Gene/Protein Disease Symptom Drug Enzyme Compound
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Query: EC:1.6.5.2 (NQO1)
 6,196 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

The vital role of coenzyme Q in mitochondrial electron transfer and its regulation, and in energy conservation, is well established. However, the role of coenzyme Q in free oxyradical formation and as an antioxidant remains controversial. Demonstration of the existence of the semiquinone form of coenzyme Q during electron transport, coupled with recent evidence that hydrogen peroxide (but not molecular oxygen) may act as an oxidant of the semiquinone, suggests that the highly reactive OH. radical may be formed from the semiquinone. On the other hand, data exist implicating the Fe-S species as the source of electron transfer chain, free radical production. Additional data exist suggesting instead that the unpaired electron of the coenzyme Q semiquinone most likely dismutases superoxide radicals. These concepts and those arising from observations at several levels of organization including subcellular systems, intact animals, and human subjects in the clinical setting, supporting the concept of reduced coenzyme Q as an antioxidant, will be presented. The results of recent studies on the interaction between the two-electron quinone reductase--DT diaphorase and coenzyme Q10 will be presented. The possibility that superoxide dismutase may interact with reduced coenzyme Q, in conjunction with DT diaphorase inhibiting its autoxidation, will be described. The regulation of cellular coenzyme Q concentrations during oxidative stress accompanying aerobic exercise, resulting in increased protection from free radical damage, will also be presented.
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PMID:An analysis of the role of coenzyme Q in free radical generation and as an antioxidant. 133 30

Coenzyme Q (CoQ0) and other quinones were shown to be potent insulin secretagogues in the isolated pancreatic islet. The order of potency was CoQ0 congruent to benzoquinone congruent to hydroquinone-menadione. CoQ6 and CoQ10 (ubiquinone), duroquinone and durohydroquinone did not stimulate insulin release. CoQ0's insulinotropism was enhanced in calcium-free medium and CoQ0 appeared to stimulate only the second phase of insulin release. CoQ0 inhibited inositol mono-, bis- and trisphosphate formation. Inhibitors of mitochondrial respiration (rotenone, antimycin A, FCCP and cyanide) and the calcium channel blocker verapamil, did not inhibit CoQ0-induced insulin release. Dicumarol, an inhibitor of quinone reductase, did not inhibit CoQ0-induced insulin release, but it did inhibit glucose-induced insulin release suggesting that the enzyme and quinones play a role in glucose-induced insulin release. Quinones may stimulate insulin release by mimicking physiologically-occurring quinones, such as CoQ10, by acting on the plasma membrane or in the cytosol. Exogenous quinones may bypass the quinone reductase reaction, as well as many reactions important for exocytosis.
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PMID:Stimulation of insulin release from pancreatic islets by quinones. 172 Mar 33

A water-soluble quinone, coenzyme Q0 (CoQ0), was shown to stimulate insulin release, and dicumarol, an inhibitor of quinone reductase, inhibited glucose-induced insulin release in pancreatic islets. Since this suggested that quinone reductase might play some role in physiological insulin release, this enzyme was characterized in islets. More than 90% of the total activity was located in the cytosol, but the specific enzyme activity was highest in the microsomal fraction. The relative rates of activity with various substrates (CoQ0 approximately equal to durohydroquinone greater than menadione greater than duroquinone greater than CoQ6 = CoQ10 greater than ferricyanide) were similar to those described previously for quinone reductase from liver Dicumarol, chlorpromazine, and T3 were much more potent inhibitors of the enzyme when NADPH was the coenzyme than when NADH was the coenzyme. Dicumarol was the most potent inhibitor. The enzyme was not inhibited by rotenone. Islets ranked second to liver in quinone reductase activity, but the activity in islets was much closer to that found in all other tissues examined. Quinone reductase may play a role in insulin secretion.
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PMID:Quinone reductase enzyme activity in pancreatic islets. 187 76

DT-diaphorase [NAD(P)H dehydrogenase (quinone), EC 1.6.99.2] is a flavoprotein enzyme widely distributed in the cytosolic fractions of various animal tissues. It is also called menadione reductase or NAD(P)H-quinone reductase and catalyzes NAD(P)H-dependent 1-, 2- or 4-electron reduction of certain redox dyes, aromatic nitro compounds, aromatic C-nitroso compounds and probably azo-dyes, as well as menadione (vitamin K3) and other quinones. Dicumarol exerts characteristic inhibition on DT-diaphorase, whereas serum albumin and certain non-ionic detergents exert activation. Excessive concentrations of many of the electron acceptors inhibit the activity of this enzyme. The physiological significance of DT-diaphorase is still obscure because the physiological vitamins (K1 and K2) and coenzyme Q10 are difficult to reduce with this enzyme. Results of recent studies suggest that DT-diaphorase prevents formation of active oxygen species. Activities in liver and other tissues are known to be enhanced by administration of chemicals including certain carcinogens such as 3-methylcholanthrene (3-MC), anti-oxidants such as 3-tert-butyl-4-hydroxyanisole (BHA), and other compounds. Both basal and induced activities vary considerably with tissue, sex, strain and species of animals. The strain variations in activities in rat and mouse liver are known to be inherited, and the trait of hereditary transmission can be adequately explained by postulating two loci of genes or gene clusters regulating the activity. Resistance of animals to various toxic or carcinogenic substances may be promoted by BHA administration and depressed by dicumarol administration. Thus, attention has been focused on the role played by DT-diaphorase in the detoxication of foreign compounds. Knowledge on strain variations in basal and induced activities of tissue DT-diaphorase is of potential value when choosing a rat or mouse strain suitable for studying the toxic effects of drugs, especially drugs expected to be detoxified by reductive metabolism. With future progress in research on DT-diaphorase, this enzyme might be applied to prophylactic and therapeutic medicine.
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PMID:Advances in research on DT-diaphorase--catalytic properties, regulation of activity and significance in the detoxication of foreign compounds. 212 71

A 40% reduction of the diameter of the ascending aorta maintained for 60 days induced the formation of a compensate cardiac hypertrophy in rabbits without changing the value of the azide insensitive Ca2+-ATPase activity in comparison to control hearts. The cardiac mitochondria isolated from constricted animals assayed in presence of glutamate and succinate did not show a change in the R.C.I. and ADP/O values in comparison to the controls, whilst the QO2 value enhanced or decreased respectively when determined with glutamate or succinate. The intramuscular injections of CoQ10 (12 mg/kg body weight/48 h) enhanced the mitochondrial CoQ10 concentrations both in the control and in the constricted animals and further increased the QO2 value determined in both groups of animals when glutamate was used as the substrate. The production of O2.- radicals by the level of the complexes I and III of the respiratory chain, did not change in the constricted animals, nor in the animals administered with CoQ10 in comparison to the control. CoQ10 augmented the rate of oxygen consumption by the submitochondrial particles only in the constricted animals. Moreover, the treatment with the coenzyme or the constriction of the aorta, did not modify the cardiac superoxide dismutase activity, but increased the glutathione peroxidase activity only in the banded animals. In addition, in the CoQ10 treated animals there was a reduction of NADH-diaphorase activity both in the control and constricted animals, while the malondialdehyde, generated during the thiobarbituric acid test, and the cardiac content of lipofuscin were decreased.
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PMID:The effect of treatment with coenzyme Q10 on the mitochondrial function and superoxide radical formation in cardiac muscle hypertrophied by mild aortic stenosis. 303 17

The blood level of [14C]coenzyme Q10 and the redox levels of [14C]coenzyme Q10 in the liver and heart were measured after intravenous injection of [14C]coenzyme Q10 solubilized in multilamellar liposomes into guinea pigs. The blood level of radioactivity declined biexponentially with half-lives of 11.5 min and 15.6 h in the first and second phases, respectively. The levels of reduced [14C]coenzyme Q10 in the liver and heart reached 55.8 and 46.4%, respectively, of the labeled compound in the tissues at 30 min after the injection. Coenzyme Q10-reducing activity in cytosol, microsomes and mitochondria was also investigated. This activity was found in all the fractions. The total activity was the highest in the liver cytosol. Moreover, the results of experiments using a purified enzyme suggested that one of the coenzyme Q10-reducing enzymes was NAD(P)H: quinone oxidoreductase [EC 1.6.99.2, DT-diaphorase]. These results are discussed in relation to the protective effect of reduced coenzyme Q10 against lipid peroxidation in membranes.
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PMID:Redox levels of intravenously administered [14C]coenzyme Q10 and coenzyme Q10-reducing activity in subcellular fractions of guinea pig liver. 392 43

The experiments reported here were designed to test the hypothesis that the two-electron quinone reductase DT-diaphorase [NAD(P)H:(quinone-acceptor) oxidoreductase, EC 1.6.99.2] functions to maintain membrane-bound coenzyme Q (CoQ) in its reduced antioxidant state, thereby providing protection from free radical damage. DT-diaphorase was isolated and purified from rat liver cytosol, and its ability to reduce several CoQ homologs incorporated into large unilamellar vesicles was demonstrated. Addition of NADH and DT-diaphorase to either large unilamellar or multilamellar vesicles containing homologs of CoQ, including CoQ9 and CoQ10, resulted in the essentially complete reduction of the CoQ. The ability of DT-diaphorase to maintain the reduced state of CoQ and protect membrane components from free radical damage as lipid peroxidation was tested by incorporating either reduced CoQ9 or CoQ10 and the lipophylic azoinitiator 2,2'-azobis(2,4-dimethylvaleronitrile) into multilamellar vesicles in the presence of NADH and DT-diaphorase. The presence of DT-diaphorase prevented the oxidation of reduced CoQ and inhibited lipid peroxidation. The interaction between DT-diaphorase and CoQ was also demonstrated in an isolated rat liver hepatocyte system. Incubation with adriamycin resulted in mitochondrial membrane damage as measured by membrane potential and the release of hydrogen peroxide. Incorporation of CoQ10 provided protection from adriamycin-induced mitochondrial membrane damage. The incorporation of dicoumarol, a potent inhibitor of DT-diaphorase, interfered with the protection provided by CoQ. The results of these experiments provide support for the hypothesis that DT-diaphorase functions as an antioxidant in both artificial membrane and natural membrane systems by acting as a two-electron CoQ reductase that forms and maintains the antioxidant form of CoQ. The suggestion is offered that DT-diaphorase was selected during evolution to perform this role and that its conversion of xenobiotics and other synthetic molecules is secondary and coincidental.
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PMID:The role of DT-diaphorase in the maintenance of the reduced antioxidant form of coenzyme Q in membrane systems. 863 8

The experiments reported here were undertaken to test the hypothesis that the antioxidative, reduced form of hydrophobic phase coenzyme Q (CoQ) may be generated and maintained by the two-electron quinone reductase, DT-diaphorase [NAD(P)H:(quinone-acceptor) oxidoreductase, EC 1.6.99.2] by catalyzing formation of the hydroquinone form of CoQ. This enzyme was isolated and purified from rat liver cytosol and its reduction of several CoQ homologs incorporated into large unilamellar vesicles (LUVETs) was demonstrated. The addition of NADH and DT-diaphorase to LUVETs and to multilamellar vesicles (MLVs) containing CoQ homologs, including CoQ9 and CoQ10, resulted in essentially complete reduction of the CoQ. Incorporation of either CoQ9H2 or CoQ10H2 and the lipophylic radical generator 2,2'-azobis(2,4-dimethylvaleronitrile) (AMVN) into MLVs in the presence of DT-diaphorase and NADH maintained the reduced state of CoQ and inhibited lipid peroxidation. The reaction between DT-diaphorase and CoQ was also demonstrated in isolated rat liver hepatocytes in which incorporation of CoQ10 provided protection from adriamycin (adr)-induced mitochondrial membrane damage. The role of DT-diaphorase in the antioxidant activity of CoQ was demonstrated by the co-incorporation of dicoumarol (dic), a potent inhibitor of DT-diaphorase, resulting in a loss of protection by incorporated CoQ10. These results support the antioxidant function of DT-diaphorase in both artificial and natural membrane systems by acting as a two-electron CoQ reductase which forms and maintains CoQ in the reduced state.
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PMID:The two-electron quinone reductase DT-diaphorase generates and maintains the antioxidant (reduced) form of coenzyme Q in membranes. 926 2

alpha-Tocopherolquinone (TQ), a product of alpha-tocopherol oxidation, can function as an antioxidant after reduction to alpha-tocopherolhydroquinone (TQH2). We examined the ability of human NAD(P)H:quinone oxidoreductase (NQO1) to catalyze the reduction of TQ to TQH2 in cell-free and cellular systems. In reactions with purified human NQO1, TQ was reduced to TQH2. Kinetic parameters for the reduction of TQ by NQO1 (Km = 370 microM; k(cat) = 5.6 x 10(3) min(-1); k(cat)/Km = 15 min(-1) x microM(-1)) indicate that NQO1 can efficiently reduce TQ to TQH2. A comparison of the rate of reduction of TQ and coenzyme Q10 by NQO1 showed that TQ is reduced more efficiently than coenzyme Q10. Experiments with either Chinese hamster ovary (CHO) cells stably transfected with human NQO1 or CHO cell sonicates demonstrated a correlation between NQO1 activity and TQ reduction to TQH2. CHO cells with elevated NQO1 generated and maintained higher levels of TQH2 after treatment with TQ relative to NQO1-deficient CHO cells. TQH2 generated from NQO1-mediated reduction of TQ prevented cumene hydroperoxide-induced lipid peroxidation in rat liver microsomes. In addition, cumene hydroperoxide-induced lipid peroxidation was inhibited more efficiently by TQ in CHO cell lines with elevated NQO1 activity. These data demonstrate that NQO1 can reduce TQ to TQH2 and that TQH2 can function as an efficient antioxidant. This work suggests that one of the physiological functions of NQO1 may be to regenerate antioxidant forms of alpha-tocopherol.
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PMID:The reduction of alpha-tocopherolquinone by human NAD(P)H: quinone oxidoreductase: the role of alpha-tocopherolhydroquinone as a cellular antioxidant. 927 53

High affinity for NADH, and low affinity for NADPH, for reduction of endogenous coenzyme Q10 (CoQ10) by pig liver plasma membrane is reported in the present work. CoQ reduction in plasma membrane is carried out, in addition to other mechanisms, by plasma membrane coenzyme Q reductase (PMQR). We show that PMQR-catalyzed reduction of CoQ0 by both NADH and NADPH is accompanied by generation of CoQ0 semiquinone radicals in a superoxide-dependent reaction. In the presence of a water-soluble vitamin E homologue, Trolox, this reduction leads to quenching of the Trolox phenoxyl radicals. The involvement of PMQR versus DT-diaphorase under the conditions of vitamin E and selenium sufficiency and deficiency was evaluated for CoQ reduction by plasma membranes. The data presented here suggest that both nucleotides (NADH and NADPH) can be accountable for CoQ reduction by PMQR on the basis of their physiological concentrations within the cell. The enzyme is primarily responsible for CoQ reduction in plasma membrane under normal (nonoxidative stress-associated) conditions.
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PMID:NADH and NADPH-dependent reduction of coenzyme Q at the plasma membrane. 1122 30


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