IgA are major effectors of antimicrobial defense in the respiratory and digestive tracts. We have analyzed the requirements for and the modalities of switching to IgA using our recently identified monoclonal model of human germinal center differentiation, CL-01 B cells. CL-01 cells bear surface IgM (sIgM) and sIgD and switch to all seven downstream isotypes in response to physiologic stimuli. In these cells, CD40 engagement by CD40 ligand induces production of endogenous TGF-beta and IL-10, expression of germline Ialpha1-Calpha1 and Ialpha2-Calpha2 transcripts, mature VHDJH-Calpha1 and VHDJH-Calpha2 transcripts, and IgA secretion. These events are associated with not only direct Smu-->Salpha, but also sequential Smu-->Sgamma, Sgamma-->Salpha DNA recombination, and are ablated by neutralizing anti-TGF-beta but not IL-10 Ab, and indicating that TGF-beta, not IL-10, is a crucial mediator of the transcriptional activation and recombination of human Calpha1 and Calpha2 genes. Our findings in CL-01 cells were reproduced in freshly isolated naive sIgM+ sIgD+ B lymphocytes. Thus, engagement of CD40, in the absence of other (known) stimuli, is sufficient to effectively induce switching to IgA in human B cells. This is effected by direct and sequential DNA recombination events, which are both dependent upon endogenous TGF-beta secreted by the CD40L-induced B cells.