Abstract
NADH cytochrome b5 reductase 3 (CYB5R3) is critical for reductive reactions such as fatty acid elongation, cholesterol biosynthesis, drug metabolism, and methemoglobin reduction. Although the physiological and metabolic importance of CYB5R3 has been established in hepatocytes and erythrocytes, emerging investigations suggest that CYB5R3 is critical for nitric oxide signaling and vascular function. However, advancement toward fully understanding CYB5R3 function has been limited due to a lack of potent small molecule inhibitors. Because of this restriction, we modeled the binding mode of propylthiouracil, a weak inhibitor of CYB5R3 (IC50 = ∼275 μM), and used it as a guide to predict thiouracil-biased inhibitors from the set of commercially available compounds in the ZINC database. Using this approach, we validated two new potent derivatives of propylthiouracil, ZINC05626394 (IC50 = 10.81 μM) and ZINC39395747 (IC50 = 9.14 μM), both of which inhibit CYB5R3 activity in cultured cells. Moreover, we found that ZINC39395747 significantly increased NO bioavailability in renal vascular cells, augmented renal blood flow, and decreased systemic blood pressure in response to vasoconstrictors in spontaneously hypertensive rats. These compounds will serve as a new tool to examine the biological functions of CYB5R3 in physiology and disease and also as a platform for new drug development.
Highlights
Cytochrome b5 reductase 3 (CYB5R3) regulates nitric oxide (NO) diffusion in the artery wall
Recent evidence has demonstrated that loss of endothelial cell CYB5R3 increases NO bioavailability in the vascular wall by regulating the redox state of ␣ globin [10]
Through superpositioning of PTU in the NADH binding pocket of CYB5R3 followed by a pharmacophore screen of commercially available PTU derivatives, we successfully identified two compounds (ZINC05626394 and ZINC39395747) that decrease the IC50 by Ͼ30-fold compared with PTU
Summary
Cytochrome b5 reductase 3 (CYB5R3) regulates nitric oxide (NO) diffusion in the artery wall. We found that ZINC39395747 significantly increased NO bioavailability in renal vascular cells, augmented renal blood flow, and decreased systemic blood pressure in response to vasoconstrictors in spontaneously hypertensive rats These compounds will serve as a new tool to examine the biological functions of CYB5R3 in physiology and disease and as a platform for new drug development. In vivo inhibition of CYB5R3 with ZINC39395747 resulted in augmented renal blood flow and decreased blood pressure in spontaneously hypertensive rats infused with vasoconstrictors Together, these results uncover novel compounds that inhibit CYB5R3 activity and can increase NO bioavailability in vascular cells. These results uncover novel compounds that inhibit CYB5R3 activity and can increase NO bioavailability in vascular cells These compounds can serve as a basis for further drug development to improve blood flow and possibly for treatment of hypertension and cardiovascular disease. These compounds will be a valuable tool in understanding the diverse biological roles of CYB5R3 in health and disease
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