IL-4-producing gamma delta T cells that express a very restricted TCR repertoire are preferentially localized in liver and spleen.

IL-4-producing gamma delta thymocytes in normal mice belong to a distinct subset of gamma delta T cells characterized by low expression of Thy-1. This gamma delta thymocyte subset shares a number of phenotypic and functional properties with the NK T cell population. Thy-1dull gamma delta thymocytes in DBA/2 mice express a restricted repertoire of TCRs that are composed of the V gamma 1 gene product mainly associated with the V delta 6.4 chain and exhibit limited junctional sequence diversity. Using mice transgenic for a rearranged V gamma 1J gamma 4C gamma 4 chain and a novel mAb (9D3) specific for the V delta 6.3 and V delta 6.4 murine TCR delta chains, we have analyzed the peripheral localization and functional properties of gamma delta T cells displaying a similarly restricted TCR repertoire. In transgenic mice, IL-4 production by peripheral gamma delta T cells was confined to the gamma delta+9D3+ subset, which contains cells with a TCR repertoire similar to that found in Thy-1dull gamma delta thymocytes. In normal DBA/2 mice such cells represent close to half of the gamma delta T cells present in the liver and around 20% of the splenic 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.     

T cell antigen receptor engagement and specificity in the recognition of stress-inducible MHC class I-related chains by human epithelial gamma delta T cells

Human gamma delta T cells with the TCR variable region V(delta)1 occur mainly in epithelia and respond to stress-induced expression of the MHC class I-related chains A and B, which have no function in Ag presentation. MIC function as ligands for NKG2D-DAP10, an activating receptor complex that triggers NK cells, costimulates CD8 alpha beta and V(gamma)9V(delta)2 gamma delta T cells, and is required for stimulation of V(delta)1 gamma delta T cells. It is unresolved, however, whether triggering of V(delta)1 gamma delta TCRs is also mediated by MIC or by unidentified cell surface components. Soluble MICA tetramers were used as a binding reagent to demonstrate specific interactions with various V(delta)1 gamma delta TCRs expressed on transfectants of a T cell line selected for lack of NKG2D. Tetramer binding was restricted to TCRs derived from responder T cell clones classified as reactive against a broad range of MIC-expressing target cells and was abrogated when TCRs were composed of mismatched gamma- and delta-chains. These results and the inability of V(delta)1 gamma delta T cells to respond to target cells expressing the ULBP/N2DL ligands of NKG2D, which are highly divergent from MIC, indicate that MIC delivers both the TCR-dependent signal 1 and the NKG2D-dependent costimulatory signal 2. This dual function may serve to prevent erroneous gamma delta T cell activation by cross-reactive cell surface determinants.     

A delta T-cell receptor deleting element transgenic reporter construct is rearranged in alpha beta but not gamma delta T-cell lineages.

T cells can be divided into two groups on the basis of the expression of either alpha beta or gamma delta T-cell receptors (TCRs). Because the TCR delta chain locus lies within the larger TCR alpha chain locus, control of the utilization of these two receptors is important in T-cell development, specifically for determination of T-cell type: rearrangement of the alpha locus results in deletion of the delta coding segments and commitment to the alpha beta lineage. In the developing thymus, a relative site-specific recombination occurs by which the TCR delta chain gene segments are deleted. This deletion removes all D delta, J delta, and C delta genes and occurs on both alleles. This delta deletional mechanism is evolutionarily conserved between mice and humans. Transgenic mice which contain the human delta deleting elements and as much internal TCR delta chain coding sequence as possible without allowing the formation of a complete delta chain gene were developed. Several transgenic lines showing recombinations between deleting elements within the transgene were developed. These lines demonstrate that utilization of the delta deleting elements occurs in alpha beta T cells of the spleen and thymus. These recombinations are rare in the gamma delta population, indicating that the machinery for utilization of delta deleting elements is functional in alpha beta T cells but absent in gamma delta T cells. Furthermore, a discrete population of early thymocytes containing delta deleting element recombinations but not V alpha-to-J alpha rearrangements has been identified. These data are consistent with a model in which delta deletion contributes to the implementation of a signal by which the TCR alpha chain locus is rearranged and expressed and thus becomes an alpha beta T cell.     

Gamma delta T cell receptor analysis supports a role for HSP 70 selection of lymphocytes in multiple sclerosis lesions.

BACKGROUND: Interactions between gamma delta T cells and heat shock proteins (HSP) have been proposed as contributing factors in a number of diseases of possible autoimmune etiology but definitive evidence to support this hypothesis has been lacking. In multiple sclerosis (MS), a chronic inflammatory neurologic disease, HSP and gamma delta T cells are known to colocalize in brain lesions. Analysis of T cell receptor (TCR) gene usage in these lesions has detected evidence of clonality within both the V delta 2-J delta 1 and V delta 2-J delta 3 populations of gamma delta T cells. In our own studies, using direct sequence analysis, a dominant V delta 2-J delta 3 TCR sequence was found in 9 MS brain samples, suggesting a response to a common antigen. In this report, we have examined gamma delta T cell receptor gene usage in MS peripheral blood T cell lines selected for reactivity to HSP 70. MATERIALS AND METHODS: TCR rearrangement patterns for V delta 2-J delta 1 and V delta 2-J delta 3 were studied using the polymerase chain reaction (PCR) and a direct sequencing technique in populations of peripheral blood mononuclear cells (PBMC) cultured with Mycobacterium tuberculosis (M. tuberculosis) purified protein derivative (PPD) and then selected for reactivity to a 70-kD heat shock protein (HSP70). Cells were obtained from health donors, patients with MS, and patients with tuberculosis (TB). PCR products were subjected to direct sequence analysis to look for evidence for clonality within these T cell lines and to define the sequence of the V-D-J (CDR3) region of the TCR. RESULTS: In freshly isolated PBMC, both V delta 2-J delta 1 and V delta 2-J delta 3 gene rearrangement patterns were detected, whereas in HSP70+ T cell lines the predominant delta chain rearrangement pattern was V delta 2-J delta 3. Direct sequence analyses indicated that in cells reactive with HSP70 the V delta 2-J delta 3 sequences were usually oligoclonal and used D delta 3 exclusively. In four of four MS and two of three TB patients, the oligoclonal sequences in the HSP70+ T cell lines were identical to one another and to a dominant sequence previously detected in MS brain lesions. In two of three HSP70+ T cell lines from healthy controls, the oligoclonal sequences differed from those found in both groups of patients but were identical to one another except for a small region of heterogeneity in the second N region. In contrast, in freshly isolated PBMC or in PPD+HSP70- T cell lines, the V delta 2-J delta 3 gene rearrangement patterns were usually polyclonal and dominant sequences were rarely identified. CONCLUSIONS: These results support the conclusion that a subpopulation of gamma delta T cells in MS lesions are responding to HSP 70 and that non-CNS-specific antigens contribute to the pathogenesis of MS.     

T cell receptor/CD3-signaling induces death by apoptosis in human T cell receptor gamma delta + T cells.

mAb directed against the TCR/CD3 complex activate resting T cells. However, TCR/CD3 signaling induces death by apoptosis in immature (CD4+CD8+) murine thymocytes and certain transformed leukemic T cell lines. Here we show that anti-TCR and anti-CD3 mAb induce growth arrest of cloned TCR-gamma delta + T cells in the presence of IL-2. In the absence of exogenous IL-2, however, the very same anti-TCR/CD3 mAb stimulated gamma delta (+)-clones to proliferation and IL-2 production. In the presence of exogenous IL-2, anti-TCR/CD3 mAb induced the degradation of DNA into oligosomal bands of approximately 200 bp length in cloned gamma delta + T cells. This pattern of DNA fragmentation is characteristic for the programmed cell death termed apoptosis. These results demonstrate that TCR/CD3 signaling can induce cell death in cloned gamma delta + T cells. In addition, this report is the first to show that apoptosis triggered by TCR/CD3 signaling is not restricted to CD4+CD8+ immature thymocytes and transformed leukemic T cell lines but can be also observed with IL-2-dependent normal (i.e., TCR-gamma delta +) T cells.     

T cell antigen receptor--structure, expression and function

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

Microanatomic clonality of gamma delta T cells in human leishmaniasis lesions.

T cells bearing gamma delta Ag receptors accumulate in the lesions of patients with localized American cutaneous leishmaniasis (LCL), and are thought to be involved in immunity to the parasite. To obtain clues as to the nature of the Ag recognized by these cells, we analyzed the diversity of the TCR delta-chain in LCL lesions. Using mAb against variable (V) encoded determinants with immunoperoxidase, both V delta 1 and V delta 2 subpopulations were identified in the dermal granulomas. However, within the epidermis of LCL lesions, the majority of the gamma delta T cells were V delta 1 positive. PCR analysis of lesion-derived DNA using oligonucleotide primers for V and junctional (J) gene segments revealed preferential usage of J delta 1 in lesions compared with the peripheral blood of these patients. Nucleotide sequence analysis of the V-J junction indicated limited diversity of gamma delta T cells within specific microanatomic regions. In addition, use of a single diversity (D) gene segment, D delta 3, in V delta 2 cells in lesions was observed, as opposed to multiple D delta gene segment usage in the blood of the same individuals. The distribution, gene segment usage and clonality of gamma delta T cells in lesions of leishmaniasis was remarkably similar to that observed in leprosy. Therefore, gamma delta T cells responding to infection may recognize a limited set of nominal Ag, perhaps common to distinct pathogens and/or those expressed by the host. Our findings are most consistent with a model in which specific gamma delta T cells are clonally selected by these Ag in lesions and undergo oligoclonal expansion within a microanatomic region.     

The unfolding story of T cell receptor gamma

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

Expression of toll-like receptor 2 on gamma delta T cells bearing invariant V gamma 6/V delta 1 induced by Escherichia coli infection in mice

We recently reported that the number of gamma delta T cells was increased after infection with Escherichia coli in C3H/HeN mice. We here showed that an i.p. injection with native lipid A derived from E. coli induced an increase of gamma delta T cells in the peritoneal cavity of LPS-responsive C3H/HeN mice and, albeit to a lesser degree, also in LPS-hyporesponsive C3H/HeJ mice. The purified gamma delta T cells from C3H/HeN and C3H/HeJ mice expressed a canonical TCR repertoire encoded by V gamma 6-J gamma 1/V delta 1-D delta 2-J delta 2 gene segments and proliferated in response to the native lipid A derived from E. coli in a TCR-independent manner. The lipid A-reactive gamma delta T cells bearing canonical V gamma 6/V delta 1 expressed Toll-like receptor (TLR) 2 mRNA, while TLR4 mRNA was undetectable. Treatment with a TLR2 anti-sense oligonucleotide resulted in hyporesponsiveness of the gamma delta T cells to the native lipid A. TLR2-deficient mice showed an impaired increase of the gamma delta T cells following injection of native lipid A. These results suggest that TLR2 is involved in the activation of canonical V gamma 6/V delta 1 T cells by native E. coli lipid A.     

V gamma 3 T cell receptor rearrangement and expression in the adult thymus.

Rearrangement and expression of the V gamma 3-J gamma 1 TCR has been found in murine dendritic epidermal cells (DEC) and fetal thymus. By using the polymerase chain reaction technique, V gamma 3-J gamma 1 rearrangements and RNA expression were detected in the murine adult thymus. Individual genomic and cDNA junctions were cloned and sequenced. In genomic DNA, 55% (16/29) of V gamma 3-J gamma 1 junctional sequences had N regions ranging in length from 1 to 12 nucleotides resulting in considerable junctional diversity. Only 5% (2/42) of cDNA sequences had N regions. The canonical DEC sequence represented 36% (15/42) of the cDNA sequences. Thus, fetal-type V gamma 3-J gamma 1 rearrangements lacking N regions were preferentially expressed in adult thymocytes, some of which may be DEC precursors. The developmental stages in which V gamma 3-J gamma 1 rearrangements are generated were studied by using polymerase chain reaction to detect circular rearrangement products. Active V gamma 3-J gamma 1 rearrangement was detected in thymuses from fetal, newborn, and 2-wk-old mice but not in 5-wk or 8-wk-old (adult) mice. V gamma 2, one of the most common V gamma rearrangements in the adult, was found to be actively rearranging to J gamma 1 in the adult thymus. However, V gamma 2-V gamma 3 replacement rearrangement was not found. These results support the hypotheses that adult thymocytes with rearranged V gamma 3-J gamma 1 are persistent from earlier developmental stages and represent a separate lineage from those with V gamma 2-J gamma 1 rearrangements.     

T cell receptor (TCR) beta chain homodimers on the surface of immature but not mature alpha, gamma, delta chain deficient T cell lines.

Transfected T cell receptor (TCR) beta chain genes are expressed as homodimers on the surface of immature (Sci/ET27F) but not on mature (58 alpha-beta-) T cell lines which lack TCR alpha, gamma and delta chains. The homodimer on Sci/ET27F cells is tightly bound to CD3 delta and CD3 epsilon while the association with CD3 gamma and CD3 zeta proteins is rather weak. Crosslinking of the TCR beta homodimers resulted in a strong and rapid calcium flux. In 58 alpha-beta- T cells the beta TCR chain could be easily visualized intracellularly but was not transported to the cell surface. The Scid cell lines considerably facilitate the molecular analysis of early differentiation events in the thymus which are likely to be regulated by the beta TCR homodimer.     

Further evidence for a gamma/delta T cell receptor-mediated TCT.1/CD48 recognition.

We have demonstrated recently that a molecule, termed TCT.1 (Blast-1/CD48), is recognized on the surface of target cells by a series of alloreactive gamma/delta T cell clones generated from PBL of one healthy individual (designated E). Southern blot analyses suggested that these clones express a TCR associating a V3-JP2-C2 gamma-chain and V1-D-J1-C delta-chain. In the present study, we have developed from PBL of a second normal donor (designated G) a novel series of gamma/delta cloned T cell lines with similar functional activity (i.e., specific recognition of TCT.1 protein). The TCR gamma- and delta-chain nucleotide sequences of both the E and G clones were determined. Results show that 1) sequences from all the clones are identical in each individual donor, 2) the delta-chains expressed by the E and the G clones are encoded by distinct gene rearrangements including V1-D-J delta 1 and V1-D-J delta 2, respectively, 3) the gamma-chains expressed by the E and the G clones are encoded by the same genomic variable elements, namely V gamma 3 and JP2, whereas the junctional regions are distinct. Because the latter rearrangement is very infrequent in human peripheral blood, these data support the view that TCT.1/CD48 recognition is likely to be TCR dependent.     

Gene transfer demonstrates that the V gamma 1.1C gamma 4V delta 6C delta T cell receptor is essential for autoreactivity.

Murine T cell lines and hybridomas derived from the epidermis that express the V gamma 1.1C gamma 4V delta 6C delta TCR and may, therefore, recognize an autoantigen, secrete cytokines spontaneously in culture. In addition, activation of these cells requires engagement of the vitronectin receptor (VNR) by extracellular matrix proteins. To further evaluate the role of the TCR, the VNR, and the putative autoantigen in the activation of this T cell subset, we cloned complete cDNA encoding the V gamma 1.1C gamma 4 and V delta 6C delta TCR and transfected the cDNA constructs into a TCR- murine hybridoma and into a TCR- variant of the human Jurkat line. The murine transfectant spontaneously produced IL-2 in culture and IL-2 production could be inhibited by anti-CD3, anticlonotypic mAb to the transfected TCR, and anti-VNR mAb, as well as by RGDS. These results demonstrate that transfection of the gamma delta TCR confers to recipient T cells the phenotype of constitutive activation, as well as dependence on engagement of the VNR as an accessory molecule. In contrast, the Jurkat gamma delta transfectant failed to produce cytokines spontaneously, although the transfected TCR was capable of signal transduction after stimulation by anti-TCR mAb. Surprisingly, neither the murine transfectant nor the human transfectant could be induced to respond to autoantigen bearing cells in coculture assays. One interpretation of these results is that coexpression on the surface of the same cell of the V gamma 1.1 V delta 6 TCR, the VNR, and a putative autoantigen are necessary for T cell activation in this system.     

Activation requirements of newborn thymic gamma delta T cells.

We have analyzed the requirements for the induction of proliferative responses by thymic CD4-CD8- gamma delta T cells. Enriched populations of CD4-CD8- thymocytes from newborn mice, purified by negative selection with anti-CD4, anti-CD8, and anti-TCR alpha beta mAbs were found to contain approximately 20% gamma delta T cells that were p55IL-2R-. When these cells were cultured with a panel of lymphokines (IL-1, -2, -4, and -7), a small response was observed to some of the cytokines tested individually; however, combinations of certain lymphokines (IL-1 + 2, IL-1 + 7, and IL-2 + 7) were found to induce significant proliferation and the selective outgrowth (75-90%) of gamma delta T cells. These cells were IL-2R+, remained CD4-, yet expressed variable levels of CD8. A limited analysis with specific anti-V gamma and V delta mAb suggested that there had not been a selective expansion of preexisting V gamma 2, V gamma 3, or V delta 4 populations in response to the stimulatory lymphokine combinations. Thymic CD4-CD8- gamma delta T cells were unresponsive to stimulation with immobilized anti-pan gamma delta mAb alone. However, in the presence of immobilized anti-pan gamma delta mAb and IL-1, IL-2, or IL-7, but not IL-4, a vigorous proliferative response was observed. Phenotypic analysis showed that 80 to 95% of the proliferating cells were polyclonally expanded gamma delta T cells, expressed the p55IL-2R, and the majority remained CD4-CD8-. Blocking studies with anti-IL-2R mAb showed that stimulation with anti-pan gamma delta + IL-1, but not anti-pan gamma delta + IL-7 was dependent on endogenously produced IL-2. Collectively, these studies suggest that the activation requirements of newborn thymic gamma delta T cells differ markedly from alpha beta T cells in that gamma delta T cells 1) respond to combinations of cytokines in the absence of TCR cross-linking, 2) can respond to TCR cross-linking in the presence of exogenous cytokines, 3) but are unable to activate endogenous cytokine production solely in the presence of TCR cross-linking.     

Only a subset of phosphoantigen-responsive gamma9delta2 T cells mediate protective tuberculosis immunity

Mycobacterium tuberculosis and Mycobacterium bovis bacillus Calmette-Guérin (BCG) induce potent expansions of human memory Vgamma(9)(+)Vdelta(2)(+) T cells capable of IFN-gamma production, cytolytic activity, and mycobacterial growth inhibition. Certain phosphoantigens expressed by mycobacteria can stimulate gamma(9)delta(2) T cell expansions, suggesting that purified or synthetic forms of these phosphoantigens may be useful alone or as components of new vaccines or immunotherapeutics. However, we show that while mycobacteria-activated gamma(9)delta(2) T cells potently inhibit intracellular mycobacterial growth, phosphoantigen-activated gamma(9)delta(2) T cells fail to inhibit mycobacteria, although both develop similar effector cytokine and cytolytic functional capacities. gamma(9)delta(2) T cells receiving TLR-mediated costimulation during phosphoantigen activation also failed to inhibit mycobacterial growth. We hypothesized that mycobacteria express Ags, other than the previously identified phosphoantigens, that induce protective subsets of gamma(9)delta(2) T cells. Testing this hypothesis, we compared the TCR sequence diversity of gamma(9)delta(2) T cells expanded with BCG-infected vs phosphoantigen-treated dendritic cells. BCG-stimulated gamma(9)delta(2) T cells displayed a more restricted TCR diversity than phosphoantigen-activated gamma(9)delta(2) T cells. In addition, only a subset of phosphoantigen-activated gamma(9)delta(2) T cells functionally responded to mycobacteria-infected dendritic cells. Furthermore, differential inhibitory functions of BCG- and phosphoantigen-activated gamma(9)delta(2) T cells were confirmed at the clonal level and were not due to differences in TCR avidity. Our results demonstrate that BCG infection can activate and expand protective subsets of phosphoantigen-responsive gamma(9)delta(2) T cells, and provide the first indication that gamma(9)delta(2) T cells can develop pathogen specificity similar to alphabeta T cells. Specific targeting of protective gamma(9)delta(2) T cell subsets will be important for future tuberculosis vaccines.