Diversity of murine gamma genes and expression in fetal and adult T lymphocytes

Ordered rearrangement of variable region genes of the T cell receptor gamma locus correlates with transcription of the unrearranged genes

T cell receptor V gamma genes rearrange to the J gamma 1 gene segment in a highly ordered fashion during development. We demonstrate a striking correlation between the pattern of expression of unrearranged V gamma genes and the timing of their rearrangement. Thus, the increases in V gamma 2 rearrangements, and decreases in V gamma 3 and V gamma 4 rearrangements observed during development are paralleled by increasing or decreasing levels of the corresponding unrearranged V gene transcript. We also provide evidence that both the V gamma 3 and V gamma 4 genes are accessible in mature V gamma 3+ cells, but that the V gamma 4 gene may be inaccessible in the progenitors of V gamma 3 cells. The results suggest that regulated local accessibility of the chromatin surrounding V gamma genes is responsible for ordered V gamma gene rearrangement during development.

A case of cutaneous T-cell lymphoma expressing gamma delta T-cell receptors

Cutaneous T-cell lymphoma expressing gamma delta T-cell receptors (TCRs) is rare; only a few cases have been reported. We report another case of the disease that had a fatal outcome and differs from two previously reported cases in its clinical, histologic, and immunohistochemical aspects. The patient had multiple skin tumors with central crusts; she showed no response to chemotherapy and died within 1 year. Histologic findings included perivascular infiltrates in the dermis and subcutaneous tissue with no epidermotropism; the large lymphoid cells had a phenotype of CD1-, CD3+, CD4-, CD8-, CD25-/+, CD30-, CD38-/+, HLA-DR+, and gamma delta TCR (beta F1-, TCR delta 1+, delta TCS1-, Ti gamma A+, BB3-). The differences in the phenotype of gamma delta T-cell malignancies may reflect the uniqueness of its clinical and histologic features. A study of gamma delta T-cell malignancies may disclose important biologic features of gamma delta TCR+ cells.

Gamma delta T-cell receptor-positive cells in human skin. I. Incidence and V-region gene expression in granulomatous skin lesions

BACKGROUND

There have been many reports that gamma delta T-cell receptor (TCR)+ cells respond to mycobacterial antigens in vitro, but there is little available information on human gamma delta TCR+ cells in clinical conditions.

OBJECTIVE

Our purpose was to investigate the distribution and involvement of human gamma delta TCR+ cells in granulomatous skin lesions.

METHODS

The incidence and V-region gene expression of human gamma delta TCR+ cells was examined in granulomatous skin diseases, including cutaneous tuberculosis and leprosy, by immunohistochemical procedures.

RESULTS

gamma delta TCR+ cells in the dermis were increased in most patients with borderline lepromatous leprosy, and they were less frequently found in lepromatous leprosy and erythema nodosum leprosum. Other granulomatous skin lesions, including sarcoidosis, contained only a few gamma delta TCR+ cells. The gamma delta TCR+ cells that were found to be increased in this study were mostly delta TCS1-, BB3+, Ti gamma A+ (V delta 1-, V delta 2+, V gamma 9+).

CONCLUSION

The gamma delta TCR+ cells in human granulomatous skin lesions may respond to some mycobacterial antigens, but they do not appear to be directly involved in granuloma formation.

New T-cell receptor gamma haplotypes in wild mice and evidence for limited Tcrg-V gene polymorphism

Tcrg gene polymorphism was investigated by Southern blot analysis on a panel of laboratory and wild mouse strains using a set of probes which identify all known Tcrg-V and -C genes. Only three haplotypes are found in laboratory mice: gA, gB, and gC which are represented by BALB/c, AKR, and DBA/2 prototypes respectively. gA and gC haplotypes are the most frequent among laboratory mice whereas gB is poorly represented. Seven new haplotypes are described among 23 wild mice corresponding to four Mus musculus subspecies (Mus mus domesticus, castaneus, musculus, and molossinus). However, only a few new alleles of individual genes are observed. Tcrg-V genes located at the 5' end of the Tcrg locus (V7 and V4) appear to be nonpolymorphic whereas two Tcrg-V3, -V5, -V6, -C4 and three Tcrg-V1, -V2, -C1, -C2, and -C3 specific restriction fragment length polymorphisms are detected. These results indicate a relatively high degree of conservation of Tcrg genes as compared to other members of the immunoglogulin (Ig) gene family and might be related to the specifity and function of gamma delta T cells. Several of the new haplotypes described here result from point mutations in noncoding Tcrg-V or -C gene-flanking regions. Recombinations may have also participated in the evolution of the Tcrg locus. Finally, these new Tcrg haplotypes are unequally distributed among the four M. m. subspecies and support the idea that the gA and gC haplotypes found in laboratory mice are inherited from M. m. domesticus whereas gB might originate from asian subspecies (castaneus, musculus or molossinus).

T cell receptor rearrangements in various S49 lymphoma sublines

The S49 cell lines are a unique series of tumor sublines isolated from a single BALB/c thymoma. Several different sublines were previously isolated from non-mutagenized cells using pharmacologic agents that would select for different stages of thymic development. In this report we show that all seven of the sublines studied express TL class I Ag confirming their derivation from immature thymocytes. This uniform TL expression is in contrast to the previously characterized locus-specific shut off of Kd,Dd, and/or LdAg by various S49 sublines. Furthermore, S49 sublines were found to display disparate CD4/CD8 expression. Whereas the unselected subline is a CD4+/CD8+ double positive, each of the selected sublines is singly positive for either CD4 or CD8. All seven sublines were found to be CD3+ and express alpha beta TCR heterodimers. To establish whether the S49 sublines have a monoclonal or polyclonal origin, their TCR rearrangements were compared. Based on the detection of identical but unusual TCR gamma rearrangements and similarity of the alpha and beta rearrangements, we propose that the S49 sublines probably had a monoclonal origin. However, significant differences between the TCR alpha and beta gene rearrangement were observed, suggesting that these sublines have undergone further differentiation at TCR loci in addition to CD4/CD8 and MHC loci. Evidence is presented that much of this phenotypic diversity preceded their in vitro selection.

Expression and biological activity of interleukin-1 receptors in mouse gamma/delta thymocytes during ontogeny

We have recently shown that the response of mouse thymocytes to interleukin (IL)-1 + IL-2 was maximal at birth and that the responding cells displayed a CD4-CD8- T cell receptor (TcR) gamma/delta + phenotype. Unexpectedly, despite their high proportion of gamma/delta + cells, fetal thymocyte populations responded only weakly to IL-1 + IL-2. In this report, we demonstrate that the discrepancy between the day 17.5 fetal and newborn sensitivities to the combined action of IL-1 and IL-2 is a consequence of the different patterns of high-affinity IL-1 receptor (IL-1R) expression displayed by these two cell subsets. Actually, high- and low-affinity IL-1R are found in TcR gamma/delta + newborn cells and, in contrast, only low-affinity IL-1R are detectable in day 17.5 fetal cells. Our binding and functional studies strongly support the hypothesis that high-affinity IL-1R on the one hand, and low-affinity ones on the other hand, are involved in the response to IL-1 + IL-2 of newborn and day 17.5 fetal thymocytes, respectively. In addition, the high-affinity IL-1R appear to be far more efficient than the low-affinity receptors in promoting IL-2 responsiveness of thymocytes.

Expression and role of interleukin-2 receptor beta chain on CD4-CD8- T cell receptor alpha beta+ cells [corrected]

Using anti-murine interleukin-2 receptor beta chain (IL-2R beta) monoclonal antibody (mAb), we have examined the expression of IL-2R beta on murine thymocyte subpopulations. We found that it was constitutively expressed on 1%-4% of thymocytes in an almost mutually exclusive fashion with IL-2R alpha. The expression of IL-2R beta is developmentally regulated. While it is expressed mainly on T cell receptor gamma delta+ (TcR gamma delta+) cells during fetal age, the major subpopulation expressing IL-2R beta in adult mouse shifts to CD4-CD8-TcR alpha beta+ thymocytes. A considerable portion of CD4-CD8- TcR alpha beta+ cells in other organs, including spleen, bone marrow and liver, was also found to express IL-2R beta. In fetal thymus organ culture, the above thymocyte subset was induced to expand in response to exogeneous IL-2, and the expansion was inhibited by addition of anti-IL-2R beta mAb, suggesting that IL-2R beta is functional in this subpopulation. However, in vivo blockade of the IL-2/IL-2R pathway with the mAb did not exert any effects on the appearance of CD4-CD8- TcR alpha beta+ cells both in the thymus and the periphery. This indicates that the development of CD4-CD8- TcR alpha beta+ cells is not solely controlled by IL-2 but also by other complex elements.

Induction of gamma/delta T cells in murine salmonellosis by an avirulent but not by a virulent strain of Salmonella choleraesuis

To elucidate the relationship between the virulence of intracellular bacterium and its ability to induce gamma/delta T cells in the host during infection, we examined the differences in appearance of gamma/delta T cells in mice infected with Salmonella choleraesuis virulent strain RF-1 carrying a virulence plasmid of 50 kb, and with avirulent strain 31N-1 cured of the 50-kb plasmid. The number of gamma/delta T cells in the peritoneal cavity was increased to a significant level on day 3 after an intraperitoneal infection with a sublethal dose (5 x 10(4) colony-forming units) of avirulent strain 31N-1. On the other hand, no increase in the number of gamma/delta T cells was evident in the peritoneal cavity at any stage after infections with various doses of virulent strain RF-1, although the numbers of the bacteria were drastically increased. Similar to that seen in the peritoneal cavity, the number of gamma/delta T cells in the liver was significantly increased after an intraperitoneal infection with avirulent strain 31N-1 but not with virulent strain RF-1. The early appearing gamma/delta T cells during salmonellosis with avirulent stain 31N-1, which preferentially used V gamma 1/V delta 6, showed blastogenesis in response to purified protein derivative (PPD) derived from Mycobacterium tuberculosis. The gamma/delta T cells also responded to the peritoneal adherent cells in mice infected with avirulent strain 31N-1 6 d previously, which expressed a high level of endogenous heat-shock protein (hsp) homologous to the mycobacterial 65-kD hsp. The expression of the hsp, however, was not prominent in the adherent cells in mice infected with virulent strain RF-1. These results suggest that the gamma/delta T cells specific for PPD may play important roles in host defense against murine salmonellosis, and that the virulence of Salmonella may be inversely correlated with its ability to induce endogenous hsp in the infected macrophages, which in turn stimulate the gamma/delta T cells in the host during salmonellosis.

Development and selection of gamma delta T cells

The gamma delta T-cell population, a subpopulation of T cells formed through cell lineages that are independent of the alpha beta T-cell lineage, consists of multiple subsets with distinct receptor repertoires and homing properties. While the cell sublineage is a critical factor in the determination of homing specificity, both cell sublineage and receptor-dependent selection are instrumental in the determination of the functional repertoire.

The development of functionally responsive T cells

The work reviewed in this article separates T cell development into four phases. First is an expansion phase prior to TCR rearrangement, which appears to be correlated with programming of at least some response genes for inducibility. This phase can occur to some extent outside of the thymus. However, the profound T cell deficit of nude mice indicates that the thymus is by far the most potent site for inducing the expansion per se, even if other sites can induce some response acquisition. Second is a controlled phase of TCR gene rearrangement. The details of the regulatory mechanism that selects particular loci for rearrangement are still not known. It seems that the rearrangement of the TCR gamma loci in the gamma delta lineage may not always take place at a developmental stage strictly equivalent to the rearrangement of TCR beta in the alpha beta lineage, and it is not clear just how early the two lineages diverge. In the TCR alpha beta lineage, however, the final gene rearrangement events are accompanied by rapid proliferation and an interruption in cellular response gene inducibility. The loss of conventional responsiveness is probably caused by alterations at the level of signaling, and may be a manifestation of the physiological state that is a precondition for selection. Third is the complex process of selection. Whereas peripheral T cells can undergo forms of positive selection (by antigen-driven clonal expansion) and negative selection (by abortive stimulation leading to anergy or death), neither is exactly the same phenomenon that occurs in the thymic cortex. Negative selection in the cortex appears to be a suicidal inversion of antigen responsiveness: instead of turning on IL-2 expression, the activated cell destroys its own chromatin. The genes that need to be induced for this response are not yet identified, but it is unquestionably a form of activation. It is interesting that in humans and rats, cortical thymocytes undergoing negative selection can still induce IL-2R alpha expression and even be rescued in vitro, if exogenous IL-2 is provided. Perhaps murine thymocytes are denied this form of rescue because they shut off IL-2R beta chain expression at an earlier stage or because they may be uncommonly Bcl-2 deficient (cf. Sentman et al., 1991; Strasser et al., 1991). Even so, medullary thymocytes remain at least partially susceptible to negative selection even as they continue to mature.(ABSTRACT TRUNCATED AT 400 WORDS)

T-lymphocyte development in scid mice is arrested shortly after the initiation of T-cell receptor delta gene recombination

Scid mice lack functional lymphocytes because they carry a mutation that impairs rearrangement of immunoglobulin and T-cell receptor (TCR) genes. Rearrangement of TCR delta, but not gamma and beta genes, was routinely observed in DNA of scid thymocytes and thymocyte hybridomas. TCR delta gene rearrangements appeared to involve D delta 1, D delta 2, and J delta 1 elements only; rearrangement of elements upstream of D delta 1 (e.g., V delta 1) was not observed, and transcripts corresponding to fully assembled TCR delta genes (VDJ delta or VDDJ delta) were not detected in RNA from scid thymocytes. These findings suggest that D delta 1, D delta 2, and J delta 1 may be among the first TCR gene elements to undergo recombination and that scid T-lineage cells are developmentally arrested during or shortly after this stage of differentiation. One class of TCR delta recombination fragments (D delta 2-J delta 1) was amplified by the polymerase chain reaction (PCR) and cloned, and the recombination junctions were sequenced. Most fragments showed normal coding joints. Interestingly, five of seven coding joints that lacked N insertions showed evidence of recombination between short stretches (2-3 bp) of homologous sequence. As discussed, the general absence of V delta-, J gamma-, and J beta-associated rearrangements, despite the occurrence of normal D delta 2-J delta 1 rearrangements, raises the possibility that the scid mutation may cause premature cessation of TCR gene recombination and thereby arrest early T-cell development.

Thymic targets for Abelson murine leukemia virus are early gamma/delta T lymphocytes

Molecular analysis has shown that the majority of Abelson murine leukemia virus (Ab-MuLV)-induced primary thymomas represent transformed gamma/delta thymocytes. Many of these thymomas are of monoclonal origin as judged by provirus integration pattern and contain rearranged genes encoding T-cell receptor (TCR) gamma and delta chains but germ-line immunoglobulin heavy-chain genes. Some of the monoclonal tumors contain multiple rearranged alleles encoding TCR gamma, delta, and beta chains. Further, one Ab-MuLV thymoma cell line contained germ-line-configuration TCR gamma- and delta-chain genes, which became rearranged after in vitro propagation. Clones of this cell line were observed to rearrange these genes after intrathymic passage. Also, some subclones of this cell line underwent rearrangement of their immunoglobulin heavy-chain genes in culture. These observations suggest that the thymic targets for Ab-MuLV transformation are early gamma/delta thymocytes, some of which continue to rearrange their TCR gamma- and delta-chain genes.

Recognition of MHC TL gene products by gamma delta T cells

We have studied the ligand specificity of a gamma delta T-cell receptor (TCR) derived from a mouse T-cell hybridoma (KN6). KN6 cells reacted with syngeneic (C57BL/6) cells from various origins (splenocytes, thymocytes, peritoneal exudate cells, etc.) and cells from many different mouse strains. KN6 reactivity against cells from a panel of congenic and recombinant mouse strains demonstrated that the ligand recognized by KN6 is controlled by an MHC-linked gene that most probably maps in the TL region. We cloned this gene and formally proved that it does map in the TL region. This gene turned out to be a novel class I gene (designated T22b) belonging to a hitherto unidentified cluster of TL region genes in strain C57BL/6. This gene was expressed in many different tissues and cell types. We also examined the tissue expression of several other TL genes. One of these, the structural gene (T3b) encoding the thymus leukemia (TL) antigen from C57BL/6 mice, was specifically expressed in the epithelium of the small intestine. Since the intestinal epithelium of the mouse is known to be the homing site for a subset of gamma delta T cells (i-IEL) bearing diverse TCR with V7 rearranged gamma chains, we propose that the T3b gene product is part of the ligand recognized by some of the i-IEL. Our data support the idea that gamma delta T cells might be specific for non-classical class I or class I-like molecules and suggest that gamma delta TCR and non-classical MHC co-evolved for the recognition of a conserved set of endogenous or foreign peptides.

Identification of a T-cell-specific enhancer at the locus encoding T-cell antigen receptor gamma chain

The gamma delta and alpha beta T-cell antigen receptor (TCR) heterodimers are expressed in a lineage-specific, mutually exclusive manner. Regulation of expression occurs at the transcriptional level. A 13-kilobase (kb) stretch of DNA encompassing variable-joining-constant segments V gamma 4-J gamma 1-C gamma 1 of the murine gamma-chain gene was examined for the presence of transcriptional enhancing elements by a transient transfection assay. DNA fragments from this region were inserted into a test plasmid containing a heterologous promoter fused to the human growth hormone gene. An 1800-base-pair (bp) fragment located 3 kb 3' to C gamma exon III was found to display enhancing activity in several T-cell lines. Maximum enhancing activity could be localized further to fragments as small as 400 bp in some cell lines. Nucleotide sequence analysis of this 400-bp segment revealed homologies to previously described core enhancer elements and to other TCR gene enhancers. The TCR gamma-chain gene enhancer is active in both gamma delta and alpha beta T cells, indicating that it is not primarily responsible for lineage-specificity of expression, but it is inactive in non-T-cells.

Coding joint formation of endogenous T cell receptor genes in lymphoid cells from scid mice: unusual P-nucleotide additions in VJ-coding joints

The mouse mutation scid adversely affects the process of VDJ recombination. Attempts to form coding joints, that is, to joint V or D to J gene segments generally fail in developing scid lymphocytes. It has been proposed that the scid mutation results a defective VDJ recombinase system. Here we describe five scid T cell lymphomas containing one or two TcR gamma coding joints each, even though the majority of the multiple TcR gamma chain gene rearrangements and all TcR beta rearrangements in these cells were abnormal with the deletions typically found in scid lymphoid cells. One of the five T cell lymphomas was shown to have an active VDJ recombinase system; however, this activity was defective indicating that the scid phenotype has been retained. We conclude that the scid VDJ recombinase system has not completely lost the ability to form coding joints. P-nucleotide additions of unusual length or composition were found at the junctional border in five of the eight TcR gamma coding joints. This might reflect a defect in the activity of a component of the VDJ recombinase system involved in the generation of P-nucleotide additions. In one of the observed rearrangements, a V gamma 5-J gamma 3 coding joint was formed. This establishes the transcriptional orientation of J gamma 3-C gamma 3 and confirms a previously proposed organization of the TcR gamma genes.

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.

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.

Self heat shock and gamma delta T-cell reactivity

We have investigated the effects of heat shock on T-cell induction and selection in vitro. We find that when cell preparations containing T lymphocytes are incubated for 30 min at 42 degrees C, a selective proliferation of gamma delta + T cells bearing the gamma delta T-cell antigen receptor follows. A greater enrichment of gamma delta + T cells is observed, upon preexposure to mycobacterial antigens in vivo. By comparing the effects of heat shock with that of mitogen or specific T-cell triggering by conventional antigens and by analyzing the gamma delta T-cell receptor genes expressed in cells that proliferate as a result of heat shock induction, we conclude that a subset of murine gamma delta T cells react to antigens on self cells in which a heat shock response was induced.

Defective V-to-J recombination of T cell receptor gamma chain genes in scid mice

The status of T cell receptor gamma chain genes (TcR gamma) in 11 spontaneous T cell lymphomas from mice with severe combined immune deficiency (scid) was analyzed. We found that as a result of large abnormal deletions accompanying attempted site-specific V-to-J recombinations, 36 of 47 rearranged TcR gamma genes lacked the variable (V) and/or joining (J) region gene segment involved in this attempted recombination. No such deletions were found in T cell lymphomas from normal mice. We interpret our data as indicating a defective V-to-J recombination in scid lymphocytes consistent with our earlier observation of faulty D-to-J recombination in transformed scid lymphocytes (Schuler et al., Cell 1986. 46: 963). The present results further support the hypothesis that the scid mutation affects a component of the VDJ-recombinase system used in common by B and T cells to assemble antigen receptor genes.

Rearrangement of human T cell receptor beta and gamma chain genes in adult T cell leukemia/lymphoma

We studied rearrangement of human T cell receptor genes (TCR) of C beta, C gamma, V gamma and J gamma in 34 cases of adult T cell leukemia/lymphoma (ATLL), consisting of 29 cases with monoclonally integrated HTLV-I proviral DNA (ATLL-W) and five without monoclonal integration (ATLL-O), in comparison with 12 cases of other peripheral T cell lymphomas (non-ATLL). All cases of both ATLL and non-ATLL showed some rearrangement of T cell receptor genes (TCRs) of C beta, C gamma, V gamma, or J gamma. Rearrangement of TCR beta was found in 28 of 29 cases of ATLL-W, all cases of ATLL-O, and eight of 12 cases of non-ATLL. Rearrangement of TCR gamma was observed in 21 of 22 cases of ATLL-W, and in all cases of ATLL-O and non-ATLL. In TCR gamma, rearrangement of C gamma was seen in six of 20 cases of ATLL-W, none of three ATLL-O cases and three of six cases of non-ATLL. V gamma rearrangement occurred in 14 of 18 cases of ATLL-W, one of two cases of ATLL-O, and three of six cases of non-ATLL. Rearrangement of J gamma was found in 16 of 22 cases of ATLL-W, two of five ATLL-O cases, and six of seven non-ATLL cases. Rearrangement was more frequent in ATLL-W than in ATLL-O and non-ATLL. The incidence rate of rearrangement of V gamma families of V gamma 1, V gamma 2, and V gamma 3 was nearly the same in each group, except for deletion of V gamma 3, which was often observed in ATLL but was absent in non-ATLL. These results indicate the usefulness of detection of TCR and HTLV-I proviral DNA to differentiate ATLL from other T cell malignancies.

T-cell receptor gamma delta bearing cells in normal human skin

T-cell antigen receptors (TCR) are divided into common alpha beta and less common gamma delta types. In the murine skin, TCR gamma delta+ cells have been reported to form the great majority of epidermal T lymphocytes. We have examined the relative contribution of TCR alpha beta+ and TCR gamma delta+ cells to the T-cell population in normal human skin. Serial sections of freshly frozen skin specimens were acetone fixed, incubated with anti-CD3, beta F1 (anti-TCR alpha beta), anti-TCR gamma delta-1 and anti-TCR delta 1 (anti-TCR gamma delta) monoclonal antibodies (MoAb), and stained with a highly sensitive method. Over 90% of the T cells of normal human skin are localized around the postcapillary venules of the dermis, while less than 5% are present within the epidermis. In papillary dermis, TCR gamma delta+ cells formed on average 7% (anti-TCR gamma delta-1) or 9% (anti-TCR delta 1) of the total number of CD3+ cells, while TCR alpha beta+ cells constituted up to 80%. In epidermis, these percentages were 18% and 29% for TCR gamma delta+ cells, and up to 60% for TCR alpha beta+ cells. It is concluded that there is no preferential immigration or in situ expansion of TCR gamma delta+ T cells in normal human skin, because the relative percentages found for the TCR alpha beta+ and TCR gamma delta+ populations in skin are comparable to those found in lymphoid organs and peripheral blood. However, the percentage of TCR gamma delta+ cells in epidermis seemed on average higher than in papillary dermis. Therefore, there may still be a difference in migration patterns of TCR gamma delta+ v TCR alpha beta+ cells, but this does not result in their preferential localization in human epidermis. The hypothesis that TCR gamma delta+ T cells have a specialized function in immunosurveillance of epithelia may thus not be valid for human epidermis.

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.

Diversity in T-cell receptor gamma gene usage in intestinal epithelium

The intraepithelial cells of the murine small intestine include a significant number of CD3+ T cells that use T-cell receptor gamma genes rather than T-cell receptor beta genes. As with other sites of T-cell receptor gamma expression, combinatorial diversity is limited, but there is junctional diversity, and this, together with the specific variable region gamma gene segments used, distinguishes gamma gene expression in the gut epithelium from that in cells derived from the dermal epithelium. The restriction of productive gamma gene expression largely to one V-J-C (V, variable; J, joining; C, constant) gene combination may result from nonproductive joining of other V-J combinations and from productively rearranged genes rendered nonfunctional by incorrect splicing.

Monoclonal antibodies specific to native murine T-cell receptor gamma delta: analysis of gamma delta T cells during thymic ontogeny and in peripheral lymphoid organs

Three hamster monoclonal antibodies (mAbs), all recognizing different epitopes present on the native form of the murine T-cell antigen receptor (TCR) gamma delta subunits, have been generated. mAb 3A10 is specific to a pan-murine TCR gamma delta, recognizing a C delta constant region determinant. mAb 8D6 is specific to a subset of T cells expressing V gamma 4- and V delta 5-encoded gamma delta TCR, and mAb 5C10 is clonotypic. Using these and other mAbs directed against a variety of T-cell surface markers, we quantitated and characterized gamma delta T cells present in developing thymuses as well as in the conventional lymphatic organs by flow cytometry. These studies revealed that (i) many gamma delta thymocytes and peripheral T cells bear CD4 and/or CD8 molecules, (ii) T cells bearing both alpha beta and gamma delta TCRs are scarce, and (iii) thymocyte subsets bearing TCR gamma delta encoded by different combinations of V gamma and V delta gene segments appear in waves during ontogeny.

Diversity of gamma delta T-cell receptors on murine intestinal intra-epithelial lymphocytes

The search for the genes encoding the T-cell receptor (TCR) alpha- and beta-subunits revealed a third gene gamma which shares with the alpha- and beta-genes several properties including somatic rearrangement. This gene, together with a fourth rearranging gene delta, encodes a second type of T-cell receptor, TCR gamma delta. Although TCR gamma delta-bearing T cells constitute a relatively minor subpopulation in the thymus and in peripheral lymphoid organs, they are the major lymphocytes of epidermis (dendritic epidermal cells or DEC) and of intestinal epithelium (intestinal intraepithelial lymphocytes or IEL) in mice, suggesting that at least some gamma delta T cells are important in the surveillance of a variety of epithelia. It was recently reported, however, that the TCR gamma delta on DEC has essentially no structural diversity, implying that the putative ligand is monomorphic. As this finding, if generally applicable, poses severe restrictions on the origin of the ligand, we investigated the diversity of the TCR on the second major epithelium-associated gamma delta T cells, namely IEL from mice. We report here that by contrast with the DEC gamma delta, the IEL gamma delta TCR are structurally diverse.

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

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

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 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.

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

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

T cell receptors

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

Limited diversity of gamma delta antigen receptor genes of Thy-1+ dendritic epidermal cells

T cells bearing gamma delta antigen receptors constitute minor populations in most peripheral lymphoid tissues but represent the major populations of T cells in certain epithelia, including the epidermis. We show that murine dendritic epidermal cell (dEC) clones express V gamma and V delta gene segments, which are rare in adult T cells but predominate in fetal thymocytes. Analysis of the junctions of the rearranged gamma and delta genes shows a striking homogeneity among the receptors of five dEC clones. Our data support a model in which dECs represent one of perhaps several waves of emigrants from the early fetal thymus, and imply a role for dECs in immune surveillance that is distinct from that of alpha beta- and other gamma delta-bearing T cells.

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.

Isotypic exclusion of gamma delta T cell receptors in transgenic mice bearing a rearranged beta-chain gene

The rearrangement of T cell antigen receptor beta- and gamma-chain gene segments was studied in transgenic mice that bear a functional beta-chain gene. Virtually all CD3-positive T cells derived from transgenic mice express beta chains containing the transgene-encoded V beta 8.2 variable region on their surfaces and do not express endogenous beta-chain variable regions. Expression of endogenous V beta genes is inhibited at the level of somatic recombination during thymic ontogeny. Furthermore, rearrangements of the TCR gamma-chain genes are also markedly inhibited in these transgenic animals. Hence expression of the TCR beta transgene has led to allelic exclusion of alpha beta receptors and isotypic exclusion of gamma delta T cell receptors.

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.

The human T-cell rearranging gamma (TRG) genes and the gamma T-cell receptor

The human T-cell Rearranging Gamma genes or T-cell Receptor Gamma (TRG) chain genes, like those encoding the T-cell Receptor (TcR) alpha and beta polypeptides, undergo rearrangements specifically in T-cells. The human TRG locus which has been mapped to chromosome 7 (7p15) is composed of 2 constant region genes (TRGC), 5 joining segments (TRGJ) and at least 14 variable gamma genes (TRGV). 8 variable genes are functional and belong to 4 different subgroups. Based on restriction fragments, the TRG rearrangements can be assigned to given V and J segments, in normal T-cells, T leukemias and lymphomas. The product of the rearranged TRG gene is the gamma chain which is expressed at the surface of a subset of CD3+4-8- T lymphocytes lacking the conventional receptor alpha beta. Structural differences exist between the different 'gamma T-cell receptors', the gamma and delta polypeptides being disulfide or non-disulfide linked. Although the TRG+ cells display a cytolytic activity, their precise function remains to be elucidated.

"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.

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

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

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

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

Diversity of the mouse T cell receptor C gamma 1 gene: structural analysis in C57BL/Ka

We have isolated an unusual T cell receptor gamma chain cDNA clone (gamma 7.1) from a library made from RNA derived from adult thymus of C57BL/Ka mice. This cDNA clone corresponds to the appropriately processed C gamma 1 constant region exons preceded by 1.5 kb of J-C gamma 1 intron. The gamma 7.1 coding region is extremely homologous to the C gamma 1 gene of BALB/c mice, differing at the protein level by a single deletion (alanine 139) and a single substitution. This latter change eliminates the sole N-linked sugar attachment site, providing a basis for strain-specific glycosylation patterns. The J-C gamma 1 intronic region contains two DNA segments (termed psi J gamma 1 and psi J gamma 2) that are highly reminiscent of joining (J) segments; both have potentially functional recombination and donor splice sequences flanking an open reading frame. Northern analysis suggests that gamma 7.1 may be derived from a large, variable region-containing precursor.

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

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

The T cell receptor

The primary structure of T cell receptor proteins and genes is well understood. Immunologists are now trying to understand the properties of these interesting molecules. Evidence suggests that T cell alpha beta receptors recognize a complex of an antigen-derived peptide bound to one of the cell-surface products of the major histocompatibility complex (MHC) genes. It is likely that alpha beta receptors and MHC proteins have coevolved to have some affinity for each other. During T cell development in the thymus, cells bearing self-reactive receptors are deleted by the mechanisms of tolerance, and cells are preferentially allowed to mature if they bear receptors that will be able to recognize antigen plus self-MHC after they have become full-fledged T cells. Some explanations for these phenomena have been tested, but no satisfactory theory can yet be proposed to account for them.

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.

Rearrangement and organization of T cell receptor gamma chain genes in human leukemic T cell lines

Seventeen T cell leukemic lines, which are arrested at different stages of differentiation, were analyzed for gamma-chain rearrangement and expression using the constant region gene and representatives of the different families of V gamma chain genes. With the exception of the T cell line P30/OKUBO, which is arrested at the earliest stage (stage I), all the leukemic lines have rearranged their gamma-chain genes and transcripts can be detected in all but MOLT-4 and P30/OKUBO cell lines. Although V gamma 1 genes were rearranged and expressed in leukemic lines arrested at stages II, III and IV, V gamma 2 and V gamma 3 were only rearranged and expressed in cells at stage III (0/5 in stage II, 5/9 in stage III and 0/1 in stage 4). Thus, there may be a sequential usage of V gamma gene during human T cell ontogeny (although it is possible that this may just be a coincidence), similar to that which has been shown during murine ontogeny. Based on the rearrangement data, the genomic order of 5' V gamma 1-V gamma 2-V gamma 3-J-C 3' is proposed.

Transient rearrangements of the T cell antigen receptor alpha locus in early thymocytes

The dull Ly-1 double-negative (Ly-1dull, Lyt-2-, L3T4-) subpopulation appears to be the major precursor group of T lymphocytes in the thymus. In examining the status of the alpha, beta, and gamma chain genes for T cell receptors (TCR) in this population of cells and hybridomas made from them, we find that all of these loci appear to begin DNA rearrangements in a nearly simultaneous fashion. In the case of the gamma genes, these involve V gamma----J gamma C gamma gene rearrangements; with the beta chain genes, both D beta----J beta C beta rearrangement and V beta----D beta J beta C beta rearrangements are evident; and in the case of the alpha locus, assayed in part by pulsed-field gel electrophoresis, they take the form of a novel series of rearrangements occurring 80 kb or more 5' to the C alpha gene. These alpha locus rearrangements are well away from any of the J alpha gene segments found in cDNA clones to date and are deleted in most mature thymocytes and functional T cell lines. Therefore they appear to represent a distinct class of rearrangement that occurs before V alpha----J alpha joining. These distinctions between the character of the TCR gene rearrangements in these cells represent useful markers in further distinguishing different stages of T cell differentiation within this compartment of early T cells. In addition, the unexpected discovery of clonal rearrangements so far away from any of the expressed J alpha gene segments, and at a stage where there is little or no stable C alpha RNA present, has interesting implications for the hierarchy of TCR gene expression.