Requirement of B cells for generating CD4+ T cell memory.

B cells can influence T cell responses by directly presenting Ag or by secreting Ab that binds to Ag to form immunogenic complexes. Conflicting evidence suggests that persisting Ag-Ab complexes propagate long-term T cell memory; yet, other data indicate that memory cells can survive without specific Ag or MHC. In this study, the roles of B cells and Ag-Ab complexes in T cell responses to lymphocytic choriomeningitis virus (LCMV) infection were investigated using B cell-deficient or B cell-competent mice. Despite normal lymphocyte expansion after acute infection, B cell-deficient mice rapidly lost CD4(+) T cell memory, but not CD8(+) T cell memory, during the contraction phase. To determine whether Ag-Ab complexes sustain CD4(+) T cell memory, T cell responses were followed in B cell-transgenic (mIg-Tg) mice that have B cells but neither LCMV-specific Ab nor LCMV-immune complex deposition. In contrast to B cell-deficient mice, mIg-Tg mice retained functional Th cell memory, indicating that B cells selectively preserve CD4(+) T cell memory independently of immune complex formation. An in vivo consequence of losing CD4(+) T cell memory was that B cell-deficient mice were unable to resolve chronic virus infection. These data implicate a B cell function other than Ab production that induces long-term protective immunity.

Rhythmic patterns in phagocytosis and the production of reactive oxygen species by zebrafish leukocytes.

Multiple components of vertebrate immune systems have been shown to exhibit circadian fluctuations. While the zebrafish is currently generating a wealth of information on the molecular pacemakers that may control circadian rhythms, there have been no reports of rhythmic activity in zebrafish leukocytes. In this study, we found that phagocytosis and the production of reactive oxygen species by zebrafish leukocytes varied significantly throughout twenty-four hour periods. A distinct peak in cellular ROS levels occurred before dawn, while the kinetics of respiratory burst responses were least rapid at this time of day. Phagocytosis of E. coli peaked late in the day, whereas there was no daily variation in phagocytosis of S. aureus. As seen in other species, the number of bacteria ingested per cell peaked during the night. These data provide direct evidence of rhythmic immune system activity, and demonstrate that zebrafish can be a valuable model in which to study the relationships between circadian gene expression, systemic pacemakers, and the activity of vertebrate immune system cells.

Investigation of the role of B-cells in type 1 diabetes in the NOD mouse.

B-cells are important in the development of type 1 diabetes, but their role is not completely defined. Although B-cells produce autoantibodies, these are not thought to be pathogenic; however, their antigen-presenting function is postulated to be critical. To examine the relative importance of these functions of B-cells, we have generated nonobese diabetic (NOD) B-cell-deficient mice that express a transgene encoding a mutant heavy chain immunoglobulin transgene on the cell surface but cannot secrete immunoglobulins (mIgs). This allowed us to dissect the importance of the relative roles of antigen presentation, dissociated from antibody production. We found that the expression of the mIg transgene increased insulitis and the incidence of diabetes compared with transgene-negative NOD B-cell-deficient mice, indicating that the ability to produce antibodies is not necessary for B-cells to have some effect on the development of diabetes. However, diabetes was not restored to the level seen in normal NOD mice. This may relate to reduced ability to activate an islet-specific T-cell repertoire, presumably due to the reduced islet-specific B-cell repertoire. Our results implicate a specific antigen-presenting function for B-cells.

Memory B cell survival and function in the absence of secreted antibody and immune complexes on follicular dendritic cells.

Ag, in the form of immune complexes retained on follicular dendritic cells, has been implicated in the development and maintenance of B cell memory. We addressed this question using a H chain transgenic (Tg) mouse model that lacks secreted Ig (mIg), and thus does not deposit Ag-containing immune complexes. We compared the ability of the mIg strain and a control Tg strain, which secretes IgM, to develop and maintain long-lived memory cells. After immunization, there was an increase of Ag-specific B cells in both strains that was maintained for at least 20 wk. We labeled the long-lived Ag-specific cells with BrdU and found that this population was similarly maintained. In addition, both Tgs were able to maintain a functional memory response as measured by secondary germinal center reactions. Our studies indicate that localization of Ag on follicular dendritic cells is not necessary for development and maintenance of B cell memory.