Abstract
Increased expression of K(Ca)3.1 has been found in vascular smooth muscle cells (SMC), macrophages, and T cells in atherosclerotic lesions from humans and mice. Pharmacological inhibition of K(Ca)3.1 in limiting atherosclerosis has been demonstrated in mice and pigs, however direct, loss-of-function, i.e. gene silencing, studies are absent. Therefore, we generated K(Ca)3.1(-/-)Apoe(-/-) (DKO) mice and assessed lesion development in the brachiocephalic artery (BCA) of DKO versus Apoe(-/-) mice on a Western diet for 3 months. In BCAs of DKO mice, lesion size and relative stenosis were reduced by ~70% compared to Apoe(-/-) mice, with no effect on medial or lumen area. Additionally, DKO mice exhibited a significant reduction in macrophage content within plaques compared to Apoe(-/-) mice, independent of sex. In vitro migration assays showed a significant reduction in migration of bone marrow-derived macrophages (BMDMs) from DKO mice compared to those from Apoe(-/-) mice. In vitro experiments using rat aortic smooth muscle cells revealed inhibition of PDGF-BB-induced MCP1/Ccl2 expression upon K(Ca)3.1 inhibition, while activation of K(Ca)3.1 further enhanced MCP1/Ccl2 expression. Both in vivo and in vitro analyses showed that silencing K(Ca)3.1 had no significant effect on the collagen content of plaque. RNAseq analysis of BCA samples from DKO and Apoe(-/-) mice revealed PPAR-dependent signaling as a potential key mediator of the reduction in atherosclerosis due to K(Ca)3.1 silencing. Overall, this study provides the first genetic evidence that K(Ca)3.1 is a critical regulator of atherosclerotic lesion development and composition and provides novel mechanistic insight into the link between K(Ca)3.1 and atherosclerosis.