Circulating plasma xanthine oxidase contributes to vascular dysfunction in hypercholesterolemic rabbits.

Reactive oxygen species play a central role in vascular inflammation and atherogenesis, with enhanced superoxide (O2.-) production contributing significantly to impairment of nitric oxide (.NO)-dependent relaxation of vessels from cholesterol-fed rabbits. We investigated potential sources of O2.- production, which contribute to this loss of endothelium-dependent vascular responses. The vasorelaxation elicited by acetylcholine (ACh) in phenylephrine-contracted, aortic ring segments was impaired by cholesterol feeding. Pretreatment of aortic vessels with either heparin, which competes with xanthine oxidase (XO) for binding to sulfated glycosaminoglycans, or the XO inhibitor allopurinol resulted in a partial restoration (36-40% at 1 muM ACh) of ACh-dependent relaxation. Furthermore, O2.(-)-dependent lucigenin chemiluminescence, measured in intact ring segments from hypercholesterolemic rabbits, was decreased by addition of heparin, allopurinol or a chimeric, heparin-binding superoxide dismutase. XO activity was elevated more than two-fold in plasma of hypercholesterolemic rabbits. Incubation of vascular rings from rabbits on a normal diet with purified XO (10 milliunits/ml) also impaired .NO-dependent relaxation but only in the presence of purine substrate. As with vessels from hypercholesterolemic rabbits, this effect was prevented by heparin and allopurinol treatment. We hypothesize that increases in plasma cholesterol induce the release of XO into the circulation, where it binds to endothelial cell glycosaminoglycans. Only in hypercholesterolemic vessels is sufficient substrate available to sustain the production of O2.- and impair NO-dependent vasorelaxation. Chronically, the continued production of peroxynitrite, (ONOO-) which the simultaneous generation of NO and O2.- implies, may irreversibly impair vessel function.

Peroxynitrite stimulates vascular smooth muscle cell cyclic GMP synthesis.

Peroxynitrite stimulated the synthesis of cyclic GMP by rat aortic smooth muscle in a time- and dose-dependent manner. Peak formation of cyclic GMP occurred at 1 min with 100 microM peroxynitrite and was inhibited by oxyhemoglobin. Peroxynitrite was less potent than nitric oxide in stimulating cyclic GMP synthesis. Peroxynitrite also enhanced endothelial-dependent cyclic GMP synthesis, via generation of a long-lived substance, which was prevented by inhibition of glutathione synthesis. These data show that peroxynitrite stimulates cyclic GMP synthesis, inferring production of low yields of nitric oxide or associated derivatives. Additionally, vascular exposure to peroxynitrite potentiates endothelial-dependent activation of guanylate cyclase.

Degradation of uric acid during autocatalytic oxidation of oxyhemoglobin induced by sodium nitrite.

The oxidation of oxyhemoglobin produced by sodium nitrite occurs in two stages: 1) an initial slow phase followed by 2) a rapid autocatalytic phase that carries the reaction to completion. The length of the slow phase is extended when uric acid is added to the reaction mixture. As the concentration of uric acid increases, the length of the slow phase increases until a concentration is reached at which the rate of methemoglobin formation is nearly linear until the reaction is complete. Further increases in the concentration of uric acid do not affect the rate of the reaction in the slow phase. At low concentrations of uric acid, where an autocatalytic phase is reached, uric acid is degraded during the reaction. At concentrations of uric acid that keep the reaction in the linear phase, the uric acid is not degraded. It is concluded that uric acid may protect oxyhemoglobin by reacting with HbO2H to yield [HbOH]+ and the urate radical. The urate radical may react with a second molecule of HbO2H and become oxidized. At higher concentrations, the radical may undergo electron transfer with oxyhemoglobin to regenerate the uric acid and form methemoglobin.

2-Imidazolethiones protect ascorbic acid from oxidation induced by copper.

The oxidation of ascorbic acid to dehydroascorbic acid was accelerated by metal ions such as copper. This stimulation of ascorbate oxidation was inhibited by the addition of 2-imidazolethiones and other sulfhydryl-containing compounds, but not by 2-imidazolones or phenytoin. Although the 2-imidazolethiones interacted with copper, as shown by a decrease in the ultraviolet absorbance of the compounds, the product formed still protected ascorbate from oxidation. The 2-imidazolethiones are proposed to complex copper through their free -SH groups.

Hemolysis of chicken erythrocytes by t-butyl hydroperoxide and protection by plasma.

Chicken erythrocytes treated with 100-microM t-butyl hydroperoxide (t-BHP) were more than 80% hemolyzed in 2 h and more than 90% hemolyzed after 4 h of incubation. Autologous plasma retarded the rate of hemolysis of chicken red cells produced by t-BHP. Dialysis of chicken plasma resulted in a marked decrease in the ability of plasma to protect erythrocytes from hemolysis by t-BHP. Low molecular weight components of plasma such as uric acid are hypothesized to account for much of the dialyzable material that protects red cells from hemolysis.