Increased phosphatidylinositol metabolism is an important but not an obligatory early event in B lymphocyte activation

The phosphatidylinositol (PI) response has been implicated in membrane signaling and cell activation. The role of phospholipid metabolism among the early events in B cell activation has not been clear. We have treated murine B cells with anti-Ig antibody and lipopolysaccharide (LPS) and have found that, although anti-IgM induces the PI response, LPS does not. The increase in metabolic labeling of PI is specific to PI, and not the phosphatidylinositols. Anti-IgM unresponsive B cells from CBA/N mice, which may correspond to a specific functional subpopulation of normal B cells, do not increase PI metabolism in response to anti-IgM, nor do they undergo blastogenesis or DNA synthesis. Moreover, when these deficient B cells are given a stimulus sufficient to drive them into S (LPS + anti-IgM), there is still no corresponding activation of PI metabolism. These results are consistent with a two-signal model of xid B cell activation by anti-IgM. One very early signal primes the cells but does not induce the PI response. A second early signal is supplied by LPS. This signal sustains cells in the activated state, allowing them to receive yet other signals to proceed through G1 and progress further along the cell cycle. A similar sequence of events may occur in the normal B cell, with the first signal provided by priming with anti-IgM, and the second signal, the PI response, supported by a sufficiently high dose of anti-IgM to induce PI turnover and maintain the cell in G1.     

Splenic B cells and antigen-specific B cells process anti-Ig in a similar manner

B lymphocytes can process and present antigen to T cells. However, the fate of native antigen after its binding to specific B cells, i.e., the intracellular events involved in the processing and recycling of the antigenic fragments to the cell surface for antigen presentation, are not well understood. In the present study, we demonstrate that murine B cells degrade anti-Ig molecules bound to their surface and release acid soluble fragments into the supernatant. We also demonstrate that the kinetics of this process are identical for anti-mu, anti-delta, and anti-light chain antibodies, indicating that both surface IgM and surface IgD are equally effective in binding antigen and directing its processing. We also describe the effects of azide, chloroquine, and irradiation on this process. To extend these studies to the processing of specifically bound antigen, we demonstrate that highly purified trinitrophenyl antigen-binding cells degrade anti-Ig molecules with the same kinetics as unpurified splenic B cells. Thus, this purified population provides a suitable model system for the analysis of antigen degradation by antigen-specific cells.     

B cell activation. VIII. Membrane immunoglobulins transduce signals via activation of phosphatidylinositol hydrolysis

Considerable evidence indicates that cross-linking of B cell surface Ig results in a "first signal" in B cell activation. We have shown that transduction of this signal is manifest by changes in plasma membrane potential leading to increased expression of surface I-A antigen. In previous studies, we have provided evidence that suggests that this signal is transduced via phosphatidylinositol (PI) hydrolysis liberating diacylglycerol (DAG), which subsequently activates protein kinase C. These biochemical events are aspects of a transmembrane signal transduction mechanism that is common in nature and utilizes the PI metabolic cycle for generation of "second messenger" diacylglycerol. Here we report direct evidence that treatment of B cells with various antibodies to surface Ig results in activation of the PI cycle. Results suggest that the increased phospholipid metabolism that occurs in B cells in response to anti-Ig involves only those phospholipids in the PI cycle and is a consequence of turnover of existing lipid rather than de novo synthesis. Furthermore, we show that PI cycle activation requires cross-linking of membrane Ig and is inhibitable by increased intracellular cyclic AMP. These findings are particularly important in view of previous studies that have shown identical requirements for and inhibitability of induction of B cell membrane depolarization and increased I-A expression. Thus, these results are consistent with our previous hypothesis that early B cell activation events initiated by receptor Ig occupancy are mediated via PI hydrolysis, diacylglycerol generation, and protein kinase C activation.     

Cross-linkage of Ly-6A/E induces Ca2+ translocation in the absence of phosphatidylinositol turnover and mediates proliferation of normal murine B lymphocytes

Ly-6A/E is a phosphatidylinositol (PI)-linked membrane protein whose expression is induced or upregulated on normal murine T and B cells by IFN-gamma. Cross-linkage of Ly-6A/E expressed on normal murine T cells stimulates Ca2+ translocation, and in the presence of a protein kinase C (PKC) activator, lymphokine secretion, and cellular proliferation. Utilizing an anti-Ly-6A/E mAb, we studied the effect of cross-linking Ly-6A/E on IFN-gamma-treated resting B cells, for Ca2+ translocation, PI turnover, and cellular proliferation. Since these events are known to be stimulated by cross-linkage of B cell membrane (m)Ig, we compared the changes mediated through these respective membrane proteins. We show that cross-linkage of B cell Ly-6A/E stimulates a large, rapid, and sustained increase in the concentration of intracellular free calcium ([Ca2+]i) comparable in magnitude, though somewhat delayed, relative to that observed after cross-linking of mIg. Cross-linkage of B cell Ly-6A/E does not, however, stimulate detectable PI turnover, in contrast to PI turnover induced by ligation of mIg. Both the Ly-6A/E- and mIg-mediated increase in [Ca2+]i occur through mobilization of internal Ca2+ stores as well as entry of Ca2+ into the cell from the extracellular compartment. Ly-6A/E-mediated Ca2+ translocation appears to be under the regulation of PKC in that short term pretreatment of B cells with the PKC activator, PMA, inhibits the Ly-6A/E- as well as the mIg-mediated increase in [Ca2+]i, whereas prolonged exposure to PMA, under conditions that lead to depletion of PKC, results in an augmentation in Ca2+ translocation after ligation of either Ly-6A/E or mIg. Co-capping studies indicate that Ly-6A/E and mIg cap independently in the B cell membrane, thus suggesting that the Ly-6A/E-induced effects on Ca2+ translocation are not mediated through simultaneous modulation of mIg. Anti-Ly6A/E, by itself, does not stimulate an increase in [3H]thymidine incorporation by IFN-gamma-treated resting B cells, but induces a striking increase in the presence of PMA. By contrast, anti-Ig by itself stimulates significant increases in [3H]thymidine incorporation that is inhibited by PMA. Thus, Ly-6A/E is a potent mediator of B cell activation that may use a signal transduction system in quiescent B cells that is distinct from that of the Ag receptor.     

Role of the CD22 human B cell antigen in B cell triggering by anti-immunoglobulin

As B cells mature during ontogeny the CD22 human differentiation Ag is exported from the cytoplasm onto the membrane. Surface expression is lost in terminal differentiation and after activation. In tonsils, CD22 is expressed on the surface of 60 to 80% of the dense B cells. Some IgM+ dense cells, however, and buoyant in vivo activated B cells are CD22-. This differential expression of CD22 and the finding that an anti-CD22 mAb augmented anti-Ig induced B cell proliferation suggested that CD22 may play a role in B cell activation. In this study we have found that CD22+ but not CD22- B cells could be triggered by anti-IgM or anti-IgD to have increased free intracellular calcium ([Ca2+]i). The presence of CD22 rather than of IgD seems to determine the ability of B cells to respond to anti-Ig with a [Ca2+]i flux. Also the proliferative response to anti-Ig or anti-Ig + B cell growth factor was restricted to the CD22+ population. Anti-CD22 mAb, although not inducing [Ca2+]i on their own after binding to B cells, did augment [Ca2+]i fluxes by anti-Ig when cross-linked. Together these results suggest that CD22 may regulate triggering of B cells through surface Ig perhaps by acting as a "bridge" to transmit an early signal into the cytoplasm.     

Regulation of B-lymphocyte activation, proliferation, and immunoglobulin secretion

Lymphocyte growth and differentiation are controlled by signals resulting from the interaction of antigen and cellular products, such as lymphokines, with specific cell membrane receptors. Resting B lymphocytes can be activated by low concentrations (1-5 micrograms/ml) of antibodies to membrane IgM, which is the B-lymphocyte receptor for antigen. The binding of anti-IgM to B cells causes a rapid increase in intracellular free calcium concentration ([Ca2+]i), in inositol phosphate concentration, and in protein kinase activity. Moreover, the effects of anti-IgM on B cells are mimicked by the combined use of calcium ionophores and phorbol esters. Since phorbol esters activate protein kinase c, this suggests that the increase in [Ca2+]i and in phosphatidylinositol metabolism stimulated by anti-IgM are critical events in B-cell activation. The entry into S phase of B cells stimulated with anti-IgM depends on the action of a T-cell-derived factor designated B-cell stimulatory factor (BSF)-1. This is a 20,000-Da protein which is a powerful inducer of class II major histocompatibility complex molecules. Although an important cofactor for B-cell proliferative responses to anti-IgM, its major locus of action is on resting B cells. B cells stimulated with anti-IgM and BSF-1 do not synthesize secretory IgM. However, if two additional T-cell-derived factors, B151-TRF and interleukin-2, are added to cultures, a substantial proportion of stimulated B cells produce secretory IgM. BSF-1 has also been shown to participate in the "switch" in Ig class expression. Resting B cells cultured with lipopolysaccharide will switch to IgG1 secretion in the presence of purified BSF-1.     

Tyrosine kinase-dependent phosphatidylinostiol turnover and functional responses in the Fc epsilon R1 signalling pathway.

In RBL-2H3 rat basophilic leukemia cells, Fc epsilon R1 crosslinking by multivalent antigen stimulates phosphatidylinositol (PI) turnover and Ca2+ influx and causes functional responses that include secretion, membrane ruffling and actin polymerization. Here, we show that the tyrosine kinase inhibitor, genistein, inhibits antigen-induced PI turnover, determined from assays of 1,4,5-inositol trisphosphate production, and impairs receptor-mediated secretion, ruffling and actin polymerization. Genistein has little effect on several functional responses to stimuli that bypass PI hydrolysis (ionomycin-induced secretion, phorbol ester-induced ruffling) but it inhibits phorbol ester-induced actin polymerization. These data implicate a common tyrosine kinase-dependent event, most likely the activation of phospholipase C gamma, in the Fc epsilon R1-mediated stimulation of PI turnover, secretion and ruffling. There may be additional tyrosine kinase-mediated events in the actin assembly pathway.     

Antigen-induced changes in phospholipid metabolism in antigen-binding B lymphocytes

Previous studies have demonstrated a marked change in the metabolism of phospholipids (PL) after activation of resting B lymphocytes with anti-immunoglobulin (anti-Ig). In this study we examined PL metabolism in highly purified trinitrophenyl (TNP)-binding B cells after their activation with various forms of TNP-carrier protein. Such cells show similar changes in PL metabolism when stimulated with either antigen or anti-Ig, i.e., increased incorporation of 32PO4 into phosphatidic acid and phosphatidyl inositol (PI) but not phosphatidyl choline, phosphatidyl ethanolamine, or phosphatidyl serine. We have demonstrated that these responses to antigen are TNP-specific and dose-related between 1 and 50 micrograms/ml, producing up to a 2.5-fold stimulation of 32PO4 incorporation into PI. The PL response is also directly related to the density of TNP on the carrier and can be augmented by additional cross-linking of the carrier protein. These data suggest that cross-linking of surface Ig by antigen induces a change in PL metabolism as an early event in B cell activation.     

Early events in B-cell activation: anti-Lyb2, but not BSF-1, induces a phosphatidylinositol response in murine B cells

Previous studies have indicated that the murine surface antigen Lyb2 is involved in an activation pathway that apparently does not involve the surface immunoglobulin receptor. As sIg has been shown to transduce its activation signal through the breakdown of phosphatidylinositol (PI), and since activation via Lyb2 does not involve sIg, it was of interest to determine if binding to Lyb2 generates a PI response. We have demonstrated that an allele-specific monoclonal antibody to Lyb2 (anti-Lyb2 mab), which has previously been shown to drive B cells into S, also activated PI metabolism in these cells. This activation occurred in a dose-dependent and allele-specific manner. Antibodies to other B-cell surface molecules such as Ia did not induce a PI response. The effect of anti-Lyb2 mab was always less in magnitude than that induced by anti-IgM, but the effects of the two antibody preparations were most comparable in larger, presumptively preactivated cells. To explore the issue that Lyb2 may represent a receptor for a growth factor, possibly the early-acting B-cell growth factor BSF-1, we studied the PI response to BSF-1 and the effect of BSF-1 on Lyb2-induced PI turnover. BSF-1 neither induced a PI response nor inhibited competitively the response induced by anti-Lyb2 mab.     

Idiotype and antigen-specific T cell responses in mice on immunization with antigen, antibody, and anti-idiotypic antibody.

Idiotypic determinants of immunoglobulin molecules can evoke both CD4(+) and CD8(+) T responses and exist not only as the integral components of a bona fide antigen binding receptor but also as distinct molecular entities in the processed forms on the cell surface of B lymphocytes. The present work provides experimental evidence for the concept that regulation of memory B cell populations can be achieved through the presentation of idiotypic and anti-idiotypic determinants to helper and cytotoxic cell. The potential of B cells to present antigens to helper and cytotoxic T cells through class II and class I MHC suggests a mechanism by which both B and T cell homeostasis can be maintained. We provide evidence for the generation of idiotype- and antigen-specific Th and Tc cells upon immunization of syngenic mice with antigen or idiotypic antibody (Ab1) or anti-idiotypic antibody (Ab2). The selective activation and proliferation of the antigen-specific Th and Tc cells mediated by idiotypic stimulation observed in these experiments suggests a B-cell-driven mechanism for the maintenance of antigen-specific T cell memory in the absence of antigenic stimulation, under certain conditions.     

Phosphatidylinositol 4-phosphate 5-kinase reduces cell surface expression of the epithelial sodium channel (ENaC) in cultured collecting duct cells

Ubiquitination of ENaC subunits has been shown to negatively regulate the cell surface expression of ENaC channels. We have previously demonstrated that epsin links ubiquitinated ENaC to clathrin adaptors for clathrin-mediated endocytosis. Epsin is thought to directly modify the curvature of membranes upon binding to phosphatidylinositol 4,5-bisphosphate (PIP2) where it recruits clathrin and stimulates lattice assembly. Murine phosphatidylinositol 4-phosphate 5-kinase alpha (PI5KIalpha) has been shown to enhance endocytosis in a PIP2-dependent manner. We tested the hypothesis that PI5KIalpha-mediated PIP2 production would negatively regulate ENaC current by enhancing epsin-mediated endocytosis of the channel. Expression of PI5KIalpha decreased ENaC currents in Xenopus oocytes by 80%, entirely because of a decrease in cell surface ENaC levels. Catalytically inactive mutants of PI5Kalpha had no effect on ENaC activity. Expression of the PIP2 binding region of epsin increased ENaC current in oocytes, an effect completely reversed by co-expression of PI5KIalpha. Overexpression of epsin reduced amiloride-sensitive current in CCD cells. Overexpression of PI5KIalpha enhanced membrane PIP2 levels and reduced apical surface expression of ENaC in CCD cells, down-regulating amiloride-sensitive current. Knockdown of PI5KIalpha with isoform-specific siRNA resulted in a 4-fold enhancement of ENaC activity. PI5KIalpha localized exclusively to the apical plasma membrane domain when overexpressed in mouse CCD cells, consistent for a role in regulating PIP2 production at the apical plasma membrane. We conclude that membrane turnover events regulating ENaC surface expression and activity in oocytes and CCD cells can be regulated by PI5KIalpha.     

Novel binding site for Src homology 2-containing protein-tyrosine phosphatase-1 in CD22 activated by B lymphocyte stimulation with antigen

CD22, a B lymphocyte membrane glycoprotein, contains immunoreceptor tyrosine-based inhibition motifs (ITIMs) in the cytoplasmic region and recruits Src homology 2-containing protein-tyrosine phosphatase-1 (SHP-1) to the phosphorylated ITIMs upon ligation of B lymphocyte antigen receptor (BCR), thereby negatively regulating BCR signaling. Among the three previously identified ITIMs, both ITIMs containing tyrosine residues at position 843 (Tyr(843)) and 863 (Tyr(863)), respectively, are shown to be required for CD22 to recruit SHP-1 and regulate BCR signaling upon BCR ligation by anti-Ig antibody (Ab), indicating that CD22 has the SHP-1-binding domain at the region containing Tyr(843) and Tyr(863). Here we address the requirement of CD22 for SHP-1 recruitment and BCR regulation upon BCR ligation by antigen, which induces much stronger CD22 phosphorylation than anti-Ig Ab does. We demonstrate that the CD22 mutant in which both Tyr(843) and Tyr(863) are replaced by phenylalanine (CD22F5/6) recruits SHP-1 and regulates BCR signaling upon stimulation with antigen but not anti-Ig Ab. This result strongly suggests that CD22 contains another SHP-1 binding domain that is specifically activated upon stimulation with antigen. Both of the flanking sequences of Tyr(783) and Tyr(817) fit the consensus sequence of ITIM, and the CD22F5/6 mutant requires these tyrosine residues for SHP-1 binding and BCR regulation. Thus, these ITIMs constitute a novel conditional SHP-1-binding site of CD22 that is activated upon BCR ligation by antigen but not by anti-Ig Ab.     

Abortive activation of B lymphocytes by monoclonal anti-immunoglobulin antibodies

Toward a better understanding of the signaling role of antigen-mIg binding in the generation of humoral immune responses, we have assessed the effects of soluble, monoclonal anti-Ig antibodies on various cell physiologic parameters known to change during B cell activation. These parameters include membrane potential, I-A antigen expression, narrow angle light scattering properties (size), and cell cycle state. Results indicate that all monoclonal antibodies that bind cell to surface IgM or IgD, or both, induce virtually all small B cells to undergo membrane depolarization and increased I-A expression. Only a small subset of these antibodies, exemplified by b-7-6 anti-mu, induce all small B cells to enter G1. An increasingly smaller proportion of these cells traverse each subsequent cell cycle phase, with 10% of cells reaching G2 or M phases by 60 hr of culture. The kinetics of this response to b-7-6 are considerably slower than those of the response induced by LPS. Finally, analysis of Percoll density-fractionated cells revealed that although B blasts made by b-7-6 stimulation of small cells remain b-7-6 responsive, natural B blasts isolated from the spleen are refractory to monoclonal anti-Ig stimulation as indicated by membrane depolarization, increased IA expression, blastogenesis, and [3H]thymidine uptake.     

Establishment of an antigen-specific B cell clone by somatic hybridization

Splenic B cells of A/J mice immunized with 2,4,6-trinitrophenyl (TNP)-lipopolysaccharide were fused with 2.52M, a mutant of a B cell line, in the presence of polyethylene glycol and dimethyl sulfoxide. TP67.21, a subclone of a resulting hybridoma, expresses IAk, IEk, IgM, B220, P50, and receptors for C3 fragment of complement, the Fc portion of IgG, and interleukin 2 receptor on the cell membrane; it also possesses receptor molecules for TNP on its surface, derived from TNP-reactive B cells of A/J mice primed with TNP-lipopolysaccharide used for somatic hybridization, by a rosette-forming assay with TNP-sheep erythrocytes. In contrast, parental 2.52M lacks IAk and IEk on the cell membrane and does not bind to TNP-sheep erythrocytes under the same conditions. Thus, it is likely that TP67.21 is an antigen-specific B cell clone directed against TNP. The antigen binding of cells was markedly inhibited by the specific free hapten or anti-IgM antibodies. Interestingly, TP67.21 was induced to generate a significant amount of anti-TNP antibody when treated with TNP conjugates including T cell-independent and -dependent antigens, such as TNP-lipopolysaccharide, TNP-bovine serum albumin, TNP-ovalbumin, and TNP-keyhole limpet hemocyanine in the absence of T cell help, as well as polyclonal activators; this was followed by a marked decrease in the expression of B cell surface markers on the cell membrane. This suggests that the cross-linkage of receptor molecules on TP67.21 by antigen may directly provide a differentiative signal for maturation to a lineage of B cells, and consequently results in the generation of antigen-specific antibodies without T cell involvement.     

Complex formation of CD23/surface immunoglobulin and CD23/CD81/MHC class II on an EBV-transformed human B cell line and inferable role of tetraspanin

CD23, a low-affinity IgE receptor, is a type II transmembrane protein having a C-type lectin domain and it associates noncovalently with MHC class II on B cells. The results of our immunoprecipitation analysis suggest that CD23 co-exists with at least two additional molecules, surface immunoglobulin (sIg) and CD81 (and/or CD9), on the cell surface of L-KT9 cells (an Epstein-Barr virus (EBV)-transformed human B cell line). When both CD23 and sIg molecules were stimulated simultaneously by the corresponding antibodies, a large increase in CD81 in the immunoprecipitation was observed as compared with the case of stimulation by only one antibody. Simultaneous stimulation by anti-CD23 and anti-Ig may mimic the situation of B cells stimulated by an antigen/IgE complex. In addition, a large increase in MHC class II in the immunoprecipitation was also observed by cross-linking of CD23 with anti-CD23 and its second antibody as compared with the case of stimulation by anti-CD23 alone. The cross-linking of CD23 with anti-CD23 and its antibody may mimic the situation of B cells stimulated by an IgE/antigen/IgE complex. Therefore, the complex formation among CD23, sIg, MHC class II, and CD81 on the cell surface of L-KT9 cells by the antigen/IgE or IgE/antigen/IgE complex is most likely to be closely related to B cell regulatory events by signaling through sIg or MHC class II. Tetraspanins such as CD81 and CD9 are thought to be involved in the formation and the preservation of various different membrane complexes consisting of several functional proteins.     

Early membrane potential and cytoplasmic calcium changes during mitogenic stimulation of WEHI 231 cell line by polyene antibiotics, lipopolysaccharide and anti-immunoglobulin

Changes in free cytosolic calcium concentration and in membrane voltage are thought to be important initiating events in lymphocyte activation. The antifungal agent amphotericin B (AmB) holds interesting immunomodulating properties and its N-thiopropionyl derivative (AmBSH) is a potent polyclonal B-cell activator. These molecules may then exert their stimulating activity through the production of early ionic signals similar to those delivered by the classical activators lipopolysaccharide (LPS) and anti-immunoglobulin (anti-Ig). We addressed this question in a B-cell line (WEHI 231) which has previously been shown to exhibit characteristic response to LPS and anti-Ig. AmBSH protected these cells against anti-Ig-induced cell growth inhibition, providing a LPS-like response. In contrast, the parental compound AmB did not. The two polyene antibiotics did not modify the resting Ca2+i level of the cells, neither did LPS, whereas anti-Ig induced a rapid increase in the cytosolic calcium concentration. On the other hand, polyene antibiotics and LPS promoted membrane depolarization, whereas membrane voltage remained unchanged after anti-Ig treatment. Polyene antibiotics-induced depolarization originated from the increase of membrane permeability to Na+ ions and occurred independently of Ca2+i changes. The relationship between membrane potential and Ca2+i changes in lymphocyte activation are discussed on the basis of these results. Our conclusion was that constitutive Ca2+(-)dependent K+ channels are absent in the WEHI 231 cell line.     

Concerted stimulation of PI-turnover, Ca2+-influx and histamine release in antigen-activated rat mast cells

Phospholipid metabolism in rat mast cells activated by antigen was examined with reference to phosphatidylinositol (PI) turnover. Upon antigen stimulation, histamine release from passively sensitized mast cells with IgE was potentiated by adding phosphatidylserine (PS). The addition of antigen to [3H]glycerol-prelabeled and sensitized mast cells induced a marked loss of radioactivity of PI and a concurrent accumulation of 1,2-diacylglycerol (DG) and phosphatidic acid (PA) within 5 to 60 sec. Furthermore, this antigen-induced PI breakdown was enhanced in the presence of Mg2+. Histamine release occurred in parallel with PI breakdown. On the other hand, the transient Ca2+ influx into mast cells, as measured by uptake of 45Ca2+, was found to occur quickly after cells were activated by antigen, which was concerted with PI breakdown. These results suggest that enhanced PI turnover may be an important step in the biochemical sequence of events leading to release of histamine, and that not only Ca2+ but also Mg2+ appears to take a part in stimulus-response coupling in rat mast cells.