Signals that initiate somatic hypermutation of B cells in vitro.

Somatic hypermutation is initiated as B lymphocytes proliferate in germinal centers. The signals that switch on the mutation process are unknown. We have derived an in vitro system to define signals that will initiate mutation in normal, naive splenic B cells. We find that three signals are required to allow detection of somatic mutation in vitro; these are anti-Ig, anti-CD40, and anti-CD38. If any one of these is omitted, mutation remains off. We show that CD40 is obligatory in vivo, as CD40 knockout mice exhibit no Ag-driven mutation. In contrast, CD38 is not, as CD38 knockout mice mutate normally. We believe that, in vitro, CD38, in combination with other stimuli, drives extensive cell division, allowing the detection of mutated sequences. However, in germinal centers in vivo, proliferative activity is instigated by a different molecule. This is the first demonstration of the initiation of hypermutation in vitro with normal splenic B cells using defined stimuli.

CD40 ligand signals optimize T helper cell cytokine production: role in Th2 development and induction of germinal centers.

The role of CD40 in the development of germinal centers (GC) is not simply to initiate the B cell response, as rudimentary GC can develop in CD40-/- mice that are injected with CD40-immunoglobulin (Ig) fusion protein. This indicates that CD40 ligand (CD40L) transduces a signal to T cells that is important in the process. In this study we have used an in vitro model of GC development to investigate the role of CD40L, cytokines and other co-stimuli. The model involves the specific induction of an H-2E transgene in GC B cells (in Sma58 mice). We find that Th2 cytokines together with Ig and CD40 cross-linking are the most efficient means of induction of the GC phenotype. Although IL-4 plays some inductive role, it is not the sole active ingredient in the mix of cytokines made by Th2 cells. Our studies on primary T cells and T cell clones activated in the absence of CD40 on antigen-presenting cells or CD40L on T cells indicate that the CD40L co-stimulus does not directly bias the response to Th2 cells, as previously reported, but that it augments terminal effector T cell differentiation or the level of secretory activity. However, both in vitro and in vivo, the CD40L co-stimulus is crucially important for Th2 development as in its absence IL-4 production is suboptimal and does not compete with a larger, more rapid IFN-gamma response.

Observations on memory B-cell development.

We dissect in this article the roles of CD40 and its ligand in memory B-cell formation. Our data indicate that CD40 ligation does not directly lead to GC formation but it plays an indirect role related to maturation of helper T cells; signalling is bidirectional, to B cells, via CD40, upregulating cytokine receptor expression and to T cells, via CD40L, causing secretion of cytokines necessary for GC initiation. Later in the GC, CD40 selects mutated B cells for entry into the memory pool. This second T-cell-mediated CD40 ligation has consequences distinct from the first (rescue versus proliferation) that arise from rewiring of CD40 signal transduction pathways.