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.     

In vivo administration of anti-I-A antibody induces the internalization of B cell surface I-A and I-E without affecting the expression of surface immunoglobulin

Injection of a hybridoma anti-Ia antibody into adult mice results in a dramatic reduction in the expression of B cell sIa without affecting the expression of sIgD or sIgM. This anti-Ia-mediated modulation of B cell sIa occurs within 3 hr and attains it maximum effect within 18 hr after injection of antibody. There is a rapid reexpression of B cell Ia when such sIa- B cells are cultured in vitro. Culture of B cells in vitro with anti-Ia antibody has no discernible effect on the expression of B cell sIa, nor does it prevent the reexpression of sIa on sIa- B cells obtained from anti-Ia-injected mice. Injection of anti-I-A antibody suppresses the expression of both I-A and of I-E, and similarly, injection of anti-I-E suppresses the expression of B cell I-E and I-A antigens. When fluorescein-labeled monoclonal anti-I-A antibody is injected into mice, a significant fraction of B cell sIa can be demonstrated to be internalized by the B cell. The potential immunologic significance of this phenomena of anti-Ia-mediated modulation of B cell sIa is discussed.     

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.     

Antibody-dependent cellular cytotoxicity effector cells lack Ia antigens.

Surface immunoglobulin (sIg)-positive and sIg-negative subpopulations of macrophage-depleted murine splenic lymphocytes were obtained by Sephadex anti-Fab immunoabsorbent fractionation. These lymphocyte subpopulations were analyzed for the presence of Thy 1 and Ia alloantigens and also for Fc receptors by fluorescence microscopy. Concurrently, these lymphocyte subpopulations were studied for effector cell activity in antibody-dependent cellular cytotoxicity (ADCC). Effector cells mediating ADCC were contained in the sIg-negative lymphocyte subpopulation and sIg-positive lymphocytes did not mediate cytotoxicity. The majority of sIg-positive lymphocytes were found to bear Ia antigens and Fc receptors, and these cell surface structures were associated in that treatment of these cells with anti-Ia sera inhibited binding of complexed immunoglobulin to Fc receptors. In contrast, most sIg-negative, Thy 1-negative lymphocytes lacked Ia Antigens, and the Fc receptors detected on such cells were not blocked by anti-Ia sera. In addition, a small subpopulation of sIg-negative, Ia antigen-positive, Fc receptor-positive lymphocytes was found. Elimination of this subpopulation of Ia antigen-positive cells from sIg-negative lymphocytes, by treatment with anti-Ia serum and complement, did not diminish ADCC effector cell activity in the resultant cell population when compared with untreated sIg-negative lymphocytes. Thus, in murine spleen, nonphagocytic mononuclear cells that lack both sIg and Ia antigens were shown to mediate ADCC.     

Sequential expression of immunoglobulin on developing mouse B lymphocytes: a systematic survey that suggests a model for the generation of immunoglobulin isotype diversity.

Paired immunofluorescent staining with antibodies specific for the major isotypes of mouse immunoglobulin was used to study the ontogenetic expression of diversity of cell surface immunoglobulin. The first B lymphocytes to emerge, derived from cytoplasmic IgM+ precursors, express sIgM exclusively. Between birth and 3 days of age separate populations of sIgM+ B lymphocyte acquire a second isotype: sIgD, one of the subclasses of sIgG, or sIgA. At 3 days, all splenic B lymphocytes that bear sIg or sIgA also express sIgM, but virtually none stain for sIgD. By 7 days, a substantial porportion of sIgG+ or sIgA+ lymphocytes in spleen and most of those in lymph node express both sIgM ans sIgD. Anti-mu antibody treatment from birth prevented development of B lymphocytes expressing any isotype. These observations suggest that the immature sIgM+ B lymphocyte is the pivotal cell in the generation of the different sublines of B cells and that sIgD ig or IgA. The frequency of lymphocytes bearing only sIgG or sIgA is higher in old than in young mice, suggesting that sIgD and sIgM may be lost after stimulation by antigens. The occurrence of a nearly identical distribution of sIg isotypes on B lymphocytes from athymic, pathogen-free mice suggests that primary expression of isotype diversity does not require T cells.     

Corticosteroid-induced suppression of murine B cell immune response antigens

The quantitative variation in expression of B cell surface immune response-associated antigens (sIa) that is induced by in vivo i.v. administration of dexamethasone was studied by flow microfluorometry. Injection of 40 micrograms of dexamethasone resulted in a 35 to 40% reduction in the expression of sIa within 3 hr, reached its maximum effect within 6 hr, which on average resulted in 75% suppression of control values of sIa, and by 12 hr after injection began returning towards baseline levels. The suppressive effect of dexamethasone on B cell sIa was dose dependent with respect to the length of time required to reach maximal suppression, as well as with respect to the duration of suppression that was attained. When injections of dexamethasone were repeated on consecutive days, no additional increase in the level of sIa suppression achieved was observed. B cell sIa was also diminished after injection of dexamethasone into athymic nude mice, which suggests that the suppressive effect of dexamethasone on B cell expression of sIa is not a T cell-dependent phenomenon. Taken together, these data suggest that the suppression of B cell sIa by corticosteroids may be a means whereby endogenous or exogenous corticosteroids are able to influence the normal as well as abnormal immunologic state.     

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.     

Interactions between lymphocyte membrane molecules. II. Characterization of an interaction between B lymphocyte surface IgD and Fc IgG receptors that differs from the surface IgM-Fc IgG receptor interaction

The B lymphocyte surface membrane receptors IgD (sigD) and Fc IgG receptors (Fc gamma R) were evaluated for interactions by means of immunofluorescence. Ligand-(F(ab')2 anti-delta) induced capping of sIgD resulted in co-capping of Fc gamma R if the latter were occupied during the capping process by soluble antigen-antibody complexes (which themselves provided insufficient cross-linking to result in capping), but not if the Fc gamma R were occupied by monomeric IgG or unoccupied. Capping of Fc gamma R by highly cross-linked complexes did not cause co-capping of sIgD occupied by monomeric F(ab') anti-delta. The interaction between sIgD and Fc gamma R was specific in that cross-reactions between ligands were excluded and ligand-induced capping of sIgD did not cause co-capping of ligand-occupied sIgM or I-A antigens. The sIgD-Fc gamma R interaction occurred on only approximately 60% of B lymphocytes, and this B cell subpopulation did not correlate with other B cell subpopulations (CBA/N strain B cells and B cells bearing either large or small amounts of sIgD). The sIgD-Fc gamma R interaction differed from the sIgM-Fc gamma R interaction in that co-redistribution of the Fc gamma R was occupied by monomeric IgG and involved nearly all B lymphocytes. The qualitative and quantitative differences between the sIgD-Fc gamma R and sIgM-Fc gamma R interactions suggest a mechanism whereby the two antigen receptors could provide different signals to the B lymphocyte.     

Lymphocyte mechanical response triggered by cross-linking surface receptors

Using a recently developed method (Petersen, N. O., W. B. McConnaughey, and E. L. Elson, 1982, Proc. Natl. Acad. Sci. USA., 79:5327-5331), we have measured changes in the deformability of lymphocytes triggered by cross-linking cell surface proteins. Our study was motivated by two previously demonstrated phenomena: the redistribution ("capping") of cross-linked surface immunoglobulin (sIg) on B lymphocytes and the inhibition of capping and lateral diffusion ("anchorage modulation") of sIg by the tetravalent lectin Concanavalin A (Con A). Both capping and anchorage modulation are initiated by cross-linking cell surface proteins and both require participation of the cytoskeleton. We have shown that the resistance of lymphocytes to deformation strongly increased when sIg or Con A acceptors were cross-linked. We have measured changes in deformability in terms of an empirical "stiffness" parameter, defined as the rate at which the force of cellular compression increases with the extent of compression. For untreated cells the stiffness was approximately 0.15 mdyn/micron; for cells treated with antibodies against sIg or with Con A the stiffness increased to approximately 0.6 or 0.4 mdyn/micron, respectively. The stiffness decreased after completion of the capping of sIg. The increases in stiffness could be reversed to various extents by cytochalasin D and by colchicine. The need for cross-linking was demonstrated by the failure both of monovalent Fab' fragments of the antibodies against sIg and of succinylated Con A (a poor cross-linker) to cause an increase in stiffness. We conclude that capping and anchorage modulation involve changes in the lymphocyte cytoskeleton and possibly other cytoplasmic properties, which increase the cellular viscoelastic resistance to deformation. Similar increases in cell stiffness could be produced by exposing cells to hypertonic medium, azide ions, and to a calcium ionophore in the presence of calcium ions. These results shed new light on the capabilities of the lymphocyte cytoskeleton and its role in capping and anchorage modulation. They also demonstrate that measurements of cellular deformability can characterize changes in cytoskeletal functions initiated by signals originating at the cell surface.     

Corticosteroid induction of Ig+Ia- B cells in vitro is mediated via interaction with the glucocorticoid cytoplasmic receptor

Flow microfluorometry was used to examine the effect of dexamethasone on the expression of surface Ia (sIa) on resting and activated murine B cells. Although dexamethasone resulted in a 50% reduction in sIa expression 12 h after injection, it was significantly less suppressive when injected together with B cell activators. In vitro dexamethasone, but not other related steroid hormones, induced a population of cells that were sIg+sIa-. A 20% reduction in the expression of sIa was noted by 4 h of culture with 10 nM dexamethasone, but maximal inhibition of 70% was not reached until 12 h of culture, and this degree of suppression persisted as long as dexamethasone remained in culture. When the dexamethasone was washed out after 8 h of culture, the maximal reduction was still noted at 12 h, but by 24 h there was re-expression of sIa toward base line levels, indicating it did not induce irreversible lethal alterations in the B cell. The inhibition of sIa expression correlated with a specific reduction in the quantity of messenger RNA for sIa as measured by Northern blot analysis, indicating that this is mediated at least in part by suppression of the steady state levels of Ia mRNA. The corticosteroid receptor antagonist RU486 was able to reverse the suppressive effects of dexamethasone on sIa expression, thus demonstrating that its effect is mediated specifically by binding to its intracellular receptor. Furthermore, when protein synthesis was inhibited during the short period of time that cells were preincubated with dexamethasone, minimal suppression of Ia expression was noted, suggesting that the dexamethasone may be stimulating a protein that has suppressive effects on MHC class II expression. The suppressive effects of dexamethasone in vitro were substantially reduced when B cells were simultaneously activated by stimuli that increase the expression of sIa. These data indicate that the suppressive effects of corticosteroids on immune response Ag are corticosteroid specific; are greater in resting than in activated B cells; are induced via the classical steroid mechanism of action, which is receptor mediated; and may result from the induction of an inhibitory protein that suppresses Ia mRNA.     

Tyrosine phosphorylation of CD19 in pre-B and mature B cells.

Cross-linking of B cell surface immunoglobulins (sIg) results in activation of mature B cells and stimulates a molecular signaling mechanism for antigen-specific B cell expansion and differentiation. This signaling pathway is dependent on tyrosine (Tyr) phosphorylation and results in the activation of sIg-associated src family kinases and p72SYK. Rapid Tyr phosphorylation occurs on multiple protein substrates. Here we show that activation of B cells by cross-linking sIg results in an increase in Tyr phosphorylation of the lineage-restricted B cell surface antigen CD19, and show that it is a major substrate of activated Tyr kinase following sIg stimulation. Lower levels of constitutive CD19 Tyr phosphorylation occurred in most sIg+ mature B cell lines examined and in normal dense tonsillar B cells. We also find that when CD19 is Tyr-phosphorylated it becomes competent to interact with SH2 domains suggesting a mechanism whereby, following B cell activation, CD19 could be linked to intracellular signaling pathways. In sIg- pre-B cell lines, CD19 was expressed but was not constitutively phosphorylated on tyrosine. Upon CD19 cross-linking, Tyr phosphorylation of CD19 was induced in sIg- pre-B cell lines. CD19 cross-linking also directly induced Tyr phosphorylation of CD19 and other substrates in mature B cells. The ability of CD19 to signal in the absence of sIg expression may provide important stimulation in pre-B cell development.     

In vitro and in vivo B lymphocyte-activating properties of monoclonal anti-delta antibodies. I. Determinants of B lymphocyte-activating properties

To appreciate better the mechanisms by which B lymphocytes are activated by anti-Ig antibodies, we characterized seven monoclonal mouse allo-antibodies to IgD of the a allotype for their isotypes, fine specificities, IgD-cross-linking abilities, avidities, and abilities to activate B cells in vitro and in vivo. Three of the monoclonal antibodies tested bound to the Fc fragment of IgD with relatively high avidity and were effective at cross-linking IgD, since they precipitated soluble IgD and rapidly capped B cell membrane IgD. These were the only antibodies tested that induced B cell DNA synthesis in vitro and were the most effective antibodies at inducing in vivo increases in B cell size and DNA synthesis and in vitro and in vivo increases in B cell surface Ia expression. Two antibodies bound to the Fd fragment of IgD with relatively high avidity but could not rapidly cap cell membrane IgD or precipitate soluble IgD even in the presence of 2% polyethylene glycol. These high-avidity, poorly cross-linking antibodies were unable to stimulate B cell DNA synthesis in vitro and were much less effective than the first group of anti-delta antibodies at stimulating in vivo increases in B cell DNA synthesis, size, or surface Ia expression or in vitro increases in surface Ia expression. One antibody, which bound to the Fc fragment of IgD with an intermediate avidity, was unable to rapidly cap B cell membrane IgD or precipitate soluble IgD in saline, but could precipitate soluble IgD in the presence of 2% polyethylene glycol. This antibody failed to induce B cell DNA synthesis in vitro and was as effective as the higher-avidity, poorly cross-linking antibodies at stimulating increases in B cell size, surface Ia expression, and DNA synthesis in vivo, and surface Ia expression in vitro. One antibody, which bound to the Fd fragment of IgD with low avidity and was unable to precipitate soluble IgD or to cap cell membrane IgD, had little ability to activate B cells by any of the parameters studied. Each of the monoclonal anti-delta antibodies, regardless of isotype or fine specificity, when bound to agarose to increase its ability to cross-link IgD, was mitogenic for B cells in vitro. None of the monoclonal antibodies to IgD of the a allotype stimulated B cells from b allotype mice to increase their size, surface Ia expression, or synthesis of DNA in vitro or in vivo.(ABSTRACT TRUNCATED AT 400 WORDS)     

Comparison of antigens recognized by xenogeneic and allogeneic anti-Ia antibodies: Evidence for two classes of Ia antigens

Previously published data suggest that both xenogeneic and allogeneic anti-Ia sera can recognize carbohydrate-defined antigenic determinants on the surface of lymphocytes. There is also evidence, based on studies with allogeneic anti-Ia sera, that protein-defined Ia antigens exist. In this paper the relationship between these two types of Ia antigen was examined. It was found that in capping studies, the allogeneic anti-Ia serum could cap off the antigens recognized by the xenogeneic antiserum, whereas the xenogeneic antibodies could, at least partially, clear the surface of lymphocytes of Ia antigens detected by the allogeneic antibodies. On the other hand, when immunoprecipitates of radioiodinated cell-surface antigens were examined by SDS-polyacrylamide-gel electrophoresis, it was found that the xenogeneic anti-Ia serum did not immunoprecipitate any labeled material. In contrast, the allogeneic antiserum immunoprecipitated a labeled molecule which corresponded to the protein-defined Ia antigen described by others. Finally, it was shown that serum Ia antigens could be bound by either mouse or rabbit anti-Ia antibody, and this binding blocked any further reactivity with either serum. These results were interpreted as suggesting that two separate classes of Ia antigen molecule appear on the lymphocyte surface-one class has carbohydrate-defined antigenic specificities and the other has protein-defined determinants. Allogeneic anti-Ia sera contain antibodies against both these antigenic systems, whereas xenogeneic sera recognize only the carbohydratedefined series. The genetic implications of this interpretation are discussed.     

Regulation of immune responses via genetically restricted cellular interactions. II. I-region-restricted cooperation between idiotypic and anti-idiotypic B lymphocytes

Immunization of BALB/c mice with MOPC-104E myeloma protein induced idiotype-specific enhancing cells which acted on anti-dextran antibody-producing cells. The enhancing cells have surface phenotypes of B cells. Using BALB/c H-2 congenic strains, it was found that the cooperation between anti-idiotypic-enhancing B lymphocytes and dextran-primed B lymphocytes was controlled by major histocompatibility gene complex. Here we have described the loci which restrict the successful cooperation between B lymphocytes, wherein it was revealed that the interaction was restricted to the I-A and I-E subregions in H-2k haplotype and the I-A subregion in H-2b haplotype. Utilizing several monoclonal antibodies specific for Ia antigens, it was revealed that the enhancing B lymphocyte activity was completely inhibited by the pretreatment of antibody-producing B cells with anti-Ia.7 in H-2d haplotype as well as H-2k, and with anti-I-A antibody in H-2b haplotype. The results suggest that the anti-idiotypic B-lymphocyte response to the self idiotype is under control of H-linked immune response (Ir) gene.     

Production of BSF-1 during an in vivo, T-dependent immune response

BSF-1, a cytokine produced by some T lymphocyte tumors, has been shown to act with anti-Ig antibodies to stimulate B lymphocyte proliferation, to independently induce resting B lymphocytes to increase their expression of surface Ia antigen, and to induce some activated B lymphocytes to differentiate into IgG1- or IgE-secreting cells. To determine whether BSF-1 might be secreted by normal lymphoid cells in the course of a physiologic immune response, BALB/c mice were injected with an affinity-purified goat antibody to mouse IgD (GaM delta), which induces the generation of a large, polyclonal T-dependent IgG1 response; 4-hr culture supernatants of spleen cells from these mice were prepared, and these supernatants were assayed for BSF-1 activity by analyzing their ability to induce BALB/c nu/nu spleen cells to increase their expression of cell surface Ia in vitro. Culture supernatants of unfractionated spleen cells removed from mice 4 to 8 days after GaM delta antibody injection induced substantial increases in B lymphocyte surface Ia expression; these increases were blocked by a monoclonal anti-BSF-1 antibody. Culture supernatants of spleen cells from untreated BALB/c mice or from untreated or GaM delta antibody-treated BALB/c nu/nu mice induced small to moderate increases in B cell surface Ia expression, and GaM delta antibody itself induced large increases in B cell surface Ia expression; however, these increases were not significantly blocked by a monoclonal anti-BSF-1 antibody. A culture supernatant of T cell-enriched spleen cells from untreated mice induced small increases in B cell surface Ia expression that were inhibited by anti-BSF-1 antibody, as was the larger increase in B cell Ia expression induced by a culture supernatant of T cell-enriched spleen cells from mice sacrificed 3 days after GaM delta injection. On the other hand, T cell-depleted spleen cells from BALB/c mice injected with GaM delta antibody 7 days before sacrifice failed to generate culture supernatants with BSF-1 activity. Supernatants prepared from spleen cells taken from untreated mice or mice treated with GaM delta antibody 1 to 3 days before sacrifice did not block the ability of purified BSF-1 to induce an increase in B cell surface Ia expression, and thus did not contain inhibitors of BSF-1 activity.(ABSTRACT TRUNCATED AT 400 WORDS)     

Size-dependent B lymphocyte subpopulations: relationship of cell volume to surface phenotype, cell cycle, proliferative response, and requirements for antibody production to TNP-Ficoll and TNP-BA

Murine splenic B lymphocytes were separated into size-dependent subpopulations by using counterflow centrifugation. Spleen cells were rigorously depleted of T lymphocytes to yield a population of cells that were greater than 90% surface immunoglobulin (Ig)-positive and that had a mean cell volume of 136.6 +/- 3.3 microns. From this population, five fractions of cells were obtained with mean cell volumes that ranged from 115.8 +/- 3.7 microns in fraction 1 to 168.0 +/- 6 microns in fraction 5. The cells in these five subpopulations were characterized by analysis on a fluorescence-activated cell sorter after staining with acridine orange to evaluate RNA and DNA content, and with fluorescein-conjugated anti-mu, anti-delta, and anti-Ia antibodies to evaluate their surface membrane phenotypes. DNA analysis revealed that virtually all of the cells in fractions 1 to 4 had 2 N DNA. Between 7 and 21% of fraction 5 cells were either in S-phase or contained 4 N DNA. In contrast, RNA content increased through the fractions, suggesting a transition from G0 to G1 in the subpopulations with increasing B cell size. As another measure of cell activation seen with increasing cell size, we observed a progressive increase in the expression of surface Ia and a decrease in the expression of surface IgD. In the absence of in vitro stimulation, the larger cells showed significantly higher levels of thymidine incorporation. When polyclonal B cell activators such as LPS or anti-Ig antibody were added, peak proliferative responses were similar in all of the fractions, but the time necessary to achieve a maximal response was shorter for the larger-sized cell subpopulations than it was for the smaller-sized cell subpopulations. Unprimed, size-dependent B lymphocyte subpopulations exhibited spontaneous or "background" antibody formation that occurred primarily in the subpopulations containing the largest cells. T cell factors present in EL4 supernatant enhanced the efficiency of in vitro differentiation of these same subpopulations. When cultured in the absence of T cell help, the thymus-independent type 1 (TI-1) antigen TNP-Brucella abortus (TNP-BA) or the thymus-independent type 2 (TI-2) antigen TNP-Ficoll induced the largest anti-TNP plaque-forming cell (PFC) responses in the fractions containing intermediate-sized cells, suggesting that in vitro, antigen-specific responses came primarily from B cells that have been influenced in vivo to leave their small resting state. The subpopulations containing the smallest size B cells required the presence of both a TI antigen and EL4 supernatant for efficient differentiation.(ABSTRACT TRUNCATED AT 400 WORDS)     

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.     

Induction of murine B cell proliferation by insolubilized anti-immunoglobulins

This study demonstrates that intact antibodies specific for mu, delta, or light chains when coupled to Sepharose are effective in delivering proliferative signals to B cells. Furthermore, using Sepharose-coupled anti-delta antibodies, we have shown that hybridoma anti-delta (that is not active as soluble protein) is as effective as rabbit anti-delta in activating murine B cells. However, antibodies directed against two other surface molecules, I-A and H-2K, were not mitogenic. Thus, sIgM and sIgD are comparable in their ability to transmit a proliferative signal to the B cell and sIg seems to play a unique role in this regard.     

Autologous B lymphoblastoid cell lines and long-term cultured T cells as stimulators in the mixed lymphocyte reaction: analysis of the role of HLA class II antigens as stimulatory molecules

Human activated T cells, long-term cultured in the presence of interleukin 2 (IL 2), were compared with autologous Epstein Barr virus-transformed B lymphoblastoid cell lines for expression of human leukocyte (HLA)-HLA-DR and -DQ antigens and for ability to induce proliferative responses in autologous and allogeneic lymphocytes. Immunofluorescence analysis performed with a panel of monoclonal antibodies (mAb) specific for HLA-DR or -DQ antigens did not reveal any significant difference in the expression of HLA-DR antigens but revealed reduced expression of HLA-DQ antigens on two out of four T cell lines tested. No obvious difference could be detected in the two-dimensional gel electrophoretic profile of HLA-DR and -DQ beta-chains synthesized by the autologous pairs of B and T cell lines. In contrast with previous reports, the IL 2-dependent cell lines consistently induced alloproliferative responses in standard 6-day mixed lymphocyte cultures; however, these responses were severalfold lower than those elicited by the autologous B lymphoid lines. Both anti-HLA-DR and anti-HLA-DQ mAb blocked the proliferative responses induced by the B cell lines but did not affect those generated by the T cell lines, suggesting that the latter cells induce T lymphocyte activation via a mechanism independent of HLA-DR or -DQ antigen expression on their surface. Addition of IL 2 to the mixed cultures with B cell lines as stimulators did not affect the outcome of the proliferative responses but partially or completely reversed the blocking activity of the mAb. In contrast, IL 2 significantly enhanced the alloproliferation induced by the T lymphoblastoid cell lines, and the anti-HLA class II mAb partially antagonized this effect. Taken together, these data suggest that unlike the HLA-DR and -DQ gene products on B cells, those on IL 2-dependent long-term cultured T cells do not play a direct or primary stimulatory role in the mixed lymphocyte reaction; the reduced levels of alloproliferation induced by the T cell lines are, at least in part, due to a defective production of endogenous IL 2 by the responder lymphocytes rather than to a defective expression of IL 2 receptors by the alloproliferative T cell subset; and the anti-HLA class II mAb in these cultures act only at the responder cell level, since they can efficiently block the enhancement of T cell proliferation triggered by exogenous IL 2, but not the proliferative responses induced by T cell lines in standard conditions.