PKCalpha: a versatile key for decoding the cellular calcium toolkit.

Conventional protein kinases C (cPKCs) play an essential role in signal transduction and are believed to integrate both global Ca(2+) transients and diacylglycerol signals. We provide evidence that PKCalpha is a ubiquitous readout sensor for the cellular Ca(2+) toolkit, including highly restricted elementary Ca(2+) release. Threshold stimulations of cells with Ca(2+)-mobilizing agonists resulted in PKCalpha translocation events with limited spatial spreads (<4 microm) comprising two groups of lifetimes; brief events (400-1,500 ms) exclusively mediated by Ca(2+)-C2 domain membrane interactions and long-lasting events (>4 s) resulting from longer DAG-C1a domain-mediated membrane interactions. Although upon uncaging NP-EGTA, which is a caged Ca(2+) compound, WT-PKCalpha displayed rapid membrane translocations within <250 ms, PKCalpha constructs with C2 domains mutated in their Ca(2+)-binding region lacked any Ca(2+)-dependent translocation. Flash photolysis of diazo-2, a photosensitive caged Ca(2+) buffer, revealed a biphasic membrane dissociation (slow and fast period) of WT-PKCalpha. The slow phase was absent in cells expressing PKCalpha-constructs containing mutated C1a-domains with largely reduced DAG binding. Thus, two groups of PKCalpha membrane interactions coexist; C2- and C1a-mediated interactions with different lifetimes but rapid interconversion. We conclude that PKCalpha can readout very fast and, spatially and temporally, very complex cellular Ca(2+) signals. Therefore, cPKCs are important transducers for the ubiquitous cellular Ca(2+) signaling toolkit.