mice, we investigated the rearrangement and expression of the TcR genes in the long-term cultured bone marrow (LTBM) cells which were homogenous in developments without mature T cells as assessed by FACS analysis. The LTBM derived from euthymic mice contained TcR gamma and delta chain genes in germline configuration, while gene rearrangements of both locus were detected in the LTBM cells from nude mice. These results suggested that gamma and delta gene rearrangements do occur in the bone marrow cells of nude mice and that the T-cell precursors in bone marrow may be increased in frequency in such animals.

The role of T cell receptors in non-MHC-restricted cytotoxicity

The relationship between natural killer cells (NK) and cells of the T lineage has been obscured by the existence of poorly characterized clones of presumed NK origin. We have analyzed nine of these cloned cell lines displaying varying levels of cytotoxic activity against NKS YAC-1 target cells for rearrangement and expression of the genes encoding the alpha, beta, and gamma chains of the T cell receptor for antigen. Rearrangements at both the TcR beta and gamma loci were detected in all clones often at both alleles. Rearrangement patterns at the TcR beta locus were identical in several clones, despite different degrees of cytotoxicity. T cell receptor alpha, beta, and gamma genes were expressed as full length transcripts in all clones regardless of their levels of cytotoxic activity. To explore the involvement of cell surface molecules in the cytolytic events, studies were undertaken to determine whether cytotoxic activity could be inhibited by antibodies against CD3, LFA-I, and H-2KdDd. In two selected clones, both alpha and beta chains of the LFA-I molecule were expressed but only monoclonal antibodies against the alpha chain significantly blocked cytotoxicity. Cytotoxicity was also inhibited by monoclonal antibodies against epitopes of H-2KdDd and CD3, the extent of inhibition correlating with the level of surface expression on both clones. These data suggest that conventional alpha/beta heterodimers may be necessary but not sufficient for target cell recognition by these clones. Since T cell receptor rearrangement and expression occur normally in the T cell lineage but not the NK lineage, these results also indicate that a subpopulation of cells with non-MHC-restricted killer activity lies on the T cell differentiation pathway and is selected by in vitro growth with IL-2. The limited rearrangement pattern observed can be explained if only a small subpopulation of T cells is capable of non-MHC-restricted killing, and if certain rearrangements favor self-MHC recognition which is known to block cytolysis in the NK system.

Characterization of T-cell-receptor gamma (TRG) gene rearrangements in alloreactive T-cell clones

Rearrangements of the T-cell Rearranging Gene (TRG) or T-cell-receptor gamma-chain genes were analyzed in 24 in vivo-sensitized alloreactive T-cell clones. This analysis represents the first complete assignment of TRG gene rearrangements to given variable and joining gene segments in nonleukemic T cells and provides some evidence for the hypothesis of sequential gamma genes rearrangements during T-lymphocyte differentiation. TRG gene rearrangements in our T-cell panel involved the known "active" V gamma genes, with a preferential use of V2 and V4 genes. In most clones, rearrangements occurred on both chromosomes and involved the J2 segment, but only 2 and 4 out of the 49 described rearrangements involved the additional J gamma segments JP1 and JP2, respectively. Two peculiar rearrangements were found. The first one was probably due to the creation of a new restriction enzyme site in the N-region at the V-J junction; the second can be explained by an aberrant rearrangement of a V gene to a sequence located between exons 2 and 3 of the TRGC1 gene.

T cell receptors

Over the past few decades, a solid body of evidence has been built up linking certain autoimmune diseases to the presence of specific major histocompatibility complex haplotypes. Major histocompatibility complex products are used by the immune system to distinguish non-self from self and are important in the recognition of foreign antigen by T cells. T cells play a number of roles in the initiation and control of the immune response, leading to the suggestion that T cells may be important in the genesis of these diseases. T cell recognition is mediated by a heterodimeric cell surface receptor, the T cell antigen receptor. A better understanding of the molecular biology of this receptor may shed some light on the cellular and molecular processes involved in the initiation and progression of these diseases.

T-cell receptor beta gene rearrangements in clones derived from human CD4-8- cells expressing natural killer cell activity

Clones derived from highly purified human peripheral blood Leu 19+ cells in the presence of phytohaemagglutinin (PHA) and interleukin-2 (IL-2) expressed cytotoxic activity against natural killer (NK)-resistant as well as NK-sensitive targets. All 66 clones analysed had a germ line configuration of T-cell receptor (TCR) beta genes and 38/40 also had unrearranged TCR gamma genes. The two exceptions were both CD3+ clones, but these did not have a cytotoxic repertoire noticeably different from CD3- clones without TCR gamma gene rearrangements. Clones were also obtained from highly purified CD4-8- cells, most of which were also cytotoxic for NK-resistant and NK-sensitive targets. About 90% of these clones were CD3+ but only around 50% remained negative for CD4 and CD8 while a significant number (12.7%) were positive for both CD4 and CD8. All clones analysed had rearranged TCR gamma genes and most had also rearranged TCR beta genes, including 20/25 of the clones which were CD3+4-8-. Many of the clones showed two rearrangements of TCR beta genes, and 3/4 CD3- clones had rearranged TCR beta as well as TCR gamma genes. There was no correlation between cytotoxic activity and TCR gene status or phenotype of these CD4-8- derived clones, except that clones which were Leu 19+ tended to have higher cytotoxic activity against NK-sensitive and NK-resistant targets than Leu 19-clones. The results strongly indicate that TCR beta and gamma gene products are not involved in the cytotoxicity mediated by these clones. They also suggest that some CD4-8- cells may be capable of limited differentiation in vitro.

Macrophages phagocytose thymic lymphocytes with productively rearranged T cell receptor alpha and beta genes

The thymus gland is important for the formation of competent T lymphocytes. However, there is long-standing evidence that greater than 95% of newly formed thymocytes do not emigrate to peripheral lymphoid tissues but instead die locally. We have identified a rapid and selective pathway for thymocyte turnover in vitro. The mechanism entails binding, uptake, and digestion by macrophages. The susceptible cells are a subpopulation of double-positive thymocytes. These thymocytes can be enriched by virtue of their high buoyant density in Percoll and prove to have low levels of surface CD3 and little or no surface TCR. However TCR-alpha and -beta genes have undergone rearrangement, and full length alpha and beta transcripts are abundant. Therefore many double-positive cells rearrange and express TCR genes but do not have normal levels of TCR on the cell surface. We propose that thymocytes that undergo high turnover in situ are unable to form receptors that can be selected by MHC molecules in the thymus, and that these cells are recognized and cleared by the macrophage.

Expression of T-cell receptor alpha-chain genes in transgenic mice

To examine the influences responsible for shaping the T-cell repertoire in vivo, we have introduced T-cell receptors of defined specificity into mice. In this report, we analyze transgenic mice carrying a T-cell receptor alpha-chain gene from a pigeon cytochrome c-reactive T-cell line. A variant of this construct, which has the immunoglobulin heavy-chain enhancer inserted into the JC intron, was also introduced into mice. Addition of the enhancer increased the steady-state level of transgene-encoded mRNA three- to fivefold in cultured T cells, leading to a two- to threefold increase in surface expression. In vivo, the difference between these two constructs was even more significant, increasing the number of transgene-positive cells from approximately 5 to 70% and the T-cell receptor surface density two- to threefold. Surprisingly, while surface expression of either type of transgene was limited to T cells, we found little tissue specificity with respect to transcription. In T cells expressing the alpha chain from the enhancer-containing construct, immunoprecipitation with a 2B4 alpha-specific monoclonal antibody revealed the expected disulfide-linked dimer. Costaining of these T cells with the 2B4 alpha-specific monoclonal antibody versus anti-CD3 indicated that expression of the transgene-encoded alpha chain precludes expression of endogenous alpha chains on the majority of cells; in contrast, 2B4 alpha-chain expression from the construct lacking the enhancer is inefficient at suppressing endogenous alpha-chain expression. In mice of the enhancer lineage, Southern blot analysis indicated suppression of endogenous alpha-chain rearrangements in T-cell populations, consistent with the observed allelic exclusion at the cellular level. Interestingly, newborn, but not adult, mice of this lineage also showed an increase in retention of unrearranged delta-chain loci in thymocyte DNA, presumably resulting from the suppression of alpha-chain rearrangements. This observation indicates that at least a fraction of alpha:beta-positive T cells have never attempted to produce functional delta rearrangements, thus suggesting that alpha:beta and gamma:delta T cells may be derived from different T-cell compartments (at least during the early phases of T-cell differentiation).

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.

Thymocyte clones from 14-day mouse embryos. II. Transcription of T3 gamma gene may precede rearrangement of TcR delta and expression of T3 delta, T3 epsilon and T11 genes

We have studied the state of TcR delta gene and the expression of T3 delta, T3 epsilon, T3 gamma and T11 (CD2) genes in the fetal thymocyte (FT) clones A2, G15, H5, E10, D5, H12, F1 and D11 obtained from a 14-day B10.BR mouse fetal thymus. The eight FT clones contain the TcR delta gene in the germ-line configuration as determined by Southern blot analysis. With the exception of clones E10 and D5, the other six FT clones express normal sized transcripts for T3 gamma gene and none of the eight FT clones produced detectable RNA transcripts for T3 delta, T3 epsilon and T11 genes as assessed by Northern blot analysis. Together with our previous work showing that all eight FT clones contain the TcR gamma and the TcR beta gene clusters in the germ-line configuration, the data indicate that the FT clones represent the earliest stage of T cell development identified within the thymus. Our results provide evidence that (a) the T3 gamma gene is the first of the genes that encode components of a TcR/T3 complex to be expressed in ontogeny within the thymus; (b) the T3 (delta, epsilon, gamma) genes are switched on asynchronously and their expression must be differentially regulated, and (c) the T11 gene product may not be involved in early stages of T cell development within the thymus.

Surface expression of only gamma delta and/or alpha beta T cell receptor heterodimers by cells with four (alpha, beta, gamma, delta) functional receptor chains

Surface expression of TCR dimers by cells synthesizing three or four distinct types of receptor chains was analyzed. Cells containing intact gamma, alpha, and beta chains had only gamma delta dimers on the cell surface. In human PEER cells, addition of a functional alpha chain led to the loss of gamma delta dimer expression and expression of only alpha beta dimers. This result was not due to transcriptional down-regulation of the gamma or delta loci. In murine cells expressing all four chains, both gamma delta and alpha beta dimers could be demonstrated on a single cell. No other chain combinations (alpha gamma, alpha delta, beta gamma, or beta delta) were detected. Thus, there is stringent control of assembly and/or transport of TCR heterodimers, such that functional receptors consist only of alpha beta and gamma delta pairs, and no additional repertoire diversity is generated by cross pairing.

Application of a T cell receptor antibody beta F1 for immunophenotypic analysis of malignant lymphomas

One hundred sixty-five non-Hodgkin's lymphomas (101 B, 63 T, one histiocytic) were immunostained with an antibody (beta F1) reactive with a common framework determinant on the beta-subunit of the T cell receptor (TCR). beta F1 stained T lymphomas exclusively, including 53% of peripheral T cell lymphomas but only 33% of T lymphoblastic lymphomas. When expression of beta F1 and CD3 were considered together, 4 types of T lymphoma were delineated: 1) beta F1+CD3+; 2) beta F1+CD3-; 3) beta F1-CD3+, and 4) beta F1-CD3-. The first represented lymphomas with classical T immunophenotype. The second might represent T lymphomas with aberrant loss of CD3 expression. The third might represent T lymphomas with a putative second TCR or cases with an immature phenotype expressing cytoplasmic CD3 only. The fourth type included cases that may be derived from natural killer cells instead of T cells, cases of T lymphoma with aberrant loss of both beta F1 and CD3, and some cases of immature T cell (lymphoblastic) lymphoma. beta F1-CD3- lymphomas exhibited a remarkable predilection for the nasal region. beta F1 is useful in studying T cell lymphomas and distinguishing a novel immunophenotype frequently expressed by nasal lymphomas.

Age-associated increase in the expression of T-cell antigen receptor gamma-chain gene in conventional and germfree mice

To determine whether environmental antigens such as intestinal microflora contribute to expansion of the T-cell repertoire, age-related changes in the expression level of T-cell antigen receptor genes encoding gamma, beta, and alpha chains were compared in the lymphoid tissues of conventional versus germfree mice. Irrespective of the conditions of maintenance, an age-associated increase in the expression of the gamma-chain gene was evident in the thymus and spleen. Both conventional and germfree old mice (age, 40 weeks) had a relatively high proportion of Thy1+ L3T4- Lyt2- cells but a reduced level of Thy1+ L3T4- Lyt2+ cells in the thymus compared with their counterparts (age 8 weeks). The thymic dysfunction but not the stimulation by intestinal microflora may contribute to this age-related increase in gamma-gene transcripts in these tissues. On the other hand, an age-associated increase in the expression of gamma RNA was not evident in the mesenteric lymph nodes of germfree mice, although a remarkable increase in the gamma-chain gene messages was detected in the lymph nodes of the aged conventional mice. These results suggest that the expression of gamma RNA in cells of gut-associated lymphoid tissue is partly influenced by intestinal microflora.

T-cell receptor gene rearrangement in primary tumors: effect of genetic background and inducing agent

The status of T-cell receptor beta and gamma genes has been assessed in a series of primary tumors induced by a chemical carcinogen or by gamma-irradiation using two inbred strains of mice. It appears that these well-characterized regimens of carcinogenesis yield T-cell tumors showing gene rearrangements consistent with a clonal origin of the tumors. Individual rearranged bands seem to represent orthodox, intralocus recombination events. A variety of rearrangement phenotypes are observed, most strikingly for the gamma genes, and differences in the degree of T-cell receptor gene rearrangements observed can be categorized according to the inducing agent and to the genetic background of the mice, with the implication that premalignant thymocytes have been captured in different stages of T-cell development. Additionally, primary tumors were shown to express significant levels of mature beta gene mRNA.

Functional T cell receptor delta chain gene messages in athymic nude mice

The rearrangement and expression of T cell antigen receptor (TcR) delta chain genes were investigated in congenitally athymic nude mice. The lymphoid cells derived from nude mice showed evidence of rearranged delta chain genes and a relatively high level of delta chain gene messages. Nucleotide sequence analysis revealed that nude mice contained an in-frame delta chain transcript, composed of V delta 5-D delta 1-D delta 2-J delta 1-C delta genes in the spleen. We have previously described functionally rearranged TcR gamma chain genes in the spleen of nude mice. Taken together, T cell precursors appear to proliferate and differentiate along the extrathymic pathway into TcR gamma/delta-bearing T cells in nude mice.

Preferential expression of fibronectin receptors on immature thymocytes

Fibronectin-adherent (FNR+) thymocytes are enriched for immature (CD4-8-) and large (CD4+8+) cells, and depleted of mature (CD4-8+ and CD4+8-) and nonmature small (CD4+8+) cells. Among purified CD4-8- thymocytes, cells with the surface marker J11d and the IL-2 receptor, which can give rise to all other thymocyte subsets, showed selective attachment to fibronectin. Analysis of FNR+ thymocytes showed that such cells are greatly enriched for cells in cycle. Additionally, FNR+ cells expressed low levels of T cell receptor. These results suggest a role for the fibronectin receptor during the early, proliferative phase of thymocyte differentiation. The data suggest that loss of the fibronectin receptor is a hallmark of cells that have become committed either to functional maturation or to programmed cell death.

Quantification of the progenitors for thymic T cells in various organs

Partial characterization and frequency determination of the progenitors for thymic T cells in various organs were made by transferring cells directly into the thymus (intrathymically, i.t.). B10. Thy-1.1 (H-2b, Thy-1.1) mice were used as the donor, and C57BL/6 (H-2b, Thy-1.2) mice that had been whole body irradiated with 800 rads and reconstituted with 10(7) syngeneic (B6) bone marrow (BM) cells were used as the recipient. BM cells, spleen cells and thymus cells from young adults and fetal liver cells (day 14 of gestation) were treated with anti-Thy-1.1 antibody plus complement, and transferred i.t. The generation of Thy-1.1+ donor type cells in the recipient's thymus was investigated by using flow cytometry. From the time course of generation, it was shown that the progenitor cells in the thymus were distinct from those in other organs. After the transfer of thymic non-T cells, donor-type cells began to generate on the 4th day, the proportion of donor-type T cells increased quickly thereafter, and the progenitors in this organ ceased to produce T cells by day 21. On the other hand, a latent period of about 10 days was required for progenitor cells in the BM, spleen or fetal liver to generate T cells, and T cell producing-activity of the progenitor cells in these organs lasted as long as 7 weeks. The frequency of progenitor cells was analyzed by transferring serial dilutions of anti-Thy-1.1 plus complement-treated cells i.t. and investigating the generation of donor-type T cells in the recipient's thymus on day 11 in the case transferred with thymic cells and on day 21 in other cases. The proportion of negative recipients which did not contain detectable levels of donor-type cells was plotted on a logarithmic scale against the number of cells transferred on a linear scale. The progenitor cell frequencies in BM, spleen, thymus and fetal liver were estimated to be 12.5 x 10(-5), 6.25 x 10(-5), 0.22 x 10(-5) and 0.14 x 10(-5), respectively. The reliability of the frequency determination was supported by the finding that when a limited number (10(3)) of a 1:1 mixture of BM cells from two mutually identifiable donors was transferred i.t., most of the recipients were negative for donor-type T cells and 3 out of 4 positive recipients were seeded by progenitor cells of a single donor.

Induction of T cell receptor gamma chain transcription in murine T cells by trans-complementation

As an initial approach to understanding the molecular basis of the developmentally regulated expression of T cell receptor (TcR) genes, we constructed hybrids among T cell clones that differ in their expression of CD4 and CD8 antigens as well as in alpha, beta and gamma mRNA levels. Here we report that the TcR gamma gene becomes transcriptionally active in hybrid cells formed between parental clones that lack TcR gamma mRNA. We also observed negative trans-regulation of TcR beta but not of TcR alpha transcription in one of these hybrids. Positive TcR gamma transcription was observed both with (CD4-CD8- X CD4-CD8-) and (CD4-CD8- X CD4+CD8+) hybrids while negative TcR beta gene regulation was only detected in (CD4-CD8- X CD4+CD8+) cells. These data suggest that the regulation of TcR alpha, beta and gamma genes is mediated by the action of specific transacting factors that become asynchronously active in the various stages of T cell development.

Further evidence for a sequentially ordered activation of T cell rearranging gamma genes during T lymphocyte differentiation

Recently, we have shown that the majority of human peripheral lymphocytes with a T cell receptor (TcR) gamma/delta receptor use a unique gamma chain recognized by the anti-TigammaA monoclonal antibody. This predominantly expressed gamma protein is encoded by a rearranged gene where the V9 segment has joined the JP segment located upstream of the C gamma 1 region (TRGC1). Peripheral TigammaA+ cells were further studied here to shed light on the relation between the two types of TRG rearrangements namely those involving the first (TRG1) vs. the second (TRG2) J-C region. Thirteen clones reactive with anti-TigammaA were tested; it was found that the second TRG allele (i.e., the one which does not involve V9-JP) of these cells was either in germ-line configuration or, more frequently, rearranged with a downstream V gamma gene joined to a J segment of the TRG1 region. These data suggest that productive rearrangements on TRG1 leading to the production of a surface-expressed gamma chain occur before rearrangements involving the TRG2 region. It supports the view that TRG genes are subjected to a sequentially ordered activation during the process of T lymphocyte differentiation.

Murine thymomas induced by fractionated-X-irradiation have specific T-cell receptor rearrangements and characteristics associated with day-15 to -16 fetal thymocytes

We report here that specific T-cell receptor rearrangements were observed in fractionated-X-irradiation-induced murine leukemias. Consistent gamma-chain rearrangements, limited beta-chain rearrangements, and no detectable alpha-chain rearrangements were observed. Gene expression studies revealed that, in comparison with normal thymus tissue, expression of alpha T-cell receptor genes was lower in the thymomas, beta expression was much higher but approximately equal to that of normal thymocytes, and gamma expression was significantly increased. After coupling these data with those from analyses using reagents against other surface markers, such as Lyt-2, L3T4, H-2, IL-2R and MEL-14, we concluded that the target T cells for fractionated-X-irradiation-induced transformation resemble fetal thymocytes from days 15 and 16 of gestation.

Comparison of T cell receptor alpha, beta, and gamma gene rearrangement and expression in T cell acute lymphoblastic leukemia

We have analyzed the configuration of the T cell receptor (TCR) alpha gene using newly developed genomic joining region (J alpha) probes, which cover approximately 80 kb of the J alpha region upstream from the constant region in 19 patients with T cell acute lymphoblastic leukemia (T-ALL) and in three CD3- leukemic T cell lines (HSB2, CEM, and MOLT4). In parallel, transcription of the TCR-alpha, beta, and gamma genes was examined in 11 of these patients and in the T cell lines. All T-ALL and the three T cell lines exhibited both TCR-gamma and beta gene rearrangements. 8 of 10 T-ALL and all T cell lines expressed TCR-gamma transcripts. All samples tested expressed both TCR-beta and CD3-gamma transcripts. TCR alpha transcripts were only observed in CD3+ T-ALL but not in CD3- T-ALL or the CD3- cell lines. Among the CD3+ T-ALL, eight had TCR-alpha gene rearrangements. In addition, TCR-alpha gene rearrangements were detected in one CD3- T-ALL and all three T cell lines. These leukemic cells may represent a transient stage between rearrangement and expression and provide an opportunity for analyzing the mechanism regulating the expression of the TCR-alpha gene.

A CD3- subset of CD4-8+ thymocytes: a rapidly cycling intermediate in the generation of CD4+8+ cells

T lymphocytes with the surface phenotype CD4+8- and CD4-8+ are considered to be representative of functionally mature cells. We show here that adult murine thymus contains a subpopulation of CD4-8+ cells that differ from CD4-8+ cells found in the periphery in that they do not express the T cell receptor-associated CD3 molecular complex. Such CD3-4-8+ thymocytes are cortisone sensitive and rapidly cycling in situ. Furthermore, in contrast to mature T cells, most CD3-4-8+ thymocytes express low levels of CD5 and high levels of the B2A2 antigen. CD3-4-8+ thymocytes fail to respond to a variety of mitogenic stimuli in vitro but do give rise upon short-term culture to CD4+8+ cells. It is suggested that CD3-4-8+ thymocytes represent a transitional stage of thymus differentiation between the CD4-8- and CD4+8+ compartments.

In transgenic mice the introduced functional T cell receptor beta gene prevents expression of endogenous beta genes

Transgenic mice were constructed with a functional T cell receptor beta gene. Transcription of the introduced gene is largely confined to T cells, but low levels of transcripts are also seen in B cells and in other tissues. Serological analyses show that most, if not all, of the T lymphocytes express the transgenic beta chain on the cell surface and lack beta chains encoded by endogenous beta genes. Molecular genetic analyses of uncloned and cloned T lymphocytes demonstrate that rearrangement of endogenous beta genes is incomplete. Partial D beta 1-J beta 1 rearrangements are found preferentially, while complete VDJ rearrangements are not seen. These findings show that expression of the transgene regulates the rearrangement of endogenous beta genes. Although the alpha beta T cell receptors of the transgenic mice are homogeneous with respect to the beta chain, they are fully functional, at least in a variety of allogeneic responses.

Progression of rearrangements at T cell receptor beta and gamma gene loci during athymic differentiation of bone marrow cells in vitro

A previously described in vitro system that supports T cell differentiation from bone marrow (BM) precursors was analyzed for T cell receptor gene rearrangement and expression. Cultured populations from days (d.) 0, 3, 6, and 12-13 were fused with BW5147. Only hybridomas from d.6 and d.12-13 bore BM-derived rearrangements. The rearrangement complexity was higher on d.12 than d.6 in that patterns consistent with D beta 1-J beta 1 and D beta 2-germ-line configurations decreased while V-D-J beta 2 and V gamma 2-J gamma 1 joining became dominant. Northern blots of d.13 BM cultures revealed gamma, alpha, and beta (1.0 and 1.3 kb) transcripts. Parallels between patterns in BM cultures and thymus ontogeny were recognized.

Analysis of T cell receptor beta chains in rat thymus, and rat C alpha and C beta sequences

In development, T cells first express their alpha beta antigen receptors in the thymus, where they may undergo selection processes leading to major histocompatibility complex (MHC) restriction and tolerance. A high proportion of thymocytes are thought to fail this selection in some way and to be destined for intrathymic death. These cells are categorized as the "cortical type" since they constitute most of the cortical cells; they express both CD4 and CD8 antigens but only very low levels of MHC class I antigens. One suggested cause of thymocyte death is a failure to produce a functional alpha beta T cell receptor (Tcr) due to errors in the rearrangements of germline DNA, resulting in V regions being absent or incorrectly spliced to the other segments of the transcribed gene. We have sequenced from the C region through to the V region of 14 rat Tcr beta chain clones isolated from thymocyte cDNA libraries. Of the 14, 13 have complete and correct rearrangements, whereas one was expressed from an unrearranged gene. Most of these clones are likely to be derived from the cortical population, for Northern blot analysis showed that these cells and total thymocytes expressed similar amounts of beta chain mRNA. Furthermore, the RNA from cortical-type cells contained a very similar ratio of full-length to truncated beta chain mRNA as did activated thymocytes and mature T lymphocytes. The data imply that defective beta chain gene rearrangement is not a major cause of failure in the selection of thymocytes. The sequences of the rat Tcr alpha and beta chain constant regions are also reported.

Regulation of expression of T cell gamma chain, L3T4 and Ly-2 messages in Abelson/Moloney virus-transformed T cell lines

Recent results have suggested that T cells may exist in two distinct pathways, one expressing alpha and beta chain of the T cell receptor genes with either or both of the cell surface markers CD4 and CD8, while the other is negative for these cell surface markers and expresses the T cell-specific gamma chain genes. The relationship between these two pathways is not known. In this study, we have examined a series of either Abelson virus or Moloney virus-derived T cell lines for their expression of these T cell receptor and cell surface marker genes. Results indicate that the Abelson T cell lines do not express the cell surface markers CD4 and CD8, but express relatively high levels of gamma chain transcripts. After culture of these cell lines with the phorbol ester phorbol myristate acetate and interleukin 2, a down-regulation of these gamma chain transcripts can be observed. More interestingly, we found that the Moloney virus-derived T cell lines, which express the cell surface markers CD4 and/CD8, contain high levels of alpha and beta chain T cell receptor transcripts but little or no gamma transcripts even though they have rearranged these latter genes. The gamma transcripts, however, can be induced to high levels after culture with phorbol myristate acetate and interleukin 2. In the process, the cell surface markers CD4 and CD8 and their transcripts were dramatically down-regulated resulting in cells with high levels of gamma chain transcripts and a CD4-CD8- phenotype. The regulation of expression of these genes is reversible. Taken together, these results indicate that the T cell receptor gamma chain genes and those of the cell surface markers CD4 CD8 can be regulated in vitro by external factors and it opens up the possibility of studying the regulatory sequences associated with these genes.

A large subpopulation of avian T cells express a homologue of the mammalian T gamma/delta receptor

This report describes an avian TCR molecule, TCR1, whose molecular characteristics, signal-transducing property, and tissue distribution suggest that it is a homologue of the mammalian TCR-gamma/delta. TCR1+ cells are the first to be generated in the thymus during ontogeny, preceding other T3+ cells by approximately 3 d. Unlike their mammalian counterpart, TCR1+ cells constitute a relatively large subpopulation of peripheral T cells in mature chickens. These results suggest a phylogenetically important role for this receptor in T cell development and function.

Immunoglobulin gene expression is a normal differentiation event in embryonic thymocytes

By in situ hybridization to frozen sections of mouse embryos, we have localized cells transcribing the Ig C mu gene during ontogeny. Transcripts were detected from before day 14 of gestation in individual pre-B cells in the liver and, surprisingly, in a large proportion of thymocytes between days 15 and 18. The level of mu RNA sequences in the thymus at day 17 was much higher than has been observed for adult thymocytes; from grain counts, the amount of mu RNA was similar to that observed for Ti gamma RNA. These findings suggest that Ig and Ti genes are under similar transcriptional controls during Ti gene recombination and that elevated mu RNA production is a normal event early in the intrathymic differentiation of T cells.