Immune complexes can trigger a SHIP-1-independent proapoptotic signal in mouse class-switched IgG(+) B cells and plasma cells by binding to Fc gammaRIIB, in the absence of concomitant coaggregation with BCR, hence regulating plasma cell survival and participating in the selection of B cells producing high affinity Abs during secondary Ab responses. By contrast, we demonstrate in the present study that the unique aggregation of Fc gammaRIIB on human peripheral IgM(+) B cells does not induce apoptosis but transiently inhibits B cell proliferation and calcium influx triggered by BCR cross-linking. Using human peripheral B cells and IIA1.6 lymphoma B cells expressing wild-type human Fc gammaRIIB (IIA1.6-Fc gammaRIIB), we also show that the unique aggregation of human Fc gammaRIIB induces ITIM phosphorylation. This aggregation provokes the recruitment of phosphorylated SHIP-1 by Fc gammaRIIB and inhibits the constitutive phosphorylation of Akt in human IIA1.6-Fc gammaRIIB cells. This inhibitory signaling pathway is abrogated in IIA1.6 cells expressing ITIM-mutated Fc gammaRIIB (Fc gammaRIIB(Y292G)), suggesting that ITIM phosphorylation is necessary for Fc gammaRIIB-induced B cell blockade. Overall, we demonstrate that the unique aggregation of Fc gammaRIIB on human peripheral IgM(+) B cells is sufficient to transiently down-regulate their activation without inducing apoptosis. Our results suggest that Fc gammaRIIB could negatively regulate IgM(+) B cells before class-switch occurrence and that its unique engagement by immune complexes represents a reversible checkpoint for peripheral IgM(+) B cells.