A functional gamma gene formed from known gamma-gene segments is not necessary for antigen-specific responses of murine cytotoxic T lymphocytes

Evolution and function of the TCR Vgamma9 chain repertoire: It's good to be public

Lymphocytes expressing a T cell receptor (TCR) composed of Vgamma9 and Vdelta2 chains represent a minor fraction of human thymocytes. Extrathymic selection throughout post-natal life causes the proportion of cells with a Vgamma9-JP rearrangement to increase and elevates the capacity for responding to non-peptidic phosphoantigens. Extrathymic selection is so powerful that phosphoantigen-reactive cells comprise about 1 in 40 circulating memory T cells in healthy adults and the subset expands rapidly upon infection or in response to malignancy. Skewing of the gamma delta TCR repertoire is accompanied by selection for public gamma chain sequences such that many unrelated individuals overlap extensive in their circulating repertoire. This type of selection implies the presence of a monomorphic antigen-presenting molecule that is an object of current research but remains incompletely defined. While selection on a monomorphic presenting molecule may seem unusual, similar mechanisms shape the alpha beta T cell repertoire including the extreme examples of NKT or mucosal-associated invariant T cells (MAIT) and the less dramatic amplification of public Vbeta chain rearrangements driven by individual MHC molecules and associated with resistance to viral pathogens. Selecting and amplifying public T cell receptors whether alpha beta or gamma delta, are important steps in developing an anticipatory TCR repertoire. Cell clones expressing public TCR can accelerate the kinetics of response to pathogens and impact host survival.

Characterization of the T-cell receptor gamma locus and analysis of the variable gene segment expression in rabbit

The genomic organization and expression of genes of the T-cell receptor gamma (TRG) locus are described for mice and humans, but not for species such as rabbits (Oryctolagus cuniculus), in which gammadelta T cells compose a sizeable proportion of T cells in the periphery. We cloned 200 kb of the rabbit TRG locus and determined the TRGV gene usage in adult and newborn rabbits by RT-PCR. We identified two TRGJ genes, one TRGC gene, and 22 TRGV genes, all of which encoded functional variable regions. One TRGV gene is the unique member of the TRGV2 subgroup, whereas the other genes belong to the TRGV1 subgroup. Evolutionary analyses of TRGV1 genes identified three distinct groups that can be explained by separate duplication events in the rabbit genome. Evidence of gene conversion between TRGV1.1 and TRGV1.6 was observed. Both TRGV1 and TRGV2 subgroup genes were expressed in the spleen, intestine, and appendix of adult rabbits, and the repertoire of TRGV genes expressed in these tissues was similar. In these tissues from newborns, and in skin from adults, only the genes from the TRGV1 subgroup were expressed. Greater TRGV-J junctional diversity was found in tissues from adult compared to newborn rabbits. Our analyses indicate rabbits have a larger germ line encoded TRG repertoire compared with that of mice and humans. In addition, we found TRGV gene usage is alike in most tissues of rabbits similar to that found in humans but in contrast to that found in mice.

Positive selection of gamma delta CTL by TL antigen expressed in the thymus

To elucidate the funciton of the mouse TL antigen in the thymus, we have derived two TL transgenic mouse strains by introducing Tl alpha 2-3 of A strain origin with its own promoter onto a C3H background with no expression of TL in the thymus. These transgenic mouse strains, both of which express high levels of Tla2-3-TL antigen in their thymus, were analyzed for their T cell function with emphasis on cytotoxic T lymphocyte (CTL) generation. A T cell response against TL was induced in Tg. Tla2-3-1, Tg. Tla2-3-2, and control C3H mice by skin grafts from H-2Kb/T3b transgenic mice, Tg.Con.3-1, expressing T3b-TL ubiquitously. Spleen cells from mice that had rejected the T3b-TL positive skin grafts were restimulated in vitro with Tg. Con.3-1 irradiated spleen cells. In mixed lymphocyte cultures (MLC), approximately 20% and 15% of Thy-1+ T cells derived from Tg.Tla2-3-1 and Tg.Tla2-3-2, respectively, expressed TCR gamma delta, whereas almost all those from C3H expressed TCR alpha beta. The MLC from Tg. Tla2-3-2 and C3H demonstrated high CTL activity against TL, while those from Tg. Tla2-3-1 had little or none. The generation of gamma delta CTL recognizing TL in Tg. Tla2-3-2, but not C3H mice, was confirmed by the establishment of CTL clones. A total of 14 gamma delta CTL clones were established from Tg. Tla2-3-2, whereas none were obtained from C3H. Of the 14 gamma delta CTL clones, 8 were CD8+ and 6 were CD4-CD8- double negative. The CTL activity of all these clones was TL specific and inhibited by anti-TL, but not by anti-H-2 antibodies, demonstrating that they recognize TL directly without antigen presentation by H-2. The CTL activity was blocked by antibodies to TCR gamma delta and CD3, and also by antibodies to CD 8 alpha and CD8 beta in CD8+ clones, showing that the activity was mediated by TCR gamma delta and coreceptors. The thymic origin of these gamma delta CTL clones was indicated by the expression of Thy-1 and Ly-1 (CD5), and also CD8 alpha beta heterodimers in CD8+ clones on their surfaces and by the usage of TCR V gamma 4 chains in 12 of the 14 clones. Taken together, these results suggest that Tla2-3-TL antigen expressed in the thymus engages in positive selection of a sizable population of gamma delta T cells.

Contribution of extrathymic gamma delta T cells to the expression of heat-shock protein and to protective immunity in mice infected with Toxoplasma gondii

We demonstrated that gamma delta T cells contribute to protective immunity against Toxoplasma gondii by inducing the expression of a 65,000 MW heat-shock protein (hsp 65) in host macrophages. Here we examined the role of extrathymic and intrathymic gamma delta T cells in protective immunity and hsp 65 expression in mice infected with T. gondii. Intrathymic gamma delta T cells were obtained from severe combined immunodeficiency (SCID) mice grafted with syngeneic fetal thymus (TG-SCID), in which only T cells derived from the donor thymus developed, whereas extrathymic gamma delta T cells were obtained from nude mice that lack thymus. Extrathymic gamma delta T cells from T. gondii-infected nude mice differed from intrathymic gamma delta T cells of infected TG-SCID mice, in terms of Thy1.2 expression and V-region gene usage of T-cell receptor (TCR) gamma delta. Extrathymic gamma delta T cells expressed extremely high levels of Thy1.2, and had V gamma 7 repertoire but lacked V gamma 5,6 and V delta 1,5. On the other hand, intrathymic gamma delta T cells express intermediate and low levels of Thy1,2. These cells possessed V gamma 5,6 and V delta 1,5 but failed to rearrange the V gamma 7 gene. Peritoneal macrophages from infected nude mice contained hsp 65, whereas this protein was scarcely expressed in those of infected TG-SCID mice. Transfer of extrathymic, but not of intrathymic gamma delta T cells to SCID mice enabled their macrophages to express hsp 65. Athymic nude mice were significantly resistant to the infection compared with SCID mice which lack gamma delta T as well as alpha beta T cells. The resistance was dependent upon extrathymic gamma delta T cells, since nude mice depleted of gamma delta T cells using a corresponding monoclonal antibody became extremely susceptible. These results indicated that extrathymic rather than intrathymic gamma delta T cells play some crucial roles in protection against T. gondii and in hsp 65 expression.

Alpha beta and gamma delta T cells can share a late common precursor

BACKGROUND

The subdivision of T cells into alpha beta and gamma delta subtypes is conserved throughout vertebrate development. The respective alpha beta and gamma delta T-cell receptors (TCRs) are encoded by somatically rearranged genes. There has been broad speculation as to whether an individual thymocyte can become either a gamma delta T cell or an alpha beta T cell as a result of stochastic gene rearrangement processes, or whether the two types of T cell are derived from separate lineages. Many of the experimental findings are apparently conflicting, however, and the issue--a basic one in immunology and development--remains unresolved.

RESULTS

To address this issue, we have used the recently developed polymerase chain reaction-restriction fragment length polymorphism (PCR-RFLP) technique, which allows us to examine quantitatively the status of TCR gamma and delta genes in postnatal alpha beta T cells and their progenitors. Interestingly, such cells are depleted of productively rearranged delta and gamma genes, which can encode delta and gamma TCR polypeptide chains. However, in mice that can rearrange TCR delta gene segments, but in which the TCR delta gene is non-functional in other respects, no such depletion of productive rearrangements is seen.

CONCLUSION

The quantitative data that we have obtained fulfill the predictions of the stochastic hypothesis: that is, a progenitor T cell first attempts to become a gamma delta T cell and, if unsuccessful, then attempts to become an alpha beta T cell. Thus, alpha beta and gamma delta T cells can derive from a common precursor thymocyte. In the simplest case, therefore, lineage-determining factors are the successful rearrangement of both gamma and delta genes before TCR alpha gene rearrangements occur, which lead to deletion of the TCR delta locus and thereby preclude further gamma delta T-cell differentiation. In contrast, successful rearrangement of the TCR beta locus remains compatible with cells becoming either gamma delta or alpha beta T cells.

Tolerance and self-reactivity in V gamma 1.1C gamma 4 transgenic mice

Immunological tolerance is the process of inhibiting or eliminating lymphocytes that recognize self-derived antigens. By removing potentially harmful self-reactive clones, this mechanism allows for the random generation of a diverse repertoire of T-cells capable of responding to foreign pathogens. Although all self-reactive T-cells should be removed from the repertoire, it is quite clear from many recent studies that a significant fraction of T-cells bearing gamma delta T-cell receptors (TCR) recognize self-derived antigens in normal healthy mice. The presence of self-reactive T-cells in healthy animals presents a paradox which may be explained by understanding the transient expression of the antigens (e.g., MHC class Ib, Heat Shock Proteins) that have been identified for gamma delta T-cells thus far. Data from experiments with V gamma 1.1C gamma 4 transgenic mice demonstrating the presence of self-reactive gamma delta T-cells and their influence on lymphoid development and immune surveillance will be examined in this review.

Gamma delta T cell receptor repertoire in brain lesions of patients with multiple sclerosis

The identification of activated T cells in the brains of patients with multiple sclerosis (MS) suggests that these cells are critical in the pathogenesis of this disease. Recently we have used the PCR method to analyse rearrangements of V alpha and V beta genes of the T cell receptor (TCR) in samples of MS and control brains. The results of these studies showed that TCR V gene usage in MS brains may be restricted and in particular that V beta genes may be preferentially rearranged in certain HLA haplotypes associated with susceptibility to MS. In view of the recent evidence that T lymphocytes bearing the gamma delta chains may have autoreactive potential, we have assessed whether or not such TCR-bearing lymphocytes were also present in chronic MS lesions. TCR V gamma and V delta were analysed by the PCR method using a panel of V gamma and V delta primers paired with C gamma or C delta primers in 12 MS brains, as well as in brain samples of ten normal post-mortem cases and three neurological controls. TCR V gamma-C gamma and V delta-C delta rearrangements were confirmed using Southern blotting and hybridisation of the PCR products with specific C gamma and C delta probes. Only one to four rearranged TCR V gamma and V delta transcripts were detected in each of the 23 brain samples obtained from 12 MS patients, with the majority of gamma delta T cells expressing the V gamma 2 and V delta 2 chains. In marked contrast, V gamma and V delta transcripts could only be found in one of the ten non-neurological control brains analysed. To assess the clonality of V gamma 2 and V delta 2 T cell receptor chains in the brain samples of MS patients, we have sequenced the junctional regions of the TCR V gamma-N-J gamma-C gamma and V delta-N-D delta-N-J delta-C delta segments amplified from brain tissues, CSF and spleens of two MS patients and from the spleen of two control subjects. The sequence analysis obtained so far shows no compelling evidence of an MS specific expansion of one or more clones expressing particular types of gamma delta T cell receptors. In contrast, a clonal expansion of a different population of TCR gamma delta-bearing T cells was found in the spleen of both an MS patient and one of the control individuals.(ABSTRACT TRUNCATED AT 400 WORDS)

Nucleotide deletion of T cell receptor V gamma 2 and J gamma 2 coding sequences at V gamma 2-J gamma 2 junctions in immature B cell lines

Immature B cell lines transformed with a temperature-sensitive mutant of Abelson murine leukaemia virus undergo preferentially V gamma 2 to J gamma 2 joinings during culture at a non-permissive temperature (39 degrees C). Here we examined nucleotide addition and deletion at the V gamma 2-J gamma 2 junctions in these V gamma 2 to J gamma 2 joinings, in comparison with the V gamma 2-J gamma 2 junctional sequences reported previously in T cells. Forty-eight V gamma 2-J gamma 2 junctions were PCR-amplified and sequenced. Only three of 48 V gamma 2-J gamma 2 junctions had nucleotide addition. The average nucleotide deletion of V gamma 2 coding sequences at the V gamma 2-J gamma 2 junctions was 6.9 nucleotides in immature B cells and 5.1 nucleotides in T cells (p less than 0.05). Also, the average nucleotide deletion of J gamma 2 coding sequences at the V gamma 2-J gamma 2 junctions was 3.1 nucleotides in immature B cells and 1.9 nucleotides in T cells (p less than 0.01). The average of total number of the deleted nucleotides at the V gamma 2-J gamma 2 junctions was 10.0 nucleotides in immature B cells and 7.0 nucleotides in T cells (p less than 0.01). No correlation was found between the extent of the nucleotide deletion of the V gamma 2 coding sequence and that of the J gamma 2 coding sequence at each V gamma 2-J gamma 2 junction in immature B and T cells. These results demonstrated that nucleotide deletion at the V gamma 2-J gamma 2 junctions was significantly wider in immature B cells than in T cells.

Gamma delta T cells and the immune response in visceral leishmaniasis

Visceral leishmaniasis (VL) caused by Leishmania donovani, a protozoan parasite, is a disease of high morbidity associated with hepatosplenomegaly, hypergammaglobulinemia, fever and death. One of the immunological hallmarks of VL is a remarkable increase in serum immunoglobulin levels as a result of polyclonal B cell activation. This study demonstrated that T lymphocytes expressing the T cell receptors (TcR) gamma delta in association with CD3 molecules are increased in circulation of patients with VL. A large proportions of TcR gamma delta-bearing T cells had CD4+ CD8- phenotype, and expressed CD25, CD38, CD71 and HLA-DR activation antigens. Furthermore, we demonstrated wide functional differences in TcR gamma delta and TcR alpha beta T cells in their proliferative response, secretion of interleukin-2 (IL-2), B cell growth factor (BCGF) and B cell differentiation factor (BCDF). It was of interest that the TcR gamma delta T cells from patients with VL could be expanded by in vitro culture with human recombinant IL-2. Although these TcR gamma delta T cells secreted diminished levels of IL-2, they produced highly augmented levels of both BCGF and BCDF, suggesting that secretion of these lymphokines in these T cell subsets is regulated independently. The relative increases in the CD4+ CDw29+ TcR gamma delta T cell subsets and their secretion of highly elevated levels of BCGF and BCDF largely accounted for the humoral immune system abnormality and hypergammaglobulinemia found in this disease. These observations may help to explain that TcR gamma delta T cells might be functional in vivo and are involved in immunological mechanisms of pathogenesis in VL.

Rearrangement and junctional-site sequence analyses of T-cell receptor gamma genes in intestinal intraepithelial lymphocytes from murine athymic chimeras

The molecular organization of rearranged T-cell receptor (TCR) gamma genes intraepithelial lymphocytes (IEL) was studied in athymic radiation chimeras and was compared with the organization of gamma gene rearrangements in IEL from thymus-bearing animals by polymerase chain reaction and by sequence analyses of DNA spanning the junction of the variable (V) and joining (J) genes. In both thymus-bearing mice and athymic chimeras, IEL V-J gamma-gene rearrangements occurred for V gamma 1.2, V gamma 2, and V gamma 5 but not for V gamma 3 or V gamma 4. Sequence analyses of cloned V-J polymerase chain reaction-amplified products indicated that in both thymus-bearing mice and athymic chimeras, rearrangement of V gamma 1.2 and V gamma 5 resulted in in-frame as well as out-of-frame genes, whereas nearly all V gamma 2 rearrangements were out of frame from either type of animal. V-segment nucleotide removal occurred in most V gamma 1.2, V gamma 2, and V gamma 5 rearrangements; J-segment nucleotide removal was common in V gamma 1.2 but not in V gamma 2 or V gamma 5 rearrangements. N-segment nucleotide insertions were present in V gamma 1.2, V gamma 2, and V gamma 5 IEL rearrangements in both thymus-bearing mice and athymic chimeras, resulting in a predominant in-frame sequence for V gamma 5 and a predominant out-of-frame sequence for V gamma 2 genes. These findings demonstrate that (i) TCR gamma-gene rearrangement occurs extrathymically in IEL, (ii) rearrangements of TCR gamma genes involve the same V gene regardless of thymus influence; and (iii) the thymus does not determine the degree to which functional or nonfunctional rearrangements occur in IEL.

Rearrangement and junctional-site sequence analyses of T-cell receptor gamma genes in intestinal intraepithelial lymphocytes from murine athymic chimeras

The molecular organization of rearranged T-cell receptor (TCR) gamma genes intraepithelial lymphocytes (IEL) was studied in athymic radiation chimeras and was compared with the organization of gamma gene rearrangements in IEL from thymus-bearing animals by polymerase chain reaction and by sequence analyses of DNA spanning the junction of the variable (V) and joining (J) genes. In both thymus-bearing mice and athymic chimeras, IEL V-J gamma-gene rearrangements occurred for V gamma 1.2, V gamma 2, and V gamma 5 but not for V gamma 3 or V gamma 4. Sequence analyses of cloned V-J polymerase chain reaction-amplified products indicated that in both thymus-bearing mice and athymic chimeras, rearrangement of V gamma 1.2 and V gamma 5 resulted in in-frame as well as out-of-frame genes, whereas nearly all V gamma 2 rearrangements were out of frame from either type of animal. V-segment nucleotide removal occurred in most V gamma 1.2, V gamma 2, and V gamma 5 rearrangements; J-segment nucleotide removal was common in V gamma 1.2 but not in V gamma 2 or V gamma 5 rearrangements. N-segment nucleotide insertions were present in V gamma 1.2, V gamma 2, and V gamma 5 IEL rearrangements in both thymus-bearing mice and athymic chimeras, resulting in a predominant in-frame sequence for V gamma 5 and a predominant out-of-frame sequence for V gamma 2 genes. These findings demonstrate that (i) TCR gamma-gene rearrangement occurs extrathymically in IEL, (ii) rearrangements of TCR gamma genes involve the same V gene regardless of thymus influence; and (iii) the thymus does not determine the degree to which functional or nonfunctional rearrangements occur in IEL.

Neoplastic epithelial cells express alpha-subunit of muscle nicotinic acetylcholine receptor in thymomas from patients with myasthenia gravis

We studied the expression of mRNAs coding for the alpha-subunit of the muscle nicotinic acetylcholine receptor (AChR) in thymomas from patients with myasthenia gravis (MG). Northern blot analysis failed to detect the expression, but amplification of mRNAs derived from thymomas by reverse transcription and polymerase chain reaction produced the DNA fragments containing the nucleotide sequence coding for part of the alpha-subunit. We further revealed that the alpha-subunit mRNA was derived from neoplastic epithelial cells of thymoma. Our results support the hypothesis that AChR expressed in thymoma is a candidate for the primary antigen which induces autoimmune responses to muscle AChR. The close relationship between MG and thymoma may be at least in part explained by this hypothesis.

Rearrangement patterns of T-cell receptor genes in the spleen of athymic (nu/nu) young mice

Although the athymic nude mouse is grossly deficient in peripheral T cells, the number of lymphocytes bearing T-cell markers (L3T4, LyT2) and the alpha beta or gamma delta T-cell receptor (Tcr) increases steadily with age. The anatomical site(s) where these cells arise are unknown. Splenocytes from 3-5-week-old C57BL/6 (nu/nu) mice contain 2%-5% Pro-T cell progenitors identified with the Joro 37-5 and Joro 75 antibodies, but not mature T cells. To study Tcr gene rearrangement outside the thymus, we fused splenocytes from 3-5-week-old C57BL/6 nude mice with the T-cell lymphoma BW 100.129. Of 22 hybrids that grew stably in culture, four had Tcrd-VD1-D2-J1, two had Tcrd-VD2-J1, and seven had Tcrd-D1-D2 types of rearrangement. Eight hybrids had rearranged the Tcrg-2 gene cluster, but none had rearranged Tcrg-1, -3, or -4. None of the hybrids had rearranged the Tcrb gene cluster and 13 contained DJ rearrangements at the Igh locus. We conclude that the spleen is one of the extrathymic sites where T-cell progenitors can rearranged Tcrd and Tcrg genes. However, there was no evidence for Tcrb gene rearrangements in this organ. Furthermore, the analysis of this limited number of hybrids suggests that extrathymic Tcr gene rearrangements seem to be distinct and much less diverse than those found in the developing thymocytes.

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.

Activation of the immune system in the testis

The present concept for the mechanism of prolonged transplant survival in the testis suggests that lymphocyte activation is inhibited locally in this site by testicular products. As the testis produces several immunoregulatory factors, the behaviour of lymphocytes in the testis may depend on the net effect of all these factors on intralymphocytic events. In the present article, the extra- and intracellular events associated with lymphocyte activation are reviewed and the steps of lymphocyte activation which might be subject to interference by testicular factors are identified.

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.

T-cell receptor gamma delta and gamma transgenic mice suggest a role of a gamma gene silencer in the generation of alpha beta T cells

A T lymphocyte expresses on its surface one of two types of antigen receptor, T-cell receptor alpha beta or T-cell receptor gamma delta, encoded by a pair of somatically rearranged alpha and beta or gamma and delta genes. It has been suggested that alpha beta T cells are generated only from precursor T cells that failed to rearrange gamma and delta genes in a functional form. However, we found that transgenic mice constructed with functionally rearranged gamma and delta genes produce a normal number of alpha beta T cells. The transgene gamma present in these alpha beta T cells is repressed apparently through an associated cis DNA element (silencer). We propose that some T-cell precursors are committed to generate alpha beta T cells independent of the rearrangement status of their gamma gene and that this commitment involves activation of a factor(s) that interacts with the gamma gene-associated silencer.

Blockage of alpha beta T-cell development by TCR gamma delta transgenes

T lymphocytes recognize antigens by means of T-cell receptors (TCR) composed of alpha beta or gamma delta heterodimers. The mechanism governing the development of alpha beta- and gamma delta-bearing T cells from a common precursor T cell is so far unknown. It has been proposed that T-cell precursors rearrange their gamma- and delta-chain genes first, and alpha beta T cells are generated only from those cells that fail to rearrange productively both gamma- and delta-chain genes. Our recent study on gamma delta-transgenic mice contradicted this hypothesis, however, and indicated that repression of gamma-chain gene expression mediated by a transcriptional silencer element has a critical role in the generation of alpha beta T cells. Here we report that the generation of alpha beta T cells is severely blocked in transgenic mice carrying gamma- and delta-chain transgenes without the associated silencer, thereby strengthening the validity of the silencer model of T-cell development.

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.

T cell function and expression are dramatically altered in T cell receptor V gamma 1.1J gamma 4C gamma 4 transgenic mice

We have characterized transgenic mice carrying a functional T cell receptor (TCR) C gamma 4 (V gamma 1.1J gamma 4C gamma 4) gene. Results indicate that active transcription of the C gamma 4 transgene can influence expression of the endogenous C gamma 4, C gamma 1 (V gamma 3-, V gamma 4-, V gamma 2-, or V gamma 5J gamma 1C gamma 1) and C gamma 2 (V gamma 1.2J gamma 2C gamma 2) genes, while the ultimate expression of other TCR delta, alpha, and beta chain genes, as well as the adult T cell response, are relatively unaltered. Cells expressing transgenic C gamma 4 and endogenous delta TCR transcripts can migrate to the skin as dendritic epithelial cells (DEC) even though C gamma 4 cells are rarely, if at all, found in the skin. Transgenic and control mice were compared at 2 weeks, 6-7 weeks, and older. At 2 weeks, the thymus of transgenic mice, particularly the medulla, was much larger than control. Moreover, peripheral lymphoid tissues of younger mice were markedly (as much as 100-fold) more immunoreactive (both Con A response and alloreactivity). These differences, although persistent, became smaller in older mice. The data suggest that transgene expression has a major effect on T cell development and reactivity.

T-cell receptor delta-chain diversity in peripheral lymphocytes

A small percentage (approximately 5%) of the cells in the adult thymus expresses a heterodimeric receptor, gamma delta, that exhibits extensive clonal diversity. The specificity and function of these cells are unclear. Furthermore, it is not known if their role in the immune system is primarily one that operates within the thymus during the selection of the T-cell repertoire or if they function primarily in an antigen-recognition capacity in the peripheral lymphoid system. To examine if gamma delta+ T cells in the periphery are as diverse as those in the thymus, we used the polymerase chain reaction to amplify delta-chain transcripts from polyclonal populations of thymic and splenic lymphocytes (the latter were derived from allogeneic mixed lymphocyte cultures). The nucleotide sequences of delta chains from the spleen, like those from the thymus, were all different. Most of the diversity was present in the region between the variable (V) and joining (J) gene segments and was generated through the use of the two known diversity (D) elements, D delta 1 and D delta 2, and by the addition or deletion of bases at the V delta D delta 1, D delta 1D delta 2, and D delta 2J delta junctions. The extensive gamma delta repertoire among peripheral cells suggests that they have the potential to recognize an array of ligands that could be as diverse as those recognized by alpha beta+ cells. The amplification strategy described here can be used to analyze rapidly the diversity exhibited by any of the members of the immunoglobulin-like gene families that undergo rearrangement.

Molecular analysis of T cell receptor gamma gene expression in allo-activated splenic T cells of adult mice

Northern analysis, hybridization in situ and cDNA sequence analysis have been used to demonstrate that the induction of T cell gamma-gene expression is a general occurrence when primary splenic T cells of adult mice are cultured in short-term mixed lymphocyte reactions (MLR). Splenic T cells from nine strains of mice examined in eleven different MLR all showed significant induction of gamma-RNA, even when the primary T cell response was to only a three amino acid mismatch in a major histocompatibility complex class I antigen. In MLR examined in detail, the expression is highly enriched for in CD3+ "double-negative" T cells (lacking both CD4 and CD8 expression). A cDNA sequence analysis, constituting the first such analysis of any size of gamma-gene transcripts from circulating, peripheral cells of adult mice, revealed transcription to be frequently of productively rearranged genes. These genes display extensive junctional diversity.

Predominant variable region gene usage by gamma/delta T cell receptor-bearing cells in the adult thymus

Previous studies have indicated that the diversity of gamma genes expressed by gamma/delta-bearing murine T cells is limited, but comparable information concerning the expressed diversity of delta genes is lacking. In this study, we have investigated the rearrangement and expression of delta and gamma genes in T cell hybridomas that express gamma/delta T cell receptors. Three productive delta chain cDNA clones were isolated (delta 7.3, delta 7.1, and delta 2.3) that encode new variable region sequences. Two of the delta cDNAs differ significantly from those observed in the V alpha repertoire. In addition, one cDNA expressed a new J delta region (J delta 2), which was localized between J delta 1 and C delta genes. Using these and other delta gene probes and gamma gene probes, we found that five independent hybridomas expressed four different V delta s and three different V gamma s. However, analysis of an enriched population of gamma/delta-expressing cells from the adult thymus suggests that only a few V delta genes and one V gamma gene are used by the majority of the cells. These results suggest that important components of receptor chain that contribute to specificity (i.e., the germline V gene sequences) are relatively nondiverse in the thymic gamma/delta population.

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.

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.

"Radioresistant" intrathymic T cell precursors express T cell receptor C gamma 4- and C delta-specific gene messages

We have studied the expression and sequences of T cell receptor gamma and delta chain gene messages in intrathymic T cell precursors of mice irradiated with 600 rads. On day 7 after irradiation a high level of expression of gamma and delta chain messages was detected in thymocytes which were composed of a relatively high proportion of CD3+CD4-CD8- thymocytes. During further development of the precursors from day 7 to day 14 after irradiation, gamma and delta chain messages fell to low levels and alpha and beta mRNA levels increased. Nucleotide sequence analysis of 14 gamma and 10 delta chain complementary DNA (cDNA) in the thymocytes on day 7 revealed that there were 7 functional gamma chain transcripts composed of V gamma 2-J gamma 2-C gamma 2 or V gamma 1-J gamma 4-C gamma 4 gene segments, and only 1 functional delta chain transcript composed of the V delta M23-D delta 1-D delta 2-J delta 1-C delta gene segments. The repertoire of gamma chain and delta chain genes used in "radioresistant" intrathymic T cell precursors of adult mice appears to be limited.

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.

Calcium ion concentrations and DNA fragmentation in target cell destruction by murine cloned cytotoxic T lymphocytes

To investigate the destruction of target cells by murine CTLs, we examined intracellular Ca2+ concentrations ([Ca2+]i) and DNA fragmentation in target cells. Changes in [Ca2+]i were followed by flow cytometry by loading the cells with indo-1, a Ca2+-binding fluorescent dye, and determining the ration of fluorescence intensities at 405 nm (emission maximum for Ca2+-bound dye) over 480 nm (emission maximum for the free dye). Within minutes after interacting with the cytolytic granule fraction that had been isolated from CTLs, [Ca2+]i in target cells was strikingly increased. A pronounced increase in [Ca2+]i was also observed in target cells when they were specifically recognized by intact CTLs. Since ionomycin, a Ca2+ ionophore, caused a similar increase in [Ca2+]i and lysed cells (provided that extracellular Ca2+ was present), it appears that a sustained high level of [Ca2+]i is cytolytic. In contrast with other cells, CTLs, which have been shown to be refractory to granule-mediated lysis and to be poor targets for other CTLs, did not manifest an elevation in [Ca2+]i when they were similarly loaded with indo-1 and treated with isolated granules. The characteristic cleavage of target cell DNA into nucleosome-sized fragments was also induced by isolated granules as well as by valinomycin, a K+ ionophore, but not by ionomycin. The results support the view that lysis of most target cells by cloned CTLs is due primarily to target cell membrane changes that are fundamentally equivalent to the formation of nonspecific ion channels. The resulting large increase in [Ca2+]i is probably responsible for target cell lysis; and changes in intracellular ion concentrations also appear to be responsible for DNA fragmentation, probably by activating endogenous target cell endonucleases.

Two types of gamma T cell receptors expressed by T cell acute lymphoblastic leukemias

CD3+ cells, isolated from peripheral blood of two patients with T cell acute lymphoblastic leukemia (T-ALL), did not react with the monoclonal antibody WT31, which is thought to recognize a framework determinant on the conventional T cell receptor (TcR), consisting of disulfide-linked alpha and beta chains. The T-ALL cells of neither patient synthesized TcR alpha mRNA; the cells of patient DD contained only truncated (D-J) TcR beta mRNA, while the cells of patient HZ contained truncated as well as mature (V-D-J) TcR beta mRNA. The leukemic cells of both patients made TcR gamma mRNA. At the cell surface, the T-ALL cells of patient DD expressed a CD3-associated disulfide-linked dimer, which contained the TcR gamma protein. On the leukemic cells of patient HZ the TcR gamma protein was present as a 41-44-kDa CD3-associated subunit in a noncovalently linked form. The TcR gamma genes in the T-ALL cells of patient DD were rearranged exclusively to the C gamma 1 locus, while in the T-ALL cells of patient HZ both C gamma 1 alleles were deleted and rearrangement to the C gamma 2 locus had occurred. The C gamma 1 gene segment, just like the TcR alpha and TcR beta gene segments, contains a cysteine codon in its second exon. This cysteine residue is involved in the formation of the interchain disulfide bond. The human C gamma 2 gene segment, however, does not contain a cysteine codon in its second exon. The absence of the cysteine residue in C gamma 2 encoded TcR gamma chains explains the lack of an interchain disulfide bond in the TcR on the T-ALL cells of patient HZ. The TcR gene configuration, as well as the expression of model for T cell differentiation in which the TcR gamma gene rearranges first to the C gamma 1 locus prior to or coinciding with D-J joining of the TcR beta gene, followed by rearrangement to the C gamma 2 locus and V-D-J joining of the TcR beta gene.

The gamma T-cell antigen receptor

The gamma-TCR is encoded by genes composed of V, J, and C elements that demonstrate a limited potential for recombinational diversity. These genes are rearranged, transcribed, and translated into proteins early during thymic ontogeny. Lymphocytes express gamma-TCR proteins on the plasma membrane only in association with the CD3 complex. gamma-TCR glycoproteins usually associate with another non-gamma glycoprotein, designated delta-TCR, to form a heterodimer receptor. Both non-disulfide-bonded and disulfide-bonded gamma/delta-TCR heterodimers have been identified on the plasma membrane of human T lymphocytes. On certain gamma-TCR-bearing T cell lines, a delta-TCR protein cannot be visualized by autoradiography. It is possible that delta-TCR proteins are associated with gamma-TCR glycoproteins on these cell lines but are not efficiently radiolabeled. Alternatively, it has been suggested that homodimers of gamma-TCR proteins can assemble with CD3 and be expressed on the plasma membrane of these cells. In adult lymphoid tissues, the majority of T lymphocytes expresses a CD3, alpha/beta antigen receptor, whereas only a minor subset (less than 5% of peripheral blood lymphocytes, lymph node, spleen, and thymocytes) express a CD3, gamma/delta antigen receptor. IL-2-dependent cell lines of both murine and human CD3, gamma/delta T cells have been established. Most CD3, gamma/delta T cell lines mediate cytotoxicity against a broad spectrum of tumor-cell targets, although the functional significance of this observation remains unclear. Cytotoxicity is apparently not restricted by or directed against MHC antigens. Antibodies against CD3 or gamma-TCR can induce proliferation and IL-2 secretion and can either augment or inhibit cytotoxicity, demonstrating that the gamma/delta-TCR is a functional receptor. The ligand recognized by this receptor has not been identified. The physiological role of T lymphocytes expressing gamma/delta-TCR, the molecular and structural properties of delta-TCR, and the relationship between CD3, alpha/beta T lymphocytes and CD3, gamma/delta T lymphocytes are the major unresolved questions that will be the primary focus of further experimentation.

T-cell gamma gene is allelically but not isotypically excluded and is not required in known functional T-cell subsets

The T-cell gamma genes, structurally related to immunoglobulin genes and the T-cell antigen-receptor alpha- and beta-chain genes, undergo somatic rearrangement in T-lineage cells. However, the role of the T-cell gamma genes has not yet been determined. To determine the potential for gamma gene expression in a set of well-characterized, cloned T-cell lines, we cloned all of the rearranged gamma genes from each cell line. The genes were sequenced to determine if the junction of the variable and joining regions maintained the proper translational reading frame. We then attempted to correlate the presence of an in-frame gamma gene with a T-cell subset. We were unable to establish such a correlation. We found evidence, however, that allelic exclusion influences the rearrangement of the gamma gene. This is consistent with the idea that the gamma gene product participates in establishing a clonally diverse population of T cells recognizing a polymorphic ligand. Isotypic exclusion does not apply to the gamma gene, however, suggesting different roles for the different gamma gene isotypes.

Resistance of cytotoxic T lymphocytes to the lytic effects of their toxic granules

A cytotoxic T lymphocyte (CTL) characteristically kills target cells one after the other by releasing toxic granules that contain one or more cytolytic components. To determine how CTLs avoid destroying themselves when they release granules and lyse target cells, 7 murine CD8+ CTL cell lines were compared with 19 other cell lines for susceptibility to lysis by the isolated toxic granules. Murine CD8+ CTLs were clearly the most resistant cells: granules did not lyse them even after they were exposed to azide, cyanide, and 2-deoxyglucose, conditions that were found to enhance the susceptibility of all the other cells tested, including other T cells. Thus, resistance of CD8+ CTLs to cytotoxic granules appears to be independent of cellular ATP. To reconcile these findings with other observations that, under some circumstances, CTLs can be lysed by other CTLs, we suggest a model in which a CTL releases only a limited proportion of its toxic granules at each antigen-specific encounter with a target cell; the amount released is sufficient to kill most target cells but to leave the CTL undamaged and with enough granules to attack other target cells.

T-cell receptors of human suppressor cells

Cells which can suppress the immune response to an antigen (TS cells) appear to be essential for regulation of the immune system. But the characterization of the TS lineage has not been extensive and many are sceptical of studies using uncloned or hybrid T-cell lines. The nature of the antigen receptor on these cells is unclear. T cells of the helper or cytotoxic lineages appear to recognize their targets using the T-cell receptor (TCR) alpha beta-CD3 complex. TCR beta-gene rearrangements are also found in some murine and human suppressor cell lines but others have been shown not to rearrange or express the beta-chain or alpha-chain genes. We previously established TS clones derived from lepromatous leprosy patients which carry the CD8 antigen and recognize antigen in the context of the major histocompatibility complex (MHC) class II molecules in vitro. We here report the characterization of additional MHC-restricted TS clones which rearrange TCR beta genes, express messenger RNA for the alpha and beta chains of the TCR and express clonally unique CD3-associated TCR alpha beta structures on their cell surface but do not express the gamma chain of the gamma delta TCR on the cell surface. We conclude that antigen recognition by at least some human CD8+ suppressor cells is likely to be mediated by TCR alpha beta heterodimers.

Characterization of Lyt-2-, L3T4- class I-specific cytolytic clones in C3H-gld/gld mice. Implications for functions of accessory molecules and programmed development

We report the first demonstration of Thy-1+, Lyt-2-, L3T4- MHC-specific CTL clones derived from the Lyt-2-, L3T4- subset of lymph node cells of C3H-gld/gld mice. These clones express alpha/beta heterodimeric TCRs on the cell surface and specifically recognize class I molecules on target cells. Lyt-2 and L3T4 molecules are therefore not essential for the induction, recognition, and killing of antigen-specific CTL. In addition, these studies suggest that antigen specificity development for class I structures may occur before Lyt-2 gene activation in the differentiation of T cells.

Expression of the T-cell receptor gamma-chain gene products on the surface of peripheral T cells and T-cell blasts generated by allogeneic mixed lymphocyte reaction

The gamma-chain genes of the T-cell receptors form a family of related genes that are specifically expressed and somatically rearranged in T cells. Using poly- and monoclonal anti-gamma antibodies, we studied the cell-surface expression of the gamma-chain gene products in mouse peripheral T cells as well as in the T-cell blasts generated by allogeneic mixed lymphocyte reactions. The gamma chains are expressed in the Lyt2-,L3T4- subsets of these T-cell populations as disulfide-linked heterodimers. Whereas the electrophoretic mobility and the N-glycosylation of the spleen and lymph-node gamma chains are indistinguishable from those of the reported thymocyte gamma chain, a minor fraction of the T blasts generated by allogeneic stimulation of B10 lymph-node T cells with B10.BR spleen cells seems to express gamma chains with distinct properties. This suggests that the mixed lymphocyte culture conditions exert a selective effect on the expression of gamma chains among peripheral T-cell populations.

A new T-cell receptor gene located within the alpha locus and expressed early in T-cell differentiation

A new T-cell receptor gene lies just 5' to the J alpha C alpha coding regions. Its placement in this location suggests a novel mechanism for the regulation of expression of one T-cell receptor polypeptide to another during ontogeny. Rearrangement of this locus occurs very early in thymic differentiation and its RNA expression parallels that of the gamma-chain in thymic subpopulations, making this a possible candidate for the recently described delta-chain of the T-cell receptor.

Identification of a second T-cell antigen receptor in human and mouse by an anti-peptide gamma-chain-specific monoclonal antibody

We developed a monoclonal antibody (mAb) (9D7) against a synthetic peptide (P13K) selected from the deduced amino acid sequence of the constant region of the gamma chain of the murine T-cell antigen receptor (TCR) (amino acids 118-130). Using this mAb, we identified a putative second TCR expressed on peripheral blood lymphocytes from a patient with severe combined immunodeficiency (SCID) that were propagated in culture with recombinant interleukin 2 (rIL-2) and Con A. This mAb immunoprecipitated two polypeptide chains of 40 and 58 kDa under nonreducing conditions and of 40 and 56 kDa under reducing conditions from 125I-labeled denatured lysates of T3+ WT31- lymphocytes expanded in culture from a SCID patient. These polypeptide chains were not disulfide linked and were not present on human peripheral blood lymphocytes from normal donors cultured for 5 days with phytohemagglutinin or for 2 weeks with rIL-2 and polyclonal activators or on cells of the Jurkat lymphoblastoid human T-cell line. Chemical crosslinking of 125I-labeled cells followed by immunoprecipitation with anti-Leu-4 mAb under nonreducing or reducing conditions revealed that the 40- and 56-kDa polypeptide chains were associated with the T3 differentiation antigen. These results were confirmed by sequential immunoprecipitation with anti-Leu-4 mAb followed by 9D7 anti-P13K mAb. The 9D7 anti-P13K mAb immunoprecipitated two polypeptide chains of 43 and 64 kDa from denatured lysates of lymphocytes from a patient with severe common variable immunodeficiency (CVI) that were expanded in culture with rIL-2 and Con A. Thus, this second TCR may be composed of two polypeptide chains (gamma gamma'), both of which appear to be the product of the gamma-chain gene. These experiments were done with polyclonal cell populations. Cloned T3+ WT31- cell populations are required to determine whether this TCR contains two gamma polypeptide chains. In contrast, only one polypeptide chain of 56 kDa was immunoprecipitated by the 9D7 anti-P13K mAb from peripheral blood lymphocytes from a patient with mild CVI expanded in culture with rIL-2 and polyclonal activators. Using the same 9D7 anti-P13K mAb and immunoblotting analysis, we identified a 35 kDa gamma-chain polypeptide under reducing conditions expressed on purified L3T4- Lyt2- BALB/c mouse thymocytes. This gamma-chain TCR is disulfide linked and has a molecular mass of 80 kDa under nonreducing conditions.

Resistance of cytotoxic T lymphocytes to lysis by a clone of cytotoxic T lymphocytes

To investigate how cytotoxic T lymphocytes (CTL) avoid killing themselves when they destroy target cells, we compared 20 different cell lines as target cells, including several CTL cell lines, for their susceptibility to lysis by CTL. Variations in recognition of this diverse set of target cells was circumvented by attaching to all of them a monoclonal antibody to the antigen-specific receptor of a cloned CTL cell line (clone 2C) and using the 2C cell line as the standard aggressor or effector cell. All of the nine tumor cell lines and the four noncytolytic T-helper cell lines tested as targets were highly susceptible to lysis by the aggressor CTL, but seven cytotoxic T-cell lines (six CTL and one T-helper cell line with cytotoxic activity) were largely resistant. These results, and the use of the lectin Con A as an alternative means for triggering CTL activity, point clearly to a level of resistance that could enable CTL to avoid their own destruction when they lyse target cells. The resistance of the cytolytic T cells did not appear to be accompanied by a similar resistance to complement-mediated lysis, indicating that mechanisms of CTL-mediated and complement-mediated lysis are not identical.