Modification of phospholipase C-gamma-induced Ca2+ signal generation by 2-aminoethoxydiphenyl borate.

Abstract

The mechanisms by which Ca(2+)-store-release channels and Ca(2+)-entry channels are coupled to receptor activation are poorly understood. Modification of Ca(2+) signals by 2-aminoethoxydiphenyl borate (2-APB), suggests the agent may target entry channels or the machinery controlling their activation. In DT40 B-cells and Jurkat T-cells, complete Ca(2+) store release was induced by 2-APB (EC(50) 10-20 microM). At 75 microM, 2-APB emptied stores completely in both lymphocyte lines, but had no such effect on other cells. In DT40 cells, 2-APB mimicked B-cell receptor (BCR) cross-linking, but no effect was observed in mutant DT40 lines devoid of inositol 1,4,5-trisphosphate (InsP(3)) receptors (InsP(3)Rs) or phospholipase C-gamma2 (PLC-gamma2). Like the BCR, 2-APB activated transfected TRPC3 (canonical transient receptor potential) channels, which acted as sensors for PLC-gamma2-generated diacylglycerol in DT40 cells. The action of 2-APB on InsP(3)Rs and TRPC3 channels was prevented by PLC-inhibition, and required PLC-gamma2 catalytic activity. However, unlike BCR activation, no increased InsP(3) level could be measured in response to 2-APB. Also, calyculin A-induced cytoskeletal reorganization prevented 2-APB-induced InsP(3)R and TRPC3-channel activation, but not that induced by the BCR. 2-APB still activated TRPC3 channels in DT40 cells with fully depleted Ca(2+) stores, indicating its action was not via Ca(2+) release. Significantly, 2-APB-induced InsP(3)R and TRPC3 activation was prevented in DT40 knockout cells devoid of the BCR- and PLC-gamma2-coupled adaptor/kinases, Syk, Lyn, Btk or BLNK. The results suggest that 2-APB activates Ca(2+) signals in lymphocytes by initiating and enhancing coupling between components of the BCR-PLC-gamma2 complex and both Ca(2+)-entry and Ca(2+)-release channels.