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.     

A Na(+)-dependent Ca2+ exchanger generates the sustained increase in intracellular Ca2+ required for T cell activation.

Movement of extracellular Ca2+ is required for the sustained increase in [Ca2+]i necessary for T cell activation. However, the mechanisms mediating mitogen-stimulated Ca2+ movement into T cells have not been completely delineated. To explore the possibility that a Na(+)-dependent Ca2+ (Na+/Ca2+) exchanger might play a role in the mitogen-induced increases in [Ca2+]i required for T cell activation, the effects of inhibitors of this exchanger were examined. Inhibitors of Na+/Ca2+ exchange suppressed the sustained increase in [Ca2+]i stimulated by ligation of the CD3-TCR complex, but did not affect mobilization of intracellular Ca2+ stores. Consistent with the importance of this prolonged increase in [Ca2+]i in T cell activation, Na+/Ca2+ exchange inhibitors, but not inhibitors of the Na+/H+ antiporter, inhibited DNA synthesis stimulated by immobilized anti-CD3 mAb. Inhibition only occurred when the agents were present during the first hours after stimulation. These agents also inhibited IL-2 production, but not expression of the IL-2R or of an early activation Ag, 4F2. Inhibition of IL-2 production did not account for the inhibition of T cell proliferation as addition of exogenous IL-2 or phorbol ester (PDB) did not overcome the inhibition. In contrast, activation pathways that are not thought to require an increase in [Ca2+]i such as IL-1 + PDB or engagement of CD28 in the presence of PDB were less sensitive to the suppressive effects of inhibitors of Na+/Ca2+ exchange. Thus, proliferation induced by these stimuli was not suppressed by low concentrations of these inhibitors and IL-2 production induced by mAb to CD28 + PDB was not inhibited by any concentration of inhibitors of Na+/Ca2+ exchange. These results suggest that stimulation of a Ca2+ transporter with the same spectrum of inhibition as the Na+/Ca2+ exchanger in other tissues mediates the sustained increase in [Ca2+]i required for T cell activation after CD3 ligation.     

Patterns of costimulation of T cell clones by cross-linking CD3, CD4/CD8, and class I MHC molecules

The ability of mAb to class I MHC molecules, CD3, or CD4/CD8 to stimulate human T cell clones alone or in combination was examined. Cross-linking each of these surface Ag with appropriate mAb and goat anti-mouse Ig (GaMIg) resulted in a unique pattern of increase in intracellular free calcium ([Ca2+]i) and different degrees of functional activation. Cross-linking class I MHC molecules provided the most effective stimulus of IL-2 production and proliferation. Cross-linking more than one surface Ag induced a compound calcium signal with characteristics of each individual response. Cross-linking CD3 + HLA-A,B,C caused a rapid and prolonged increase in [Ca2+]i and synergistically increased IL-2 production and proliferation of all clones. Cross-linking CD3 + CD4/CD8 also generated a compound calcium signal and increased IL-2 production and DNA synthesis. Purposeful inclusion of CD3 was not required for costimulation as cross-linking HLA-A,B,C + CD4/CD8 also increased [Ca2+]i, IL-2 production, and proliferation. Cross-linking three surface Ag, CD3 + HLA-A,B,C + CD4/CD8, resulted in the greatest initial and sustained [Ca2+]i, IL-2 production, and DNA synthesis. Although there was a tendency for the various stimuli to increase both [Ca2+]i and functional responsiveness, neither the magnitude nor duration of the increased [Ca2+]i correlated with the amount of IL-2 produced or the ultimate proliferative response. To determine whether costimulation required that the various surface molecules were cross-linked together, experiments were carried out using isotype specific secondary antibodies. Augmentation of [Ca2+]i and costimulation of functional responses were noted when class I MHC molecules were cross-linked and CD3 was bound, but not cross-linked. Similarly, costimulation through CD3 and CD4/CD8 was observed when CD4/CD8 was cross-linked and the CD3 complex was engaged by an anti-CD3 mAb which was not further cross-linked. In contrast, costimulation by class I MHC molecules and CD4/CD8 was only observed when these molecules were cross-linked together. These data demonstrate that cross-linking class I MHC determinants or CD4/CD8 provides a direct signal to T cell clones that can be enhanced when CD3 is independently engaged. The results also indicate that T cell clones can be stimulated without engaging CD3 by the combination of signals delivered via class I MHC molecules and CD4/CD8, but only when these determinants were cross-linked together. These studies have demonstrated that these cell surface molecules differ in their capacity to deliver activation signals to T cell clones and also exhibit unique patterns of positive cooperativity in signaling potential.     

The role of the L3T4 molecule in mitogen and antigen-activated signal transduction

We investigated the role of the L3T4 molecule in mitogen and antigen-initiated signal transduction in the L3T4(+) murine T cell hybridoma, 3DT52.5.9 and an L3T4(-) variant, 3DT52.5.24. Both Concanavalin A (Con A) and specific antigen stimulated increases in cytosolic-free calcium ([Ca2+]i), phosphatidylinositol turnover, and interleukin-2 (IL-2) production in both cell lines. About 85% of the stimulated rise in [Ca2+]i was from an extracellular source. Anti-L3T4 monoclonal antibody (MAb) inhibited 90% of antigen- and 50% of Con A-stimulated increases in [Ca2+]i and IL-2 production but had no effect on the ability of either activation signal to stimulate phosphatidylinositol turnover in the parent L3T4(+) cells. Stimulus-response coupling in the L3T4(-) cells was unaffected by the MAb. The anti-L3T4-insensitive increase in [Ca2+]i induced by Con A was inhibited by EGTA, suggesting that this mitogen also stimulated an influx of Ca2+ via an additional transport mechanism distinct from that stimulated by antigen. The fact that anti-L3T4 antibodies inhibit antigen and Con A-stimulated Ca2+ transport and IL-2 production without affecting phosphatidylinositol turnover suggests that L3T4 may play a critical role in modulating the activation of the T cell receptor-associated Ca2+ transporter in T cell stimulus-response coupling.     

Activation of human T cell clones and Jurkat cells by cross-linking class I MHC molecules

Cross-linking class I MHC molecules on human T cell clones by reacting them with various mAb directed at either monomorphic or polymorphic determinants on class I MHC molecules followed by cross-linking with GaMIg stimulated a rise in intracellular free calcium concentration ([Ca2+]i), and induced proliferation and IL-2 production. T cell clones varied in the mean density of class I MHC molecules and the capacity to respond to mAb to class I MHC molecules. However, the functional responses of the clones did not correlate with class I MHC density or the CD4/CD8 phenotype. mAb to polymorphic class I MHC determinants were less able to induce an increase in [Ca2+]i and a functional response in the T cell clones. Additive stimulatory effects were noted when mAb against both HLA-A and HLA-B determinants were employed. Cross-linking class I MHC molecules on Jurkat cells induced a rise by [Ca2+]i and induced IL-2 production upon co-stimulation with PMA. Cross-linking class I MHC molecules on mutant Jurkat cells that expressed diminished levels of CD3 and were unable to produce IL-2 in response to anti-CD3 stimulation triggered both a rise in [Ca2+]i and IL-2 production with PMA co-stimulation. In contrast, cross-linking class I MHC molecules on mutant Jurkat cells that were CD3- stimulated neither a rise in [Ca2+]i nor IL-2 production. The combination of mAb to CD28 or ionomycin and PMA, however, was able to induce IL-2 production by CD3- Jurkat cells. The data demonstrate that cross-linking class I MHC molecules delivers a functionally important signal to T cell clones and Jurkat cells and indicate that class I MHC molecules may function to transduce activation signals to T cells. In addition, the data demonstrate that transmission of an activation signal via class I MHC molecules requires CD3 expression. The data, therefore, support a central role for CD3 in the transduction of activation signals to T cells via class I MHC molecules.     

Intact antigen receptor-mediated generation of inositol phosphates and increased intracellular calcium in CD4 CD8 T lymphocytes from MRL lpr mice

The predominant T lymphocytes that accumulate in the peripheral lymphoid tissues of mice homozygous for the lpr gene bear the phenotype CD3+CD4-CD8-. By certain functional criteria these cells would appear to have impaired CD3-mediated signal transduction, in that they do not respond to alloantigen and produce little if any detectable IL-2 or other lymphokines. However, the signal pathway appears adequate for achieving other T cell functions, including induction of high affinity IL-2R, and thymic deletion. To clarify the basis of this seeming discrepancy, we examined transmembrane signal transduction in T cell subsets of lpr/lpr (lpr) and +/+ mice, as defined by increased [Ca2+]i and the generation of inositol phosphates (InsPs). Stimulation of lpr CD4-CD8- cells with anti-CD3 antibody produced prompt and sustained increases in the concentration of [C2+]i and in InsPs. Similar responses occurred in mature T cells from lpr and +/+ mice, except for the somewhat slower kinetics of their increased [Ca2+]i. In marked distinction to the anti-CD2-mediated response, Con A, even in high doses, could not stimulate any increase of [Ca2+]i in lpr CD4-CD8- cells, and only modest increases in InsPs. Mature T cells, whether of lpr or +/+ origin, yielded normal increased [Ca2+]i with Con A. The reason for the differences in signal transduction between anti-CD3 and Con A stimulation of lpr CD4-CD8- cells may relate to the absence of surface structures on these immature T cells that are required for activation by Con A but not by anti-CD3. The data demonstrate that the CD3 complex in lpr CD4-CD8- T cells can couple to phospholipase C to hydrolyze phosphoinositides. These activation properties of lpr CD4-CD8- T cells have interesting functional parallels to thymocytes at the time of thymic selection, as well as tolerance induction of mature T lymphocytes.     

The induction of T cell unresponsiveness by rapidly modulating CD3

The immunomodulatory effects of an IgM anti-CD3 mAb (38.1) were investigated. 38.1 was distinct from other anti-CD3 mAb, in that it was rapidly modulated from the cell surface in the absence of a secondary antibody. Although 38.1 induced an immediate increase in intracellular free calcium [Ca2+]i by highly purified T cells, it did not induce entry of the cells into the cell cycle in the absence of accessory cells (AC) or a protein kinase C-activating phorbol ester. Clearing of 38.1 from the surface of AC-depleted T cells, documented both by immunofluorescence and by functional activity, was rapid, with markedly reduced levels of initially bound mAb observed after a 1 to 2 h incubation at 37 degrees C and complete modulation noted after a 5-h incubation. Despite rapid modulation of 38.1, the T cells continued to express substantial amounts of surface CD3, suggesting there is a rapid rate of turnover of CD3 molecules on resting T cells. After modulation of 38.1 bound CD3, T cells were markedly inhibited in their capacity to respond to PHA. Inhibition could be overcome by culturing the cells with supplemental AC or IL-2. The inhibitory effects of 38.1 could be mimicked by briefly pulsing cells with the calcium ionophore, ionomycin, that had no effect on surface expression of CD3. 38.1- or ionomycin-pulsed cells were inhibited in their subsequent response to PHA even when exposures were carried out in the presence of EGTA to prevent increases in [Ca2+]i from extracellular sources. Inhibition could not be accounted for by an inability of the ionomycin-treated or 38.1-modulated T cells to increase [Ca2+]i in response to PHA. These studies demonstrate that a state of T cell nonresponsiveness can be induced by modulating CD3 with an anti-CD3 mAb in the absence of co-stimulatory signals. A brief increase in [Ca2+]i resulting from mobilization of internal calcium stores appears to be sufficient to induce this state of T cell nonresponsiveness.     

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.     

hsBAFF regulates proliferation and response in cultured CD4(+) T lymphocytes by upregulation of intracellular free Ca(2+) homeostasis

B cell activating factor belonging to the TNF family (BAFF, also called BLyS, TALL-1, THANK, or zTNF4) is an important survival factor for B cells, and is able to regulate T-cell activation. Recently, we have demonstrated that treatment of mice with human soluble BAFF (hsBAFF) causes a significant increase of percentages of splenic CD4(+) T lymphocytes dose-dependently, but the CD8(+) T lymphocyte percentages maintained unchanged. Here, we show that hsBAFF significantly enhanced CD4(+) T lymphocyte response of cultured mouse splenic cells, and hsBAFF induced the proliferation and IL-2/IFN-γ secretion of purified CD4(+) T lymphocytes suboptimally stimulated through anti-CD3. Of importance, we observed that IL-2 or IFN-γ cytokine has additive effect on the proliferation and activity of hsBAFF-stimulated CD4(+) T lymphocytes. Using Flow cytometry with fluorescent probe, Fluo-3/AM, we found that hsBAFF elicited [Ca(2+)](i) elevation contributing to CD4(+) T cell proliferation. This is evidenced by our finding that pretreatment with BAPTA/AM, an intracellular Ca(2+) chelator, significantly attenuated the proliferation of hsBAFF-stimulated CD4(+) T lymphocytes. Subsequently, we revealed that hsBAFF-stimulated CD4(+) T cell proliferation was markedly suppressed after pretreatment with EGTA, an extracellular Ca(2+) chelator, or with 2-APB, an inhibitor of Ca(2+) influx through CRAC channels, respectively, suggesting that extracellular Ca(2+) influx due to hsBAFF is closely associated with [Ca(2+)](i) elevation contributing to CD4(+) T cell proliferation. In addition, we noticed that hsBAFF-treated cells conferred partial resistance to decrease of cellular viability induced by thapsigargin (Tg), an endoplasmic reticulum (ER) Ca(2+)-ATPase inhibitor. Taken together, our data indicate that hsBAFF may promote CD4(+) T cell proliferation and response by upregulation of [Ca(2+)](i) homeostasis.     

Differences of T-cell activation by the anti-CD3 antibodies Leu4 and BMA030

Two anti-CD3 antibodies and their Fab/F(ab')2 fragments were compared with regard to their requirement for secondary signals and generations of intracellular messengers. The anti-CD3 antibody BMA030 was found to require monocyte contact to elicit T-cell mitogenesis. Cross-linking by plastic-bound goat anti-mouse antibodies (panning) failed to activate T cells, even in the presence of recombinant IL-1 or IL-2. In contrast, crosslinking of the anti-CD3 antibody Leu4 or Leu4 fragments was mitogenic in monocyte-free cultures. Measurements of intracellular Ca2+ ([Ca2+]i) and generation of inositol phosphates revealed that binding (+/- panning) of BMA030, Leu4, and their F(ab')2 fragments generated similar amounts of intracellular messengers and thus failed to explain the different responsiveness to passive crosslinking. Since the generation of these messengers was not necessarily followed by proliferation but was always observed when mitogenesis occurred, we conclude that the elevation of [Ca2+]i and the production of inositol phosphates are required but not sufficient to trigger mitogenesis.     

Quantitative analysis of the cytosolic-free-Ca2+-dependency of aldosterone production in bovine adrenal glomerulosa cells. Different requirements for angiotensin II and K+.

Angiotensin II (AII) and K+ raise the cytosolic free Ca2+ concentration [( Ca2+]i) and stimulate aldosterone production in isolated bovine adrenal glomerulosa cells. The mechanisms leading to an elevation of [Ca2+]i were analysed with the fluorescent Ca2+ probe quin 2. (1) Whereas [Ca2+]i rose transiently and returned to basal values within 5 min in response to AII, the effect of K+ was sustained for at least 15 min. (2) AII released Ca2+ from intracellular stores, whereas the [Ca2+]i response to K+ depended solely on extracellular [Ca2+]. (3) When added after K+ stimulation, AII provoked a dramatic decrease in [Ca2+]i to below the resting value. The role of [Ca2+]i in stimulating steroidogenesis was determined by manipulating the concentration of this cation. (4) In a cell superfusion system, the aldosterone response to AII is biphasic. Suppressing the transient [Ca2+]i elevation triggered by AII resulted in the disappearance of the initial secretory peak, but the final production rate was similar to that of control cells. (5) Normal basal [Ca2+]i levels were, however, necessary to maintain continuous AII-induced steroidogenesis. (6) When added after AII, the antagonist analogue [Sar1,Ala8]AII suppressed steroidogenesis without affecting [Ca2+]i levels. (7) In contrast, continuously elevated [Ca2+]i values were required for the initiation and the maintenance of K+-stimulated aldosterone production. These results demonstrate important differences in the mechanisms through which AII and K+ activate the Ca2+ messenger system. Moreover, functional correlations have shown that K+, but not AII, depends solely on a sustained [Ca2+]i response for its steroidogenic effect. However, the AII-induced effect is also a Ca2+-requiring process: the initial [Ca2+]i transient accelerates the onset of steroidogenesis, which is subsequently extremely sensitive to [Ca2+]i decreases below normal basal levels.     

Functional alterations of herpes simplex virus-specific CD4+ multifunctional T cell clones following infection with human T lymphotropic virus type I

In an attempt to understand the mechanisms of immunodeficiency induced by human T lymphotropic virus type I (HTLV-I), HSV-specific CD4+ human multifunctional T cell clones were infected with HTLV-I in vitro. Early after HTLV-I infection, when their growth was still IL-2-dependent, clones were found to have almost completely lost their cytotoxic activity. At that time, their HSV-Ag-induced proliferative response and helper function for anti-HSV antibody production by B cells were only partially impaired. After this initial phase, the HTLV-I-infected clone became IL-2-independent, and the helper function was also completely lost. IL-2-dependent HTLV-I-infected clones showed degrees of proliferative response and elevation of intracellular free Ca2+ concentration induced by anti-CD3 mAb equivalent to those of HTLV-I-uninfected clones. On the other hand, during the IL-2-independent stage, expression of CD3-TCR complex on the cell surface was markedly decreased, and no significant elevation of intracellular free Ca2+ concentration was detected in response to anti-CD3 mAb. These data indicated that the loss of cytotoxic activity of HSV-specific T cell clones observed early after HTLV-I infection was not the result of impaired antigen recognition via the CD3-TCR complex, but might be due to dysfunction in the effector phase. On the other hand, the dysfunction of helper activity found late after HTLV-I infection might have mainly occurred in the recognition phase due to the decreased expression of CD3-TCR complex. The present data appear to suggest certain aspects of the pathogenesis of the immunodeficiency occurring in HTLV-I infection.     

Evidence implicating utilization of different T cell receptor-associated signaling pathways by TH1 and TH2 clones

We have reported recently that high concentrations of anti-CD3 mAb inhibited IL-2-dependent proliferation of TH1 but not TH2 clones. The selective inhibitory effect on TH1 clones suggested that the two helper T lymphocyte subsets might utilize different TCR-associated signal transduction mechanisms. In the present study, we demonstrate that this distinction was not due to a gross difference in the level of TCR expression by TH1 and TH2 clones. Inhibition of TH1 proliferation by anti-CD3 mAb appeared to depend on calcium for maximal effect, suggesting that a substantial elevation of intracellular free calcium concentration ([Ca2+]i) might not occur after ligation of the TCR complex of TH2 clones. Calcium ionophore inhibited IL-2-dependent proliferation of both subsets, suggesting that receptor/ligand systems which stimulate elevated [Ca2+]i would be expected to inhibit proliferation. Although elevated [Ca2+]i and generation of inositol phosphates were readily detected in TH1 clones, these second messengers were not detected following stimulation of TH2 clones via the TCR complex. In addition, lymphokine production by TH1 clones was more sensitive to inhibition by cholera toxin, 8-bromoadenosine 3':5'-cyclic monophosphate, and cyclosporin A than was lymphokine production by TH2 clones. Collectively, these results suggest that TH1 and TH2 clones utilize distinct TCR-associated signal transduction mechanisms for lymphokine gene expression. The difference in signaling mechanisms suggests a potential pharmacologic target for intervention in situations where inappropriate activation of TH1 or TH2 cells occurs in vivo.     

Murine lymphocytes exhibit heterogeneity in their proliferative responsiveness to calcium ionophore.

The calcium ionophore, A23187, when used alone was found to induce proliferation of murine T cells, at concentrations of 0.5-1 mM. This response required the presence of syngeneic splenic adherant cells (SAC) as a source of accessory cells. Interestingly, only CD4+ T cells but not CD8+ T cells or B cells responded to the calcium ionophore by proliferation. The inability of CD8+ T cells or B cells to respond was not related to decreased elevation in the intracellular ionized calcium [Ca2+]i concentration induced by the ionophore, because activated CD4+ T, CD8+ T and B cells all exhibited similar elevation in [Ca2+]i. The inability of CD8+ T cells to respond to calcium ionophore was probably due to insufficient production of autocrine growth factors, such as IL-2, inasmuch as the addition of exogenous IL-2 could completely restore the CD8+ T cell responsiveness. Also, exogenous rIL-1 could partially restore purified T cell response to calcium ionophore, whereas, rIL-6 failed to do so. IL-2, but not IL-4, acted as an autocrine growth factor for T cells responding to the calcium ionophore in the presence of SAC, since, antibodies against IL-2 or IL-2 receptor (IL-2R) but not against IL-4, could inhibit the T cell proliferation. Furthermore, exogenous rIL-2 but not rIL-4 supported the proliferation of T cells to calcium ionophore in the absence of accessory cells. Our results suggest that murine lymphocytes exhibit heterogeneity in their proliferative responsiveness to calcium ionophore and that this may not depend on the early activation signal such as the elevation in [Ca2+]i) induced by the ionophore but may depend on subsequent signals which regulate endogenous growth factor production.     

Ca2+ entry in T cells is activated by emptying the inositol 1,4,5-triphosphate sensitive Ca2+ pool

Using alpha-linolenic acid (ALA), one of several polyunsaturated fatty acids (PUFAs) that have previously been shown to both mobilize intracellular Ca2+ from the inositol 1,4,5-trisphosphate (IP3)-sensitive Ca2+ pool independently of IP3 production and inhibit Ca2+ influx, the relationship between Ca2+ mobilization from intracellular stores and Ca2+ influx in T cells (JURKAT) was studied. JURKAT cells were treated with 30 microM ALA to deplete the IP3-sensitive Ca2+ pool. When the intracellular free Ca2+ concentration [( Ca2+]i) returned to basal level, fatty acid free bovine serum albumin (BSA) was added to remove extracellular and membrane bound ALA. This resulted in a sustained increase in [Ca2+]i in the absence of inositol phosphates' formation. This sustained increase in [Ca2+]i was insensitive to protein kinase C activation but was inhibited by Ni2+ ions. The extent of Ca2+ influx was found to be correlated to the amount of Ca2+ initially discharged from the IP3-sensitive Ca2+ pool by sub-optimal concentrations of ALA. Ligation of the CD3 complex of the T cell antigen receptor with an anti-CD3 antibody (OKT3) during the sustained [Ca2+]i increased (induced by a sub-optimal concentration of ALA), produced a greater response. No increase in the sustained response was observed when the CD3 complex was activated in cells pretreated with an optimal concentration of ALA. In summary, Ca2+ entry in T cells is activated by emptying of the IP3-sensitive Ca2+ pool which can be dissociated from inositol phosphate production. The rate of Ca2+ influx appears to be closely correlated to the initial discharge of Ca2+ from the IP3-sensitive Ca2+ pool, suggesting that Ca2+ may first enter the depleted pool and then is released into the cytosol.     

Enhancement of T helper2 response in the absence of interleukin (IL-)6; an inhibition of IL-4-mediated T helper2 cell differentiation by IL-6

Functional roles of interleukin (IL-)6 in T cell response were investigated. Mice deficient in IL-6 and wild mice were immunized with antigens (myelin oligodendrocyte glycoprotein or methylated BSA) and production of IL-4 and interferon (IFN)-gamma by regional lymph nodes was measured. IL-6 deficiency led to an enhancement of IL-4 and an inhibition of IFN-gamma production. Moreover, polyclonal stimulation of spleen T cells from unimmunized IL-6-deficient mice with anti-CD3 plus anti-CD28 antibodies (Abs) demonstrated an enhancement of T helper (Th)(2)responses. The presence of IL-6, however, augmented IL-4 production but it inhibited IFN-gamma expression by spleen T cells in response to polyclonal stimulation and by antigen-primed spleen T cells in response to re-challenge with the antigen. In contrast, the induction of spleen CD4-positive T cells into Th(2)cells in vitro by the anti-CD3 plus IL-4 was completely suppressed by exogenously added IL-6, whereas Th(1)differentiation of T cells by the anti-CD3 plus IL-12 was not inhibited by the presence of IL-6. Thus, these results indicate that IL-6 physiologically could modulate qualitative T cell response and suggest that it augments Th(1)responses partly through its inhibitory capability of IL-4-induced Th(2)differentiation of naive T cells.     

Calcium fluxes in T lymphocytes.

Mechanisms controlling Ca2+ fluxes through the plasma membrane of lymphocytes have been characterized in a human T-cell clone and in the Jurkat T-cell line. Due to endogenous buffers, about 1/125 of the Ca2+ ions that enter the cell are free. Ca2+ fluxes were estimated from the variations in intracellular Ca2+ concentration ([Ca2+]i) elicited by concentration jumps in extracellular Ca2+ ([Ca2+]o). Thapsigargin was used to inhibit Ca2+ uptake into intracellular stores and to stimulate Ca2+ entry. Ca2+ extrusion was strictly due to the activity of plasma membrane Ca(2+)-ATPases since there was no detectable Na+/Ca2+ exchange activity in these cells. The rate of Ca2+ extrusion was mainly influenced by [Ca2+]i and less by [Ca2+]o but was insensitive to cell depolarization. In depolarized cells, thapsigargin-induced Ca2+ influx was reduced to 10% of the value measured in normally polarized cells, suggesting that depolarization not only reduces the electrochemical gradient for Ca2+ ions, but also inhibits Ca2+ permeation. When Ca2+ ions enter the cell, they bind to a site inside the channel, with a Kd of 3.3 mM. Stimulation of clonal T-cells with low concentrations of either anti-CD3 antibodies or thapsigargin elicited Ca2+ oscillations. Both the amplitude and the frequency of CD3-induced Ca2+ oscillations were sensitive to [Ca2+]o. These oscillations were immediately interrupted when extracellular Ca2+ was removed. The properties of Ca2+ oscillations in T lymphocytes suggest that they are mainly due to variations of Ca2+ influx, modulated by variations in [Ca2+]i.     

Imaging early steps of human T cell activation by antigen-presenting cells.

In this work the Ca2+ response and the morphological changes elicited by Ag in human CD4+ T cells are described at the single cell level. The APC used to present the diphtheria toxoid Ag to a human diphtheria toxoid-specific T cell clone were murine L cell fibroblast transfectants expressing MHC class II molecules. The increase of the intracellular Ca2+ concentration, [Ca2+]i, which is one of the earliest steps of the response to TCR stimulation, was followed by fluorimetry with fura-2 on an imaging system. This response was a specific consequence of successful Ag presentation, because it only took place when fibroblasts expressed both class II MHC molecules and Ag. CD4 molecules were also involved in this intercellular interaction, because the Ca2+ response could be inhibited by preincubating the T cells with an anti-CD4 antibody. The response induced by APC started after a delay of at least 6 min, after which large Ca2+ oscillations took place, with a pseudo period of 100 s at 35 degrees C. The frequency of these oscillations decreased with temperature. The oscillations became progressively more damped during the first 30 to 40 min of cell-to-cell interaction, after which they completely stopped; however, [Ca2+]i remained well above its resting level for more than 1 h after the contact. The Ca2+ oscillations were entirely dependent on Ca2+ influx because they immediately disappeared when external calcium was removed. Similar oscillations were observed when the cells were stimulated with an anti-CD3 antibody. After stimulation with APC, many T cells abandoned their spherical shape and tended to flatten and elongate. This aspect of the T cell response was not observed after stimulation with an anti-CD3 antibody. In the presence of cytochalasin B, the morphologic changes elicited by the APC were blocked, whereas the Ca2+ response was slightly enhanced. However, when T cells were loaded with the Ca2+ chelator BAPTA, both Ca2+ and morphologic changes were inhibited, suggesting that the Ca2+ response plays a permissive role for the morphologic changes.