Deoxyadenosine modulates human suppressor T cell function and B cell differentiation stimulated by Staphylococcus aureus protein A

Adenosine deaminase (ADA) deficiency and the resultant accumulation of deoxyadenosine (AdR) are associated with profound T cell dysfunction and variable B cell dysfunction in vivo. We examined the effects of AdR on the in vitro function of normal human peripheral blood B and T lymphocytes whose ADA activity was inhibited by 2'-deoxycoformycin. We found that OKT8+ T cell-mediated suppression of SPA-induced Ig production was markedly reduced by concentrations of AdR (3 to 10 microM) that did not affect helper T cell function. Because the lectin-induced proliferative responses of OKT8+ T cells and OKT8- T cells were equally susceptible to AdR, modulation of in vitro immune responses by low-dose AdR probably reflected different proliferative requirements for the expression of T cell helper or suppressor functions. Although low doses of AdR did not inhibit Ig production in SPA-stimulated cultures, we found that T cell-dependent, SPA-stimulated B cell proliferation was blocked by 3 to 10 microM AdR. Therefore, it appeared that B cell proliferation was not required for the induction of Ig synthesis in this system. Higher doses (30 to 100 microM) of AdR did block the induction of Ig synthesis, presumably by interfering with T-helper functions via a mechanism other than inhibition of proliferation and/or by inhibiting B cell differentiation events.     

Production of human suppressor T cell hybridomas

To study human T cell suppression of immunoglobulin (Ig) synthesis with homogeneous populations of immunoregulatory cells, human suppressor T cell hybridomas were prepared by somatic cell fusion of concanavalin A-activated peripheral blood T cells with hypoxanthine-guanine phosphoribosyltransferase-(HGPRT, EC 2.4.2.8) deficient human leukemic CEM T cells. After selection in hypoxanthine-aminopterin-thymidine (HAT) medium and cloning by limiting cell dilution, two human T cell hybridomas were identified that produced 60 to 80% suppression of in vitro polyclonal immunoglobulin production when cocultured with pokeweed mitogen- (PWM) stimulated peripheral blood lymphocytes. Further, one of the suppressor T cell hybridomas constitutively secreted a soluble suppressor factor(s) (TsF) of m.w. 70,000 to 85,000 daltons, which produced reversible noncytotoxic inhibition of lectin-activated B cell Ig production. In contrast, this TsF did not inhibit lectin- or antigen-induced T cell proliferation, nor did it interfere with the generation or effector function of cytotoxic T cells. Additional studies indicated that this Tsf acts directly on B cells or monocytes rather than indirectly modulating the activity of immunoregulatory T cells. In summary, these studies suggest that techniques of somatic cell fusion may provide a valuable approach to further study human immunoregulatory cell-cell interactions as well as provide a source of sufficient quantities of important lymphokines for further purification and characterization.     

Regulation of B cell maturation and differentiation. I. Suppression of pokeweed mitogen-induced B cell differentiation by tumor necrosis factor (TNF)

Growth and differentiation of B cells into Ig-secreting plasma cells is regulated by both T cells and macrophages and/or their secreted factors. Although the regulatory role of various cell-derived factors has been examined, the involvement of the macrophage-derived factor, TNF, in human B cell growth and differentiation has not yet been investigated. In the present study we examine the role of rTNF in polyclonal B cell response of human PBL induced by PWM. The addition of rTNF at the initiation of the culture resulted in the dose-dependent inhibition of the generation of both IgG and IgM PFC. Inhibition of PFC development followed the same dose response as rTNF-mediated cytotoxicity against a TNF-sensitive tumor target. The mechanism of rTNF-mediated suppression was examined in different experimental systems. Recombinant TNF did not affect the viability or proliferation of either the T cell or B cell subpopulations, suggesting that TNF does not mediate its suppressive effect by cytotoxic mechanisms. Kinetic studies in which rTNF was added at different times after initiation of culture indicated that inhibition can be observed as late as 4 days of culture and suggested that TNF acts at a late phase of the growth and differentiation pathway of B cells. In further studies we examined the cellular level of TNF-mediated suppression. The addition of rTNF to supernatants containing helper factors and enriched B cells resulted in no inhibition, suggesting that TNF does not act at the B cell level. This was confirmed by demonstrating that rTNF does not inhibit spontaneous PFC development by the CESS B cell line. The effect of TNF on T cell subpopulations was examined by using normal or irradiated T cells, which inactivate suppressor cells. Addition of rTNF to B cells combined with either T cell population suppressed both IgG and IgM PFC development, indicating that the target cell for suppression is the T helper cell but not ruling out an effect on macrophages or the T suppressor cells. Combined, the observed results demonstrate that rTNF suppresses PWM-induced B cell differentiation without affecting B cell proliferation. TNF appears to mediate the suppression by acting directly on T helper cells or else by regulating the production of factors controlling T cell activation and lymphokine secretion.     

Human low molecular weight B cell growth factor induces surface IgM+/A- B cells to express and secrete IgA.

The regulation of Ig class expression has been a controversial area of research. It is well established that T cells, and/or their products, influence which Ig isotype is produced during an immune response. In this study the regulation of Ig secretion of activated human IgM+/A- B cells was examined. Human T cell supernatants induced PWM-activated IgM+/A- B cells to switch to IgA secretion. Purification of the lymphokine mediating this effect involved hydroxylapatite, ion exchange, and gel filtration chromatography. The purified lymphokine could induce switch of IgM+/A- B cells, and it was also capable of inducing proliferation of Staphylococcus aureus Cowan 1 strain (SAC)-activated IgM+/A- B cells. SDS-PAGE and isoelectric focusing indicated the protein mediating this activity had a molecular mass of approximately 14 kDa and a pI of 6.8. These results suggested that the observed activity might be due to low m.w. B cell growth factor (LMW-BCGF), a lymphokine which is capable of inducing proliferation of SAC-activated B cells and has a molecular weight and pI value in the range of the purified protein. Indeed, rLMW-BCGF was able to switch IgM+/A- B-cells to IgA expression and secretion as well as induce the proliferation of SAC-activated IgM+/A- B cells. These results demonstrate that LMW-BCGF is capable of inducing PWM-activated IgM+/A- B-cells to switch to IgA possibly by providing a proliferation signal which induces clonal expansion of IgM+/A- B cells, the progeny of which express a range of isotypes including IgA. This study also demonstrates that lymphokine induced isotype switching involves an intermediate stage of B cell development where human B cells coexpress IgM and a downstream isotype on their surface.     

Mechanism of Staphylococcus aureus exotoxin A inhibition of Ig production by human B cells

Staphylococcus enterotoxins and toxic shock syndrome toxin 1 are members of a family of exoproteins that are produced by staphylococci and bind specifically to MHC class II molecules. Upon binding to MHC class II molecules, these exoproteins are potent stimulators of T cell proliferation via interaction with specific TCR V-beta segments of both CD4+ and CD8+ T cells. These exoproteins also directly stimulate monocytes to secrete IL-1 and TNF-alpha. Furthermore, these exoproteins have a profound inhibitory effect on Ig production by PBMC. We examined the effects of Staphylococcus enterotoxin A (SEA) on proliferation and Ig production of highly purified human B cells. Our results demonstrated that the binding of SEA to MHC class II molecules on B cells does not alter their ability to proliferate in response to Staphylococcus aureus Cowan strain I (SAC) or to produce Ig in response to SAC plus rIL-2. In contrast, the anti-DR mAb L243 inhibited both B cell proliferation and Ig production. Unable to determine a direct effect of SEA on B cell function, we investigated whether the capacity of SEA to inhibit SAC-induced Ig production by PBMC was T cell-dependent. Our results demonstrated that in the presence of T cells, under appropriate conditions, SEA can either function as a nominal Ag for stimulation of B cell proliferation and Ig production or induce T cell-mediated suppression of Ig production. SEA-induced Ig production required T cell help, which was dependent on pretreatment of the T cells with irradiation or mitomycin C; Ig production was not induced by SEA in the absence of T cells or in the presence of untreated T cells. Furthermore, SEA inhibited Ig production in SAC-stimulated cultures of autologous B cells and untreated T cells; pretreatment of the T cells with irradiation or mitomycin C abrogated SEA-induced inhibition of Ig production. Thus, T cell suppression of SAC-induced Ig production was dependent on T cell proliferation. Similar results were observed with both SEA and toxic shock syndrome toxin 1.     

Analysis of the mechanisms of T cell-dependent polyclonal activation of human B cells. Induction of human B cell responses by fixed activated T cells.

Coculture of resting human B cells with T cells stimulated with immobilized mAb to the CD3 molecular complex induces polyclonal activation and the production of Ig of all isotypes. The current experiments were carried out to determine the nature of the signals provided to B cells by the anti-CD3-activated T cells. For these experiments, fresh T cells or T cell clones were activated with immobilized mAb to CD3 and then fixed with 1% paraformaldehyde. Upon coculture, the fixed activated T cells or T cell clones induced B cell RNA synthesis and IL-2R expression, but only minimal DNA synthesis and no Ig production. Induction of B cell RNA synthesis by fixed activated T cells was not inhibited by mAb to the alpha-chain of the IL-2R, and was not enhanced by supplementing cultures with IL-2, IL-4, IL-6, or supernatants of mitogen-activated T cells. Upon the addition of IL-2, but not IL-4 or IL-6, to cultures of B cells and fixed activated T cells, sustained proliferation was noted along with the production of Ig. Control fixed T cells or T cell clones did not induce any of these responses. The presence of cycloheximide or cyclosporin A during the activation with anti-CD3 prevented T cells from developing the capacity to provide help for B cells. The use of mAb to a variety of cell surface molecules indicated that several T cell surface molecules including CD11a/CD18, CD44, CD54, and class I MHC molecules are involved in the induction of B cell responses. Among the mAb that inhibited B cell DNA synthesis and/or Ig production, only mAb to CD11a, CD18, or CD54 inhibited initial B cell activation as assessed by RNA synthesis. Even though mAB to CD11a/CD18 inhibited the capacity of fixed activated T cells to induce B cell responses, the finding that fixed activated CD18 deficit clones provided help for B cells indicated that expression of the beta 2 family of integrins by T cells was not necessary. These results indicate that activated T cells acquire the capacity to stimulate B cells polyclonally and induce cytokine responsiveness, proliferation, and Ig production by utilization of a variety of surface molecules. Moreover, these results indicate that the initial activation of the B cell is independent of the metabolic activity of the T cell and the production of cytokines.     

Modulation of IL-2-induced human B cell proliferation in the presence of human 50-kDa B cell growth factor and IL-4

Several human T cell derived factors capable of stimulating human B cells to synthesize DNA have been previously described. One such factor exhibits an apparent m.w. of 50,000 Da and has been termed 50-kDa-B cell growth factor (BCGF). In this report, we show that a human B cell proliferation pathway based on the sequential action of anti-mu antibody, 50-kDa-BCGF and IL-2 is inhibited in the presence of human rIL-4. Although IL-4 itself is capable of triggering B cell DNA synthesis as measured at 72 h, this lymphokine inhibits, in a dose-related manner, the 50-kDa-BCGF driven response of B cells to IL-2 when such proliferation is determined after 144 h. This inhibition takes place at an early step of the B cell activation and does not require the presence of IL-4 during the whole culture period. Such inhibitory activity of IL-4 is specific to the IL-2-induced B cell proliferation because DNA synthesis measured in the presence of semi-purified human 12-kDa-BCGF is not affected by the presence of IL-4. Our results suggest that a particular pathway of human B cell activation leading to the proliferation of these cells in the presence of IL-2 could be either up- or down-modulated by 50-kDa-BCGF and IL-4, respectively.     

Monoclonal antibody against the human peripheral lymph node homing receptor homologue (Leu 8) inhibits B cell differentiation but not B cell proliferation.

Previous studies have shown that a subpopulation of circulating human B cells expresses the Leu 8 peripheral lymph node homing receptor homologue and that these B cells are capable of producing Ig in response to staphylococcus A Cowan I (SAC). In the present study the effect of a signal delivered via the Leu 8 molecule (using anti-Leu 8 mAb) on B cells was examined. Initially, it was shown that immobilized anti-Leu 8 suppressed IgM and IgG secretion of B cells activated by SAC + IL-2 but not that by PWM-prestimulated B cells or B cells stimulated with PWM in the presence of CD4+, Leu 8- T cells (a source of helper cells). It was also shown that anti-Leu 8 did not suppress SAC + IL-2-stimulated B cell proliferation or expression of IL-2R alpha-chain or c-myc mRNA in B cells. The addition of T cells, monocytes, purified IL-2, rIL-1, rIL-6, or human B cell growth factor did not overcome the inhibitory effect of anti-Leu 8 on SAC-stimulated B cell Ig production, and the inhibitory effect of anti-Leu 8 was not blocked by anti-TGF-beta. Finally, inhibition of B cell differentiation occurred even when anti-Leu 8 was added up to 72 hrs after initiation of cell culture. Thus, anti-Leu 8 is unique among inhibitors of B cell function in that it can down-regulate immunoglobulin synthesis without affecting B cell proliferation. These findings suggest that a natural ligand for Leu 8 could affect not only homing of B cells, but also B cell differentiation.     

Effects of interferon-alpha on human B cell responsiveness: biphasic effects in cultures stimulated with Staphylococcus aureus.

Although interferon-alpha (IFN-alpha) has been found to be involved in the immune regulation in vivo, the effects of IFN-alpha on human B cells have not yet been clarified because of conflicting results in the literature. The present study therefore examined the effects of several subtypes of IFN-alpha (natural, alpha 1, alpha 2a, alpha 2b) on B cell responsiveness in detail by comparing different experimental conditions. Highly purified B cells from normal human individuals were cultured with Staphylococcus aureus (SA) + IL-2 or with immobilized anti-CD3-activated T4 cells in the presence or absence of IFN-alpha. IFN-alpha enhanced the immunoglobulin (Ig) production induced by immobilized anti-CD3-activated T4 cells. By contrast, IFN-alpha (5-50,000 IU/ml) suppressed the Ig production induced by SA + IL-2. The suppression by IFN-alpha was dependent on the concentration of SA. The inhibitory effects of IFN-alpha in SA-stimulated cultures were exerted in the first 72 hr of cultures and required the presence of IL-2, whereas IFN-alpha enhanced the maturation of B cells when it was added after 72 hr of cultures. The suppressive effects of IFN-alpha were overcome by addition of immobilized anti-CD3-preactivated T cells that had been treated with mitomycin C, but not by the addition of fresh T cells or soluble factors produced by activated T cells. Of interest, IFN-alpha did not inhibit the expression of IL-2R, but inhibited that of intercellular adhesion molecule-1 (ICAM-1) on B cells after stimulation with SA + IL-2, suggesting that the suppressive effects of IFN-alpha might be related to the regulation of B cell-B cell contacts through ICAM-1. There was no significant difference in effects on B cells among various subtypes of IFN-alpha. These results suggest that the effects of IFN-alpha on human B cell responsiveness may be different depending on the nature of stimulation. Moreover, the data indicate that IFN-alpha enhances the differentiation of activated B cells irrespective of the activation signals.     

Two independent pathways of helper activity provided by a single T cell clone

Data presented in this paper demonstrate the existence of two separate pathways by which a single T cell clone can induce B cell differentiation. With the use of high doses of antigen, a T cell clone can induce a primary antibody response in unprimed B cells. With the use of low doses of antigen, the same T cell clone can induce an immunoglobulin (Ig)G response in primed B cells. The primary response is accompanied by T cell proliferation and lymphokine production (interleukin 2, B cell growth factor, B cell differentiation factor for immunoglobulin M, and B cell differentiation factor for immunoglobulin G). The secondary response does not require proliferation and occurs independently of detectable lymphokine production. Variants of the wild type T cell helper clone have been isolated. One variant can provide help to unprimed B cells when high doses of antigen are used. This variant cannot provide help to primed B cells when low doses of antigen are used, nor can it provide help to CBA/N "xid" B cells at any antigen concentration tested. Additional variants have been isolated that proliferate on antigen-pulsed-presenting cells, but fail to secrete detectable lymphokines and do not induce B cell differentiation. These results suggest that a single T cell helper clone has multiple functional activities that can be independently expressed.     

Suppression of a pokeweed mitogen-stimulated plaque-forming cell response by a human B lymphocyte-derived aggregated IgG-stimulated suppressor factor: suppressive B cell factor (SBF)

The mechanisms whereby formed immune complexes (IC) or immunoglobulin aggregates can suppress further antibody production were explored by culturing normal human peripheral blood mononuclear leukocytes (PBL) with heat-aggregated IgG (HAIgG) and collecting the culture supernatants at 24 hr. These supernatants were found to suppress a pokeweed mitogen (PWM)-induced rheumatoid factor plaque-forming cell (RF-PFC) response in normal individuals. PWM-induced anti-trinitrophenylated sheep red blood cell (TNP-SRBC) PFC were also inhibited by suppressor supernatants from HAIgG-stimulated PBL, suggesting that the polyclonal PFC response was inhibited by a suppressor factor. The suppressor factor inhibited PWM stimulated RF-PFC throughout the culture period, but suppression was maximal at the peak of the RF-PFC response. Suppressor factor was only effective at the initiation of cultures, suggesting that it inhibited early events in the PWM-stimulated RF-PFC response. Molecular weight determination of the suppressor factor by differential membrane fractionation suggested a m.w. range of 30,000 to 50,000, and chromatography on Sephadex G-100 showed a peak activity at an approximate m.w. of 32,000. Studies suggested the factor was not an interferon. Depletion of T lymphocytes by E rosetting and macrophages/monocytes by G-10 adherence did not affect the generation of suppressor factor. Depletion of T lymphocytes (OKT4, OKT8) and NK cells (Leu-11b) by antibody-dependent, complement-mediated cytotoxicity also did not affect the generation of suppressor factor. Depletion of B lymphocytes with OKB7 resulted in the generation of significantly less suppressor factor. Suppression produced by unstimulated purified B lymphocytes was approximately one-half that seen when B lymphocytes were stimulated with HAIgG. Differential membrane fractionation studies suggested that only HAIgG-stimulated B cell cultures contained peak activity in the 30,000 to 50,000 m.w. fraction. Supernatants from unstimulated purified T cells also generated suppression, which was approximately one-half of that seen with HAIgG-stimulated B cells, but no increase in suppressor activity was seen in T cell cultures after incubation with HAIgG. These studies demonstrate that HAIgG is capable of stimulating B lymphocytes to produce a lymphokine, suppressive B cell factor (SBF), which is capable of suppressing a polyclonal PFC response. SBF may be important in feedback control of human immunoglobulin production.     

Inhibition of N-linked oligosaccharide trimming mannosidases blocks human B cell development.

Deoxymannojirimycin (dMM) or swainsonine (SW), which block conversion of high-mannose to complex-type N-linked glycans, strongly inhibited the production of immunoglobulin (Ig) when added to cultures of human lymphocytes together with the polyclonal B cell activators pokeweed mitogen (PWM) and Staphylococcus aureus (SAC). To obtain the inhibitory effect, inhibitor had to be present during the first 36 h of culture. Addition at later timepoints was less effective and showed that neither inhibitor interfered with rate of production or secretion of Ig as such. Viability and proliferation of the lymphocytes, as defined by cell number and rate of DNA synthesis, were not influenced by the presence of dMM or SW, and no changes in the relative number of helper (T4+) or suppressor (T8+) cells were observed. Thus, for normal differentiation of human B lymphocytes into Ig secreting (plasma) cells in response to PWM and SAC, conversion of high-mannose to complex N-linked glycans is essential.     

Human T cell leukemia/lymphoma virus-infected antigen-specific T cell clones: indiscriminant helper function and lymphokine production

The ability of human T cell leukemia/lymphoma virus (HTLV)-I to alter the function of infected T lymphocytes was examined directly by investigating the properties of an antigen-specific T cell clone before and after transformation with HTLV-I. Following infection, the T4 antigen-specific clone manifested a tenfold increase in its surface interleukin 2 (IL 2) receptor (Tac) density and acquired the viral determinants p19, p24, and 4D12 not present in the uninfected clone. Prior to infection, the T cell clone responded to antigen stimulation in the presence of histocompatible antigen-presenting cells with proliferation and secretion of multiple lymphokines, including IL 2, B cell growth factor (BCGF), B cell differentiation factor (BCDF), and interferon-gamma (IFN-gamma). Following infection, the T cell clone both proliferated and produced constitutively three of these lymphokines (BCGF, BCDF, and IFN-gamma) in the absence of accessory cells or antigen. Co-cultivation with any accessory cells regardless of histocompatibility resulted in increased proliferation and lymphokine production. IL 2 production by the HTLV-I-transformed cell, however, could not be detected. Similarly, the uninfected clone was able to provide B cell help for Ig production only when stimulated with both histocompatible cells and antigen. In contrast, the infected cell provided T cell help to B cells in an unregulated manner, independent of antigen or histocompatibility. Thus, functions such as the induction of proliferation, B cell help, and lymphokine production, which are finely regulated in uninfected antigen-specific T cell clones, became indiscriminant after HTLV-I infection.     

Immunoregulatory human T lymphocytes triggered as a consequence of viral infection: clonal analysis of helper, suppressor inducer and suppressor effector cell populations

The regulatory functions of a series of human T cell clones specific for an autologous Epstein-Barr virus transformed B lymphoblastoid cell line were examined. Two T4+ T cell clones, termed AT4II and AT4IV, and one T8+ clone, AT8III, were maintained in culture for greater than or equal to 9 months and were characterized in detail. Both T4+ clones provided helper function for autologous B cell immunoglobulin production when added to unstimulated peripheral blood mononuclear cells. In addition, these same clones produced soluble inducer factors after specific antigenic stimulation. However, when AT4II, AT4IV and their subclones were tested on pokeweed mitogen stimulated peripheral blood mononuclear cells, it was found that AT4IV provided help for immunoglobulin production whereas AT4II cells were strongly suppressive. This suppression by AT4II was indirect and required the presence of fresh, autologous, unirradiated T8+ cells. In contrast, the T8+ AT8III clone markedly inhibited Ig production by autologous B cells in the absence of any additional T8+ cells from peripheral blood and produced a soluble suppressor factor upon specific antigenic triggering. Thus, after stimulation with autologous Epstein-Barr virus transformed cells, at least three discrete regulatory human T cell populations can be defined at the clonal level: helper, inducer of suppression and suppressor effector clones.     

The Ba fragment of complement factor B inhibits human B lymphocyte proliferation

Normal human B lymphocyte function is finely regulated by both positive and negative signals at each stage of activation, proliferation, and differentiation. Activation signals include antigen and surface Ig cross-linking agents such as anti-mu or anti-delta. Signals inducing proliferation include IL-2, high m.w.-B cell growth factor (BCGF), and low m.w.-BCGF. IL-2 as well as IL-6 and other partially characterized B cell differentiation factors can induce terminal differentiation of proliferating B cells into Ig-secreting plasma cells. Various C components have been described to regulate B cell function including Bb that enhances proliferation, C5a that enhances Ig production, and C3a that inhibits Ig production. In our study, we examined the ability of the factor B cleavage fragment Ba to influence human B cell function. Ba did not affect the activation of resting B cells but inhibited the proliferation of activated B cells stimulated with either high m.w.-BCGF or low m.w.-BCGF. The inhibition occurred with doses of Ba as low as 1 microgram/ml (29 nM). Ba was found to bind to activated human B lymphocytes in a saturable manner with an apparent K of approximately 25 nM and an apparent Bmax of 56,000 sites/cell. A peptide made of the carboxy terminal 10 amino acids of Ba (GHGPGEQQKR), was also found to inhibit growth factor induced proliferation of activated B cells but at an ID50 of approximately 5 microM. Finally, Ba was found to inhibit the terminal differentiation of Staphylococcus aweus Cowan-activated B cells stimulated with B cell differentiation factors but not Ig secretion by the partially differentiated EBV-transformed cell line SKW.6. Thus, concentrations of Ba achievable in vivo at sites of active inflammation were found to act on human B lymphocytes by inhibiting their proliferation. This may act to limit the immune response to a specific antigenic challenge.     

Artificial T cell:B cell conjugation. A unique approach to analyze weak cell-cell interactions

An antibody response against a thymic-dependent Ag requires cognate recognition of the Ag by B and T cells. Functional T-B cell (T-B) interaction involves binding of Ag by B cell surface Ig, internalization and processing of Ag, expression of an Ag fragment in the context of Ia, binding of Ag/Ia by the TCR and binding of T cell-derived lymphokines by B cell lymphokine receptors. It is becoming increasingly evident that B and T cell accessory molecules also are involved in T-B interactions. To determine the role of accessory molecules in T-B collaboration, we have designed a system in which T-B interaction was artificially induced in the absence of carrier protein. TNP-modified, turkey gamma-globulin-specific, Th cells were allowed to form conjugates with TNP-specific B cells in the absence of hapten-carrier complex. Both B and T cells were induced to proliferate and B cells partially differentiated into antibody-secreting cells when B cells were cultured with TNP-modified but not unmodified T cells. The activation of B cells by TNP-modified T cells was not MHC restricted but was blocked by anti-Ia antibodies, suggesting a role for Ia distinct from Ag presentation. Furthermore, B cell proliferation was also inhibited by antibodies to L3T4 and LFA-1, suggesting a functional accessory role for these molecules in induction of B cell proliferation/differentiation.     

Membranes from both Th1 and Th2 T cell clones stimulate B cell proliferation and prepare B cells for lymphokine-induced differentiation to secrete Ig.

Plasma membranes from the mitogen-activated mouse Th2 cell clone D10.G4.1 have recently been shown to provide the cell contact-dependent signals necessary for the induction of small B cell proliferation. Together with the Th2-derived lymphokines IL-4 and IL-5, these membranes stimulate production of Ig isotypes identical to those produced when B cells were stimulated by intact Th2 cells. In contrast, Th1 clones are poor inducers of Ig production in vitro. This could be solely due to differences in the lymphokines released by Th1 and Th2 cells or to differences in the cell-cell contact signals delivered by activated Th1 and Th2 cells. We report that membranes from three different activated Th1 clones induced strong Ag-independent proliferation of small dense B cells. The level of B cell proliferation was enhanced approximately fourfold by the addition of lymphokine-containing supernatant from Con A-activated Th2 cells and was unaffected by any of the lymphokine-containing supernatants from Con A-activated Th1 clones. As with D10.G4.1 membranes, Th1 membranes alone induced B cell proliferation but not secretion of Ig. However, addition of supernatant from Con A-activated D10.G41 cells, but not any supernatants from Con A-activated Th1 cells, induced Ig secretion of all isotypes. These effects were shown to not simply result from increased B cell numbers after stimulation with Th2 lymphokines. Thus, Th1 cell clones seem to poorly induce antibody responses entirely because of their lymphokine repertoire and not because of differences or deficiencies in the ability of these cells to deliver cell contact-dependent signals to B cells.     

CD19 regulation of human B cell responses. B cell proliferation and antibody secretion are inhibited or enhanced by ligation of the CD19 surface glycoprotein depending on the stimulating signal used.

The regulation of human B cell proliferation and differentiation by the CD19 surface glycoprotein was investigated. As expected, proliferation induced by costimulation with anti-IgM plus IL-4 or IL-2, or with G28.8 antibody plus IL-4 was inhibited by antibody ligation of CD19. In contrast, proliferation of tonsillar B cells to mitogenic doses of PMA (5 ng/ml) or to EBV were enhanced, and proliferation of B cell lines to BCGF(low) was unaffected. Similarly, specific antibody responses by tonsillar B cells to influenza virus, and Ig secretion by the CESS lymphoblastoid cell line in response to IL-6 were inhibited, whereas polyclonal Ig production in response to EBV was enhanced. These results show that human B cell responses may be inhibited or enhanced by CD19 depending on the stimulating signal used. The difference in response to CD19 ligation did not depend on whether proliferation or differentiation was being measured, or whether stimulation was by surface Ig. In experiments using PMA as a T cell independent mitogen, it was found that ligation of CD19 inhibited proliferation of B cells costimulated with low doses of PMA plus G28.5 (CD40) antibody, but enhanced the response to higher (mitogenic) doses with or without costimulation with G28.5. The change from inhibition to enhancement occurred over a very small increase in PMA dose (0.5-1.0 ng/ml) that corresponded exactly to the lowest dose required for mitogenic activity. Finally, we showed that CD19 ligation inhibited the increase in surface expression of CD23, but not IgM, induced by IL-4, showing that CD19 ligation can have opposed effects on different responses to the same signal. Together our results suggest that CD19 activation of human B cells interacts with other signaling events to enhance or inhibit the subsequent response.     

Effect of interferon-alpha on immunoglobulin synthesis by human B cells

We have investigated the effect of human recombinant interferon-alpha (IFN-alpha) on mitogen-induced immunoglobulin (Ig) production by peripheral blood mononuclear cells from normal individuals. Low concentrations (1 to 100 IU/ml) of IFN-alpha enhanced pokeweed mitogen-stimulated Ig production. In contrast, high concentrations of IFN-alpha (10(5) IU/ml) suppressed pokeweed mitogen-induced Ig production. Irradiation of T cells did not ablate the high dose suppression, indicating that suppression was not due to a radiation-sensitive T cell. Kinetic experiments revealed that IFN-alpha needed to be added to 10 day cultures within the first 72 hr for either enhancement or suppression to be noted. Preincubation of purified B cells with IFN-alpha suppressed Ig production as completely as when unfractionated mononuclear cells were incubated with IFN-alpha. On the other hand, preincubation of T cells or monocytes with IFN-alpha had no effect on subsequent Ig production in reconstituted mononuclear cell cultures. Mitogen-induced proliferation of purified B cells was not affected by IFN-alpha at any concentration, but Ig production by purified B cells stimulated with Staphylococcus aureus Cowan I or anti-mu and B cell differentiation factors responded to IFN-alpha with low concentration enhancement and high concentration suppression. Studies of Ebstein-Barr virus-transformed B cell lines showed that IFN-alpha caused a similar effect on the CESS line as on peripheral blood B cells, with low dose enhancement and high dose suppression of Ig production. Thus one IFN-alpha effect is to modulate Ig production, and this appears to be a direct effect on B cells. Combined with the data in the accompanying paper, the effects of IFN-alpha on B cell function are similar in vivo and in vitro.