Gene/Protein Disease Symptom Drug Enzyme Compound
Pivot Concepts: Gene/Protein Disease Symptom Drug Enzyme Compound   Target Concepts: 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)

A systematic study of the influence of biological lipid peroxidation conditions on lipid hydroperoxide decomposition to thiobarbituric acid-reactive malondialdehyde is presented. A superoxide-dependent, iron-catalyzed peroxidation system was employed with xanthine oxidase plus hypoxanthine plus ferric iron-adenosine diphosphate complex as free radical generator. Purified cardiac membrane phospholipid (as liposomes) was the peroxidative target, and 15-hydroperoxy-eicosatetraenoic acid was used as a standard lipid hydroperoxide. Exposure of myocardial phospholipid to free radical generator at physiological pH (7.4) and temperature (37 degrees C) was found to support not only phospholipid peroxidation, but also rapid lipid hydroperoxide breakdown and consequent malondialdehyde formation during peroxidation. Under lipid peroxidation conditions, oxidative injury to the phospholipid polyunsaturated fatty acids required superoxide radical and ferric iron-adenosine diphosphate complex, whereas 37 degrees C temperature and trace iron were sufficient for lipid hydroperoxide decomposition to malondialdehyde. Harsh thiobarbituric acid-test conditions following peroxidation were not mandatory for either lipid hydroperoxide breakdown or thiobarbituric acid-reactive malondialdehyde formation. However, hydroperoxide decomposition that had begun in the peroxidation reaction could be completed during a subsequent thiobarbituric acid test in which no lipid autoxidation took place. Iron was more critical than heat in promoting the observed hydroperoxide decomposition to malondialdehyde during the lipid peroxidation reaction at 37 degrees C and pH 7.4. These data demonstrate that the radical generator, at physiological pH and temperature, serves a dual role as both initiator of membrane phospholipid peroxidation and promotor of lipid peroxide breakdown and thiobarbituric acid-reactive malondialdehyde formation.(ABSTRACT TRUNCATED AT 250 WORDS)
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PMID:Thiobarbituric acid-reactive malondialdehyde formation during superoxide-dependent, iron-catalyzed lipid peroxidation: influence of peroxidation conditions. 254 30

Oxygenase-catalyzed and non-enzymatic polyunsaturated fatty acid peroxidations have potential pathogenic roles in ischemic-reperfusion damage to the myocardium. Certain oxygenase inhibitors protect heart muscle from irreversible ischemic injury, and some antiperoxidants can inhibit oxygenase enzymes. We investigated the antiperoxidative abilities of eight anti-ischemic, cardioprotective oxygenase inhibitors to prevent myocardial-membrane phospholipid peroxidation through superoxide-driven, iron-promoted reactions with xanthine oxidase as the source of superoxide. Flurbiprofen, ibuprofen, and REV-5901-5 did not affect peroxidation at concentrations up to 1000 microM. BW755C, AA-861, nafazatrom, dipyridamole, and propyl gallate did protect and cardiac lipids against oxidative injury in a concentration-dependent manner with respective and antiperoxidant IC50 values (concentrations at which peroxidation was inhibited by 50%) of 0.22, 1.25, 3.0, 3.6 and 50 microM. Catechin and phenidone, known oxygenase inhibitors not yet evaluated as anti-ischemic agents, were also found to be antiperoxidants at low micromolar concentrations. Four cyclooxygenase inhibitors ineffective against myocardial infarction (aspirin, indomethacin, naproxen, and sulfinpyrazone) evidenced no antiperoxidant properties at concentrations up to 500 microM. The oxygenase inhibitor-antiperoxidants identified could neither quench superoxide radical nor inhibit xanthine oxidase. However, they were able to interrupt the propagation of an on-going peroxidation reaction. Their antiperoxidant profiles resembled those of known antioxidants, such as alpha-tocopherol, which inhibit peroxidation by intercepting lipid free-radical intermediates. These data raise the possibility that at least some oxygenase inhibitors could exert cardioprotective effects by directly influencing the sensitivity of myocardial-membrane phospholipid to peroxidative injury. Consequently, recognition of the antiperoxidant properties of these agents may aid dissection of their physiological and pharmacological actions.
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PMID:Influence of cardioprotective cyclooxygenase and lipoxygenase inhibitors on peroxidative injury to myocardial-membrane phospholipid. 255 48

During the last few years, the scientific field has focused its attention on the pathogenic role of free radicals in the process of ischemia-revascularization. It is a well-known fact that xanthine oxidase is an important source of tissular free radicals. Bearing this in mind, we designed an experimental protocol to analyse the effect of allopurinol (a xanthine oxidase inhibitor) in the survival of rats after the occlusion of the superior mesenteric artery during a period of 90 minutes and its action on the superoxide radical liberation. The concentration of oxipurinol and allopurinol in the ischemic area (intestine), liver and blood were measured. We concluded that the administration of allopurinol increased the survival rate, which is correlated to higher concentrations of allopurinol and oxipurinol in the inner part of the intestinal cells. A correlation between the survival rate and superoxide radicals was not found.
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PMID:[Effect of xanthine oxidase inhibitors on the prognosis of acute intestinal ischemia]. 256 72

Current dogma associates reperfusion injury with the introduction of reactive oxygen species (ROS) into the ischemic tissue. The sources of ROS under discussion are xanthine oxidase in the endothelium of small vessels and/or invaded polymorphonuclear leukocytes (PMN). The beneficial effects of both superoxide dismutase and catalase suggest an involvement of superoxide anions and hydrogen peroxide in this pathophysiological process, without describing the targets of their action. In our work we demonstrate that these two ROS effectively interact with two enzymes. Superoxide anions inhibit soluble guanylate cyclase. Its product, cGMP, is considered to antagonize platelet activation and to cause smooth muscle relaxation. Thus O2- can intensify platelet aggregability and small vessel occlusion. Similar effects are elicited by H2O2, which shifts the dose response curve of several agonists towards smaller concentrations by activating cyclooxygenase. This enzyme provides the substrate for thromboxane synthase which generates TxA2, the most potent physiologically occurring platelet aggregating and smooth muscle contacting agonist. These results lead us to the suggestion that the influence of the oxidative burst of PMN in the phenomenon of reperfusion injury should be reconsidered.
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PMID:Physiological targets of superoxide anion and hydrogen peroxide in reperfusion injury. 257 64

Incubation of a number of ferric ion chelates with H2O2 at pH 7.4 generated a reactive species able to produce chemical modifications of the bases in DNA that are very similar to those produced in DNA by the hypoxanthine/xanthine oxidase system (Aruoma, O.I., Halliwell, B., and Dizdaroglu, M. (1989) J. Biol. Chem. 264, 13024-13028). Products were identified and quantitated by the use of gas chromatography-mass spectrometry with selected-ion monitoring. Compared with other complexes used, ferric ion-nitrilotriacetic acid produced by far the largest amount of the base products. Typical hydroxyl radical scavengers and superoxide dismutase provided significant decreases in the yields of the products. On this basis, it is proposed that ferric ion complexes react with H2O2 to produce hydroxyl radical; this was also shown using the deoxyribose assay. Inhibition of product formation by superoxide dismutase suggests the involvement of superoxide radical in this reaction. It is likely that hydroxyl radical generated by reaction of the ferric ion-nitrilotriacetic acid complex with H2O2 contributes to the carcinogenicity and nephrotoxicity associated with this chelating agent.
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PMID:Damage to the bases in DNA induced by hydrogen peroxide and ferric ion chelates. 258 27

The mono-electronic reduction of oxygen in the hypoxanthine-xanthine oxidase system led to the formation of active species eliciting an evident and highly reproducible mutagenic response in strain TA104 of S. typhimurium. Similar effects were observed by generating oxy radicals either extracellularly or inside bacterial cells. Mutagenicity was selectively detected in TA104 and not in other Salmonella strains, which points out the importance of the hisG428 mutation and of the deletion excising the uvrB gene, as far as sensitivity to oxy radicals is concerned. The mutagenicity of the system was further enhanced in the presence of superoxide dismutase. Catalase did not affect the mutagenicity of hypoxanthine plus xanthine oxidase, whereas it inhibited the mutagenicity induced by the mixture of hypoxanthine with xanthine oxidase and superoxide dismutase. This demonstrates that not only hydrogen peroxide but also the superoxide radical anion is positive in this system. Glutathione and 2 synthetic thiols, i.e., N-acetylcysteine and alpha-mercaptopropionylglycine, besides decreasing the high spontaneous mutagenicity of TA104, efficiently prevented the mutagenicity of active oxygen species.
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PMID:Mutagenicity of active oxygen species in bacteria and its enzymatic or chemical inhibition. 267 96

Although oxygen has been known to be toxic for more than 200 years, the clinical importance of oxygen toxicity was not appreciated until an epidemic of retrolental fibroplasia occurred in the early 1950s. Oxygen at high partial pressures is toxic to the respiratory, cardiovascular, nervous, and gastrointestinal systems. Toxicity results from the formation of oxygen-free radicals. These arise within mitochondria as oxygen is reduced to water, as byproducts of prostaglandin and thromboxane synthesis, and by the xanthine oxidase catalyzed reduction of xanthine or hypoxanthine. They are also produced by activated macrophages as part of the immune response. Superoxide anion is the radical most commonly produced. It dismutes to hydrogen peroxide, which is able to diffuse through lipid membranes. Hydrogen peroxide reacts with transition metals to produce the highly reactive hydroxyl radical which can initiate chain reactions of lipid peroxidation leading to cell rupture. Oxygen radical scavengers such as superoxide dismutase and catalase protect the body against normal levels of oxygen-free radicals. Oxygen toxicity can result from either reperfusion of ischemic tissue or prolonged exposure to high concentrations of oxygen. Limiting hyperoxia to maintain arterial oxygen percent saturation (SaO2) greater than or equal to 90% is recommended.
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PMID:Oxygen toxicity: an introduction. 267 91

Three lipophilic, membrane-active "stabilizing agents," cepharanthine, chlorpromazine, and trifluoperazine, were found to protect myocardial membrane phospholipid from peroxidative injury. The compounds prevented, in a concentration-dependent manner, the cardiac phospholipid peroxidation which resulted from lipid exposure to superoxide-dependent, iron-promoted oxygen-radical chemistry of the type thought to be a causative factor in ischemic-reperfusion tissue damage. Chlorpromazine's antiperoxidant IC50 (i.e., concentration at which peroxidation was inhibited by 50%) was 180 microM; the antiperoxidant potencies of cepharanthine (IC50 = 90 microM) and trifluoperazine (IC 50 = 100 microM) were some two-fold greater. These agents, at effective antiperoxidant concentrations, did not inhibit the enzymatic superoxide source, xanthine oxidase, scavenge superoxide radical, or act like a chain-breaking antioxidant. The data raise a possibility that the these three membrane-active compounds, as lipophilic anesthetics, may exert antiperoxidant effects by inducing structural changes in the lipid-rich (membrane or liposome) target of free radical attack.
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PMID:Prevention of oxidative injury to cardiac phospholipid by membrane-active "stabilizing agents". 271 Oct 24

Ischemia-reperfusion injury has been associated with intracellular H2O2 and superoxide radical production from accumulated hypoxanthine (HX) and xanthine oxidase (XO). The effect of H2O2 and superoxide radical on mitochondrial Ca2+ efflux was characterized in isolated renal mitochondria using a HX-XO system. Mitochondria were suspended in buffered medium containing 200 microM HX. Extramitochondrial Ca2+ was monitored kinetically at 660-685 nm using the Ca2+ indicator arsenazo III. After preloading mitochondria with 18-25 nmol Ca2+/mg protein, addition of XO to the medium caused a rapid oxidation of mitochondrial NAD(P)H followed by Ca2+ release. Ca2+ efflux was attributed to mitochondrial metabolism of H2O2 because efflux could be prevented with catalase but not superoxide dismutase. The Ca2+ efflux rate (r = 0.995) and lag time to Ca2+ efflux (r = 0.987) both correlate well with the NAD(P)H oxidation rate. Exogenous ATP prevents Ca2+ efflux in a dose-dependent fashion (Km = 35 microM ATP) without affecting NAD(P)H oxidation; ATP plus oligomycin, however, had no effect. The protective effect of ATP on Ca2+ efflux was diminished by ruthenium red (RR). XO-induced Ca2+ efflux increased state 4 respiration 148% via a futile Ca2+ cycle involving the Ca2+ uniport. The increase in state 4 respiration could be reversed with RR (alpha less than 0.001) or ATP (alpha less than 0.01); ATP plus oligomycin, however, had no effect. The results are discussed in relation to the oxygen free radical theory of reperfusion injury.
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PMID:Potential role of mitochondrial calcium metabolism during reperfusion injury. 273 95

Superoxide anion (O2-) generated from xanthine oxidase/xanthine has been used to decrease the half life of endothelium derived relaxing factor (EDRF). However, by itself, xanthine oxidase causes endothelium dependent relaxation. This relaxation is unrelated to the oxidative property of the enzyme since it is not inhibited by allopurinol. In addition, the relaxation is not inhibited by the cyclooxygenase inhibitor, indomethacin, or the phospholipase A2 inhibitor, p-bromophenacyl bromide. On the other hand the relaxation is inhibited by the trypsin inhibitor (TI) from chicken egg white. A similar endothelium dependent relaxation elicited by pancreatin and trypsin is also inhibited by TI. Pancreatin used in the preparation of xanthine oxidase contains trypsin, chymotrypsin and carboxypeptidase. When compared to trypsin both chymotrypsin and carboxypeptidase elicit little relaxation. Thus the endothelium dependent relaxation elicited by xanthine oxidase is likely due to contamination with trypsin. Our results emphasize that when the superoxide generating system, xanthine oxidase/xanthine is used to study the effect of oxygen radicals on EDRF, it is advantageous to ensure that only purified preparations of xanthine oxidase are used.
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PMID:Xanthine oxidase and endothelium dependent relaxation. 282 Apr 11


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