B Cell Tolerance in Health and Disease

B lymphocyte receptors are generated randomly during the bone marrow developmental phase of B cells. Hence, the B cell repertoire consists of both self and foreign antigen specificities necessitating specific tolerance mechanisms to eliminate self-reactive B cells. This review summarizes the major mechanisms of B cell tolerance, which include clonal deletion, anergy and receptor editing. In the bone marrow presentation of antigen in membrane bound form is more effective than soluble form and the role of dendritic cells in this process is discussed. Toll like receptor derived signals affect activation of B cells by certain ligands such as nucleic acids and have been shown to play crucial roles in the development of autoimmunity in several animal models. In the periphery availability of BAFF, a B cell survival factor plays a critical role in the survival of self-reactive B cells. Antibodies against BAFF have been found to be effective therapeutic agents in lupus like autoimmune diseases. Recent developments are targeting anergy to control the growth of chronic lymphocytic leukemia cells

Bone Marrow Dendritic Cell-Mediated Regulation of TLR and B Cell Receptor Signaling in B Cells

Dendritic cells (DCs) play an essential role in regulation of immune responses. In the periphery, Ag presentation by DCs is critical for adaptive responses; for this reason, DCs are often targets of adjuvants that enhance vaccine responses. Activated mature DCs enhance B cell activation and differentiation by providing cytokines like BAFF and a proliferation-inducing ligand. However, the role of immature DCs in B cell tolerance is not well studied. Recently, mouse immature bone marrow-derived DCs (iBMDCs) have been shown to suppress anti-IgM–induced B cell activation. In this study, we tested the ability of mouse DCs to modulate B cell functions during TLR activation. We found that iBMDCs potently suppressed proliferation and differentiation of various B cell subsets on TLR stimulation. However, iBMDCs did not affect CD40-mediated B cell activation. Optimal suppression of B cell activation by iBMDCs required cell contact via the CD22 receptor on B cells. The B cell suppression was a property of iBMDCs or DCs resident in the bone marrow (BM), but not mature BM-derived DCs or DCs resident in the spleen. Presence of iBMDCs also enhanced the Ag-induced apoptotic response of BM B cells, suggesting that the suppressive effects of iBMDCs may have a role in B cell tolerance

Regulation of the Mucosal Phenotype in Dendritic Cells by PPARγ: Role of Tissue Microenvironment

Mucosal DCs play a critical role in tissue homeostasis. Several stimuli can induce a mucosal phenotype; however, molecular pathways that regulate development of mucosal DC function are relatively unknown. This study sought to determine whether PPARγ contributes to the development of the “mucosal” phenotype in mouse DCs. Experiments demonstrated that PPARγ activation in BMDCs induced an immunosuppressive phenotype in which BMDCs had reduced expression of MHC class II and costimulatory molecules, increased IL‐10 secretion, and reduced the ability to induce CD4 T cell proliferation. Activation of PPARγ enhanced the ability of BMDC to polarize CD4 T cells toward iTregs and to induce T cell expression of the mucosal homing receptor, CCR9. Activation of PPARγ increased the ability of BMDCs to induce T cell‐independent IgA production in B cells. BMDCs from PPARγΔDC mice displayed enhanced expression of costimulatory molecules, enhanced proinflammatory cytokine production, and decreased IL‐10 synthesis. Contrary to the inflammatory BMDC phenotype in vitro, PPARγΔDC mice showed no change in the frequency or phenotype of mDC in the colon. In contrast, mDCs in the lungs were increased significantly in PPARγΔDC mice. A modest increase in colitis severity was observed in DSS‐treated PPARγΔDC mice compared with control. These results indicate that PPARγ activation induces a mucosal phenotype in mDCs and that loss of PPARγ promotes an inflammatory phenotype. However, the intestinal microenvironment in vivo can maintain the mucosal DC phenotype of via PPARγ‐independent mechanisms