Regulation of the alternative pathway of T cell activation by anti-T3 monoclonal antibody

T cell activation may be triggered either through the T3-Ti antigen receptor complex or via an alternative macrophage-independent pathway involving the 50KD T11 sheep erythrocyte-binding glycoprotein. Monoclonal antibodies anti-T11(2) and anti-T11(3), directed at distinct epitopes of the T11 molecule, trigger mature T cells to proliferate and express their functional programs, and induce expression of IL 2 receptors on both T3+ and T3- thymocytes. We now show that a non-mitogenic anti-T3 antibody blocks activation via the T11 pathway of not only peripheral blood T cells, but also T3+ thymocytes. Anti-T3 does not affect surface expression of T11 or the rapid augmentation of T11(3) expression after incubation of cells with anti-T11(2). However, anti-T3 inhibits generation of IL 2 receptors and production of IL 2 by T lineage cells cultured with anti-T11(2) plus anti-T11(3). In contrast, modulation of the T11 molecule by a non-mitogenic anti-T11 antibody does not inhibit activation of T cells by a mitogenic anti-T3 antibody. The ability of anti-T3 to block expression of IL 2 receptors on both thymocytes and mature T cells activated by the T11 pathway suggests that a regulatory interaction may be important during T cell ontogeny to provide a mechanism for inhibiting expansion of autoreactive clones.     

Differential immunomodulation by anti-CD2 monoclonal antibodies of anti-CD3-induced T cell activation: dependence upon the individual anti-CD3 monoclonal antibody used for activation

Two monoclonal antibodies (mAb) recognizing different CD2 epitopes each inhibited anti-CD3-induced proliferation and anti-CD3-induced increase in surface CD2 expression. The magnitude of inhibition by either anti-CD2 mAb was dependent upon which anti-CD3 mAb was used as the stimulus, being more pronounced when the anti-CD3 mAb 454 was used as the stimulus than when either anti-CD3 mAb 147 or 446 was the stimulus. The effects of neuraminidase-treated sheep erythrocytes (which bind to CD2) were also more pronounced on mAb 454-induced proliferation than on mAb 147- or 446-induced proliferation. Furthermore, the effects of preincubation with anti-CD2 mAb depended upon the responder status of the donor to IgG1 anti-CD3 mAb. Preincubation of high-responder cells with anti-CD2 mAb had little effect on subsequent IgG1 anti-CD3-induced proliferation. In contrast, preincubation of low-responder cells with anti-CD2 mAb usually augmented the otherwise small proliferative response to IgG1 anti-CD3 mAb. Taken together, these observations suggest that interaction of surface CD2 with ligand alters the response of T cells to anti-CD3 mAb, but these effects depend upon the individual anti-CD3 mAb used for stimulation. These studies raise the possibility that perturbation of different parts of the CD3-T cell antigen receptor complex may lead to different sequelae, and, as a result, the T cell may respond to a given immunomodulator in different ways.     

Inhibition by anti-CD2 monoclonal antibodies of anti-CD3-induced T cell-dependent B cell activation

Anti-CD3 mAb can activate T cells to help in B cell activation as detected by late events, such as maturation of B cells into Ig-secreting cells (IgSC), or by early events, such as B cell surface expression of the activation marker CD23. Two different anti-CD2 mAb each inhibited anti-CD3-induced T cell-dependent B cell activation in a dose-dependent fashion. Neither irradiation of the T cells prior to culture nor depletion of CD8+ cells abrogated the inhibitory effects of anti-CD2 mAb. Despite the ability of these anti-CD2 mAb to inhibit anti-CD3-induced IL2 production, addition of exogenous IL2 to anti-CD2 mAb-containing cultures could not fully reverse the inhibitory effects on IgSC generation. Furthermore, addition of various combinations of IL1, IL2, IL4, and IL6 or crude PBMC or monocyte culture supernatants also could not reverse anti-CD2-driven inhibition. In T cell-depleted cultures, anti-CD2 mAb had no effect on the ability of IL4 to induce B cell CD23 expression, confirming that anti-CD2 mAb had no direct effect on B cells. However, in cultures containing T+ non-T cells, anti-CD2 mAb did partially inhibit IL4-induced B cell CD23 expression. Taken together, these observations demonstrate that certain CD2 ligands can modulate T cell-dependent B cell activation by a mechanism which, at least in part, involves a direct effect by the CD2 ligand on the T cell itself.     

Inhibitory effects of anti-CD2 monoclonal antibodies on interleukin 2 production and interleukin 2 receptor expression in anti-CD3-induced T cell activation

The effects of anti-CD2 monoclonal antibodies (mAb) on anti-CD3-driven interleukin 2 (IL2) production and IL2 receptor (IL2R) expression were investigated. Two anti-CD2 mAb, which had previously been shown to inhibit in vitro anti-CD3-induced T cell proliferation, also inhibited anti-CD3-induced IL2 production. However, it seemed unlikely that this was the crucial mechanism in the inhibition of anti-CD3-driven proliferation, since anti-CD2 mAb also partially inhibited T cell proliferation induced by the anti-CD3 mAb 446 which does not induce detectable IL2 levels. Anti-CD2 mAb also inhibited anti-CD3-induced surface IL2R expression as measured by immunofluorescence staining with an anti-IL2R mAb against the p55 chain. Inhibition of IL2R expression paralleled inhibition of proliferation. This anti-CD2-mediated inhibition involved a block in the generation of normal numbers of IL2R+ cells rather than a direct inhibitory effect on the IL2R+ cells themselves, since IL2R+ cells isolated from anti-CD2-containing cultures responded normally to IL2. Exogenous IL2 and IL4, singly or in combination, could reverse neither the anti-CD2-mediated inhibition of anti-CD3-induced proliferation nor the anti-CD2-mediated inhibition of anti-CD3-induced IL2R expression. Taken together, these observations suggest that anti-CD2 mAb inhibit anti-CD3-driven proliferation by inhibiting the generation of IL2R+ cells at a maturational stage proximal to their expression of surface IL2R. This inhibition cannot be overcome by exogenous IL2 or IL4, suggesting that the underlying biochemical mechanism involves an IL2- and IL4-independent pathway.     

Activation of autoreactive cytolytic T lymphocyte clone against human melanoma by anti-T3 monoclonal antibody and autologous accessory cells

A cytotoxic T-lymphocyte (CTL) clone Tc1.8 was derived in a limiting dilution culture from a single cell that was derived from melanoma-involved lymph node lymphocytes activated in in vitro coculture against the autologous melanoma cells (VIP). The clone Tc1.8 (T3+, T8+, T4-, and Leu7-) expressed restricted cytolytic activity against only the autologous target VIP. As it aged in continuous culture containing interleukin 2, Tc1.8 lost cytolytic activity. The cytolytic function could be restored, however, with monoclonal antibody (MoAb) against T3 (OKT3) or with F(ab')2 fractions of OKT3, and upon restimulation with irradiated accessory cells. OKT3-mediated reinduction of cytotoxicity by the aged Tc1.8 could not be achieved if the T3 molecules were modulated from the effector cell surface following overnight incubation of Tc1.8 with saturating concentrations of OKT3 MoAb. Following reactivation with OKT3 Tc1.8 gained cytolytic function against NK targets in addition to VIP. Reactivation with F(ab')2 fractions of OKT3 and with autologous accessory cells, however, maintained its restricted antigen fidelity. The NK-like activity of Tc1.8 upon reactivation with OKT3 resulted from conjugate formation between the activated Tc1.8 and NK targets via the activating ligand itself. Thus, upon stimulation with anti-T3 MoAb and with autologous accessory cells, independently, the autoreactivity could be restored in an aged and inactive CTL clone.     

The anti-T cell monoclonal antibody 9.3 (anti-CD28) provides a helper signal and bypasses the need for accessory cells in T cell activation with immobilized anti-CD3 and mitogens

CD28 is an antigen of 44 kDa which is expressed on the membrane of the majority of human T cells. The present study examines the functional effects of an anti-CD28 monoclonal antibody (mAb 9.3) on T cell activation induced with immobilized anti-CD3 mAb OKT3 or with mitogens, in the absence of accessory cells. To this end, we used blood resting T cells that were completely depleted of accessory cells (monocytes, B cells, and natural killer cells), and consequently did not respond to recombinant interleukin-2 (rIL-2), to immobilized OKT3, to PHA, or to Con A. Addition of mAb 9.3 to the cultures enhanced IL-2 receptor expression (Tac antigen) on PHA- or immobilized OKT3-stimulated T cells and induced IL-2 receptors on Con A-stimulated T cells. Moreover, addition of mAb 9.3 to cultures of T cells stimulated with PHA, Con A, or immobilized OKT3 resulted in IL-2 production. Soluble mAb 9.3 was a sufficient helper signal for T cell proliferation in response to PHA or immobilized OKT3. Crosslinking of mAb 9.3 by culture on anti-mouse IgG-coated plates enhanced the helper effect and was an essential requirement for the induction of T cell proliferation in response to Con A. No other anti-T cell mAb (anti-CD2, -CD4, -CD5, -CD7, -CD8) was found to provide a complete accessory signal for PHA or Con A stimulation of purified T cells. T cell proliferation induced by the combination of PHA and mAb 9.3 was strongly inhibited by the anti-IL-2 receptor mAb anti-Tac. In conclusion, mAb 9.3 can provide a signal bypassing monocyte requirement in T cell activation with immobilized OKT3, PHA, and Con A, resulting in an autocrine IL-2-dependent pathway of proliferation.     

T cell activation induced by anti-CD3 antibodies requires prolonged stimulation of protein kinase C

Accessory cell-depleted T cells required the presence of a protein kinase C (PKC) stimulating phorbol ester, such as phorbol 12,13-dibutyrate (PDB), to be activated by soluble antibodies to the CD3 molecular complex. To determine the duration of PDB costimulation necessary to induce a proliferative response, highly purified T cells were pulsed with anti-CD3, incubated with PDB for limited periods of time, and then washed and recultured in the absence of PDB. T cells stimulated with anti-CD3 and PDB for 2 hr were unable to proliferate unless IL-2 or PDB was added to the second culture. With more prolonged exposure to PDB (4-18 hr), anti-CD3-pulsed cells exhibited an increased capacity to proliferate in the absence of additional PDB. Proliferation could be augmented by exogenous IL-2, but remained submaximal. Optimal DNA synthetic responses required the presence of PDB throughout the entire culture. Despite this, costimulation with anti-CD3 and PDB induced a significant number of cells to express IL-2 receptors and enter the cell cycle after 18 hr of costimulation with PDB. Moreover, T cells costimulated by anti-CD3 and PDB produced IL-2 within 4 hr. However, T cells that were stimulated with anti-CD3 and PDB for 4 hr, washed, and recultured rapidly lost the ability to continue to produce IL-2, which reflected a decrease in the content of mRNA encoding IL-2. This loss of IL-2 production was prevented by reculturing the cells with PDB. These studies therefore indicate that after initial T cell activation by anti-CD3, continued stimulation of PKC is necessary for ongoing IL-2 production. These results suggest a model of T cell activation in which sustained stimulation of PKC after cell cycle entry is required to maintain growth factor production and continued proliferation.     

Induction of T cell-dependent B cell differentiation by anti-CD3 monoclonal antibodies

Three monoclonal antibodies (mAb) recognizing the CD3 (T3) surface complex each induced B cell differentiation (as measured by PFC generation) in cultures containing T + non-T cells. Irradiation of the T cells before culture usually augmented the PFC response. An IgG2a mAb (454) induced PFC in all donors tested, whereas two IgG1 mAb (147 and 446) induced PFC in only 80% of the donors tested. This heterogeneity in PFC response to IgG1 anti-CD3 mAb strictly paralleled the heterogeneity in proliferative response to IgG1 anti-CD3 mAb and was governed by cells within the non-T population. In IgG1 anti-CD3 high responders (HR), all anti-CD3 mAb tested induced Tac expression. In IgG1 anti-CD3 low responders (LR), mAb 454 induced Tac expression, but mAb 147 did not. However, when the cultures were supplemented with exogenous interleukin 2, Tac expression and PFC generation in response to mAb 147 was similar to the response to mAb 454 in both HR and LR. The addition of anti-Tac to the cultures partially inhibited anti-CD3-induced PFC generation. These studies indicate that anti-CD3 mAb can lead to B cell differentiation under appropriate experimental conditions and may be valuable in studying polyclonal T cell-dependent B cell differentiation in normal and disease states.     

Characterization of IgG FcR-mediated proliferation of human T cells induced by mouse and human anti-CD3 monoclonal antibodies. Identification of a functional polymorphism to human IgG2 anti-CD3.

T cell activation induced by mouse anti-CD3 mAb has shown to be dependent on the Ig isotype of these antibodies. A study of isotype dependency of human antibodies, however, seems more relevant to human effector systems, especially in view of the availability of humanized antibodies for clinical applications. We constructed a panel of mouse and mouse/human chimeric anti-CD3 mAb, which differ only in their CH region and hence have identical binding sites and affinity. By using these antibodies, we now studied their ability to induce T cell proliferation in human PBMC and analyzed the classes of IgG FcR involved in these responses. The human (h)IgG1, hIgG3, and hIgG4, as well as mouse (m)IgG2a and mIgG3 anti-CD3 mAb induced an Fc gamma RI (CD64)-dependent T cell proliferation in all donors. Activation with hIgG2 and mIgG1 anti-CD3 mAb was observed to be mediated via the low affinity Fc gamma RII (CD32). It was found that leukocytes in a normal donor population display a functional polymorphism with respect to hIgG2 anti-CD3 responsiveness. This polymorphism was found to be inversely related to the previously defined Fc gamma RII-polymorphism to mIgG1 anti-CD3 mAb. Monocytes expressing the Fc gamma RII mIgG1 low responder (LR) allele support hIgG2 anti-CD3 induced T cell proliferation efficiently, whereas cells homozygous for the Fc gamma RII mIgG1 high responder (HR) allele do not. This observation could be confirmed in T cell activation studies using hFc gamma RIIa-transfected mouse fibroblasts, expressing either the mIgG1 anti-CD3 HR or LR Fc gamma RII-encoding cDNA.     

Cell surface comodulation of CD4 and T cell receptor by anti-CD4 monoclonal antibody

In our study we have used anti-CD4 mAb to investigate the cell surface association between CD4 and the Ag-specific TCR complex on mature peripheral T cells. Anti-CD4 mAb was administered in vivo and in vitro and its effects on CD4 and CD3 cell surface expression were determined. In vivo, anti-CD4 mAb reduced cell surface expression of its ligand, CD4, and secondarily also reduced cell surface expression of CD3/TCR on CD4+ splenic T cells. In vitro, multivalent cross-linking of CD4 by anti-CD4 mAb and either FcR+ cells or anti-Ig mAb also resulted in decreased surface expression of CD4 and specific comodulation of CD3/TCR. The secondary reduction in cell surface CD3/TCR expression induced by CD4 cross-linking could be pharmacologically disrupted by high doses of PMA, indicating that the comodulation of CD3 with CD4 was dependent upon intracellular mediators, possibly including protein kinase C. These results demonstrate that, in the presence of anti-CD4 mAb, CD4 is functionally associated with the CD3/TCR complex, and that this association is dependent upon the activity of intracellular mediators. Such intracellular mediators might induce the coordinate down-modulation of physically unassociated CD4 and CD3/TCR molecules, or, alternatively, might promote a physical interaction between CD4 and CD3/TCR molecules.     

Cooperation between an anti-T cell (anti-CD28) monoclonal antibody and monocyte-produced IL-6 in the induction of T cell responsiveness to IL-2

CD28 is an Ag of 44-kDa Mr that is expressed on the membrane of the majority of human T cells and that is recognized by mAb 9.3. The functional effects of mAb 9.3 on peripheral blood T cells were studied. mAb 9.3 was not mitogenic, unless it was combined with PMA. When CD28 was cross-linked after binding of mAb 9.3 to the T cell by immobilized or soluble anti-mouse IgG, T cells proliferated in response to rIL-2, provided that monocytes were also present. The additional signal required for IL-2 responsiveness after cross-linking of CD28 could also be delivered in cultures of purified T cells by a cellfree monocyte culture supernatant. Expression of IL-2R on about 10% of the T cells was demonstrated by staining with an anti-IL-2R mAb, and was found to be largely restricted to CD4+ cells. The active compound responsible for the helper signal in the monocyte culture supernatant was identified as IL-6 because purified IL-6 (but not IL-1 beta) had similar activity and because an antiserum to IL-6 (but not an antiserum to IL-1 beta) neutralized the activity of the monocyte supernatant and blocked T cell proliferation. An anti-IL-2R antibody also completely inhibited T cell proliferation induced by the combination of mAb 9.3, IL-2, and IL-6. Our results provide evidence that cross-linking of CD28 induces functional IL-2R and that this activity is dependent on a helper signal provided by monocytes, more specifically IL-6. Moreover, our results indicate that IL-6 (previously called B cell stimulatory factor-2) is active on T cells. If a natural ligand for CD28 can be identified, the mechanism of induction of IL-2 responsiveness described here might explain how T cells become nonspecifically involved in an ongoing cellular immune reaction.     

Human T cell activation induced by a monoclonal mouse IgG3 anti-CD3 antibody (RIV9) requires binding of the Fc part of the antibody to the monocytic 72-kDa high-affinity Fc receptor (FcRI)

The mitogenic activity of anti-CD3 mouse monoclonal antibodies (mAb) in cultures of human peripheral blood mononuclear cells (PBMC) depends on the ability of the mAb to interact with CD3 molecules on the T cells, and with Fc receptors (FcR) on monocytes. Two types of FcR with distinct specificity for murine (m) IgG subclasses are involved: a 72-kDa receptor (FcRI) binds mIgG2a and a 40-kDa receptor (FcRII) binds mIgG1. In this study we examined the mitogenic activity of mIgG3 anti-CD3 mAb RIV9. In cultures of human PBMC, the mAb induced T cell proliferation and interleukin 2 production. We found that subjects, unresponsive to mIgG2a anti-CD3 (e.g., OKT3), were also RIV9 nonresponders. In contrast, nonresponders to mIgG1 anti-CD3 (e.g., anti-Leu4) had a normal response to RIV9. Our results therefore suggested that anti-CD3 mAb of the mIgG2a and mIgG3 subclass bind to the same monocytic FcR. Human monomeric IgG, which has been shown to bind to FcRI only, blocked T cell proliferation induced by mIgG2a and mIgG3 anti-CD3, but had no effect on T cell proliferation induced by mIgG1 anti-CD3. In contrast, a mAb (IV.3) to FcRII, which blocks ligand binding of the receptor, blocked the mitogenic activity of mIgG1 anti-CD3 antibodies, but had no effect on T cell proliferation induced by mIgG3 anti-CD3 or by mIgG2a anti-CD3. Binding of RIV9 to FcR of responder monocytes could be demonstrated in immunofluorescence. Monocytes from the RIV9 nonresponder subjects however were unable to bind the Fc portion of this antibody. The binding of fluorescein (FITC)-conjugated mIgG3 or FITC-conjugated mIgG2a to responder monocytes could be inhibited by human monomeric IgG and by mIgG2a and mIgG3, but not by the mAb to FcRII. The results demonstrate that mIgG3 binds to FcRI on human monocytes and that this binding is needed for the mitogenic activity of mIgG3 anti-CD3.     

Inhibition of IL 2-driven proliferation of murine T lymphocyte clones by supraoptimal levels of immobilized anti-T cell receptor monoclonal antibody

Both cloned murine helper T lymphocytes (HTL) and cytolytic T lymphocytes (CTL) proliferated and secreted lymphokines when stimulated with immobilized anti-T cell receptor monoclonal antibody (anti-TCR mAb). However, although proliferation of CTL increased and reached plateau levels as concentrations of anti-TCR mAb were increased, the proliferation of HTL decreased with high concentrations of anti-TCR mAb. A reduction of IL 2-dependent proliferation by CTL was observed when IL 2 was added to cultures of CTL in the presence of high concentrations of anti-TCR mAb, whereas IL 2-independent proliferation appeared to be unaffected by these concentrations of anti-TCR mAb. Inhibition of IL 2-driven proliferation caused by high concentrations of immobilized anti-TCR mAb did not seem to be mediated by soluble factors. Cells continued to express cell surface receptors for IL 2 and transferrin after treatment with immobilized anti-TCR mAb. Inhibition of IL 2-driven proliferation by high concentrations of immobilized anti-TCR mAb may represent a mechanism for regulating the proliferation of T lymphocytes. This inhibitory mechanism is initiated by stimulation of the T cell receptor, in this case by immobilized anti-TCR mAb, and is independent of other cells and factors.     

Regulation of influenza virus-specific cytotoxic T cell responses by monoclonal antibody to a human T cell differentiation antigen

The results in this report indicate that the OKT3 monoclonal antibody, which is specific for a human T cell differentiation antigen present on 90 to 95% of peripheral T cells, can exert several effects that regulate the generation and expression of human influenza virus-immune cytotoxic T lymphocytes (CTL). The OKT3 antibody, but not OKT1 or OKT11 (which bind to all peripheral T cells), is able to inhibit anti-influenza CTL effector cell activity. An F(ab')2 preparation of OKT3 IgG were as effective as whole IgG for the inhibition of CTL effectors, indicating that the inhibitory activity of the antibody was not a function of the Fc portion of the molecule. OKT3 IgG and OKT3 F(ab')2 fragments (but not OKT4, OKT8, or OKI were able to inhibit the generation of anti-influenza CTL. The culture of human lymphoid cells with OKT3 in the presence or absence of influenza virus induced radioresistant cells that could suppress the CTL response of fresh autologous lymphocytes to influenza. These results suggest that T cell functions can be regulated by signals that are initiated by the binding of antibody to cell surface molecules that may not be related to the T cell antigen-specific receptor(s).     

Differential inhibition of human antigen-specific T cell clone proliferative responses by distinct monoclonal anti-HLA-DR antibodies

The inhibition of diphtheria toxoid and varidase-specific T cell clones from a single DR 6/7 donor by eight distinct monoclonal anti-HLA-DR antibodies was tested in proliferative assays. These moAb were selected because they had been previously defined for their ability: 1) to react with Ia molecules; 2) to recognize similar or different epitopes; 3) to share or not share idiotypic specificities. Our results show a distinct inhibition pattern for each clone tested. Furthermore, the various moAb could be classified into three groups according to their inhibitory effect on T cell proliferation. These data suggest: a) an epitopic restriction by class II antigens of antigen-specific human T cell clone proliferation; and b) the recognition of functional epitopes on the human Ia-like antigens by some but not all moAb studied.     

Induction of nonspecific cytotoxicity by monoclonal anti-T3 antibodies

The effects of monoclonal anti-T3 antibodies on the effector phase of cytotoxic T lymphocytes (CTL) were studied with respect to antigen-specific and antigen-nonspecific lysis of different target cells. Anti-T3 antibodies inhibited the antigen-specific lysis by CTL generated in mixed lymphocyte cultures (MLC), but they concomitantly augmented the nonspecific killing of third-party cells such as the cell lines Daudi, Raji, and K562. This nonspecific cytotoxicity was induced by various anti-T3 antibodies, whereas antibodies reactive with other antigens expressed on the cytotoxic effector cells lacked any such activity. Anti-T3 antibodies induced nonspecific cytotoxicity only when activated T cells, obtained by primary MLC, by repeated restimulation, or after cloning, were used. The antibodies had no effect on unstimulated peripheral T lymphocytes or thymocytes. The inhibition of the antigen-specific lysis and the induction of nonspecific lysis by anti-T3 was dose dependent, and both effects occurred at the same concentration range of anti-T3. F(ab')2 fragments of anti-T3 inhibited the specific lysis but were not able to induce cytotoxic activity, indicating that this induction is an Fc-dependent process. When different target cells were tested, only Fc receptor-positive cells were susceptible for this nonspecific cytotoxicity. Thus, anti-T3 antibodies have a dual effect on effector CTL: they inhibit antigen-specific lysis and concomitantly induce nonspecific lysis in an Fc-dependent way.     

Stimulation of a T helper cell class 2 clone with immobilized anti-T cell receptor antibody activates a Ca2+ and protein kinase C-independent lethal signaling pathway.

Stimulation of an IL-2-dependent variant of the Th2 clone D10.G4.1 with antibodies (Ab) specific for CD3 epsilon or the TCR-alpha beta caused either activation of the clone to secrete the autocrine lymphokine IL-4, or lethal activation in which the cells secreted high quantities of IL-4 but then died within 2 days. High densities of immobilized Ab delivered a lethal signal, whereas soluble forms of Ab and low densities of immobilized Ab caused productive activation in which cell viability was maintained. Lethal activation was not prevented by accessory cells, IL-1, or IL-2, or by co-cross-linkage of CD4 and TCR. The lethal signal was not mediated via a soluble effector from the activated cells. Lethal signaling was insensitive to cyclosporin A or dexamethasone. Studies with activators of protein kinase C (PKC), and PKC inhibitors, indicated that direct activation of PKC was not sufficient for lethal signaling. Nor could direct activation of PKC prevent the lethal signal. The lethal signal was not caused by Ca2+ mobilization mediated by Ca2+ ionophore and there was no evidence of apoptosis. The combination of a PKC activator and Ca2+ ionophore was not lethal, thereby showing that together these events are not sufficient. That these signal pathways were not necessary for lethal activation was evidenced by their inability to lower the density of immobilized anti-CD3 required to cause cell death. In this model, ligation of the TCR specifically activates a Ca2+/PKC-independent lethal signal transduction pathway.     

Stimulation of human T cells via anti-T cell receptor monoclonal antibody BMA031: distinct cellular events involving interleukin-2 receptor and lymphocyte function antigen 1

We have analyzed activation of resting human T cells by anti-T cell receptor (TCR) monoclonal antibody (mAb) BMA031, a murine mAb of the G2b isotype. Human peripheral blood lymphocytes (PBL) respond to anti-TCR mAb by short-term proliferation in vitro and by acquisition of responsiveness to interleukin 2 (rIL-2) in the absence of detectable IL-2 production. Cell depletion and limiting dilution experiments indicate that anti-TCR mAb +/- rIL-2 stimulation covers a substantial portion of human T cells, including CD4+ and CD8+ cells. Enhancement by rIL-2 of anti-TCR mAb-induced proliferation is blocked by anti-IL-2 receptor (IL-2R, p55) mAb, while anti-TCR mAb-induced proliferation is not. In contrast, anti-TCR mAb-induced proliferation is blocked by anti-lymphocyte function antigen 1 (LFA-1, CD11a) mAb and is not demonstrable in PBL from two patients with severe congenital LFA-1 deficiency, not even in the presence of irradiated LFA-1+ PBL. We conclude that stimulation of resting human T cells by anti-TCR mAb BMA031 enables dissociation of distinct steps in T cell activation that specifically require participation of IL-2R (p55) and LFA-1 cell surface molecules in a mutually exclusive way.     

Suppression of antibody synthesis by CD4+ T cell clones and normal T cells stimulated with monoclonal anti-CD3 antibody

CD4+ve Th1 clones, as well as normal splenic T cells, were found to suppress LPS-driven antibody secretion in a non-Ag-specific and non-MHC-restricted manner when the T cells were activated with the anti-CD3 mAb, 145-2C11. Suppression was observed with both primed and naive B cells, as well as with purified hapten-specific B cells, a result that suggests a direct effect of anti-CD3-activated T cells on B cell differentiation. Th1 clones activated by cognate Ag also suppressed LPS-driven antibody secretion. Furthermore, suppression of LPS-driven antibody secretion could be achieved across a cell-impermeable porous membrane when T cells were activated with anti-CD3. Suppression by Th1 clones and by normal T cells could not be attributed to a concomitant decrease in B cell proliferation or to a shift in the kinetics or isotype of the antibody response. These data demonstrate that CD4+ve Th1 clones, as well as normal T cells, can effect suppression of polyclonal antibody formation.