The cytoplasmic tail of the T cell receptor ζ chain is dispensable for antigen-mediated T cell activation

The T cell antigen receptor consists of an antigen-binding αβ heterodimer and a group of invariant polypeptides denoted CD3-γ, CD3-δ, CD3-εand CD3-ζ. Whether antigen responsiveness is dependent on the expression of functional CD3-ζ subunit remains controversial. Forinstance, transfection of a ζ^? / n^? variant of the 2B4.11. T cell hybridoma with mutated ζ cDNA that encoded a ζ protein truncated at residue 108, restored the surface expression of T cell antigen receptor complexes with, however, impaired antigen responsiveness [Frank, S. J., Niklinska, B. B., Orloff, D. G., Mercep, M., Ashwell, J. D. and Klausner, R. D., Science 1990. 249: 174.]. In marked contrast, BW5147 transfectants that expressed T cell antigen receptors devoid of functional ζ subunits were still able to trigger the production of interleukin-2 in response to antigen [Wegener, A.-M. K., Letourneur, E, Hoeveler, A., Brocker, T., Luton, F. and Malissen, B., Cell 1992. 68: 83.]. To assess if the above discrepancies may have resulted from the use of different recipient T cells, we transfected a ζ/n-deficient variant of 2B4.11 (MA5.8) with the very same truncated ζ cDNA we previously used in BW5147. Consistent with our initial observations in BW5147, the cytoplasmic tail of the ζ polypeptide was found dispensable for antigenic responsiveness. Furthermore, a difference between the two recipient T cells was detected when cells were challenged via the Thy-1 and Ly-6 molecules. Once expressed in MA5.8, but not in BW5147, T cell antigen receptor complexes devoid of functional ζ subunits were able to sustain activation initiated via Thy-1 and Ly-6 molecules.     

Expression of two T cell receptor α chains on the surface of normal murine T cells

We have previously reported that a subset of T cells in T cell receptor (TCR)-transgenic mice may express two different α chains on their surface. The expression of two functional α chains has also been demonstrated for human peripheral blood T cells. In this report, we show that a proportion of normal murine lymph node T cells express two functional α chains on their surface. The extrapolated frequency of these cells present in the normal repertoire ranges from 7–21%, with an average of 15%. Our analysis of a small number of antigen-specific T cell clones suggests that the frequency of antigen-responsive cells expressing two surface α chains is relatively low. This raises the possibility that dual α chain T cells may have a selective disadvantage in responding to specific antigen.     

T cell receptor α gene rearrangement and transcription in adult thymic γδ cells

T cells belong to two separate lineages based on surface expression of αβ or γδ T cell receptors (TCR). Since during thymus development TCR β, γ, and δ genes rearrange before α genes, and γδ cells appear earlier than αβ cells, it has been assumed that αδ cells are devoid of TCR α rearrangements. We show here that this is not the case, since mature adult, but not fetal, thymic γδ cells undergo VJα rearrangements more frequently than immature αβ lineage thymic precursors. Sequence analysis shows VJα rearrangements in γδ cells to be mostly (70 %) nonproductive. Furthermore, VJα rearrangements in γδ cells are transcribed normally and, as shown by analysis of TCR β-/- mice, occur independently of productive VDJβ rearrangements. These data are interpreted in the context of a model in which precursors of αβ and γδ cells differ in their ability to express a functional pre-TCR complex.     

Prevention and treatment of Lewis rat experimental allergic encephalomyelitis with a monoclonal antibody to the T cell receptor Vβ8.2 segment

The predominance of T cell receptor (TCR) Vβ8.2 utilization by encephalitogenic T cells induced in Lewis rats by immunization with myelin basic protein (MBP) is controversial. Thus, both an almost exclusive usage of Vβ8.2 [Burns, F. R., Li, X., Shen, N., Offner, H., Chou, Y. K., Vandenbark, A. A. and Heber-Katz, E., J. Exp. Med. 1989. 169: 27; Chluba, J., Steeg, C., Becker, A., Wekerle, H. and Epplen, J. T., Eur. J. Immunol. 1989. 19: 279] and a quite diverse Vβ composition of CD4 T cells causing experimental autoimmune encephalomyelitis (EAE) [Sun, D., Gold, P. D., Smith, L., Brostoff, S. and Coleclough, C., Eur. J. Immunol. 1992. 22: 591; Sun, D., Le, J. and Coleclough, C., Eur. J. Immunol. 1993. 23: 494] have been reported. Using a recently developed monoclonal antibody (mAb) specific for TCR Vβ8.2, we show that postnatal treatment effectively eliminates Vβ8.2-bearing cells and prevents MBP-induced EAE in the majority of Lewis rats. Moreover, treatment of adult Lewis rats with Vβ8.2-specific mAb as late as on day 12 after MBP immunization suppressed the development of neurological symptoms. Thus, Vβ8.2-bearing cells do play a decisive role in Lewis rat EAE, and suppression of the small (5%) Vβ8.2-expressing T cell subset provides an effective therapeutic strategy.     

The expansion and selection of T cell receptor αβ intestinal intraepithelial T cell clones

In conventional mice, the T cell receptor (TCR)αβ⁺ CD8αα⁺ and CD8αβ⁺ subsets of the intestinal intraepithelial lymphocytes (IEL) constitute two subpopulations. Each comprise a few hundred clones expressing apparently random receptor repertoires which are different in individual genetically identical mice (Regnault, A., Cumano, A., Vassalli, P., Guy-Grand, D. and Kourilsky, P., J. Exp. Med. 1994. 180: 1345). We analyzed the repertoire diversity of sorted CD8αα and CD8αβ⁺ IEL populations from the small intestine of individual germ-free mice that contain ten times less TCRαβ⁺ T cells than conventional mice. The TCRβ repertoire of the CD8αα and the CD8αβ IEL populations of germ-free adult mice shows the same degree of oligoclonality as that of conventional mice. These results show that the intestinal microflora is not responsible for the repertoire oligoclonality of TCRαβ⁺ IEL. The presence of the microflora leads to an expansion of clones which arise independently of bacteria. To evaluate the degree of expansion of IEL clones in conventional mice, we went on to measure their clone sizes in vivo by quantitative PCR in the total and in adjacent sections of the small intestine of adult animals. We found that both the CD8αα and the CD8αβ TCRαβ IEL clones have a heterogeneous size pattern, with clones containing from 3 × 10³ cells up to 1.2 × 10⁶ cells, the clones being qualitatively and quantitatively different in individual mice. Cells from a given IEL clone are not evenly distributed throughout the length of the small intestine. The observation that the TCRαβ IEL populations comprise a few hundred clones of very heterogeneous size and distribution suggests that they arise from a limited number of precursors, which may be slowly but continuously renewed, and undergo extensive clonal expansion in the epithelium.     

αβ Lineage-committed thymocytes can be rescued by the γδ T cell receptor (TCR) in the absence of TCR β chain

Commitment of the αβ and γδ T cell lineages within the thymus has been studied in T cell receptor (TCR)-transgenic and TCR mutant murine strains. TCRγδ-transgenic or TCRβ knockout mice, both of which are unable to generate TCRαβ-positive T cells, develop phenotypically αβ-like thymocytes in significant proportions. We provide evidence that in the absence of functional TCRβ protein, the γδTCR can promote the development of αβ-like thymocytes, which, however, do not expand significantly and do not mature into γδ T cells. These results show that commitment to the αβ lineage can be determined independently of the isotype of the TCR, and suggest that αβ versus γδ T cell lineage commitment is principally regulated by mechanisms distinct from TCR-mediated selection. To accommodate our data and those reported previously on the effect of TCRγ and δ gene rearrangements on αβ T cell development, we propose a model in which lineage commitment occurs independently of TCR gene rearrangement.     

Lack of intermediate-affinity interleukin-2 receptor in mice leads to dependence on interleukin-2 receptor α, β and γ chain expression for T cell growth

An interleukin (IL)-4 dependant mouse T cell clone 8.2 derived from an IL-2-dependent T cell line was characterized. As measured by flow cytometric analysis and Northern blotting, it expresses IL-2 receptor β (IL-2Rβ) and γ (IL-2Rγ) chains, but has lost expression of IL-2 receptor α chain (IL-2Rα). To investigate the properties of the mouse IL-2Rβγ complex and the role of IL-2Rα gene expression, this clone was further studied. T cell clone 8.2 has lost the capacity to bind ¹²⁵I-labeled human IL-2 under experimental conditions able to detect intermediate-affinity IL-2R in human cells. Mouse IL-2 is unable to block the binding of mAb TMβ1 to 8.2 cells. Under the same experimental conditions, mouse IL-2 blocks the binding of TMβ1 to C30-1 cells expressing the IL-2αβγ complex. Since TMβ1 recognizes an epitope related to the IL-2 binding site of IL-2Rβ, these results can be taken as a demonstration that mouse IL-2Rβγ does not bind mouse IL-2. Furthermore, T cell clone 8.2 does not proliferate in response to recombinant mouse or human IL-2. On the other hand, T cell transfectant lines expressing heterospecific receptors made of the human IL-2Rβ and mouse IL-2Rγ chains bind ¹²⁵I-labeled human IL-2 and proliferate in response to IL-2. This establishes the difference between mouse and human IL-2Rβ chains. Transfection of T cell clone 8.2 with human IL-2Rα genes restores their capacity to proliferate in response to IL-2. In addition, all transfectants grown in IL-2 express the endogeneous mouse IL-2Rα chain. When grown in IL-4, the endogeneous mouse IL-2Rα gene remains silent in all these transfectants. These results show that, contrary to the human, the mouse does not express an intermediate-affinity IL-2R. Expression of the IL-2Rα gene is therefore required for the formation of the functional IL-2R in mice.     

The cytoplasmic tail of the T cell receptor ζ chain is required for signaling via CD26

The protease dipeptidylpeptidase IV (CD26) provides an alternative activation pathway for T lymphocytes and is involved in several aspects of T cell function. Activation via CD26 requires the expression of the T cell receptor (TcR)/CD3 complex. Here we have investigated the role of the TcR ζ chain for T cell activation via CD26. T cell hybridomas expressing TcR with various deletions in the CD3 ζ chain were transfected with a CD26 cDNA and the response of the transfected cells to anti-CD26 monoclonal antibodies was tested. Our data show that the ζ chain is essential and that at least one YXXL motif in the cytoplasmic tail of the ζ chain is required for CD26-mediated signaling. Other TcR components do not replace the ζ chain.     

T cell receptor-γδ-expressing fetal mouse thymocytes are generated without T cell receptor Vβ selection

We investigated whether fetal mouse T cell receptor (TCR) γδ cells have been subjected to so-called TCRβ selection at the CD25 stage of thymus development. To this end, we carried out a comparative three-color flow microfluorimetric analysis of TCRβδ cells developing in the fetal, neonatal and adult thymus using monoclonal antibodies to CD2, CD8, CD24, CD25 and CD44. Day-15 fetal TCRγδ cells were CD2⁺, suggesting an origin at a post-CD25 stage. Molecular analysis of TCRβ rearrangements were also carried out. Thus, by semi-quantitative polymerase chain reaction (PCR) amplification of Vβ6 and Vβ8 to Jβ2 rearrangements day-15 fetal TCRγδ showed extensive TCRβ rearrangements, a finding confirmed by PCR amplification from single micromanipulated cells. Finally, sequencing analysis of 104 PCR-amplified TCR VDJβ2 fragments showed that the majority (58%) were rearranged out of frame. Taken together, these phenotypic and molecular analyses suggest that fetal TCRγδ cells have not been subject to TCRβ selection.     

The expression of γΔ T cell receptor and the prevalence of primed,activated and IgA-bound T cells in Behçet's syndrome

Mucosal ulceration of the oral, and to a lesser extent genital tissues is an essential feature of Behçet''s syndrome and is associated with changes in the IgA class of immune responses. Indeed, a significant increase in the proportion of cytophilic IgA1 was found in circulating CD8 and CD4 cells (P less than 0.01), with a corresponding decrease in IgA-Fc receptors on these T cells. Furthermore, 30-40% of the cytophilic IgA1 on T cells may have been of the polymeric secretory type and the rest of the monomeric variety. IgA isotype of B cells was also significantly increased (P less than 0.001), without an overall change in circulating B cells. However, a surprising finding was the significant up-regulation of gamma delta T cell receptor in the CD8 (P less than 0.01) in the absence of a change in the proportion of alpha beta T cell receptor. The results suggest that some common microbial antigen might initiate at the mucosal surface an immune defence reaction characterized by T cells with gamma delta receptors and IgA-specific B cells. However, IgA1 bound to circulating T cells may down-regulate the central T cell function.     

Evidence that productive rearrangements of TCR γ genes influence the commitment of progenitor cells to differentiate into αβ or γδ T cells

Two models have been considered to account for the differentiation of γδ and αβ T cells from a common hematopoietic progenitor cell. In one model, progenitor cells commit to a lineage before T cell receptor (TCR) rearrangement occurs. In the other model, progenitor cells first undergo rearrangement of TCRγ, δ, or both genes, and cells that succeed in generating a functional receptor commit to the γδ lineage, while those that do not proceed to attempt complete β and subsequently α gene rearrangements. A prediction of the latter model is that TCRγ rearrangements present in αβ T cells will be nonproductive. We tested this hypothesis by examining Vγ2-Jγ1Cγ1 rearrangements, which are commonly found in αβ T cells. The results indicate that Vγ2-Jγ1Cγ1 rearrangements in purified αβ T cell populations are almost all nonproductive. The low frequency of productive rearrangements of Vγ2 in αβ T cells is apparently not due to a property of the rearrangement machinery, because a transgenic rearrangement substrate, in which the Vγ2 gene harbored a frame-shift mutation that prevents expression at the protein level, was often rearranged in a productive configuration in αβ T cells. The results suggest that progenitor cells which undergo productive rearrangement of their endogenous Vγ2 gene are selectively excluded from the αβ T cell lineage.     

Developmental expression of the αIELβ7 integrin on T cell receptor γδ and T cell receptor αβ T cells

A novel monoclonal antibody, 2E7, was shown by immunoprecipitation to be reactive with the α_IELβ7 integrin and was employed to analyze the expression of this integrin in lymphocyte subsets and during T cell ontogeny. In adult lymph nodes, α_IEL was expressed at low levels by 40–70% of CD8⁺ T cells and < 5% of CD4⁺ T cells. However, virtually all intestinal intraepithelial lymphocytes and ?20% of lamina propria CD4⁺ T cells were 2E7⁺, indicating a preferential expression of this integrin on mucosal T cells. Examination of α_IEL integrin expression during thymus ontogeny revealed that ?3–5% of fetal or adult thymocytes were 2E7⁺. Interestingly, early in fetal thymus ontogeny, ?40% of 2E7⁺ cells expressed T cell receptor (TcR)-γδ and this subset persisted through birth. A developmental switch occurred such that 2E7⁺ TcR^? CD4^?8⁺ cells detected on fetal day 19 were followed by 2E7⁺ TcR-αβ CD4^?8⁺ cells in the neonatal thymus. The latter population persisted throughout thymus ontogeny into adulthood. Interestingly, a subset of TcR-γδ Vγ3⁺ day 16 fetal thymocyte dendritic epidermal cell (DEC) precursors were 2E7⁺, but all mature DEC expressed high levels of α_IEL integrin, suggesting that the α_IEL integrin was acquired late in DEC maturation. This possibility was strenghthened by immunohistochemical localization of the majority of 2E7⁺ γδ and αβ T cells to the medullary regions of the thymus. Overall, the results demonstrate a developmentally ordered expression pattern of the α_IELβ₇ integrin that suggests a common function for this integrin during TcR-γδ and -αβ CD4^?8⁺ T cell thymocyte development or perhaps in effector functions for these subsets.     

Development of γδ T cells in the adult murine thymus

The development of T cells belonging to the γδ lineage is not well understood. We have analyzed the cells in the adult murine thymus which express the γδ TcR on the surface in order to learn more about this process. Our data demonstrate a number of clear subpopulations of γδ expressing cells in the thymus based on the expression of Thy-1 and HSA (heat-stable antigen). Only one of these subpopulations, the one expressing both Thy-1 and HSA, contains dividing cells or has a significant rate of turnover. Together with the fact that emigrant γδ cells are HSA⁺Thy-1⁺, this suggests that this thymic subpopulation is the sole, or major, source of exported cells. However, the turnover of cells from this population is 5 × 10⁴ - 10 × 10⁴ cells per day, while previous estimates of the rate of export of γδ cells are in the order of 10⁴ cells per day. Furthermore the Vγ profile of recent γδ⁺ emigrants differs from that of the thymic HSA⁺Thy-1⁺ cells. This raises the possibility that only a selected subpopulation of the thymic γδ⁺HSA⁺Thy-l⁺ population is exported, and that some γδ cells may die in situ in the thymus. The function of the other γδ thymic subpopulations, which are turning over very slowly or not at all, (i.e. the HAS^?Thy-l^? and HAS^?Thy-l⁺ subpopulations) remains unclear.