CD40 ligand-positive CD8+ T cell clones allow B cell growth and differentiation

A fraction of activated CD8⁺ T cells expresses CD40 ligand (CD40L), a molecule that plays a key role in T cell-dependent B cell stimulation. CD8⁺ T cell clones were examined for CD40L expression and for their capacity to allow the growth and differentiation of B cells, upon activation with immobilized anti-CD3. According to CD40L expression, CD8⁺ clones could be grouped into three subsets. CD8⁺ T cell clones expressing high levels of CD40L (≥80% CD40L⁺ cells) were equivalent to CD4⁺ T cell clones with regard to induction of tonsil B cell proliferation and immunoglobulin (Ig) production, provided the combination of interleukin (IL)-2 and IL-10 was added to cultures. CD8⁺ T cell clones, with intermediate levels of CD40L expression (10 to 30% CD40L⁺ cells), also stimulated B cell proliferation and Ig secretion with IL-2 and IL-10. B cell responses induced by these CD8⁺ T cell clones were neutralized by blocking monoclonal antibodies specific for either CD40L or CD40. By contrast, CD40L^?? T cell clones (?5 % CD40L⁺ cells), only induced marginal B cell responses even with IL-2 and IL-10. All three clone types were able to activate B cells as shown by up-regulation of CD25, CD80 and CD86 expression. A neutralizing anti-CD40L antibody indicated that T cell-dependent B cell activation was only partly dependent on CD40-CD40L interaction. These CD40L^?? clones had no inhibitory effects on B cell proliferation induced by CD40L-expressing CD8⁺ T cell clones. Taken together, these results indicate that CD8⁺ T cells can induce B cell growth and differentiation in a CD40L-CD40-dependent fashion.     

Interaction of B cells with activated T cells reduces the threshold for CD40-mediated B cell activation

CD154-CD40 interactions are of central importance for the induction of antibody responses to T-dependent antigens. Since most anti-CD40 mAb are only weak B cell mitogens, it is believed that under physiological conditions, signals through CD40 synergize with those from other receptors on B cells to induce B cell activation. We show here that the interaction of either normal B cells, or those from CBA/N (xid) mice, with CD3-activated primary T cells in whole spleen cell cultures markedly reduces the threshold for B cell activation via CD40. Hence, these pre-activated cells undergo vigorous proliferation when stimulated with either optimal or suboptimal concentrations of weakly mitogenic anti-CD40 mAb, or with soluble CD40 ligand. Blocking experiments indicate that the establishment of this priming effect requires stimulation via CD40 itself, plus T cell-derived IL-2. In support of this concept, only CD3/CD28-pre-activated, but not CD3-pre-activated T cells induce this effect, unless the co-cultures of B cells with the latter T cells are supplemented with IL-2. Although B cells activated in this fashion do express higher levels of CD40 than naive cells, we believe that this is insufficient to explain the observed dramatic effects on their proliferative capacity. Rather we propose that T cell-dependent B cell activation induces fundamental changes in the signalling machinery invoked by ligation of CD40. It is likely that this amplification loop could play an important role during the initiation of antibody responses to T-dependent antigens, when activated CD4 T cells only express low levels of CD154.     

Cleavage of membrane-bound CD40 ligand is not required for inducing B cell proliferation and differentiation

The phycical interaction between the B cell surface molecule CD40 and its ligand, CD40L, is known to be crucial in the development and maintenance of humoral immunity. Recently it has been shown that the CD40L is processed and that its soluble cleavage products are released into the extracellular environment. To study the functions of soluble and membrane-bound human CD40L on human B cells, we generated an uncleavable CD40L cDNA deletion mutant. The activities of transfectants expressing either mutated or wild-type CD40L were then compared on human B cells. Both the soluble and the uncleavable membrane-bound CD40L were able to induce, in conjunction with interleukin-4, B cell proliferation and IgE synthesis. Therefore, membrane-bound and soluble CD40L exhibit the same pattern of activities on B cells and membrane CD40L cleavage is not a prerequisite for its function.     

Identification of two distinct CD5- B cell subsets from human tonsils with different responses to CD40 monoclonal antibody

This study investigated the response of different CD5^? B cell subsets to CD40 monoclonal antibody (mAb) in various combinations with interleukin (IL)-4 or rabbit anti-human μ chain antibody (a-μ-Ab). The different CD5 B cell subsets were isolated from tonsillar B cell suspensions depleted of CD5⁺ B cells and subsequently fractionated on Percoll density gradients. While resting CD5⁺ B cells proliferated and produced IgM molecules in response to a-μ-Ab, IL-4 and CD40 mAb as well as to Staphylococcus aureus Cowan strain I (SAC) and IL-2, resting CD5^? B cells, which were co-purified in the same 60% Percoll fractions, consistently failed to respond. These cells were, however, activated by the stimuli employed, as demonstrated by their capacity to express the surface activation markers CD69, CD25 and CD71. Resting CD5⁺ B cells had the typical phenotype of mantle zone B cells (IgM⁺ IgD⁺ CD39+ CD38^? CD10^? CDw75^dim), whereas resting CD5^? B cells were CD38^? CD39^? CD 10^? CDw75 intermediate and expressed surface IgM but relatively little surface IgD and could not be classified as mantle zone or germinal center cells. The finding that purified germinal center cells (CD38⁺ CD10⁺ CD39^? CDw75^bright, IgG⁺) responded to CD40 mAb and IL-4 and also to SAC plus IL-2 further underlined the differences to resting CD5^? B cells. However, some of the data collected suggest possible relationships between CD5^? B cells and germinal center cells. The CD5^? B cells isolated from the 50 % Percoll fraction proliferated in response to a-μ-Ab, CD40 mAb and IL-4 as well as to SAC and IL-2. These cells had the same mantle zone B cell phenotype as the CD5⁺ B cells, but their capacity to respond to the stimuli in vitro was unrelated to a possible contamination with CD5⁺ B cells, as documented by the appropriate controls. Furthermore, upon exposure to SAC or phorbol esters, the large majority of CD5^? B cells from the 50 % Percoll fraction did not express surface CD5 and there was very little if any accumulation of CD5 mRNA. Finally, most of the cycling cells in the stimulated CD5^? B cells did not express CD5. The CD5^? B cells from the 50 % Percoll fraction were comprised of a consistent proportion of cells that expressed surface activation markers. The removal of these cells abrogated the capacity of the suspensions to respond to the stimuli in vitro, possibly suggesting that these cells additional activation signals in vivo which were essential to acquire the capacity to respond and that could not be reproduced in vitro. The present study underlines the phenotypic and functional heterogeneity of CD5^? B cells and contributes to the identification of two subsets of these cells which differ in phenotype, tissue distribution and in vitro responses to different stimuli.     

Regulation of B cell growth and differentiation via CD21 and CD40

Stimulation in vitro of murine splenic B cells by lipopolysaccharide, anti-ϰ Sepharose, anti-CD40 or allo-reactive T helper cells all up-regulated CD21 and CD23 surface expression. Neither anti-CD21 nor anti-CD23 antibodies induced B cell growth or differentiation when added in soluble form or coupled to Sepharose. However, anti-CD40-stimulated B cells showed increased proliferation in the presence of anti-CD21 antibodies coupled to Sepharose; co-stimulation via CD21 also induced differentiation to immunoglobulin secretion in a fraction of anti-CD40-stimulated B cells. Furthermore, anti-CD40 antibodies inhibited differentiation to immunoglobulin secretion induced by lipopolysaccharide and, hence, appears to be a dominant negative signal for B cell differentiation.     

Properties of mouse CD40: Cellular distribution of CD40 and B cell activation by monoclonal anti-mouse CD40 antibodies

We describe here the derivation of a rat monoclonal antibody (mAb) against mouse CD40 (designated 3/23), which stains 45–50% of spleen cells of adult mice, approximately 90% of which are B cells. Interestingly, some 5–10% of both CD4⁺ and CD8⁺ T cells in the spleens of (some, but not all) adult, unimmunized mice are also CD40⁺, whereas CD40⁺ cells were not detectable in the thymus, even following collagenase digestion. Some 35–40% of lymphoid cells in the bone marrow of adult mice are CD40⁺ and virtually all of these are B220⁺, and hence of the B cell lineage: triple-color flow cytometry showed that CD40 is expressed at low levels on some 30% of pre-B cells, at intermediate levels on 80% of immature B cells and on essentially all mature B cells in the bone marrow. These results, therefore, suggest that in the mouse CD40 is expressed relatively late during the process of B cell differentiation. The mAb induced marked up-regulation of major histocompatibility complex class II molecules, CD23 and B7.2 antigens on mature B cells. It also stimulated modest levels of DNA synthesis in mature B cells by itself: this was markedly enhanced by suboptimal concentrations of mitogenic (but not non-mitogenic) anti-μ and anti-δ mAb, and moderately enhanced by co-stimulation with interleukin-4. Hyper-cross-linking of CD40 (using biotinylated mAb and avidin) also enhanced the proliferative response to anti-CD40.     

CD40-CD40 ligand interactions stimulate B cell antigen processing

The interactions between B cell CD40 and T cell CD40 ligand (CD40L) have been shown recently to play an important role in T cell-dependent activation of B cells. Here, we show that the ligation of CD40 stimulates the processing of antigen by B cells. The activation of an antigen-specific T cell hybrid by B cells co-cultured with insect cells expressing recombinant CD40L or with a CD40-specific monoclonal antibody requires less antigen and fewer B cells compared to control cells. The augmentation was observed both for processing initiated by antigen binding to and cross-linking the surface immunoglobulin, and processing of antigen taken up by fluid-phase pinocytosis. CD40 appears to affect a step in the intracellular processing of antigen, as CD40 has no effect on the presentation of an antigenic peptide which does not require processing. In addition, the CD40-induced augmentation of processing is not attributable to the effect of CD40 ligation on the cell surface expression of B7, LFA-1 or CD23. CD40 ligation does not affect the biosynthesis of the class II E^k molecules, and although ligation of CD40 induces B cell proliferation, the augmentation of processing does not require proliferation. The ability of CD40 to stimulate B cell antigen processing has the potential to influence significantly the outcome of antigen-dependent T cell-B cell interactions.     

B cells regulate expression of CD40 ligand on activated T cells by lowering the mRNA level and through the release of soluble CD40

The expression of CD40 ligand (CD40L) on activated T cells (CD4⁺ T cell clone MT9) is diminished when the T cells are cultured in the presence of B cells. This effect, observed both with normal tonsil B cells and with the B cell line JY, was detected after 6 h and sustained at least until 18 h of co-culture. Analysis of mRNA showed that CD40L mRNA levels were not modified after 6 h, but were significantly down-regulated after 18 h of co-culture with B cells. Although CD40L expression could not be detected by a CD40-Fc chimera, the molecule was still expressed at the membrane as shown with a polyclonal antiserum against CD40L (anti-TRAP). In addition, T cells activated in the presence of B cells were stained by a polyclonal antiserum against CD40, without the appearance of CD40 mRNA. These results indicated that a soluble form of CD40 (sCD40) bound to the expressed CD40L on T cells. The existence of sCD40 was confirmed by detection of sCD40 in B cell supernatants using a specific enzyme-linked immunosorbent assay. Collectively, these data show that B cells can regulate the expression of CD40L on activated T cells at least by two different mechanisms.     

CD40 cross-linking inhibits specific antibody production by human B cells

Ligation of CD40 on B cells is a co-stimulatory signal for proliferation,antibody secretion, heavy chain switching and rescue from apoptosisafter somatic mutation in the germinal centre. The importanceof these manifold responses to CD40 activation for humoral immunityis exemplified by the inability of boys with X-linked hyperIgM syndrome to make IgG, IgE or IgA due to a mutation in inthe gene coding for CD40 ligand (CD40L). In the present study,we have investigated the effect of CD40 ligation on specificantibody production by human B cells to influenza virus. Theantibody. response was T cell dependent and specific for thestrain of influenza virus used as antigen. Addition of eitherCD40 mAb or recombinant trimeric CD40L profoundly inhibitedspecific antibody production. Antibody production by unseparatedtonsillar mononuclear cells and by T-depleted B cells stimulatedwith antigen in the presence of T cell replacing factor wereequally inhibited with CD40 antibody showing that the effectwas due to ligation of CD40 on B cells rather than blockingof T cell help. The specific antibody detected in these experimentswas mostly IgG with little or no IgM and was obtained from surfaceIgM B cells consistent with activation of a secondary (memoryresponse. Co-stimulation of tonsillar B cells with CD40 antibodyand anti-IgG induced proliferation of IgG⁺ B cells. These resultssuggest that CD40 ligation can inhibit specific antibody responsesand stimulate proliferation in the same IgG⁺ (memory) B cellsubpopulation. Addition of CD40 antibody during the first 24–48h of the response was required for inhibition, suggesting thatthe effect was on early B cell activation and/or proliferationrequired for antibody production. There was no correlation,however, between the ability of CD40 mAb to stimulate proliferationand inhibit antibody production. We suggest that early activationof CD40 in the specific antibody response inhibits the formationof plasma cells and promotes instead the generation of memorycells.     

Role of the human CD38 molecule in B cell activation and proliferation

Human CD38 is a surface molecule which has been attributed the function of a signaling channel leading to cellular activation and proliferation, an ectoenzyme with multiple function as well as an inducer of Ca²⁺ mobilization from cytoplasmic stores. The effect mediated by CD38 have been studied in different cell populations: the results obtained in human B cells are apparently contradictory, with CD38 simultaneously leading to apoptosis in early B cells while increasing survival in cells derived from lymph node germinal center. Other effects recently reported concern a different potential in terms of signaling in early B cells and derived cell lines or in more detailed disease models of human leukemia, namely B chronic lymphocytic leukemia cells.
To complete the picture of the effects mediated by CD38 in the B cell compartment, we have studied the signals elicited by ligation of the human molecule in mature B cells from circulating pool and also from spleen of normal individuals. The information obtained completes the picture of CD38 and mature B cells, where we also studied the contribution of relevant cytokines involved in maintenance and differentiation of these normal cells, namely IL-1 α, IL-2, IL-4 and IL-6. Our results indicate that human CD38 plays a key role as a co-receptor in mature B cells from normal individuals.     

Polyclonal activation of immature B cells by preactivated T cells: the role of IL-4 and CD40 ligand

It is well-established that preactivated CD4⁺ T cells can activatemature B cells in a polyclonal, MHC-unrestricted fashion. Wehave used this system to investigate the effects of T cell-derivedsignals on immature B cells purified from the spleens of neonatalmice, since these cells are unresponsive to many polyclonalactivators and are exquisitely sensitive to tolerizatlon. Weshow that immature B cells can be induced to proliferate byanti-CD3 activated, fixed T_h1 and T_h2 cells, although the latterinduce a greater response than the former. Antibodies to IL-4partially blocked stimulation by T_h2 cells, where as antibodiesto IL-2 and IL-5 had no effect on responses to T_h1 cells. Thissuggested that molecules in addition to IL-4 contribute to thecapacity of T cells to induce B cell activation, one likelycandidate being the ligand for CD40. We therefore generatedmouse erythroleukemia (MEL) transfectants which express CD40ligand (CD40L). These transfectants also induced proliferationof immature B cells, which is enhanced by IL-;4. Unlike thesituation with mature B cells, both anti-µ and anti- antibodiesinhibited the activation of immature B cells by CD40L-MEL cells.However, this inhibition was reversed by IL-4, which synergizedwith signals delivered through CD40 to render immature B cellsrefractory to negative signals delivered through slg. Takentogether these data suggest that immature B cells can be activatedby T cell-derived contact signals and that CD40L – CD40interactions, in the presence of IL-4, are capable of abrogatingthe negative signals generated via slgM and slgD receptors expressedby these cells.     

Co-stimulation by anti-immunoglobulin is required for B cell activation by CD40Llow T cells

During cognate B : T interactions, B cells encounter antigen (Ag) through surface immuno-globulin (sIg) and present antigenic peptides to T helper (Th) cells. However, most in vitro systems used to study contact events involved in the delivery of T help for B cells circumvent the requirement for T cell Ag specificity by using anti-CD3/T cell receptor (TcR) monoclonal antibodies (mAb) to activate T cells. To study the role of sIg engagement in the responsiveness of B cells to T help, we pre-treated small resting B cells with soluble anti-χ mAb prior to contact with an activated Th1 clone. By reducing the concentration of anti-TcR mAb we obtained low levels of CD40 ligand (CD40L^low) on Th cells, comparable to those expressed by lymph node T cells activated in vitro (ex vivo T cells). In contrast to untreated B cells, which did not respond to CD40L^low Th, anti-Ig-treated B cells responded strongly. Low buoyant density B cells also responded to CD40L^low Th cells. There was no B cell response to resting Th cells. mAb against CD54/intercellular adhesion molecule-1 or major histocompatibility complex (MHC) class II completely inhibited B cell responses to CD40L^low Th1 cells, equivalent to the effects of blocking CD40 interactions. This contrasts with mAb blocking responses to CD40L^highTh, where CD40 effects predominate. Our data show that sIg engagement is necessary for the induction of B cell response to CD40L^low Th cells. Anti-CD3-activated ex vivo T cells that were also CD40L^low did not provide help to small resting B cells, but did induce responses from sIg-stimulated B cells. Thus, our data support a requirement for sIg signaling in physiological B cell activation, and further confirm previous work showing CD40 ligation to be necessary but not sufficient for delivery of T help to B cells.     

Normal CD40-mediated activation of monocytes and dendritic cells from patients with hyper-IgM syndrome due to a CD40 pathway defect in B cells

Patients with X-linked hyper-IgM syndrome [CD40 ligand (CD40L) deficiency] are prone to infections by intracellular parasites. It has been suggested that this susceptibility is caused by defective macrophage activation through the CD40L-CD40 pathway. We studied the CD40-mediated activation of monocytes and dendritic cells from patients affected with a CD40L⁺ hyper-IgM syndrome characterized by a defect of B lymphocyte responses to CD40 agonists. We show that the CD40-induced production of IL-6, IL-8 and TNF-α by monocytes, and IL-12 by dendritic cells, and expression of the activation markers CD83, the co-stimulatory molecules CD86 and CD80, and HLA-DR antigens were all similar in patient and control cells. This observation is consistent with the clinical characteristics of the syndrome: a defect of immunoglobulin switch but no susceptibility to opportunistic infections, as observed in CD40L-deficient patients. These observations suggest that CD40-mediated activation pathways could be, at least in part, different in B and monocytic/dendritic cell lineages.     

Engagement of CD40 lowers the threshold for activation of resting B cells via antigen receptor

Cross-linking of surface Ig (sIg) on resting B cells can generate intracellular signals; however, for T-dependent antigens to promote growth and differentiation additional surface receptors must be engaged. Ligation of CD40 can stimulate B cell proliferation in the presence of interleukin-4. A recently identified counterstructure for CD40 is found on T helper cells and is believed to represent the cognate ligand for B cell activation. This study investigates the role of CD40 as an accessory molecule in sIg-dependent B cell activation. Simultaneous ligation of sIg and CD40 by monoclonal antibodies (mAb) in the presence of mouse L cells which express human Fey receptor type II (FcγRII-L cells) results in potent stimulation of small resting B cells. When CD40 is co-ligated, picomolar concentrations of mouse IgG1 anti-μ, and anti-δ mAb can stimulate B cell proliferation. This requires interaction of the anti-Ig mAb with the FcγRII-L cells: a mouse IgG2a anti-μ, mAb which is not recognized by FcγRII, was ≥ 1000-fold less effective. These findings suggest a mechanism for B cell activation whereby engagement of T cells via CD40 and its cognate ligand provides potent enhancement of signals delivered through sIg. Based on these observations, models for the activation of B cells by T-dependent antigens are presented.     

反义CD40RNA对EB病毒转化的B细胞CD40分子表达和增殖能力的影响

目的 :探讨瞬时表达的反义CD4 0RNA ,对EB病毒转化的健康人B细胞膜表面CD4 0分子表达和增殖能力的影响。方法 :应用T A克隆技术和亚克隆技术 ,构建人反义CD4 0RNA的真核表达载体pcDNA3/CD4 0 ,并以其转染本室建立的EB病毒转化的健康人B细胞。应用流式细胞仪 (FACS) ,检测B细胞膜上CD4 0分子表达的变化。应用MTT比色法检测反义CD4 0RNA对B细胞增殖能力的影响。结果 :与转染空载体pcDNA3组相比 ,转染pcDNA3/CD4 0细胞上CD4 0分子的表达降低 (P<0 .0 1) ,其增殖能力明显降低 (P <0 .0 1)。结论 :反义CD4 0RNA技术 ,可作为有效的免疫调控手段。CD4 0基因本身在细胞的生长代谢中也起着重要作用     

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

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

Epitope‐dependent synergism and antagonism between CD40 antibodies and soluble CD40 ligand for the regulation of CD23 expression and IgE synthesis in human B cells

BACKGROUND: The induction of IgE synthesis in naive B cells requires two T-cell-derived signals: one delivered through CD40 and the other via interleukin-4 (IL-4). The natural counterstructure to CD40 is the CD40 ligand (CD40L). We have asked about the interplay between CD40L and CD40 mAb that recognize distinct epitopes in delivering signals for regulating IL-4-dependent IgE synthesis and the expression of CD23, the low-affinity IgE receptor, in resting B cells. METHODS: After culture of purified human tonsillar B cells with CD40 agonists and IL-4, surface CD23 was determined by flow cytometric analysis. CD23 levels in cell lysates and supernatants were quantified by ELISA, as were those of secreted IgE. RESULTS: With regard to both induction of CD23 and IgE production, soluble CD40L trimer (sCD40LT) showed synergistic interaction with two mAb to CD40 which bind to epitopes located outside the ligand binding site (EA5 and 5C3), but not with a mAb (G28-5) which effectively competes for CD40L binding to CD40. Each of the two noncompeting mAb to CD40 was able to cooperate strongly with sCD40LT in promoting high-level induction of CD23 even in the absence of IL-4, an effect mirrored in the promotion of strong homotypic clustering and high-rate DNA synthesis. G28-5, uniquely, induced a down-regulation in IL-4-induced CD23 expression with time, a change that was accompanied by an increase in the amount of soluble CD23 detected. While the two noncompeting mAb consistently synergized with sCD40LT for the promotion of IL-4-dependent IgE synthesis, sCD40LT and G28-5 (which, by itself, was the most potent of the CD40 mAb at inducing IL-4-dependent IgE production) exhibited mutual antagonism in this regard, the level of which could be quite profound. CONCLUSIONS: This study demonstrates that appropriate targeting of CD40 can modulate IgE synthesis either positively or negatively.