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)

Following the two-electron reduction of 2-methyl-1,4-naphthoquinone by rat liver DT-diaphorase (also called NAD(P)H: (quinone acceptor) oxidoreductase, EC 1.6.99.2), the hydroquinone product is slowly autoxidized to the quinone in buffered solutions at pH 7.0. The autoxidation, which generates the superoxide radical (O2-.) and other reactive oxygen species, is the rate-limiting step in the oxidation-reduction (redox) cycling of the quinone. The addition of ascorbate to these reaction mixtures increases the rate of redox cycling. Two mechanisms are proposed to explain this increase: (1) ascorbate reduces the quinone in a one-electron reduction and (2) if Fe(3+)-EDTA is present, ascorbate reduces the metal chelate in a one-electron reduction. Both mechanisms produce O2-. which initiates the free radical chain reaction that results in autoxidation of the hydroquinone. Although ascorbate may be a physiologically important antioxidant under some conditions, the studies reported here show that ascorbate is a prooxidant in the redox cycling of 2-methyl-1,4-naphthoquinone and, as such, could increase the potential toxicity of this quinone.
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PMID:Effect of ascorbate on the DT-diaphorase-mediated redox cycling of 2-methyl-1,4-naphthoquinone. 773 72

High-level cytosolic class-3 aldehyde dehydrogenase (ALDH-3)-mediated oxazaphosphorine-specific resistance (> 35-fold as judged by the concentrations of mafosfamide required to effect a 90% cell-kill) was induced in cultured human breast adenocarcinoma MCF-7/0 cells by growing them in the presence of 30 microM catechol for 5 days. Resistance was transient in that cellular sensitivity to mafosfamide was fully restored after only a few days when the inducing agent was removed from the culture medium. The operative enzyme was identified as a type-1 ALDH-3. Cellular levels of glutathione S-transferase and DT-diaphorase activities, but not of cytochrome P450 IA1 activity, were also elevated. Other phenolic antioxidants, e.g. hydroquinone and 2,6-di-tert-butyl-4-hydroxytoluene, also induced ALDH-3 activity when MCF-7/0 cells were cultured in their presence. Thus, the increased expression of a type-1 ALDH-3 and the other enzymes induced by these agents was most probably the result of transcriptional activation of the relevant genes via antioxidant responsive elements present in their 5'-flanking regions. Cellular levels of ALDH-3 activity were also increased when a number of other human tumor cell lines, e.g. breast adenocarcinoma MDA-MB-231, breast carcinoma T-47D and colon carcinoma HCT 116b, were cultured in the presence of catechol. These findings should be viewed as greatly expanding the number of recognized environmental and dietary agents that can potentially negatively influence the sensitivity of tumor cells to cyclophosphamide and other oxazaphosphorines.
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PMID:Phenolic antioxidant-induced overexpression of class-3 aldehyde dehydrogenase and oxazaphosphorine-specific resistance. 788 82

Norepinephrine was oxidized by the Mn(3+)-pyrophosphate complex to the corresponding o-quinone at pH 6.5. Cyclized norepinephrine ortho-quinone showed an absorption maximum at 289 and 483 nm. No oxygen consumption was observed during oxidation of norepinephrine to o-quinone by Mn3+ and subsequent cyclization. The reduction of cyclized norepinephrine ortho-quinone to the corresponding hydroquinone was catalyzed by DT-diaphorase. However, the hydroquinone formed proved to be unstable in the presence of oxygen, since reduction of cyclized norepinephrine o-quinone by DT-diaphorase was accompanied by continuous oxidation of NADH and oxygen consumption. Addition of the chelator DETAPAC or SOD to the incubation mixture during reduction of cyclized norepinephrine ortho-quinone by DT-diaphorase strongly inhibited NADPH oxidation and oxygen consumption, suggesting that manganese and superoxide radicals were involved in hydroquinone autoxidation. Elimination of the effects of superoxide radicals, manganese and H2O2 on autoxidation of hydroquinone by addition of SOD, catalase and DETAPAC to the incubation mixture resulted in a 79% inhibition of NADH oxidation, suggesting that 21% of the autoxidation is oxygen-dependent. However, the effect of these additions on oxygen consumption was even more pronounced (93% inhibition).
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PMID:The protective effect of superoxide dismutase and catalase against formation of reactive oxygen species during reduction of cyclized norepinephrine ortho-quinone by DT-diaphorase. 803 41

Dopa was oxidized by Mn(3+)-pyrophosphate complex to the corresponding o-quinone, accompanied by the cyclization of the amino chain to form cyclized dopa ortho-quinone (cDoQ) with absorption maxima at wavelengths of 305 and 475 nm. The cyclization was found to proceed in a single step from DoQ to cDoQ without formation of cDoQH2 and oxygen consumption. DT-diaphorase catalyzes the reduction of cDoQ to the corresponding hydroquinone (cDoQH2), which was found to be unstable in the presence of oxygen. The autoxidation of the cDoQH2 was followed by recording the constant oxidation of NADH and oxygen consumption and reduction of cDoQ at a wavelength of 475 nm. It was found that three different oxidizing agents were involved in autoxidation of cDoQH2. The addition of DETAPAC resulted in a strong inhibition of NADH oxidation (65% inhibition) during the reduction of cDoQ by DT-diaphorase, suggesting that manganese was responsible for 65% of the autoxidation of cDoQH2. The addition of SOD to the incubation mixture resulted in the inhibition of NADH oxidation (79%) during the reduction of cDoQ by DT-diaphorase. In the presence of DETAPAC, the addition of SOD inhibited NADH oxidation during cDoQH2 autoxidation 75%, suggesting that superoxide radicals are responsible for 75% of the oxygen-dependent autoxidation. The remaining NADH oxidation, which was not inhibited by DETAPAC and SOD, was accompanied by a constant oxygen consumption, suggesting that this autoxidation of cDoQH2 proceeds by reducing oxygen to superoxide radical. The effect of SOD and catalase in the presence of DETAPAC was also studied. A nearly complete inhibition (90%) of oxygen consumption during the reduction of cDoQ by DT-diaphorase was observed when SOD alone or SOD and catalase were added to the incubation mixture containing DETAPAC. We conclude that SOD and catalase constitute a protective cellular system against formation of reactive oxygen species during reduction of cDoQ by DT-diaphorase.
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PMID:Superoxide dismutase and catalase prevent the formation of reactive oxygen species during reduction of cyclized dopa ortho-quinone by DT-diaphorase. 808 30

Levels of mRNAs encoding class-alpha glutathione transferases, class-mu glutathione transferases, quinone reductase, and cytochrome P450 1A were measured after xenobiotic induction in murine tissues and in the Hepa1c1c7 murine hepatoma cell line. RNA levels in liver and intestinal mucosa were determined after induction with phenobarbital, butylated hydroxyanisole, beta-naphthoflavone, isosafrole, or combinations of these compounds. The tissue culture cells were presented with combinations of butylated hydroxyanisole, tert-butyl-hydroquinone, and beta-naphthoflavone. In murine liver and intestinal mucosa, the greatest induction (5-15-fold) of glutathione transferases and quinone reductase was seen with butylated hydroxyanisole. Administration of phenobarbital or beta-naphthoflavone has only a modest effect (2-3-fold). In contrast, cytochrome P450 1A mRNA levels increase only slightly after BHA induction but are induced dramatically by beta-naphthoflavone. The pattern of induction is different in Hepa1c1c7 cells; there the greatest induction of all mRNAs occurred with beta-naphthoflavone. Administration of antioxidants with other xenobiotics increases mRNA levels only slightly over the levels obtained with BHA in murine tissues, or with beta-naphthoflavone in Hepa1c1c7 cells. mGSTM1 (GT8.7, Yb1), the most abundant glutathione transferase mRNA in murine liver, is also the most abundant glutathione transferase mRNA in both normal and induced Hepa1c1c7 cells. Our results suggest that BHA induction in murine liver and intestinal mucosa of class-mu and class-alpha glutathione transferases may involve regulatory elements and mediators that function poorly in Hepa1c1c7 cells.
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PMID:Differences in induction by xenobiotics in murine tissues and the Hepa1c1c7 cell line of mRNAs encoding glutathione transferase, quinone reductase, and CYP1A P450s. 822 Apr 36

Stromal cells from DBA/2 mouse bone marrow have been shown to be susceptible to cytotoxicity induced by several redox-active metabolites of benzene, including hydroquinone (HQ). Treatment with HQ also alters the composition of stromal cell populations by preferentially killing stromal macrophages compared to stromal fibroblasts. This cytotoxicity can be prevented by 1,2-dithiole-3-thione (DTT) as a result of the induction of quinone reductase (QR), a quinone-processing enzyme, and glutathione. The inductive activities of DTT protected stromal cells against HQ-induced cytotoxicity and against HQ-induced impairment of stromal cell ability to support myelopoiesis. In vivo feeding of DTT to DBA/2 mice increased QR activity within the bone marrow compartment and protected bone marrow stromal cells isolated from the DTT-fed animals from ex vivo HQ challenge. Thus, the inducibility of cellular defense mechanisms and xenobiotic-processing enzymes by chemoprotective agents such as DTT may be a useful strategy for protecting against chemically induced bone marrow toxicities.
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PMID:Studies with 1,2-dithiole-3-thione as a chemoprotector of hydroquinone-induced toxicity to DBA/2-derived bone marrow stromal cells. 835 4

A simple system for aerobic assay of the quinol-fumarate reductase reaction catalyzed by purified soluble bovine heart succinate-ubiquinone reductase in the presence of NADH, NAD(P)H-quinone reductase (DT-diaphorase) and an appropriate quinone is described. The reaction is inhibited by carboxin, suggesting that the same quinone/quinol binding site is involved in electron transfer from succinate to ubiquinone and from ubiquinol to fumarate. The kinetic properties of the reaction in both directions and comparative affinities of the substrate binding sites of the enzyme to substrates (products) and competitive inhibitors are reported. Considerable difference in affinity of the substrates binding site to oxaloacetate was demonstrated when the enzyme was assayed in the direct and reverse directions. These results were taken to indicate that the oxidized dicarboxylate-free enzyme is an intermediate during the steady-state succinate-ubiquinone reductase reaction, whereas the reduced dicarboxylate-free enzyme is an intermediate of the steady-state ubiquinol-fumarate reductase reaction. No difference in the reactivity of the substrate-protected cysteine and arginine residues was found when the pseudo-first-order rate constants for N-ethylmaleimide and phenylglyoxal inhibition were determined for oxidized and quinol-reduced enzyme. Quinol-fumarate reductase activity was reconstituted from the soluble succinate dehydrogenase and low-molecular-mass ubiquinone reactivity conferring protein(s). No reduction of cytochrome b was observed in the presence of quinol generating system, whereas S-3 low temperature EPR-detectable iron-sulfur center was completely reduced by quinol under equilibrium (without fumarate) or steady-state (in the presence of fumarate). No significant reduction of ferredoxin type iron-sulfur centers was detected during the steady-state quinol-fumarate oxidoreductase reaction. The data obtained eliminate participation of cytochrome b in the quinol-fumarate reductase reaction and show that the rate limiting step of the overall reaction lies between iron-sulfur center S-3 and lower midpoint potential redox components of the enzyme.
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PMID:Fumarate reductase activity of bovine heart succinate-ubiquinone reductase. New assay system and overall properties of the reaction. 841 79

The nucleotide sequence preferences for the formation of interstrand cross-links induced in DNA by 2,5-diaziridinyl-1,4-benzoquinone (DZQ) and 3,6-dimethyl-2,5-diaziridinyl-1,4-benzoquinone (MeDZQ) were studied using synthetic duplex oligonucleotides and denaturing polyacrylamide gel electrophoresis (PAGE). Reaction of these bifunctional alkylating agents with a DNA duplex containing several potential cross-linking sites resulted in the formation of cross-linked DNAs with different electrophoretic mobilities. Analysis of the principal cross-linked products by piperidine fragmentation revealed that the preferential site of cross-linking was altered from a 5'-GNC to a 5'-GC sequence upon reduction of DZQ to the hydroquinone form by the enzyme DT-diaphorase. In contrast, the reduced form of MeDZQ was found to preferentially cross-link at 5'-GNC sites within the same sequence. These preferences were confirmed in duplex oligonucleotides containing single potential cross-linking sites. Additional minor cross-linked products were characterized and revealed that DZQ and MeDZQ are both capable of cross-linking across four base pairs in a 5'-GNNC sequence.
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PMID:Two structurally related diaziridinylbenzoquinones preferentially cross-link DNA at different sites upon reduction with DT-diaphorase. 846 Dec 96

The enzymic activity of phytoene desaturase in Narcissus pseudonarcissus chromoplast membranes depends in an essential way on the redox state of its environment. Here, the main redox-active components are quinones and tocopherols. Quinones (oxidized) act as intermediate electron acceptors in the desaturation reaction, as can be shown in reduced, hydroquinone-rich membranes. However, their complete oxidation by ferricyanide treatment of membranes leads to inhibition of the desaturation activity and, under these conditions, hydroquinones are required for reactivation. Using redox titrations, it is shown here that the optimal activity lies in the range of the midpoint potential of the plastoquinone/plastohydroquinone redox couple. For the adjustment of redox states of the redox-active lipid components in (photosynthetically inactive) chromoplasts, NADPH and oxygen are involved, the latter acting as a terminal acceptor. This results in a respiratory redox pathway in chromoplast membranes which is described here, to our knowledge, for the first time. Since phytoene desaturation responds to the redox state of quinones, which is adjusted by the respiratory redox pathway, the two reactions must be regarded as being mechanistically linked. The first protein component involved in the respiratory pathway which we have investigated molecularly is a 43-kDa NAD(P)H:quinone oxidoreductase, which is organized as a homodimer (23 +/- 3 kDa/subunit) and apparently possesses a manganese redox center. Internal protein microsequencing and cloning of the corresponding cDNA revealed a high degree of similarity to the 23-kDa protein of the oxygen-evolving complex of photosystem II, but no information about the N-terminal organization of the oxidoreductase could be obtained. During flower development, the steady-state concentration of the corresponding mRNA is up-regulated, indicating a specific function of the gene product in chlorophyll-free chromoplasts.
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PMID:Carotene desaturation is linked to a respiratory redox pathway in Narcissus pseudonarcissus chromoplast membranes. Involvement of a 23-kDa oxygen-evolving-complex-like protein. 852 52

NADPH-cytochrome1 P450 reductase and DT-diaphorase catalyze and one- and two-electron reduction of adrenochrome to its o-semiquinone and o-hydroquinone, respectively. Under aerobic conditions both adrenochrome o-semiquinone and o-hydroquinone proved to be unstable, undergoing autoxidation with concomitant oxygen consumption and continuous NADPH and NADH oxidation. Molecular oxygen was found to play a predominant role in autoxidation of o-semiquinone during reduction of adrenochrome catalyzed by NADPH-cytochrome P450 reductase. In addition, molecular oxygen, in the presence of manganese, was found to be responsible for the majority of autoxidation of o-semiquinone. However, the role of superoxide radicals in the autoxidation of leucoadrenochrome during the reduction of adrenochrome by DT-diaphorase was found to be predominant. Catalase different significantly with respect to NADPH and NADH oxidation during reduction of adrenochrome catalyzed by NADPH-cytochrome P450 reductase and DT-diaphorase. Catalase increased NADPH oxidation slightly, while NADH oxidation was inhibited during reduction of adrenochrome by NADPH cytochrome P450 reductase and DT-diaphorase, respectively. The presence of manganese in the incubation mixture was found to increase the prooxidant role of catalase on autoxidation during one-electron reduction of aminochrome catalyzed by NADPH cytochrome P450 reductase. A marked difference in the inhibitory effect of superoxide dismutase on oxygen consumption during adrenochrome reduction catalyzed by NADPH-cytochrome P450 reductase and DT-diaphorase was also observed. A possible mechanism for reduction of adrenochrome by NADPH-cytochrome P450 reductase and DT-diaphorase and a role for superoxide dismutase and catalase are proposed.
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PMID:Effects of superoxide dismutase and catalase during reduction of adrenochrome by DT-diaphorase and NADPH-cytochrome P450 reductase. 859 36


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