Nitric oxide regulates oxygen uptake and hydrogen peroxide release by the isolated beating rat heart.

Isolated rat heart perfused with 1.5-7.5 microM NO solutions or bradykinin, which activates endothelial NO synthase, showed a dose-dependent decrease in myocardial O2 uptake from 3.2 +/- 0.3 to 1.6 +/- 0.1 (7.5 microM NO, n = 18, P < 0.05) and to 1.2 +/- 0.1 microM O2.min-1.g tissue-1 (10 microM bradykinin, n = 10, P < 0.05). Perfused NO concentrations correlated with an induced release of hydrogen peroxide (H2O2) in the effluent (r = 0.99, P < 0.01). NO markedly decreased the O2 uptake of isolated rat heart mitochondria (50% inhibition at 0.4 microM NO, r = 0.99, P < 0.001). Cytochrome spectra in NO-treated submitochondrial particles showed a double inhibition of electron transfer at cytochrome oxidase and between cytochrome b and cytochrome c, which accounts for the effects in O2 uptake and H2O2 release. Most NO was bound to myoglobin; this fact is consistent with NO steady-state concentrations of 0.1-0.3 microM, which affect mitochondria. In the intact heart, finely adjusted NO concentrations regulate mitochondrial O2 uptake and superoxide anion production (reflected by H2O2), which in turn contributes to the physiological clearance of NO through peroxynitrite formation.

Differential inhibitory action of nitric oxide and peroxynitrite on mitochondrial electron transport.

Various authors have suggested that nitric oxide (.NO) exerts cytotoxic effects through the inhibition of cellular respiration. Indeed, in intact cells .NO inhibits glutamate-malate (complex I) as well as succinate (complex II)-supported mitochondrial electron transport, without affecting TMPD/ascorbate (complex IV)-dependent respiration. However, experiments in our lab using isolated rat heart mitochondria indicated that authentic .NO inhibited electron transport mostly by reversible binding to the terminal oxidase, cytochrome a3, having a less significant effect on complex II- and no effect on complex I-electron transport components. The inhibitory action of .NO was more profound at lower oxygen tensions and resulted in differential spectra similar to that observed in dithionite-treated mitochondria. On the other hand, continuous fluxes of .NO plus superoxide (O.(2)(-)), which lead to formation of micromolar steady-state levels of peroxynitrite anion (ONOO-), caused a strong inhibition of complex I- and complex II-dependent mitochondrial oxygen consumption and significantly inhibited the activities of succinate dehydrogenase and ATPase, without affecting complex IV-dependent respiration and cytochrome c oxidase activity. In conclusion, even though nitric oxide can directly cause a transient inhibition of electron transport, the inhibition pattern of mitochondrial respiration observed in the presence of peroxynitrite is the one that closely resembles that found secondary to .NO interactions with intact cells and strongly points to peroxynitrite as the ultimate reactive intermediate accounting for nitric oxide-dependent inactivation of electron transport components and ATPase in living cells and tissues.

Effect of hypoxia on the intracellular chloride activity of cultured glomus cells of the rat carotid body.

Clusters of rat carotid body glomus cells were cultured for 1 to 12 days. Preparations were exposed to a control PO2 of 134.9 +/- 1.1 torr (mean +/- SE), and an external chloride activity, ao(Cl), of 105.6 +/- 2 mM. Thirty-six cells had a resting potential (Em) of -25.2 +/- 0.9 mV. The intracellular chloride activity, ai(Cl), was 32.8 +/- 1.1 mM, and the calculated chloride equilibrium potential (ECl) was -30.9 +/- 0.9 mV. ECl was more negative than Em, indicating that Cl- ions are not passively distributed. Hypoxia (5.4 +/- 0.8 torr), induced by Na-dithionite (Na2S2O4) 1.25 mM, elicited cell depolarization, increased ai(Cl) and a less negative ECl in about 80% of the cells. Fourteen per cent of the cells showed opposite effects. It is hypothesized that the increased ai(Cl) occurs because an outward-directed chloride pump is blocked by hypoxia. This effect is aided by depolarization of the cell. Decreased ai(Cl) may be due to cell hyperpolarization.

Luminol chemiluminescence using xanthine and hypoxanthine as xanthine oxidase substrates.

Luminol chemiluminescence induced by the xanthine or hypoxanthine-O2-xanthine oxidase system is analyzed and compared. Characteristics of the light emission curves were examined considering the conventional reaction scheme for the oxidation of both substrates in the presence of xanthine oxidase. The ratio of the areas of the rate of superoxide production during substrate oxidation to uric acid. The O2-. to uric acid ratio for each substrate can account for differences in xanthine and hypoxanthine-supported light emission, since uric acid is a strong inhibitor of O2-.-dependent luminol chemiluminescence. These results are consistent with a free radical scavenging role for uric acid. A similar but weaker scavenging effect of xanthine may also contribute to the observed differences in chemiluminescent yields between both substrates.