LAUSR

Mutations in CULLIN3 gene (causing in-frame deletion of exon 9) cause hypertension in humans. The hypertension phenotype is unlikely to be driven by renal tubular mechanisms, as kidney-specific deletion of Cullin3 (Cul3) in mice results in hypotension, not hypertension. We have recently shown that smooth muscle expression of Cul3Δ9 causes vascular dysfunction and elevation of blood pressure (BP) via augmented RhoA/Rho-kinase signaling, strongly supporting a vascular role of Cul3 in BP regulation. To test the importance of endothelial Cul3 in vivo , we bred the conditionally activatable Cul3α9 mice with Tek-CRE ERT2 mice specifically expressing tamoxifen-inducible Cre-recombinase in the endothelium. The resultant mice (E-Cul3α9) exhibited impaired endothelial-dependent relaxation in the basilar artery (maximal relaxation in response to 30 μM acetylcholine, 45% vs 85% in control mice) and carotid artery. No difference in smooth muscle function was observed. Moreover, E-Cul3α9 mice exhibited nocturnal hypertension as determined by radiotelemetry (night time peak BP, 141±3 mmHg vs 122±3 mmHg). However no difference was seen in daytime pressure. E-Cul3α9 mice also exhibited arterial stiffening as indicated by elevated pulse wave velocity (3.7±0.3 m/s vs 2.7±0.1 m/s). To determine the molecular mechanism of endothelial dysfunction, primary aortic endothelial cells were isolated from mice carrying the inducible Cul3α9 construct and Cul3α9 expression was robustly induced by adenovirus carrying Cre recombinase gene in vitro . Cul3α9 acted in a dominant negative manner by interfering with expression and function of wild type Cul3, leading to impaired turnover of a Cul3 substrate protein phosphatase 2A, marked reduction in phosphorylated eNOS, and decreased nitric oxide production. Treatment with a selective PP2A inhibitor Okadaic Acid (1 nM) rescued Cul3α9-induced impairment of eNOS activity. These data define a novel pathway involving Cullin-3/PP2A/phospho-eNOS in the endothelium. Selective endothelial expression of Cul3α9 partially phenocopies the hypertension observed in Cul3α9 patients, suggesting that mutations in Cullin-3 cause human hypertension in part through a vascular mechanism characterized by endothelial dysfunction.