The Rho/Rac exchange factor Vav2 controls nitric oxide–dependent responses in mouse vascular smooth muscle cells
Vincent Sauzeau, María A. Sevilla, María J. Montero, Xosé R. Bustelo
Vincent Sauzeau, María A. Sevilla, María J. Montero, Xosé R. Bustelo
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Research Article Vascular biology

The Rho/Rac exchange factor Vav2 controls nitric oxide–dependent responses in mouse vascular smooth muscle cells

Abstract

The regulation of arterial contractility is essential for blood pressure control. The GTPase RhoA promotes vasoconstriction by modulating the cytoskeleton of vascular smooth muscle cells. Whether other Rho/Rac pathways contribute to blood pressure regulation remains unknown. By studying a hypertensive knockout mouse lacking the Rho/Rac activator Vav2, we have discovered a new signaling pathway involving Vav2, the GTPase Rac1, and the serine/threonine kinase Pak that contributes to nitric oxide–triggered blood vessel relaxation and normotensia. This pathway mediated the Pak-dependent inhibition of phosphodiesterase type 5, a process that favored RhoA inactivation and the subsequent depolymerization of the F-actin cytoskeleton in vascular smooth muscle cells. The inhibition of phosphodiesterase type 5 required its physical interaction with autophosphorylated Pak1 but, unexpectedly, occurred without detectable transphosphorylation events between those 2 proteins. The administration of phosphodiesterase type 5 inhibitors prevented the development of hypertension and cardiovascular disease in Vav2-deficient animals, demonstrating the involvement of this new pathway in blood pressure regulation. Taken together, these results unveil one cause of the cardiovascular phenotype of Vav2-knockout mice, identify a new Rac1/Pak1 signaling pathway, and provide a mechanistic framework for better understanding blood pressure control in physiological and pathological states.

Authors

Vincent Sauzeau, María A. Sevilla, María J. Montero, Xosé R. Bustelo

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Figure 2

Vav2 is essential for NO-triggered F-actin depolymerization and Rho/Rock pathway inactivation in vSMCs.

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Vav2 is essential for NO-triggered F-actin depolymerization and Rho/Rock...
(A) Representative images of F-actin (red) and G-actin (green) in vSMCs of the indicated genotypes that were treated (+) or untreated (–) with SNP for 1 hour as described. Scale bar: 20 μm. (B) F-actin/G-actin ratio in vSMCs of the indicated genotypes before (–) and after (+) SNP stimulation (n ≥ 4). #P < 0.05; *P < 0.01 compared with either nonstimulated wild-type cells (which were given an arbitrary value of 1) or the indicated nonstimulated cells (brackets). NS, values not statistically significant. Data are shown as mean + SEM. (C) Top panel: membrane localization of RhoA in wild-type and Vav2–/– vSMCs before (–) and after (+) SNP stimulation for 1 hour. Remainder of panels: phosphorylation and total expression levels of the indicated proteins in vSMCs before and after SNP stimulation. p-, phospho-protein. (D) Vav2–/– vSMCs were infected with the indicated retroviruses and left untreated (–) or treated (+) with SNP for 1 hour as shown; their F-actin cytoskeleton was visualized by fluorescence microscopy. F-actin and GFP-derived fluorescence signals are shown in red and green, respectively. Scale bar: 20 μm. *, an EGFP-positive cell showing F-actin depolymerization upon SNP stimulation. (E) Anti-Vav2 (top panel) and antitubulin (bottom panel) immunoblot analysis of total cellular lysates obtained from the indicated retroviral infections of Vav2–/– vSMCs. (F) Antiphosphotyrosine (top panel) and anti-Vav2 (bottom panel) immunoblot analysis of anti-Vav2 immunoprecipitates obtained from lysates of wild-type vSMCs cultured under the indicated conditions.