Cross-talk between NO and oxyradicals, a supersystem that regulates energy metabolism and survival of animals

Mammalian tissues have large amounts of available ATP which are generated by oxidative phosphorylation in mitochondria. For the maintenance of the human body, a large amount of oxygen is required to regenerate these ATP molecules. A small fraction of the inspired oxygen is converted to superoxide radical and related metabolites even under physiological conditions. Most reactive oxygen species react rapidly with a variety of molecules thereby interfering with cellular functions and induce various diseases. Nitric oxide (NO) is an unstable gaseous radical with high affinity for various molecules, such as hemeproteins, thiols, and related radicals. NO easily penetrates through cell membrane/lipid bilayers, forms dissociable complexes with these molecules and modulates cellular metabolism and functions. Because NO has an extremely high affinity for the superoxide radical, the occurrence of the latter might decrease the biological function of NO. Thus, superoxide radicals in and around vascular endothelial cells play critical roles in the pathogenesis of hypertension and vasogenic tissue injury. Because NO also reacts with molecular oxygen, it rapidly loses its biological activity, particularly under ambient atmospheric conditions where the oxygen tension is unphysiologically high. Thus, biological functions of NO are determined by the local concentrations of molecular oxygen and superoxide radicals. NO also inhibits electron transfer reaction and ATP synthesis in mitochondria and aerobic bacteria, such as E. coli; the inhibitory effects are also enhanced by hypoxia. Thus, the cross-talk between NO, molecular oxygen and oxyradicals play critical roles in the regulation of energy metabolism, fates and the survival of aerobic organisms. The present work describes the pathophysiological significance of the supersystem driven by the cross-talk between NO and oxyradicals.