NF-kappa B is required for surface Ig-induced Fas resistance in B cells.

The susceptibility of primary murine B cells to Fas-mediated apoptosis is regulated in a receptor-specific fashion. Whereas CD40 engagement produces marked sensitivity to Fas killing, engagement of the B cell Ag receptor blocks Fas signaling for cell death in otherwise Fas-sensitive, CD40-stimulated targets and thus induces Fas resistance. The signaling pathway that leads from B cell Ag receptor to Fas resistance has not been fully characterized, but has been shown to depend on new gene expression. NF-kappa B is activated following B cell Ag receptor engagement and is associated with antiapoptosis; thus, it would seem a likely candidate to mediate transcriptional activation for inducible Fas resistance. Inhibition of B cell Ag receptor signaling for NF-kappa B activation completely blocked induction of Fas resistance by anti-Ig, and this same phenotype was observed both with chemical inhibitors such as lactacystin and pyrrolidinedithiocarbamate as well as with an I kappa B alpha dominant negative TAT fusion protein. Antiapoptotic, NF-kappa B-responsive transcripts include two gene products previously implicated in mediating anti-Ig-induced Fas resistance, Bcl-x(L) and FLIP. B cell Ag receptor-induced up-regulation of both these gene products was blocked by NF-kappa B inhibition, suggesting a mechanism by which the loss of nuclear NF-kappa B alters the sensitivity of B cell Ag receptor-stimulated B cells to Fas-mediated apoptosis. These results indicate that activation of NF-kappa B plays a key role in mediating Fas resistance produced by B cell Ag receptor engagement.

Differential roles for extracellularly regulated kinase-mitogen-activated protein kinase in B cell antigen receptor-induced apoptosis and CD40-mediated rescue of WEHI-231 immature B cells.

One of the major unresolved questions in B cell biology is how the B cell Ag receptor (BCR) differentially signals to transduce anergy, apoptosis, proliferation, or differentiation during B cell maturation. We now report that extracellularly regulated kinase-mitogen-activated protein kinase (Erk-MAP kinase) can play dual roles in the regulation of the cell fate of the immature B cell lymphoma, WEHI-231, depending on the kinetics and context of Erk-MAP kinase activation. First, we show that the BCR couples to an early (< or =2 h) Erk-MAP kinase signal which activates a phospholipase A(2) pathway that we have previously shown to mediate collapse of mitochondrial membrane potential, resulting in depletion of cellular ATP and cathepsin B execution of apoptosis. Rescue of BCR-driven apoptosis by CD40 signaling desensitizes such early extracellularly regulated kinase (Erk) signaling and hence uncouples the BCR from the apoptotic mitochondrial phospholipase A(2) pathway. A second role for Erk-MAP kinase in promoting the growth and proliferation of WEHI-231 immature B cells is evidenced by data showing that proliferating and CD40-stimulated WEHI-231 B cells exhibit a sustained cycling pattern (8-48 h) of Erk activation that correlates with cell growth and proliferation. This growth-promoting role for Erk signaling is supported by three key pieces of evidence: 1) signaling via the BCR, under conditions that induce growth arrest, completely abrogates sustained Erk activation; 2) CD40-mediated rescue from growth arrest correlates with restoration of cycling Erk activation; and 3) sustained inhibition of Erk prevents CD40-mediated rescue of BCR-driven growth arrest of WEHI-231 immature B cells. Erk-MAP kinase can therefore induce diverse biological responses in WEHI-231 cells depending on the context and kinetics of activation.

Human B cell activation by autologous NK cells is regulated by CD40-CD40 ligand interaction: role of memory B cells and CD5+ B cells.

NK cells are a subpopulation of lymphocytes characterized primarily by their cytolytic activity. They are recognized as an important component of the immune response against virus infection and tumors. In addition to their cytolytic activity, NK cells also participate either directly or indirectly in the regulation of the ongoing Ab response. More recently, it has been suggested that NK cells have an important role in the outcome of autoimmune diseases. Here, we demonstrate that human NK cells can induce autologous resting B cells to synthesize Ig, including switching to IgG and IgA, reminiscent of a secondary Ab response. B cell activation by the NK cell is contact-dependent and rapid, suggesting an autocrine B cell-regulated process. This NK cell function is T cell-independent, requires an active cytoplasmic membrane, and is blocked by anti-CD40 ligand (anti-CD154) or CD40-mIg fusion protein, indicating a critical role for CD40-CD40 ligand interaction. Depletion studies also demonstrate that CD5+ B cells (autoreactive B-1 cells) and a heterogeneous population of CD27+ memory B cells play a critical role in the Ig response induced by NK cells. The existence of this novel mechanism of B cell activation has important implications in innate immunity, B cell-mediated autoimmunity, and B cell neoplasia.

Antigen receptor proximal signaling in splenic B-2 cell subsets.

Splenic marginal zone (MZ) and follicular mantle (FO) B cells differ in their responses to stimuli in vitro and in vivo. We have previously shown that MZ cells exhibit greater calcium responses after ligation of membrane IgM (mIgM). We have now investigated the molecular mechanism underlying the difference in calcium responses following ligation of mIgM and studied the response to total B cell receptor ligation in these two subsets. We compared key cellular proteins involved in calcium signaling in MZ and FO cells. Tyrosine phosphorylation and activity of phospholipase C-gamma 2 and Syk protein tyrosine kinase were significantly higher in MZ cells than in FO cells after mIgM engagement, providing a likely explanation for our previous findings. Tyrosine phosphorylation of CD22 and expression of Src homology 2-containing inositol phosphatase and Src homology 2-containing protein tyrosine phosphatase-1 were also higher in the MZ cells. Expression and tyrosine phosphorylation of Btk, BLNK, Vav, or phosphatidylinositol 3-kinase were equivalent. In contrast, stimulation with anti-kappa induced equivalent increases in calcium and activation of Syk in the two subsets. These signals were also equivalent in cells from IgM transgenic, J(H) knockout mice, which have equivalent levels of IgM in both subsets. With total spleen B cells, Btk was maximally phosphorylated at a lower concentration of anti-kappa than Syk. Thus, calcium signaling in the subsets of mature B cells reflects the amount of Ig ligated more than the isotype or the subset and this correlates with the relative tyrosine phosphorylation of Syk.

Nuclear factor (NF)-kappa B2 (p100/p52) is required for normal splenic microarchitecture and B cell-mediated immune responses.

The nfkb2 gene is a member of the Rel/NF-kappa B family of transcription factors. COOH-terminal deletions and rearrangements of this gene have been associated with the development of human cutaneous T cell lymphomas, chronic lymphocytic leukemias, and multiple myelomas. To further investigate the function of NF-kappa B2, we have generated mutant mice carrying a germline mutation of the nfkb2 gene by homologous recombination. NF-kappa B2-deficient mice showed a marked reduction in the B cell compartment in spleen, bone marrow, and lymph nodes. Moreover, spleen and lymph nodes of mutant mice presented an altered architecture, characterized by diffuse, irregular B cell areas and the absence of discrete perifollicular marginal and mantle zones; the formation of secondary germinal centers in spleen was also impaired. Proliferation of NF-kappa B2-deficient B cells was moderately reduced in response to lipopolysaccharide, anti-IgD-dextran, and CD40, but maturation and immunoglobulin switching were normal. However, nfkb2 (-/-) animals presented a deficient immunological response to T cell-dependent and -independent antigens. These findings indicate an important role of NF-kappa B2 in the maintenance of the peripheral B cell population, humoral responses, and normal spleen architecture.

Membrane IgM-induced tyrosine phosphorylation of CD19 requires a CD19 domain that mediates association with components of the B cell antigen receptor complex.

CD19 enhances membrane IgM (mIgM) signaling and is required for B lymphocyte responses to T-dependent Ags. CD19 is tyrosine phosphorylated when mIgM is ligated and binds SH2 domain-containing signaling proteins. We suggest that the basis for phosphorylation is the association of CD19 with Syk and other components of the mIgM complex. IgM, CD22, Ig-alpha, Ig-beta, and Syk were coimmunoprecipitated with CD19 from detergent lysates of B lymphocytes. The association was maintained with a chimeric form of CD19 containing only the transmembrane domain and the membrane proximal 17 amino acids of the cytoplasmic domain encoded by exon 6. This sequence is sufficient to mediate the association, as a synthetic peptide of the exon 6-encoded region adsorbs IgM and Syk. Deletion of the juxtamembrane 17 amino acids of the cytoplasmic domain encoded by CD19 exon 6 abolishes association of CD19 with the mIgM complex. Deletion of these amino acids, which contain no tyrosines, also reduces mIgM-induced tyrosine phosphorylation of the remainder of the CD19 cytoplasmic domain. Coligating this mutant CD19 to mIgM restores phosphorylation. Thus, a discrete region of the cytoplasmic domain regulates the tyrosine phosphorylation of CD19 in the activation of B cells by mIgM.

Cognate T cell help for CD40-deficient B cells induces c-myc RNA expression, but DNA synthesis requires an additional signal through surface Ig.

To investigate the role of CD40 ligand in the delivery of help to B cells, we examined the Ag-specific interaction of B cells from CD40-deficient mice with a Th2 cell line in vitro. Small resting B cells from normal mice are stimulated to synthesize DNA when they present monovalent Ag (rabbit Fab anti-Ig) to a rabbit Ig-specific Th cell line. This response, which is independent of a signal through the B cell Ag receptor (sIg), is nearly absent in B cells from CD40-deficient mice. The CD40-deficient B cells are not defective in Ag presentation because they induce T cell IL-4 synthesis as well as normal B cells. Also, CD40-deficient B cells respond to T cell help with DNA synthesis almost as well as normal B cells if an additional signal is provided through sIg. In conjunction with a sIg signal, cell contact with helper T cells induces DNA synthesis more effectively than soluble cytokines. CD40-independent T cell help can also be measured as an early increase in c-myc mRNA levels in CD40-deficient B cells presenting Ag to helper T cells, although the levels of c-myc RNA expression are lower than those in normal B cells. However, c-myc RNA induced by noncognate interaction with anti-CD3-activated T cells is completely CD40 dependent. We conclude that early growth signals from activated Th cells are received by CD40-/- B cells, but that CD40 and/or sIg signals are required for efficient induction of DNA synthesis.

Negative signaling in B cells by surface immunoglobulins.

Cross-linking of surface immunoglobulins generates negative signals that cause B-cell death unless appropriate rescue signals are provided. Surface IgM is the main transducer of the negative signaling, but surface IgD and IgG may also transduce negative signaling when cross-linked intensively. In the surface IgM+, IgD+ human malignant B lymphoma cell lines B104 and DND-39, cross-linking of surface IgM by anti-IgM antibodies induced cell death. Anti-IgM antibody-induced B104 cell death was inhibited by stimulation with alpha- and beta-interferons but not stimulation with anti-CD40 antibody or IL-4, whereas anti-IgM antibody-induced DND-39 cell death was inhibited by stimulation with anti-CD40 antibody but not stimulation with alpha- and beta-interferons. Anti-IgM antibody-stimulated B104 cells had morphologic features compatible with necrosis, whereas anti-IgM antibody-stimulated DND-39 cells showed morphologic features of apoptosis. CD11a/CD54-dependent cell adhesion induced by stimulation with anti-CD40 antibody was involved in anti-CD40 antibody-mediated inhibition of anti-IgM antibody-induced DND-39 cells. In normal human mature B cells, cross-linking of surface IgM induced different signaling consequences, including DNA synthesis or cell division (positive signaling) or cell cycle arrest or death (negative signaling). In this system, too, CD40-transduced signal inhibited anti-IgM antibody-induced negative signaling, and CD11a/CD54-dependent cell adhesion played a role in the rescue process. It is suggested that quantitatively different intensities of surface IgM cross-linking induce qualitatively different signaling consequences; relatively weak cross-linking may induce DNA synthesis; moderate cross-linking may induce DNA synthesis with cell cycle arrest at the G2/M interphase; and intense cross-linking may induce apoptotic cell death. The reasons for this difference are not yet known. Further elucidation of the molecular mechanisms responsible for surface IgM-mediated negative signaling and its rescue signaling may contribute toward development of therapy for allergic disorders by artificial modulation of specific immunoglobulin production.

Maintenance of nuclear factor-kappa B/Rel and c-myc expression during CD40 ligand rescue of WEHI 231 early B cells from receptor-mediated apoptosis through modulation of I kappa B proteins.

Engagement of surface IgM (sIgM) on WEHI 231 murine B lymphoma cells leads to abortive activation and apoptosis, suggesting that this cell line may represent a model for tolerance. Loss of viability in these cells is preceded by an early increase in c-myc RNA levels followed by a decline below control values, implicating c-myc in the control of apoptosis. Costimulation with CD40 ligand (CD40L) has been shown to rescue WEHI 231 cells from anti-sIgM-induced apoptosis, and therefore, the effects of CD40L on c-myc RNA and protein levels were measured. Treatment of these cells with the combination of CD40L and anti-sIgM led to induction and maintenance of elevated levels of c-myc RNA and protein. Since transcriptional regulation of c-myc is mediated through two nuclear factor-kappa B (NF-kappa B) sites in WEHI 231, the effects of CD40L on DNA binding by this family of transcription factors were evaluated. CD40L induced and sustained the levels of NF-kappa B binding to both of these sites, paralleling the changes in c-myc RNA levels. Elevated levels of NF-kappa B were partially achieved through a sustained decrease in the steady state amount of the NF-kappa B/Rel-specific inhibitory protein, I kappa B alpha, and a transient decrease in I kappa B beta. These data lend support to the hypothesis that anti-sIgM-induced apoptosis is caused by a drop in c-myc expression and that an appropriate second signal, such as that provided by CD40L, is able to rescue these cells by inducing NF-kappa B and thereby maintaining c-myc RNA levels.

Activation of mitogen-activated protein kinases via CD40 is distinct from that stimulated by surface IgM on B cells.

CD40 plays critical roles in B cell proliferation and differentiation in response to T cell-dependent antigenic stimulation. It has been suggested that CD40-mediated biological activities are transduced by a CD40 receptor-associated factor, CRAF1 and probably by protein tyrosine kinase Lyn and its substrates, phospholipase C gamma (PLC gamma) and phosphatidylinositol-3 kinase (PI-3 kinase). Here, we describe the novel finding that a mitogen-activated protein kinase (MAPK) extracellular signal-regulated protein kinase (ERK) cascade is involved in CD40 signaling in mouse B cells. Analysis of ERK activities in the B cell lymphoma cell line WEHI 231, which shows an increase in DNA synthesis or arrest of the cell cycle by cross-linking of CD40 or surface IgM (sIgM) cross-linking, respectively, indicated that one of the ERK isoforms, ERK2, was preferentially and rapidly activated after CD40 cross-linking. The CD40-mediated ERK2 activation was comparable to that after sIgM stimulation, although the activity was reduced toward the basal level within several minutes after stimulation. In contrast, ERK1 and ERK2 were activated to a similar extent by sIgM cross-linking, and the activities remained stable for at least 10 min. Furthermore, similar features of differential activation of ERK isoforms were observed in normal resting B cells in CD40 and sIgM signaling. These results suggest divergent regulatory pathways for ERK1 and ERK2 activation, and they support the notion that CD40 signaling may utilize a limited set of elements in the ERK cascade. Co-stimulation of WEHI 231 cells with anti-CD40 mAb rescues the cells from anti-IgM-mediated apoptosis, whereas this co-stimulation resulted in activation of ERK isoforms comparable to that in sIgM stimulation, without a synergistic effect. This result indicates the dominance of ERK activation in sIgM signaling over that of CD40, and it suggests that ERK activation may not be linked to the biological effect that CD40 stimulation in this cell line.

Transcriptional regulation of the junB promoter in mature B lymphocytes. Activation through a cyclic adenosine 3',5'-monophosphate-like binding site.

The experiments presented herein were designed to understand the molecular mechanism(s) by which membrane Ig (mIg)-dependent signals are integrated at the level of the junB promoter to induce gene transcription. Functional studies using chloramphenicol acetyltransferase reporter gene constructs that contained deleted 5' flanking region junB sequences identified a region located between -194 and -87 that contains an Ets binding site and a putative cAMP response element binding site (CRE-like). Point mutagenesis of the CRE-like site blocked junB promoter activation in response to mIg cross-linking in mature Bal17 B cells. Nuclear extract binding activity to a synthetic oligonucleotide containing the junB CRE-like site was detected in unstimulated B cells and was increased in response to mIg cross-linking. Binding activity was competed with unlabeled oligonucleotides that contained the junB CRE-like site or the somatostatin CRE consensus motif, the latter observation suggests that members of the activating transcription factor/CRE binding protein (CREB) family may mediate mIg-dependent junB transcription. Consistent with this interpretation, recombinant CREB and activating transcription factor proteins bound the junB CRE-like site, but did not interact with a mutant CRE-like site. Expression of a dominant negative CREB protein blocked mIg-mediated transcription from a junB CRE-like site-chloramphenicol acetyltransferase reporter gene. CRE-like nucleoprotein complexes from Bal17 B cells contained constitutively bound CREB-1, which was phosphorylated on serine 133 in response to mIg cross-linking. Activating transcription factor-1 protein was also constitutively expressed in CRE-like nucleoprotein complexes. Collectively, these results suggest that components of the protein kinase A signaling pathway are recruited by mIg to induce junB transcription.

IFN-gamma is a potent inducer of Ig secretion by sort-purified murine B cells activated through the mIg, but not the CD40, signaling pathway.

IFN-gamma has been shown to either stimulate or inhibit Ig secretion. No studies have yet addressed the basis for these seemingly conflicting properties nor whether IFN-gamma acted directly at the level of the B cell to mediate its effects. Thus, we studied the ability of IFN-gamma to regulate Ig secretion in sort-purified, resting murine B cells that were >99% Ig+, activated either through membrane Ig using unconjugated or dextran-conjugated anti-IgD antibodies (alphadelta-dex) or through CD40 using soluble or membrane CD40 ligand (CD40L). B cells activated with alphadelta-dex proliferated but do not secrete Ig, even in the presence of IL-1 + IL-2. We demonstrate that IFN-gamma only when added subsequent to B cell stimulation with alphadelta-dex, but not unconjugated anti-IfD antibody, plus IL-1 + IL-2 induces up to 100-fold enhancements in Ig secretion and in the numbers of Ig-secreting cells. The predominant Ig isotype secreted is IgM, with IgG3 and IgG2a comprising the majority of non-IgM antibody. IFN-gamma must act in concert with IL-2 for stimulation of Ig secretion. Further, IFN-gamma synergizes with IL-3 + granulocyte-macrophage colony stimulating factor for induction of Ig synthesis. IFN-gamma also enhances IgA syntheses by transforming growth factor-beta-induced membrane IgA+ cells. By contrast, 125IIFN-gamma fails to stimulate Ig secretion in B cells activated with CD40L in the presence or absence of IL-1 + IL-2 or IL-4. However, the combination of CD40L and alphabeta-dex is strongly synergistic for IFN-gamma-induced Ig secretion. Thus, these data establish that IFN-gamma can act directly on the B cell to induce Ig synthesis without the participation of any other cell and demonstrates that the mode of activation of the B cell plays an important role in directing the action of IFN-gamma.

Mitogenic effect of HIV-infected human T cell lines on mouse B cells mediated by surface immunoglobulin.

Following HIV-1 infection, a number of disorders are induced in both normal T and B cells by virus products derived from infected CD4+ T cells. In the present study, we found that HIV-infected, but not uninfected, human T cell lines generated vigorous blastogenesis and proliferation of freshly isolated mouse B cells in a short-term culture. Neither human B cells nor rat B cells showed significant responses to the HIV-infected T cell lines in the present condition. The mitogenic effect of HIV-infected human T cell line requires direct cell-cell interaction between mouse B cells and HIV-infected T cell lines. Since either mitomycin c treatment or paraformaldehyde fixation of HIV-infected T cell lines resulted in complete loss of the mitogenic effect, it seems that de novo synthesized viral products are responsible for this effect. Furthermore, anti-mouse immunoglobulin antibody inhibited completely the B cell stimulation by the HIV-infected human T cell lines. Thus, surface immunoglobulin (sIg) on mouse B cells appears to be an essential molecule which transduces activation signals from HIV-infected human T cells into cytoplasm of the B cells.

Th1 and Th2 help for B cells: differential capacity for induction of autonomous responsiveness to IL-2.

Sustained interaction with Th1 cells has been shown to induce IL-2 responsiveness by murine B cells. This is equivalently dependent on CD40, CD54/ICAM-1 and MHC II ligation, and co-cross-linking of CD54 and MHC II in the presence of IL-5 up-regulates a functional IL-2R on B cells. We now show that IL-5 (125 U/ml) synergizes with Th1 cells to induce B cell responses to IL-2, that are maintained following T-cell removal, e.g. autonomous. Th1 help in the absence of IL-5 resulted in weak or undetectable responses following T cell removal. The mechanism of IL-5 synergy involved persistence of IL-2R beta expression following T cell removal, as opposed to enhancement of IL-2R induction or function. The level of contact-induced IL-2R expression on B cells was not itself modified by IL-5. The effects of IL-5 did not overcome the requirement for T contact signals and treatment of B cells with soluble anti-Ig did not circumvent the need for IL-5 for autonomous IL-2 responses. Consistent with the above, interaction with an IL-5-producing Th2 clone induced strong autonomous B cell responses to IL-2. Qualitative differences of Th2 help over that of Th1 may thus be attributable to their differential ability to induce autonomous B cell responsiveness to cytokines. This may be representative of events in which maintenance of cell cycle is important, as is the case in germinal centers.

Surface IgM-stimulated proliferation, inositol phospholipid hydrolysis, Ca2+ flux, and tyrosine phosphorylation are not altered in B cells from p59fyn-1- mice.

The surface immunoglobulin M (sIgM)-associated src family protein tyrosine kinases (PTKs) p55blk, p59fyn, and p53/56lyn become activated in B cells within seconds following sIgM cross-linking. Studies using protein tyrosine kinase (PTK) inhibitors have demonstrated that PTK activity is crucial for downstream events such as calcium flux, inositol phospholipid hydrolysis, and cell cycle entry. The roles that the individual src family PTKs play in sIgM signaling are largely unknown, however. In order to determine whether p59fyn plays a distinct role in sIgM signal transduction, the signaling capabilities of B cells isolated from fyn "knockout" mice were evaluated. We observed that in the absence of p59fyn, there was no demonstrable compromise of the sIgM-coupled signaling events measured (tyrosine phosphorylation, inositol phospholipid hydrolysis, and Ca2+ flux). We propose that either p59fyn is not involved in coupling sIgM to these specific signaling pathways or that other PTKs are able to compensate for the absence of p59fyn, indicating redundancy in the sIgM signaling pathways.

Anti-Ig-stimulated B lymphoblasts can be restimulated via their surface Ig.

Engaging AgR (surface Ig) on B lymphocytes leads to rapid inositol phosphate turnover and elevation of intracellular [Ca2+]. Continuous receptor occupancy (greater than 18 h) by anti-Ig leads to transit of most B lymphocytes from G0 to G1 stage of the cell cycle (blast transformation); a fraction of cells continue into S phase but do not proliferate continuously in the absence of growth factors. Prolonged exposure to ligand can induce receptor desensitization of some receptors. We therefore investigated whether such desensitization occurs in B cells activated by insolubilized anti-Ig. Resting B cells and anti-Ig-activated blasts were examined for their potential to elevate [Ca2+]i, maintain viability, and synthesize DNA in response to reexposure to anti-Ig. B cells and anti-Ig blasts had similar basal [Ca2+]i levels. Anti-Ig blasts retained the capacity to increase [Ca2+]i in response to anti-Ig; the magnitude of the increase was equal to or greater than that observed with resting B cells and occurred in more than 90% of cells. Isolated anti-Ig blasts subcultured in the presence of T cell-derived growth factors for 3 to 5 days responded to restimulation by anti-Ig with an increase in [Ca2+]i similar to that observed in freshly isolated blasts. The B cell and B lymphoblast ion channels were found to be permeable to Ca2+ but impermeable to Mn2+. Finally, blasts restimulated by anti-Ig retained viability and incorporated low levels of [3H]thymidine for 24 h. These results suggest that AgR on activated B lymphocytes can remain functionally coupled to intracellular signaling pathways and can participate in immune responses subsequent to initial activation.

Different patterns of inositol polyphosphate production are seen in B lymphocytes after cross-linking of sIg by anti-Ig antibody or by a multivalent anti-Ig antibody dextran conjugate.

Anti-delta antibody conjugated to 2 x 10(6) m.w. dextran (dex) stimulates B lymphocyte proliferation at 10,000-fold lower concentrations than that required by the unconjugated antibody. Dex conjugated antibody also stimulates a greater and more sustained increase in intracellular ionized calcium [( Ca2+]i) than does the unconjugated anti-Ig antibody. Inasmuch as inositol phosphate metabolites have been linked to rises in [Ca2+]i, we analyzed by FPLC the relative amounts of the inositol polyphosphates (IP) in these cells. Anti-Ig-dextran induced a threefold greater increase in total IP than did the unconjugated anti-Ig. Furthermore, in cells stimulated by unconjugated anti-Ig there was a transient induction of I(1,4,5)P3 followed by a rapid accumulation of the I(1,3,4)P3 isomer with little accumulation of I(1,4)P2, whereas in anti-Ig-dex-stimulated cells there was prolonged elevation of I(1,4,5)P3 with more accumulation of I(1,4)P2. In addition, levels of I(1,3,4,5)P4 were maintained over a longer period of time in B cells stimulated by anti-Ig-dex than in those stimulated by unconjugated anti-Ig. The enhanced ratio of I(1,4,5)P3/I(1,3,4)P3 was also seen when suboptimal concentrations of anti-Ig-dex were used which stimulated a level of total inositol phosphate that was similar to that stimulated by the unconjugated anti-Ig. The possibility that the greater stimulation of increased [Ca2+] by anti-Ig-dex than by unconjugated anti-Ig was a predominant factor in influencing the metabolic pathway of I(1,4,5)P3 was excluded. These results show that 1) stimulation of increases in the various IP isomers occurs in anti-Ig stimulated normal B cells as has been shown in B cell lines and 2) that signal transduction and consequent PIP2 hydrolysis that is stimulated by Ag-mediated cross-linking of sIg is strongly influenced by the extent and type of cross-linking that is induced.

Heterogeneity of mouse B lymphocytes: studies using in vitro response to lipopolysaccharide.

When murine lymphoid cells from spleen and lymph nodes were cultured with LPS, all the transformed blasts observed were B cells bearing surface IgM which could be classified into two types depending upon whether they contained intracellular IgM (i mu +) or not (i mu -). At the ultrastructural level, the two categories of blasts appeared to correspond to cells having a well-developed ER or primarily free ribosomes. A striking observation was that the proportion of i mu + blasts among transformed cells was 5-10 times lower in cultures of lymph node than in cultures of spleen cells. The same observations were made on LPS cultures of "purified" B lymphocytes. Prolongation of the culture period did not modify these results. This indicated that the differences in the response to LPS reflected the existence of at least two pre-existing subpopulations of B cells unequally distributed in peripheral lymphoid organs. Analysis of the surface antigens and receptors (MBLA, surface Ig classes, Fc and C receptors) of the B cells from spleen and lymph nodes did show some differences between these two lymphoid organs. Among the transformed cells, Fc receptors were present mainly on i mu - cells and C receptors on i mu + cells; however, no strict correlation could be made between the i mu + or i mu - nature of these cells and their surface characteristics. The possibility that precursors of i mu + and i mu - blasts might represent virgin and memory B cells or B cell populations differing in their requirement for helper factors released by stimulated T cells was explored by using cultures of spleen and lymph node cells (1) obtained from germ-free mice, which are expected to have few memory cells, or (2) performed in the presence of the supernatant of mixed lymphocyte cultures, in conditions where these supernatants are known to contain factors released by activated T cells. Neither condition modified the degree of transformation or Ig content of blasts.