Carvedilol suppresses coronary artery spasm in A-kinase anchoring protein 150 knockout mouse

Abstract

Abstract Backgrounds A-kinase anchoring proteins (AKAPs) act as scaffold to regulate activation of protein kinases and subsequent downstream signaling. AKAP 150 interacts with protein kinase A and protein kinase C, and has a critical role in regulating L-type calcium channel activity. We previously reported enhanced phospholipase C activity as an important mechanism of coronary spastic angina (CSA), known as Prinzmetal’s angina. Coronary artery spasm was induced by intravenous ergometrine injection in mouse model of vascular smooth muscle cell (VSMC)-specific enhanced phospholipase C activity concomitantly with enhanced intracellular Ca2+ concentration ([Ca2+]i). Then, we hypothesized that coronary artery spasm would be inhibited by AKAP 150 knockout, however, coronary artery spasm was unexpectedly induced in AKAP 150 knockout (AKAP-KO) mice without affecting [Ca2+]i, suggesting that AKAP-KO mouse is an unique model of CSA independent of [Ca2+]i. Previous report showed that AKAP-KO mice have a high Ca2+/calmodulin-dependent protein kinase (CaMK) II activity, and carvedilol, a non-selective beta-adrenergic receptor antagonist, inhibits CaMK II activity. Aim We tested the hypothesis that carvedilol could prevent coronary artery spasm via inhibiting CaMK II activity, which is a key molecule to regulate VSMC contraction, in AKAP-KO mice. Methods and Results We pretreated 14-18-weeks-old AKAP-KO mice with intraperitoneal injection of carvedilol (2.5mg/kg), propranolol (20mg/kg), or vehicle (control). Coronary artery spasm, evaluated by ST-segment elevation on lead II of body surface electrocardiogram, was induced by intravenous ergometrine injection (30mg/kg) in all controls (5/5, 100%) and all propranolol-treated mice (5/5, 100%), whereas it tended to be inhibited in carvedilol-treated mice (3/6, 50%) (p=0.08 vs control). In isolated VSMCs obtained from the aorta of AKAO-KO mice, the changes in [Ca2+]i from baseline in response to acetylcholine (ACh, 100μM) did not differ among the groups of pretreatment with carvedilol (10μM), propranolol (10μM), or vehicle, indicating that coronary artery spasm in AKAP-KO mice was induced by Ca2+-independent mechanism. In response to ACh, the phosphorylation of CaMK II was tended to be decreased (p=0.07), and the phosphorylation of myosin light chain was decreased (p<0.05) in VSMCs treated with carvedilol compared with control. Conclusions Carvedilol may inhibit coronary artery spasm probably via inhibiting CaMK II activity in AKAP-KO mice. Our results may provide a new paradigm into the pathogenesis of CSA as a model of enhanced Ca2+ sensitivity and important clinical implications for the mechanism of calcium channel antagonist-refractory coronary artery spasm.