Oxygenation of biomembranes by mammalian lipoxygenases: The role of ubiquinone
Autor: | Martina Hellwing, Kerstin Schnurr, Hartmut Kühn, Samuel M. Rapoport, Tankred Schewe, Britta Seidemann, Peter Jungblut |
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Rok vydání: | 1996 |
Předmět: |
Erythrocytes
Free Radicals Ubiquinone Radical Oxidative phosphorylation Biochemistry Mitochondria Heart Electron Transport Superoxide dismutase Lipid peroxidation chemistry.chemical_compound Multienzyme Complexes Physiology (medical) Animals Arachidonate 15-Lipoxygenase Vitamin E Electrophoresis Gel Two-Dimensional NADH NADPH Oxidoreductases Submitochondrial particle Amino Acids Chromatography High Pressure Liquid Heart metabolism Mammals biology Chemistry Succinate dehydrogenase Cell Membrane Keto Acids Oxygen Succinate Dehydrogenase Models Chemical Catalase Fatty Acids Unsaturated biology.protein Cattle Lipid Peroxidation Rabbits |
Zdroj: | Free Radical Biology and Medicine. 20:11-21 |
ISSN: | 0891-5849 |
Popis: | 15-Lipoxygenase is implicated in the selective breakdown of mitochondria during red cell maturation by virtue of its capability of directly oxygenating phospholipids. To address the reason of the selectivity for mitochondria, we studied the reaction of pure rabbit 15-lipoxygenase with beef heart submitochondrial particles in vitro. This reaction is characterised by a loss of polyenoic fatty acids, the formation of phospholipid-bound hydroperoxy- and keto-polyenoic fatty acids, and oxidative modification of membrane proteins. The total oxygen uptake exceeds the formation of oxygenated polyenoic fatty acids several times. The excessive oxygen uptake was not inhibited by 3,5-di-tert-butyl-4-hydroxytoluene or by respiratory inhibitors, but was partly suppressed by superoxide dismutase plus catalase, salicylate, or mannitol. Pentane-extraction of the submitochondrial particles abolished the excessive oxygen uptake, whereas reconstitution with ubiquinone- 50 restored it. A marked excessive oxygen uptake did not occur during the analogous reaction with erythrocyte ghosts. It is proposed that ubiquinone-50 triggers the formation of hydroxyl radicals from 15-lipoxygenase-derived hydroperoxy-lipids via a Fenton-type reaction driven by ubisemiquinone radicals. A new prooxidative function of ubiquinone in the biologically programmed degradation of mitochondria in certain types of cells is proposed. |
Databáze: | OpenAIRE |
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