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

A gamma/delta cell receptor heterodimer induces the expression of CD4 and CD8 in thymocytes

CD4 and CD8 have been useful surface markers for alpha/beta T cell maturation. In an alpha/beta T cell receptor (TCR) transgenic SCID mice system, it has been shown that alpha/beta TCR alone is sufficient to induce CD4 and CD8 surface expression on thymic T cells. Although the late embryonic thymic gamma/delta T cells are predominately single and double positive, it has not been clear if gamma/delta TCR has a similar capacity. In this study, we show that when transgenes encoding the earliest embryonic gamma/delta TCR are coexpressed with the SCID defect, the gamma/delta transgenes promote the appearance of both the CD4-8- and CD4+8+ T cells in the thymus. Furthermore, the expression of CD4 and CD8 does not require continuous surface gamma/delta TCR expression. These results indicate that gamma/delta TCR alone can promote the CD4/8 surface expression, and may suggest a role for gamma/delta T cells in initiating normal thymic ontogeny.

Predominant appearance of gamma/delta T lymphocytes in the liver of mice after birth

gamma/delta T lymphocytes residing in the liver of mice were systematically characterized with respect to their age-related variation, phenotype and V gene segment usage of gamma/delta T cell receptor (TcR). Previous human and murine studies have shown that a high proportion of gamma/delta T cells reside in the liver and that such liver gamma/delta T cells have lymphoblastic morphology and can spontaneously proliferate in vitro. In the present study, a predominant appearance of gamma/delta T cells (up to 23% among CD3+ cells) in the liver was confirmed in 4-week old mice of various strains. gamma/delta T cells in the liver preferentially co-expressed CD8 antigens, whereas the vast majority of gamma/delta T cells in the spleen lacked the CD8 antigens. The identification of gamma/delta T cells in various lymphoid and non-lymphoid organs also revealed the liver to be one of the organs where gamma/delta T cell are most abundant. The level of such liver gamma/delta T cells showed a clear age-related variation. In the fetal stage and just after birth, gamma/delta T cells were not detectable in the liver (less than 0.2%). However, a significantly higher percentage of gamma/delta T cells among both the total population of mononuclear cells and CD3+ cells was detected in the liver of young 2- to 8-week-old mice; this percentage subsequently declined. As the total number of liver mononuclear cells increased in aged mice, the absolute number of liver gamma/delta T cells also increased as a function of age. V gene segment usage analysis by the polymerase chain reaction method demonstrated that V gamma 1 or V gamma 2/V delta 6 were preferentially used by liver gamma/delta T cells. The age-related increase of gamma/delta T cells was more prominent in the liver of athymic nude mice, and such gamma/delta T cells highly co-expressed the CD8 antigens and also utilized the V gamma 1 or V gamma 2/V delta 6 for gamma/delta Tcr. The predominant appearance of unique gamma/delta T cells in the liver, which was inversely related to the existence of the thymus, indicates that these gamma/delta T cells may differentiate extrathymically in the liver.

Nonconventional (TL-encoded) major histocompatibility complex molecules present processed viral antigen to cytotoxic T lymphocytes

A large number of class I-like genes are located distal to the K and D regions of the murine major histocompatibility complex (MHC) within the Q and TL region. The function of the molecules encoded within this region is obscure since unlike conventional MHC gene products, these molecules have not been reported to present processed environmental antigens to T cells. In the present report, we demonstrate that a peptide corresponding to processed influenza virus hemagglutinin can be recognized by CD8+ T cell receptor alpha/beta-positive cytotoxic T lymphocytes (CTL) in association with a MHC class I-like product encoded within the TL region. Thus, nonconventional class I MHC molecules can bind and present processed environmental antigens, and TCR-alpha/beta CTL directed to such peptide MHC complexes are represented in the mature T cell pool. Our data imply that Q/TL region products may be charged by peptides generated through an antigen processing and presentation pathway distinct from the pathway used by conventional MHC molecules and not normally available to environmental antigens.

Interleukin 4 induces CD8 alpha expression on T cell receptor V gamma 5 thymocytes

It is generally accepted that most T cell receptor (TcR) gamma/delta cells are CD4-CD8-. After in vitro culture; however, a low percentage of these cells express the CD8 alpha subunit. We show here that addition of recombinant interleukin (IL) 4 to IL 2-cultured murine TcR V gamma 5 thymocytes induces the expression of CD8 alpha; CD8 beta is not expressed. Co-addition of the anti-IL 4 mAb 11B11 abrogates the induction of CD8 alpha expression, ruling out the possibility of a contaminant. Furthermore, we demonstrate that a substantial part of freshly prepared TcR V gamma 5 thymocytes express CD8 alpha.

CD4-CD8- T cell receptor alpha beta T cells: generation of an in vitro major histocompatibility complex class I specific cytotoxic T lymphocyte response and allogeneic tumor rejection

The generation of an in vitro major histocompatibility complex class I specific response of CD4-CD8- T cell receptor (TCR) alpha beta cytotoxic T lymphocytes (CTL) and their allogeneic tumor rejection were investigated. Inocula of BALBRL male 1 were rejected in C57BL/6 (B6) mice treated with minimum essential medium (MEM) (control), anti-L3T4 (CD4) monoclonal antibody (mAb) or anti-Lyt-2.2 (CD8) mAb and CTL against the tumor were generated in vitro. No rejection and no induction of CTL were observed in B6 mice treated with anti-L3T4 (CD4) plus anti-Lyt-2.2 (CD8) mAb. CTL with the classical Thy-1+ CD3+CD4-CD8+ TCR alpha beta phenotype were generated in mixed lymphocyte tumor cell culture (MLTC) spleen cells from B6 mice treated with MEM (control) or anti-L3T4 (CD4) mAb, whereas CTL with an unusual Thy-1+CD3+CD4-CD8- TCR alpha beta phenotype were generated in MLTC spleen cells from anti-Lyt-2.2 (CD8) mAb-treated B6 mice. Both types of CTL were reactive with both H-2Kd and Dd (Ld) class I antigen. These findings suggest that when CD4+ cells were blocked by anti-L3T4 (CD4) mAb, CD8+ CTL mediated rejection, and when CD8+ cells were blocked by anti-Lyt-2.2 (CD8) mAb, CD4+ cells were capable of mediating rejection, although less efficiently than CD8+ cells, by inducing CD4-CD8- TCR alpha beta CTL. The finding that adoptive transfer of CD4 and CD8-depleted MLTC spleen cells, obtained from anti-Lyt-2.2 (CD8) mAb-treated B6 mice that had rejected BALBRL male 1, resulted in rejection of BALBRL male 1 inoculated into B6 nu/nu mice confirmed the above notion. CTL clones with the CD4-CD8- TCR alpha beta phenotype specific for Ld were established.

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.

Repertoire development and ligand specificity of murine TCR gamma delta cells

During the past several years, we have been studying the circulating TCR gamma delta cells expressed in peripheral lymphoid tissues. Biochemical and molecular characterization of the TCR gamma delta heterodimers present on these TCR gamma delta cells identified 3 TCR gamma proteins, V gamma 2-C gamma 1, V gamma 1.2-C gamma 2, and V gamma 1.1-C gamma 4. In addition, at least 6 different V delta gene products (V delta 2,4,5,6,V alpha 10, V alpha 11) are expressed in peripheral lymphoid tissue. Nucleotide sequence analysis has revealed a great deal of junctional diversity present among the different V gamma and V delta proteins. Thus, compared to other nonlymphoid tissues (e.g., skin), this population of TCR gamma delta cells appears quite extensive. The development and specificity of TCR gamma delta cells has been pursued by two approaches. First, different TCR gamma delta cells clones were generated which recognize MHC-encoded gene products. One clone recognizes an unconventional TL-encoded antigen, whereas others have been shown to recognize either classical MHC class I or class II antigens. The TCR gamma delta receptor genes have been cloned from the TL-specific TCR gamma delta cell and used to construct transgenic mice to examine the development of TCR gamma delta cells. Although the Tg+ TCR gamma delta cells are tolerized by thymic clonal tolerance similar to TCR alpha beta cells, the epithelial Tg+ TCR gamma delta cells are subjected to non-deletional tolerance (anergy). A second approach towards examining the development of TCR gamma delta cells has been to compare the repertoire of TCR gamma delta splenocytes in a variety of inbred and MHC-congenic strains of mice using subset-specific anti-murine TCR gamma delta mAb. The percentage of individual subsets of splenic TCR gamma delta cells differ widely between different inbred strains of mice due to both MHC- and TCR-encoded genetic differences. In summary, these studies provides a basis for understanding and determining the ligand(s) of the TCR gamma delta heterodimer and the factors which shape the peripheral TCR gamma delta repertoire.

Alpha beta T-lymphocyte depleted mice, a model for gamma delta T-lymphocyte functional studies

Adult mice can be depleted of essentially all mature alpha beta T lymphocytes by chronic treatment with the framework-recognizing, pan-specific anti-TCR alpha beta mAb, H57-597. Similar findings have been reported in rats, gamma delta cell populations remain essentially unaltered in size and reactivity. Suppression of alpha beta T-cell development results in the loss of alloantigen reactivity and of B-cell help, suggesting that gamma delta and alpha beta populations differ in their functional capabilities. Indirect effects of the antibody treatment include quantitative changes in splenic B cells, as well as reduced sizes and weights of experimental animals. alpha beta-suppressed mice and rats may provide model systems for studies on gamma delta cell function in vivo.

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.

Pulmonary epithelial T cells induced by viral infection express T cell receptors alpha/beta

Cells were recovered from the lungs of mice by bronchoalveolar lavage before and after infection with respiratory syncytial (RS) virus. Uninfected mice yielded mostly macrophages, but after RS virus infection lymphocytes also appeared. Recovered cells were stained for CD4, CD8' and either CD3, T cell receptor (TcR) alpha/beta or TcR gamma/delta and analyzed by 3-color flow cytometry. Both the CD4+CD8- and CD4-CD8+ subpopulations stained uniformly for CD3 and TcR alpha/beta, while none stained for TcR gamma/delta. Of the CD4-CD8- cells, about 5% stained for CD3 and TcR alpha/beta during the first week after infection, although this figure increased during the second week. A small and variable fraction of this subset stained for TcR gamma/delta. These results oppose the view that lymphocytes expressing TcR gamma/delta predominate in initial epithelial immune responses to viral infections.

Memory and distribution of virus-specific cytotoxic T lymphocytes (CTLs) and CTL precursors after rotavirus infection

The gastrointestinal tract is constantly exposed to a variety of potentially invasive bacteria, viruses, and parasites. The first line of defense against these pathogens is the intestinal mucosal surface, which consists of epithelial cells, intraepithelial lymphocytes (IELs), mucus, and secretory immunoglobulins. In addition, the intestine is a rich source of lymphocytes located within Peyer's patches and the lamina propria. Little is known about the function, memory, trafficking, or origin of intestinal T lymphocytes after intestinal infection. We studied the murine cytotoxic T-lymphocyte (CTL) response to the intestinal pathogen rotavirus (simian strain RRV). Adult mice were inoculated orally or via the hind footpad with RRV; virus-specific cytotoxic activities in intestinal and nonintestinal lymphocyte populations were determined by 51Cr release assays. In addition, virus-specific CTL precursor (CTLp) frequencies were determined by limiting-dilution analysis. IELs containing rotavirus-specific cytotoxic activity were detected after oral but not footpad inoculation and expressed alpha/beta but not gamma/delta cell surface protein; virus-specific CTLs did not appear to arise from CTLp among IELs. In addition, the site at which RRV was presented to the immune system determined the site at which RRV-specific CTLp first appeared. Frequencies of rotavirus-specific CTLp detected in Peyer's patches were 25- to 30-fold greater after oral than after footpad inoculation. However, regardless of the route of inoculation, rotavirus-specific CTLp were distributed throughout the lymphoid system 21 days after infection. Implications of these findings for vaccine design are discussed.

Culture conditions dictate whether mouse fetal thymus lobes generate predominantly gamma/delta or alpha/beta T cells

Thymus lobes from 14 day-old mouse embryos cultured submerged in r-IL-2 generated a mixture of CD8 alpha+/CD4- and CD8-/CD4- gamma delta TcR expressing cells (Ceredig et. al. 1989). Based upon Northern analysis with TcR constant region probes, no alpha beta T cells could be identified in these cultures. Submerged lobes also showed responsiveness to IL-7. In contrast, when cultured at an air liquid interface as organ cultures (OC), most cells appeared to express alpha beta TcR (Ceredig 1988). Thus depending on the mode of culture, fetal thymus lobes generate predominantly gamma delta or alpha beta T cells; it is unclear how this difference is regulated. Previous phenotypic and functional experiments suggested that gamma delta T cells may be present in OC. In order to study gamma delta T cells in both submerged lobe and OC, we have carried out three colour flow microfluorimetric analysis of gamma delta TcR, abTcR, CD3, J11d and CD8 beta expression by subpopulations of CD8 alpha and CD4 defined thymocytes. In addition, using V gamma-specific oligonucleotides and the polymerase chain reaction, we have begun identifying and sequencing the V gamma repertoire of gamma delta T cells in these mouse fetal thymus cultures.

Gamma delta T cells in murine epithelia: origin, repertoire, and function

The earliest TCR+ cells to appear during fetal development express products of the gamma and delta loci, and emerge as successive waves of cells bearing different V gamma gene products. These appear to emigrate and seed different epithelia. The TCR repertoire of the first two of these waves, V gamma 3 and V gamma 4, respectively, is extremely restricted. Whether the repertoire of these cells is restricted by selective processes or is shaped by developmental restrictions on rearrangements remains to be determined. These cells may function in surveillance for signals of trauma by recognizing self products induced by cellular stress.

Extrathymic origin of intestinal intraepithelial lymphocytes bearing T-cell antigen receptor gamma delta

The kinetics of postnatal intestinal colonization by T cells carrying gamma delta and alpha beta T-cell antigen receptors were studied in nude and normal mice by flow cytometry and immunohistology. Furthermore, gamma delta and alpha beta T-cell development was analyzed in lethally irradiated mice that were reconstituted by fetal liver precursors with or without a thymus. Our results establish that a major subpopulation of gamma delta intestinal intraepithelial lymphocytes is produced from uncommitted precursors at extrathymic sites. This work further shows that a small pool of T cells carrying alpha beta T-cell receptors can also differentiate extrathymically from CD3- fetal liver precursors but with rates of production and peripheral expansion much reduced as compared with those observed in thymus-bearing animals.

The neonatally T cell receptor 2-suppressed rat: lymphocyte subset composition and immune reactivity

Rats were injected intraperitoneally from birth on with a mouse monoclonal antibody (R73) to a constant determinant of the rat T cell receptor (TcR)2. Throughout the observation period (6 months), TcR2+ cells in peripheral lymphoid organs and blood were absent in treated animals with the exception of few (less than 10%) cells with a tenfold reduced TcR2 density; peripheral TcR2-CD3+ cells, i.e. most likely TcR1+ T cells, were increased in frequency. Among thymocyte subpopulations, only those expressing the TcR2 at a high level were reduced in number. The lack of a visible effect on immature thymocytes may, however, be due to the fact that despite high serum levels, thymic R73 determinants were incompletely saturated. Spleen and lymph node cells from TcR2-suppressed rats were completely unresponsive in mixed lymphocyte reaction (two fully allogeneic haplotypes tested) even in the presence of interleukin 2. Reactivity to the T cell mitogen concanavalin A was, in contrast, only partially reduced. Since rat TcR1 cells are activated by concanavalin A, these results suggest that the TcR1 cells present in TcR2-suppressed rats are functional, but do not respond to foreign major histocompatibility complex antigens at a high frequency, a finding of possible importance for immunosuppression with anti-TcR2 monoclonal antibody in human allografting. Neonatally TcR2-suppressed rats were unable to respond to the strong T-dependent antigen keyhole limpet hemocyanin administered intraperitoneally in alum with B. pertussis. Thus, in the absence of peripheral TcR2 cells, the numerically expanded TcR1 T cells are not capable of providing help for B lymphocytes.

Characterization of suppressor T cells for antibody production by chicken spleen cells. I. Antigen-induced suppressor cells are CT8+, TcR1+ (gamma delta) T cells

Suppressor activity of chicken T cells has been previously defined in an in vitro assay of the secondary response of spleen cells to sheep erythrocytes. We have used this assay to examine the phenotype of the T-cell subpopulation(s) that is responsible for this activity. The suppressive effect was alleviated by removal of the TcR1+ (gamma delta) and CD8+ subpopulations, but was unaffected by the removal of the TcR2+ (alpha beta) and CD4+ cells. The addition of a histamine type 2 (H2) receptor antagonist, cimetidine, enhanced the antibody response in the presence of the suppressor cells. The data indicate that one type of T cells with suppressor capability expresses TcR1 and the CD8 accessory molecule, and that these cells may be influenced via H2 receptors.

Gamma/delta T cells and alpha/beta T cells differ in their developmental patterns of receptor expression and modulation requirements

Measurement of the cell surface levels of gamma/delta (TcR 1) and alpha/beta (TcR 2) T cell receptors in the chicken revealed that thymocyte subpopulations that express these receptor isotypes differ remarkably in their rates of receptor acquisition. Whereas TcR 1 expression was relatively high (greater than 10(4) sites per cell) beginning on day 12 of embryonic life, the initial levels of TcR 2 expression on embryonic thymocytes were relatively low (approximately 10(3) sites per cell) when first measurable on day 15, and increased gradually as a function of T cell maturation. In peripheral tissues, the TcR 1 cells also expressed higher receptor levels than did the TcR 2 cells, but the difference was only 2-3-fold. The TcR 2 receptors on immature T cells could be easily modulated by receptor cross-linkage, very much like immunoglobulin receptors on immature B cells. While the TcR 2 receptor modulation occurred within minutes, TcR 1 receptor modulation required several hours for completion, even in the embryonic thymus. The data indicate very different developmental programs for TcR 1 and TcR 2 expression, and suggest fundamental differences in clonal selection modes for the two T cell subpopulations.

Selection of gamma delta T cells with canonical T-cell antigen receptors in fetal thymus

Two gamma delta T-cell subsets that are generated in the fetal thymus and selectively localize in epidermis and uterus-vagina-tongue epithelia exhibit remarkable homogeneity in their (T-cell) antigen receptors (TCR). In the present study, we show that cells expressing the canonical gamma delta TCR are also generated in fetal thymus organ cultures. Treatment of these cultures with anti-gamma delta TCR antibodies did not prevent gamma delta T-cell development but led to a striking increase in the frequency of noncanonical in-frame sequences. We conclude from this finding that cells expressing the canonical TCR accumulate selectively as a result of TCR-mediated positive selection in the fetal thymus.

Expression of gamma/delta T cell receptors on lymphocytes from the lactating mammary gland

gamma/delta cells were at least four times more frequent in lactating mouse mammary glands than among T cells of the most proximal lymph nodes. Two-color staining of freshly isolated T cells and a study of clonally expressed gamma/delta receptors on hybridomas further revealed that the mammary gamma/delta population is heterogeneous, including at least three different subsets, among them cells expressing V gamma 5, V gamma 4 together with V delta 4, or none of these V regions.

Effects of cyclosporin A on T-cell development in organ-cultured foetal thymus

The effects of cyclosporin A (CsA) on T-cell development were assessed in an organ culture of murine foetal thymus. Applying three-colour flow cytometric analysis, we showed that the agent inhibits the development of mature CD3/T-cell receptor alpha beta (TcR alpha beta)+ cells both in CD4+8- and CD4-8+ populations. CD4-8- cells appeared to be accumulated by CsA. We examined the heterogeneity of CD4-8- cells generated in the organ culture, and defined five subpopulations by the expression of the cell-surface molecules CD3/TcR, J11d and CD25. It has been demonstrated that only the CD3/TcR alpha beta+ J11d- CD25- subpopulation is susceptible to the suppressive effects of CsA among CD4-8- cells, whereas all the other four subpopulations, including CD3/TcR gamma delta+ cells, are resistant. Thus, all of the TcR alpha beta-bearing cells, including CD4-8- cells but none of the TcR alpha beta- cells, are CsA sensitive. Because it is known that CsA inhibits the TcR-mediated signalling events in mature T cells and that signallings mediated via the interaction of TcR with major histocompatibility complex (MHC) molecules on thymic stroma cells are crucial for thymic selection of T cells, these results indicate that TcR alpha beta-bearing CD4-8- cells but not TcR gamma delta-bearing CD4-8- cells undergo thymic positive selection.

Expression of T cell receptor V gamma 5 in the adult thymus of irradiated mice after transplantation with fetal liver cells

T cell receptor (TcR) gamma/delta displays limited diversity and its diversity is distinct in different stages of ontogeny and in different anatomical sites. The V gamma 5 and V delta 1 gene products are preferentially expressed on the early fetal thymocytes and on Thy-1+ dendritic epidermal cells, whereas the V gamma 4 and V delta 5 gene products are abundantly expressed on the adult thymocytes. To elucidate whether the developmentally ordered appearance of thymocytes expressing TcR gamma/delta is dependent on the source of T cell precursors or is controlled by the thymic environment where T cells develop, we compared the expression of V gamma 5 on the early-appearing thymocytes between irradiated mice after transplantation with fetal liver (FL) cells and those after transplantation with bone marrow (BM) cells. Sequential appearance of thymocyte subpopulations was observed in the thymus of radiation FL chimeras similar to that seen in radiation BM chimeras. A substantial number of thymocytes bearing V gamma 5 appeared in the thymus at the early stage of radiation FL chimeras, whereas few, if any, of such V gamma 5-bearing thymocytes were detected in the thymus at any stage of radiation BM chimeras. These results suggested that the ordered expression of V gamma repertoire may depend on the origin of the T cell precursors but not on the thymic environment.

Cloning of self-major histocompatibility complex antigen-specific suppressor cells from adult bone marrow

We examined if suppressor cell clones may be established from adult bone marrow that contains a population of cells capable of specifically downregulating the immune response directed toward self-major histocompatibility complex (MHC) antigens. Freshly prepared adult C3H (H-2k) marrow cells were cultured in medium containing interleukin 2 (IL-2), IL-3, or a mixture of IL-2 and IL-3. After 7-10 d, cells grown in IL-3-containing medium were screened for their capacity to suppress cytotoxic T lymphocyte (CTL) generation against self-MHC antigens in allogeneic mixed lymphocyte cultures. Cells capable of suppressing anti-C3H CTL generation were cloned by limiting dilution. Several suppressor clones were established that exhibited strong suppression of anti-H-2k, anti-H-2Kk/Ik, and anti-H-2Dk CTL generation, but failed to suppress anti-H-2d and anti-H-2b responses. When tested in a skin allograft model, intravenous injections of these bone marrow-derived anti-self suppressor cells (2.5 x 10(7) cells) together with IL-3 induced prolongation of C3H skin allografts in anti-mouse lymphocyte serum-treated B6AF1 mice. Injection of IL-3 alone had no effect on allograft survival. Moreover, these cells failed to prolong B10.AKM skin allografts on B6AF1 recipients. Northern blot analysis showed that these cells express full-length transcripts of the T cell receptor (TCR) gamma gene, but not those of TCR alpha, beta, or delta genes. However, no rearrangement of gamma gene was observed by Southern blot analysis. Flow cytometric analysis revealed that bone marrow-derived suppressor cells are strongly positive for Thy-1 antigen but negative for CD3, CD4 (L3T4), and CD8 (Lyt-2) surface markers, and express only class I MHC antigens. Suppressor cells derived from adult bone marrow may play an important role in extrathymic induction of self-tolerance.

Participation of a dominant cytotoxic T cell population defined by a monoclonal antibody in syngeneic anti-tumor responses

Cytotoxic T lymphocyte (CTL) clones against a syngeneic Friend virus-induced erythroleukemia (FBL-3) were generated in C57BL/6 (B6) mice. A monoclonal antibody (mAb, N9-127) was then raised from spleen cells of a B6 mouse immunized syngenically against one of these CTL clones. This mAb detected the epitope (127Ep) of the T cell antigen receptor (TcR) on the immunizing CTL clone in tests of immunoprecipitation, specific blocking and proliferation, and induction of TcR-mediated nonspecific lysis of the clone. In addition, more than 10% of the FBL-3-specific CTL clones isolated independently from B6 mice were 127Ep+. Further investigations revealed that up to 30% of B6 anti-FBL-3 T cell blasts from mixed lymphocyte tumor cell cultures were positive for this epitope, and that its expression was confined to CD8+ T cells. This epitope was not detected in naive lymphoid cells from the spleen, lymph nodes or thymus or in T cell clones specific for tumors other than FBL-3. The FBL-3-specific CTL clones were next grouped into 127Ep+ and 127Ep- clones. Sequence analyses of the CTL clone used for immunization showed the rearrangements of V alpha 1J alpha 112-2 and V beta 10D beta 2.1J beta 2.7. Southern blot analysis of all the 127Ep+ CTL clones examined showed the same DNA rearrangement bands of both the TcR alpha and beta genes. These findings suggested that mAb N9-127 recognized the shared determinant of the TcR molecule which was expressed by the dominant CTL population in the response to FBL-3.

Differential peripheral expansion and in vivo antigen reactivity of alpha/beta and gamma/delta T cells emigrating from the early fetal lamb thymus

The concentrations of different lymphocyte subsets in the blood of lambs which had been thymectomized (Tx) in utero between days 67-75 of fetal gestation were measured at birth and at various intervals during the first year of life. Compared to thymus-intact (Ti) controls, Tx lambs were severely depleted of both alpha/beta and gamma/delta T cells at birth (less than 10% of control levels). The majority of the residual alpha/beta T cells present in Tx lambs at birth were CD4+CD8-. As the Tx lambs aged, the concentration of alpha/beta T cells in blood increased steadily to reach levels around 50% of control values. In contrast, the circulating gamma/delta T cells did not expand in Tx animals and remained barely detectable throughout the observation period, although these cells accounted for 30%-60% of the T cells in the blood of Ti lambs. The expansion of alpha/beta but not gamma/delta T cells was also reflected in changes in the cellular composition of solid lymphoid organs in Tx lambs. B cell numbers were similar in both groups at birth but Tx lambs were persistently B lymphopenic from 3 weeks of age onwards. The alpha/beta T cells that had expanded in Tx lambs responded to stimulation with bacterial antigens in a way that was qualitatively similar to the response in Ti lambs. By contrast, the few gamma/delta T cells in Tx lambs responded abnormally. Our results show that although sheep alpha/beta and gamma/delta T cells are equally thymus dependent during ontogeny, the early fetal thymic emigrants which establish the two T cell lineages in the periphery have strikingly different antigen reactivities and capacities for self-renewal and expansion.

Molecular cloning of sheep T cell receptor gamma and delta chain constant regions: unusual primary structure of gamma chain hinge segments

The primary structure of sheep T cell receptor (TcR) gamma and delta chain constant (C) regions has been determined by cDNA cloning. A comparison of the nucleotide and deduced amino acid sequences of the sheep chains with known human and mouse sequences shows that the primary structure of the immunoglobulin, transmembrane and cytoplasmic C gamma domains and all of the C delta region has been substantially conserved. However, the hinge or connector region of sheep gamma chains differs significantly from all known TcR chains. Clones representing two different sheep C gamma genes were isolated and both contain additional sequence in this region, making them the longest TcR chains so far identified. The hinge region of both sheep C gamma sequences contains two additional cysteine residues and a motif of five amino acids (TTESP or TTEPP) which has been triplicated in one of the clones. Other repetitive segments of 13-17 amino acids could also be identified suggesting that, as in the human C gamma 2 gene, this region of the sheep genes could have arisen from an exon duplication or triplication event. Southern blot analysis of sheep DNA confirmed the presence of one C delta gene and at least two C gamma genes. A restriction fragment length polymorphism that is probably associated with allelic sequence variation in the sheep C delta gene was detected in DNA from different animals. Although the essential structure of the gamma/delta TcR appears well conserved through evolution, the marked heterogeneity evident in the hinge region of gamma chains both within and between species, and particularly the presence of additional cysteine residues in the sheep sequences, may be of structural and functional importance.

Intrathymic nurse cell lymphocytes can induce a specific graft-versus-host reaction

Single chicken thymic nurse cells (TNC) placed onto the chorionallantoic membrane (CAM), showed that intra-TNC lymphocytes (TNC-L) possess a strong graft-versus-host reactivity (GVHR) in allogeneic MHC combinations. This reaction shows the morphological, phenotypic, and functional characteristics of a classical GVH reaction (GVHR). The induction of a GVHR was significantly higher for TNC-L as compared with thymocytes or peripheral blood lymphocytes (PBL). The specificity of the GVHR was shown by serial transfer experiments onto appropriate allogeneic and syngeneic secondary embryonic hosts. In immunofluorescence analyses with monoclonal antibodies (mAb) to the chicken alpha/beta and gamma/delta T cell receptors (TCR) and the CD3, CD4, and CD8 equivalents, an enrichment of CD3+/CD4+/CD8- and CD3+/CD-4-/CD8+, TCR-alpha/beta + and TCR- gamma/delta + cells was observed inside TNC as compared with extra-TNC thymocytes. A large proportion of CD4+ and/or CD8+ TCR- gamma/delta + cells were demonstrated inside TNC. A minor population among TCR- gamma/delta extra-TNC thymocytes also expressed CD4 and/or CD8 molecules. Based on functional tests and double staining experiments, we propose that CD4+/CD8+ thymocytes enter the TNC where they may undergo positive selection for MHC restriction and further differentiation to CD4 or CD8 single-positive cells. Taken together these data support the concept that TNC contribute a specialized thymic microenvironment for T cell differentiation and maturation.

Localization of gamma/delta T cells to the intestinal epithelium is independent of normal microbial colonization

Using monoclonal antibodies identifying all gamma/delta and alpha/beta T cell receptors in cytofluorometric analysis, we have compared the composition of intestinal intraepithelial lymphocytes (i-IEL) in euthymic and athymic germ-free (GF) and conventional (SPF) mice. The results show a marked influence of microbial colonization in the numbers of single-positive (CD4+ or CD8+) alpha/beta i-IEL, but little effect in the pool size or characteristics of gamma/delta i-IEL. In young athymic mice, virtually no alpha/beta i-IEL are detected, while considerable numbers of gamma/delta i-IEL remain, though reduced in GF animals.

Development of cytoplasmic CD3+/T cell receptor-negative cells in the peripheral lymphoid tissues of chickens

In a study of T cell ontogeny using monoclonal antibodies specific for chicken T cell receptors (TcR) and associated cell surface molecules, we found a subset of lymphocytes that express cytoplasmic CD3 epitopes in the absence of cell surface CD3/TcR complexes. Approximately half of these cells, which were present in the spleen, bursa and intestine of young chick embryos, expressed surface CD8. None expressed CD4, TcR 1 (gamma/delta), TcR 2 (alpha/beta) or TcR 3 (a third CD3-associated heterodimer in the chicken). These cytoplasmic CD3+CD8 +/- cells, tentatively named TcR 0 cells to denote their lack of surface TcR, appeared first in the spleen of 8-day embryos, 4 days before TcR expression begins in the thymus, and reached a peak frequency of approximately 10% of the splenic cell in 14-day embryos. The TcR 0 cells were also present in adult birds, where they comprised only about 1% of the CD3+ spleen cells and approximately 40% of the lymphocytes in the intestinal epithelium. We conclude that the avian TcR 0 cells represent a thymus-independent lineage of lymphocytes which, like natural killer cells in mammals, may play an important role in body defense.

TCR gamma/delta+ dendritic epidermal T cells as constituents of skin-associated lymphoid tissue

The epidermis of all strains of normal mice is populated by two distinct dendritic, bone marrow-derived cells: Langerhans cells and CD4-CD8- Thy-1+ dendritic epidermal T cells (DETC). The overwhelming majority of DETC are an unusually homogeneous population of thymic-dependent cells which express CD3-associated T-cell antigen receptors (TCRs) of the gamma/delta type, thereby distinguishing them from conventional CD4+CD8- or CD4-CD8+ T cells expressing CD3-associated alpha/beta TCR. Most DETC are ontogenetically primitive, derived from early fetal thymocytes with a preferential, but poorly understood tropism for the epidermis. Like the TCR on other populations of gamma/delta cells, which preferentially populate other epithelia such as in the gut and lung, the TCR on most DETC selectively utilize particular variable (V) gene segments (i.e., V gamma 3 and V delta 1 for DETC vs V gamma 5 and V delta 4 or V delta 6 for intestinal intraepithelial lymphocytes). However, unlike other gamma/delta populations whose TCR junctional regions exhibit marked heterogeneity, DETC junctional diversity is extremely limited. This lack of TCR heterogeneity among DETC suggests they recognize a narrow range of physiologic ligands (antigens) and that this recognition is restricted not by conventional polymorphic class-I or class-II MHC molecules, but rather by relatively nonpolymorphic self MHC-like molecules of the class Ib MHC type [e.g., Qa, TL, and CD1 (T6)]. Additional studies are required to clarify precisely what DETC recognize, their relevant biological functions, as well as their relationship(s) to the gamma/delta cells recently identified in human skin.

Transgenic mice demonstrate that epithelial homing of gamma/delta T cells is determined by cell lineages independent of T cell receptor specificity

gamma/delta T cells with different TCR repertoires are compartmentalized in different epithelia. This raises the possibility that the TCR-gamma/delta directs homing of T cells to these epithelia. Alternatively, the signals that induce TCR-gamma/delta expression in developing T cells may also induce homing properties in such cells, presumably in the form of cell surface receptors. We have examined this issue by studying the homing of gamma/delta T cells in transgenic mice constructed with specific pairs of rearranged gamma and delta genes. In such mice, most gamma/delta T cells express the transgene-encoded TCR. We find that homing to both skin and gut epithelia is a property of T cells and is not determined by the type of gamma and delta genes used to encode their TCR. We also studied the effect of TCR replacement on the expression of Thy-1 and CD8 proteins on the gamma/delta T cells associated with gut epithelia. Our results show that the expression of the appropriate type of TCR-gamma/delta is not required for the Thy-1 expression by these T cells, suggesting that Thy-1 is not an activation marker. In contrast, CD8 expression by gut gamma/delta T cells seems to depend on the expression of the appropriate type of TCR.

Polymorphisms and diversity of T-cell receptor-gamma proteins expressed in mouse spleen

Bulk populations of T-cell receptor (Tcr) gamma delta-expressing splenocytes from different inbred strains of mice were examined for the diversity of Tcr gamma delta proteins. Immunoprecipitations with anti-C gamma 1/2, anti-C gamma 4, and anti-V gamma 1 sera demonstrated that splenocytes from B10.BR, C57BL/6, and C57L strains of mice expressed the same array of Tcr gamma proteins, namely V gamma 1-C gamma 2, V gamma 1-C gamma 4, and V gamma 2-C gamma 1, although the Tcr gamma delta heterodimers observed for each of these strains were biochemically distinct. Examination of bulk splenic Tcr gamma delta heterodimers from several other inbred strains of mice demonstrated that each of the strains could be categorized into one of three basic phenotypes. For several reasons, the differences observed between the strains appeared to be solely dependent on polymorphisms of the Tcrg loci. First, F1 mice co-expressed both parental Tcr gamma delta phenotypes. Second, the distinguishing polymorphism between mice of phenotype 1 and phenotypes 2 or 3 was due to the presence of an N-linked glycosylation site within the Tcrg-Cl gene segment, previously described for BALB.B and C57BL/6 Tcrg-Cl genes. Finally, the V gamma 1-C gamma 4 polymorphism between mice of phenotype 3 and phenotypes 1 or 2 was due to differences in core protein size. Furthermore, the three defined Tcr gamma chains were expressed independently of the major histocompatibility complex (MHC) haplotype. Although no striking qualitative differences in Tcr gamma delta heterodimers were observed between strains (including those with autoimmune disorders), a quantitative difference in the relative amount of C gamma 4-encoded proteins was observed on Tcr gamma delta splenocytes from both newborn euthymic and adult athymic mice when compared to adult Tcr gamma delta splenocytes from euthymic mice. These results demonstrate that genetic polymorphisms exist among different mouse strains and suggest that selective developmental pressures may govern Tcr gamma delta expression.

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-tolerance to transgenic gamma delta T cells by intrathymic inactivation

During their intrathymic differentiation, T lymphocytes expressing alpha beta T-cell receptors (TCR) are negatively and positively selected. This selection contributes to the establishment of self-tolerance and ensures that mature CD4+ and CD8+ cell populations are restricted by the self major histocompatibility complex. Little is known, however, about gamma delta T-cell development. To investigate whether selection operates in the establishment of the gamma delta T-cell class, we have generated transgenic mice using gamma- and delta-transgenes encoding a TCR that is specific for a product of a gene in the TL-region of the TLb haplotype. Similar numbers of thymocytes expressing the transgenic TCR were generated in mice of TLb and TLd haplotypes. But gamma delta thymocytes from TLb and TLd transgenic mice differed in cell size, TCR density and in their capacity to respond to TLb stimulator cells or interleukin-2 (IL-2). In contrast to gamma delta T cells from TLd transgenic mice, gamma delta T cells from TLb transgenic mice did not produce IL-2 and did not proliferate in response to TLb stimulator cells, but they did proliferate in the presence of exogenous IL-2. These results indicate that functional inactivation of self-antigen-specific T cells could contribute to the establishment of self-tolerance to thymic determinants.

Homing of a gamma delta thymocyte subset with homogeneous T-cell receptors to mucosal epithelia

In mice gamma delta T-cell populations with distinct T-cell receptor (TCR) repertoires and homing properties have been identified. Diversified populations are found in lymphoid organs and intestinal epithelia. By contrast, the gamma delta T-cells that have been found in the murine skin are homogeneous. They express a TCR consisting of one particular V gamma 5 and one particular V delta 1 chain and seem to originate from early fetal thymocytes. We have now systematically analysed many tissues by immunohistochemistry and TCR gene sequencing aided by the polymerase chain reaction. These studies revealed a second homogeneous gamma delta T-cell subset in epithelia not of the intestine and skin, but of the vagina, uterus and tongue. The TCR expressed by this gamma delta T-cell subset consists of the same V delta 1 chain. Cells that express this particular TCR have previously been shown to be positively selected in the late fetal thymus.

Self-reactive gamma delta T cells are eliminated in the thymus

The genes encoding a gamma delta T-cell receptor specific for a major histocompatibility complex class I molecule encoded by the TIa locus have been inserted into the mouse germ line. In mice that do not express the TIa-encoded determinant, transgenic gamma delta T cells are a functional component of the CD4-CD8- 'double-negative' T cells in the thymus and peripheral lymphoid organs. In mice that express the TIa-encoded determinant, there are no transgenic gamma delta T cells in peripheral lymphoid organs, and there are no thymocytes expressing normal levels of the transgenic gamma delta T-cell receptor.

Flow cytometric and immunohistochemical characterization of the gamma/delta T-lymphocyte population in normal human lymphoid tissue and peripheral blood

We determined the quantitative and topographic distribution of gamma/delta lymphocytes in normal human lymphoid tissue and peripheral blood using a monoclonal antibody that detects a framework determinant on delta molecules and delineated the immunophenotypic characteristics of the gamma/delta lymphocyte population by one- and/or two-color immunohistochemical and two- and/or three-color flow cytometric analysis. Variable, but generally small, numbers of gamma/delta lymphocytes are present in peripheral blood and in all lymphoid tissues. The vast majority, greater than or equal to 90%, of lymphoid tissue delta lymphocytes reside in interfollicular (T-cell) zones. Approximately 90% of delta thymocytes are present in the thymic medulla. The percentage of CD3-positive T cells that express delta are: spleen 12.5 +/- 8.1%, peripheral blood 4.0 +/- 3.1%, appendix 2.9 +/- 1%, lymph node 2.2 +/- 1%, thymus 1.4 +/- 0.5%, and tonsil 0.7 +/- 0.5%. We further demonstrated that 1) gamma/delta-thymocytes and gamma/delta peripheral lymphocytes express T-cell lineage restricted antigens CD3 and CD2 but only a variable subset, 30% to 90%, express T-cell lineage associated antigens CD5 and/or CD8; (2) approximately 60% of gamma/delta thymocytes express low-density CD4 while all gamma/delta peripheral lymphocytes lack detectable CD4; 3) gamma/delta lymphocytes lack natural killer (NK), macrophage, and B-cell associated antigens CD16, CD14, and CD20, respectively, but greater than or equal to 70% of gamma/delta T lymphocytes express CD11b, Leu7, and NKH-1, antigens, which are also expressed by suppressor/cytotoxic and NK cells; and 4) a large subpopulation, approximately 25%, of gamma/delta thymocytes are in S1-G2 phase, while greater than or equal to 98% of gamma/delta peripheral lymphocytes are small lymphocytes in G0-G1 phase and lack activation/proliferation markers. Together these results indicate that gamma/delta lymphocytes are resting, mature T cells that probably play a primary role in suppressor/cytotoxic phenomena. They also indicate that gamma/delta lymphocytes variably express multiple-cell surface antigens associated with various cell lineages, suggesting that gamma/delta lymphocytes represent a considerably more heterogeneous cell population than previously appreciated and that they may actually subserve multiple functions.

Identification and characterization of rat T cell subpopulations expressing T cell receptors alpha/beta and gamma/delta

Peripheral lymphoid organs of the rat were investigated for the presence of lymphocytes that expressed the pan-T cell markers CD5 and OX-52 but not the T cell receptor (TcR) alpha/beta. Two such populations were identified: 2% to 4% of lymphocytes in adult spleen, lymph nodes and peripheral blood are CD5+ TcR alpha/beta- and express the OX-52 antigen at the same density as TcR alpha/beta+ T-cells. About 90% of these cells are CD8+. A second population is CD5-, CD8+ and OX-52low. Radioimmunoprecipitation from digitonin lysates of surface-labeled cells with an anti-CD3 antiserum showed that the CD5+, but not the CD5- population of TcR alpha/beta- cells expresses a CD3-associated disulfide-linked cell surface molecule of about 100 kDa apparent mol. mass. Upon reduction, one major band, migrating with 48 kDa was observed. A band of the same size was obtained with an anti-human delta chain peptide antiserum, indicating that the CD3-associated non-TcR alpha/beta molecule is the rat TcR gamma/delta. Functional assays showed that most, if not all natural killer (NK) cell activity is present in the CD5(-)-OX-52low population. Reactivity to foreign major histocompatibility complex (MHC) antigens in mixed lymphocyte reaction was exclusively found in TcR alpha/beta+ splenic T cells. It is concluded that rat gamma/delta T cells in the spleen do not contain a high frequency of cells with specificity for foreign MHC antigens. The seeding of the periphery with alpha/beta and the presumptive gamma/delta T cells was followed from birth. Most prominently in the spleen, alpha/beta T cells reached adult levels much later than gamma/delta T cells. Taken together, these findings demonstrate the expression of the TcR gamma/delta on a minor population of peripheral rat T cells with the predominant phenotype CD4-CD8+ that has no NK cell activity when freshly isolated and does not contain a high frequency of alloreactive cells.

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.

Recognition of a self major histocompatibility complex TL region product by gamma delta T-cell receptors

Ligand specificity of a murine gammadelta T-cell receptor-expressing hybridoma (KN6) derived from adult thymocytes has been analyzed in detail. The molecule recognized by the KN6 gammadelta T-cell receptor is expressed on syngeneic cells of various sources (peritoneal macrophages, thymocytes, spleen cells, and Abelson murine leukemia virus-transformed cell lines) and on transformed cells arrested at an early stage of development (e.g., PCC3 embryonal carcinoma cells). Linkage of the gene coding for the KN6 ligand to the major histocompatibility complex genes could be demonstrated by testing KN6 hybridoma reactivity to cells from congenic strains that differ only at H-2. In addition, analysis of recombinant strains indicates that the gene controlling the KN6 ligand is located in or distal to the TL region. Involvement of the KN6 gammadelta T-cell receptor in this recognition process could be directly demonstrated by transferring the KN6 TL specificity after introduction of the productively rearranged KN6 gamma and delta genes into an alphabeta T-cell clone or into the germ line in transgenic mice. These observations raise the possibility that at least some gammadelta cells regulate hemopoietic cell maturation and activation.