Cross-linking of the B cell antigen receptor (BCR) results in the activation of several protein tyrosine kinases leading to phospholipase C-gamma2-dependent phospholipid hydrolysis and Ca2+ mobilization, followed by activation of the protein kinase C (PKC) family members. Sustained Ca2+ release in B lymphocytes is dependent on the membrane localization and activation of the protein tyrosine kinase BTK. Ca2+ release is a tightly regulated process involving BTK membrane localization through its phosphorylation by PKCbeta. A selective role of PKCbeta in B cell signaling was first revealed by the characterization of PKCbeta knockout mice, which displayed decreased B cell proliferation in response to various mitogenic stimuli. However, it is not clear whether the B cell defects displayed by the PKCbeta knockout mice are due a B cell developmental defect or the scaffolding function of PKCbeta, resulting in a defect in the recruitment or formation of signal transducing complex molecules. Thus, in this report we investigated the effects of pharmacologic inhibition of the catalytic function of PKCbeta on B cell survival and growth. Treatment of Daudi B lymphoma cell line with a selective PKCbeta inhibitor, LY333531, inhibited anti-IgM-induced phosphorylation of BTK on Ser180 in a concentration-dependent manner, which was concomitant with an increase in BTK activation, and Ca2+ mobilization. In primary splenic B cells, LY333531 inhibited BCR-induced B cell proliferation, but did not affect basal or LPS-induced proliferation. Finally, LY333531 treatment resulted in the induction of apoptosis of anti-IgM-activated B cells, which corroborated with their inability to up-regulate pro-survival factors, Bcl-X(L) and Bcl-2. These results support the important and selective role of the PKCbeta enzymatic function in controlling Ca2+ release during BCR signaling leading to B lymphocyte survival and growth.