A role for interleukin 4 in the differentiation of mature T cell receptor gamma/delta + cells from human intrathymic T cell precursors

We have analyzed the effect of human recombinant interleukin 4 (rIL-4) on the growth and differentiation of human intrathymic pre-T cells (CD7+2+1-3-4-8-). We describe that this population of T cell precursors proliferates in response to rIL-4 (in the absence of mitogens or other stimulatory signals) in a dose-dependent way. The IL-4-induced proliferation is independent of the IL-2 pathway, as it cannot be inhibited with an anti-IL-2 receptor alpha chain antibody. In our culture conditions, rIL-4 also promotes the differentiation of pre-T cells into phenotypically mature T cells. Although both CD3/T cell receptor (TCR)-alpha/beta + and CD3-gamma/delta + T cells were obtained, the preferential differentiation into TCR-gamma/delta + cells was a consistent finding. These results suggest that, in addition to IL-2, IL-4 plays a critical role in promoting growth and differentiation of intrathymic T cell precursors at early stages of T cell development.     

Rearrangement and expression of the alpha, beta, and gamma chain T cell receptor genes in human thymic leukemia cells and functional T cells

Using cDNA and genomic probes representing the alpha, beta, and gamma chain of the human T cell receptor genes, we have examined the structure and expression of these genes in 14 human leukemic T cell lines, representing different stages of thymic differentiation, and 15 functional human T cell clones. Rearrangement of the gamma and beta chain genes was found in all of the functional T cell clones and all but one (P30/OKUBO) thymic leukemia cell line; all of the lines that had rearrangement of the beta chain expressed beta mRNA. Expression of the alpha chain was found in all of the functional T cell clones examined, while rearrangement of the alpha chain gene, using currently available probes to the J region, could be shown in 10 of 13 functional clones. In contrast, expression of the alpha chain was found in 6 of 10 leukemic T cell lines, while rearrangement was found in six of these nine cell lines. Of the 14 leukemic cell lines studied for rearrangement of the alpha chain, rearrangement was found in six cases. The data obtained with the cell lines are consistent with an ordered rearrangement and expression of the gamma, beta, and alpha chains of the T cell antigen receptor (TcR) genes. The leukemic cell lines used in the present study have previously been characterized with regard to cell surface antigens and intracellular enzymes. Based on those results a scheme of thymic development was proposed. The developmental stages identified by those studies are not in complete agreement with stages of T cell development, as determined in the present study using molecular probes.     

Diversity and structure of human T cell receptor delta chain genes in peripheral blood gamma/delta-bearing T lymphocytes

We have investigated the diversity and repertoire of human TCR delta chain variable gene segments in the human peripheral blood CD4- CD8- (double-negative) population, using rearrangement and expression studies and sequence analyses. 20 TCR delta DNA clones were derived from the RNA of bulk-cultured double-negative T cells and their nucleotide sequences determined. These clones can be classified into six different V delta subfamilies. The distribution, however, was uneven in these cells, with 16 of 20 being derived from the V delta 1 (9) and V delta 2 (7) subfamilies. The remaining subfamilies, V delta 3, V delta 4, V delta 5, and V delta 6, were only represented by one clone each. The majority of these subfamilies seem to consist of a single member, in contrast with the closely linked V alpha subfamilies, which, in most cases, consist of multiple members. Our findings suggest that only a limited number of V delta genes are used in human peripheral blood double-negative T cells and that two major V delta subfamilies (V delta 1 and V delta 2) are used more frequently. Sequence comparison of our cDNA clones to V alpha clones indicates that there is no overlap in usage of V alpha and V delta gene segments, except for the V delta 4 (V alpha 6) subfamily. Comparison of the different V delta sequences suggests that the majority of the sequence diversity is concentrated in the junctions between V, D, and J segments and results from extensive N region diversity.     

T cell receptor gamma/delta chain diversity

The TCR-gamma and -delta chains of six murine hybridomas were compared by one-dimensional SDS-PAGE and two-dimensional NEPHGE/SDS-PAGE analysis. This allowed the identification of three distinct gamma chains (gamma a, gamma b, and gamma c) and three distinct delta chains (delta a, delta b, and delta c). Four gamma/delta chain combinations (gamma a delta a, gamma b delta b, gamma b delta c, and gamma c delta a) were observed. These results indicate that multiple forms of the delta chain are expressed and suggest that the delta chains are encoded for by an Ig-like rearranging gene. This delta chain polymorphism significantly enhances the potential diversity of TCR-gamma/delta, which may be of importance for a better understanding of the putative ligand(s) recognized by this receptor.     

Characterization of a third form of the human T cell receptor gamma/delta

A subpopulation of the CD3+ peripheral T lymphocytes express the TCR-gamma/delta complex. Three distinct TCR-gamma forms that differ in size and in the ability to form a disulfide bridge with the TCR-delta subunit have been described. In this study we analyze the structural difference between the non-disulfide-linked 55-kD and 40-kD TCR-gamma chains. The 40-kD TCR-gamma form contains a smaller polypeptide backbone and carries less carbohydrate compared with the 55-kD TCR-gamma form. A cDNA clone corresponding to the 40-kD TCR-gamma subunit lacks one copy of the second exon of the constant region that is present in the other TCR-gamma subunit. This exon copy encodes part of the connector region that is located between the constant domain and the membrane spanning region. We show that the number of potential N-linked glycan attachment sites are the same for the two TCR-gamma forms. Since these attachment sites are located in the connector region we conclude that the connector region influences the amount of N-linked carbohydrates added to the core TCR-gamma polypeptide, probably by affecting the conformation of the protein. In contrast to the TCR-beta constant region usage, the TCR-gamma constant regions are unequally expressed. Virtually exclusive usage of disulfide-linked complexes were found in some individuals, while both the disulfide-linked and the 40-kD, non-disulfide-linked TCR-gamma forms were detected in other subjects. The ability to distinguish these TCR-gamma/delta forms now makes it possible to study the mechanisms that govern their selection and to determine if they correspond to functionally distinct isotypes.     

Evidence that the T cell antigen receptor may not be involved in cytotoxicity mediated by gamma/delta and alpha/beta thymic cell lines

After culture in IL-2, thymocytes expressing either TCR-alpha/beta or - gamma/delta acquired the ability to lyse hematopoietic and solid tumor cell targets without deliberate immunization or apparent restriction by the MHC. Moreover, TCR-alpha/beta- and TCR-gamma/delta-bearing thymic cell lines demonstrated an essentially identical spectrum of cytolysis against several tumor cell targets. Cytotoxicity was not inhibited by antibodies against CD3 or CD2 and modulation of the CD3/TCR complex also failed to affect cytotoxicity. Thus, non-MHC-restricted cytotoxicity can be mediated by thymocytes with either TCR-alpha/beta or TCR-gamma/delta, but the TCR may not be responsible for target recognition.     

Structure of the gamma/delta T cell receptor of a human thymocyte clone

The CD3+, IL-2-dependent normal human thymocyte clone, CII, expresses on its surface a CD3-associated gamma/delta TCR. We have further elucidated the structure of this receptor from the nucleotide sequence of cDNA and genomic clones from CII that encode functional TCR-gamma and -delta chains. We find that the CII line expresses a C gamma 2 constant region that is a polymorphic form lacking a copy of an internal exon; the sequence of this constant region accounts for the size of the gamma chain and noncovalent linkage of gamma and delta chains in the CII TCR. The V gamma region used for the CII TCR is identical to the several previously characterized expressed human V gamma segments. Possible implications of this finding are discussed.     

Intercellular interactions and cytokine responsiveness of peritoneal alpha/beta and gamma/delta T cells from Listeria-infected mice: synergistic effects of interleukin 1 and 7 on gamma/delta T cells

Peritoneal gamma/delta T cells from Listeria-immune mice show an enhanced potential to expand when restimulated with antigens or mitogens in vitro (see companion paper [Skeen, M. J., and H. K. Ziegler. 1993. J. Exp. Med. 178:971]). When cocultured with peritoneal alpha/beta T cells, the gamma/delta T cell population expanded preferentially even when the in vitro stimulus was specific for the alpha/beta T cell population. Purified gamma/delta T cells did not respond to alpha/beta T cell-specific stimuli. If isolated T cell subsets were recombined in cell mixing experiments, the resulting proliferative response was greater than additive. Irradiated alpha/beta T cells could enhance the proliferation of responding gamma/delta T cells, but the effect was unidirectional; i.e., irradiated gamma/delta T cells did not stimulate responding gamma/delta T cells. This effect appeared to be cytokine mediated and did not require cell-cell contact. Both recombinant interleukin 2 (rIL-2) and rIL-7 could support the expansion of the gamma/delta T cells, while rIL-7 was only minimally stimulatory for the alpha/beta T cells. The magnitude of the response by gamma/delta T cells to rIL-7 exceeded the response to other in vitro stimuli, including immobilized anti-T cell receptor monoclonal antibody, and was 50-100-fold greater than the alpha/beta T cell response to IL-7. This unique sensitivity of gamma/delta T cells to IL- 7 was strongly enhanced by the presence of accessory cells. These cells could be replaced by rIL-1, establishing a synergy for IL-1 and IL-7 as factors that could uniquely stimulate this gamma/delta T cell population. Isolated peritoneal gamma/delta T cells from Listeria- immune mice react to heat-killed Listeria preparations in the presence of macrophages accessory cells in a non-H-2-restricted manner. Considered collectively, these results suggest a potential mechanism by which gamma/delta T cells can predominate in epithelial tissues and at sites of infection.     

Tolerance of T cell receptor gamma/delta cells in the intestine

The present study examined the mechanism(s) of tolerance induction for intestinal intraepithelial lymphocytes (iIELs) using an alloantigen (Ag)-specific gamma/delta T cell receptor (TCR gamma/delta) transgenic (Tg) model. In Tg Ag-bearing H-2b/d mice (Tgb/d), Tg iIELs were Thy-1-, CD44+, CD45R (B220)+, and CD5+, whereas in syngeneic Tgd/d mice, iIELs were Thy-1+, CD44-, and CD45R- with a subset of CD5+ cells. Previously, we had shown that tolerance for Tgb/d iIELs involved functional anergy and deletion (Barrett, T. A., M. L. Delvy, D. M. Kennedy, L. Lefrancois, L. A. Matis, A. L. Dent, S. M. Hedrick, and J. A. Bluestone. 1992. J. Exp. Med. 175:65). In this study we demonstrate that Tgb/d iIELs expressing dull levels of Thy-1 proliferated in the presence of exogenous rIL-2. A direct precursor-product relationship between the Thy-1+-responsive iIELs and the tolerant Thy-1dul/- iIELs was demonstrated by adoptive transfer into severe combined immunodeficient (SCID) mice. Tg Thy-1+ iIELs reconstituting Ag+ but not Ag- SCID mice downregulated Thy-1 after Ag exposure in vivo. Analysis of bone marrow (BM) chimeras demonstrated the persistence of Tg IELs in all Ag+ chimeras although a modest degree of clonal deletion was apparent. The greatest percentage of Tg IELs were detected when Ag was restricted to radioresistant cells (e.g., epithelial cells) compared with BM-derived antigen-presenting cells (APC). This was especially apparent in thymectomized chimeric mice. Consistent with the notion that Ag-bearing epithelial cells may be poor APC, isolated intestinal epithelial cells from Ag-bearing mice failed to stimulate Tg iIELs compared with splenic APC. These studies suggest that the major population of TCR gamma/delta iIELs were probably extrathymically derived and encountered self-Ag on intestinal epithelial cells. The induction of tolerance likely involved an activation event resulting in downregulation of Thy-1. These mechanisms of tolerance for TCR gamma/delta iIELs led to the persistence of a reservoir of self- reactive T cells with the potential for mediating autoimmune disease.     

Interactions of human alpha/beta and gamma/delta T lymphocyte subsets in shear flow with E-selectin and P-selectin

We have compared the ability of human alpha/beta and gamma/delta T lymphocytes to adhere to selectin-bearing substrates, an interaction thought to be essential for homing and localization at sites of inflammation. Both T cell populations form rolling adhesions on E- and P-selectin substrates under physiologic flow conditions. Although equivalent to alpha/beta T cells in binding to E-selectin, gamma/delta T cells demonstrated greater ability to adhere to P-selectin that was purified or expressed on the surface of activated, adherent platelets. Under static conditions, 80% of gamma/delta T cells and 53% of alpha/beta T cells formed shear-resistant adhesions to P-selectin, whereas only 30% of gamma/delta and alpha/beta T cells adhered to E- selectin. The enhance ability of gamma/delta T cells to adhere to P- selectin cannot be attributed to differences in expression of the P- selectin glycoprotein ligand (PSGL-1), as all alpha/beta T cells versus approximately 75% of gamma/delta T cells expressed PSGL-1. Both cell populations expressed a similar percentage of the carbohydrate antigens sialyl LewisX and cutaneous lymphocyte-associated antigen. Depletion of lymphocyte populations or T cell clones bearing these oligosaccharides with the monoclonal antibody CSLEX-1 and HECA-452, respectively, resulted in a substantial reduction in adhesion to E-selectin and slight reduction in adhesion to P-selectin under flow conditions. Treatment of cells with an endopeptidase that selectively degrades O- sialomucins such as PSGL-1, abolished P-selectin but not E-selectin adhesion. Removal of terminal sialic acids with neuraminidase or protease treatment of cells abrogated cell adhesion to both selectin substrates. These results provide direct evidence for the presence of distinct E- and P-selectin ligands on T lymphocytes and suggest that gamma/delta T cells may be preferentially recruited to inflammatory sites during the early stages of an immune response when P-selectin is upregulated.     

Site-specific deletions involving the tal-1 and sil genes are restricted to cells of the T cell receptor alpha/beta lineage: T cell receptor delta gene deletion mechanism affects multiple genes

Site-specific deletions in the tal-1 gene are reported to occur in 12- 26% of T cell acute lymphoblastic leukemias (T-ALL). So far two main types of tal-1 deletions have been described. Upon analysis of 134 T- ALL we have found two new types of tal-1 deletions. These four types of deletions juxtapose the 5' part of the tal-1 gene to the sil gene promoter, thereby deleting all coding sil exons but leaving the coding tal-1 exons undamaged. The recombination signal sequences (RSS) and fusion regions of the tal-1 deletion breakpoints strongly resemble the RSS and junctional regions of immunoglobulin/T cell receptor (TCR) gene rearrangements, which implies that they are probably caused by the same V(D)J recombinase complex. Analysis of the 134 T-ALL suggested that the occurrence of tal-1 deletions is associated with the CD3 phenotype, because no tal-1 deletions were found in 25 TCR-gamma/delta + T-ALL, whereas 8 of the 69 CD3- T-ALL and 11 of the 40 TCR-alpha/beta + T-ALL contained such a deletion. Careful examination of all TCR genes revealed that tal-1 deletions exclusively occurred in CD3- or CD3+ T- ALL of the alpha/beta lineage with a frequency of 18% in T-ALL with one deleted TCR-delta allele, and a frequency of 34% in T-ALL with TCR- delta gene deletions on both alleles. Therefore, we conclude that alpha/beta lineage commitment of the T-ALL and especially the extent of TCR-delta gene deletions determines the chance of a tal-1 deletion. This suggests that tal-1 deletions are mediated via the same deletion mechanism as TCR-delta gene deletions.     

Enhancer-dependent and -independent steps in the rearrangement of a human T cell receptor delta transgene

The rearrangement and expression of T cell receptor (TCR) gene segments occurs in a highly ordered fashion during thymic ontogeny of T lymphocytes. To study the regulation of gene rearrangement within the TCR alpha/delta locus, we generated transgenic mice that carry a germline human TCR delta minilocus that includes V delta 1, V delta 2, D delta 3, J delta 1, J delta 3, and C delta segments, and either contains or lacks the TCR delta enhancer. We found that the enhancer- positive construct rearranges stepwise, first V to D, and then V-D to J. Construct V-D rearrangement mimics a unique property of the endogenous TCR delta locus. V-D-J rearrangement is T cell specific, but is equivalent in alpha/beta and gamma/delta T lymphocytes. Thus, either there is no commitment to the alpha/beta and gamma/delta T cell lineages before TCR delta gene rearrangement, or if precommitment occurs, it does not operate directly on TCR delta gene cis-acting regulatory elements to control TCR delta gene rearrangement. Enhancer- negative mice display normal V to D rearrangement, but not V-D to J rearrangement. Thus, the V-D to J step is controlled by the enhancer, but the V to D step is controlled by separate elements. The enhancer apparently controls access to J delta 1 but not D delta 3, suggesting that a boundary between two independently regulated domains of the minilocus lies between these elements. Within the endogenous TCR alpha/delta locus, this boundary may represent the 5' end of a chromatin regulatory domain that is opened by the TCR delta enhancer during T cell development. The position of this boundary may explain the unique propensity of the TCR delta locus to undergo early V to D rearrangement. Our results indicate that the TCR delta enhancer performs a crucial targeting function to regulate TCR delta gene rearrangement during T cell development.     

Normal regulatory alpha/beta T cells effectively eliminate abnormally activated T cells lacking the interleukin 2 receptor beta in vivo

Although interleukin 2 (IL-2) has been thought to be the most important cytokine for T cell growth, animals lacking IL-2 or a component of its receptor molecules have more expanded T cells with activated memory phenotype, indicating an indispensable role for the IL-2/IL-2 receptor system in regulating the size and activity of the T cell population. In this study, we investigated the possible mechanism of abnormal expansion of activated T cells in IL-2 receptor beta chain (IL-2Rbeta)(-/-) mice using the systems of bone marrow transplantation and T cell transfer. Here, we show that IL-2Rbeta(2/-) T cells in mice reconstituted with a mixture of IL-2Rbeta(2/-) and IL-2Rbeta(1/+) bone marrow cells did not develop into an abnormally activated stage, and that already activated IL-2Rbeta(2/-) T cells were effectively eliminated by IL-2Rbeta(1/+) T cells when both cells were cotransferred to T cell-deficient host mice. This regulation and/or elimination was dependent on T cells bearing alpha/beta type T cell receptor, especially on CD8(+) T cells and independent of the Fas-Fas ligand (FasL) system. IL-2Rbeta(1/+) T cells that eliminated activated IL-2Rbeta(2/-) T cells expressed FasL, perforin, granzyme B, and tumor necrosis factor alpha/beta. These results indicate a novel function of IL-2Rbeta that is necessary for the induction of regulatory T cells acting to eliminate activated T cells.     

Evidence for extrathymic changes in the T cell receptor gamma/delta repertoire

The germline repertoire of variable genes for the TCR-gamma/delta is limited. This, together with the availability of several V delta-specific and a C delta-specific mAbs, has made it possible to assess differences in the TCR-gamma/delta repertoire in man. TCR-gamma/delta cells expressing particular V gene segments have been previously shown to be localized in different anatomical sites. In this study, analysis of TCR-gamma/delta V gene segment usage performed on subjects from the time of birth through adulthood revealed striking age-related changes in the TCR-gamma/delta repertoire in peripheral blood. V delta 1+ gamma/delta T cells predominated in thymus as well as in peripheral blood at birth and then persisted as a relatively constant proportion of CD3+ PBL. However, V delta 2+ gamma/delta T cells that constitute a small proportion of the CD3+ cells in thymus and in peripheral blood at birth, then expand and account for the major population of gamma/delta T cells in PBL in adults. No parallel postnatal expansion of V delta 2+ cells in the thymus was observed, even when paired thymus-peripheral blood specimens were obtained on subjects between the ages of 3 d and 8 yr. The subset of V delta 2+ lymphocytes that was expanded in peripheral blood expressed high levels of CD45RO suggesting prior activation of these cells, consistent with the possibility that their expansion might have resulted from exposure to foreign antigens or superantigens. In contrast, V delta 1+ T cells in PBL showed no comparable increase in relative numbers and were either negative or expressed only low levels of CD45RO. Consistent with evidence for extrathymic peripheral expansion of selective TCR-gamma/delta subsets, no link between MHC haplotype and differences in the TCR-gamma/delta V gene usage between individuals was apparent, and identical twins displayed TCR-gamma/delta variable gene segment phenotypes that were strikingly different from one another. The elements that determine the TCR-gamma/delta repertoire in individuals are not known. It is possible that both thymic selection and extrathymic factors may influence the peripheral repertoire. Recently, TCR-gamma/delta+ lymphocytes have been shown to expand markedly in peripheral lymphoid tissues and infectious lesions in response to mycobacterial antigens, and a correlation between mycobacterial responses and TCR-gamma/delta V gene usage has been shown in mice. The data presented here demonstrated peripheral age-related changes in the gamma/delta repertoire and point to the importance of extrathymic expansion of specific gamma/delta subsets in generating the human TCR-gamma/delta repertoire.     

Production of a T cell hybridoma that expresses the T cell receptor gamma/delta heterodimer

We have produced a T cell hybridoma line by fusion of an IL-2-dependent, long-term T cell receptor (TCR) gamma/delta+ Thy-1+, bone marrow-derived, dendritic epidermal cell line to the BW5147 tumor line. The resultant hybridoma was rapidly growing, lymphokine independent, and expressed T3 in association with the TCR gamma/delta heterodimer. Several subclones of the hybridoma line produced easily detectable levels of IL-2 after stimulation by anti-T3 or Con A. The availability of these cloned cell lines should greatly facilitate further functional, biochemical, and molecular studies of the TCR delta chain.     

Retroviral transformation in vitro of chicken T cells expressing either alpha/beta or gamma/delta T cell receptors by reticuloendotheliosis virus strain T

Exposure of normal juvenile chicken bone marrow cells to the replication defective avian reticuloendotheliosis virus strain T (REV- T) (chicken syncytial virus [CSV]) in vitro resulted in the generation of transformed cell lines containing T cells. The transformed T cells derived from bone marrow included cells expressing either alpha/beta or gamma/delta T cell receptors (TCRs) in proportions roughly equivalent to the proportions of TCR-alpha/beta and TCR-gamma/delta T cells found in the normal bone marrow in vivo. Essentially all TCR-alpha/beta- expressing transformed bone marrow-derived T cells expressed CD8, whereas few, if any, expressed CD4. In contrast, among TCR-gamma/delta T cells, both CD8+ and CD8- cells were derived, all of which were CD4-. Exposure of ex vivo spleen cells to REV-T(CSV) yielded transformed polyclonal cell lines containing > 99% B cells. However, REV-T(CSV) infection of mitogen-activated spleen cells in vitro resulted in transformed populations containing predominantly T cells. This may be explained at least in part by in vitro activation resulting in dramatically increased levels of T cell REV-T(CSV) receptor expression. In contrast to REV-T(CSV)-transformed lines derived from normal bone marrow, transformed lines derived from activated spleen cells contained substantial numbers of CD4+ cells, all of which expressed TCR- alpha/beta. While transformed T cells derived from bone marrow were stable for extended periods of in vitro culture and were cloned from single cells, transformed T cells from activated spleen were not stable and could not be cloned. We have therefore dissociated the initial transformation of T cells with REV-T(CSV) from the requirements for long-term growth. These results provide the first demonstration of efficient in vitro transformation of chicken T lineage cells by REV- T(CSV). Since productive infection with REV-T(CSV) is not sufficient to promote long-term growth of transformed cells, these results further suggest that immortalization depends not only upon expression of the v- rel oncogene but also on intracellular factor(s) whose expression varies according to the state of T cell physiology and/or activation.