Cross-linking of CD40 using anti-CD40 antibody, 5C11, has different effects on XG2 multiple myeloma cells

A multiple myeloma (MM) cell line, XG2, has high-level expression of CD40, a tumor necrosis factor receptor (TNFR) family member. CD40 is present on the surfaces of a large variety of cells, including B cells, endothelial cells, dendritic cells and some carcinoma cells, and delivers signals regulating diverse cellular responses, such as proliferation, differentiation, growth suppression, cell death. In this research, we study the effects of cross-linking of CD40 on myeloma cells using different concentrations of anti-CD40 monoclonal antibody (mAb), 5C11. We found that low concentrations of 5C11 induced proliferation of XG2, while high concentrations of 5C11 resulted in homotypic aggregation of XG2, and strongly suppression of its proliferation and apoptosis after 24 h of treatment. These dose-dependent effects of 5C11 were verified by flow cytometry, Western blotting and immunoprecipitation. Autocrine or paracrine induction of IL-6, and up-regulation of membrane TNF and phosphorylation of TNFR1 may partially explain the contradictory biological effects of CD40 cross-linking on XG2 by anti-CD40 mAb.     

The role of CD40 and CD154/CD40L in dendritic cells

In this review, we focus on the function of CD40–CD40L (CD154) interactions in the regulation of dendritic cell (DC)–T cell and DC–B cell crosstalk. In addition, we examine differences and similarities between the CD40 signaling pathway in DCs and other innate immune cell receptors, and how these pathways integrate DC functions. As research into DC vaccines and immunotherapies progresses, further understanding of CD40 and DC function will advance the applicability of DCs in immunotherapy for human diseases.     

In vitro activation of leukaemic B cells by interleukin-4 and antibodies to CD40.

Chronic lymphocytic leukaemia (CLL) B cells have the phenotype of mature, partially activated B cells, but are relatively resistant to stimulation through cell-surface receptors with agents such as antibodies to immunoglobulin M. In the present study we have shown that culture of CLL cells with interleukin-4 (IL-4) and antibodies to CD40 caused significant DNA synthesis as assessed by incorporation of thymidine. This effect was largely mediated by antibody binding to CD40, a molecule known to induce B-cell activation and to mediate survival signals to germinal centre B cells. Epstein-Barr virus (EBV) infection of CLL cells stimulated with IL-4 and anti-CD40 did not affect the state of differentiation of the cell, augment the proliferative capacity, prolong cell survival or cause virus-driven immortalization.     

Pathogenic role of B cells in anti-CD40-induced necroinflammatory liver disease

Activated B cells function in antibody production and antigen presentation, but whether they perform any pathophysiological functions at sites of inflammation is not fully understood. Here, we report that intravenous injection of an agonistic anti-CD40 monoclonal antibody (alphaCD40) causes a biphasic inflammatory liver disease in inbred mice. The late phase of disease was suppressed in B-cell-deficient mice and by the depletion of macrophages, but not T cells or natural killer cells. We also report that SCID mice were not susceptible to alphaCD40-induced liver disease unless they were reconstituted with normal B cells and that B cells as well as macrophages played key roles in alphaCD40-induced late phase of liver inflammation. Finally, liver disease and the recruitment of inflammatory cells into the liver were mediated by interferon-gamma and tumor necrosis factor-alpha, but not by Fas. In conclusion, these results indicate that CD40 ligation can trigger a B-cell-mediated inflammatory response that can have pathogenic consequences for the liver.     

Differential effects of interleukin-2 and interleukin-4 on immunomodulatory role of platelet-activating factor in human B cells.

Platelet-activating factor (PAF), a naturally occurring phospholipid cytokine, is a potent mediator of allergic and inflammatory reactions, as well as a modulator of immune responses. In the present study we showed that PAF is involved in early B-cell activation, as demonstrated by the increased cyclic AMP (cAMP) generation by PAF in a time- and dose-dependent manner in anti-mu antibody- plus B-cell growth factor-activated normal human peripheral blood B lymphocytes. PAF also regulated differentiation by causing a biphasic response on immunoglobulin M (IgM) production with an inhibitory signal generated at 10(-6) M and a stimulatory signal generated at 10(-8) to 10(-10) M. PAF enhanced IgA secretion. The regulation exerted by PAF was shown to be specific because the addition of the PAR antagonist CV-3988 abrogated these effects and the inactive form of PAF, lyso-PAF, induced neither cAMP generation nor immunoglobulin secretion in normal human B cells. Other cytokines, interleukin-2 (IL-2) and IL-4, potent mediators of the immune response, were unable to elicit a cAMP response in B cells. However, the addition of PAF (10(-6) M) with wither IL-2 or IL-4 enhanced cAMP production above the levels enhanced by the addition of PAF alone. IL-2 or IL-4, individually, stimulated IgM production, yet costimulation with PAF resulted in a differential effect between IL-2 and IL-4. PAF down-regulated the IL-4-induced IgM secretion, whereas the IL-2-induced IgM secretion was enhanced. The presence of CV-3988 returned all valued to those obtained with IL-2 or IL-4 alone, demonstrating the specificity of PAF. These data suggest that PAF is an important B-cell immunomodulator which can interact with other leukocyte cell mediators.     

Activated T cells induce interleukin-12 production by monocytes via CD40-CD40 ligand interaction

Previous studies on the production of interleukin-12 (IL-12) have shown that it is released, together with other proinflammatory cytokines, shortly after exposure of phagocytic cells to a variety of pathogens. We here report that IL-12 is also released during the recall response to soluble antigen (Ag) devoid of intrinsic adjuvant activity. We show that activated T cells induce the production of IL-12 by monocytes via a mechanism involving the interaction of T cell-associated CD40 ligand with CD40 on monocytes. The data suggest that Ag presentation on monocytes favors the persistence of type 1 responses.     

Epithelial cells as immune effector cells: The role of CD40

Through the expression of inflammatory mediators and immune-related molecules, epithelial cells function as immune effector cells in a wide variety of tissues; the expression of the CD40 receptor on these cells contributes this role. Engagement of CD40 activates epithelial cells and results in their release of pro- and anti-inflammatory mediators as well as pro-fibrotic molecules. As such, epithelial CD40 has been implicated in the pathogenesis of inflammatory disorders, generation of self-tolerance, and rejection of allografts.     

Activation of thymic B cells by signals of CD40 molecules plus interleukin-10

We have previously found that thymic B cells, particularly thymic CD5⁺ B cells, show low responsiveness to the usual B cell stimulants such as lipopolysaccharide or anti-IgM plus interleukin (IL)-4, although they proliferate and produce antibodies after direct interaction with major histocompatibility complex class II-restricted T blasts. These findings raise the possibility that a CD40-CD40 ligand (L) interaction is involved in the activation of thymic B cells. In the present study, we therefore examine this possibility using CD40L-transfected Chinese hamster ovary (CHO) cells or anti-CD40 monoclonal antibody (mAb). When B cells in the spleen and peritoneal cavity were stimulated, they proliferated and produced immunoglobulin (Ig) in the presence of CD40L-CHO cells or anti-CD40 mAb alone. However, another signal delivered by IL-10 in addition to CD40L-CHO cells or anti-CD40 mAb was found to be necessary for thymic B cells to proliferate and secrete Ig. Other interleukins acting on B cells, such as IL-4, IL-5, and IL-6, had no effect on the activation of thymic B cells, which thus have unique characteristics not found in peripheral B cells. This report discusses the physiological significance of IL-10- and CD40-driven signals in the activation of thymic B cells.     

Properties of mouse CD40: the role of homotypic adhesion in the activation of B cells via CD40

Stimulation of human B cells via CD40 is known to induce their homotypic aggregation. We show here that anti-mouse CD40 monoclonal antibodies (mAb) also induce B cells to form large, spherical, extremely stable clusters. This clustering is markedly enhanced by co-stimulation with either interleukin-4 (IL-4) or anti-immunoglobulin (Ig). The aggregation is slow in onset, and is largely (but not completely) abrogated by anti-LFA-1 mAb, but not by mAb directed against other potentially important adhesion molecules on B cells. Anti-LFA-1 mAb also partially suppressed DNA synthesis induced by anti-CD40, but not by other B cell mitogens, suggesting that clustering is an important component of B cell activation via CD40. This concept is supported by analyses of the phenotype of clustered B cells: the cells within clusters express higher levels of various activation markers, and also more of them are in cell cycle than non-clustered cells. These results therefore suggest that CD40 stimulation may either induce B cells to secrete soluble factors which act in an autocrine way to promote Bcell activation, or that clustering generates cell contact-mediated signals which are important in the activation cascade.     

Properties of mouse CD40: differential expression of CD40 epitopes on dendritic cells and epithelial cells.

In this study we describe the tissue distribution of mouse CD40 using two monoclonal antibodies (mAb) against different epitopes of the molecule. In lymphoid tissues CD40 was expressed by B lymphocytes. Most B cells in typical B-cell compartments were CD40-positive, including germinal centre B cells. Interestingly, the two CD40 epitopes were differentially distributed on subpopulations of dendritic cells and epithelial cells. The 3/23 mAb, but not 3/3, recognized interdigitating dendritic cells (IDC) in lymph nodes, spleen and thymus. Langerhans cells were CD40 negative. In contrast, epithelial cells in the thymus and some other tissues (e.g. skin) were stained with the 3/3 mAb, but not with the 3/23 mAb. The expression of CD40 on dendritic cells and epithelial cells is in agreement with earlier findings in humans. Our data also demonstrate that different epitopes of CD40 are differentially expressed on dendritic cells and epithelial cells. This suggests the existence of different forms of CD40, that are expressed in a cell-type-specific fashion.     

Inhibitory effect of interleukin-16 on interleukin-2 production by CD4+ T cells

Signalling through CD4 by human immunodeficiency virus (HIV)-1 envelope glycoprotein (gpl20) and/or anti-CD4 antibodies can promote T-cell activation and anergy. Interleukin (IL)-16 is a competence growth factor for CD4+ T cells that can induce a G0 to G1 cell cycle transition but cannot induce cell division. The receptor of this cytokine is thought to be the CD4 molecule, although the binding epitope of IL-16 differs from that of HIV. We have demonstrated that both HIV-1/gp120 and IL-16 induced CD4+ T-cell dysfunction, as indicated by suppression of mitogen-induced IL-2 production. Two anti-CD4 antibodies with different binding sites on CD4 also showed an inhibitory effect on IL-2 production. These results indicate that promotion of CD4+ T-cell anergy via the CD4 molecule does not depend on the binding sites of the CD4 ligands.     

Mechanisms of immunotherapeutic intervention by anti-CD154 (CD40L) antibody in high-risk corneal transplantation.

This study aimed to determine the effects of anti-CD154 on T cell cytokine profiles and ocular chemokine gene expression after high-risk corneal transplantation and to specifically determine if CD154 blockade is associated with a switch from a Th1 to a Th2 alloimmune response. Mice were used as recipients of syngeneic or multiple minor H or MHC antigen-mismatched corneal grafts. Recipient beds were neovascularized (high-risk). Hosts were randomized to receive either anti-CD154 antibody or control immunoglobulin (Ig) perioperatively. Two weeks after corneal transplantation, allospecific delayed-type hypersensitivity (DTH) was evaluated. Frequencies of interferon-gamma (IFN-gamma)-, interleukin-2 (IL-2)-, IL-4-, and IL-5-secreting T cells in the hosts were measured by enzyme-linked immunospot (ELISPOT) assay. Ocular chemokine gene expression in anti-CD154-treated and control hamster Ig-treated groups was determined using a multiprobe ribonuclease protection assay (RPA). Leukocyte infiltration of corneal grafts was evaluated microscopically. Anti-CD154-treated mice did not exhibit allospecific DTH. The frequencies of Th1 cytokine-producing but not Th2 cytokine-producing T cells were significantly reduced in anti-CD154-treated hosts. Postoperative mRNA levels of RANTES and macrophage inflammatory protein-1beta (MIP-1beta) in anti-CD154-treated eyes were substantially suppressed compared with hamster Ig-treated controls. Leukocyte infiltration was profoundly suppressed in grafts of anti-CD154-treated hosts. These data demonstrate that blockade of the CD40-CD154 costimulatory pathway after corneal transplantation inhibits Th1-mediated responses but does not induce a switch to a Th2-specific response. In addition, anti-CD154 therapy suppresses ocular chemokine gene expression and leukocytic infiltration into allografts.     

The effects of CD40- and interleukin (IL-4)-activated CD23+ cells on the production of IL-10 by mononuclear cells in Graves' disease: the role of CD8+ cells

The possible roles of CD8+ cells in the abnormal T cell-dependent B-cell activation in Graves' disease were investigated by analysing lymphocyte subsets in peripheral blood mononuclear cells (PBMC) and their production of soluble factors and cytokines such as IL-10 in patients with Graves' disease, Hashimoto's thyroiditis and normal controls. The PBMC were separated into CD8+ and CD8-depleted cells by magnetic separation columns, and cultured for 7 days with or without anti-CD40 monoclonal antibodies and IL-4. The culture supernatant was assayed for sCD23 and IL-10 using EIA, and the remaining cells were analysed by flow cytometry. Stimulation with anti-CD40 antibody together with IL-4 increased sCD23 levels and the number of CD23+ cells. The latter was further augmented by depletion of CD8+ cells. This combination of B cell stimulants increased production of IL-10 by PBMC from patients with Graves' disease. The CD40- and IL-4-activated production of IL-10 was decreased by CD8+ cell depletion. In contrast, constitutive production of IL-10 was increased after CD8+ cell depletion in a group of patients with low basal secretion levels (<35 ng/ml). It was, however, decreased in a group with higher basal production levels, but such a relationship was not found in the normal control group. Thus, T cell-dependent B-cell activation via a CD40 pathway activates CD23+ cells, leading to over-production of IL-10 and a shift of the Th1/Th2 balance to Th2 dominance, while CD8+ cells may suppress this activation to counteract the Th2 deviation in Graves' disease.     

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.     

Levels of CD40 expression on dendritic cells dictate tumour growth or regression

Tumour regression requires activation of T cells. It has been shown that the interaction between T cell-expressed CD40-ligand (CD40-L) and antigen-presenting cell-expressed CD40 plays a crucial role in T cell activation. CD40-L- or CD40-deficient mice are susceptible to tumour growth. CD40-based therapies are also shown to control tumour growth significantly, suggesting that CD40-CD40-L interaction induces anti-tumour T cell responses and tumour regression. We demonstrate that the anti-tumour T cell response can be modulated reciprocally as a function of the levels of CD40 expression. At low expression levels, CD40 promotes tumour growth; at higher expression levels, CD40 induces tumour-regressing T cell response. Dendritic cells (DC) sorted onto major histocompatibility complex (MHC)-II expression are found to be similar in CD40 and CD80 expression. The MHC-II(hi)/CD40(hi) DC induce interleukin (IL)-12-dominated and T helper 1 (Th1)-type response, whereas MHC-II(lo)/CD40(lo) DC promote high IL-10 and Th2-type T cells. The T cells induced by these DC also differ in terms of regulatory T cell markers, lymphocyte activation gene-3 (LAG-3) and glucocorticoid-induced tumour necrosis factor (TNF) receptor family-related gene (GITR). Thus, we report for the first time that CD40-induced effector T cell response depends on CD40 expression levels in vivo.     

Ku in the cytoplasm associates with CD40 in human B cells and translocates into the nucleus following incubation with IL-4 and anti-CD40 mAb.

CD40 plays a critical role in survival, growth, differentiation, and class switching of B lymphocytes. Although Ku is required for immunoglobulin class switching, how CD40 signal transduction is coupled to Ku is still unknown. Here, we show that CD40 directly interacts with Ku through the membrane-proximal region of cytoplasmic CD40. Ku was confined to the cytoplasm in human primary B cells, and the engagement of CD40 on the B cells cultured in the presence of IL-4 resulted in the dissociation of Ku from CD40, translocation of Ku into the nucleus, and increase in the activity of DNA-dependent protein kinase. These findings indicate that Ku is involved in the CD40 signal transduction pathway and may play an important role in the CD40-mediated events.     

Induction of sensitivity to activation-induced death in primary CD4+ cells: A role for interleukin-2 in the negative regulation of responses by mature CD4+ T cells

We examine the requirements for converting naive, mature CD4⁺ cells from an activation-induced death (AID)-resistant to a -sensitive phenotype. Priming for sensitivity to AID can be divided into two steps. The first is a mitogen/CD3-dependent, cyclosporin-sensitive signal and the second a cytokine-dependent, cyclosporin-insensitive one. Under these conditions, interleukin (IL)-2, but not IL-4, IL-7 or IL-15, the receptors of which share a common receptor γ chain, is capable of providing the cytokine signal for inducing sensitivity to AID. Increased expression of the low-affinity IL-2Rα chain (CD25) is associated with acquisition of AID sensitivity and antibodies to CD25 block acquisition of AID sensitivity in the presence of IL-2. As with T cell hybridomas, AID is dependent on both CD95 and CD95 ligand (CD95L) expression, but unlike hybridomas, the sensitive and resistant phenotypes of primary CD4⁺ cells cannot be distinguished by levels of CD95 expression, functional CD95L nor the fraction of cells in cycle. The results suggest that the unique function of IL-2 is to regulate proteins, either not important or constitutively regulated in T cell hybridomas, that are essential for cell-autonomous suicide of activated CD4⁺ cells. These experiments provide a mechanism for the recent observations of chronic lymphoproliferation and autoimmune disease in mice with null mutations in IL-2 or CD25.