Cytochrome B5 Reductase 3 And Xanthine Oxidase Coordinately Regulate Soluble Guanylyl Cyclase Physiological Redox State

In cardiovascular disease, oxidative stress can drive soluble guanylyl cyclase (sGC) heme oxidation resulting in the loss of the sGC heme (apo-sGC), the impairment of nitric oxide (NO) binding and cGMP production, and vasoconstriction. Consequently, a new class of therapeutic compounds sGC activators have been developed which target oxidized and apo-sGC to cause irreversible, NO-independent reactivation of cGMP production and vasodilation. While sGC activators have had varied clinical success, surprisingly few studies have defined the impact of NO-independent sGC activation on vascular physiology in healthy conditions. We found mesenteric and pulmonary arteries are two log orders more sensitive to NO-independent sGC activator BAY 58-2667 induced vasodilation than aorta; no difference in NO-dependent sGC vasodilation between vessels was observed. These data indicate the presence of an activatable physiological pool of oxidized and/or apo-sGC in pulmonary and mesenteric arteries. We recently published that smooth muscle cell cytochrome b5 reductase 3 (CYB5R3) acts to reduce oxidized heme sGC back to its NO-sensitive reduced heme state during vascular disease. We found transgenic CYB5R3 overexpression (CYB5R3 OE) mice were more resistant to BAY 58-2667 mesenteric artery vasodilation and blood pressure lowering compared to wild-type controls (n=5-9) under physiologic conditions. Also, healthy CYB5R3 OE pulmonary arteries had a near complete loss of BAY 58-2667 vasodilation suggesting both mesenteric and pulmonary arteries contain a pool of oxidized sGC. We next asked if physiological H 2 O 2 production accounts for changes in BAY 58-2667 responsiveness. We found using mitochondrial-specific catalase overexpression mice, that BAY 58-2667 vasodilation did not differ from controls in any vascular bed (n=4-6). We next tested whether xanthine oxidase (XO), which can produce H 2 O 2 at the endothelial cell surface of vessels, can impact physiological BAY 58-2667 vasodilation. We found that Febuxostat, a XO inhibitor, led to a significant decrease in mesenteric artery BAY 58-2667 induced vasodilation from ~70% to ~30% (n=6). Combined, these data provide evidence for CYB5R3 and XO as regulators of physiological sGC resistance artery vasodilation.