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.     

T-cell stimulation through the T-cell receptor/CD3 complex regulates CD2 lateral mobility by a calcium/calmodulin-dependent mechanism

T lymphocyte activation through the T cell receptor (TCR)/CD3 complex alters the avidity of the cell surface adhesion receptor CD2 for its ligand CD58. Based on the observations that activation-associated increases in intracellular [Ca2+] ([Ca2+]i) strengthen interactions between T cells and antigen-presenting cells, and that the lateral mobility of cell surface adhesion receptors is an important regulator of cellular adhesion strength, we postulated that [Ca2+]i controls CD2 lateral mobility at the T cell surface. Human Jurkat T leukemia cells were stimulated by antibody-mediated cross-linking of the TCR/CD3 complex. CD2 was labeled with a fluorescently conjugated monoclonal antibody. Quantitative fluorescence microscopy techniques were used to measure [Ca2+]i and CD2 lateral mobility. Cross-linking of the TCR/CD3 complex caused an immediate increase in [Ca2+]i and, 10-20 min later, a decrease in the fractional mobility of CD2 from the control value of 68 +/- 1% to 45 +/- 2% (mean +/- SEM). One to two hours after cell stimulation the fractional mobility spontaneously returned to the control level. Under these and other treatment conditions, the fraction of cells with significantly elevated [Ca2+]i was highly correlated with the fraction of cells manifesting significantly reduced CD2 mobility. Pretreatment of cells with a calmodulin inhibitor or a calmodulin-dependent kinase inhibitor prevented Ca2+-mediated CD2 immobilization, and pretreatment of cells with a calcineurin phosphatase inhibitor prevented the spontaneous reversal of CD2 immobilization. These data suggest that T cell activation through the TCR/CD3 complex controls CD2 lateral mobility by a Ca2+/calmodulin-dependent mechanism, and that this mechanism may involve regulated phosphorylation and dephosphorylation of CD2 or a closely associated protein.     

CD8alpha+ and CD11b+ dendritic cell-restricted MHC class II controls Th1 CD4+ T cell immunity

The activation, proliferation, differentiation, and trafficking of CD4 T cells is central to the development of type I immune responses. MHC class II (MHCII)-bearing dendritic cells (DCs) initiate CD4(+) T cell priming, but the relative contributions of other MHCII(+) APCs to the complete Th1 immune response is less clear. To address this question, we examined Th1 immunity in a mouse model in which I-A(beta)(b) expression was targeted specifically to the DCs of I-A(beta)b-/- mice. MHCII expression is reconstituted in CD11b(+) and CD8alpha(+) DCs, but other DC subtypes, macrophages, B cells, and parenchymal cells lack of expression of the I-A(beta)(b) chain. Presentation of both peptide and protein Ags by these DC subsets is sufficient for Th1 differentiation of Ag-specific CD4(+) T cells in vivo. Thus, Ag-specific CD4(+) T cells are primed to produce Th1 cytokines IL-2 and IFN-gamma. Additionally, proliferation, migration out of lymphoid organs, and the number of effector CD4(+) T cells are appropriately regulated. However, class II-negative B cells cannot receive help and Ag-specific IgG is not produced, confirming the critical MHCII requirement at this stage. These findings indicate that DCs are not only key initiators of the primary response, but provide all of the necessary cognate interactions to control CD4(+) T cell fate during the primary immune response.     

Regulatory role of CD4/L3T4 molecules in IL-2 production by affecting intracellular Ca2+ concentration of T cell clone stimulated with soluble anti-CD3

To elucidate the role of CD4 molecule in T cell activation, the effect of anti-CD4 on T cell IL-2 production was examined by using an alloreactive Th clone. The alloreactive T cell used in the present experiments produced IL-2 in response to soluble anti-CD3 epsilon-chain (anti-CD3) without accessory cell or insoluble antibody carrier. The IL-2 production was suppressed by the addition of anti-CD4 in cultures. An intracellular free Ca2+ concentration ([Ca2+]i) of the T cell clone was elevated by anti-CD3 stimulation, but the elevation was suppressed in the presence of anti-CD4. When the clone was stimulated in Ca2(+)-free medium, the elevation of [Ca2+]i was not observed. When Ca2+ influx was induced by calcium ionophore A23187 or ionomycin, the clone produced IL-2 in response to anti-CD3 in the presence of anti-CD4. When polyclonal T cell line or several other alloreactive T cell clones were examined for their anti-CD3 response, essentially the same results as mentioned above were obtained. Taken together, these results suggest that the slow and sustained elevation of [Ca2+]i is an essential signal for IL-2 production of T cells, and that anti-CD4 suppresses the IL-2 production by interfering the [Ca2+]i elevation. The significance of CD4 molecules in murine T cell activation was discussed.     

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.     

Kinetics of MHC-antigen complex formation on antigen-presenting cells

With the use of flow cytometry, we recorded changes in intracellular ionized calcium [Ca2+]i of Indo-1 loaded T cells that were triggered by contact with APC. This rapid readout of TCR perturbation enabled us to monitor the formation of stimulatory Ag-MHC complexes on EBV-transformed B cells that were either pulsed with native tetanus toxoid (TT) or with a 12-amino-acid fragment of this protein. Neither unpulsed APC nor Ag-specific APC that were pulsed with native Ag and kept at +4 degrees C were able to induce changes in basal T cell [Ca2+]i in TT-specific T cell clones. After 1 h at 37 degrees C, however, the Ag-pulsed APC were able to induce a three-to-fourfold increase in [Ca2+]i. This length of time appeared to be almost independent of the concentration of Ag with which the APC were pulsed, suggesting that the lag time was due more to intracellular transit than to association of the processed Ag with the MHC molecule. Furthermore, the same lag time and independence of Ag concentration were found when the EBV-transformed B cells were pulsed with a mouse-anti-transferrin receptor mAb and tested for their capacity to trigger a T cell clone specific for processed mouse Ig. This indicates that, in addition to surface Ig, other receptors that are internalized can function in the same fashion in the uptake and processing of a soluble Ag. In contrast to what was found with intact native Ag, no lag time was observed when the APC were pulsed with high concentrations of a 12-amino-acid peptide, containing the amino acid sequence recognized by a TT-specific T cell clone, suggesting that the formation of MHC-peptide complexes occurs instantly. Pulsing with a lower peptide concentration, however, caused the appearance of a time-dependent increase in efficacy of Ag presentation, suggesting a slow accumulation of MHC-peptide complexes on the B cell membrane.     

Activation of human B cells. Comparison of the signal transduced by IL-4 to four different competence signals

The effects of the cytokine IL-4 on resting and activated human B cells were compared with the effects of known "competence" signals able to drive resting B cells into the cell cycle, including anti-Ig, PMA, anti-CD20, and a recently described competence signal, anti-Bgp95. In proliferation assays, IL-4 was costimulatory with anti-Ig and anti-Bgp95 but not with anti-CD20 or PMA. IL-4 alone triggered increases in expression of class II DR/DQ and CD40, but it did not trigger increases in intracellular free calcium [Ca2+]i in resting B cells or induce resting B cells to leave G0 and enter the G1 phase of the cell cycle. Although IL-4 has some characteristics of competence signals, it was most effective if added to B cells up to 12 h after anti-Ig or anti-Bgp95 rather than before, and thus, in this respect, works more like a progression signal. Like IL-4, all four competence signals for B cells triggered increases in class II and CD40, but only IL-4 consistently induced increases in CD23 surface levels. IL-4 was costimulatory only with anti-Ig and anti-Bgp95, each of which can trigger increases in [Ca2+]i and new protein synthesis of the proto-oncogene c-myc, and can increase attachment of protein kinase C to the plasma membrane. IL-4 was not costimulatory with signals that 1) did not affect [Ca2+]i yet induced c-myc protein synthesis (anti-CD20), 2) only stimulated the translocation of protein kinase C (PMA), or 3) only stimulated increases in [Ca2+]i (calcium ionophore). These results suggest that resting human B cells require at least two intracytoplasmic signals before IL-4 can effectively promote B cell proliferation.     

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.     

Defective signal transduction in CD4-CD8- T cells of lpr mice

Mice homozygous for the lpr gene develop a lymphoproliferative disorder due to expansion of a subset of CD4-CD8- T cells. Triggering of the T-cell receptor in these lpr T cells does not lead to translocation of protein kinase C or phosphorylation of CD3, interleukin-2 production, or proliferation, whereas a combination of phorbol ester and calcium ionophore does. Stimulation with concanavalin A or anti-CD3 induces phosphoinositide hydrolysis. The rise in inositol bisphosphate, inositol triphosphate, and inositol tetrakisphosphate, identified by HPLC, is similar in +/+ and lpr T cells. The concentration of cytoplasmic free calcium ([Ca2+]i), however, under basal and stimulated conditions is significantly lower in lpr T cells. The lower basal [Ca2+]i may explain why induction of proliferation with phorbol ester and calcium ionophore requires a higher concentration of ionophore in these cells than in normal T cells. The lower [Ca2+]i obtained on stimulation may contribute to the activation defect of CD4-CD8- lpr T cells.     

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.     

Mechanism of peripheral T cell activation by coengagement of CD44 and CD2.

A number of CD44 antibodies are known to augment peripheral T cell proliferation stimulated with suboptimal concentrations of activating pairs of CD2 mAb. These findings have implicated the CD44 adhesion receptor in the activation of peripheral T cells via CD2. We have investigated early events after CD44 and CD2 coengagement on peripheral T cells. CD44 and CD2 coengagement resulted in enhanced [Ca2+]i mobilization. However, the increase in [Ca2+]i mobilization did not occur until at least 3 min after CD2 and CD44 coengagement, suggesting that other events precede the elevation in [Ca2+]i. Using a T cell/fibroblast adhesion assay, we could demonstrate a dramatic increase in T cell adhesiveness after about 1 min after CD44 and CD2 coengagement. The increase in T cell adhesiveness was comparable to that induced by PMA. In the absence of antibodies or treatment with mAb directed to other T cell surface Ag, there was little if any adhesion between unstimulated peripheral T cells and fibroblasts. Enhancement of T cell adhesiveness through CD44 engagement was not mediated by a direct effect on lymphocyte-function associated Ag-3, the known ligand of CD2. However, cross-linking of CD44 resulted in epitopic modulation of CD2 as demonstrated by the increased expression of the T11(3) activation epitope. Furthermore, anti-CD44 could substitute for anti-T11(2) in the activation of peripheral T cells via CD2. These results suggest that CD44 ligation has profound effects on CD2-mediated events by inducing epitopic modulation of CD2.     

Unexpected reactivities of T cells selected by a single MHC-peptide ligand.

In H2-DM mutant mice, most MHC class II molecules are bound by a single peptide, CLIP, derived from the class II-associated invariant chain. Previous studies showed that H2-DM- cells are defective in presenting synthetic peptides to class II-restricted T cells. In sharp contrast, however, the same peptides elicited strong CD4+ T cell responses in H2-DM- animals. We now provide an explanation for this apparent discrepancy. Peptide-specific CD4+ T cells from wild-type mice were efficiently stimulated by H2-DM+, but not by H2-DM- cells pulsed with the cognate peptide. In sharp contrast, CD4+ T cells from mutant animals specific for the same MHC-peptide combination recognized peptide-pulsed H2-DM+ and H2-DM- cells equally well. In addition, unlike Ag-specific T cells from wild-type animals, the reactivities of peptide-specific T cells from mutant animals could not be efficiently blocked by Abs specific for the cognate MHC class II-peptide combination. We further demonstrated that the distinct reactivities of CD4+ T cells from H2-DM+ and H2-DM- mice are due to differences in thymic selection. Collectively, these findings indicate that the CD4+ T cell repertoires of H2-DM+ and H2-DM- mice are remarkably different.     

Simultaneous measurements of cytosolic calcium and secretion in single bovine adrenal chromaffin cells by fluorescent imaging of fura-2 in cocultured cells

The cytosolic free calcium concentration ([Ca2+]i) and exocytosis of chromaffin granules were measured simultaneously from single, intact bovine adrenal chromaffin cells using a novel technique involving fluorescent imaging of cocultured cells. Chromaffin cell [Ca2+]i was monitored with fura-2. To simultaneously follow catecholamine secretion, the cells were cocultured with fura-2-loaded NIH-3T3t cells, a cell line chosen because of their irresponsiveness to chromaffin cell secretagogues but their large Ca2+ response to ATP, which is coreleased with catecholamine from the chromaffin cells. In response to the depolarizing stimulus nicotine (a potent secretagogue), chromaffin cell [Ca2+]i increased rapidly. At the peak of the response, [Ca2+]i was evenly distributed throughout the cell. This elevation in [Ca2+]i was followed by a secretory response which originated from the entire surface of the cell. In response to the inositol 1,4,5-trisphosphate (InsP3)-mobilizing agonist angiotensin II (a weak secretagogue), three different responses were observed. Approximately 30% of chromaffin cells showed no rise in [Ca2+]i and did not secrete. About 45% of the cells responded with a large (greater than 200 nM), transient elevation in [Ca2+]i and no detectable secretory response. The rise in [Ca2+]i was nonuniform, such that peak [Ca2+]i was often recorded only in one pole of the cell. And finally, approximately 25% of cells responded with a similar Ca2+-transient to that described above, but also gave a secretory response. In these cases secretion was polarized, being confined to the pole of the cell in which the rise in [Ca2+]i was greatest.(ABSTRACT TRUNCATED AT 250 WORDS)     

Induction of MHC class I presentation of exogenous antigen by dendritic cells is controlled by CD4+ T cells engaging class II molecules in cholesterol-rich domains.

We investigated interactions between CD4+ T cells and dendritic cells (DC) necessary for presentation of exogenous Ag by DC to CD8+ T cells. CD4+ T cells responding to their cognate Ag presented by MHC class II molecules of DC were necessary for induction of CD8+ T cell responses to MHC class I-associated Ag, but their ability to do so depended on the manner in which class II-peptide complexes were formed. DC derived from short-term mouse bone marrow culture efficiently took up Ag encapsulated in IgG FcR-targeted liposomes and stimulated CD4+ T cell responses to Ag-derived peptides associated with class II molecules. This CD4+ T cell-DC interaction resulted in expression by the DC of complexes of class I molecules and peptides from the Ag delivered in liposomes and permitted expression of the activation marker CD69 and cytotoxic responses by naive CD8+ T cells. However, while free peptides in solution loaded onto DC class II molecules could stimulate IL-2 production by CD4+ T cells as efficiently as peptides derived from endocytosed Ag, they could not stimulate induction of cytotoxic responses by CD8+ T cells to Ag delivered in liposomes into the same DC. Signals requiring class II molecules loaded with endocytosed Ag, but not free peptide, were inhibited by methyl-beta-cyclodextrin, which depletes cell membrane cholesterol. CD4+ T cell signals thus require class II molecules in cholesterol-rich domains of DC for induction of CD8+ T cell responses to exogenous Ag by inducing DC to process this Ag for class I presentation.     

Incomplete activation of CD4 T cells by antigen-presenting transitional immature B cells: implications for peripheral B and T cell responsiveness

B cells leave the bone marrow as transitional B cells. Transitional B cells represent a target of negative selection and peripheral tolerance, both of which are abrogated in vitro by mediators of T cell help. In vitro, transitional and mature B cells differ in their responses to B cell receptor ligation. Whereas mature B cells up-regulate the T cell costimulatory molecule CD86 (B7.2) and are activated, transitional B cells do not and undergo apoptosis. The ability of transitional B cells to process and present Ag to CD4 T cells and to elicit protective signals in the absence of CD86 up-regulation was investigated. We report that transitional B cells can process and present Ag as peptide:MHC class II complexes. However, their ability to activate T cells and elicit help signals from CD4-expressing Th cells was compromised compared with mature B cells, unless exogenous T cell costimulation was provided. A stringent requirement for CD28 costimulation was not evident in interactions between transitional B cells and preactivated CD4-expressing T cells, indicating that T cells involved in vivo in an ongoing immune response might rescue Ag-specific transitional B cells from negative selection. These data suggest that during an immune response, immature B cells may be able to sustain the responses of preactivated CD4(+) T cells, while being unable to initiate activation of naive T cells. Furthermore, the ability of preactivated, but not naive T cells to provide survival signals to B cell receptor-engaged transitional immature B cells argues that these B cells may be directed toward activation rather than negative selection when encountering Ag in the context of a pre-existing immune response.     

Direct human T helper cell-induced B cell activation is not mediated by inositol lipid hydrolysis

The Ag-specific interaction between cloned allospecific human Th cells and class II MHC determinants on the surface of allogeneic B cells induces a significant fraction of resting B cells to express a B cell specific activation Ag BLAST-2 (CD23). On the other hand, cross-linking of B cell surface Ig R by Ag analogues does not lead to BLAST-2 expression. By utilizing the BLAST-2 induction assay as a positive control for efficient Th-B cell interaction, we have investigated the biochemical basis of human B cell activation mediated by Ag and Th cells. Our data demonstrate that ligands for sIg R, including F(ab')2 goat anti-human IgM and Staphylococcus aureus protein A, stimulate the metabolism of B cell membrane inositol lipids as assessed by: 1) increased [3H]inositol phosphates formation in myo-[3H]inositol-labeled B cells; 2) selective incorporation of [32P]orthophosphate into phosphatidic acid and phosphatidylinositol, but not into phosphatidylethanolamine or phosphatidylcholine; and 3) rapid increase in B cell cytoplasmic ionized Ca2+ concentration ([Ca2+]i). In contrast, direct Th-B cell interaction leads to high intensity BLAST-2 expression on the B cell surface but this response is not mediated by changes in inositol lipid metabolism or [Ca2+]i. Further, Th-B cell interaction does not affect the changes in B cell inositol lipid metabolism or [Ca2+]i triggered by sIg cross-linking. Taken together, our results suggest that Ag and Th cells induce different functional B cell responses by activating distinct second messenger systems within the B cell.     

Exposure of a Distinct PDCA-1+ (CD317) B Cell Population to Agonistic Anti-4-1BB (CD137) Inhibits T and B Cell Responses Both In Vitro and In Vivo

4-1BB (CD137) is an important T cell activating molecule. Here we report that it also promotes development of a distinct B cell subpopulation co-expressing PDCA-1. 4-1BB is expressed constitutively, and its expression is increased when PDCA-1⁺ B cells are activated. We found that despite a high level of surface expression of 4-1BB on PDCA-1⁺ B cells, treatment of these cells with agonistic anti-4-1BB mAb stimulated the expression of only a few activation markers (B7-2, MHC II, PD-L2), cytokines (IL-12p40/p70), and chemokines (MCP-1, RANTES), as well as sTNFR1, and the immunosuppressive enzyme, IDO. Although the PDCA-1⁺ B cells stimulated by anti-4-1BB expressed MHC II at high levels and took up antigens efficiently, Ig class switching was inhibited when they were pulsed with T-independent (TI) or T-dependent (TD) Ags and adoptively transferred into syngeneic recipients. Furthermore, when anti-4-1BB-treated PDCA-1⁺ B cells were pulsed with OVA peptide and combined with Vα2⁺CD4⁺ T cells, Ag-specific cell division was inhibited both in vitro and in vivo. Our findings suggest that the 4-1BB signal transforms PDCA-1⁺ B cells into propagators of negative immune regulation, and establish an important role for 4-1BB in PDCA-1⁺ B cell development and function.     

Recognition of the self idiotype by T cells: induction of a rapid increase in cytoplasmic free calcium in T cells recognizing a variable L chain determinant.

To investigate the initial stages of recognition of the self idiotype (Id) by T cells, we examined the early increase in cytoplasmic free calcium ([Ca2+]i) occurring in murine CD4+ T cells specific for a model Id, Id315, following their interaction with the Id. The changes in [Ca2+]i were monitored with stopped-flow fluorometry by loading T cells with fura 2, a Ca(2+)-binding fluorescent dye. An increase of [Ca2+]i in the Id-specific T cell line was dependent on the presence of both antigen-presenting cells (APC) and Id315. When T cells were mixed with APC pulsed with M315 for 90 min at 37 C, a significant increase in T cell [Ca2+]i was observed within one second. A pronounced elevation in [Ca2+]i was also observed in T cells after their interaction with APC which had been pulsed for 90 min with VL-315 Id-containing proteins (such as VL-315, L315, Fv-315 or Fab'-315 fragments). In contrast, pulsing APC for 5 min with the VL fragment produced little or no change in the [Ca2+]i. These results suggest that VL must be further processed by APC before it can be recognized by T cells. Indeed, a synthetic VL region peptide (positions 91-108, designated as P18) produced an elevation in T cell [Ca2+]i when mixed with APC without pulsing.     

Prostaglandins enhance parathyroid hormone-evoked increase in free cytosolic calcium concentration in osteoblast-like cells.

Prostaglandins (PGs) are autocrine or paracrine hormones that may interact with circulating hormones such as parathyroid hormone (PTH) in bone. We examined the interaction of the PGs, PGF2 alpha, PGE2, and 6-keto-PGF1 alpha with PTH to enhance the rapid, initial transient rise in free cytosolic calcium ([Ca2+]i) and cAMP levels stimulated by PTH. Pretreatment of UMR-106, MC3T3-E1, and neonatal rat calvarial osteoblast-like cells by PGs resulted in an enhancement of the early transient rise in [Ca2+]i stimulated by PTH. PGF2 alpha was approximately 100 times more potent than PGE2. PGE2 itself was more potent than 6-keto-PGF1 alpha in enhancing PTH-stimulated rise in [Ca2+]i. Near-maximal augmentation was achieved at PGF2 alpha doses of 10 nM and PGE2 of 1 microM. The degree of augmentation in [Ca2+]i by PGF2 alpha was independent of preincubation time. PGF2 alpha pretreatment did not alter the EC50 for the PTH-induced [Ca2+]i increase but only the extent of rise in [Ca2+]i at each dose of PTH. The augmented increase in [Ca2+]i was mostly due to enhanced PTH-mediated release of Ca2+ from intracellular stores. PGF2 alpha did not stimulate an increase in PTH receptor number as assessed by [125I]-PTH-related peptide binding. PG pretreatment partially reversed PTH inhibition of cell proliferation, suggesting that an increase in [Ca2+]i may play a role in tempering the anti-proliferative effect of PTH mediated by cAMP. These studies suggest a new mode by which PGs can affect cellular activity.     

CD5 antibodies increase intracellular ionized calcium concentration in T cells

The binding of a variety of monoclonal antibodies to the CD5 (T, gp67) pan T cell differentiation antigen has been shown to potentiate T cell proliferation. In this paper we show that CD5 monoclonal antibodies cause increased intracellular free calcium concentration ([Ca2+]i) in T cells. An increase in [Ca2+]i occurred within 1 min in indo-1-loaded PBMC after the addition of CD5 monoclonal antibodies and cross-linking with a second step anti-mouse kappa light chain antibody. Cross-linking of CD5 was effective when done directly on the cell surface or by the administration of preformed soluble complexes that contained CD5 antibodies. Calcium mobilization induced by suboptimal concentrations of CD3 antibodies was specifically augmented and sustained by CD5 antibodies, although the enhancement was modest in magnitude. When cell surface phenotype was correlated with calcium mobilization, it was found that the CD5 response was restricted to CD5+/CD3+ cells, and that approximately 90% of CD5+ cells had responded. CD5-induced calcium mobilization was found to differ from CD3 stimulation in that EGTA entirely ablated the CD5 response, whereas the CD3 response was resistant to EGTA, indicating that the CD5-induced increased [Ca2+]i is derived primarily or entirely from extracellular calcium. CD5-stimulated calcium mobilization also differed from CD3 in that the CD5 response was inhibited by pretreatment with phorbol myristate acetate, whereas the CD3 response was not, suggesting that depletion of protein kinase C causes an uncoupling of signal transduction between CD5 and calcium channels. Finally, experiments were done with T cells after antigenic modulation of the CD3 or CD5 molecules. Unexpectedly, both the CD5 and the CD3 responses were ablated on CD3-modulated cells, whereas only the CD5 response was ablated on CD5-modulated cells. In addition, several Cd5+/CD3- T cell leukemia lines also failed to respond to CD5 stimulation, providing further evidence which indicates that the CD5 response depends on the cell surface expression of CD3 or a CD3-associated structure. These findings suggest that one mechanism for CD5-induced augmentation of mitogen-stimulated T cell proliferation involves increased [Ca2+]i which is distinct from but interdependent with that induced by stimulation of the CD3 molecule.