IL-5 induces IgG1 isotype switch recombination in mouse CD38-activated sIgD-positive B lymphocytes.

Mouse B cells express CD38, whose ligation by anti-CD38 Ab induces their proliferation and protection from apoptosis. We previously showed that stimulation of mouse splenic B cells with IL-5 together with CS/2, an anti-mouse CD38 mAb, induces production of IgG1 and IgM. Here we examined the role of IL-5 and CS/2 in the expression of germline gamma1 transcripts and the generation of reciprocal products forming DNA circles as byproducts of mu-gamma1 switch recombination. By itself, CS/2 induced significant expression of germline gamma1 transcripts in splenic naive B cells, whereas IL-5 neither induced nor enhanced germline gamma1 expression. Increased cellular content of reciprocal product, which is characteristic of mu-gamma1 recombination, was not observed after culturing B cells with CS/2, but increased reciprocal product, along with high levels of lgG1 secretion, was found when B cells were cultured with CS/2 plus IL-5. Although IL-4 did not, by itself, induce mu-gamma1 recombination in B cells stimulated with CS/2, in conjunction with CS/2 plus IL-5, IL-4 dramatically enhanced sterile gamma1 transcription and IgG1 production. These results demonstrate that CD38 ligation induces only germline gamma1 transcription and that IL-5 promotes both mu-gamma1 switch recombination and lgG1 secretion in an IL-4-independent manner.

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