Local Ca2+ Signals within Caveolae Cause Nuclear Translocation of CaMK1α in Mouse Vascular Smooth Muscle Cells.

An increase in intracellular Ca2+ concentration ([Ca2+]i) activates Ca2+-sensitive enzymes such as Ca2+/calmodulin-dependent kinases (CaMK) and induces gene transcription in various types of cells. This signaling pathway is called excitation-transcription (E-T) coupling. Recently, we have revealed that a L-type Ca2+ channel/CaMK kinase (CaMKK) 2/CaMK1α complex located within caveolae in vascular smooth muscle cells (SMCs) can convert [Ca2+]i changes to gene transcription profiles that are related to chemotaxis. Although CaMK1α is expected to be the key molecular identity that can transport Ca2+ signals originated within caveolae to the nucleus, data sets directly proving this scheme are lacking. In this study, multicolor fluorescence imaging methods were utilized to address this question. Live cell imaging using mouse primary aortic SMCs revealed that CaMK1α can translocate from the cytosol to the nucleus; and that this movement was blocked by nifedipine or a CaMKK inhibitor, STO609. Experiments using two types of Ca2+ chelators, ethylene glycol-bis(2-aminoethylether)-N,N,N',N'-tetraacetic acid (EGTA) and 1,2-bis(2-aminophenoxy)ethane-N,N,N',N'-tetraacetic acid (BAPTA), combined with caveolin-1 knockout (cav1-KO) mice showed that local Ca2+ events within caveolae are required to trigger this CaMK1α nuclear translocation. Importantly, overexpression of cav1 in isolated cav1-KO myocytes recovered the CaMK1α translocation. In SMCs freshly isolated from mesenteric arteries, CaMK1α was localized mainly within caveolae in the resting state. Membrane depolarization induced both nuclear translocation and phosphorylation of CaMK1α. These responses were inhibited by nifedipine, STO609, cav1-KO, or BAPTA. These new findings strongly suggest that CaMK1α can transduce Ca2+ signaling generated within or very near caveolae to the nucleus and thus, promote E-T coupling.

A molecular complex of Cav1.2/CaMKK2/CaMK1a in caveolae is responsible for vascular remodeling via excitation-transcription coupling.

Elevation of intracellular Ca2+ concentration ([Ca2+]i) activates Ca2+/calmodulin-dependent kinases (CaMK) and promotes gene transcription. This signaling pathway is referred to as excitation­transcription (E-T) coupling. Although vascular myocytes can exhibit E-T coupling, the molecular mechanisms and physiological/pathological roles are unknown. Multiscale analysis spanning from single molecules to whole organisms has revealed essential steps in mouse vascular myocyte E-T coupling. Upon a depolarizing stimulus, Ca2+ influx through Cav1.2 voltage-dependent Ca2+ channels activates CaMKK2 and CaMK1a, resulting in intranuclear CREB phosphorylation. Within caveolae, the formation of a molecular complex of Cav1.2/CaMKK2/CaMK1a is promoted in vascular myocytes. Live imaging using a genetically encoded Ca2+ indicator revealed direct activation of CaMKK2 by Ca2+ influx through Cav1.2 localized to caveolae. CaMK1a is phosphorylated by CaMKK2 at caveolae and translocated to the nucleus upon membrane depolarization. In addition, sustained depolarization of a mesenteric artery preparation induced genes related to chemotaxis, leukocyte adhesion, and inflammation, and these changes were reversed by inhibitors of Cav1.2, CaMKK2, and CaMK, or disruption of caveolae. In the context of pathophysiology, when the mesenteric artery was loaded by high pressure in vivo, we observed CREB phosphorylation in myocytes, macrophage accumulation at adventitia, and an increase in thickness and cross-sectional area of the tunica media. These changes were reduced in caveolin1-knockout mice or in mice treated with the CaMKK2 inhibitor STO609. In summary, E-T coupling depends on Cav1.2/CaMKK2/CaMK1a localized to caveolae, and this complex converts [Ca2+]i changes into gene transcription. This ultimately leads to macrophage accumulation and media remodeling for adaptation to increased circumferential stretch.