Effect of wheat germ agglutinin on the interleukin pathway of human T lymphocyte activation

Wheat germ agglutinin (WGA) inhibits proliferation of human peripheral blood mononuclear cells (PBMC) induced by mitogens and antigens. We investigated the mechanism by which WGA inhibits PHA-induced human lymphocyte proliferation with regard to the interleukin pathway. Our data revealed that although PBMC-proliferation was markedly suppressed by WGA, levels of IL 2 activity in WGA-inhibited cultures were not reduced, but instead were increased, suggesting failure to utilize IL 2. Furthermore, the addition of exogenous IL 2 failed to overcome the suppression. Consistent with these observations, culturing PBMC with PHA plus WGA markedly decreased the number of high-affinity IL 2 receptor per cell, as determined by binding of purified [3H]IL 2, relative to cultures containing PHA alone. WGA immobilized on support beads bound detergent-solubilized IL 2 receptors from PHA-activated T cells, but did not bind human IL 2. However, WGA did not competitively block the binding of [3H]IL 2 to PHA-induced lymphoblasts. These results suggest that WGA inhibits lymphocyte proliferation by binding to and decreasing the number of high-affinity IL 2 receptors displayed on T cells, without impairing IL 2 production.     

Functional properties of the 50 kd protein associated with the E-receptor on human T lymphocytes: suppression of IL 2 production by anti-p50 monoclonal antibodies

Monoclonal antibody 9.6 is specific for a 50 kd T cell surface protein (p50) associated with the sheep erythrocyte (E)-receptor on human T lymphocytes. This antibody interferes with many T cell functions. We have examined the effect of antibody 9.6 on lymphocyte proliferation and interleukin 2 (IL 2) production triggered by mitogens, soluble antigens, and alloantigens to elucidate the mechanism(s) of its immunosuppressive action. At concentrations as low as 50 ng/ml, 9.6 suppressed lymphocyte proliferation and the elaboration of IL 2 by T cells stimulated by PHA, alloantigens, or low concentrations of the phorbol ester TPA (less than or equal to ng/ml). Furthermore, in cultures stimulated by a combination of PHA plus TPA, 9.6 did not inhibit the acquisition of IL 2 receptors but inhibited proliferation and IL 2 production. Immunoaffinity-purified IL 2 completely restored lymphocyte proliferation in cultures inhibited by 9.6. Studies of kinetics of inhibition by 9.6 showed that this antibody inhibited lymphocyte proliferation induced by PHA, alloantigen, and PPD even when added at 24, 48, and 72 hr, respectively, after the initiation of these cultures, suggesting that 9.6 does not block lectin binding or antigen recognition by T cells and that it can inhibit lymphocyte proliferation even after cells have undergone one or more rounds of cell division. A dose-response analysis of lymphocyte proliferation induced by PHA or by TPA demonstrated that the degree of inhibition by 9.6 decreased with increasing concentrations of these mitogens. Antibody 9.6 did not inhibit lymphocyte response induced by optimal concentrations of PHA (50 to 100 micrograms/ml; PHA-M) but inhibited proliferation of maximally induced lymphocytes by using a synergistic combination of low concentrations of PHA (5 micrograms/ml, PHA-M) plus TPA (1 ng/ml). Taken together, these findings indicate that 1) 9.6 inhibits lymphocyte proliferation by affecting IL 2 production, 2) 9.6 does not inhibit the acquisition of 9.6 receptors induced by a synergistic combination of PHA plus TPA, and 3) p50 molecules may be involved in multiple pathways of T cell activation.     

Regulation of human T lymphocyte mitogenesis by antibodies to CD3

The inhibitory and mitogenic effects of anti-CD3 antibodies (anti-CD3) were examined in cultures of human peripheral blood T cells. Resting T cells required the presence of accessory cells (AC) or phorbol myristate acetate (PMA) to be stimulated by soluble anti-CD3 (OKT3 and 64.1). Anti-CD3 was unable to induce activation of AC-depleted T cells as determined by IL 2 receptor expression, IL 2 production, cell cycle analysis, or detectable DNA synthesis. Although T cell responses to PHA also required AC, far fewer were necessary to generate responses. Anti-CD3 inhibited PHA-stimulated T cell IL 2 production, IL 2 receptor expression and proliferation in partially AC-depleted cultures. Moreover, anti-CD3 was able to inhibit PHA responses when added to culture as late as 24 to 42 hr after the initiation of a 96-hr incubation. Increasing concentrations of PHA reduced the inhibitory effect of anti-CD3 on PHA-stimulated T cell proliferation, whereas IL 2 production remained suppressed. Anti-CD3 linked to Sepharose beads effectively inhibited PHA-stimulated T cell DNA synthesis, indicating that internalization of the CD3 molecule was not required for inhibition of PHA responses. Although inhibition of IL 2 production was a major effect of anti-CD3 in PHA-stimulated cultures, it was not the only apparent inhibitory effect because the addition of exogenous IL 2 could not prevent inhibition completely. Intact AC but not IL 1 also reduced anti-CD3-mediated inhibition of PHA responsiveness, whereas the addition of both IL 2 and AC largely prevented inhibition. Thus, anti-CD3 in the absence of adequate AC signals exerted a number of distinct inhibitory effects on mitogen-induced T cell activation. These results suggest that the CD3 molecular complex may play a role in regulating T cell responsiveness after engagement of the T cell receptor by a number of mechanisms, some of which involve inhibition of IL 2 production.     

Effect of T3 modulation on pokeweed mitogen-induced T cell activation: evidence for an alternative pathway of T cell activation

Modulation of the T3 molecule on human T cells with monoclonal anti-T3 antibodies has been shown to result in the disappearance of the T3-Ti complex from the membrane and to preclude subsequent T cell activation by various mitogenic and antigenic stimuli. We have examined the effect of T3 modulation on pokeweed mitogen (PWM)-induced T cell activation. T3 modulation was accomplished by incubating peripheral blood mononuclear cells (PBMC) or mixtures of T cells and non-T cells at 37 degrees C for 18 hr in the presence of UCHT-1, a mouse IgG1 anti-T3 monoclonal antibody. Only donors whose PBMC were unresponsive to the mitogenic activity of this antibody were selected. Although T3 modulation resulted in complete to substantial inhibition of T cell proliferation induced by low PWM concentrations of 5 or 50 ng/ml, it had no effect on T cell proliferation when PWM was added at a concentration of 0.5 and 5 micrograms/ml. The results demonstrate that the higher doses of PWM can induce T cell proliferation via an alternative pathway that does not involve participation of the T3-Ti complex. In contrast, irrespective of the PWM dose added, T3 modulation almost totally inhibited PWM-induced interleukin 2 (IL 2) production. The differential effect of T3 modulation on IL 2 production and on T cell proliferation induced by high doses of PWM suggests that this alternative pathway of T cell proliferation is IL 2 independent. This suggestion was additionally substantiated by the lack of effect of anti-Tac, and anti-IL 2 receptor antibody, on PWM-induced proliferation of T3-modulated T cells. In conclusion our data demonstrate that high doses of PWM can induce T cells to proliferate via an alternative pathway that does not involve perturbation of the T3-Ti complex.     

Differential inhibition of T cell receptor signal transduction and early activation events by a selective inhibitor of protein-tyrosine kinase

Engagement of the TCR (CD3-Ti) by Ag/MHC, CD3 mAb, or lectin mitogen stimulates the very early tyrosine phosphorylation of several cellular substrates including TCR-zeta. The T cell specific protein-tyrosine kinase (PTK), p56lck, has been implicated in the tyrosine phosphorylation of TCR-zeta. However, the significance of this event with regard to CD3-Ti signal transduction remains unclear. Herein, we have investigated the effect of the selective PTK inhibitor genistein (4',5,7-trihydroxyisoflavone) on cellular events associated with activation via CD3-Ti triggering. Genistein inhibited the T cell PTK, p56lck, in a dose-dependent fashion with an ID50 = 40 microM. Genistein also inhibited CD3 mAb or PHA-induced TCR-zeta chain phosphorylation in intact peripheral blood T cells. Genistein blocked the expression of IL-2 and IL-2R (CD25) in T cells stimulated with PHA/PMA or CD3 mAb/PMA, but did not inhibit the de novo expression of the CD69 early activation Ag, which is induced primarily by a PKC-dependent pathway. IL-2 and CD25 expression induced by calcium ionophore A23187 and PMA was largely refractory to inhibition by genistein, suggesting an effect of the drug on calcium-dependent pathways stimulated via CD3-Ti triggering. In this last regard, genistein partially inhibited the CD3 mAb-induced rise in [Ca2+]i but did not inhibit PHA- or CD3 mAb-induced phosphatidylinositol hydrolysis. Consequently, protein-tyrosine phosphorylation does not appear to be a prerequisite for CD3-Ti-mediated activation of phosphatidylinositol-specific phospholipase C activity and PIP2 hydrolysis. An alternative role for PTK in CD3-Ti signal transduction is suggested.     

Immunologic and molecular characterizations of T cell-derived T cell activating factor

Culture supernatants from several subclones of a human T hybrid line (24A) stimulated with PMA showed co-stimulatory activity in the proliferation of Con A-stimulated murine thymocytes, but did not show any IL 2 activity. Some subclones did not show co-stimulatory activity even when stimulated with PMA, excluding the possibility of a carry-over effect. The factor found in the culture supernatants increased IL 2 production in normal T cells stimulated with a suboptimal concentration of PHA. The factor also induced IL 2 production in a T hybrid clone, T-394.1, when the latter was stimulated with a suboptimal concentration of mitogens, indicating a direct effect by this T cell-derived factor on mitogen-stimulated T cells inducing IL 2 production. This factor also induced the generation of other lymphokines such as BCDF and IFN-gamma. Northern blot analysis showed that the factor induced an increase in mRNA for IL 2 as well as IL 2 receptor. These results indicated that T cells could secrete a factor with IL 1-like activity. However, Northern blot analysis showed that mRNA from a T hybrid clone does not cross-react with cDNA for IL 1 (beta) derived from human monocytes.     

Stimulation and inhibition of human T cell subsets by wheat germ agglutinin

Wheat germ agglutinin (WGA), a tetravalent lectin, has both stimulatory and inhibitory effects on human T lymphocytes. It has been suggested that these actions are related and that WGA selectively stimulates a suppressive subset of T cells. We studied the ability of WGA to stimulate and inhibit subpopulations of human peripheral blood mononuclear cells (PBMC) known to have helper or suppressor activity. Fresh human PBMC were depleted of either T4+ or T8+ cells by using antibody-mediated complement lysis. The resultant cell populations were stimulated with WGA, and the proliferative response was assessed by [3H]thymidine incorporation, IL 2 receptor expression, the ability to elaborate IL 2 in culture supernatants, and the susceptibility to inhibition by the monoclonal antibody anti-Tac. Similar experiments with cells from a WGA-responsive continuous T cell culture were also performed. WGA inhibited phytohemagglutinin (PHA)-induced proliferation of PBMC depleted of either T4+ or T8+ cells. WGA also inhibited PBMC that had been depleted of adherent cells and Ia+ cells and then induced to proliferate with a combination of TPA and PHA. Our findings indicate that WGA induces IL 2-dependent proliferation in a small proportion of both T4+ and T8+ lymphocytes. We also provide evidence that the inhibitory activity of WGA is not mediated by a T4+, T8+, or Ia+ cell, suggesting that WGA acts directly on the proliferating cell rather than selectively stimulating a suppressive subpopulation.     

Wheat germ agglutinin activates human T lymphocytes by stimulation of phosphoinositide hydrolysis

Recently, it has become evident that stimulated phosphoinositide (PI) hydrolysis plays a crucial role in early T lymphocyte activation. We have investigated the effects of the nonmitogenic lectin wheat germ agglutinin (WGA) on several parameters associated with PI hydrolysis in human T cells. It was found that WGA was as effective as anti-T3 antibody and PHA in producing a rise in cytosolic free Ca++ ((Ca++)i) in blood T cells and in cells of the T cell line CCRF-CEM. It was inferred that identical cells within the blood T cell preparation responded to each of the three agents, refuting the contention that WGA only stimulated a subfraction of circulating mature T lymphocytes. WGA-induced, but not PHA-induced rises in (Ca++)i could be blocked completely by N-acetyl-D-glucosamine, demonstrating that the sugar-binding characteristics of the lectin dictate its action on T lymphocytes. Anti-T3 antibody, PHA, and WGA all initiated inositol phosphate formation in blood T cells, indicating that each of the agents stimulated PI hydrolysis. The combination of WGA with nonmitogenic amounts of phorbol-12-myristate-13-acetate resulted in strong mitogenicity. It is concluded that WGA, like anti-T3 antibody and PHA, is a pan-T activator of PI hydrolysis.     

Activation of IL 1-dependent and IL 1-independent T cell lines by calcium ionophore and phorbol ester

We have studied the activation of interleukin 1 (IL 1)-dependent and IL 1-independent T cell lines, specifically their capacity to produce and secrete interleukin 2 (IL 2). The IL 1-dependent T cell lymphoma LBRM33-1A5.47, which requires phytohemagglutinin (PHA) and IL 1 to produce IL 2, was compared with the IL 1-independent T cell lymphoma LBRM33-5A4 and T cell hybridomas DO-11.10/S4.4 and 3DO-54.8. The latter hybridomas do not require exogenous IL 1 to produce IL 2 in response to mitogens or ovalbumin (OVA)/I-Ad. Even though IL 1 is not required by these IL 1-independent T cell lines, we tested whether IL 1 could modulate their response but found no significant effect of exogenous IL 1. We then studied the activation of these T cell lines by the calcium ionophore A23187 and phorbol myristate acetate (PMA). In the case of the IL 1-dependent line LBRM33-1A5.47, there was a strong response when both A23187 and PMA were used simultaneously. We subsequently found that A23187 can replace PHA, and PMA can replace IL 1 in the activation of this cell line to IL 2 production. These observations suggest that the signal(s) provided by PHA and IL 1 involve at least in part a calcium flux, and activation of protein kinase C. Parallel experiments with the use of the IL 1-independent T cell lines showed a strong response to both agents when used simultaneously. A modest response observed to A23187 alone was always enhanced by the addition of PMA. No response was observed to PMA alone. IL 1-rich P388D1 supernatant could replace the enhancing effect of PMA in the response of the IL 1-independent T cell lines. We suggest that the activating signals provided by A23187 and PMA are at least part of the sequence of events that lead to production of IL 2 in either IL 1-dependent or IL 1-independent T cell lines. In IL 1-independent T cell lines, however, both of the activating signals studied may be delivered through stimulation of the Antigen-MHC T cell receptor.     

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.     

Effect of wheat germ agglutinin on T lymphocyte activation

Wheat germ agglutinin (WGA) is low mitogenic or nonmitogenic for human T lymphocytes and inhibits phytohemagglutinin (PHA)-induced mitotic response of the lymphocytes. In this study, the effect of WGA was analyzed in terms of interleukin 2 (IL2) production, expression of IL2 receptor, and IL2 responsiveness of the T lymphocytes. WGA as well as PHA could induce IL2 mRNA and IL2 production and also elevate cytoplasmic free Ca2+ concentration. The IL2 production was reduced by inhibitors of calmodulin and protein kinase C. The IL2 receptor (Tac) expression was induced at about 20% of the lymphocytes by WGA and the expression induced by PHA was not blocked by the addition of WGA. The lymphocytes precultured with WGA for 3 days could proliferate by the addition of IL2 after removal of WGA. The IL2-dependent proliferation of PHA-blasts was blocked by the addition of WGA. These results indicate that WGA inhibits T lymphocyte proliferation by inhibiting the responsiveness of the lymphocytes to IL2 but not by interfering with IL2 production and IL2 receptor expression.     

Modulation of cytolytic T cell function by lectins

Human thymocytes cultured for 5 days in interleukin 2 containing supernatants (IL 2 Sup) virtually become a population of mature T cells (T3+, HTA-) that acquires strong cytotoxic activity against NK-sensitive and NK-resistant target cells. The addition of different lectins to the cultures abrogated the expression of the cytotoxic activity and enhanced thymocyte proliferation. The modulation of this cytotoxic activity by lectins has the following properties: a) inhibition of cytotoxicity is related to the concentration of lectins added, but does not correlate with their mitogenic properties, because either strong mitogens such as PHA or weak mitogens such as wheat germ agglutinin (WGA) are both able to strongly decrease cytotoxicity; b) lectin presence is not required at the onset of the culture but is required during the last 24 hr of the 5-day incubation period; c) reversion of inhibition with full expression of cytotoxic activity can be obtained after removal of the lectin and subsequent culture in lectin-free conditions for at least an 18 to 24 hr period; d) lack of cytotoxicity is observed regardless of target cell specificities and cannot be overcome in a lectin-dependent cytotoxicity assay (LDCC); and e) abrogation of cytotoxicity is not restricted to thymocyte cultures because it can also be observed in peripheral lymphocytes. These results cannot be explained by a simple steric blockade, the overgrowth of a distinctive noncytotoxic lymphocyte population, autologous killing, or a failure in the recognition phase of the lytic event. Modulation by lectins of function-associated cell surface structures implicated in cytolysis is discussed as an alternative hypothesis that might account for the observed phenomenon.     

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.     

Distinct signals are required for proliferation and lymphokine gene expression in murine T cell clones

Experiments were performed to assess the capacity of lectin (Con A), ionomycin, phorbol ester (PMA), and recombinant IL 2 to mediate proliferation as well as the expression of cell surface IL 2 receptors, two lymphokine genes, IL 2 and IFN-gamma, and the c-myc proto-oncogene in cloned T cell populations. Stimulation of T cell clones with recombinant IL 2 resulted in proliferation and sustained expression of the c-myc cellular proto-oncogene, but did not induce the expression of mRNA for the lymphokines IFN-gamma and IL 2. In contrast, stimulation of cloned T cells with lectin alone induced significant IFN-gamma and IL 2 mRNA expression, up-regulation of the number of cell surface IL 2 receptors, and transient c-myc expression. Ionomycin alone was not a sufficient signal for lymphokine mRNA induction. The phorbol ester PMA alone induced neither proliferation nor lymphokine gene expression but potentiated lectin and ionomycin-mediated signals. We also performed experiments to examine whether the T cell response to extracellular stimuli was a function of the activation state of the cell. Reexposure of 48-hr antigen-activated cloned cells to identical stimuli revealed several differences. Low but significant levels of IFN-gamma mRNA were now also reinduced in activated clones cells in response to IL 2 or PMA alone. Activated cells were refractory to reinduction of IL 2 mRNA by any stimulus, which may reflect a physiologic mechanism to limit clonal expansion after antigenic stimulation. This could be partially reversed by restimulation with lectin in the presence of cycloheximide, suggesting a role for a labile protein repressor in the down-regulation of IL 2 mRNA expression. PMA alone induced an IL 2-independent proliferative response. We demonstrate that distinct signals are required for lymphokine gene expression vs cellular proliferation in cloned T lymphocyte populations, and that the capacity of extracellular stimuli to reinduce expression of lymphokine genes or to mediate cell proliferation is altered by prior activation.     

The role of T3 surface molecules in the activation of human T cells: a two-stimulus requirement for IL 2 production reflects events occurring at a pre-translational level

The human T cell leukemia Jurkat was used as a model to examine the requirements of T cell activation. These studies demonstrated that antibodies reactive with the T cell-specific T3 antigen were insufficient to result in the activation of Jurkat cells, determined by the secretion of IL 2. IL 2 production occurred only in the presence of a second stimulus, the phorbol ester PMA. With the use of an IL 2-specific cDNA probe, the appearance of IL 2 RNA, similarly, occurred only when cells were stimulated with both anti-T3 antibodies and PMA. These results demonstrate a two-stimulus requirement for gene expression in human T cells.     

Inhibition of lymphocyte proliferation by monoclonal antibody directed against the T3 antigen on human T cells

Peripheral blood mononuclear cells from 40% of normal donors are mitogenically unresponsive to UCHT1, a monoclonal antibody reactive to the T3 surface molecule on human T lymphocytes. Cell preparations from non-UCHT1 responders were used to examine whether and how interaction of UCHT1 with the T3 molecule affects T-cell functionality. It was found that UCHT1 profoundly (greater than 85%) suppressed lymphocyte proliferation induced by plant mitogens (phytohemagglutinin (PHA) and concanavalin A (Con A], recall antigen (candidin), and allogeneic non-T cells. The antibody abrogated both the production of interleukin 2 (IL-2) by and the expression of IL-2-specific receptors on T lymphocytes stimulated by PHA or allogeneic non-T cells. UCHT1 was maximally suppressive when added to cells within 2 hr (PHA stimulation) or 1 day (allogeneic non-T cell activation) after the initiation of the culture period. The inhibiting activity of UCHT1 could be related to its ability to modulate T3 molecules from the T-cell surface: both actions displayed the same antibody concentration dependence and had a comparable time dependence. Moreover, after modulation, unresponsive lymphocytes regained responsiveness to PHA in parallel with reexpression of surface T3 molecules. These findings are consistent with the idea that the human T3 molecule functions as an essential signal transducer during the early phases of T-cell activation.     

Regulation of interleukin 2 receptor expression: effects of phorbol diester, phospholipase C, and reexposure to lectin or antigen

Anti-Tac monoclonal antibody identifies the receptor for interleukin 2 (IL 2, or T cell growth factor) present on activated human T lymphocytes. By using tritiated anti-Tac, we now report a sensitive and specific binding assay to evaluate cell surface IL 2 receptor expression. IL 2 receptors on human peripheral blood lymphocytes can be detected within 6 hr after PHA stimulation. PHA-induced receptor expression is inhibited by actinomycin D and cycloheximide, but not by mitomycin C, suggesting a requirement for de novo RNA and protein synthesis, but not DNA synthesis. Scatchard analysis of [3H]-anti-Tac binding to lymphocytes stimulated with PHA for 3 days revealed from 20,000 to 60,000 molecules of antibody bound per cell, and a Kd of 1 to 3 x 10(-10) mol/l. Sequential binding studies of activated human lymphocytes maintained in long-term culture with IL 2 demonstrated a progressive decline in receptor number correlating with diminished growth rate. Restimulation with lectin or antigen increased the number of IL 2 receptors, suggesting that IL 2 dependent immune responses may be regulated, at least in part, by IL 2 receptor expression. Receptor number was also increased by PMA. Moreover, similar effects were produced by incubation with phospholipase C but not interleukin 1. Because both PMA and phospholipase C result in activation of protein kinase C, these data suggest the possibility that activation of protein kinase C may induce IL 2 receptor expression.     

FK-506 and cyclosporin A inhibit highly similar signal transduction pathways in human T lymphocytes.

This report compares the ability of cyclosporin A and FK-506 to inhibit human T cell activation triggered via cell surface molecules that utilize different intracellular processes. We stimulated highly purified peripheral blood T lymphocytes with mitogens (Con A and PHA), ionomycin + PMA, or monoclonal antibodies specific for cell surface antigens involved in activation (CD2, CD3, CD28) either in combination with each other or in conjunction with PMA. Using measurements of the proliferative response, IL-2 production, and changes in intracellular Ca2+ ([Ca2+]i), we demonstrate that FK-506 exerts its inhibitory effect on early events of T-cell activation in a manner indistinguishable from that of CsA. An important finding in this study is the strict correlation between those activation pathways that are inhibited by FK-506 and CsA and the requirement that the sensitive pathways induce a measurable rise in [Ca2+]i. This correlation held even for the CD28/CD2 pathway which was previously shown to be calcium-independent; however by employing FACS analysis of [Ca2+]i within individual cells, a subset of cells activated via CD28/CD2 was found to respond with a measurable rise in [Ca2+]i. We also noted that the proliferative response induced by certain stimuli, such as ionomycin + PMA and PHA + PMA, was partially resistant to FK-506 and CsA, while IL-2 production was completely suppressed. The partial FK-506/CsA-resistance of these responses was shown to be determined by the amount of PMA added to the cultures. We conclude from our investigations that FK-506 and CsA inhibit highly similar signal transduction pathways in human T lymphocytes.     

A transferrin receptor antibody represents one signal for the induction of IL 2 production by a human T cell line

We previously demonstrated a two-signal requirement for the activation of the human T cell lines Jurkat and HUT 78. Interleukin 2 (IL 2) production by these lines can be induced by phytohemagglutinin (PHA), T3 antibodies, or calcium ionophores, but only in combination with phorbol myristate acetate (PMA). To obtain further information about surface structures involved in T cell activation, we produced a monoclonal antibody that could substitute for PMA in the activation of HUT 78. This antibody, designated J64, induced IL 2 secretion by HUT 78 in combination with PHA, T3 antibodies, or calcium ionophores, however not by itself. J64 also had other PMA-like effects on HUT 78, such as an increase in IL 2 receptor expression and an inhibition of cell growth. J64 was shown to immunoprecipitate the transferrin receptor (TfR). However, it bound to an epitope different from those recognized by other TfR antibodies and different from the transferrin-binding site. In addition, other previously described TfR antibodies did not, like J64, function as activating stimuli for HUT 78. Possible mechanisms for activation signaling in T cells involving the TfR are discussed.