Differential responses of invariant V alpha 24J alpha Q T cells and MHC class II-restricted CD4+ T cells to dexamethasone.

NK T cells are a T cell subset in the human that express an invariant alpha-chain (V alpha 24invt T cells). Because of the well-described immunomodulation by glucocorticoids on activation-induced cell death (AICD), the effects of dexamethasone and anti-CD3 stimulation on V alpha 24invt T cell clones and CD4+ T cell clones were investigated. Dexamethasone significantly enhanced anti-CD3-mediated proliferation of V alpha 24invt T cells, whereas CD4+ T cells were inhibited. Addition of neutralizing IL-2 Ab partially abrogated dexamethasone-induced potentiation of V alpha 24invt T cell proliferation, indicating a role for autocrine IL-2 production in corticosteroid-mediated proliferative augmentation. Dexamethasone treatment of anti-CD3-stimulated V alpha 24invt T cells did not synergize with anti-Fas blockade in enhancing proliferation or preventing AICD. The V alpha 24invt T cell response to dexamethasone was dependent on the TCR signal strength. In the presence of dexamethasone, lower doses of anti-CD3 inhibited proliferation of V alpha 24invt T cells and CD4+ T cells; at higher doses of anti-CD3, which caused inhibition of CD4+ T cells, the V alpha 24invt T cell clones proliferated and were rescued from AICD. These results demonstrate significant differences in TCR signal strength required between V alpha 24invt T cells and CD4+ cells, and suggest important immunomodulatory consequences for endogenous and exogenous corticosteroids in immune responses.     

Signals delivered via MHC class II molecules synergize with signals delivered via TCR/CD3 to cause proliferation and cytokine gene expression in T cells.

We examined the role of MHC class II molecules in transducing signals to activated human T cells. Cross-linking of MHC class II molecules synergized with submitogenic amounts of anti-CD3 mAb in causing proliferation and secretion of the cytokines IL-2, IL-3, IFN-gamma, and TNF-alpha by MHC class II-alloreactive T cell lines. Signaling via MHC class II molecules in T cells resulted in activation of tyrosine kinases, in generation of inositol phosphates, and in Ca2+ mobilization that was abrogated by the tyrosine kinase inhibitor herbimycin A. Thus, like signaling via TCR/CD3, signaling via MHC class II molecules involved tyrosine kinase-dependent activation of phospholipase C, resulting in phosphoinositol turnover and Ca2+ flux. However the signaling pathways coupled to MHC class II molecules and to TCR/CD3 differed, because engagement of the transmembrane phosphatase CD45 inhibited Ca2+ fluxes triggered via TCR/CD3 but not Ca2+ fluxes triggered via MHC class II molecules.     

Inhibition of CD4+ T cell activation and adhesion by peptides derived from the gp160.

It has been previously demonstrated that the HIV envelope glycoprotein gp160 can inhibit the activation of T cells triggered by phytohemagglutinin, anti-CD3 antibody and Ag, caused in part by the modulation of the expression of CD4. In this study, we show that gp160 is also able to inhibit the Ag-independent adhesion of CD4+ T cells to B cells as anti-CD4 antibodies do. In addition, synthetic peptides (14 to 21 mer) derived from the gp160 sequence and analogous to the putative binding site of gp160 to CD4 (residues 418-460), and also covering residues 460 to 474 inhibit the capacity of both CD4+ T cell proliferation induced by tuberculin and anti-CD3 antibody and adhesion. This was not associated with inhibition of Ca2+ flux in T cell activation. These inhibitory activities are specific because a) CD4+ T cells but not CD8+ T cells are susceptible to their effects, and b) soluble CD4 neutralizes the inhibitory activities. Peptides are, however, about 100- to 1000-fold less potent inhibitors than the native gp160. In addition, they do not induce CD4 modulation. It is thought therefore that at least part of the gp160 inhibitory activity is not secondary to CD4 modulation but may rely either upon steric hindrance of CD4-MHC class II interaction, of CD4/CD3 TCR complex interaction, or upon negative signaling through binding to CD4. The latter hypothesis is suggested by the inhibition by gp160, gp160-derived peptides, and anti-CD4 antibodies of the Ag-independent adhesion of CD4+ T cells. This adhesion process has been previously shown to be mediated by the LFA-1 and CD2 molecules and not by the TCR/CD3 complex and by CD4. Together, these results support the role of part of the 418-460 region of gp160 as a binding site to CD4, and suggest that binding of part of this region to CD4 can alter T cell proliferation and adhesion. It is proposed that these effects are mainly mediated by negative signaling through CD4.     

Clonal anergy is maintained independently of T cell proliferation

Ag encounter in the absence of proliferation results in the establishment of T cell unresponsiveness, also known as T cell clonal anergy. Anergic T cells fail to proliferate upon restimulation because of the inability to produce IL-2 and to properly regulate the G(1) cell cycle checkpoint. Because optimal TCR and CD28 engagement can elicit IL-2-independent cell cycle progression, we investigated whether CD3/CD28-mediated activation of anergic T cells could overcome G(1) cell cycle block, drive T cell proliferation, and thus reverse clonal anergy. We show here that although antigenic stimulation fails to elicit G(1)-to-S transition, anti-CD3/CD28 mAbs allow proper cell cycle progression and proliferation of anergic T cells. However, CD3/CD28-mediated cell division does not restore Ag responsiveness. Our data instead indicate that reversal of clonal anergy specifically requires an IL-2-dependent, rapamycin-sensitive signal, which is delivered independently of cell proliferation. Thus, by tracing proliferation and Ag responsiveness of individual cells, we show that whereas both TCR/CD28 and IL-2-generated signals can drive T cell proliferation, only IL-2/IL-2R interaction regulates Ag responsiveness, indicating that proliferation and clonal anergy can be independently regulated.     

Naive CD8+ T cells do not require costimulation for proliferation and differentiation into cytotoxic effector cells

Most current models of T cell activation postulate a requirement for two distinct signals. One signal is delivered through the TCR by engagement with peptide/MHC complexes, and the second is delivered by interaction between costimulatory molecules such as CD28 and its ligands CD80 and CD86. Soluble peptide/MHC tetramers provide an opportunity to test whether naive CD8+ T cells can be activated via the signal generated through the TCR-alphabeta in the absence of any potential costimulatory molecules. Using T cells from two different TCR transgenic mice in vitro, we find that TCR engagement by peptide/MHC tetramers is sufficient for the activation of naive CD8+ T cells. Furthermore, these T cells proliferate, produce cytokines, and differentiate into cytolytic effectors. Under the conditions where anti-CD28 is able to enhance proliferation of normal B6 CD4+, CD8+, and TCR transgenic CD8+ T cells with anti-CD3, we see no effect of anti-CD28 on proliferation induced by tetramers. The results of this experiment argue that given a strong signal delivered through the TCR by an authentic ligand, no costimulation is required.     

Induction of lysis by T cell receptor gamma delta+/CD3+ T lymphocytes via CD2 requires triggering via the T11.1 epitope only

The requirements for activation of the lytic machinery through CD2 of TCR gamma delta+/CD3+ cells were examined, by utilizing bispecific heteroconjugates containing anti-CD2 mAb cross-linked to anti-DNP. Contrary to the CD2 activation requirements in TCR alpha beta+/CD3+ cells, cytotoxic activity in TCR gamma delta+/CD3+ clones and TCR-/CD3- NK cell clones can be induced by heteroconjugates containing a single anti-CD2 (OKT11.1) mAb. Activation of TCR gamma delta+/CD3+ cells via CD2 is independent of heteroconjugates binding to CD16 (Fc gamma RIII), because heteroconjugates prepared from Fab fragments induced equal levels of lysis. Moreover, anti-CD16 mAb did not inhibit triggering via CD2 in TCR gamma delta+/CD3+ cells. In TCR-/CD3- NK cells, however, induction of cytotoxicity via CD2 is co-dependent on interplay with CD16. Anti-CD3 mAb blocked the anti-CD2 x anti-DNP heteroconjugate-induced cytotoxicity of TCR gamma delta+/CD3+ cells, indicating a functional linkage between CD2 and CD3 on these cells. We conclude that induction of lysis via CD2 shows qualitatively different activation requirements in TCR gamma delta+/CD3+, TCR alpha beta+/CD3+ CTL and TCR-/CD3- NK cells.     

Human resting B lymphocytes can serve as accessory cells for anti-CD2-induced T cell activation.

Although resting B cells are poor accessory cells for signals transmitted through the TCR/CD3 complex, we report that these B cells can support T cell proliferation when T cell activating signals are delivered through CD2. This was first suggested when leucine methyl ester treatment of PBMC abolished proliferation induced by anti-CD3, but not by the accessory cell-dependent anti-CD2 mAb combination, GT2 and OKT11. Then we demonstrated that unstimulated, resting B cells could support the proliferation of both CD4+ and CD8+ T cells. Aggregated IgG inhibited proliferation, suggesting that anti-CD2 mAb bound to T cells were cross-linked by attachment to B cell FcR. Two lines of evidence suggested that lymphocyte function-associated Ag-1/intercellular adhesion molecule-1 interaction was crucial for anti-CD2-induced proliferation. First, proliferation was blocked by mAb against these adhesion molecules. Second, intercellular adhesion molecule-1 expression rapidly increased on resting B cells after the addition of anti-CD2, but not anti-CD3. This was of interest because fixed monocytes, but not fixed B cells, were able to support the proliferative response. In contrast to lymphocyte function-associated Ag-1/intercellular adhesion molecule-1, CD28/B7 interaction was not required for anti-CD2-induced proliferation, although ligation of these molecules provided important costimulatory signals for stimulation by anti-CD3. Finally, neutralizing antibodies against IL-1 alpha, IL-1 beta, and IL-6 showed only modest inhibitory effects on T cell proliferation. The addition of IL-1 and/or IL-6 to T cells failed to substitute for accessory cells and were only partially effective with fixed B cells. Further evidence of a linkage between CD2 and CD45 isoforms was obtained. Anti-CD45RA, but not anti-CD45RO, potentiated anti-CD2-induced T cell proliferation. These studies have revealed a novel role for resting B cells as accessory cells and have documented costimulatory signals that are important for this effect. Because Ag-presentation by resting B cells to T cells generally leads to T cell nonresponsiveness, it is possible that this tolerogenic signal may be converted to an activation signal if there is concurrent perturbation of CD2 on T cells.     

Cell surface modulation of CD26 by anti-1F7 monoclonal antibody. Analysis of surface expression and human T cell activation

In this paper, we examined in detail the ability of anti-1F7 to modulate 1F7 (CD26) surface expression as well as analyzed the functional relationship between the surface expression of CD3, CD2, and CD26 and human T cell activation. We showed that anti-1F7-induced modulation is an energy-dependent process that occurs via capping and internalization of the Ag-antibody complex. Although the recovery rate for Ag reexpression of 1F7 following optimal modulation is relatively delayed, reexpression of 1F7 is greatly accelerated following phorbol ester treatment. Most importantly, we demonstrated that modulation of the CD26 Ag leads to an enhancement in the proliferative activity of modulated human T cells treated with anti-CD3 or anti-CD2, which is preceded by an enhancement in Ca2+ mobilization. CD26 modulation also led to an increase in anti-CD3- or anti-CD2-mediated T cell clone proliferation. Finally, whereas modulation of the CD26 Ag has an effect on CD3- or CD2-induced T cell activation, modulation of the CD3/TCR complex inhibits the proliferative response of T cells incubated with anti-CD3 plus anti-1F7 or anti-CD2 plus anti-1F7. However, modulation of the CD2 structure does not affect anti-CD3- plus anti-1F7-induced human T cell activation. The above results thus provide additional evidence that the CD26 Ag plays an integral role in the regulation of human T cell activation.     

T cell activation through TCR/-CD3 complex. IL-2 production of T cell clones stimulated with anti-CD3 without cross-linkage.

To elucidate the Th cell activation mechanism through the TCR/CD3 complex, we examined the reactivity of T cell clones to soluble monovalent and divalent anti-CD3 without accessory cells or costimulatory factor. All T cell clones tested produced IL-2 in response to monovalent anti-CD3, although reactivity to divalent anti-CD3 was variable depending upon clones. IL-2 production of T cell clones induced by monovalent anti-CD3 was suppressed by cross-linking of the antibody with anti-hamster IgG. IL-2 mRNA expression and the increment of intracellular Ca2+ concentration were consistent with the IL-2 production. When T cell clones were stimulated with monovalent anti-CD3, they increased in size, although divalent anti-CD3 stimulation did not affect their size irrespective of their IL-2 production. These results indicate that monovalent anti-CD3 is more efficient than divalent anti-CD3 in induction of IL-2 production and that the cross-linkage of the TCR/CD3 complex is not necessarily required for the T cell clone activation.     

T cell activation via Leu-23 (CD69)

The CD69 (Leu-23) activation Ag is a phosphorylated 28 to 32-kDa disulfide-linked homodimer that is rapidly induced after lymphocyte activation. CD69 is not present on the surface of peripheral blood resting T cells, but is constitutively expressed by CD3bright thymocytes. Activation of protein kinase C (PKC) by stimulation of the TCR/CD3 or by phorbol esters directly induces CD69 expression on T cells. In the attempt to elucidate the function of CD69 we investigated the ability of the CD69 glycoprotein to transmit an activation signal. Cross-linking of CD69 by mAb induced a prolonged elevation of intracellular [Ca2+], mostly due to an influx of extracellular Ca2+. This signal alone was unable to effectively activate PKC. When PKC was simultaneously activated by PMA, stimulation of CD69 induced IL-2 and IFN-gamma gene expression, enhancement of CD25 expression, and ultimately IL-2-dependent T cell proliferation. Both CD4+ and CD8+ peripheral T cells responded to CD69-mediated activation. Stimulation of CD69 induced proliferation of thymocytes as well as peripheral T cells, but both required independent PKC activation by PMA. Cyclosporin A, which does not prevent PKC-induced CD69 expression, completely suppressed CD69-induced IL-2 and IFN-gamma gene expression. Although the signal delivered by the CD69 initiates T cell proliferation, it is unable to trigger cytotoxicity programs in CD69+-activated T cells or T cell clones.     

Ligation of the lymphocyte homing receptor CD44 triggers T-helper and cytolytic functions of human T cells

We show that antibodies to the CD44 molecule trigger proliferation of human CD3+/CD4+ T-cell clones. Such effect is IL2-dependent, as shown by IL2 production induced by anti-CD44 mAb and by inhibition of cell proliferation in the presence of anti-IL2 antibodies or cyclosporin A (CsA). Moreover, anti-CD44 mAb triggered human cytolytic CD4+ and CD8+ TCR /+ clones, and V1 or V2 TCR Y/+ clones to lyse Fc-gamma-R+ P815 cells and to release granule trypsin-like esterase enzymes. Anti-CD44 mAb-triggered proliferation and cytotoxicity were blocked by the PTK-inhibitor, genestein. In addition, ligation of the CD44 molecule induced tyrosine phosphorylation of proteins identical, by molecular weight, to those phosphorylated following anti-CD3 mAb-stimulation. Notably, anti-CD44 mAb does not induce tyrosine phosphorylation of a 21 kD protein (the phosphorylated zeta chain of the TcR molecular complex) typically observed upon anti-CD3 mAb stimulation.     

CD28 is not required for c-Jun N-terminal kinase activation in T cells.

Studies in Jurkat cells have shown that combined stimulation through the TCR and CD28 is required for activation of c-Jun N-terminal kinase (JNK), suggesting that JNK activity may mediate the costimulatory function of CD28. To examine the role of JNK signaling in CD28 costimulation in normal T cells, murine T cell clones and CD28(+/+) or CD28(-/-) TCR transgenic T cells were used. Although ligation with anti-CD28 mAb augmented JNK activation in Th1 and Th2 clones stimulated with low concentrations of anti-CD3 mAb, higher concentrations of anti-CD3 mAb alone were sufficient for JNK activation even in the absence of anti-CD28. JNK activity was comparably induced in both CD28(+/+) and CD28(-/-) 2C/recombinase-activating gene 2(RAG2)(-/-) T cells stimulated with anti-CD3 mAb alone, and with L(d)/peptide dimers, a direct alphabeta TCR ligand. Moreover, JNK activation was also detected in 2C/RAG2(-/-) T cells stimulated with P815 cells that express the relevant alloantigen L(d) whether or not B7-1 was coexpressed. However, IL-2 production by both Th1 clones and CD28(+/+) 2C/RAG2(-/-) T cells was detected only upon TCR and CD28 coengagement. Thus, CD28 coligation is not necessary, and stimulation through the TCR is sufficient, for JNK activation in normal murine T cells. The concept that JNK mediates the costimulatory function of CD28 needs to be reconsidered.     

T cell receptor aggregation, but not dimerization, induces increased cytosolic calcium concentrations and reveals a lack of stable association between CD4 and the T cell receptor.

Exposure of T94, a CD4+ V beta 8-expressing murine Th cell clone, or immediately ex vivo CD4+ T cells to deaggregated, bivalent antibodies specific for either the TCR or CD3 failed to induce an increase in [Ca2+]i, or activation of phosphatidylinositol hydrolysis unless cross-linked with a secondary anti-Ig antibody. In contrast, we show that a combination of two mAb directed against different components of the TCR/CD3 complex (145.2C11, anti-CD3 epsilon and F23.1, anti-V beta 8) successfully induce second messenger formation, that is, without any requirement for a secondary antibody. This requirement for either a secondary antibody or two independent bivalent antibodies to activate second messenger production in T cells suggested that the signal transduction apparatus may be activated by multiple TCR/CD3 complexes being brought together on the T cell surface. This was supported by the observation that conditions inducing increased T cell [Ca2+]i through the TCR/CD3 complex also resulted in aggregation of the TCR/CD3 complex on the T cell surface. Conversely, binding of anti-TCR/CD3 antibodies to the T cell under conditions that did not induce increased [Ca2+]i also failed to induce surface TCR/CD3 redistribution. Cross-linking of the CD4 accessory molecule on T94 also resulted in increased [Ca2+]i, with kinetics similar to those observed after TCR/CD3 oligomerization. CD4 is involved in the recognition of invariant regions of MHC class II during Ag presentation and has been proposed to be associated with TCR/CD3 in the absence of Ag. Aggregation of TCR/CD3 and subsequent second messenger formation was achieved by combinations of mAb to distinct determinants within the complex due to the stable association of these determinants within the T cell membrane. We therefore assessed the functional association of CD4 with the TCR/CD3 complex by examining whether a combination of mAb directed against CD4 and CD3 or TCR induced second messenger formation. We found that anti-CD4 in combination with F23.1 or with 145.2C11 failed to induce increases in [Ca2+]i. Furthermore, mAb to CD4 failed to inhibit the increase in [Ca2+]i observed with the combination of 145.2C11 and F23.1. We therefore conclude that CD4 is not stably associated with TCR or CD3 in the absence of Ag/MHC class II composites.     

The role of Ca2+ and Mg2+ in the cytotoxic T lymphocyte reaction and in the secretion of N alpha-benzyloxycarbonyl-L-lysine thiobenzyl ester-serine esterase by human T cell clones

Human T cell clones contain enzymes that can cleave the substrate N-alpha-benzyloxycarbonyl-L-lysine thiobenzyl ester (BLT). All CTL clones tested in this study secreted BLT-serine esterase activity, whereas only one of three tested non-cytolytic T cell clones secreted this enzymatic activity upon Ag-specific activation. BLT-serine esterase secretion could also be induced by the Fc gamma+ target cell Daudi in the presence of mAb specific for the TCR/CD3 complex, CD2, or the T cell activation Ag Tp 103. In addition, anti-CD3 and a mitogenic combination of anti-CD2 mAb, induced secretion of BLT-serine esterase in the absence of target cells, whereas anti-Tp 103 failed to do so. The secreted BLT-serine esterase activity induced by the various ligands was inhibited by the serine esterase inhibitors PMSF and m-ABA, but not by N-alpha-p-tosyl-L-lysine chloromethyl ketone. Significant BLT-serine esterase activity was induced by target cells or soluble anti-CD3 in the absence of extracellular Ca2+ ions, provided that extracellular Mg2+ ions were present. The cytotoxic activities by the human CTL clones were completely blocked under these conditions. All ligands that induced BLT-serine esterase secretion in the absence of extracellular Ca2+, induced a transient rise of intracellular Ca2+. Soluble anti-CD3 mAb did not induce a transient rise in intracellular Ca2+ or secretion of BLT serine esterase in CTL preincubated for 2 h with 5 mM EGTA. These findings indicate that mobilization of intracellular Ca2+ in human CTL clones is required for induction of secretion of BLT-serine esterase.     

CD4-mediated signals induce T cell dysfunction in vivo.

Triggering of CD4 coreceptors on both human and murine T cells can suppress TCR/CD3-induced secretion of IL-2. We show here that pretreatment of murine CD4+ T cells with the CD4-specific mAb YTS177 inhibits the CD3-mediated activation of the IL-2 promoter factors NF-AT and AP-1. Ligation of CD4 molecules on T cells leads to a transient stimulation of extracellular signal-regulated kinase (Erk) 2, but not c-Jun N-terminal kinase (JNK) activity. Pretreatment with anti-CD4 mAb impaired anti-CD3-induced Erk2 activation. Costimulation with anti-CD28 overcame the inhibitory effect of anti-CD4 Abs, by induction of JNK activation. The in vivo relevance of these studies was demonstrated by the observation that CD4+ T cells from BALB/c mice injected with nondepleting anti-CD4 mAb were inhibited in their ability to respond to OVA Ag-induced proliferation and IL-2 secretion. Interestingly, in vivo stimulation with anti-CD28 mAb restored IL-2 secretion. Furthermore, animals pretreated with anti-CD4 elicited enhanced IL-4 secretion induced by OVA and CD28. These observations suggest that CD4-specific Abs can inhibit T cell activation by interfering with signal 1 transduced through the TCR, but potentiate those delivered through the costimulatory molecule CD28. These studies have relevance to understanding the mechanism of tolerance induced by nondepleting anti-CD4 mAb used in animal models for allograft studies, autoimmune pathologies, and for immunosuppressive therapies in humans.     

Diacylglycerol mediates the T-cell receptor-driven Ca(2+) influx in T cells by a novel mechanism independent of protein kinase C activation

The mechanism of Ca(2+) influx in nonexcitable cells is not known yet. According to the capacitative hypothesis, Ca(2+) influx is triggered by IP(3)-mediated Ca(2+) release from the intracellular Ca(2+) stores. Conversely, many workers have reported a lack of association between release and influx. In this work, the role of diacylglycerol (DAG) as the mediator of T-cell receptor (TCR)-driven Ca(2+) influx in T cells was investigated. Stimulation of mouse splenic T cells with naturally occurring DAG caused Ca(2+) entry in a dose- and time-dependent manner. Such stimulation was blocked by Ni(2+), a divalent cation known to block Ca(2+) channels. Inhibition of protein kinase C (PKC) by calphostin C did not inhibit, but slightly enhanced, the DAG-stimulated Ca(2+) entry. However, inhibition of DAG metabolism by DAG kinase and lipase inhibitors enhanced the DAG-stimulated Ca(2+) entry. DAG lipase and kinase inhibitors also enhanced the Ca(2+) entry in T cells stimulated through TCR/CD3 complex with anti-CD3 antibody. Calphostin C did not affect the anti-CD3-stimulated Ca(2+) entry. These results showed that TCR-driven Ca(2+) influx in T cells is mediated by DAG through a novel mechanism(s) independent of PKC activation.     

Stimulation of PIP2 hydrolysis by aluminum fluoride in resting T cell subsets of normal and autoimmune-prone lpr mice

T cells of autoimmune-prone mice homozygous for the lpr mutation respond poorly to mitogens in terms of proliferation and of IL-2 production. In a previous study, we have correlated this deficient activation with the inability of mitogens to stimulate hydrolysis of phosphatidylinositol 4,5-bisphosphate in lpr T cells, although these cells bind mitogen and express the TCR/CD3 complex. In order to determine whether activation-deficient lpr T cells contain functional GTP-binding (G) protein(s) and phospholipase C, we examined the effects of the G protein activating agent sodium fluoride plus Al+3 (AlF-4). AlF-4 stimulated phosphatidylinositol turnover, a response characteristic of TCR/CD3 occupancy, in mature L3T4+ and Ly2+ T cells. Second, and more important, AlF-4 stimulated the same biochemical events in L3T4-, Ly2- (double-negative) T cells from the normal thymus or from the enlarged lymph nodes of autoimmune-prone mice homozygous for the lpr mutation. However, these double-negative T cells were unresponsive to receptor-active ligands such as T cell mitogens or anti-CD3-epsilon mAb, despite their ability to bind these ligands. These findings suggest that activation-deficient double negative T cells express the receptors, G protein(s) and effector enzymes necessary for second messenger formation and further suggest that the failure of these cells to generate the relevant second messengers in response to mitogens or anti-CD3-epsilon antibody may be due to inefficient coupling of the TCR/CD3 complex to G proteins.