sIg Cross-linking Research Articles

Biochemical analysis of the immune B cell defect in xid mice.

Previous studies have shown that B cells from xid immune defective CBA/N mice that are unresponsive do not proliferate after stimulation with unconjugated anti-Ig. The experiments in this manuscript demonstrate that dextran-anti-Ig conjugates, which induce extensive and prolonged sIg cross-linking, are able to stimulate proliferation of xid B cells. The ability of these conjugates to stimulate proliferation of xid B cells is not related to their ability to stimulate higher levels of PIP2 breakdown. Thus, high concentrations of unconjugated anti-Ig antibody, which are nonmitogenic for xid B cells, stimulate higher levels of PIP2 breakdown and of calcium transients than lower concentrations of dextran-conjugated anti-Ig, which are mitogenic. Although unconjugated anti-Ig does not provide a fully competent signal to stimulate proliferation of xid B cells, it induces a sufficiently stimulatory signal to enable them to enter DNA synthesis in the presence of the protein kinase C activator, indolactam. This suggests that the extent or duration of activation of protein kinase C by anti-Ig may be limiting in xid B cells. To examine whether another recently described pathway of B cell activation is defective in these mice, we studied the induction of early anti-Ig-mediated tyrosine kinase activity in xid B cells. Both unconjugated and dextran-conjugated anti-Ig antibody stimulated comparable but not identical patterns of tyrosine phosphorylation. These data taken together with other findings that the combination of phorbol ester and calcium ionophore stimulates high levels of proliferation in xid B cells suggests that the immune defect of xid B cells may be distal to surface Ig-mediated activation of tyrosine kinase and of PIP2 breakdown but proximal to PKC activation. Alternatively, the xid immune defect may not result from abnormalities in the early signal transduction pathways, but rather from more distal and/or as yet undefined pathways leading to B cell activation.

Negative signaling by surface IgM on B cells isolated from ileal Peyer's patch follicles of sheep

Lymphoid follicles from the sheep ileal Peyer's patch (PP) were used to prepare a cell suspension consisting of 98% surface IgM-positive (sIgM+) B cells and 1% T cells. Co-stimulation of follicular cells with pokeweed mitogen and either recombinant bovine interleukin 1 (IL 1) or IL 2 resulted in a marked proliferative response. In contrast, the addition of soluble F(ab')2 rabbit anti-sheep Ig completely inhibited the proliferative response induced by pokeweed mitogen and IL 1 or IL 2 co-stimulation. Anti-Ig inhibition of B cell proliferation was specific for ileal PP follicular cells and was not observed with mesenteric lymph node cells or splenocytes. Furthermore, suppression of ileal PP follicular B cell proliferation required at most divalent cross-linking of sIg was independent of Fc receptors, but was dependent on the concentration of anti-Ig and required 48 h for maximal effect. Negative signaling by sIgM indicates that ileal PP follicular B cells are functionally distinct from B cells in other secondary lymphoid tissues. Also, the present observations are consistent with previous reports indicating that B cell proliferation in ileal PP follicles is antigen independent.

Intracellular localization of tyrosine kinase substrates beneath crosslinked surface immunoglobulins in B cells.

Crosslinking of surface immunoglobulins (sIg) in B cells led to the accumulation of submembranal phosphotyrosine, which was followed morphologically with the PY20 antiphosphotyrosine monoclonal antibody. Phosphotyrosine was not detected before sIg crosslinking. After sIg crosslinking, phosphotyrosine-containing proteins were redistributed from scattered small clusters near the plasma membrane to a juxtanuclear region, where immunofluorescent staining decreased with time. Double immunofluorescent staining of individual cells showed accumulation of phosphotyrosine beneath crosslinked sIg molecules at the cell surface. The sIg molecules were subsequently internalized more rapidly than the phosphotyrosine-containing molecules were redistributed. Genistein, a protein tyrosine kinase (PTK) inhibitor, blocked intracellular tyrosine phosphorylations but not cell surface patching of crosslinked sIg. When polyacrylamide beads coated with anti-Ig antibodies were added to the cells, intracellular tyrosine phosphorylation occurred beneath the regions of contact with the beads. This study provides an independent line of evidence confirming recent biochemical experiments that show that crosslinking of the antigen receptor induces PTK activity in B cells, and that components of the newly described sIg complex are among the PTK substrates. The surprising finding that the bulk of the induced phosphotyrosine remains associated with crosslinked sIg for many minutes suggests a role for complex local protein interactions in phosphotyrosine-mediated signal transduction through the antigen receptor of B cells.

Relative frequencies of secondary B cells activated by cognate vs. other mechanisms

Three distinct mechanisms for the activation of secondary B cells to antibody-forming cells have been examined in splenic fragment cultures. The clonal response to a protein antigen [cytochrome c (cyt)] was quantified in terms of both the number of B cells activated and the amount of antibody produced by each clone. The vast majority of memory B cells required surface immunoglobulin (sIg) receptor-mediated uptake of antigen followed by cognate interactions with an antigen-specific T helper cell. Nevertheless, a significant number (as many as 12%) could be activated via soluble factor-mediated bystander activation, involving occupation of neither the sIg receptor nor class II major histocompatibility complex (MHC) molecules. This pathway, however, was relatively inefficient in that individual clones secreted less than half as much antibody as clones activated as a result of cognate collaboration with a T helper cell. A similar number of secondary B cells were activated following nonspecific uptake of high concentrations of antigen for which splenic fragment T cells had been primed [i.e., hemocyanin (Hy)], independent of sIg receptor occupancy. Antibody levels were similar to those in cultures where B cells were activated in a cognate manner with sIg receptor occupancy. When Hy-stimulated fragment cultures were supplemented with polymerized cyt, the frequency of activation via this latter pathway increased fourfold, despite the fact that no cyt-primed T cells were present. This observation supports the idea that receptor-mediated uptake of antigen serves not just to focus antigen but also provides an important signal in activating B cells. Bystander B cell activation, however, was not enhanced by providing a sIg cross-linking signal with polymerized cyt. The lower level of antibody production by B cells activated in a bystander fashion and the inability to enhance their frequency of activation with sIg receptor occupancy suggest that there is indeed a fundamental difference between soluble factor-mediated bystander activation and activation via T cell determinant-mediated cognate T helper-B cell interactions, perhaps involving signaling through class II MHC molecules.

Differential effects of the stimulation of complement receptors CR1 (CD35) and CR2 (CD21) on cell proliferation and intracellular Ca2+ mobilization of chronic lymphocytic leukemia B cells.

The regulatory role of CR1 and CR2 on B cell activation and proliferation has been investigated by using B cells from patients with chronic lymphocytic leukemia. The chronic lymphocytic leukemia B cells are clonal expansions of B lymphocytes frozen at specific stages of activation. They displayed two patterns of response upon surface Ig (sIg) cross-linking in terms of in vitro proliferation and intracellular free Ca2+ mobilization: cells from patient F (first pattern) proliferated in the presence of mitogenic anti-mu antibodies, whereas cells from patient A (second pattern) did not respond to sIg cross-linking but proliferated in the presence of low m.w. B cell growth factor and IL-2. Coculture of A or F cells with C3b-bearing SRBC led to a two- to four-fold increase in thymidine incorporation in cultures containing low m.w. B cell growth factor but not in cultures containing rIL-2. This enhanced proliferation was inhibited by F(ab')2 polyclonal rabbit antihuman CR1 antibodies. Only cells which proliferated in the presence of anti-mu (cells F) responded to cross-linking of sIg with a rise in intracellular Ca2+. No increase in calcium mobilization was observed after co-cross-linking of CR1 and sIg on A and F cells with mAb or polyclonal anti-CR1 antibodies. Co-cross-linking of CR2 with sIg only led to an enhanced intracellular Ca2+ rise in F cells but not in A cells. The lack of CR2-mediated synergy in Ca2+ rise in A cells indicates that the synergy occurs only if there is a proper coupling of sIg to phospholipase C. CR1-induced proliferation of B cells does not involve the signaling pathways of sIg. These results provide additional evidences for the role of C3 fragments in modulation of human B cell activation.

Antigen-induced Ca2+ signaling and desensitization in B cells.

Cross-linking of B cell surface Ig (sIg) by anti-Ig results in transmembrane signaling. However, the capacity of a thymus-dependent (TD) Ag to mediate B cell signal transduction has been less well documented. Therefore, we examined Ag-induced intracellular free calcium concentration [( Ca2+]) in B cells by using TD Ag that would be expected to either cross-link or not cross-link sIgM and/or induce the coupling of sIgM to FcR. Stimulation of mouse TA3 hybridoma B cell transfectants that express the SP6 anti-TNP specific sIgM with either TNP-OVA or anti-IgM antibodies resulted in a maximal fourfold increase in [Ca2+]i. The net increase in [Ca2+]i in response to TNP-OVA was dependent upon both the Ag dose and the TNP:OVA molar ratio. Because occupancy of several cell-surface receptor types leads to a loss of response to subsequent stimulation by ligand (homologous desensitization), we examined the ability of Ag to induce homologous desensitization of sIgM in these B cells. TNP1-OVA at all concentrations tested (up to 500 micrograms/ml) did not lead to any change in [Ca2+]i or desensitization. Cross-linking of TNP1-OVA (10 micrograms/ml) with F(ab')2 of anti-OVA antibody induced both a rise in [Ca2+]i and homologous desensitization of sIg, suggesting that cross-linking of sIgM by Ag is sufficient to induce both these processes. TNP6-OVA at a concentration of 10 micrograms/ml induced changes in [Ca2+]i and partially desensitized TNP-specific B cells to stimulation by anti-IgM. Interestingly, a high dose (180 micrograms/ml) of TNP6-OVA stimulated minimal changes in [Ca2+]i yet did not lead to desensitization. However, cross-linking of TNP6-OVA at this high dose with F(ab')2 of rabbit anti-OVA elevated [Ca2+]i and elicited partial desensitization. Complete desensitization of sIgM by Ag was achieved when intact (Fc-containing) anti-OVA antibody was used, suggesting that the FcR can play a role in desensitization. Ag- and antibody-mediated desensitization was not caused by steric hindrance of sIg. Thus, we have observed two forms of Ag-induced desensitization of sIgM, both of which involve sIg cross-linking and one of which is mediated by the physiologic coupling of sIg to FcR.

Cross‐linking of the surface immunoglobulin on lymphocytes from the bursa of Fabricius results in second messenger generation

The bursa of Fabricius represents the major site of B lymphocyte development in avian species. Although the vast majority of bursal lymphocytes express cell surface immunoglobulin (sIg), it is generally considered that the bursa does not represent a significant site of antigen-induced B cell maturation to Ig secretion. However, the question as to whether antigen, either exogenous or self, can induce positive or negative selection of bursal lymphocytes in such a way as to modify the peripheral B cell repertoire remains open. Clearly, such intrabursal selection would require that bursal lymphocyte sIg have the molecular machinery to transduce signals into the cell as a consequence of its interaction with antigen. In this report we demonstrate that exposure of bursal lymphocytes to antibodies directed against sIg induced a rapid increase in cytosolic free calcium ion concentrations [Ca2+]i. Furthermore, such antibodies also induced a rapid increase in intracellular phosphatidic acid concentrations followed by a rise in intracellular phosphatidylinositol. Increased [Ca2+]i, phosphatidic acid and phosphatidylinositol levels required the cross-linking of sIg and were not induced by antibodies to other bursal cell surface antigens. Thus, cross-linking of the sIg on bursal lymphocytes results in second messenger generation, demonstrating that bursal sIg is a functional signal transduction element.

Altered signal transduction secondary to surface IgM cross-linking on B-chronic lymphocytic leukemia cells. Differential activation of the phosphatidylinositol-specific phospholipase C.

To further study the mechanisms by which surface Ig triggering activates the inositol phospholipid signaling pathway, we have used B cells from chronic lymphocytic leukemia patients which, as previously described, display two patterns of response upon sIg cross-linking: in one group this cross-linking induces an inositol phosphate release, an intracellular free Ca2+ concentration elevation and a subsequent cell proliferation; in a second group none of these events occur although there is an increased class II Ag expression following anti-mu stimulation as in the first group. We have been able to demonstrate that the phosphatidyl inositol specific phospholipase C (PI-PLC) can be activated in permeabilized B cells from the first group by direct stimulation, with GPT gamma S, of a guanine nucleotide binding (G) protein. In addition, since anti-mu + GTP gamma S stimulate an increased inositol phosphate production in these cells, this suggests that surface Ig cross-linking activates PI-PLC via a G protein. However, in cells from the second group no inositol phosphate is released after GTP gamma S stimulation although PI-PLC can be directly activated by high Ca2+ concentrations. This reflects in these cells, an interruption of the signaling cascade sIg/G protein/PI-PLC at the level of the G protein or at the G protein/PI-PLC coupling. In cells from both groups PMA treatment, which is known to alter phosphatidyl inositol metabolism in B cells, completely inhibits PI-PLC activation even by high Ca2+ concentrations. These studies show that the phosphatidyl inositol-dependent signaling cascade after surface Ig triggering can be altered at different levels in B cells.

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.

Differential expression of a zinc finger-encoding gene in response to positive versus negative signaling through receptor immunoglobulin in murine B lymphocytes.

Egr-1 is a murine early growth factor-inducible gene that encodes a protein with zinc fingers and that is believed to be involved in transcriptional regulation. Expression of this gene was investigated in murine B lymphocytes stimulated through their receptor for antigen (surface immunoglobulin [sIg]) with antireceptor antibodies (anti-sIg). Rapid (by 15 min) up-regulation of Egr-1 mRNA expression was observed after sIg cross-linking at a dose of anti-sIg sufficient to drive the majority of cells into cell cycle. Interestingly, signaling through sIg on the murine B-lymphoma cell line WEHI-231 did not up-regulate Egr-1 expression even though similar signaling pathways, including up-regulation of c-fos expression, are associated with this receptor in these cells. Importantly, cell growth and proliferation of WEHI-231 cells were inhibited by anti-sIg stimulation, which suggested a relationship between Egr-1 expression and differential processing of receptor immunoglobulin signals with respect to cellular growth responses. This notion was further supported by the finding that murine B lymphomas whose proliferation was not inhibited by anti-sIg showed receptor immunoglobulin-coupled Egr-1 expression. In further support of this association are results showing that under conditions in which Egr-1 expression was induced in WEHI-231 cells in response to stimulation by anti-sIg, a concomitant change was observed in the growth response of these cells. These results, then, indicate a potential role for Egr-1 expression in the translation of receptor-generated signals into cellular activation or induced unresponsiveness.

Differential Expression of a Zinc Finger-Encoding Gene in Response to Positive versus Negative Signaling through Receptor Immunoglobulin in Murine B Lymphocytes

Egr-1 is a murine early growth factor-inducible gene that encodes a protein with zinc fingers and that is believed to be involved in transcriptional regulation. Expression of this gene was investigated in murine B lymphocytes stimulated through their receptor for antigen (surface immunoglobulin [sIg]) with antireceptor antibodies (anti-sIg). Rapid (by 15 min) up-regulation of Egr-1 mRNA expression was observed after sIg cross-linking at a dose of anti-sIg sufficient to drive the majority of cells into cell cycle. Interestingly, signaling through sIg on the murine B-lymphoma cell line WEHI-231 did not up-regulate Egr-1 expression even though similar signaling pathways, including up-regulation of c-fos expression, are associated with this receptor in these cells. Importantly, cell growth and proliferation of WEHI-231 cells were inhibited by anti-sIg stimulation, which suggested a relationship between Egr-1 expression and differential processing of receptor immunoglobulin signals with respect to cellular growth responses. This notion was further supported by the finding that murine B lymphomas whose proliferation was not inhibited by anti-sIg showed receptor immunoglobulin-coupled Egr-1 expression. In further support of this association are results showing that under conditions in which Egr-1 expression was induced in WEHI-231 cells in response to stimulation by anti-sIg, a concomitant change was observed in the growth response of these cells. These results, then, indicate a potential role for Egr-1 expression in the translation of receptor-generated signals into cellular activation or induced unresponsiveness.

Cross-linking of membrane IgM on B CLL cells: dissociation between intracellular free Ca2+ mobilization and cell proliferation.

It has been shown previously that chronic lymphocytic leukemia (CLL) B cells are frozen at different stages of activation with unique requirements for proliferation. Although most B CLL cells express surface IgM, anti-mu antibodies are able to trigger only some of them to proliferate and/or respond to B cell growth factor (BCGF) or interleukin 2 (IL2), as normal B cells. In this report we extend these observations using three different monoclonal antibodies (mAb) to human mu chain (one mitogenic in soluble form for normal B cells, the two others mitogenic only when coupled on Sepharose 4B beads). Cells from only 3 out of 11 B CLL patients proliferated in the presence of either mitogenic anti-mu. When the early events following surface Ig cross-linking, such as calcium mobilization (by flow cytometry on indo-1-labeled cells), were studied all three mAb in soluble form were able to induce a similar increase in the intracellular free calcium concentration ([Ca2+]i); analogous to [Ca2+]i rise after the mitogenic F(ab')2 anti-mu stimulation. This response was seen only in 8 out of the 12 CLL B cells studied. All B CLL cells, however, proliferate in response to a combination of phorbol ester 12,13-dibutyrate (PBt2) and ionomycin. Therefore, three patterns of response to sIg cross-linking by anti-mu could be distinguished: cells from 4 out of 12 cases proliferate and mobilize Ca2+ upon anti-mu triggering (behaving like resting B lymphocytes); in 4 other cases anti-mu lead to Ca2+ mobilization without cell proliferation; in the last 4 cases neither Ca2+ mobilization, IP3 generation (in the one case studied) nor cell proliferation are observed although these cells do proliferate directly in response to growth factors. Moreover, anti-mu stimulation in this group leads to increased proliferation in response to BCGF and IL2 suggesting an anti-Ig signaling independent of inositol phosphate metabolism. These results are interpreted in terms of differential anti-mu signaling on B cells at different stages of activation.

Picogram quantities of anti-Ig antibodies coupled to dextran induce B cell proliferation.

To investigate the properties which enable type 2 Ag, as exemplified by dextran and Ficoll, to stimulate high levels of antibody responses in the relative absence of T cells, we conjugated anti-IgD and anti-IgM mAb to both dextran and Ficoll and examined their B cell-activating properties. Such conjugated anti-Ig antibodies stimulated both early and later stages of B cell activation at picogram concentrations, which are at least 1000-fold lower than that required for B cell stimulation by unconjugated anti-Ig antibodies, and the level of proliferation they stimulated was on average 10-fold greater. Furthermore, concentrations of anti-Ig dextran (100 pg/ml) which modulated little sIgD from the B cell surface were strong inducers of enhanced B cell expression of MHC class II molecules. Conjugation of Fab fragments of anti-IgD or nonmitogenic anti-IgM mAb to dextran rendered them as mitogenic as dextran conjugated to strongly stimulatory anti-IgD or anti-IgM antibodies. The ability of dextran and Ficoll to serve as effective carrier molecules for anti-IgD was not related solely to their large m.w., because anti-IgD coupled to polymerized BSA (m.w. 1.5 X 10(6), was only 10- to 50-fold more potent than unconjugated anti-IgD antibodies at stimulating B cell DNA synthesis. These results suggest, therefore, that the unique ability of picogram concentrations of haptenated type 2 Ag to stimulate Ig secretion in the absence of T cells may be a function of their ability to promote effective cross-linking without resulting in the modulation of sIg. This would enable such Ag to mediate repetitive B cell signaling, a situation that cannot be achieved by unconjugated anti-Ig antibodies which result in modulation of sIg at their mitogenic concentrations. These compounds therefore may be employed to study B cell activation stimulated by sIg cross-linking at concentrations that may more closely reflect those which are achieved under physiologic conditions by type 2 Ag.

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.

Biochemical analysis of inhibitory effects of a lymphokine suppressive B-cell factor on the activation process of resting B cells

Suppressive B-cell factor (SBF) is elaborated by FcRγ (Fc receptor for IgG)-bearing small, resting B cells after the stimulation of immune complexes and is known to inhibit humoral immune responses by acting on resting B cells. In order to elucidate where and how SBF interferes with B-cell activation in the course of transmembrane signaling, we examined the effect of SBF on the several sequential events which B cells undergo after crosslinking surface immunoglobulin (sIg). Hyper-Ia expression, plasma membrane depolarization, and activation of phosphatidylinositol (PI) hydrolysis of resting B cells, all of which were induced by the stimulation with anti-μ antibody, were significantly suppressed by the pretreatment of cells with SBF. However, SBF had no effect on the intracytoplasmic cyclic AMP level of either activated or resting B cells. Another inhibitory effect of SBF on the activation process of resting B cells by anti-μ antibody was to suppress the transient elevation of intracytoplasmic free Ca 2+ only in the initial phase after triggering with anti-μ antibody. This seems to be due to a decrease in the release of inositol triphosphate into the cytoplasm by suppressing the activation of PI hydrolysis. Considering all the data, the suppressive effect of SBF on the transmembrane signaling by sIg crosslinking is ascribed to the selective suppression of the activation of PI hydrolysis. This provides a concept on a molecular basis that feedback regulation of humoral immune response is, at least partly, regulated by SBF.

Direct T helper-B cell interactions induce an early B cell activation antigen.

We have explored the consequences for the B cell of cognate interaction with T cells. Early expression of the B cell-restricted cell surface activation antigen, BLAST-2, has been used as an assay system to measure direct T-B cell collaboration. BLAST-2 is preferentially expressed by allogenic B cells cultured with MHC class II antigen-restricted Th clone cells matched to the DR specificity of the target B cells. B cells cultured with DR-mismatched allospecific Th cells express minimal BLAST-2. Th cell-induced BLAST-2 expression appears to be accessory cell independent and occurs as early as 8 h after initiation of culture, with peak expression at 18 h. Direct T-B cell contact, rather than Th-derived lymphokines, provides the most efficient stimulus for BLAST-2 expression. Crosslinking of sIg on B cells is a poor stimulus for BLAST-2 expression. The BLAST-2 assay permits the evaluation of early events associated with B cell activation through cognate interactions, and may facilitate subsequent studies of the mechanism of B cell differentiation.

Cross-linking surface immunoglobulin increases the stiffness of lymphocytes

Cross-linking surface immunoglobulin (sIg) on B-lymphocytes causes a substantial increase in the mechanical stiffness of the cells. This has been demonstrated using a new method for measuring cellular deformability. The method is based on a device, the “Cell Poker”, which we use to determine the force required slightly to indent or compress a cell adherent to a rigid substrate in culture. Cross-linking of sIg by bivalent anti-sIg antibodies is necessary to elicit the increase in stiffness; binding of monovalent Fab fragments is insufficient. The increase in stiffness is partially reversed by cytochalasin D and by completion of the capping of the cross-linked sIg. The modulation of cellular deformability and the induction of cellular dynamic processes such as capping are similar in their requirements for cross-linking sIg and in their sensitivity to cytochalasins. This suggests that both kinds of responses stem from similar cellular processes and structures. These results emphasize the mechanical capability of lymphocytes and suggest that the physiological functions of these cells are likely to employ this capability.

T lymphocyte-dependent B lymphocyte proliferative response to antigen. II. Induction of polyclonal B lymphocyte activation of normal B cells and of Lyb-5- B cells from xid mice via recognition of self-IA antigens.

We extended our investigations into the genetic requirements and antigen dependence for the induction of polyclonal B lymphocyte proliferation by primed T lymphocytes. By using recombinant inbred mouse strains and antigen-specific T lymphocyte clones that lack alloreactivity, the genetic requirement was mapped to the IA subregion of the MHC. Furthermore, approaches that prevented or limited the accessibility of antigens to the B lymphocyte surface demonstrated that antigen binding onto the B lymphocyte surface was probably not necessary for induction of B lymphocyte proliferation. These experiments suggest strongly that T lymphocyte recognition of B lymphocyte Ia molecules in the absence of sIg cross-linking or in the absence of antigen bound nonspecifically to B lymphocytes can cause cellular activation. Similar T lymphocyte-dependent B lymphocyte activation was seen when Lyb-5- cells from CBA/N mice with the xid defect were cultured. Increases in the number of cells secreting immunoglobulins could be detected in the proliferating B lymphocyte cultures, suggesting that the culture conditions had fulfilled the requirements for B lymphocyte differentiation into antibody-producing cells. Although anti-Ig did not interfere with the B lymphocyte proliferative responses, it did diminish the number of cells secreting immunoglobulins. The implications of these experiments in extending our understanding of the activation pathway of Lyb-5- and Lyb-5+ B lymphocytes are discussed.

Lyb-5- B cells of CBA/N mice can be induced to synthesize DNA by culture with insolubilized but not soluble anti-Ig.

The use of anti-immunoglobulin (anti-Ig) antibodies to stimulate B cell proliferation (1-4), and to stimulate B cell differentiation in the presence of T cell derived-lymphokines (5-8), has simplified investigations into the mechanisms of B cell growth and maturation that are dependent on the cross-linking of surface Ig (sIg). It is only the ontogenetically late appearing Lyb-5+ murine splenic B cells, however, that proliferate in response to anti-Ig antibodies, whereas B cells of the Lyb-5- phenotype obtained from neonatal mice or from mice with the xid immune defect cannot be induced to proliferate in response to this stimulus (1, 9, 10). Thus, the analysis of B lymphocyte physiology of the Lyb-5- B cell population has been hampered by the unavailability of B cell stimulants that mimic an antigen-induced sIg cross-linking event that leads to B cell activation. The inability of soluble anti-Ig antibodies to induce the proliferation of Lyb-5- cells has been particularly difficult to explain because these cells can be induced to increase in size (11) and to show an increase in their expression of surface Ia (sIa) after exposure to anti-Ig (12). Apparently, therefore, these cells are not entirely refractory to this stimulus but are simply unable to progress to the latter stages of cell activation. In view of our observations that the cells of CBA/N mice cannot respond to soluble trinitrophenyl-(TNP) dextran or TNP-polyacrylamide (13) but can respond to insolubilized forms of these antigens, we evaluated their ability to respond to insolubilized anti-Ig. In this paper we report that B cells from CBA/N mice can be stimulated to proliferate in response to anti-Ig conjugated to Sepharose beads, but in contrast to normal B cells they need to be stimulated with beads expressing a high-epitope density of anti-Ig antibodies.

Increased expression of I-region-associated antigen (Ia) on B cells after cross-linking of surface immunoglobulin.

Both surface Ig (sIg) surface Ia (sIa) have been shown to have important roles in B lymphocyte activation. In order to investigate a possible relationship between these molecules, we studied the effects of cross-linking of sIg on the expression of sIa, as measured by fluorescence-activated cell sorter analysis of lymphoid cells stained with conventional anti-Ia anti-serum or with fluorescein-labeled anti-Ia antibodies. Exposure of cells for 24 hr in vitro to anti-delta, anti-mu, anti-kappa antibodies, or their F(ab')2 fragments induced a very dramatic increase in expression of sIa. Similarly, i.v. injection of anti-delta antibodies into adult mice induced a 2- to 3-fold increase in expression of B cell sIa on spleen, lymph node, and Peyer's patch lymphocytes. There was no increase under these conditions in expression of other B lymphocyte surface antigens, including H-2, 4B9, and 17C9. Furthermore, exposure of B lymphocytes to antibodies directed to B lymphocyte surface antigens other than sIg did not result in an increase in expression of sIa. The anti-Ig-induced increase in sIa expression appeared to be T independent, required cellular protein synthesis, and required more time to occur than did the cross-linking and removal of sIg. This increase in expression of sIa did not occur on B lymphocytes obtained from mice younger than 3 wk old. This increase in expression of sIa may reflect a proximal event in B lymphocyte activation that occurs after cross-linking of sIg by antigen and that may enhance subsequent cellular interactions involving B lymphocytes.