Abstract
Rac1, which is associated with cytoskeletal pathways, can activate phospholipase Cbeta2 (PLCbeta2) to increase intracellular Ca(2+) levels. This increased Ca(2+) can in turn activate the very robust PLCdelta1 to synergize Ca(2+) signals. We have previously found that PLCbeta2 will bind to and inhibit PLCdelta1 in solution by an unknown mechanism and that PLCbeta2.PLCdelta1 complexes can be disrupted by Gbetagamma subunits. However, because the major populations of PLCbeta2 and PLCdelta1 are cytosolic, their regulation by Gbetagamma subunits is not clear. Here, we have found that the pleckstrin homology (PH) domains of PLCbeta2 and PLCbeta3 are the regions that result in PLCdelta1 binding and inhibition. In cells, PLCbeta2.PLCdelta1 form complexes as seen by Förster resonance energy transfer and co-immunoprecipitation, and microinjection of PHbeta2 dissociates the complex. Using PHbeta2 as a tool to assess the contribution of PLCbeta inhibition of PLCdelta1 to Ca(2+) release, we found that, although PHbeta2 only results in a 25% inhibition of PLCdelta1 in solution, in cells the presence of PHbeta2 appears to eliminates Ca(2+) release suggesting a large threshold effect. We found that the small plasma membrane population of PLCbeta2.PLCdelta1 is disrupted by activation of heterotrimeric G proteins, and that the major cytosolic population of the complexes are disrupted by Rac1 activation. Thus, the activity of PLCdelta1 is controlled by the amount of bound PLCbeta2 that changes with displacement of the enzyme by heterotrimeric or small G proteins. Through PLCbeta2, PLCdelta1 activation is linked to surface receptors as well as signals that mediate cytoskeletal pathways.
Highlights
Mammalian phospholipase Cs (PLCs)2 are critical signaling enzymes whose activity results in an increase in intracellular Ca2ϩ through the hydrolysis of PI[4,5]P2
To better understand the linkage between PLC␦ and cell surface receptors, we have found that the pleckstrin homology (PH) domain of phospholipase C2 (PLC2) and -3 is responsible for binding and inhibition of PLC␦1 and have used this as a reagent to study the importance of PLC inhibition of PLC␦1 in cells
PLC␦1 by PLC2 in cells, we set out to identify the region of PLC2 that is responsible for PLC␦1 inhibition with the goal of developing a reagent to inhibit association of the enzymes
Summary
Mammalian phospholipase Cs (PLCs) are critical signaling enzymes whose activity results in an increase in intracellular Ca2ϩ through the hydrolysis of PI[4,5]P2. Most PLCs have established protein regulators, and many appear to have multiple mechanisms of regulation that, in principle, may connect different signaling pathways. Association between PLC2–3 and PLC␦1 can be disrupted by the addition of G␥ subunits in solution, and preliminary studies in cultured cells suggest that the same association may occur in cells. These results suggested a model in which, upon release of G␥ subunits after stimulation, PLC becomes activated by G␥ subunits, and concomitantly activates PLC␦ through a combination of increased level of Ca2ϩ and loss of inhibition by PLC2 and -3. Microinjection of PH2 resulted in a greatly reduced Ca2ϩ release after stimulation with carbachol suggesting that the extent of a Ca2ϩ response is directly related to the level of unbound PLC␦1
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