Platelets are essential for normal hemostasis, but close regulation is required to avoid the destructive effects of either inappropriate platelet activation or excessive responses to injury . Here, we describe a novel complex comprising the scaffold protein, spinophilin (SPL), and the tyrosine phosphatase, SHP-1, and show that it can modulate platelet activation by sequestering RGS10 and RGS18, 2 members of the regulator of G protein signaling family. We also show that SPL/ RGS/SHP1 complexes are present in resting platelets where constitutive phosphorylation of SPL(Y398) creates an atypical binding site for SHP-1. Activation of the SHP-1 occurs on agonist-induced phosphorylation of SHP-1(Y536), triggering dephosphorylation and decay of the SPL/ RGS/SHP1 complex. Preventing SHP-1 activation blocks decay of the complex and produces a gain of function. Conversely, deleting spinophilin in mice inhibits platelet activation. It also attenuates the rise in platelet cAMP normally caused by endothelial prostacyclin (PGI 2 ). Thus, we propose that the role of the SPL/RGS/ SHP1 complex in platelets is time and context dependent. Before injury, the complex helps maintain the quiescence of circulating platelets by maximizing the impact of PGI 2 . After injury, the complex gradually releases RGS proteins, limiting platelet activation and providing a mechanism for temporal coordination of pro thrombotic and antithrombotic inputs.
IntroductionPlatelet responses to most agonists are mediated by G proteincoupled receptors, giving rise to the intracellular events that trigger platelet aggregation and granule exocytosis. 1 It has been known for some time that signaling by G proteins in platelets is subject to regulation by extrinsic factors arising from endothelial cells, especially nitric oxide and prostacyclin (PGI 2 ). 2 However, intrinsic modulators of platelet activation also exist, including members of the RGS (regulator of G protein signaling) family, 3 proteins that suppress G protein signaling by accelerating the hydrolysis of GTP bound to active G ␣ . 4,5 In contrast to nitric oxide and PGI 2 , RGS proteins are thought to have their effect once activation has begun; hence, the gain of function that we observed when an RGSinsensitive variant of G i2␣ was introduced into platelets. 3 This inhibitory role for RGS proteins produces a potential conundrum: although preventing unwarranted platelet activation is desirable, preventing the rapid onset of the hemostatic response to injury is not. We have, therefore, sought the means by which the onset of signal suppression by RGS proteins can be delayed, allowing signaling to begin. That search brought us to spinophilin (SPL or neurabin-II), a 130-kDa scaffold protein originally identified in screens for brain proteins that can bind to the serine/ threonine phosphatase, PP1, 6 and F-actin, 7 and subsequently found to associate with other proteins as well, 8 including a limited set of G protein-coupled receptors and RGS proteins. [9][10][11][12] Prior evidence suggests that one reg...
