Gene/Protein Disease Symptom Drug Enzyme Compound
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Query: UNIPROT:P47989 (xanthine oxidase)
 8,633 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

The stable free radical Tempol (4-hydroxy-2,2,6,6-tetramethyl-piperidinyloxy) has been shown to protect against X-ray-induced cytotoxicity and hydrogen peroxide- or xanthine oxidase-induced cytotoxicity and mutagenicity. The ability of Tempol to protect against X-ray- or neocarzinostatin (NCS)-induced mutagenicity or DNA double-strand breaks (dsb) was studied in Chinese hamster cells. Tempol (50 mM) provided a protection factor of 2.7 against X-ray-induced mutagenicity in Chinese hamster ovary (CHO) AS52 cells, with a protection factor against cytotoxicity of 3.5. Using the field inversion gel electrophoresis technique of measuring DNA dsb, 50 mM Tempol provides a threefold reduction in DNA damage at an X-ray dose of 40 Gy. For NCS-induced damage, Tempol increased survival from 9% to 80% at 60 ng/mL NCS and reduced mutation induction by a factor of approximately 3. DNA dsb were reduced by a factor of approximately 7 at 500 ng/mL NCS. Tempol is representative of a class of stable nitroxide free radical compounds that have superoxide dismutase-mimetic activity, can oxidize metal ions such as ferrous iron that are complexed to DNA, and may also detoxify radiation-induced organoperoxide radicals by competitive scvenging. The NCS chromophore is reduced by sulfhydryls to an active form. Electron spin resonance (ESR) spectroscopy shows that 2-mercaptoethanol-activated NCS reacts with Tempol 3.5 times faster than does unactivated NCS. Thus, Tempol appears to inactivate the NCS chromophore before a substantial amount of DNA damage occurs.
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PMID:Nitroxide-mediated protection against X-ray- and neocarzinostatin-induced DNA damage. 145 74

The purpose of this study was to develop a simple antioxidant screening assay for quantifying the protective effects of antioxidant enzymes, inhibitors and scavengers against extracellularly generated oxygen species on human skin fibroblast cytotoxicity. Different in vitro oxidative stresses have been studied: xanthine oxidase-hypoxanthine, flavin mononucleotide-NADH, and hydrogen peroxide. Cytotoxicity and protection were evaluated by two procedures: evaluation of the living cells using a colorimetric method (3-(4,5-dimethylthiazol-2-yl)-2,5-diphenyltetrazolium bromide MTT), and ability of the viable cells to adherate and proliferate. Hypoxanthine-xanthine oxidase and H2O2 induced a dose dependent cytotoxicity only when we considered the delayed toxicity. The influence of the cell density was also investigated. The delayed toxicity was higher when cell density increased. One hundred percent protection against free radical cytotoxicity induced by the three systems were obtained with catalase (500 U/ml). When the oxidative stress used was H2O2 90-96% protection was obtained with deferoxamine an iron chelating agent that prevents iron catalysed radical reactions. Using the colorimetric method no significant protection was obtained when SOD was added before and during the stresses. Using the fibroblasts ability to proliferate SOD (10-150 micrograms/ml) reduced xanthine oxidase (20 U/l)-hypoxanthine (0.10-0.30 mM) or H2O2 (1-6 mM) cytotoxicity by 15-20%. SOD did not act as antioxidant when the applied stress was mediated by flavin. In this study we showed a paradoxical effect and the cytotoxicity of flavin-NADH system increased when we added SOD to the cell medium. This simple and reliable antioxidant screening assay required no costly or radioactive equipment.
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PMID:Development of a simple antioxidant screening assay using human skin fibroblasts. 150 88

Myocardial phospholipase D (PLD) is primarily localized at the sarcolemmal level and selectively hydrolyzes phosphatidylcholine to form phosphatidic acid as part of the signal transduction mechanisms for regulating Ca2+ movements in the heart. Since the myocardial cell damage induced by oxidative stress is associated with abnormalities in Ca2+ homeostasis and thiol status, we examined the thiol group dependence and the effects of oxidant species on this enzyme. Sarcolemmal membranes isolated from rat heart were exposed to several types of thiol group modifiers. Alkylation with N-ethylmaleimide or methyl methanethiosulfonate, mercaptide formation with p-chloromercuriphenylsulfonic acid, and thiol-disulfide exchange with 5,5'-dithio-bis(2-nitrobenzoate) depressed sarcolemmal PLD activity; in all cases the depression was prevented by dithiothreitol. At different concentrations of N-ethylmaleimide the PLD depression correlated well (r = 0.98) with the decrease in total thiol group content of the membrane. The enzyme activity was not affected by xanthine-xanthine oxidase, a superoxide anion-generating system, but was depressed by hydrogen peroxide (H2O2) in a concentration-dependent manner. This inhibitory effect was prevented by catalase as well as by dithiothreitol, but not by D-mannitol. The effect of a hydroxyl radical-generating system (Fenton reaction) could not be assessed because of an interfering direct inhibition by Fe2+. Dithiothreitol was also able to restore PLD activity in H2O2-pretreated membranes and to prevent a severe deactivation of the enzyme by hypochlorous acid (HOCI). Protection by glutathione and inhibition by its oxidized form were also observed.(ABSTRACT TRUNCATED AT 250 WORDS)
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PMID:Depression of cardiac sarcolemmal phospholipase D activity by oxidant-induced thiol modification. 151 67

Peroxynitrite (ONOO-) is a potent oxidizing agent that initiates lipid peroxidation and sulfhydryl oxidation and may be responsible for a portion of the cytotoxicity attributed to superoxide anion (.O2-). We quantified the extent to which ONOO-, xanthine plus xanthine oxidase (XO) and hydrogen peroxide (H2O2), decreased sodium (Na+) uptake into membrane vesicles derived from colonic cells of dexamethasone-treated rats. Carrier-free 22Na+ uptake into vesicles was measured in the presence of an inside-negative membrane potential, produced by the addition of the potassium ionophore valinomycin (10 microM) after removal of all external potassium by cation exchange chromatography. Preincubation of vesicles with either 100 microM or 1 mM ONOO- for 30 s decreased the amiloride-blockable fraction of Na+ uptake by 27 +/- 7% and 65 +/- 2%, respectively (means +/- S.E.; n greater than or equal to 5; P less than 0.05 from control). However, the amiloride-insensitive part of Na+ uptake was not affected, indicating that there was no overt destruction of these vesicles by these ONOO- concentrations. Decomposed ONOO-, hydrogen peroxide (1 microM-10 mM), or xanthine (500 microM) plus XO (10-30 mU/ml), either in the absence or in the presence of 100 microM FeEDTA, did not decrease Na+ uptake. These data suggest that ONOO- is a potent injurious agent that can compromise Na+ uptake across epithelial cells, possibly by damaging Na+ channels.
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PMID:Peroxynitrite inhibits sodium uptake in rat colonic membrane vesicles. 155 Aug 56

The hepatotoxic effects of hyperthermia have been proposed to be related to lipid peroxidation as a consequence of oxidative stress. This can result from exposure of the cell to "radical oxygen" species such as the superoxide and hydrogen peroxide generated by the activity of the oxidase form (type O) of xanthine oxidase (XO), which is converted to that form by perfusion of the liver at hyperthermic temperatures. These radical species are not reactive enough in themselves to cause cell damage but require the presence of a catalyst such as low molecular weight chelated iron. In these studies, ferritin was shown to be a source of iron for the oxidative stress of hyperthermia. (a) Iron was released from ferritin in vitro by the activity of rat liver XO. The rate of iron release from ferritin in this incubation system was a function of the amount of type O XO present and the temperature. Inclusion of allopurinol or superoxide dismutase in the incubation resulted in significantly lower rates of iron release. (b) Livers from Sprague-Dawley rats were perfused at 42.5 degrees and 37 degrees C for 1 h. During the recirculating perfusion, loss of iron from the liver into the perfusate was significantly greater (P less than 0.05) at 42.5 degrees C than at 37 degrees C. Also, there was a pronounced increase in the lactate dehydrogenase and aspartate aminotransferase enzymes in the perfusate during perfusion at 42.5 degrees C. Furthermore, intrahepatic levels of low molecular weight chelated iron were significantly (P less than 0.05) increased following perfusion at 42.5 degrees C. All these responses were abrogated by the inclusion of allopurinol in the perfusate. (c) Oxidative stress, assessed by the efflux of glutathione and oxided glutathione from the liver at 42.5 degrees and 37 degrees C, was significantly (P less than 0.05) increased at the hyperthermic temperature. This oxidative stress was inhibited by iron chelation and allopurinol. These results demonstrate that there is a causal relationship between the generation of superoxide by type O XO produced by hyperthermic perfusion and mobilization of iron from ferritin to form a pool of low molecular weight chelated iron. This iron pool in combination with active oxygen species leads to oxidative stress and lipid peroxidation.
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PMID:Involvement of xanthine oxidase in oxidative stress and iron release during hyperthermic rat liver perfusion. 155 Oct 99

Nitroxide compounds are stable free radicals which were previously investigated as hypoxic cell radiosensitizers. The stable nitroxide 4-hydroxy-2,2,6,6-tetramethylpiperidine-N-oxyl (Tempol) has recently been shown to protect aerated cells in culture against superoxide generated from hypoxanthine/xanthine oxidase, hydrogen peroxide, and radiation-induced cytotoxicity and to modestly sensitive hypoxic cultured cells. To extend these observations from the cellular level to the whole animal, the toxicity, pharmacology, and in vivo radioprotective effects of Tempol were studied in C3H mice. The maximum tolerated dose of Tempol administered i.p. was found to be 275 mg/kg, which resulted in maximal Tempol levels in whole blood 5-10 min after injection. Mice were exposed to whole-body radiation in the absence or presence of injected Tempol (275 mg/kg) 5-10 min after administration. Tempol treatment provided significant radioprotection (P less than 0.0001); the dose of radiation at which 50% of Tempol-treated mice die at 30 days was 9.97 Gy, versus 7.84 Gy for control mice. Tempol represents a new class of in vivo, non-sulfur-containing radiation protectors. Given the potential for hypoxic radiosensitization and aerobic cell radioprotection, Temporal or other analogues may have potential therapeutic application.
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PMID:Tempol, a stable free radical, is a novel murine radiation protector. 155 Nov 4

Two superoxide dismutase-mimetic lipophilic copper complexes, Cu(II)2(indomethacin)4 [Cu(II)2(indo)4] and Cu(II)2(3,5-diisopropylsalicylate)4 [Cu(II)2(3,5-DIPS)4], were tested for their effects on the respiratory burst of intact human granulocytes and on xanthine oxidase, under conditions where superoxide and hydrogen peroxide were generated. The effect of the copper complexes on these enzyme systems (as opposed to their dismutase effect on superoxide) was determined by measuring oxygen uptake with an oxygen meter. It was found that, after a short delay, both systems were inhibited markedly by micromolar amounts of these complexes. This inhibition was prevented by treatment with EDTA or catalase if added prior to starting the reaction. Similar inhibitory effects were seen using copper sulfate. It appears that these lipophilic SOD-mimetic compounds can, in the presence of H2O2 and O2-, give rise to a species that can inhibit some component of the respiratory burst oxidase or protein kinase C in intact granulocytes and xanthine oxidase in solution. The observed decrease in O2- levels observed upon addition of these compounds is likely due to inhibition of the source and not to their SOD-mimetic properties.
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PMID:Inhibition by superoxide dismutase-mimetic copper complexes of phorbol ester-induced respiratory burst in human granulocytes. 155 79

Reperfusion of ischaemic myocardium is necessary to sustain tissue viability (without it the tissue becomes necrotic), but reperfusion, on the other hand, can damage cells which have survived ischaemia. There is now considerable evidence that oxygen radicals, especially hydroxyl radicals produced via the Haber-Weiss and Fenton reactions, are responsible for reperfusion damage. Various investigators have reported that desferal, an iron chelator, has a beneficial effect on the myocardium during ischaemia and reperfusion. The aim of this study was two-fold: i) whether superoxide anions in the absence of LMWI can impair mitochondrial function, and ii) whether the protective effect of desferal on the mitochondrial function persists after withdrawal of desferal. Experiments were done on isolated rat hearts subjected to normothermic ischaemic cardiac arrest (NICA), with or without desferal, followed by 15-min reperfusion with desferal, followed by 15-min perfusion without desferal, or a hypoxanthine/xanthine oxidase medium that generates superoxide anions (with or without desferrioxamine (desferal) in the perfusate). Mitochondrial function (QO2 (state 3), ADP/O and OPR) as well as LMWI were measured. Our results indicated that i) superoxide anions and/or hydrogen peroxide can, independently of LMWI, damage the mitochondria, and ii) withdrawal of desferal after the respiratory burst resulted in the same or more severe mitochondrial damage than without any desferal.
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PMID:The protective effect of desferal on rat myocardial mitochondria is not prolonged after withdrawal of desferal. 156 53

The effect of hypoxia on subsequent susceptibility of porcine pulmonary artery endothelial cells (PAEC) to hydrogen peroxide (H2O2) injury was studied. Preexposure of PAEC to hypoxia for 3 or more h significantly increased susceptibility to subsequent H2O2 challenge. Analysis of the activities of antioxidant enzymes and xanthine oxidase/dehydrogenase suggested that changes in these enzymes in hypoxic PAEC were not responsible for the increased susceptibility. However, hypoxia resulted in significant time-dependent decreases in total glutathione at 12 h or more. The rate of glutathione regeneration in diethylmaleate-treated PAEC and the rate of uptake of cystine and glycine were significantly lower during hypoxia. Hypoxia also caused depletion of ATP and NADPH levels in PAEC, but these did not occur until well after hypoxia-enhanced susceptibility to H2O2 injury was demonstrable. Alterations in glutathione levels and enhanced susceptibility were reversible when hypoxic PAEC were returned to normoxia. These results indicate that hypoxia increased the susceptibility to H2O2 injury by decreasing the ability of PAEC to maintain and regenerate cellular glutathione content in response to H2O2 challenge.
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PMID:Hypoxia increases the susceptibility of pulmonary artery endothelial cells to hydrogen peroxide injury. 157 99

Activation of glutathione transferase activity in rat liver microsomes under a variety of conditions producing oxidative stress was investigated. Neither hydrogen peroxide (10 mM) (added or produced endogenously by glucose + glucose oxidase) nor duroquinone together with an NADPH-regenerating system (which generates the superoxide anion radical) had any significant effect on the glutathione transferase activity towards 1-chloro-2,4-dinitrobenzene. On the other hand, incubation of microsomes with 1 mM noradrenaline (which autooxidizes and generates superoxide anion radical) gave a 160% activation, as shown earlier (Aniya and Anders, J Biol Chem 264: 1998-2002, 1989). This was taken as an indication that microsomal glutathione transferase could be activated by oxidative stress. Here, we demonstrate that activation by this compound is due to covalent binding (presumably of the quinone formed during autooxidation). The xanthine/xanthine oxidase system, which generates the superoxide anion radical and hydrogen peroxide, increases microsomal glutathione transferase activity, but this activation was not dependent on the presence of xanthine. Western blots of microsomes treated with xanthine oxidase revealed that activation was due to proteolysis (presumably by contaminating proteases in the xanthine oxidase). In conclusion, there is no firm evidence that rat liver microsomal glutathione transferase is activated directly by reduced oxygen species in the microsomal system. The possibility remains that oxidative stress triggers secondary mechanisms such as generation of reactive intermediates and/or activation of proteolysis, which can in turn increase enzyme activity.
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PMID:Mechanism of activation of rat liver microsomal glutathione transferase by noradrenaline and xanthine oxidase. 157 69


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