SVEP1 is a new regulator of arterial tone

Abstract Funding Acknowledgements Type of funding sources: Foundation. Main funding source(s): British Heart Foundation Introduction Vascular tone is regulated by the relative contractile state of vascular smooth muscle cells (VSMCs). Several integrins can directly modulate VSMC contraction by regulating calcium influx through L-type voltage-gated Ca2+ channels (VGCCs). Integrin α9β1 has been identified as preventing exaggerated airway bronchiole contraction. Genetic variants in ITGA9, which encodes the α9 subunit of integrin α9β1, and SVEP1, a ligand for integrin α9β1, are associated with elevated blood pressure, however, neither SVEP1 nor integrin α9β1 have a reported role in vasoregulation. Purpose To determine whether SVEP1 and integrin α9β1 regulate blood vessel contraction. Methods & Results Animal experimentation was performed according to ARRIVE (Animal Research: Reporting of In Vivo Experiments) guidelines and "the Principles of laboratory animal care". Immunocytochemical staining showed both ligand and receptor co-localised within the medial layer of the aorta, and in smooth muscle cells in the mesenteric artery. siRNA inhibition of SVEP1 or integrin α9β1 significantly enhanced real-time [Ca2+]i release in isolated human VSMCs to several Gαq/11-vasoconstrictors and to UTP in VSMCs isolated from Svep1+/- mice (Fig. 1A, n=5, P<0.0001). This enhanced cellular contraction was confirmed in blood vessels by wire myography where aortic rings and mesenteric arteries (Fig. 1B, n=10 P<0.0001) from Svep1+/- mice contracted at significantly higher levels than littermate controls. Similar responses were seen in aortic rings when integrin α9β1 was inhibited using the small molecule inhibitor BOP (n=10 P<0.001). Inhibition of VGCCs using nifidepine, or PKC using bisindolylmaleimide (I) prevented this enhanced contraction, suggesting this effect is mediated via VGCCs in a PKC dependent mechanism. Conclusions Our studies reveal a novel role for SVEP1 and integrin α9β1 in reducing vascular hyper-contractility in response to a range of vasoconstrictor agonists through an L-type voltage gated Ca2+ channel-mediated effect. This regulatory mechanism could suggest a possible explanation for the genetic associations with blood pressure, and provide a new treatment strategy for hypertension.