Correction of hypoxic state by metabolic precursors of endogenous activator of mitochondrial ATP-dependent K+channels

Abstract

Aim. The antihypoxic properties of uridine and uridine-5'-monophosphate (UMP), which are the metabolic precursors of the natural activator of mitochondrial ATP-dependent K+ channels (mitoKATP channels) uridine diphosphat were investigated on the models of hypoxic hypoxia with hypercapnia (HHH), hemic hypoxia and local circulatory hypoxia. Methods. HHH was created in males and females white mice weighing 28-30 g. The animals were placed one by one in hermetically closed container and the duration of their life was determined. The antihypoxic activity of the substances was compared with the reference anthypoxant amtizole (50 mg/kg). Hemic hypoxia was caused in Wistar rats weighing 350-370 g by the injection of sodium nitrite (intramuscularly, 100 mg/kg). Uridine or UMP 30 mg/kg was injected intraperitoneally 30 minutes before the onset of HHH and hemic hypoxia. Local circulatory hypoxia was modeled in male Wistar rats weighing 250-300 g. Acute coronary occlusion lasting 60 min was reproduced by legation of descending branch of the left coronary artery (LCA). Uridine or UMP (30 mg/kg) was administered intravenously 5 minutes prior to LCA occlusion. Selective blocker of mitoKATP channels 5-hydroxydecanoate (5 mg/kg, intravenously, 5 minutes prior uridine or UMP) was used to determine the role of these channels in the mechanism of antihypoxic action of the studied drugs. The volume of the damaged myocardium was used as the marker of antihypoxic activity of uridine and UMP. Results. Different resistance to hypoxia in female and male mice was observed in HHH. The female mice were more resistant, their life duration was 43% more than the males. Uridine and UMP displayed antihypoxic activity only in male mice, increasing their life duration by 25% and 20% respectively. This effect was 2 times less than that of amtisol. In similar conditions in females mice the preparations did not show a protective effect. In hemic hypoxia the life duration of rats treated with uridine and UMP did not differ from the control values. Circulatory hypoxia, caused by occlusion of the LCA, led to the formation of a local zone of myocardial damage. Uridine or UMP decreased the damage zone in 2 and 3,5 times respectively. The inhibitor of mitoKATP channels blocked the protective effect of these compounds. Conclusion. Uridine and UMP have a distinct antihypoxic effect in HHH and a marked protective effect in local circulatory hypoxia. The antihypoxic activity of druges in HHH is manifested differently in female and male mice. It may be due to sexual differences in the resistance to hypoxia. The maximum effect is observed in male who have initially low resistance to oxygen deficiency. The mechanism of the protective action of uridine and UMP in the circulatory hypoxia is associated with the activation of mitoKATP channels.