The Underlying Mechanism of HNO Production by the Myoglobin-Mediated Oxidation of Hydroxylamine.

Azanone (HNO, nitroxyl) is a highly reactive molecule that, in the past few years, has drawn significant interest because of its pharmacological properties. However, the understanding of how, when, and where endogenous HNO is produced remains a matter of discussion. In this study, we examined the ability of myoglobin to produce HNO via the peroxidation of hydroxylamine with H2O2 using both experimental and computational approaches. The production of HNO was confirmed using an azanone selective electrochemical method and by the detection of N2O using FTIR. The catalytic capacity of myoglobin was characterized by the determination of the turnover number. The reaction kinetics of the hydroxylamine peroxidation were studied by both electrochemical and UV-vis methods. Further evidence about the reaction mechanism was obtained by EPR spectroscopy. Additionally, quantum mechanical/molecular mechanics experiments were performed to calculate the energy barrier for HNO production and to gain insight into the reaction mechanism. Our results confirm that myoglobin produces HNO via the peroxidation of hydroxylamine with a great catalytic capacity. In addition, our mechanistic study allows us to state that the Mb ferryl state is the most likely intermediate that reacts with hydroxylamine, yielding important evidence for endogenous HNO generation.