Résumé
The antioxidant ability of nitric oxide (NO) generated by a chemical donor and of commercially available antioxidant preparations was assayed. SNAP (S-Nitroso-N-acetylpenicilamine) was used as the NO donor, and Ginkgo biloba, wheat and alfalfa preparations were tested. Lipid peroxidation was assayed by EPR employing a reaction system consisting of rat liver microsomes, ADP, FeCl3, NADPH and POBN in phosphate buffer, pH=7.4. In vitro NO exposure decreased microsomal lipid peroxidation in a dose-dependent manner. The dose responsible for inhibiting the microsomal content of lipid radical adducts by 50% (LD50) for SNAP was 550 microM (NO generation rate 0.1 microM/min). The addition of 50 microM hemoglobin to the incubation media prevented NO effect on lipid peroxidation. The addition of an amount of the antioxidant preparations equivalent to the LD50 doses inhibited lipid peroxidation by 21, 15, and 33% for wheat, alfalfa, ginkgo biloba preparations respectively in the presence of 550 microM SNAP. We detected a decrease in the content of lipid radical adducts after simultaneous supplementation, although it was less than 50%, even when LD50 doses of the products were added. This suggests that NO and the natural antioxidants inhibit lipid peroxidation by a mechanism that has both common and non-shared features.
Sujets)
Animaux , Mâle , Rats , Antioxydants/pharmacologie , Donneur d'oxyde nitrique/pharmacologie , Microsomes du foie/effets des médicaments et des substances chimiques , Peroxydation lipidique/effets des médicaments et des substances chimiques , N-Acétyl-S-nitroso-pénicillamine/pharmacologie , Extraits de plantes/pharmacologie , Ginkgo biloba , Dose létale 50 , Medicago sativa , Microsomes du foie/métabolisme , Rat Wistar , Piégeage de spin , TriticumRésumé
1. Hepatotoxicity is the most common finding in patients with iron overload since the liver is the major recipient of iron excess, even though the kidney could be a target of iron toxicity. The effect of iron overload was studied in the early stages after iron-dextran injection inrats, as a model for secondary hemocromatosis. 2. Total hepatic and kidney iron content was markedly over control values 20h after the iron administration. Plasma GOT, GPT and LDH activities were not affected, suggesting that liver cell permeability was not affected by necrosis. 3. Spontaneous liver chemiluminescence was measured as an indicator of oxidative stress and lipid peroxidation. Light emission was increased four-fold 6 h after iron supplementation. 4. Increases in the generation of thiobarbituric acid reactive substances (TBARS) in liver and kidney homogenates were detected after iron administration. 5. The activities of catalase, SOD and glutathione peroxidase were determined. Enzymatic activities declined in liver homogenates by 25, 36 and 32 por cento, respectively, 20 h after iron injection. These activities were not affected in kidney as compared to control values, except for SOD activity that was decreased by 26 por cento. 6. The content of alfa-tocopherol was decreased by 31 por cento in whole kidney homogenates and by 40 por cento in plasma. 7. Our data indicate that lipid peroxidation occurs after mild iron overload both in liver and kidney. Enzymatic antioxidantes are consumed significantly in liver and alfa-tocopherol content decreases in kidney, suggesting an organ-specific antioxidant effect