EC:1.6.99.3 - FACTA Search

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Query: EC:1.6.99.3 (diaphorase)
5,903 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

The role of flavins in vitamin K function was assessed by examining blood coagulation and in vitro activities of hepatic vitamin K-dependent enzymes from control and riboflavin-deficient rats. One-stage prothrombin times and Factor VII activities were lower in flavin-deficient rats than in ad libitum or pair-fed controls. Fibrinogen, prothrombin, and Factor X activities were normal. Hepatic vitamin K-dependent carboxylase activity was severely depressed in flavin-deficient rats when assayed with [vitamin K + NADH] and somewhat depressed with reduced vitamin K (vitamin KH2) as substrate. One-hour flavin repletion appreciably restored [vitamin K + NADH]-dependent activity, but vitamin KH2-dependent activity was not restored even after 16 hours repletion. These results suggest that the carboxylating enzyme itself is not a flavoprotein, but that the microsomal NADH dehydrogenase required for [vitamin K + NADH]-dependent carboxylation is a flavoprotein. This dehydrogenase may differ from the cytosolic Warfarin-inhibitable 'DT-diaphorase' in that the activity of the latter, which is reduced 50% in flavin-deficient rats, is not at all restored by one-hour flavin repletion. Flavin status-dependent differences in NADH-dependent or vitamin KH2-dependent epoxidation of vitamin K paralleled differences in the carboxylase. Flavin deficiency had no effect on vitamin K 2,3-epoxide reductase activity nor on its inhibition by Warfarin.
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PMID:Vitamin K-dependent reactions in rat liver: role of flavoproteins. 731 May 34

This study investigated the effect of inducers on the major enzymes responsible for metabolising the quinone antitumor agent mitoxantrone, and on its cytotoxicity in MCF 7 human breast cancer cells. Four inducers were used: 1,2-benzanthracene (BA), phenobarbitone (PB); rifampicin (R) and dexamethasone (DEX). Of these, BA was the most effective, increasing cytochrome P450 dependent metabolism 64-fold and DT-diaphorase activity 1.6-fold. R did not cause an increase in any of the enzyme activities measured and, in fact inhibited glutathione peroxidase activity. PB and DEX increased NADPH cytochrome c reductase activity but had no effect on either DT-diaphorase or cytochrome P450 dependent activities. BA potentiated the cytotoxicity of mitoxantrone in terms of leakage of lactate dehydrogenase (LDH) activity and loss of reduced glutathione (GSH) and protein from cultures. PB had a smaller potentiating effect on cytotoxicity and DEX had no effect. Studies with the enzyme inhibitors, dicoumarol (inhibits DT-diaphorase) and metyrapone (inhibits cytochrome P450), indicate that at least two reactive species are involved in mitoxantrone cytotoxicity. One intermediate, formed by cytochrome P450, caused LDH leakage and GSH depletion. Formation of the second intermediate was catalysed by DT-diaphorase and this hydroquinone caused loss of intracellular protein and GSH. We propose that autooxidation of the hydroquinone resulting in generation of reactive oxygen species contributes to mitoxantrone cytotoxicity. Concomitant exposure to inducing agents may alter the cytotoxicity associated with many cytotoxic drugs, not just mitoxantrone, and this is an important consideration as many cytotoxics have a narrow therapeutic index.
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PMID:The activity of xenobiotic enzymes and the cytotoxicity of mitoxantrone in MCF 7 human breast cancer cells treated with inducing agents. 754 30

Quinone reductase [NAD(P)H:(quinone acceptor) oxidoreductase, EC 1.6.99.2], also called DT diaphorase, is a homodimeric FAD-containing enzyme that catalyzes obligatory NAD(P)H-dependent two-electron reductions of quinones and protects cells against the toxic and neoplastic effects of free radicals and reactive oxygen species arising from one-electron reductions. These two-electron reductions participate in the reductive bioactivation of cancer chemotherapeutic agents such as mitomycin C in tumor cells. Thus, surprisingly, the same enzymatic reaction that protects normal cells activates cytotoxic drugs used in cancer chemotherapy. The 2.1-A crystal structure of rat liver quinone reductase reveals that the folding of a portion of each monomer is similar to that of flavodoxin, a bacterial FMN-containing protein. Two additional portions of the polypeptide chains are involved in dimerization and in formation of the two identical catalytic sites to which both monomers contribute. The crystallographic structures of two FAD-containing enzyme complexes (one containing NADP+, the other containing duroquinone) suggest that direct hydride transfers from NAD(P)H to FAD and from FADH2 to the quinone [which occupies the site vacated by NAD(P)H] provide a simple rationale for the obligatory two-electron reductions involving a ping-pong mechanism.
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PMID:The three-dimensional structure of NAD(P)H:quinone reductase, a flavoprotein involved in cancer chemoprotection and chemotherapy: mechanism of the two-electron reduction. 756 29

A metallothionein-I-transgenic mouse strain (MT-TG) was characterized to determine whether they would be suitable to study the functions of this protein. MT-TG mice were visually indistinguishable from nontransgenic littermate controls, but had 10- to 20-fold higher basal levels of MT protein in pancreas, liver, and stomach, as well as 2- to 6-fold higher MT protein levels in other organs (kidney, intestine, uterus, testes, spleen, heart, and lung) than control mice, as determined by the Cd/hemoglobin assay. The MT-TG mice had 50% more Zn in liver and 300% more Zn in pancreas than control mice. Interestingly, female MT-TG mice have 4- to 5-fold higher MT levels in liver than those of males. To determine whether MT can be further increased by well-known MT inducers, control and MT-TG mice were given Zn (200 mumol/kg), Cd (20 mumol/kg), or diethyl maleate (DEM, 5 mmol/kg), and tissue MT concentrations were measured 24 hr later. MT-TG mice responded to MT inducers in a manner similar to control mice. The hepatic antioxidant components (glutathione (GSH), GSH-peroxidase, GSH-reductase, GSH S-transferase, superoxide dismutase, DT-diaphorase, and catalase) of MT-TG mice were not different from those of controls. The cytochrome P450 enzymes (total P450, b5, NADPH cytochrome c reductase) were normal in these MT-TG mice. The activities of CYP1A, CYP2B, and CYP2E enzymes in MT-TG mice were also similar to those of controls, as determined by ethoxy- and pentoxyresorufin O-dealkylation and chlorzoxazone 6-hydroxylation. Thus, MT-TG mice appear to be a good model for studying functions of MT.
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PMID:Characterization of metallothionein-I-transgenic mice. 764 27

Bovine leukemia virus-transformed lamb embryo fibroblasts (line FLK) possess activity of DT-diaphorase of ca. 260 U/mg protein and similar levels of other NADP(H)-oxidizing enzymes: NADH:oxidase, 359 U/mg; NADPH:oxidase, 43 U/mg; NADH:cytochrome-c reductase, 141 U/mg; NADPH:cytochrome-c reductase, 43 U/mg. In general, the toxicity of aromatic nitrocompounds towards FLK cells increases on increase of single-electron reduction potentials (E1(1)) of nitrocompounds or the log of their reduction rate constants by single-electron-transferring enzymes, microsomal NADPH:cytochrome P-450 reductase (EC 1.6.2.4) and mitochondrial NADH:ubiquinone reductase (EC 1.6.99.3). No correlation between the toxicity and reduction rate of nitrocompounds by rat liver DT-diaphorase (EC 1.6.99.2) was observed. The toxicity is not significantly affected by dicumarol, an inhibitor of DT-diaphorase. Nitrocompounds examined were poor substrates for DT-diaphorase, being 10(4) times less active than menadione. Their poor reactivity is most probably determined by their preferential binding to a NADPH binding site, but not to menadione binding site of diaphorase. These data indicate that at comparable activities of DT-diaphorase and single-electron-transferring NAD(P)H dehydrogenases in the cell, the toxicity of nitrocompounds will be determined mainly by their single-electron reduction reactions.
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PMID:The toxicity of aromatic nitrocompounds to bovine leukemia virus-transformed fibroblasts: the role of single-electron reduction. 766 3

We have cloned and sequenced the mouse NMO1 cDNA, which encodes the NAD(P)H:menadione oxidoreductase [also called NAD(P)H:(quinone acceptor) oxidoreductase; quinone reductase; azo dye reductase; DT diaphorase; EC 1.6.99.2]. The cDNA is 1528 bp in length excluding the poly(A+) tail, and has 5' and 3' nontranslated regions of 108 bp and 595 bp, respectively. The deduced protein contains 274 amino acids, including the first methionine (M(r) = 30,959). The mouse NMO1 protein is: 94% similar to the rat NMO1 and 86.5% to the human NMO1 proteins; 49.3% identical to the human NQO2 protein; and < 20% similar to several dozen other proteins in the quinone oxidoreductase superfamily. Southern hybridization analysis of mouse DNA reveals that the Nmo1 gene is likely to span less than a total of 20 kb. The Nmo1 gene is highly inducible by 2,3,7,8,-tetrachlorodibenzo-p-dioxin (dioxin; TCDD) in mouse liver and mouse cell cultures. TCDD inducibility of NMO1 is detectable at 12 and 18 days of gestation, but markedly elevated at 1-3 weeks post partum as compared with the 6- and 12-week-old mouse. NMO1 mRNA levels are strikingly elevated in the untreated mouse hepatoma Hepa-1c1c7 mutant line c37 lacking CYP1A1 (aryl hydrocarbon hydroxylase) activity, and in the untreated 14CoS/14CoS mouse cell line having an 'oxidative stress response' caused by homozygous deletion of about 3800 kb on chromosome 7. Previous work and the data in this report show that the murine Nmo1 gene is regulated by three distinct mechanisms: CYP1A1 metabolism-dependent repression, Ah receptor-mediated induction by TCDD, and activation by the chromosome 7-mediated oxidative stress response.
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PMID:Mouse dioxin-inducible NAD(P)H: menadione oxidoreductase: NMO1 cDNA sequence and genetic differences in mRNA levels. 770 40

A major and a minor ascorbate free radical (AFR) reductase were separated from the soluble fraction in the human lens cortex by DEAE-cellulose ion-exchange column chromatography. These AFR reductases also exhibited diaphorase activity using dichlorophenolindophenol and ferricyanide as electron acceptors. The major AFR reductase was partially purified by 5'AMP-Sepharose 4B affinity column chromatography. This partially purified AFR reductase showed a single band of diaphorase activity in native polyacrylamide disc gel electrophoresis. This activity band corresponded to the major protein observed in protein staining by Coomassie Brilliant Blue. However, the protein staining by Coomassie Brilliant Blue showed this activity band surrounded by diffused staining. Molecular weight of the partially purified AFR reductase was determined to be 32 kDa by gel filtration, and the apparent Km value for AFR was about 15 microM. This major lens AFR reductase could be distinguished from soluble Neurospora, Euglena and cucumber AFR reductases, and from two ubiquitous enzymes with reduction activity of AFR and/or foreign compounds, ie, NADH-cytochrome b5 reductase and DT-diaphorase, by their molecular weights, Km values and/or ion-exchange chromatographic behaviors.
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PMID:Soluble ascorbate free radical reductase in the human lens. 793 90

Many solid tumors contain substantial fractions of hypoxic cells which are relatively resistant to both radiation therapy and certain cytotoxic drugs. We have previously shown that exposure of human HT29 cells to hypoxic conditions results in the overexpression of certain enzymes involved in the detoxication of xenobiotics, including NAD(P)H:(quinone acceptor) oxidoreductase (DT)-diaphorase, and gamma-glutamylcysteine synthetase, the rate-limiting enzyme in glutathione synthesis. This hypoxic effect on DT-diaphorase was shown to involve both transcriptional induction and altered message stability. We have investigated the effects of hypoxia on elements in the promoter region of DT-diaphorase. Electrophoretic mobility shift assays demonstrate the induction of a binding activity to the AP-1 response element of DT-diaphorase. Supershift assays suggest that this binding is due to AP-1 nuclear factors and that members of the jun family are induced to a greater degree than fos by hypoxia. Analysis of the kinetics of transcription factor expression indicates that the expression of c-jun and junD is induced during hypoxic exposure; mRNA levels fall during reoxygenation. Induction of fos on the other hand is not as florid during hypoxia (5-fold) and is most pronounced (17-fold) 24 h after the restoration of an oxic environment. Thus, the hypoxic response of DT-diaphorase expression is mediated in part through AP-1, initially by a jun-related mechanism and then by the involvement of fos. The affinity of transcription factors for the AP-1 binding site depends on the redox state of a cysteine residue located close to the DNA-binding region of both Fos and Jun. A nuclear protein, Ref-1, maintains the reduced state of Fos and Jun and promotes binding to AP-1. Nuclear extracts of HT29 cells exposed to hypoxia show markedly increased Ref-1 protein content. Elevation of ref-1 steady-state mRNA levels occurs as an early event following induction of hypoxia and persists when cells are restored to a normally oxygenated environment. Nuclear run-on analysis demonstrates that induction of transcription is the mechanism of ref-1 mRNA elevation. Electrophoretic mobility shift assays and immunodepletion assays were used to further define the interaction of Ref-1 with specific AP-1-binding proteins under hypoxic conditions. These data demonstrate that the induction of detoxicating enzyme expression in HT29 cells exposed to hypoxia results from the induction of both transactivating factors that bind to the AP-1 element and of redox proteins that enhance their affinity for this element.
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PMID:Activation of AP-1 and of a nuclear redox factor, Ref-1, in the response of HT29 colon cancer cells to hypoxia. 806 32

Mitomycin C (MC), a clinically used natural antitumor agent, was shown to form three monoconjugates (11a-13a) and two bisconjugates (14a, 15a) with GSH upon reductive activation by rat liver microsomes, purified NADPH-cytochrome c reductase, or NADH-cytochrome c reductase or chemical reduction using H2/PtO2. Rat liver cytosol/NADH activated MC only at acidic pH (5.8), resulting in the formation of a single GSH-MC monoconjugate, 13a. The reductase responsible for cytosolic activation of MC to form this conjugate was DT-diaphorase. GSH itself did not reduce MC, and unreduced MC did not form conjugates with GSH. A moderate catalytic effect by glutathione S-transferase was demonstrated on the cytosol-activated reaction. Mercaptoethanol and N-acetylcysteine gave analogous sets of five MC-thiol conjugates under cytochrome c reductase or H2/PtO2 activation conditions. The structures of all 15 MC-thiol conjugates (five each with GSH, mercaptoethanol, and N-acetylcysteine, respectively) were determined, using 1H-NMR, UV, and mass spectroscopies, combined with analytical chemical and radiolabeling methods. The mechanism of formation of the conjugates features SN2 displacement of the carbamate of the reduced MC by GS-. The MC-GSH conjugates were noncytotoxic to the tumor cells tested. The conjugation of GSH with activated MC is likely to represent detoxication in mammalian cells. As another effect, GSH accelerates the rate of reduction of MC by "slow" reducing agents such as cytochrome c reductases and H2/PtO2. A mechanism is proposed to explain this effect, which involves further reduction of the initially formed MC semiquinone free radical by GSH.
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PMID:Conjugation of glutathione and other thiols with bioreductively activated mitomycin C. Effect of thiols on the reductive activation rate. 807 71

It was found that the activities of prooxidant enzymes (NAD(P)H oxidases and NAD(P)H:cytochrome c reductases) in bovine leukemia virus-transformed calf and lamb embryo kidney fibroblasts (lines Mi-18 and FLK) were by 1.25-18 times higher when compared to corresponding nontransformed calf cells. The activity of DT-diaphorase was also increased by about one order of magnitude in transformed cells. The activities of antioxidant enzymes were almost unchanged (superoxide dismutase), decreased by 13% or 53% (catalase) or increased by 25% or 90% (glutathione reductase) in Mi-18 or FLK cells, respectively. These changes of enzyme activity increased the toxicity of simple redox-cycling quinones (duroquinone, naphthazarin) towards transformed cells, but did not affect the toxicity of daunorubicin. The latter was most probably related to the inhibition of plasma membrane NADH dehydrogenase.
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PMID:The changes of prooxidant and antioxidant enzyme activities in bovine leukemia virus-transformed cells. Their influence on quinone cytotoxicity. 839 4

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