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.     

Regulation of antigen-presentation-I. IFN-gamma induces antigen-presenting properties on B cells

B cells require activation to efficiently present Ag to T cells. In agreement with this earlier observation we show that live, mitomycin C-treated B cells, but not B cells fixed in paraformaldehyde, stimulated the growth of allogeneic T cells in the primary MLR. However, if B cells were cultured with anti-Ig antibodies and IFN-gamma before fixation they acquired excellent T cell stimulatory activity. Neither reagent alone conferred this novel co-stimulatory function on the B cell surface. The activity induced by both stimuli was not attributed to an increase expression of class II-MHC molecules or IL-1. IL-2 or IL-4, in combination with anti-Ig, also induced B cell stimulatory activity, but were less effective than IFN-gamma. TNF failed to stimulate B cells, but synergized with IFN-gamma in the induction of this activity. These studies therefore demonstrate an important role for lymphokines in modulating B cell Ag-presenting activity as well as the acquisition by B cells of a novel co-stimulatory surface activity.     

Processed antigen binds to newly synthesized MHC class II molecules in antigen-specific B lymphocytes

We describe the direct detection of radiolabeled antigen fragments bound to class II MHC molecules following immunoglobulin-mediated endocytosis and processing of native antigen in B lymphoblastoid cells. Tris-Tricine SDS gels revealed six distinct iodinated processing products that could be detected on class II MHC 1 hr after antigen endocytosis and persisted for at least 20 hr. These physiological processed antigen-class II complexes were remarkably stable, as judged by the fact that class II alpha beta dimers, which remain associated in SDS, became labeled with the same set of processed peptides. Using a lectin-binding assay, we show that these physiological processing products bind to the newly maturing population of MHC molecules rather than binding to the preexisting cell surface population; in contrast, an exogenous peptide binds predominantly to the latter population. A direct T cell-independent assay for processed peptide-MHC complex formation should facilitate additional studies on the exogenous antigen processing pathway.     

Antigen presentation by hapten-specific B lymphocytes. IV. Comparative ability of B cells to present specific antigen and anti-immunoglobulin antibody

The ability of trinitrophenyl (TNP)-binding murine B lymphocytes to present native rabbit IgG (RGG), TNP-modified RGG, and rabbit anti-mouse Ig (RAMG) to an Ia-restricted, RGG-specific helper/inducer T cell clone was compared. By three independent assays (lymphokine secretion, T cell proliferation, and B cell differentiation), TNP-RGG was presented at 10(2)- to 10(3)-fold lower concentrations than RGG, and RAMG at 10(2)- to 10(3)-fold lower concentrations than TNP-RGG. The available data suggest that the efficiency of antigen presentation is dependent primarily on the avidity of binding of a ligand to B cell surface Ig and/or the extent of subsequent endocytosis (modulation). Despite the observed quantitative differences between anti-Ig (RAMG) and specific antigen (TNP-RGG), these results demonstrate that qualitatively both are essentially similar in their ability to mediate specific T-B interactions. Thus, anti-Ig antibodies are valid models for analyzing cognate interactions between antigen-specific B and helper T lymphocytes.     

Characterization of antigen processing and presentation by resting B lymphocytes

The production of antibody to a thymus-dependent Ag requires cooperation between the B cell and an Ag-specific Th cell. MHC restriction of this interaction implies that the Th cell recognizes Ag on the B cell surface in the context of MHC molecules and that the Ag-specific B cell gets help by acting as an APC for the Th cell. However, a number of studies have suggested that normal resting B cells are ineffective as APC, implying that the B cell must leave the resting state before it can interact specifically with a Th cell. Other studies, including our own with rabbit globulin-specific mouse T cell lines and hybridomas, show that certain T cell lines can be efficiently stimulated by normal resting B cells. One possible explanation for the above contradiction is that our B cells have become activated before presentation. Here we show that presentation by size-selected small B cells is not the result of nonspecific activation signals generated by the T cells or components of the medium. Also, although LPS activation does increase the efficiency of presentation by small B cells, use of large cells in place of small cells or preincubation of resting B cells with mitogenic doses of anti-Ig does not. Another possibility that we considered was that small B cells are unable to process Ag and that we had selected T cell lines that were capable of recognizing native Ag on the B cell surface. In the majority of cases, experiments with B cell lines and macrophages have shown that Ag presentation requires Ag processing, a sequence of events that includes internalization of Ag into an acid compartment, denaturation or digestion of Ag into fragments, and its return to the cell surface in the context of class II MHC molecules. The experiments reported here show that our T cell lines require an Ag processing step and that small resting B cells, like other APC, process Ag before presenting it to T cells. Specifically, we show that an incubation of 2 to 4 h is required after the Ag pulse before Ag presentation becomes resistant to irradiation. Shortly after the pulse, the Ag enters a pronase-resistant compartment. Although efficient Ag presentation requires initial binding to membrane Ig, Ag is no longer associated with membrane Ig at the time of presentation and is not presented in its intact form, because removal of membrane Ig by goat anti-Ig blocks presentation before but not after the Ag pulse.     

Receptor-mediated B cell antigen processing. Increased antigenicity of a globular protein covalently coupled to antibodies specific for B cell surface structures

Helper T cell recognition of globular protein antigens requires the intracellular processing of the native molecule by an antigen-presenting cell and subsequent presentation of a peptide fragment, containing the antigenic determinant, on the cell surface where it is recognized by the specific T cell in conjunction with Ia. B lymphocytes can function as antigen-presenting cells and, when antigen is bound by their surface Ig, are greatly enhanced in this capacity. In this report it is demonstrated that pigeon cytochrome c covalently coupled to antibodies directed toward either B cell surface immunoglobulin, class I or class II are effectively processed and presented by B cells to cytochrome c-specific T cells, requiring up to 1000-fold less cytochrome c as compared with cytochrome c alone or cytochrome c coupled to nonspecific immunoglobulin. The potent activity of the cytochrome c-antibody conjugates appears to be due to the ability of B cells to concentrate the antigen when the process becomes receptor mediated rather than to a signal provided to the B cell by the conjugate binding, because cytochrome c was not more effectively presented in the presence of unconjugated antibodies as compared with cytochrome c alone. Furthermore, the binding of the native antigen to B cell surfaces is not alone sufficient for T cell activation, in that the cytochrome c-antibody conjugates require processing and are major histocompatibility complex restricted. The results presented here indicate that surface immunoglobulin is not unique in its ability to facilitate antigen processing and/or presentation and that Ig, class I and class II are capable of transporting the cytochrome c to a cytoplasmic vesicle where proteolysis occurs yielding the required peptide, minimally of 10 amino acids. Cytochrome c coupled to monovalent fragments of anti-Ig-antibodies was nearly as effectively presented as cytochrome c coupled to bivalent antibodies, indicating that phenomena mediated by bivalent binding, such as patching and capping of the surface Ig, were not required for effective antigen presentation. The cytochrome c-antibody conjugates, which allow antigen processing to be initiated by receptor-mediated endocytosis, may provide the necessary tools to unravel the intracellular processes by which protein antigens are processed and presented by B lymphocytes.     

The actin cytoskeleton coordinates the signal transduction and antigen processing functions of the B cell antigen receptor

The B cell antigen receptor （BCR） is the sensor on the B cell surface that surveys foreign molecules （antigen） in our bodies and activates B cells to generate antibody responses upon encountering cognate antigen. The binding of antigen to the BCR induces signaling cascades in the cytoplasm, which provides the first signal for B cell activation. Subsequently, BCRs internalize and target bound antigen to endosomes, where antigen is processed into T cell recognizable forms. T helper cells generate the second activation signal upon binding to antigen presented by B cells. The optimal activation of B cells requires both signals, thereby depending on the coordination of BCR signaling and antigen transport functions. Antigen binding to the BCR also induces rapid remodeling of the cortical actin network of B cells. While being initiated and controlled by BCR signaling, recent studies reveal that this actin remodeling is critical for both the signaling and antigen processing functions of the BCR, indicating a role for actin in coordinating these two pathways. Here we will review previous and recent studies on actin reorganization during BCR activation and BCR- mediated antigen processing, and discuss how actin remodeling translates BCR signaling into rapid antigen uptake and processing while providing positive and negative feedback to BCR signaling.     

B cells activated by lipopolysaccharide,but not by anti-Ig and anti-CD40 antibody,induce anergy in CD8+ T cells: role of TGF-beta 1

B cells recognize Ag through their surface IgRs and present it in the context of MHC class II molecules to CD4(+) T cells. Recent evidence indicates that B cells also present exogenous Ags in the context of MHC class I to CD8(+) T cells and thus may play an important role in the modulation of CTL responses. However, in this regard, conflicting reports are available. One group of studies suggests that the interaction between B cells and CD8(+) T cells leads to the activation of the T cells, whereas other studies propose that it induces T cell tolerance. For discerning this dichotomy, we used B cells that were activated with either LPS or anti-Ig plus anti-CD40 Ab, which mimic the T-independent and T-dependent modes of B cell activation, respectively, to provide accessory signals to resting CD8(+) T cells. Our results show that, in comparison with anti-Ig plus anti-CD40 Ab-activated B cells, the LPS-activated B cells (LPS-B) failed to induce significant levels of proliferation, cytokine secretion, and cytotoxic ability of CD8(+) T cells. This hyporesponsiveness of CD8(+) T cells activated with LPS-B was significantly rescued by anti-TGF-beta1 Ab. Moreover, it was found that such hyporesponsive CD8(+) T cells activated with LPS-B had entered a state of anergy. Furthermore, LPS-B expresses a significantly higher level of TGF-beta1 on the surface, which caused the observed hyporesponsiveness of CD8(+) T cells. Therefore, this study, for the first time, provides a novel mechanism of B cell surface TGF-beta1-mediated hyporesponsiveness leading to anergy of CD8(+) T cells.     

Activation of rat B lymphocytes. I. Characterization of anti-immunoglobulin responses and isotype density of rat B cells

Spleen cells of two rat strains, Lewis and Brown Norway (BN), have been activated by lectins and by antibodies specific for immunoglobulin isotypes embedded in their cell membranes. Optimal concentrations of antibodies specific for mu, gamma, or delta-chains of rat augments in vitro incorporation of 3H-TdR 5 to 18-fold in Lewis B lymphocytes and 1.5 to 4-fold in BN B lymphocytes. In addition, F(ab')2 fragments of anti-Ig reagents induced Lewis splenic B cells but not BN B cells to incorporate 3H-TdR. Responses to LPS and dextran sulfate, B lymphocyte mitogens, measured by radioactive uptake, were five to 10 times greater in Lewis B cell populations than in BN B cell populations. Density of surface Ig isotypes and capping kinetics were similar in the two rat strains, although the percentage of T cells, T cell subsets, B cells, and Ia+ B cells differed in the spleens of these strains of rats. Both T lymphocytes and macrophages were needed in culture to effect an optimal response. IL-2 restored the response in B cell cultures depleted of T cells and macrophages, and enhanced 3H-TdR uptake in whole spleen cells of Lewis but not BN rats. The strain-dependent responsiveness of B cells to specific anti-Ig reagents or B cell mitogens appears to be associated with inherent (genetic) defects in T cells and B cells or defects in T cell to B cell cooperation in BN rats.     

IL-4 (B cell stimulatory factor 1) overcomes Fc gamma receptor-mediated inhibition of mouse B lymphocyte proliferation without affecting inhibition of c-myc mRNA induction

Mouse B cells are stimulated to proliferate by Fab'2 fragments of rabbit anti-mouse Ig antibodies. Proliferation is inhibited, however, in the presence of IgG anti-mouse Ig. We have previously shown that this inhibition is mediated by binding of the IgG anti-Ig to receptors for Fc gamma R on B cells. This report describes conditions under which IgG anti-mu or anti-delta will induce proliferation despite Fc gamma R engagement. Culture supernatants of Con A-stimulated, Il-4-secreting Th cell lines, but not of Il-2-secreting Th cell lines, will co-stimulate with IgG anti-Ig to induce small B cells to incorporate [3H]TdR. This co-mitogenic activity is inhibitable by anti-IL-4 antibodies and can also be induced by Il-4 affinity purified from the T cell supernatants or by supernatants containing rIl-4. B cells precultured with Il-4 for 18 h, while still expressing normal levels of Fc gamma R, also proliferate to IgG anti-Ig. We have previously shown that Fc gamma R-mIg cross-linking will inhibit mIg-dependent increases in c-myc mRNA levels. We investigated whether Il-4 allows B cells to respond to IgG anti-Ig by elevating c-myc. The data show that Il-4 has little effect on c-myc mRNA levels in either IgG or Fab'2 anti-Ig-containing cultures.     

Induction of proliferation and Ig production in human B leukemic cells by anti-immunoglobulins and T cell factors

The proliferation and differentiation of human leukemic B cells (B-CLL cells) with anti-Ig and T cell-derived helper factors are described. Stimulation of B-CLL cells with anti-Ig and T helper factors could induce proliferation as well as differentiation into IgM- and IgG-producing cells. Neither anti-Ig nor T helper factors alone could induce any proliferation and/or differentiation of B-CLL cells. Not only whole molecules of anti-Ig but also F(ab')2 fragments could induce proliferation and differentiation of B-CLL cells in the presence of T helper factors, but monovalent Fab' fragments were not effective. Induction of both IgM and IgG with the same idiotype was confirmed by immunofluorescent and SDS-PAGE analysis. By employing an IL 2-dependent cytotoxic T cell line and a TRF-responsive B cell line, T cell factors were separated into a fraction with IL2 activity but no TRF activity and a fraction with TRF activity but no IL 2 activity by chromatofocusing. Anti-Ig and IL 2 fraction could induce proliferation of B-CLL cells, but TRF fraction was not effective for the induction of proliferation in anti-IG-stimulated cells. For IgM and IgG production, anti-Ig and both IL 2 and TRF fractions were required. Depletion of IL 2 fraction in the first 2 days' culture inhibited Ig production, whereas the absence of TRF fraction in the first 2 days did not show any inhibitory effect on Ig production.     

Activation of human B cell proliferation through surface Bp35 (CD20) polypeptides or immunoglobulin receptors

Human B cells can be activated with monoclonal antibodies (mAb) to surface IgM receptors or mAb to a 35-kilodalton B cell differentiation antigen, Bp35 (CD20). We compared anti-Ig-induced B cell activation with B cell triggering by anti-Bp35. Both anti-Ig- and anti-Bp35-dependent proliferation were augmented by the same co-stimulants, including a partially purified BCGF, recombinant IL 1, TPA, or each other. When anti-Bp35 and anti-Ig were used together to induce proliferation of tonsillar B cells, the strongest response was observed when anti-Bp35 was added 12 to 24 hr before anti-Ig. Anti-Bp35 also was found to act most effectively when added before the BCGF. Blood and tonsillar B cells differed in their proliferative response to anti-Ig or anti-Bp35: unlike dense tonsillar B cells, which consistently proliferated in response to either stimulus, blood B cells from many donors proliferated in response to anti-Ig but not to anti-Bp35 even in the presence of other co-stimuli. Dense tonsillar B cells that proliferate in response to anti-Bp35 appeared to be at a more activated stage than unresponsive blood B cells because they expressed higher levels of HLA class II molecules than blood B cells. Pretreatment of blood B cells with anti-Bp35 converted them to an HLA-DR(bri) phenotype and made them more responsive to anti-Ig-induced proliferation. These results suggest that B cells at different stages of differentiation differ in their response to anti-Bp35 and anti-Ig. The Bp35 surface polypeptide may play an early role in the activation of B cells prior to antigen or other signals.     

B7, a B-cell-restricted antigen that identifies preactivated B cells

After activation with antigen or mitogen, a number of cell surface proteins appear that are not expressed on resting B cells. To date, a number of B lineage restricted and associated activation antigens have been reported that appear at distinct intervals after in vitro activation. In this report, we describe a new B lineage restricted activation antigen (B7) that appears within 24 hr of in vitro stimulation. The expression of B7 antigen, which is detected on a minor subpopulation of B cells isolated from peripheral blood and lymphoid tissues, is strongly induced following stimulation with either anti-immunoglobulin or Epstein-Barr virus. In contrast, B7 was not detected on resting or activated T cells or monocytes. The B7 antigen was expressed on a subset of B cell lines and B cell neoplasms, but was not detected on leukemias and lymphomas of T cell or myeloid origin. B7 was distinguished from other B cell restricted and associated activation antigens by its unique pattern of expression on a variety of hemopoietic cell lines. The biochemical characterization of B7, that it is a single chain protein of 60 kDa, further distinguishes it from other B cell activation antigens. The functional importance of the B7 antigen was demonstrated when splenic B cells were fractionated into the B7+ and B7- populations. The peak of proliferation in response to anti-Ig, appeared earlier within the B7+ population. These studies suggest that B7 antigen identifies a subpopulation of B cells that are preactivated or primed in vivo, and have an accelerated response to subsequent activation via cross-linking of surface Ig.     

Regulation of B cell receptor-mediated MHC class II antigen processing by FcgammaRIIB1

The processing and presentation of Ag by Ag-specific B cells is highly efficient due to the dual function of the B cell Ag receptor (BCR) in both signaling for enhanced processing and endocytosing bound Ag. The BCR for IgG (FcgammaRIIB1) is a potent negative coreceptor of the BCR that blocks Ag-induced B cell proliferation. Here we investigate the influence of the FcgammaRIIB1 on BCR-mediated Ag processing and show that coligating the FcgammaRIIB1 and the BCR negatively regulates both BCR signaling for enhanced Ag processing and BCR-mediated Ag internalization. Treatment of splenic B cells with F(ab')2 anti-Ig significantly enhances APC function compared with the effect of whole anti-Ig; however, whole anti-Ig treatment is effective when binding to the FcgammaRIIB1 was blocked by a FcgammaRII-specific mAb. Processing and presentation of Ag covalently coupled to anti-Ig were significantly decreased compared with Ag coupled to F(ab')2anti-Ig; however, the processing of the two Ag-Ab conjugates was similar in cells that did not express FcgammaRIIB1 and in splenic B cells treated with a FcgammaRII-specific mAb to block Fc binding. Internalization of monovalent Ag by B cells was reduced in the presence of whole anti-Ig as compared with F(ab')2 anti-Ig, but the internalized Ag was correctly targeted to the class II peptide loading compartment. Taken together, these results indicate that the FcgammaRIIB1 is a negative regulator of the BCR-mediated Ag-processing function.     

In vivo obtained antigen presented by germinal center B cells to T cells in vitro

Shortly after secondary immunization germinal center (GC) B cells obtain antigen from follicular dendritic cells (FDC) in the form of immune complexes. This antigen appears to be degraded by the GC B cells and may be processed for presentation to T cells. The present study was undertaken to determine whether GC B cells can process and present antigen obtained from FDC in vivo to appropriate T cells in vitro. GC B cells were isolated from immune mice with the use of Percoll density separation followed by a panning procedure which utilizes the ability of the plant lectin, peanut agglutinin (PNA), to selectively bind to GC B cells. The enriched GC B cells were approximately 80% highly positive for PNA, 97% positive for Ia and surface IgM, but less than 0.01% positive for Thy-1.2 or esterase. In some experiments, this population was further purified to near 100% highly PNA-positive cells with the use of fluoresceinated PNA and a fluorescence-activated cell sorter. Cell sorting analysis indicated that the antigen (125I-labeled ovalbumin (OVA)) was restricted to the highly PNA-positive cell fraction. The capacity of these highly PNA-positive B cells to present antigen was assessed by monitoring interleukin 2 (IL-2) production by the OVA-specific T cell hybridoma, 3DO-54.8. GC B cells obtained from mice 3 wk or more after secondary immunization did not elicit IL-2 production in the absence of added OVA. However, GC B cells isolated as early as 1 day and for over 1 wk after a challenge with OVA, were able to stimulate high levels of IL-2 production, in the absence of adding OVA to the cell cultures. This response was maximal on day 5 and corresponded precisely with the kinetics of the ultrastructural studies which document the uptake of antigen by GC B cells in vivo. The FDC-derived antigen was remarkably immunogenic when compared with exogenous antigen. These findings demonstrated that antigen obtained in vivo by GC B cells could be processed and presented to T cells. In vivo, GC B cells may induce the T cell help needed for the germinal center reaction, generate B memory cells, and help induce the high titers of antibody associated with the secondary antibody response.     

Three classes of signalling molecules on B-cell membranes

The question of whether surface immunoglobulin and Ia molecules have a signalling function in helper T cell-dependent activation of B cells has been evaluated. Two sources of B cells have been used, one a purified population of hapten-binding B cells, the other a B-cell lymphoma, CH12, with known antigen specificity. Evidence is presented that both immunoglobulin and Ia molecules are receptors actively involved in the initial activation of resting B cells. Nevertheless, the requirements for ligand binding to either receptor can be bypassed under appropriate conditions, and the implications of this result for the function of these molecules is discussed. With respect to B-cell Ia, the authors present data that demonstrate two distinct functions of this molecule, one as a restricting element for T-cell activation, the second as a signalling receptor for B-cell excitation. On the CH12 surface, the I-A molecule fulfills the former function, but T-cell interactions with I-A fail to result in B-cell stimulation, suggesting that B-cell Ia may limit helper T cell-B cell interactions. We suggest that the binding of antigen surface immunoglobulin and binding of helper T-cell receptors to the appropriate Ia molecule(s) results in the activation of genes that encode for a third class of membrane B-cell receptors, those that bind B-cell stimulating factors.     

Anergy in immature B lymphocytes. Differential responses to receptor-mediated stimulation and T helper cells

We have compared the responses of purified neonatal and adult B lymphocytes to stimulation by anti-Ig antibodies, which are functional analogues of Ag, and by Th cells. Neonatal B cells are markedly deficient in proliferative responses to anti-Ig antibodies + IL-4 or to anti-Ig conjugated to dextran, both of which induce strong proliferation of adult B cells in the absence of T lymphocytes. Anti-Ig antibodies actually inhibit the functional responses of neonatal B cells, even to polyclonal stimuli such as LPS. However, Th cells induce both proliferation and Ig secretion by neonatal B cells in the presence of Ag that bind to B cell Ig and are subsequently presented by the B cells. Thus, in neonatal B lymphocytes, cross-linking of membrane Ig in the absence of Th cells has a net inhibitory effect, and this inhibition is overcome by T cell help. These results also suggest that unresponsiveness or tolerance to thymus-independent Ag is induced in the B cells themselves, but tolerance to thymus-dependent proteins resides primarily in the T cell compartment.     

The role of immunoglobulin receptors and T cell mediators in B lymphocyte activation. I. B cell activation by anti-immunoglobulin and anti-idiotype reagents

The possibility that the failure of anti-mouse immunoglobulin (Ig) antibody to induce antibody synthesis by B cells might be due to reversible receptor blockade was investigated. Murine spleen cells were cultured for 3 days in the presence of minute quantities of intact of (Fab') fragments of rabbit anti-mouse Ig antibody. Thereafter, the cells were washed and either trypsin treated or not before reculturing for 18 hr. Only cells that had been trypsinized after culturing with either intact or fragments of anti-Ig gave a vigorous polyclonal antibody response. This response was extremely T dependent, since T cells or culture supernatants from Con A-activated T cells were required for the B cell response. Moreover, anti-delta was much more effective than anti-mu in inducing antibody synthesis. Finally, the use of three different anti-idiotypic antisera rather than anti-Ig reagents selectively activated the specific idiotype in each instance. The findings demonstrate that anti-Ig reagents can potentiate the response of B cells to signals delivered by T cells.     

LPS-activated CBA/N mouse B cells respond to anti-Ig and a BSF-1-like factor

Highly purified small splenic CBA/N B cells show little or no proliferative response to LPS, soluble anti-Ig, LPS plus anti-Ig, or anti-Ig plus the B cell stimulatory factor BSF-1. An excellent proliferative response is obtained, however, if CBA/N B cells are cultured concurrently with LPS, anti-Ig, and a supernatant rich in T cell-derived lymphokines. The pertinent T cell-derived CBA/N B cell co-stimulating factor has the same m.w., isoelectric point range, and hydrophobicity as BSF-1, and co-migrates with BSF-1 throughout a two-step biochemical scheme developed for BSF-1 purification. These data therefore suggest that CBA/N B cells respond to a BSF-1-like lymphokine under appropriate activation conditions. In support of this conclusion, separate experiments demonstrated that unstimulated small CBA/N B cells respond to HPLC-purified BSF-1 by increased expression of membrane-bound class II major histocompatibility antigens. Taken together, these findings indicate that small CBA/N B cells express the receptor for a factor resembling BSF-1, and acquire the capacity to proliferate in response to anti-Ig and this BSF-1-like factor when co-stimulated with LPS.     

T helper cell-dependent B cell activation.

Small, resting B lymphocytes are driven into the cell cycle as a consequence of receiving multiple signals from elements found within their local environment. The first of these signals results from the binding of specific antigen to membrane immunoglobulin (mIg) receptors on the B cells. Pursuant to antigen binding, signals are transduced and the B cell commences to endocytose and degrade the antigen. Fragments of the antigen are expressed on the B cell surface in noncovalent association with class II major histocompatibility complex (MHC) molecules. The antigen-class II MHC complex serves as a recognition complex for CD4+ helper T cells (Th). As a consequence of recognition, Th form stable physical conjugates with the B cells. Over an extended period of time the Th and B cells bilaterally signal one another. This interchange of signals results in the growth and differentiation of both cells. This review will discuss the sequence of events that culminate in the growth and differentiation of B lymphocytes to antibody-producing cells.