Activation of T lymphocytes through the Ly-6 pathway is defective in A strain mice

The Ly-6 alloantigens have been shown to participate in the process of T cell activation based on the ability of anti-Ly-6 mAb to induce IL-2 production and proliferation of T lymphocytes. In the present investigation we have demonstrated that peripheral T lymphocytes from A strain mice exhibited abnormally low proliferative responses after stimulation through Ly-6A/E and Ly-6C molecules when compared to responses of T cells from numerous other mouse strains. The abnormal activation of the Ly-6 pathway of A strain T cells was not due to ineffective FcR cross-linking of the anti-Ly-6 mAb, to inappropriate cellular expression of the Ly-6A/E alloantigen in A strain T cells, or to an active suppressive phenomenon. T lymphocytes from A strain mice proliferated normally when the cells were activated by mAb to Thy-1 or the CD3/TCR complex suggesting that A strain mice did not exhibit a generalized T cell activation defect. Cell separation studies of T cells and accessory cells demonstrated that this defect was quantitative, rather than qualitative, and that it was complex, residing at both the T cell and accessory cell levels. These results suggest that activation of T lymphocytes via the Ly-6 molecule may involve a signaling pathway and/or cell-cell interactions distinct from those required for optimal activation via CD3/TCR.     

Selection of T cell receptor expression mutants through the functionally linked Ly-6A

Ly-6A is a glycosyl-phosphatidylinositol (GPI)-anchored molecule that participates in murine T cell activation. Activation of T cell hybridomas with anti-Ly-6A monoclonal antibody (mAb) leads to production of interleukin-2 (IL-2), but also to a paradoxical growth inhibition, which was used to select for signaling mutants. Fifteen subclones derived from two independent mutageneses and anti-Ly-6A selection were characterized. Thirteen subclones responded poorly or not at all to soluble anti-Ly-6A mAb. Although the selective pressure was exerted through Ly-6A, only one mutant did not express the Ly-6A antigen. Interestingly, 10 of the 15 subclones expressed either nondetectable or a very low level of T cell receptor/CD3 complex (TCR/CD3). Preferential expansion of TCR/CD3 expression mutants following anti-Ly-6A selection further established functional linkage between Ly-6A and TCR/CD3 complex. The mechanism of the functional coupling was investigated by analyzing the hydrolysis of phosphatidylinositol 4,5-bisphosphate (PIP2), one of the early events in T cell activation. We showed that PIP2 was not hydrolyzed in response to anti-Ly-6A in TCR/CD3-negative mutants. Aluminum fluoride, which activates G protein directly, did induce PIP2 hydrolysis in these cells. These data suggest that activation signals originated from Ly-6A must be transmitted first to TCR/CD3 complex, which then couples to the G protein/phospholipase C system. A similar requirement also applies to the Thy-1 protein and lectin receptors. Thus, the TCR/CD3 complex plays a central role in the integration and transmission of activation signals that originated from several T cell surface molecules.     

Activation-driven T cell death. II. Quantitative differences alone distinguish stimuli triggering nontransformed T cell proliferation or death.

Clonal deletion is the major mechanism by which T cell tolerance is achieved in vivo. The process of activation-driven cell death, originally characterized with T cell hybridomas, likely represents the mechanism of clonal deletion because it shares a number of properties with the in vivo process, especially the ability to be triggered in an Ag-specific manner, the cell-autonomous nature of the response, and its sensitivity to the drug cyclosporin A. We now have extended our analysis of activation-driven cell death to clonal populations of nontransformed T cells. Activation-driven cell death can be induced in nontransformed T lymphocytes by combinations of mitogenic stimuli. In particular, two mitogenic stimuli at high dose, one a lymphokine and the other delivered via the TCR or another activation structure, are required to induce activation-driven cell death. Activation-driven cell death is an active cell suicide process with attributes typical of physiological cell death, including early nuclear disintegration and a requirement for macromolecular synthesis, and is distinct from death by factor deprivation. Susceptibility to the induction of cell death by antigenic or activating stimulation is a common aspect of most T cells and is consistent with observations that clonal deletion can occur throughout T cell ontogeny. Most importantly, the alternative cellular responses of cell death and cell proliferation in nontransformed T cells appear to be triggered solely as a function of quantitative differences in the doses of identical stimuli. This can be viewed as a dose-dependent switch that determines cell fate. Developmental regulation of this switch may explain the processes of positive and negative selection during T cell ontogeny and also provide a mechanistic rationale for a strategy of selective anti-tumor therapy.     

sgp-60, a signal-transducing glycoprotein concerned with T cell activation through the T cell receptor/CD3 complex

T cell activation depends not only on the expression of a TCR, but also on that of accessory molecules that function in cell-cell adhesion and/or signal transduction. The subject of this report is the biochemical and functional characterization of what appears to be a novel murine lymphocyte cell surface antigen, provisionally termed sgp-60. Extensive, higher-order cross-linking of this glycoprotein with an anti-sgp-60 mAb and a second-step antibody reagent results in the activation of resting CD4+ T cells in the presence of a second signal. Monovalent or bivalent engagement of sgp-60 by the anti-sgp-60 antibody results in profound and direct inhibition of anti-CD3- or Con A-driven T cell activation, whereas alternative T cell activation via the phosphatidylinositol-linked proteins Thy-1 and TAP/Ly-6A is not affected. These findings raise the possibility that the sgp-60 molecule may be specifically involved in signal transduction through the TCR/CD3 complex and thus point to an important physiologic role for this protein in CD4+ T cells.     

Internalization of phosphatidylinositol-anchored lymphocyte proteins. I. Documentation and potential significance for T cell stimulation

Several proteins that are anchored to the surface of T lymphocytes via a phosphatidylinositol (PI) moiety can initiate cell stimulation upon cross-linking. Inasmuch as these proteins do not traverse the plasma membrane, it is not clear how they are capable of signaling across the membrane. Herein we report two distinct sets of experiments that examine the consequence of cross-linking PI-anchored molecules on murine T cells. We first analyzed the fate of antibody cross-linked TAP (Ly-6A.2) and Thy-1 molecules on T-T hybrids. Using an assay to measure receptor-mediated endocytosis, an intracellular accumulation of 125I labeled anti-TAP and anti-Thy-1 mAb was documented that was specific and Ag dependent. The internalization of these molecules was confirmed by cytotoxicity assays using antibody-toxin conjugates, and electron microscopic studies. Although the PI-anchored proteins lack a cytoplasmic domain that is necessary for the internalization of many receptors, they nevertheless can be induced to enter the cell upon cross-linking. The rate of entry of cross-linked TAP and Thy-1 into cells was shown to be 10 and 2% per hour, respectively, which is considerably less than that observed for the transferrin receptor or TCR/CD3 complex. To assess whether the internalization of TAP and Thy-1 might be of importance in their ability to stimulate T cells, we attempted to cross-link these molecules under conditions where the mAb or its cross-linked complex can not enter the cell. We observed that anti-TAP and anti-Thy-1 mAb conjugated to a cell impermeant matrix fail to stimulate T cells. This loss of stimulatory activity was observed with multiple T-T hybridomas and mAb over a wide titration of antibody concentration and was independent of the mAb isotype. Results from experiments with anti-Ig cross-linking of the mAb-PI anchored protein complex suggested that the loss of T cell stimulation upon mAb immobilization is not simply due to an alteration in the degree of antibody cross-linking. These findings were generalized to three distinct PI-anchored proteins: TAP, Thy-1, and Ly6C on normal T cells. When the same cells were stimulated through the TCR/CD3 complex, only immobilized mAb are stimulatory. These results demonstrate a marked difference in the cross-linking requirements for stimulating T cells through PI-anchored molecules in contrast to the transmembrane TCR complex. Furthermore, these findings raise the possibility that molecular internalization of Ab-PI-anchored complexes may be necessary in signaling through these molecules.     

Thy-1-negative and Ly-1-negative variants of T cells produce interleukin 2 in response to mitogens

IL 2 production by T cell variants, which lack the Thy-1 or Ly-1 surface glycoproteins, was studied. Cross-linking of the Thy-1 molecule resulted in IL 2 production by the EL4 thymoma and by a T cell hybridoma, suggesting that Thy-1 may play a role in T lymphocyte triggering. To further study the functional role of this molecule, Thy-1-negative variants were selected and analyzed for IL 2 production in response to phorbol-12-myristate-13-acetate (PMA) or to Con A. It was demonstrated that in spite of their failure to express Thy-1, the Thy-1-negative clones were capable of IL 2 production. These results indicated that although Thy-1 cross-linking triggers cell activation, a signal provided by Thy-1 is not indispensable for cell activation by mitogens. The T cell tumor line LBRM331A5 responds synergistically to IL 1 and PHA by releasing IL 2. It was demonstrated that anti Ly-1 monoclonal antibodies and PHA co-stimulated LBRM331A5 cells, as did IL 1 plus PHA. Thus, anti Ly-1 antibodies mimic the effect of IL 1, suggesting a role for Ly-1 antigen in T cell activation, perhaps by serving as an IL 1 receptor or as an associated molecule. To further study the functional role of Ly-1 and its relation to IL 1 receptor, Ly-1-negative variants of the LBRM331A5 cell line were selected and analyzed for IL 2 production in response to PHA plus IL 1. It was demonstrated that the Ly-1-negative clones were capable of IL 2 production as efficiently as Ly-1-positive clones. These results indicate that the Ly-1 and IL 1 receptor are distinct molecules, which are involved in different activation pathways.     

Stimulation of T cells via the TAP molecule, a member in a family of activating proteins encoded in the Ly-6 locus

T-cell activating protein, TAP, is a Ly-6 encoded 12,000 dalton glycoprotein involved in the activation of murine T cells. TAP is distinct from other known surface activating structures, such as the T cell receptor/T3 complex and Thy-1. This study investigates the mechanism of activation via the TAP molecule. Soluble alpha TAP monoclonal antibody (MAb) is sufficient for T cell activation. This, however, requires cross-linking because F(ab) monovalent antibody is not stimulatory unless cross-linked by a second antibody. Immediately after cross-linking, there is a rapid influx of calcium, which is comparable with concanavalin A or T cell receptor triggered responses. Subsequently, interleukin 2 (IL 2) is produced, and IL 2 receptors (IL 2R) are expressed. TAP-stimulated T cell proliferation is driven by this autocrine pathway because it is inhibited by alpha IL 2R MAb. Thus TAP-mediated activation appears to share a common final pathway with other mitogenic stimuli. A nonactivating alpha TAP MAb was observed to stimulate T cells upon additional cross-linking. Given this observation, we asked whether other Ly-6 linked proteins might share similar activating potential. We show that at least three distinct Ly-6 linked molecules are capable of stimulating T hybrid clones and/or heterogeneous T lymphocytes. Thus it appears that the Ly-6 locus encodes a family of activating cell surface molecules.     

Ly-6A is required for T cell receptor expression and protein tyrosine kinase fyn activity.

To characterize the function of the Ly-6A antigen in T cell activation, antisense Ly-6 RNA was expressed in a stably transfected antigen-specific T cell clone. Reduced Ly-6A expression results in inhibition of responses to antigen, anti-TCR (anti-T cell receptor) crosslinking and concanavalin A plus recombinant interleukin 1 and causes impairment of in vitro fyn tyrosine kinase activity. More substantial reduction of Ly-6A results in reduction of TCR expression. Analysis of mRNA species indicates that the reduction is specific for the TCR beta chain. These data demonstrate that Ly-6A may regulate TCR expression and may be involved in early events of T cell activation via regulation of fyn tyrosine kinase activity.     

Thy-1: more than a mouse pan-T cell marker

Thy-1 (CD90) is a small GPI-anchored protein that is particularly abundant on the surface of mouse thymocytes and peripheral T cells. T cell proliferation and cytokine synthesis in response to Thy-1 cross-linking by specific mAb suggests a role for Thy-1 in mouse T lymphocyte activation. However, a physiological ligand or counterreceptor for murine Thy-1 in the lymphoid compartment has not yet been identified. Thy-1 cross-linking, in the context of strong costimulatory signaling through CD28, results in an activating signal that can at least partially substitute for TCR signaling during mouse T cell activation. Remarkably, Thy-1 cross-linking also results in the potent costimulation of T cells activated through the TCR. This novel dual signaling capacity suggests a possible role for Thy-1 in the maintenance of T cell homeostasis in the absence of TCR triggering, as well as potentiating Ag-induced T cell responses.     

Down-regulation of IL-2 production by activation of T cells through Ly-6A/E

Ly-6A/E molecules are expressed on the surface of T cells and have been shown to function in activation by the capacity of anti-Ly-6A/E mAb to induce T cell hybridomas or normal T cells to produce IL-2. Recent evidence suggests that activation through Ly-6A/E may be linked to the TCR signaling pathway. To further investigate the relationship between Ly-6- and TCR-induced T cell activation, we have examined whether an anti-Ly-6A/E mAb (D7) modulates TCR signaling in vitro. We now report that mAb D7 specifically inhibited IL-2 production by T cells also activated through TCR. Such inhibition was noted for normal T cells stimulated by soluble anti-CD3 or alloantigen and for T hybridomas stimulated by soluble anti-CD3. The ability of D7 to inhibit IL-2 production by T hybridomas was dependent on the nature of the TCR activating signal because IL-2 production was not inhibited when T hybridomas were stimulated with Ag or immobilized anti-CD3. Inhibition of IL-2 production by D7 apparently required cross-linking of the mAb because D7 F(ab')2 fragments were not effective for inhibition of IL-2 production. Similar to its ability to enhance anti-Ly-6A/E-induced activation of T and B cells, IFN-gamma enhanced the D7-induced inhibition of IL-2 production by alloantigen-activated normal T cells. These data further support the notion that Ly-6 and TCR signaling pathways are interrelated.     

Structure/function relationship of activating Ly-49D and inhibitory Ly-49G2 NK receptors.

Murine NK cells express Ly-49 family receptors capable of either inhibiting or activating lytic function. The overlapping patterns of expression of the various receptors have complicated their precise biochemical characterization. Here we describe the use of the Jurkat T cell line as the model for the study of Ly-49s. We demonstrate that Ly-49D is capable of delivering activation signals to Jurkat T cells even in the absence of the recently described Ly-49D-associated chain, DAP-12. Ly-49D signaling in Jurkat leads to tyrosine phosphorylation of TCRzeta and requires Syk/Zap70 family kinases and arginine 54 of Ly-49D, suggesting that Ly-49D signals via association with TCRzeta. Coexpression studies in 293-T cells confirmed the ability of Ly-49D to associate with TCRzeta. In addition, we have used this model to study the functional interactions between an inhibitory Ly-49 (Ly-49G2) and an activating Ly-49 (Ly-49D). Ly-49G2 blocks activation mediated by Ly-49D in an immunoreceptor tyrosine-based inhibitory motif (ITIM)-dependent manner. In contrast, Ly-49G2 was incapable of inhibiting activation by the TCR even though human killer cell inhibitory receptor (KIR) (KIR3DL2(GL183)) effectively inhibits TCR. Both the ability of Ly-49G2 to block Ly-49D activation and the failure of Ly-49G2 to inhibit TCR signaling were confirmed in primary murine NK cells and NK/T cells, respectively. These data demonstrate the dominant effects of the inhibitory receptors over those that activate and suggest an inability of the Ly-49 type II inhibitory receptors to efficiently inhibit type I transmembrane receptor signaling in T cells and NK cells.     

T cell receptor/CD3 negative variants are unresponsive to stimulation through the Ly-6 encoded molecule, TAP

TAP is a phosphatidylinositol-anchored Ly-6-encoded, glycoprotein that is involved in the activation of murine T-inducer cells. Anti-TAP antibodies can stimulate T cells directly and also synergize with Ag stimulation. To determine the relationship between TAP and TCR-mediated activation, we have derived TCR/CD3 loss variants of functional T hybrid clones. T-T hybrid variants that have lost TCR expression are not responsive to anti-TAP stimulation. Isolation and analysis of revertant clones, obtained from one of the TCR/CD3-negative mutant cell lines, demonstrate a concordant re-expression of the TCR/CD3 complex and responsiveness to anti-TAP stimulation. A similar loss of responsiveness to TAP stimulation is observed after antibody-induced modulation of the TCR/CD3 complex from the surface of T cell hybrids. In contrast, both the TCR/CD3 loss variants and TCR/CD3-modulated T-T hybrids remain fully responsive to stimulation with a calcium ionophore and phorbol esters. This structure-function correlation has been observed repeatedly in independent isolations of variants, and with TCR/CD3 modulated cells, from two different T-T hybridomas. Given the apparent functional interrelationship between TAP and the TCR/CD3 complex, we have also analyzed if these molecules were significantly associated on the T cell surface. Antibody-induced modulation of the TCR/CD3 complex does not affect the cell surface expression of TAP molecules. Moreover, the expression of these two sets of proteins is also independent as evidenced by the selective loss of either set of these proteins in the TCR/CD3 expression mutants.     

Phenotypic and functional analysis of gamma delta T cell receptor-positive murine dendritic epidermal clones

Thy-1+ dendritic cells isolated from the epidermis of normal mice (dEC)3 bear the gamma delta TCR associated with the CD3 complex. We have analyzed the effects of antibodies directed against the TCR complex, Ly-6C, and Thy-1, as well as pharmacologic agents which have been shown to activate T cells without engagement of the TCR complex, on levels of intracellular free calcium, activation of protein kinase C, cytolysis, IL-2R expression, and secretion of lymphokines by dEC clones. We have found that the dEC cells express a fully functional TCR complex which can function to transmit signals upon perturbation leading to an increase in IL-2R expression, release of lymphokines, and cytolytic activity. These results indicate that the gamma delta TCR+ dEC are capable of responding to activation signals in the same manner as mature alpha beta TCR+ cells and suggests that they may play a functional role in the skin.     

Stimulation of murine T cells via the Ly-6C antigen: lack of proliferative response in aberrant T cells from lpr/lpr and gld/gld mice despite high Ly-6C antigen expression

Cross-linking of cell surface Ly-6C molecules with the 6C3 rat monoclonal antibody (MAb) followed by anti-rat immunoglobulin antibody acts in concert with phorbol myristate acetate (PMA) as a potent mitogenic stimulus for normal T cells. Specificity of this stimulation was demonstrated by its absence in T cells from NZB, NOD, or STb/J mice which lack the 6C3 determinant. In 6C3+ normal strains, the extent of 6C3-mediated stimulation varied, depending on the level of 6C3 antigen expression. Analysis of this stimulation in purified T cell subsets revealed that in Ly-6.1 strains (e.g., BALB/c, CBA/J), Lyt-2+ cells responded, but not L3T4+ cells, whereas in Ly-6.2 strains (e.g., C57BL/6, MRL-+/+), both subsets produced IL 2 and proliferated, although with different kinetics. Moreover, in adult MRL-+/+ mice, the minor Lyt-2-/L3T4- subset from the lymph nodes gave low responses to 6C3 cross-linking, whereas that from the thymus reacted strongly. Stimulation via Ly-6C therefore provides a pathway for differential activation of normal T cells. In contrast, the expanding population of Lyt-2-/L3T4- T cells from lpr/lpr or gld/gld mice did not proliferate in response to 6C3 antigen cross-linking plus PMA despite high levels of 6C3 antigen expression. Responsiveness of lpr/lpr T cells could not be restored with IL 1, IL 2, or both. These T cells also failed to be triggered by conjunction of PMA with either Thy-1 antigen cross-linking or concanavalin A. Moreover, they were not stimulated, in the presence of PMA, by doses of ionomycin that were optimal for normal T cells, but did respond to higher ionomycin concentrations (2 micrograms/ml), and this response was not altered by Ly-6C cross-linking. It is concluded that the Ly-6C pathway of T cell activation is not functional in the aberrant lpr/lpr (and gld/gld) T cells, and that this defect may reflect abnormalities of intracellular signaling.     

Stimulation of human Jurkat cells by monoclonal antibody crosslinking of transfected-Ly-6A.2 (TAP) molecules.

Monoclonal antibody crosslinking of phosphatidylinositol-anchored Ly-6A.2 molecules on the surface of murine T lymphocytes leads to cell activation and secretion of IL-2. To examine the potential activity of these molecules in human T cells we transfected the Ly-6A.2 gene into Jurkat cells. Transfection of Jurkat cells with genomic Ly-6A.2 sequences results in low levels of Ly-6A.2 on the cell surface. However, linking the Ly-6A.2 sequences to the enhancer from the human CD2 gene results in greatly increased expression of Ly-6A.2. These molecules are anchored to the membrane via a phosphatidylinositol linkage. Crosslinking of Ly-6A.2 molecules with soluble mAb stimulates the transfected Jurkat cells to produce IL-2. This stimulation is abrogated by treatment with phosphatidylinositol-specific phospholipase C. The transfected human T cells displayed the same unusual crosslinking requirements for stimulation with anti-Ly-6A.2 mAbs as previously observed for murine T cells. Crosslinking of Ly-6A.2 with soluble antibodies is stimulatory, whereas immobilized antibodies are inactive. The crosslinking requirements for antiCD3 mAb stimulation display a reciprocal pattern. These data demonstrate that the Ly-6A.2 pathway for T cell activation is conserved between human and murine T cells.     

Tyrosine phosphorylation of the human T cell antigen receptor zeta-chain: activation via CD3 but not CD2

TCR stimulation by Ag or anti-receptor antibodies in murine T cells results in the activation of two independent protein kinases, protein kinase C (PKC) and a protein tyrosine kinase. Similarly, stimulation of murine Thy-1 or Ly-6 with mAb also results in activation of both of these kinase pathways. Tyrosine phosphorylation in all cases occurs on the TCR zeta-chain. It is known that Ag and anti-receptor antibodies activate PKC in human T cells. In this study we demonstrate that mitogen or anti-CD3 antibodies activate tyrosine phosphorylation of the human TCR-zeta-chain. PMA, which activates PKC, does not result in zeta-chain tyrosine phosphorylation. Stimulation of human T cells by antibodies that bind the CD2 molecule is an alternate mode of inducing T cell proliferation. These antibodies surprisingly do not induce tyrosine phosphorylation of the zeta-chain. Thus, different methods of cellular activation can result in distinguishable patterns of receptor-mediated biochemical signaling events.     

Identification of early stages of T lymphocyte development in the thymus cortex and medulla

Thymocyte subpopulations with a phenotype suggesting they are early stages of T cell development in the adult mouse thymus were characterized and isolated by using multiparameter flow cytometry and sorting, in conjunction with selective killing with antibody and complement (C). The intrathymic localization of these subpopulations was assessed by dipping the thymus in fluorescent dyes to selectively label outer-cortical cells. The main phenotypic markers used were sensitivity to C-mediated lysis by the monoclonal antibody B2A2 (which spares most prothymocytes but kills most thymocytes), the expression of the T cell lineage specific markers Ly-2 and L3T4, and the levels of the common T cell antigens Ly-1 and Thy-1. A preliminary selection for cells lacking Ly-2 and L3T4, or resistant to B2A2 and C, produced a population of large cells, only 5% of all thymocytes and distinct from the typical cortical blast cells. This population of putative early thymocytes was itself heterogeneous, consisting of eight subpopulations separable by phenotype and intrathymic localization. One group of two subpopulations (B2A2-, Ly-1++, Thy-1+ and either Ly-2+ L3T4- or Ly-2- L3T4+) appeared to be of medullary location, and their phenotype suggested they could have been early members of the medullary lineages. Another group of two subpopulations (B2A2-, Ly-1++, Thy-1-, Ly-2-, L3T4- and B2A2-, Ly-1++, Thy-1+, Ly-2- L3T4-) did not show a clear localization pattern and may have represented cells in an earlier stage of transition to medullary phenotype and location. A quite different group of three subpopulations (B2A2++, Ly-1-, Thy-1-, Ly-2- L3T4-; B2A2++, Ly-1-, Thy-1+, Ly-2-, L3T4-; and B2A2++, Ly-1+, Thy-1++, Ly-2- L3T4-) was concentrated in the outer cortex and seemed to represent a series of stages of a cortical pathway, before the typical cortical blast cells. Finally, a very minor subset (0.2% of thymocytes), lacking all these markers, was concentrated in the outer cortex; this fifth group had the phenotype expected of the earliest intrathymic precursor cells. The results suggest that the separate developmental streams of cortical and medullary thymocytes may be traced back, via these minor early blast subpopulations, to common precursor cells in the outer cortex.     

IL-7-regulated homeostatic maintenance of recent thymic emigrants in association with caspase-mediated cell proliferation and apoptotic cell death

Homeostasis of T cells is essential to the maintenance of the T cell pool and TCR diversity. In this study, mechanisms involved in the regulation of cytokine-mediated expansion of naive T cells in the absence of Ag, in particular the role of caspase activation and susceptibility to apoptosis of recent thymic emigrants (RTEs), were examined. Low level caspase-8 and caspase-3 activation was detected in proliferating IL-7-treated cells in the absence of cell death during the first days of culture. Caspase inhibitors suppressed IL-7-induced expansion of RTEs. Low level expression of CD95 and blocking Ab experiments indicated that this early caspase activation was CD95 independent. However, CD95 levels subsequently became dramatically up-regulated on proliferating naive T cells, and these cells became susceptible to CD95 ligation, resulting in high level caspase activation and apoptotic cell death. These results show a dual role for caspases in proliferation and in CD95-induced cell death during Ag-independent expansion of RTEs. This method of cell death in IL-7-expanded RTEs is a previously unrecognized mechanism for the homeostatic control of expanded T cells.     

Evidence of synergy between Thy-1 and CD3/TCR complex in signal delivery to murine thymocytes for cell death.

The potential role of Thy-1 in CD3/TCR complex-mediated signal delivery to murine thymocytes was studied. Ag-mimicking cross-linked anti-CD3 mAb stimulated suspension of thymocytes from adult (6 to 8 wk old) mice for a brisk free cytoplasmic calcium ion ([Ca2+]i) rise, low level of inositol phosphate production, and marginal increase in tyrosine-specific phosphorylation of 110/120-kDa and 40-kDa cellular proteins. Weak but sustained [Ca2+]i rise, low inositol phosphate production, and weak protein tyrosine phosphorylation were also induced by the cross-linked anti-Thy-1 mAb that mimicked the putative natural ligand. The signal delivered via either of these two pathways was however insufficient for definitively promoting cell death and DNA fragmentation in the adult thymocytes. Here we demonstrated that anti-Thy-1 mAb synergized with anti-CD3 mAb for inducing a long-lasting prominent [Ca2+]i rise, definite inositol 1,4,5-triphosphate and inositol 1,3,4,5-tetrakiphosphate production, and extensive tyrosine-specific phosphorylation of 110/120-, 92-, 75-, and 40-kDa proteins, which resulted in marked promotion of cell death and DNA fragmentation in the adult thymocytes. This unique anti-Thy-1 antibody activity was confirmed to be directed to glycosylphosphatidylinositol-anchored Thy-1, and was distinguished from the known anti-L3T4 activity that augmented the CD3-mediated signal transduction in a different manner. The synergistic actions of anti-CD3 and anti-Thy-1 mAb obligatorily required the cross-linking of the two mAb together. The anti-CD3 and anti-Thy-1 mAb cross-linked together acted on immature thymocytes from newborn (less than 24 h after birth) mice for rather more extensive promotion of protein tyrosine phosphorylation and cell death. In addition, they affected peripheral T lymphocytes for accelerating protein tyrosine phosphorylation but not cell death. These results suggest a novel function of glycosylphosphatidylinositol-anchored Thy-1 as a possible unique intrathymic intensifier of the CD3/TCR complex-delivered signal for negative thymocyte selection.