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)

The effects of allopurinol pretreatment (1 mg/ml in the drinking water for 7 days at an estimated daily dose of 75 mg/kg) on biochemical and chemical changes occurring following left circumflex coronary artery ligation (40 min) and reperfusion (60 min) were examined in pentobarbital-anesthetized rabbits. During the ischemic phase, allopurinol pretreatment provided significant preservation of cellular ATP levels and of mitochondrial ATP generation as compared with untreated animals (P less than 0.05). During the reperfusion phase, allopurinol pretreatment significantly prevented the decrease in left ventricular pressure, sodium and calcium accumulation and decreases in sarcolemmal Na+,K+-stimulated and sarcoplasmic reticulum K+,Ca2+-stimulated ATPase activities as compared with untreated animals (P less than 0.05). In contrast, the decrease in mitochondrial (azide-sensitive) ATPase during ischemia and the partial recovery during reperfusion were unaffected by allopurinol pretreatment. Our results indicate that the myocardial protective effects of allopurinol may differ mechanistically in the ischemic and reperfusion phases of injury. The fact that rabbit hearts do not contain detectable xanthine oxidase activity would seem to preclude an obligatory role of this enzyme both in the generation of myocardial ischemic/reperfusion injury and in the protective actions of allopurinol.
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PMID:Effects of allopurinol on myocardial ischemic injury induced by coronary artery ligation and reperfusion. 303 15

In this lecture, evidence is presented to support the following hypothesis regarding the roles of xanthine oxidase-derived oxidants and granulocytes in ischemia-reperfusion-induced microvascular injury. During the ischemic period, ATP is catabolized to yield hypoxanthine. The hypoxic stress also triggers the conversion of NAD-reducing xanthine dehydrogenase to the oxygen radical-producing xanthine oxidase. During reperfusion, molecular oxygen is reintroduced into the tissue where it reacts with hypoxanthine and xanthine oxidase to produce a burst of superoxide anion and hydrogen peroxide. In the presence of iron, superoxide anion and hydrogen peroxide react via the Haber-Weiss reaction to form hydroxyl radicals. This highly reactive and cytotoxic radical then initiates lipid peroxidation of cell membrane components and the subsequent release of substances that attract, activate, and promote the adherence of granulocytes to microvascular endothelium. The adherent granulocytes then cause further endothelial cell injury via the release of superoxide and various proteases.
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PMID:Role of xanthine oxidase and granulocytes in ischemia-reperfusion injury. 305 26

The role of free radicals in the conversion of 1-aminocyclopropane-1-carboxylic acid (ACC) to ethylene by a membrane-bound enzyme from carnation petals was studied. The membrane preparation oxidized ACC more effectively than it oxidized cyclopropaneamine or 2-keto-4-methylthiobutyric acid (KMB). All these substrates were oxidized chemically by NaOCl to ethylene very effectively. Free radicals generated by the xanthine/xanthine oxidase system oxidized KMB far more effectively than it oxidized ACC; only 0.004% of the ACC included in the reaction mixture was oxidized in 1 h, compared with 0.9% of the KMB. Conversion of ACC to ethylene by the membrane-bound enzyme was inhibited by Co2+, ATP and EDTA, while the inhibition of the oxidation of KMB by the same inhibitors was much less pronounced. These results suggest that ACC, the natural immediate precursor of ethylene, is specifically oxidized by the membrane-bound enzyme rather than through a nonspecific oxidation by free radicals.
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PMID:Free radicals play little role in the conversion of 1-aminocyclopropane-1-carboxylic acid to ethylene in carnation membrane fraction. 314 43

Age-dependent differences in the effects of ischemia and reperfusion on ATP breakdown were studied in perfused adult and newborn (10 days old) rat hearts. No-flow ischemia (15 min at 37, 30, or 23 degrees C) was applied and reperfusion (20 min at 37 degrees C) was studied after ischemia at 23 or 37 degrees C. Hypothermia during ischemia protected both age groups to a similar degree against ATP decline, which was linear with temperature. Reperfusion after normothermic ischemia resulted in higher ATP levels in newborn hearts with less release of ATP catabolites (purines). We found no age-related differences in lactate release but large differences in purine release. During normoxia, adult hearts released mainly urate (80% of total) and inosine (7%), but newborns released hypoxanthine (64%) and inosine (15%). Early during reperfusion adult hearts released inosine (58%) and adenosine (18%), but newborns released inosine (53%) and hypoxanthine (38%). These data suggested a lower activity of the potentially deleterious enzyme xanthine oxidoreductase in newborn hearts, which was confirmed by enzymatic assay. ATP-catabolite release during reperfusion was less in newborn than adult hearts, and this coincided with lower xanthine oxidase activity.
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PMID:Different ATP-catabolism in reperfused adult and newborn rat hearts. 316 69

Xanthine oxidase increases the rate of actin polymerization. This occurs at oxidase concentrations as low as 40 nM provided the concentration of the polymerizing agent is low (0.5 mM MgCl2). In the presence of 0.1 M KCl plus 1 mM MgCl2 as the polymerizing agents, xanthine oxidase does not affect the rate of the polymerization but increases significantly the rate of the conversion of F(ATP)actin into F(ADP.Pi)actin and probably also the rate of the orthophosphate release.
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PMID:On the interaction between xanthine oxidase and actin. 319 Jul 22

When incubated with mitochondria in an air atmosphere, menadione and doxorubicin (which redox cycle with the respiratory chain to produce oxygen radicals), as well as xanthine oxidase plus xanthine (which generate superoxide and H2O2), stimulated the degradation of newly-synthesized [( 3H]leucine-labelled) mitochondrial polypeptides. No stimulation was observed in an N2 atmosphere, ATP was not required, and xanthine oxidase was not effective without xanthine. Various forms of oxidative stress induced varying degrees of protein cross-linking, protein fragmentation and proteolysis, as judged by gel electrophoresis and amino acid analysis. To learn more about the proteolytic enzymes involved in degradation, we undertook studies with purified protein substrates which had been exposed to oxidative stress (OH or H2O2) in vitro. Despite mitochondrial contamination with acid proteases of lysosomal (and other) origin, pH profiles revealed distinct proteolytic activities at both pH 4 and pH 8. The pH 8 activity preferentially degraded the oxidatively-denatured forms of haemoglobin, albumin and superoxide dismutase; was unaffected by digitonin; and exhibited a several-fold increase in activity upon mitochondrial disruption (highest activity being found in the matrix). In contrast, the pH 4 activity was dramatically decreased by digitonin treatment (to reduce lysosomal contamination); was unaffected by mitochondrial disruption; and showed no preference for oxidatively-denatured proteins. The pH 8 activity was not stimulated by ATP, but was inhibited by EDTA, haemin and phenylmethylsulphonyl fluoride. In contrast, the contaminating pH 4 activity was only inhibited by pepstatin and leupeptin. Thus, our experiments reveal a distinct mitochondrial (matrix) proteolytic pathway which can preferentially degrade oxidatively-denatured proteins.
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PMID:Mitochondria contain a proteolytic system which can recognize and degrade oxidatively-denatured proteins. 319 85

Based on work from our laboratory and studies by others, we propose the following hypothesis to explain the interaction among xanthine oxidase, PMNs, and tissue injury in the postischemic small intestine (Figure 2). During the ischemic period, ATP is catabolized to yield hypoxanthine. The hypoxic stress also triggers the conversion of NAD-reducing xanthine dehydrogenase to the oxygen radical-producing xanthine oxidase via a protease. When the intestine is reperfused, molecular oxygen is reintroduced into the tissue where it reacts with hypoxanthine and xanthine oxidase to produce a burst of superoxide anion and hydrogen peroxide. In the presence of ferric iron, superoxide anion and hydrogen peroxide react via the Haber-Weiss reaction to form hydroxyl radicals. This highly reactive and cytoxic free radical then initiates lipid peroxidation of cell membrane components and the subsequent release of substances that activate, attract, and promote the adherence of PMN to microvascular endothelium. The adherent PMN then causes further endothelial cell injury via the release of superoxide and various proteases.
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PMID:Mechanisms of oxidant-mediated microvascular injury following reperfusion of the ischemic intestine. 325 May 38

Compelling evidence has been accumulated which indicates that myocardial tissue damage occurring during reperfusion after an ischaemic period may partly be due to the formation of oxygen free radicals and subsequent peroxidative processes. It has been well established that the actual toxicity of free radicals is dependent on the presence of free iron in the heart tissue. Based upon the hypothesis of McCord et al., proposing xanthine oxidase mediated formation of superoxide (O2-.) during the conversion of ATP-breakdown product(s) (hypo)xanthine to urate, we studied whether xanthine oxidase was able to mobilize free iron from the intra- and extracellular iron-binding proteins, ferritin and transferrin. It appeared that there was an O2-.-dependent and O2-.-independent mechanism by which xanthine oxidase could mobilize iron from ferritin while no iron mobilization from transferrin was detectable. The capacity of xanthine oxidase to mobilize iron from ferritin by an O2-.-independent mechanism implies that already during the anoxic/ischaemic period, iron may become available in the tissue which, upon the re-entrance of O2, catalyzes the formation of the very reactive OH radicals. The interaction between endothelial cells and cardiocytes in free radical homeostasis is discussed with the emphasis on the tissue localization of xanthine oxidase. The latter is located in endothelial cells implying an interaction between xanthine oxidase-induced endothelial cells initiated lipid peroxidation and the actual overall myocardial tissue damage.
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PMID:Lipid peroxidation and myocardial ischaemic damage: cause or consequence? 331 Oct 8

We have investigated the effect of oxidants on ligand recognition and internalization by the macrophage mannose receptor. Rat bone marrow macrophages were treated with increasing concentrations of H2O2 for 30 min at 37 degrees C. Fifty percent inhibition of ligand uptake was observed at 250 microM, with only 10% of control uptake remaining following exposure to 1 mM H2O2 for 30 min. Electron micrographic analysis of macrophages following H2O2 treatment showed no morphological alterations compared to untreated cells. Ligand uptake was also inhibited by the following H2O2 generating systems: menadione, xanthine/xanthine oxidase, glucose/glucose oxidase, and phorbol 12-myristate 13-acetate-stimulated polymorphonuclear leukocytes. Inhibition could be blocked by catalase plus or minus superoxide dismutase. Treatment of macrophages at 4 degrees C with H2O2 had no effect on ligand binding, whereas treatment with H2O2 at 37 degrees C reduced binding to 15% of control levels and decreased the number of surface receptors to one-third of control cells. H2O2 treatment inhibited ligand degradation by macrophages, but did not prevent ligand movement from the surface to the interior of the cell. In addition, ligand delivery to lysosomes was blocked by oxidant treatment. These results suggest that treatment of macrophages with reagent H2O2 or H2O2-generating systems inhibits the normal ligand delivery and receptor recycling process involving the mannose receptor. Potential mechanisms might include receptor oxidation, alterations in ATP levels, or membrane lipid peroxidation.
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PMID:Oxidant-mediated inhibition of ligand uptake by the macrophage mannose receptor. 333 43

The evidence is convincing that oxidants and agents which induce a cellular pro-oxidant state can act as carcinogens, in particular as promoters and progressors. Importantly, infiltrated phagocytes represent a source of oxidants in inflamed tissues. We have studied the mechanism of the promotional action of active oxygen (AO) in mouse epidermal cells JB6 by comparing the non-promotable clone 30 to the promotable clone 41. In order to mimick AO released by phagocytes we used xanthine/xanthine oxidase as a source of extracellular superoxide and hydrogen peroxide. We found that AO stimulated the growth only of promotable clone 41 after an initial period of moderate inhibition while it was strongly cytostatic for non-promotable clone 30. Reasons for the higher cytostatic effect of AO on the non-promotable clone 30 were discovered when we measured DNA strand breakage and poly ADP-ribosylation of chromosomal proteins. At equal doses AO induced 4-5 times more DNA breaks in clone 30 in reactions which required iron--and probably also calcium--ions. The higher amount of DNA breakage in clone 30 was reflected in a higher extent of poly ADP-ribosylation. Excessive DNA breakage and poly ADP-ribosylation which causes the depletion of NAD and ATP may be responsible for the strong cytostatic effect of AO in clone 30. We conclude that differential resistance to the cytostatic/cytotoxic effect of AO in part determines the promotability of mouse epidermal cells JB6.
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PMID:Active oxygen induced DNA strand breakage and poly ADP-ribosylation in promotable and non-promotable JB6 mouse epidermal cells. 333 7


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