Abstract

ObjectiveThe objective of this investigation was to demonstrate that in vivo induction of hypertension (HTN) and in vitro cyclic stretch of aortic VSMCs can cause SGK-1-dependent production of cytokines to promote macrophage accumulation as agents of vascular remodeling. MethodsHTN was induced in C57Bl/6 mice with AngiotensinII (AngII) infusion (1.46mg/kg/day x 21 days) with or without systemic infusion of EMD638683 (2.5mg/kg/day x 21 days), a selective SGK-1 inhibitor. Systolic blood pressure (SBP) was recorded on days 0 and 21. At terminal study, abdominal aortas were harvested to quantify SGK-1 activity (pSGK-1:SGK-1) by immunoblot. Additional replicates were digested and analyzed by flow cytometry for abundance of CD11b+/F4-80+ cells (macrophages). Plasma was analyzed by ELISA to quantify IL-6 and MCP-1. Aortic VSMCs from wild-type (WT) mice were subjected to 12% biaxial cyclic stretch for 3 or 12 hours +/- EMD638683 (10M) and +/- SGK-1siRNA with subsequent QPCR for IL-6 and MCP-1 expression. Culture media was analyzed by ELISA for IL-6 and MCP-1. Aortic VSMCs from SGK-1flox+/+ mice were transfected with Cre-Adenovirus to knockout SGK-1 (SGK-1KO VSMCs) and underwent parallel tension experimentation. Computational modeling was employed to simulate VSMC signaling due to mechanical strain and AngII. Statistical analysis included ANOVA with significance at p<0.05. ResultsSGK-1 activity (pSGK-1:SGK-1) was upregulated in the abdominal aorta of mice with HTN and significantly reduced by treatment with EMD638683. Concurrently, increased CD11b+/F4-80+ cells and plasma IL-6 levels in the HTN group and reduction with EMD638683 was observed. This mirrored the increased abundance of IL-6 in media from Stretch WT VSMCs, and attenuation of the effect with EMD638683. Treating WT VSMCs with SGK-1siRNA likewise inhibited IL-6 expression. MCP-1 also demonstrated increased expression and secretion into the media in WT VSMCs with Stretch. Further supporting the integral role of mechanical signaling through SGK-1, target gene expression and cytokine secretion was unchanged in SGK-1KO VSMCs with Stretch, and computer modeling confirmed SGK-1 as an intersecting node of signaling due to mechanical strain and AngII. In summation, this data suggests a biomechanical link between aortic VSMC mechanotransduction and cytokine production to promote macrophage accumulation, mediated in-part by SGK-1 activation. ConclusionMechanotransduction through SGK-1 is instrumental in pro-inflammatory cytokine production and aortic macrophage accumulation in systemic HTN, therefore further investigation into targeting this kinase may present opportunities to modulate hypertensive vascular remodeling.