EC:1.17.3.2 - FACTA Search

Gene/Protein Disease Symptom Drug Enzyme Compound
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Query: EC:1.17.3.2 (xanthine oxidase)
8,383 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

Sources of superoxide anion (O2-.) production in calf pulmonary artery smooth muscle homogenate and subcellular fractions were examined in this study by measurement of the chemiluminescence produced by the reaction of O2-. with 50 microM lucigenin, because recent evidence suggests that endogenously produced reactive O2 species appear to mediate certain vascular responses. In the homogenate fraction, an NADH (0.1 mM)-dependent oxidoreductase activity was the major detected source of chemiluminescence. NADPH (0.1 mM) produced only 3% of the O2-. observed with NADH. Quantitation of certain other potential sources of O2-. (under optimized conditions), including xanthine oxidase (0.1 mM hypoxanthine), mitochondria (5 mM succinate + 30 microM antimycin), cyclooxygenase/lipoxygenase (1 microM arachidonic acid + 0.1 mM NADPH), or autooxidation (0.1 mg/ml superoxide dismutase), resulted in the detection of minimal amounts (< 3% of NADH) of chemiluminescence. Estimation of mitochondrial O2-. production from tissue respiration rates suggests that lucigenin is a poor detector of intramitochondrial O2-.. These observations were confirmed by examination of chemiluminescence produced by subcellular fractions, where the major activity detected was an NADH oxidoreductase, which fractionated in a manner closely matching the activity of the microsomal marker enzyme rotenone-insensitive NADH-cytochrome c reductase. Because this NADH oxidoreductase appears to be a major vascular smooth muscle-derived source of O2-. production, this system has the potential to be an important endogenous source for the generation of vasoactive reactive O2 species.
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PMID:Sites of superoxide anion production detected by lucigenin in calf pulmonary artery smooth muscle. 781 Jun 85

Nitroxides stable radicals are unreactive toward most diamagnetic molecules, but readily undergo one-electron redox reactions with paramagnetic species such as free radicals and transition metals, thus serving as cell-permeable antioxidants. The cytotoxicity of juglone (5-hydroxy-1,4-naphthoquinone), like that of other naphthoquinones, requires bioreduction to yield the semiquinone which in turn reduces oxygen to O2.-. Therefore, nitroxides are expected to mitigate cytotoxicity of quinone-based xenobiotics, such as naphthoquinones. In the present study, in vitro scission of isolated DNA was induced upon juglone reduction by glutathione and Fe(II) ions, however, not by xanthine oxidase or cytochrome c reductase. The DNA scission was inhibited by nitroxides, catalase and chelating agents, though not by superoxide dismutase. Juglone was more toxic toward bacterial cells under hypoxia than under air. Nitroxides < or = 2 mM protected bacterial cells from juglone-induced toxicity under both aerobic and hypoxic conditions. The cytoprotective effect of lipophilic nitroxide was greater than that of hydrophilic ones. Catalase and metal chelating agents decreased juglone-induced cell killing, whereas H2O2 increased it. The mechanisms underlying the nitroxides protective effect involve (a) the reoxidation of reduced transition metal ions, (b) the selective radical-radical reaction with juglone semiquinone, and possibly (c) under aerobic condition catalytic removal of extra- and intracellular O2.-. The present results suggest also that the cell membrane rather than DNA is the main target of juglone toxicity.
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PMID:Effects of nitroxide stable radicals on juglone cytotoxicity. 803 50

Both phenylbutazon and mofebutazon inhibit oxidative fragmentation of the methionine derivative, 2-keto-4-methylthio-butyric acid (KMB) by xanthine oxidase--or diaphorase mediated OH radical production. Differentiation of the two non-steroidal antiinflammatory drugs is possible by means of determining oxygen reduction by xanthine oxidase or diaphorase in the presence of the naphthoquinone, juglone, where only mofebutazon shows an inhibitory effect.
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PMID:Antioxidative properties of phenazone derivatives: differentiation between phenylbutazon and mofebutazon. 821 10

Ethanolic extracts of Propolis are used as antiinflammatory and wound healing drugs since ancient times. In order to facilitate a comparison of different extracts, the standardization on the basis of quantitative determination of prominent components of these extracts has been substituted for simple biochemical "activity" tests. One of these activity tests bases on the inhibition of peroxidase-catalyzed oxidation of indole acetic acid indicating the presence of a defined mixture of monophenolic and diphenolic compounds. Other tests (diaphorase-catalyzed reductions and xanthine oxidase-catalyzed oxidations) demonstrate significant radical scavenging properties. Water-soluble extracts of propolis exhibit higher antioxidative and inhibitory activities as compared to the ethanolic extract.
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PMID:Biochemical activities of propolis extracts. I. Standardization and antioxidative properties of ethanolic and aqueous derivatives. 829 22

The small intestine can metabolize a variety of substances and can play a role in the presystemic clearance of ingested compounds. Relatively little is known about the ability of small intestine to catalyze the presystemic reductive metabolism of xenobiotics. 1,3-Dinitrobenzene (1,3-DNB), which is known to undergo reductive biotransformation in an intact, oxygenated isolated perfused intestinal preparation, was used as a model substrate for reductive enzymes of the small intestine of the rat. Subcellular fractions from duodenal, jejunal, and ileal regions of rat small intestinal mucosa were used to characterize the enzyme source(s) of those reductive reactions of 1,3-DNB that are relevant in the oxygenated intestinal tissue. 1,3-DNB was reduced to 3-nitroaniline (3-NA) by cytosol from duodenum and jejunum. The rate of reduction was 2 times faster when incubations contained duodenal rather than jejunal cytosol. Jejunal cytosol-catalyzed reduction of 1,3-DNB was supported by hypoxanthine, NADPH, or NADH. Duodenal microsomes catalyzed the reduction of 1,3-DNB to 3-NA in the presence of supplemental NADPH or NADH; however, the reaction was very slow. Jejunal microsomes, ileal microsomes, and ileal cytosol failed to catalyze the reduction of 1,3-DNB. Studies with chemical inhibitors suggested possible roles for DT diaphorase, glutathione reductase, or xanthine oxidase in the jejunal cytosol-catalyzed reaction. Purified, commercially available xanthine oxidase (from buttermilk) catalyzed the reduction of 1,3-DNB to 3-NA when supplemented with NADH or hypoxanthine.
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PMID:Metabolism of [14C]1,3-dinitrobenzene by rat small intestinal mucosa in vitro. 856 89

Mitomycin C (MMC), an alkylating anti-tumor agent, was activated by non-enzymatic and enzymatic mechanisms leading to DNA binding and adduct formation. However, it was enzymatically, not non-enzymatically, activated MMC which induced inter-strand DNA cross-linking, a major determinant of cell death. The enzymatic activation of MMC was catalyzed by microsomal NADPH:cytochrome P450 reductase (P450 reductase) and cytosolic enzyme activities. Human P450 reductase, transiently expressed from its cDNA in the COSI cells, metabolically activated MMC to generate 9 specific MMC-DNA adducts and induced inter-strand DNA cross-linking. Co-chromatography of the MMC-DNA adducts generated by P450 reductase and sodium borohydride in separate experiments indicated that MMC was metabolized by P450 reductase to produce 2,7-diaminomitosenes that exhibited binding to deoxyguanosine. Several experiments indicated that cytosolic enzymes which catalyzed reductive activation of MMC and DNA cross-linking included NAD(P)H:quinone oxidoreductaseI (NQOI or DT diaphorase) when present in extremely high concentrations and a unique cytosolic activity. The unique cytosolic activity was present in several mammalian cells and mouse colon and liver but absent in mouse kidney. The unique activity had properties of a diaphorase but was distinct from NQOI because of a lack of correlation between NQOI (2,6-dichlorophenolindophenol reduction) activity and the amount of MMC-reductive activation leading to DNA cross-linking. This activity was also distinct from xanthine oxidoreductase and NADH-cytochrome b5 reductase, 2 other enzymes that catalyze metabolic activation of MMC, because the unique activity was not inhibited by allopurinol (an inhibitor of xanthine oxidoreductase) and its activity was the same with NADH and NADPH (cytochrome b5 reductase is specific to NADH).
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PMID:Non-enzymatic and enzymatic activation of mitomycin C: identification of a unique cytosolic activity. 856 27

Nitroreductase enzymes generally catalyze the reduction of nitroaromatic compounds to the corresponding amines. In contrast, ferredoxin NADP oxidoreductase (FNR), glutathione reductase, xanthine oxidase, and cytochrome c reductase catalyze the NADPH dependent elimination of the nitramine nitro group from 2,4,6-trinitrophenylmethylnitramine to form N-methylpicramide (NMP). Nitrite elimination was inhibited under aerobic conditions. Our results suggest that under aerobic conditions, tetryl is enzymatically reduced to the nitroanion radical which is then involved in the reduction of molecular oxygen. Under anaerobic conditions, the radical is reduced to NMP and nitrite is eliminated.
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PMID:Elimination of nitrite from the explosive 2,4,6-trinitrophenylmethylnitramine (tetryl) catalyzed by ferredoxin NADP oxidoreductase from spinach. 860 4

Iron catalyzed free radical formation and lipid peroxidation are accepted mechanisms of heme protein-induced acute renal failure. However, the source(s) of those free radicals which trigger lipid peroxidation in proximal tubular cells remains unknown. This study tested the potential involvement of mitochondrial electron transport, xanthine oxidase activity, and arachidonic acid metabolism in the heme-induced peroxidative state. The impact of cytosolic Ca2+ loading also was assessed. Rhabdomyolysis was induced in mice by glycerol injection, and two hours later heme-laden proximal tubular segments (PTS) were isolated for study. PTS from normal mice served as controls. During 30 to 60 minute incubations, heme loaded PTS developed progressive cytotoxicity (LDH release) and iron-dependent lipid peroxidation (malondialdehyde, MDA, generation; inhibited by deferoxamine). Site 2 (antimycin A) or site 3 (cyanide, hypoxia) mitochondrial respiratory chain inhibition completely blocked lipid peroxidation, whereas site 1 inhibition (rotenone) doubled its extent (presumably by shunting NADH through NADH dehydrogenase, a free radical generating system). Conversely, these agents did not substantially alter MDA in normal PTS. Normal and heme loaded PTS developed comparable degrees of LDH release during respiratory blockade irrespective of increased or decreased MDA production (indicating that lipid peroxidation was not a critical determinant of cell death). Neither increasing free arachidonic acid (PLA2 treatment) nor adding cyclooxygenase/lipoxygenase/cytochrome p450 inhibitors conferred a consistent protective effect. Altering free Ca2+ status (chelators; ionophore addition) and xanthine oxidase inhibition had no discernible impacts. Despite mitochondrial free radical production, mitochondrial function, as assessed by the ATP/ADP ratio, seemingly remained intact. In conclusion, (1) the terminal mitochondrial respiratory chain is the dominant source of free radicals which trigger PTS lipid peroxidation; (2) iron is a required secondary factor; (3) although mitochondria fuel lipid peroxidation, they do not appear to be critical targets of the heme-induced oxidant attack.
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PMID:Mitochondrial free radical production induces lipid peroxidation during myohemoglobinuria. 864 15

The effects of reactive oxygen species (ROS) on myocardial antioxidants and on the activity of oxidative mitochondrial enzymes were investigated in the following groups of isolated, perfused rat hearts. I: After stabilization the hearts freeze clamped in liquid nitrogen (n = 7). II: Hearts frozen after stabilization and perfusion for 10 min with xanthine oxidase (XO) (25 U/l) and hypoxanthine (HX) (1 mM) as a ROS-producing system (n = 7). III: Like group II, but recovered for 30 min after perfusion with XO + HX (n = 9). IV: The hearts were perfused and freeze-clamped as in group III, but without XO + HX (n = 7). XO + HX reduced left ventricular developed pressure and coronary flow to approximately 50% of the baseline value. Myocardial content of hydrogen peroxide (H2O2) and malondialdehyde (MDA) increased at the end of XO + HX perfusion, indicating that generation of ROS and lipid peroxidation occurred. Levels of H2O2 and MDA normalized during recovery. Superoxide dismutase, reduced glutathione and alpha-tocopherol were all reduced after ROS-induced injury. ROS did not significantly influence the tissue content of coenzyme Q10 (neither total, oxidized, nor reduced), cytochrome c oxidase, and succinate cytochrome c reductase. The present findings indicate that the reduced contractile function was not correlated to reduced activity of the mitochondrial electron transport chain. ROS depleted the myocardium of antioxidants, leaving the heart more sensitive to the action of oxidative injury.
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PMID:Exogenous reactive oxygen species deplete the isolated rat heart of antioxidants. 895 32

Muscle necrosis induced by various phenylenediamine derivatives has been correlated with their autoxidation rate. However, a more detailed investigation of the cytotoxic mechanism using a model system of isolated hepatocytes and 2,3,5,6-tetramethylphenylenediamine (DD) shows little oxygen activation as indicated by the absence of cyanide resistant respiration, lipid peroxidation and lack of cytoprotection by iron chelators, superoxide dismutase mimics and xanthine oxidase inhibitors. Cytotoxicity was however attributed to oxidative stress as GSH was not only rapidly oxidized to GSSG but mixed protein disulfide formation also occurred. Furthermore, the disulfide reductant dithiothreitol added some time after DD restored protein thiols and prevented further cytotoxicity. This oxidative stress was attributed to a futile two electron redox cycle involving oxidation of DD to the corresponding diimine by the mitochondrial electron transport chain and rereduction by DT diaphorase. Evidence suggesting this was that both diimine accumulation and the ensuing cytotoxicity were markedly increased by inactivating hepatocyte DT diaphorase but were prevented by a subtoxic concentration of the mitochondrial respiratory inhibitor cyanide. Furthermore, addition of NADH generating substrates such as lactate, sorbitol, xylitol or ethanol prevented DD induced GSH oxidation and cytotoxicity. This suggests that DD undergoes intracellular redox cycling without oxygen activation until the hepatocyte is unable to maintain redox homeostasis and mixed protein disulfide cytotoxicity ensues.
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PMID:Phenylenediamine induced hepatocyte cytotoxicity redox. Cycling mediated oxidative stress without oxygen activation. 920 97

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