EC:1.6.5.2 - FACTA Search

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)

1. The metabolism of the benzoquinone 2,5-dimethylbenzoquinone and of the naphthoquinone 2,3-dimethoxy-1,4-naphthoquinone was studied in subcellular fractions isolated from cardiac tissue of guinea pig and rat. 2. In both species the benzoquinone was mainly metabolized through the mitochondrial NADH-ubiquinone-oxidoreductase, whereas the naphthoquinone was metabolized to approximately equal extents by mitochondrial reductase and by soluble DT-diaphorase. 3. Guinea pig heart metabolized 3 times more naphthoquinone than rat heart. 4. As a consequence of quinone metabolism, marked amounts of O2- center dot - were generated; naphthoquinone-induced O2- center dot - generation was about 4-fold higher in guinea pig than in rat heart.
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PMID:Metabolism of simple quinones in guinea pig and rat cardiac tissue. 874 66

The group I aziridinylquinone anti-cancer agents mitomycin C, diaziquone or trenimon were much more cytotoxic to DT-diaphorase-enriched L5178Y/HBM10 lymphoblasts than parental L5178Y cells and caused little oxygen activation. Furthermore, inactivation of cellular DT-diaphorase prevented cytotoxicity whereas catalase did not affect cytotoxicity. This suggests that DT-diaphorase activated these agents and the hydroquinone formed mediated DNA alkylation, crosslinking and cytotoxicity. The group II quinone agents phenanthrenequinone, 2-amino-1, 4-naphthoquinoneimine or naphthazarin were also more cytotoxic to L5178Y/HBM10 cells than parental cells and caused considerable oxygen activation. Inactivation of DT-diaphorase, however, prevented both oxygen activation and cytotoxicity. Furthermore added catalase decreased cytotoxicity, whereas catalase inactivation enhanced cytotoxicity. This suggests that DT-diaphorase activated these agents and the hydroquinone formed caused extensive oxygen activation sufficient to cause DNA oxidative damage and cytotoxicity. The group III quinone agents menadione, 2,3-dimethoxy-1,4-naphthoquinone and 2,6-dimethoxy-benzoquinone, on the other hand, were more cytotoxic to the parental cells than L5178Y/HBM10 cells and caused less oxygen activation than group II agents. Furthermore, inactivation of DT-diaphorase enhanced cytotoxicity and prevented oxygen activation than group II agents. Oxygen activation was therefore also attributed to hydroquinone autoxidation. However catalase did not affect cytotoxicity towards parental cells. This suggests that DT-diaphorase detoxified group III quinones and that cytotoxicity may involve DNA oxidative damage by the semiquinone radicals.
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PMID:Cytotoxic mechanisms of anti-tumour quinones in parental and resistant lymphoblasts. 876 40

Incubation of cultured Chinese hamster V79 cells with menadione (2-methyl-1,4-naphthoquinone), a generator of superoxide anion radicals, caused a rapid increase in the level of glutathione disulfide (GSSG) and a decrease in the level of glutathione (GSH), which followed a 1.5- to 2-fold increase in the level of GSH during post-treatment incubation. Menadione also caused a concentration- and time-dependent increase in the activity of gamma-glutamylcysteine synthetase (gamma-GCS), a rate-limiting enzyme in the synthesis of GSH. These results suggested that the increase in level of GSH after treatment with menadione was due to the increase in the activity of gamma-GCS. Dicoumarol, an inhibitor of DT-diaphorase, did not influence the increase in the activity of gamma-GCS caused by menadione but it did enhance the cytotoxicity and the increase in the level GSSG caused by menadione. This result suggested that neither the DT-diaphorase-mediated metabolism of menadione nor the increase in level of GSSG caused by menadione was associated with the increase in the activity of gamma-GCS. Chelators of divalent iron and copper (I), and cycloheximide did not influence the increase in the activity of gamma-GCS caused by menadione. Thus, it appeared that reactive oxygen radicals, generated from hydrogen peroxide by an iron- or copper-catalyzed Fenton reaction, were not responsible for the increase in the activity of gamma-GCS and that the increase was not an inducible phenomenon.
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PMID:Menadione causes increases in the level of glutathione and in the activity of gamma-glutamylcysteine synthetase in cultured Chinese hamster V79 cells. 879 48

The mechanism of action of antimicrobial naphthoquinones from the fungus Fusarium was studied by using Pseudomonas aeruginosa. Bostricoidin, methyl ether fusarubin, and fusarubin stimulated the oxygen consumption of bacterial cells and induced cyanide-insensitive oxygen consumption. These activities of the tested compounds were also observed in bacterial membrane preparations in a dose-dependent manner. Naphthoquinones stimulated the generation of superoxide anion and hydrogen peroxide. The naphthoquinone effectively acted as the electron acceptors for bacterial diaphorase, which could explain the antibacterial activity of Fusarium naphthoquinones since electron acceptors lead to the stimulation of respiratory activity and the generation of oxygen radical species.
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PMID:Respiratory stimulation and generation of superoxide radicals in Pseudomonas aeruginosa by fungal naphthoquinones. 900 Mar 35

Lipoamide dehydrogenase from Mycobacterium smegmatis was purified to homogeneity over 60-fold. Of 20 amino acid residues identified at the amino terminus of the enzyme, 18 and 17 were identical to the sequences of Mycobacterium leprae and Pseudomonas fluorescens lipoamide dehydrogenases, respectively. The visible spectrum of the isolated enzyme was characteristic of a flavin in apolar environment. Reduction of the enzyme with dithionite results in the appearance of an absorbance shoulder at 530-550 nm, suggesting that reducing equivalents of the two-electron reduced enzyme reside predominantly on the redox-active disulfidedithiol. The kinetic mechanism of the forward (NAD+ reducing) and reverse (NADH oxidizing) reactions proved difficult to study due to severe substrate inhibition by NAD+ and NADH. The rate of lipoamide reduction was found to depend upon the NAD+/NADH ratio, with the reaction being activated at low ratios and inhibited at high ratios. The use of 3-acetylpyridine adenine dinucleotide allowed initial velocity kinetics to be performed and revealed that the kinetic mechanism is ping pong. In addition to catalyzing the reversible oxidation of dihydrolipoamide, the enzyme displayed high oxidase activity (30% of the lipoamide reduction rate), hydrogen and t-butyl peroxide reductase activity (10% of the lipoamide reduction rate), and both naphthoquinone and benzoquinone reduction (approximately 200% of the lipoamide reduction rate). The enzyme failed to catalyze the redox cycling of nitrocompounds, but could anaerobically reduce nitrofurazone. The lipoamide-reducing reaction was reversibly inactivated by sodium arsenite, but no decrease in diaphorase activity was observed under these conditions.
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PMID:Catalytic properties of lipoamide dehydrogenase from Mycobacterium smegmatis. 914 18

The 2-hydroxy-N-(3,4-dimethyl-5-isoxazolyl)-1,4-naphthoquinone-4-imine (Q1) revealed good activity against Staphylococcus aureus. Q1 in contact with the bacteria experimented reduction evidenced by changes in its spectrum of absorption simultaneously with loss of colour. During the first 4 hours of incubation, oxygenation restored the original spectrum. Treatment with sodium borohydrure reduces irreversibly Q1. Redox-reaction "in vitro" was detected between Q1 and NADH in the presence of diaphorase. The environment of the probable site of action of Q1 was simulated using an artificial membrane system, instead of S. aureus membranes. Q1 interacts with lisophosphatidylcholine micelles following a cooperative binding model. The kinetics of Q1-reduction was increased by lipid micelles incorporated with the antibacterial compound.
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PMID:An "in vitro" system simulates in membranes the antibacterial mechanism postulated for the action of isoxazolylnaphtoquinoneimine in Staphylococcus aureus. 934 93

The enzyme DT-diaphorase catalyses the 2-electron reduction of quinones. This reaction may facilitate the detoxification of such compounds, since the hydroquinone so formed can be converted into non-toxic conjugates. There is evidence for the involvement of DT-diaphorase in the detoxification of menadione (2-methyl-1,4-naphthoquinone) in a wide range of cells and tissues in vitro, but no information is available on the possible influence of this enzyme on the harmful effects of menadione in vivo. In animals, menadione is selectively toxic to erythrocytes, causing haemolytic anaemia. In the present study, rats were treated with dicoumarol, an inhibitor of DT-diaphorase, or butylated hydroxyanisole (BHA), a substance that increases the activity of this enzyme in vivo. They were then challenged with a toxic dose of menadione. Dicoumarol increased the severity of menadione-induced haemolytic anaemia while BHA decreased it, consistent with a role for DT-diaphorase in the detoxification of menadione in vivo, as previously described in vitro.
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PMID:Effects of butylated hydroxyanisole and dicoumarol on the toxicity of menadione to rats. 952 87

2-Amino-3-carboxy-1,4-naphthoquinone, discovered as a novel bifidogenetic growth stimulator (BGS), has been characterized by determination of redox and acid-base equilibria, partition properties, and UV-vis and electron spin resonance spectral properties. BGS is proposed to function as an electron transfer mediator from NADH to O2. BGS is reduced by NADH-reduced diaphorase (or related enzymes) and the reduced BGS is reoxidized by autoxidation and a peroxidase-catalyzed reaction. The proposed reaction would spare pyruvate as an important metabolic intermediate, and minimize the cytotoxic effects of H2O2 generated by the autoxidation. Kinetic studies were performed in model enzymatic systems using 2-methyl-1,4-naphthoquinone (VK3) as a reference compound with a very weak growth-stimulating effect. The results support our proposal and reveal the superiority of BGS to VK3 as an electron transfer mediator in the proposed reactions.
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PMID:Mechanistic study on the roles of a bifidogenetic growth stimulator based on physicochemical characterization. 983 15

Rat blood exhibited a significant quinone-dependent N-oxide reductase activity towards imipramine N-oxide. The reduction mediated by the blood proceeded in the presence of both NAD(P)H and menadione under anaerobic conditions. When menadione was replaced with 1,4-naphthoquinone or 9,10-phenanthrenequinone, similar results were obtained. The reduction was also mediated by the combination of rat erythrocytes and plasma. The reducing activity was inhibited by dicumarol and carbon monoxide. When boiled plasma was combined with untreated erythrocytes, the N-oxide reducing activity was abolished. In contrast, when boiled erythrocytes were combined with untreated plasma, the activity was unchanged. These results suggest that the activity is caused by the heme of hemoglobin in erythrocytes and quinone reductase in plasma. In fact, erythrocytes and hemoglobin have the ability to reduce the N-oxide when supplemented with DT-diaphorase purified from rat liver in the presence of both NAD(P)H and menadione. Hemoglobin also exhibits N-oxide reductase activity with reduced menadione (menadiol). Furthermore, hematin exhibits a significant reducing activity in the presence of menadiol. The reduction appears to proceed in two steps. The first step is enzymatic reduction of quinones to dihydroquinones by quinone reductase(s) with NADPH or NADH in plasma. The second step is nonenzymatic reduction of imipramine N-oxide to imipramine by the dihydroquinones, catalyzed by the heme group of hemoglobin in erythrocytes. Cyclobenzaprine N-oxide and brucine N-oxide are similarly transformed to the corresponding amines by the above reducing system in blood. These results suggest that blood plays an important role in the reduction of tertiary amine N-oxides to tertiary amines.
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PMID:Quinone-dependent tertiary amine N-oxide reduction in rat blood. 988 51

The results of this study show the quinone-dependent reduction of tertiary amine N-oxides to the corresponding tertiary amines by rat liver preparations. The reduction of imipramine N-oxide to imipramine mediated by liver mitochondria, microsomes, and cytosol proceeded in the presence of both NAD(P)H and menadione under anaerobic conditions. When menadione was replaced with 1, 4-naphthoquinone or 9,10-anthraquinone, similar results were obtained in the cytosolic reduction. The quinone-dependent reducing activity in liver cytosol was inhibited by dicumarol and carbon monoxide. This result suggested that the activity is caused by DT-diaphorase, a cytosolic quinone reductase, and hemoproteins in liver cytosol. In fact, catalase and hemoglobin showed the ability to reduce imipramine N-oxide when supplemented with DT-diaphorase. The hemoproteins also exhibited the N-oxide reductase activity with reduced menadione, menadiol. The N-oxide reductase activity of the hemoproteins was also exhibited with 1,4-dihydroxynaphthalene, 1,4,9, 10-tetrahydroxyanthracene, or 1,4-dihydroxy-9,10-anthraquinone. Furthermore, hematin revealed a significant N-oxide-reducing activity in the presence of menadiol. The reduction appears to proceed in two steps. The first step is reduction of menadione to menadiol by a quinone reductase with NADPH or NADH. The second step is nonenzymatic reduction of tertiary amine N-oxides to tertiary amines by menadiol, catalyzed by the heme group of hemoproteins. Cyclobenzaprine N-oxide and brucine N-oxide were also transformed similarly to the corresponding amine by the quinone-dependent reducing system.
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PMID:A unique tertiary amine N-oxide reduction system composed of quinone reductase and heme in rat liver preparations. 988 15

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