MHC-unrestricted cytotoxic and proliferative responses of two distinct human gamma/delta T cell subsets to Daudi cells.

Human V gamma 9/V delta 2 T cells, the major subset of gamma/delta T cells in peripheral blood of adults, mediate proliferative and cytotoxic responses to Daudi Burkitt's lymphoma cells without previous in vitro exposure to Daudi. Our experiments show that some gamma/delta T cells coexpressing V gamma 9 and V delta 1 genes also react to Daudi cells in cytotoxic and proliferative assays. Expression of V gamma 9 is not sufficient for the recognition of Daudi cells because most gamma/delta T cells expressing V delta 1 paired with V gamma 9 or other V gamma genes neither kill Daudi cells nor proliferate to Daudi. V gamma 9/V delta 2 T cells do not proliferate to other cell lines such as K562 or Molt4 that are sensitive to MHC-unrestricted cytolysis by NK cells and by most IL-2-activated gamma/delta T cell clones. Cold target inhibition assays demonstrate that Daudi cells are stronger inhibitors than K562 and Molt4 of MHC-unrestricted lysis by V gamma 9/V delta 2 clones. However, cold Daudi cells are relatively weaker inhibitors of MHC-unrestricted lysis by NK cell clones, most gamma/delta T cell clones expressing V delta 1 and alpha/beta T cell clones. Thus, recognition by V gamma 9/V delta 2 T cells and certain V gamma 9/V delta 1 T cells of Daudi appears to involve a specific triggering pathway that is distinct from recognition by these gamma/delta T cells of Molt4, K562, and other target cells. NK cell clones and most other gamma/delta and alpha/beta T cell clones derived from the same normal volunteer blood donors do not show this specific interaction with Daudi cells. These data show that distinct subsets of human gamma/delta T cells recognize Daudi cells and support the idea that the gamma/delta TCR may be directly involved.     

Functional and phenotypic differences between CD4+ and CD4- T cell receptor-gamma delta clones from peripheral blood.

CD4+ TCR-gamma delta+ T cells comprise a very small subset of TCR-gamma delta+ T cells. CD4+ TCR gamma delta+ T cell clones were established to study the phenotypical and functional characteristics of these cells. Thirty-four CD4+ TCR-gamma delta+ T cell clones were established after sorting CD4+ T cells from a pre-expanded TCR-gamma delta+ T cell population. These clones as well as the CD4- TCR-gamma delta+ T cells from the same donor used V gamma 2 and V delta 2. In a second cloning experiment CD4+ TCR-gamma delta+ T cells were cloned directly from freshly isolated TCR-gamma delta+ T cells using a cloning device coupled to a FACS sorter. Forty-three clones were obtained, which all expressed CD4 and TCR-gamma delta. Eleven of these clones used V delta 1 and three of them coexpressed V gamma 2. The other CD4+ TCR-gamma delta+ T cell clones used both V delta 2 and V gamma 2. CD4+ TCR-gamma delta+ T cell clones expressed CD28 irrespective of the V gamma or V delta usage, and were CD11b negative. Three CD4-CD8+ TCR-gamma delta+ clones expressed CD8 alpha but not CD8 beta and were CD11b positive. CD28 expression among CD4-CD8+ and CD4-CD8- was variable but lower than on CD4+ T cell clones. CD4- TCR-gamma delta+ T cell clones using V gamma 2 and V delta 2 specifically lyse the Burkitt lymphoma cell line Daudi and secrete low levels of IFN-gamma and granulocyte-macrophage-CSF upon stimulation with Daudi. In contrast, most CD4+ T cell clones that use V gamma 2 and V delta 2 had a very low lytic activity against Daudi cells and secrete high levels of IFN-gamma and granulocyte-macrophage-CSF after stimulation with Daudi cells. The NK-sensitive cell line K562 was killed efficiently by the CD4- TCR-gamma delta+ T cell clones, but not by CD4+ TCR-gamma delta+ T cell clones, and could not induce cytokine secretion in CD4+ or CD4- T cell clones. CD4+ TCR-gamma delta+ T cell clones, but not the CD4- clones, could provide bystander cognate T cell help for production of IgG, IgM, and IgA in the presence of IL-2 and IgE in the presence of IL-4. Thus, CD4+ TCR-gamma delta+ T cells are similar to CD4+ TCR-alpha beta+ T cells in their abilities to secrete high levels of cytokines and to provide T cell help in antibody production.(ABSTRACT TRUNCATED AT 400 WORDS)     

Specific triggering of gamma, delta T cells by K562 activates the gamma, delta T cell receptor and may regulate natural killer-like function.

Freshly isolated and resting gamma/delta T cell lines, although capable of lysing a variety of MHC-unrestricted targets, fail to lyse K562. Yet, the killing of K562 can be specifically induced by antibodies to CD3 or delta-chains. Although this phenomenon may be caused by redirected lysis, it also raised the possibility that K562 may possess ligands capable of specifically interacting with the gamma/delta receptor. We found that K562 specifically induced both CD3 and delta modulation as well as IL-2R expression and IL-2 production by gamma/delta cells, supporting the idea that the TCR-gamma/delta is specifically triggered by K562 cells. Moreover, although the gamma/delta cell clones lysed other target cells (e.g., Molt 4, U937, Jurkat etc.), these latter targets did not induce delta modulation or IL-2R expression. In addition, F(ab)2 anti-CD3 antibodies inhibited activated gamma/delta T cells from killing K562 but did not inhibit the lysis of the other targets. Taken together, these results suggest that gamma/delta cells lyse some targets by utilizing receptors (perhaps NK-like) distinct from the gamma/delta receptor. We also found that triggering of the gamma/delta receptor by K562 inhibited the capacity of resting gamma/delta to lyse Molt 4 cells under conditions in which the K562 cells were not lysed. These findings suggest that the gamma/delta receptor maybe directly involved in the lysis of certain targets (i.e., K562) and, importantly, may potentially regulate the function of NK-like receptors that are involved in the lysis of other targets.     

Functional gamma delta T-lymphocyte defect associated with human immunodeficiency virus infections.

BACKGROUND: Antiviral cellular immune responses may influence immunological homeostasis in HIV-infected persons. Recent data indicate that V gamma 9/V delta 2 T lymphocytes display potent cytotoxic activities against human cells infected with certain viruses including HIV. Understanding the role of gamma delta T cells in the course of HIV infection may be helpful for designing novel treatment strategies for HIV-associated disorders. MATERIALS AND METHODS: The constitutive recognition of Daudi cells and monoethyl pyrophosphate (Etpp) by peripheral blood V gamma 9/V delta 2 T cells was assessed using a proliferation assay. The cytotoxicity of Daudi-stimulated lymphocyte populations was measured by chromium release assays. The HIV infectivity for gamma delta T cell clones was determined by measuring the levels of HIV p24 in cell supernatants. The effect of in vitro HIV-infection on cytokine mRNA production by gamma delta T cell clones was assessed by PCR. RESULTS: The constitutive proliferative responses of peripheral blood V gamma 9/V delta 2 T cells and the lytic functions of Daudi-expanded lymphoid cells from HIV+ persons were substantially diminished in comparison with those of HIV-seronegative persons. These alterations were present in asymptomatic HIV+ persons prior to substantial alpha beta CD4+ T cell loss. Productive HIV infection of gamma delta T cells in vitro had no measurable effect either on their proliferative response to Daudi stimuli or on the expression of cytokine mRNAs for IFN-gamma, IL-2, IL-4, IL-5, IL-6, IL-10, and IL-13. CONCLUSIONS: The constitutive responsiveness of V gamma 9/V delta 2 T lymphocytes to Daudi and Etpp is severely altered in HIV+ persons. HIV infection of gamma delta T cells in vitro does not substantially change their cytokine expression or antigenic response.     

Staphylococcal enterotoxin-mediated human T-T cell interactions.

Staphylococcal enterotoxins (SE) are known to stimulate a large proportion of T cells. SE bind to MHC-class II molecules on APC and a particular segment of certain TCR V beta and V gamma gene products. Resting human T cells do not express HLA class II Ag and therefore cannot present SE to T cells. Activated human T cells, however, do express HLA-DR, -DP, and -DQ Ag and could consequently serve as APC for SE. As such, local immune responses to SE might be regulated and/or abrogated by SE-mediated T-T cell interactions leading to T cell destruction. We have investigated if such SE-mediated T-T cell interactions can occur in vitro using human cytolytic TCR-alpha beta+ and TCR-gamma delta+ T cell clones. We demonstrate that the TCR-alpha beta+ T cell clones can efficiently present staphylococcal enterotoxin A (SEA) to each other: T cell clones coated with SEA are lysed by SEA-reactive T cell clones but not by a SEA-nonreactive T cell clone. Furthermore, the SEA-reactive TCR-alpha beta+ clones (but not the SEA-nonreactive clone) destruct themselves in the presence of SEA at low concentrations of SEA (less than 0.01 microgram/ml). Also, SEA-coated T cell clones can induce proliferative responses although such responses are much weaker than those induced when B cells are used as stimulator cells. In contrast, the SEA-reactive TCR-gamma delta+ T cell clones are resistant to autokilling in the presence of SEA and they do not lyse SEA-coated TCR-gamma delta+ targets. However, such targets can be lysed by TCR-alpha beta+ effector cells. These results indicate that TCR-gamma delta+ cells are relatively resistant to lysis and that during local nonspecific immune responses triggered by SE, which induces HLA-class II expression by the responding T cells, SE-mediated T-T cell interactions may play a role in the regulation and/or abrogation of these immune responses.     

Different roles of the CD2 and LFA-1 T-cell co-receptors for regulating cytotoxic, proliferative, and cytokine responses of human V gamma 9/V delta 2 T cells

BACKGROUND: Human V gamma 9/V delta 2 T lymphocytes recognize nonpeptidic antigens in a manner distinct from the classical antigen recognition by alpha beta T cells. The apparent lack of major histocompatibility (MHC) restriction and antigen processing allows very fast responses against pathogenic insults. To address the potential functional requirement for accessory molecules, we investigated the roles of the CD2 and lymphocyte function-associated antigen (LFA)-1 T-cell co-receptors in antigen-induced activities of human V gamma 9/V delta 2 T-cell clones. MATERIALS AND METHODS: Human peripheral blood V gamma 9/V delta 2 T lymphocytes were cloned and their cytotoxicity against Daudi lymphoma was measured by a standard 51Cr-release assay. The responses of V gamma 9/V delta 2 T lymphocytes to nonpeptidic antigens were assessed using DNA synthesis and cytokine ELISA assays. Monoclonal antibodies specific for various molecules with potential T-cell accessory functions were utilized in blocking assays. RESULTS: All of our V gamma 9/V delta 2 T-cell clones displayed the Th1 phenotype. The anti-LFA-1 antibody strongly inhibited the cytotoxicity of V gamma 9/V delta 2 T cells against Daudi B-cell lymphoma; whereas, it had no influence on the antigen-induced cytokine release or proliferation. In contrast, antibodies against CD2 and LFA-3 had no effect on the lytic activity of V gamma 9/V delta 2 T cells, but strongly inhibited the cytokine release and proliferation. However, the CD2-LFA-3 interaction was not an absolute requirement for the cytokine release and the DNA synthetic activity of antigen-stimulated V gamma 9/V delta 2 T cells, since the inhibitory effect could be reversed by addition of exogenous interleukin 2 (IL-2). CONCLUSIONS: These novel observations indicate that the signals generated by different accessory molecules and IL-2 can contribute in an integrated fashion to the regulation of V gamma 9/V delta 2 T cells. These interactions may be important for the effectiveness of V gamma 9/V delta 2 T-cell responses.     

Peripheral T cell receptor gamma delta variable gene repertoire maps to the T cell receptor loci and is influenced by positive selection.

Although the mechanisms that determine TCR-alpha beta V gene repertoire are well studied, the genetic influences involved in TCR-gamma delta repertoire development are unclear. Unlike the TCR-gamma delta populations that localize in epithelial tissues, the circulating peripheral TCR-gamma delta V region repertoire is quite diverse. Previous studies have shown that three TCR-gamma chains and at least six TCR-V delta genes are expressed by splenic TCR-gamma delta cells. However, the relative frequency of individual gamma delta subsets among genetically diverse mice has not been determined. Therefore, the repertoire of TCR-gamma delta cells was examined using anti-TCR V region specific mAb against V gamma 2 and V delta 4 on TCR-gamma delta + cells from total splenocytes. We found that there was a strain-specific variation in TCR-gamma delta usage. The frequency of V gamma 2 expression in different strains varied from 54 to 12%, and the frequency of V delta 4 expression in different strains varied from 38 to 10%. However, the level of V delta 4 and V gamma 2 expression for an individual strain was highly consistent from experiment to experiment. F1 analysis between parental strains that differed in relative frequency of either V gamma 2+ or V delta 4+ cells revealed that high expression was genetically dominant, suggesting that positive selection events play a major role in the peripheral gamma delta repertoire. Variations in the levels of V gamma 2+ cells and V delta 4+ cells was not associated with Mls or MHC haplotype. Analysis of recombinant inbred strains revealed that high V delta 4 expression mapped to the TCR-gamma locus, while high V gamma 2 expression was influenced by the TCR-delta locus. Back-cross analysis confirmed that the TCR loci dominantly influenced the level of V delta 4+ cells and V gamma 2+ cells; however, there was clear evidence that multiple genes affect the TCR-gamma delta repertoire.     

Systematic development of distinct T cell receptor-gamma delta T cell subsets during fetal ontogeny

To elucidate the developmental pattern and diversity of murine cluster of differentiation (CD)3-associated TCR-gamma delta heterodimers, adult and fetal thymocytes were examined for cell-surface expression of various gamma- and delta-encoded TCR. Biochemical analysis, using antisera specific for distinct C gamma gene products, revealed the presence of T cells expressing C gamma 1 and/or C gamma 4 heterodimers in adult and fetal CD4- CD8- thymocyte populations. Although CD4-CD8- thymocyte populations express both C gamma 1 and C gamma 4 TCR-gamma delta heterodimers early in fetal thymus development, the relative level of C gamma 4-expressing T cells was significantly lower than previously observed in peripheral lymphoid organs. In addition, biochemical studies revealed the presence of TCR-gamma delta heterodimer(s) expressed during fetal ontogeny which were not detected in adult thymocyte or peripheral lymphoid populations. Studies of N-glycosylation patterns of one of these heterodimers suggested that it contained a rearranged V gamma 3/C gamma 1 gene product. To examine in detail individual TCR-gamma delta heterodimers, a panel of TCR-gamma delta expressing hybridomas was prepared. Biochemical analysis at the clonal level revealed that indeed three distinct TCR-gamma delta heterodimers were present at day 16 of fetal thymus development, with TCR-gamma-chains most likely encoded by V gamma 2/C gamma 1, V gamma 3/C gamma 1, and V gamma/C gamma 4. Together these findings suggest an ordered development of TCR-gamma delta T cells in the thymus and selective expression of distinct TCR-gamma delta subsets in peripheral lymphoid organs such as spleen and lymph nodes.     

Identification of distinct T cell receptor (TCR)-gamma delta heterodimers using an anti-TCR-gamma variable region serum

T cell hybridomas were generated from CD3+, CD4-, CD8- splenocytes and fetal thymocytes. V gamma 1-expressing proteins present on these murine TCR-gamma delta hybridomas were identified by using an anti-TCR V gamma 1 peptide serum. This antiserum specifically immunoprecipitated 41-kDa TCR V gamma-C gamma 4 chains and 31-kDa TCR V gamma-C gamma 1/2 chains from distinct heterodimers expressed on the TCR-gamma delta T cell hybridomas. The RNA from a hybridoma with a 31-kDa TCR-gamma chain hybridized with a V gamma 1 probe but failed to hybridize with a V gamma 2 probe. In contrast, the RNA from a hybridoma with a 32-kDa TCR-gamma chain hybridized with a V gamma 2 probe. This 32-kDa TCR-gamma chain was not immunoprecipitated by the anti-V gamma 1 serum. These data were consistent with the conclusion that the 31-kDa protein was the product of a V gamma 1 to C gamma 2 rearrangement, whereas the 32-kDa protein was the product of a V gamma 2 to C gamma 1 rearrangement. Furthermore, Southern analyses confirmed that the 32-kDa protein was the product of a V gamma 1.2-J gamma 2 rearrangement, and all three of the 41-kDa TCR-gamma chains were the results of V gamma 1.1-J gamma 4 rearrangements. This was the first demonstration at the clonal level of TCR-gamma proteins which use members of the V gamma 1 gene family, as well as the C gamma 2 constant region. Additional biochemical analyses of the TCR-gamma and -delta proteins from three independently derived C gamma 4-bearing T cell hybridomas suggested that most of the molecular mass diversity observed in the bulk subpopulation of peripheral C gamma 4-containing heterodimers may be contributed by the TCR-delta chains.     

Synaptic transfer by human gamma delta T cells stimulated with soluble or cellular antigens

B, alpha beta T, and NK lymphocytes establish immunological synapses (IS) with their targets to enable recognition. Transfer of target cell-derived Ags together with proximal molecules onto the effector cell appears also to occur through synapses. Little is known about the molecular basis of this transfer, but it is assumed to result from Ag receptor internalization. Because human gamma delta T cells recognize soluble nonpeptidic phosphoantigens as well as tumor cells such as Daudi, it is unknown whether they establish IS with, and extract molecules from, target cells. Using flow cytometry and confocal microscopy, we show in this work that Ag-stimulated human V gamma 9/V delta 2 T cells conjugate to, and perform molecular transfer from, various tumor cell targets. The molecular transfer appears to be linked to IS establishment, evolves in a dose-dependent manner in the presence of either soluble or cellular Ag, and requires gamma delta TCR ligation, Src family kinase signaling, and participation of the actin cytoskeleton. Although CD45 exclusion characterized the IS performed by gamma delta T cells, no obvious capping of the gamma delta TCR was detected. The synaptic transfer mediated by gamma delta T cells involved target molecules unrelated to the cognate Ag and occurred independently of MHC class I expression by target cells. From these observations, we conclude that despite the particular features of gamma delta T cell activation, both synapse formation and molecular transfer of determinants belonging to target cell characterize gamma delta T cell recognition of Ags.     

Expression of human T cell receptor-gamma delta structural forms

The human TCR-gamma delta occurs in three biochemically distinct forms (forms 1, 2bc, and 2abc). A 40-kDa TCR gamma-chain is disulfide-linked to the TCR delta-chain in form 1, whereas 40-kDa or 55-kDa TCR-gamma polypeptides are noncovalently associated with the TCR delta-chain in forms 2bc and 2abc, respectively. Sequence analysis of TCR-gamma cDNA clones indicates that form 1 utilizes the C gamma 1 gene segment, whereas forms 2bc and 2abc appear to use allelic C gamma 2 gene segments containing either two copies (b and c) or three copies (a, b, and c) of the CII exon, respectively. We transfected TCR-gamma cDNA encoding form 1 or form 2abc into the MOLT-13 cell line that expresses form 2bc. The transfected TCR gamma-chains associate with the resident MOLT-13 TCR-delta, normally part of form 2bc, to yield CD3-associated TCR-gamma delta heterodimers identical to those seen on the donor cell lines (form 1 or 2abc). These transfection experiments show directly that, 1) when a single TCR-delta subunit is available, the presence or absence of disulfide linkage between TCR gamma- and TCR delta-chains is controlled by the TCR gamma-chain, and 2) the difference in the amount of N-linked carbohydrate attached to the transfected TCR-gamma proteins of form 2bc vs form 2abc is influenced by the presence or absence of CII exon copy "a" which appears to alter the secondary and/or tertiary structure of these TCR gamma-chain constant regions, thereby affecting the attachment of N-linked glycans. In contrast to the similar structure and usage of C beta 1 and C beta 2, TCR-gamma delta forms show striking differences in structure and are not equally represented in peripheral blood. Although the role of each form is unknown, it is possible that variable or joining-gene segment selection events or functional differences account for their unequal usage.     

Self-reactive, T cell receptor-gamma delta+, lymphocytes from the intestinal epithelium of weanling mice.

Intraepithelial T lymphocytes (IEL) are dispersed throughout the intestinal epithelial lining but their role in cellular immune defense is unknown. Their location suggests that their highly activated state may be due to constant exposure to bacterial Ag. To study IEL specificity and function we have prepared a panel of IEL-T cell hybridomas from both adult and weanling C57B1/6 mice. Many of these expressed TCR-gamma delta, a cell type rare in peripheral lymph nodes and spleen but predominant at epithelial surfaces. We have identified a subset of gamma delta T cells from weanling mice which is self reactive, i.e., these hybrids secrete IL-2 spontaneously, without antigenic stimulation or a requirement for APC. Self-reactive TCR-gamma delta+ hybrids and lines, all of which bear a particular TCR (V gamma 1.1C gamma 4V delta 6), have previously been derived from neonatal thymus and the skin. Northern blot and immunoprecipitation analyses suggest that the self-reactive IEL hybrids also bear a C gamma 4/V delta 6 TCR. Antibody inhibition experiments showed that the self-reactivity of the IEL hybrids is TCR mediated. Spontaneous IL-2 production was blocked by soluble anti-CD3 and anti-TCR-gamma delta antibodies but not by antibodies to the TCR-alpha beta. The self-reactive IEL hybrids lack class II MHC and the class I-like proteins CD1 and TLA but express class I MHC. IEL hybrids may also require the vitronectin receptor as an accessory molecule for their activation because spontaneous IL-2 production is blocked by antibody to the vitronectin receptor as well as by the extracellular matrix protein active site peptide RGDS, but not the control peptide RGES. V gamma 1.1C gamma 4V delta 6 T cells in the thymus, skin, and intestine may represent a small and unique subpopulation of lymphocytes with a potential for autoimmune reactivity at peripheral sites.     

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.     

Cytotoxic activity and lymphokine production of T cell receptor (TCR)-alpha beta+ and TCR-gamma delta+ cytotoxic T lymphocyte (CTL) clones recognizing HLA-A2 and HLA-A2 mutants. Recognition of TCR-gamma delta+ CTL clones is affected by mutations at positions 152 and 156

TCR-gamma delta+ CTL clones were generated from CD4-CD8- T cells that were stimulated twice with the cell line JY. Either IL-2 or IL-4 was used as growth factor. A number of TCR-gamma delta+ clones were found to lyse the stimulator cell line JY. Two of these clones secreted N alpha-benzyloxycarbonyl-L-lysine thiobenzyl ester serine esterase activity after stimulation with JY cells. The cytotoxic activity of these two clones was blocked by a mAb specific for HLA-A2. Moreover, these two TCR-gamma delta+ clones selectively lysed human fibroblast line M1 and murine P815 cells transfected with DNA fragments encoding HLA-A2 but not those transfected with HLA-B7 encoding DNA, indicating that these clones recognize HLA-A2. Analysis of the recognition of HLA-A2 by using target cells transfected with mutated HLA-A2 encoding genes revealed that the nature of the amino acid at position 152 of the molecule is critical for recognition of the TCR-alpha beta+ as well as the TCR-gamma delta+ CTL clones since replacement of Val for Ala at that position resulted in abrogation of recognition of one TCR-gamma delta+ and one TCR-alpha beta+ clone and substitution of Val for Glu affected recognition of all clones. Substitution of Leu for Trp at position 156 abrogated recognition by one TCR-gamma delta+ and one TCR-alpha beta+ T cell clone, but recognition by the other clones was not changed. All clones were able to secrete IL-2, IFN-gamma, and GM-CSF but not IL-4 after activation.     

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.     

Functional and morphologic characterization of human T lymphocytes expressing the TCR gamma /delta

A minor subset of T lymphocytes express a TCR composed of gamma and delta chains. This subset differs from conventional T cells for a number of phenotypic and functional characteristics. TCR gamma/delta+ cells simultaneously lack both CD4 and CD8 antigens. Cloning of CD4-8- peripheral blood lymphocytes, under limiting dilution conditions, revealed that they are homogeneously composed of cytolytic cells which efficiently lyse tumor target cells. Formal proofs have been provided that TCR gamma/delta+ cells are able to recognize antigens. For example, they proliferated in response to allogeneic mixed lymphocyte culture (MLC); in addition, MLC-derived TCR gamma/delta+ cells specifically lysed PHA-induced blast cells bearing the stimulating alloantigens. The selection of monoclonal antibodies specific for TCR gamma/delta molecules allowed to identify two distinct subsets of TCR gamma/delta+ cells. Both of these mABs, termed BB3 and delta TCS-1 respectively, induced specific activation of cloned cells expressing the corresponding antigenic determinants (as assessed by measurements of intracellular Ca++ and/or lymphokine production or cytolytic activity). Analysis of the distribution of subsets expressing different forms of TCR gamma/delta, showed that the BB3-reactive form is prevalent in the peripheral blood. In contrast, delta-TCS-1-reactive cells are relatively unfrequent in peripheral blood but represent the majority of TCR gamma/delta+ cells in tissues.     

V delta 1+ subset of human gamma delta T cells responds to ligands expressed by EBV-infected Burkitt lymphoma cells and transformed B lymphocytes.

Human gamma delta T cells of peripheral blood can be divided in two groups in terms of their TCR as well as their behavior upon in vitro stimulation. The major subset expresses the TCR V-segments V gamma 9 and V delta 2 and proliferates in response to ligands revealed by various microorganisms, and the cell line Daudi in addition. The minor group is less homogenous on the gamma-chain but is almost completely identified by mAb against the V delta 1 segment; there is no ligand known to promote growth of these cells. Here we demonstrate that gamma delta T cells out of this subgroup are strongly stimulated in vitro by cells from several Burkitt's lymphoma cell lines. EBV infection of the Burkitt's lymphoma cell lines enhanced the stimulatory ability towards the T cells. Although EBV infection influenced the expression of a variety of cell surface molecules including ICAM-1 and LFA-3, no correlation to the gamma delta T cell-stimulating capacity became apparent. We conclude that Burkitt's lymphoma cells and transformed B cells express ligands of cellular origin for a hitherto poorly characterized subgroup of human gamma delta T cells.     

T cell receptor gamma delta expression of Thy-1+ dendritic epidermal cells--an update

Thy-1+ dendritic epidermal cells (Thy-1+DEC) are present in the murine epidermis. They are morphologically dendritic and express Thy-1, CD3 and asialoGM1, but not CD4 or CD8. T cell receptor (TCR) of Thy-1+DEC is TCR gamma delta. Allison et al and Tonegawa et al recently found that TCR of Thy-1+DEC is V gamma 5 J gamma C gamma -V delta 1D2J2C delta and has no junctional diversity. This TCR gamma delta of Thy-1+DEC is identical to TCR expressed on the earliest fetal thymocytes. It is distinct from that of other epithelial associated lymphocytes or other thymocytes. The ligand of Thy-1+DEC is not known, although TCR gamma delta of adult type could recognize allogenic major histocompatibility complex(MHC) class I or class II and mycobacterium antigen, especially heat shock protein. The TCR of Thy-1+DEC may not be the homing receptor to epidermis. The further studies are needed to elucidate the ligands or functions of Thy-1+DEC.     

Gamma delta TCR cells in hepatic sinusoids and intestinal intraepithelia

We provided here the conception that the liver is an important immune organ after birth. On the other hard, it is well established that the liver in the fetal stage works as a hematopoietic organ. Although a significant number of gamma delta TCR cells are distributed in epithelia of the skin, intestine and reproductive organs, the liver is also one of the most predominant organs of gamma delta TCR cells. The percentages of gamma delta TCR cells in MNC of hepatic sinusoids increased up to 16.0% in young mice aged 4 wk, and approximately 40% of such gamma delta TCR cells expressed the CD8 antigens. V gene segment usage analysis by the PCR method demonstrated that a unique set of V gamma 2/V delta 6 was preferentially used by hepatic gamma delta TCR cells. The predominant appearance of unique gamma delta TCR cells in hepatic sinusoids of mice, including nude mice, proposed us the possibility that these gamma delta TCR cells may differentiate non-thymus dependently in the liver. The lymphocytes in the hepatic sinusoids may be intimately related to the antigens come from the intestine and to the lymphocytes sensitized there. Therefore, we introduced recent evidences about gamma delta T cells in the intestine and discussed their connection with the hepatic gamma delta T cells.