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)

To investigate renal tubular epithelial cell injury mediated by reactive oxygen molecules and to explore the relative susceptibility of epithelial cells and endothelial cells to oxidant injury, we determined cell injury in human umbilical vein endothelial cells and in four renal tubular epithelial cell lines including LLC-PK1, MDCK, OK and normal human kidney cortical epithelial cells (NHK-C). Cells were exposed to reactive oxygen molecules including superoxide anion, hydrogen peroxide and hydroxyl radical generated by xanthine oxidase and hypoxanthine. We determined early sublethal injury with efflux of 3H-adenine metabolites and a decline in ATP levels, while late lytic injury and cell detachment were determined by release of 51chromium. When the cells were exposed to 25, 50, and 100 mU/ml xanthine oxidase with 5.0 mM hypoxanthine, ATP levels were significantly lower (P less than 0.001) in LLC-PK1, NHK-C and OK cells compared to MDCK cells while ATP levels were significantly lower (P less than 0.01) in endothelial cells compared to all tubular cell lines. A similar pattern of injury was seen with efflux of 3H-adenine metabolites. When the cells were exposed to 50 mU/ml xanthine oxidase with 5.0 mM hypoxanthine for five hours, total 51chromium release was significantly (P less than 0.001) greater in LLC-PK1, NHK-C and OK cells compared to MDCK cells, while total 51chromium release was significantly (P less than 0.001) greater in endothelial cells compared to all tubular cells. However, lytic injury was the greatest in LLC-PK1 cells and NHK-C cells while cell detachment was the greatest in endothelial cells. MDCK cells were remarkably resistant to oxidant-mediated cell detachment and cell lysis. In addition, we determined ATP levels, 3H-adenine release and 51chromium release in LLC-PK1, NHK-C and endothelial cells in the presence of superoxide dismutase to dismute superoxide anion, catalase to metabolize hydrogen peroxide, DMPO to trap hydroxyl radical and DMTU to scavenge hydrogen peroxide and hydroxyl radical. We found that catalase and DMTU (scavengers of hydrogen peroxide) provided significant protection from ATP depletion, prevented efflux of 3H-adenine metabolites and cell detachment while DMPO (scavenger of hydroxyl radical) prevented lytic injury. In addition, we found that the membrane-permeable iron chelator, phenanthroline, and preincubation with deferoxamine prevented cell detachment and cell lysis, confirming the role of hydroxyl radical in cell injury.(ABSTRACT TRUNCATED AT 400 WORDS)
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PMID:Reactive oxygen molecule-mediated injury in endothelial and renal tubular epithelial cells in vitro. 217 55

Red blood cells (RBC) are thought to be well protected against oxidative stress by the antioxidant, cu-pro-zinc enzyme superoxide dismutase (CuZn SOD) which dismutates O2- to H2O2. CuZn SOD, however, is irreversibly inactivated by its product H2O2. Exposure of intact RBC to H2O2 resulted in the inactivation (up to 50%) of endogenous SOD in a concentration-dependent manner. When RBC were exposed to O2- and H2O2, generated by xanthine + xanthine oxidase, an even greater loss of SOD activity (approximately 75%) was observed. Intracellular proteolysis was markedly increased by exposure to these same oxidants; up to a 12-fold increase with H2O2 and a 50-fold increase with xanthine oxidase plus xanthine. When purified SOD was treated with H2O2, inactivation of the enzyme also occurred in a concentration-dependent manner. Accompanying the loss of SOD activity, the binding of the copper ligand to the active site of the enzyme diminished with H2O2 exposure, as evidenced by an increase in accessible copper. Significant direct fragmentation of SOD was evident only under conditions of prolonged exposure (20 h) to relatively high concentrations of H2O2. Gel electrophoresis studies indicated that under most experimental conditions (i.e. 1-h incubation) H2O2, O2-, and H2O2 + O2- treated SOD experienced charge changes and partial denaturation, rather than fragmentation. The proteolytic susceptibility of H2O2-modified SOD, during subsequent incubation with (rabbit, bovine or human) red cell extracts also increased as a function of pretreatment with H2O2. Both enzyme inactivation and altered copper binding appeared to precede the increase in proteolytic susceptibility (whether measured as an effect of H2O2 concentration or as a function of the duration of H2O2 exposure). These results suggest that SOD inactivation and modification of copper binding are prerequisites for increased protein degradation. Proteolytic susceptibility was further enhanced by H2O2 exposure under alkaline conditions, suggesting that the hydroperoxide anion is the damaging species rather than H2O2 itself. In RBC extracts, the proteolysis of H2O2-modified SOD was inhibited by sulfhydryl reagents, serine reagents, transition metal chelators, and ATP; suggesting the existence of an ATP-independent proteolytic pathway of sulfhydryl, serine, and metalloproteases, and peptidases. The proteolytic activity was conserved in a "Fraction II" of both human and rabbit RBC, and was purified from rabbit reticulocytes and erythrocytes to a 670-kDa proteinase complex, for which we have suggested the trivial name macroxyproteinase. In erythrocytes macroxyproteinase may prevent the accumulation of H2O2-modified SOD.(ABSTRACT TRUNCATED AT 400 WORDS)
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PMID:Superoxide dismutase undergoes proteolysis and fragmentation following oxidative modification and inactivation. 219 28

We made use of the xanthine oxidase inhibitor allopurinol and examined changes related to myocardial injury of the rat heart during hypoxia-re-oxygenation. The rat heart was perfused using the Langendorff method. With low-oxygen perfusion for 60 min in a solution saturated with mixed gases of 95% N2 + 5%O2, contractile tension did not develop and tension development was not restored upon re-oxygenation. During hypoxia, the resting tension increased (4.1 g) in the absence of allopurinol. In the allopurinol-administered group (100 microM), contractile tension did not develop during hypoxia; however, the development of tension was restored (18%) upon re-oxygenation. The elevation of resting tension was less (3.2 g) during hypoxia. All events related to the myocardial injury (inhibition of Na+, K(+)-ATPase activities, generation of malondialdehyde, extracellular leakage of creatine kinase) after low-oxygen perfusion for 60 min and re-oxygenating perfusion for 30 min were mild in the allopurinol treated group, compared with findings in the non-administered group. Tissue ATP at 10 min after low-oxygen perfusion was of a significantly high value in the allopurinol treated group (13.2 mumols/g dry weight), compared with findings in the group not given the drug (8.4 mumol/g dry weight). Sixty minutes after low-oxygen perfusion, tissue ATP in the allopurinol group also remained high, compared with the group not given the drug. Although the intensity of the epicardial NADH fluorescence indicated that the extent of inhibition of aerobic energy production during 10 min of low-oxygen perfusion was the same for both groups, lactate was produced in large quantities in the allopurinol treated group, hence energy generation advanced with glycolysis. These observations suggest that allopurinol prevents myocardial injury as a result of hypoxia-re-oxygenation. In the low-oxygen perfusion period, generation of energy is maintained and improved with glycolysis and there is a reduction in the generation of free radicals and an inhibition in lipid peroxidation.
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PMID:Does allopurinol prevent myocardial injury as a result of hypoxia-re-oxygenation in rats? 220 93

The biochemical mechanisms behind skeletal muscle soreness and damage with muscular overuse have remained unclear. Recently, however, a growing amount of evidence indicates that free radicals play an important role as mediators of skeletal muscle damage and inflammation. During exercise, two of the potentially harmful free radical generating sources are semiquinone in the mitochondria and xanthine oxidase in the capillary endothelial cells. During high intensity exercise the flow of oxygen through the skeletal muscle cells is greatly increased at the same time as the rate of ATP utilisation exceeds the rate of ATP generation. The metabolic stress in the cells causes several biochemical changes to occur, resulting in a markedly enhanced rate of production of oxygen free radicals from semiquinone and xanthine oxidase. During normal conditions free radicals are generated at a low rate and subsequently taken care of by the well developed scavenger and antioxidant systems. However, a greatly increased rate of free radical production may exceed the capacity of the cellular defence system. Consequently, a substantial attack of free radicals on the cell membranes may lead to a loss of cell viability and to cell necrosis and could initiate the skeletal muscle damage and inflammation caused by exhaustive exercise.
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PMID:Biochemical mechanisms for oxygen free radical formation during exercise. 224 25

Irreversible transformation of xanthine dehydrogenase (XDH) to xanthine oxidase (XO) during ischemia was determined measuring XDH and total enzyme activity in kidneys before and after 60 min of clamp of the renal pedicle. Tissue levels of adenine nucleotides, xanthine and hypoxanthine were used as indicators of ischemia. After 60 min of clamping, ATP levels decreased by 72% with respect to controls whereas xanthine and hypoxanthine progressively reached tissue concentrations of 732 +/- 49 and 979 +/- 15 nmol.g tissue-1, respectively. Both total and XDH activities in ischemic kidneys (30 +/- 15 and 19 +/- 1 nmol.min-1.g tissue-1) were significantly lower than in controls when expressed on a tissue weight basis. The fraction of enzyme in the XDH form was however unchanged indicating that the reduction of the nucleotide pool is not accompanied by induction of the type-O activity of xanthine oxidase.
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PMID:Lack of conversion of xanthine dehydrogenase to xanthine oxidase during warm renal ischemia. 225 87

Acetaminophen (500 mg/kg i.p.) induced hepatotoxicity in fasted ICR mice in vivo. Acetaminophen also caused a long-lasting 50% reduction of the hepatic ATP content, an irreversible loss of hepatic xanthine dehydrogenase activity and a transient increase of the xanthine oxidase activity. All effects occurred before parenchymal cell damage, i.e., the release of cellular enzymes. The hepatic content of GSH and GSSG was initially depleted by acetaminophen without affecting the GSSG:GSH ratio (1:200), however, during the recovery phase of the hepatic GSH levels the GSSG content increased faster than GSH, resulting in a GSSG:GSH ratio of 1:18 24 h after acetaminophen administration. The mitochondrial GSSG content increased from 2% in controls to greater than 20% in acetaminophen-treated mice. The extremely elevated tissue GSSG levels were accompanied by a 4-fold increase of the plasma GSSG concentrations but not by an enhanced biliary efflux, although hepatic GSSG formation and biliary excretion were not affected by acetaminophen. Allopurinol protected dose-dependently against acetaminophen-induced cell injury, the loss of ATP and the increase of the GSSG content in the total liver and in the mitochondrial compartment without inhibiting reactive metabolite formation. High, protective as well as low, nonprotective doses of allopurinol almost completely inhibited hepatic xanthine oxidase and dehydrogenase activity, but only high doses prevented the increase of the mitochondrial GSSG content. The data indicate a long-lasting, primarily intracellular oxidant stress during the progression phase of acetaminophen-induced cell necrosis. The protective effect of allopurinol is unlikely to involve the inhibition of reactive oxygen formation by xanthine oxidase but could be the result of its antioxidant property.
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PMID:Glutathione disulfide formation and oxidant stress during acetaminophen-induced hepatotoxicity in mice in vivo: the protective effect of allopurinol. 226 12

Acetylcholine and ATP are costored and coreleased during synaptic activity at the electric organ of Torpedo. It has been suggested that released ATP is converted to adenosine at the synaptic cleft, and in turn this nucleoside would depress the evoked release of acetylcholine. In the present communication we have used a chemiluminescent reaction that let us to monitor continuously the presence of adenosine in this preparation. The chemiluminescent reaction is based on the conversion of adenosine into uric acid and H2O2 by adenosine deaminase, nucleoside phosphorylase, and xanthine oxidase enzymes. The hydrogen peroxide has been detected by peroxidase-luminol mixture. The reaction has a sensitivity on the picomol range and discerned between Adenosine, AMP, ADP, and ATP. We have developed this technique in the hope of understanding whether adenosine is released during synaptic activity or it comes from the released ATP. We have studied the release or formation of adenosine in fragments of the electric organ and in isolated cholinergic nerve terminals obtained from it. In both conditions we have followed the effect of potassium stimulation upon the detection of adenosine. Potassium stimulation increased the extracellular adenosine either in slices or the synaptosomal fraction of Torpedo electric organ. The presence of alpha, beta-methylene ADP, an inhibitor of 5'-nucleotidase, inhibits the detection of adenosine, suggesting that extracellular adenosine is a consequence of ectocellular dephosphorylation of released ATP.
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PMID:The release of adenosine at the electric organ of Torpedo. A study using a continuous chemiluminescent method. 232 27

An in vivo rat hindlimb tourniquet ischemia model was used to study the purine nucleotide metabolism in response to 2, 4, and 6 h of ischemia and to the same ischemia periods followed by 1 h of reperfusion. All purine intermediates from ATP to uric acid were determined in skeletal muscle with a high-performance liquid chromatography (HPLC) system. The major metabolic event during ischemia is to temporarily save the nucleotide pool as inosine-5'-monophosphate (IMP. On restitution of the circulation as the energy state recovers, the IMP is converted back to AMP via the purine nucleotide cycle. Six hours of ischemia is associated with irreversible damage and no recovery fo the adenine nucleotides on reperfusion. Fast-twitch muscles appear to be more susceptible than slow-twitch muscles in response to ischemia and reperfusion. A severalfold increase of intracellular hypoxanthine occurred during ischemia, whereas uric acid formation is observed only after reperfusion. These findings are discussed in relation to the proposed role of xanthine oxidase, as an enzyme generating tissue-injurious oxygen free radicals.
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PMID:Purine metabolism after in vivo ischemia and reperfusion in rat skeletal muscle. 236 Jun 63

Hypoxanthine is the final product of the catabolism of ATP in the stored red cell. Upon transfusion, this purine may be uptaken by the endothelial cell and oxidized in a post-ischemic or post-anoxic environment with production of oxygen-derived free radicals. We have tested this hypothesis with a isolated perfused rat heart model monitoring the recovery of the heart function from 20 min anoxia in the presence of 0.1 mM hypoxanthine or xanthine. Addition of 0.1 mM guanine minimized the fraction of hypoxanthine to be salvaged. The presence of hypoxanthine in the vascular space impaired the recovery of the end-diastolic pressure, left ventricular developed pressure, contraction rate, and coronary perfusion pressure. We conclude that intravascular hypoxanthine is oxidized by the endothelial cell xanthine oxidase contributing to the post-anoxic reoxygenation injury. Since the injury led by equimolar xanthine was nearly half of that observed for hypoxanthine, this injury appears to be correlated to the stoichiometry of the oxygen-derived free radical generating reaction.
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PMID:Impairment of the post-anoxic recovery of isolated rat hearts by intravascular hypoxanthine and xanthine. 236 53

To investigate mechanisms of ATP depletion in human umbilical vein endothelial cells after oxidant injury, we studied the relationship between DNA damage, activation of the DNA-repairing enzyme poly ADP-ribose polymerase, NAD depletion, and ATP depletion. We found that oxidant stress generated with hypoxanthine-xanthine oxidase and glucose-glucose oxidase resulted in profound DNA damage. When endothelial cells were exposed to 25 and 50 mU/ml xanthine oxidase for 60 min, the percentage of double-stranded DNA was significantly reduced (p less than 0.05) to 15.2 +/- 1.2 and 4.6 +/- 0.5%, respectively, compared to 75.7 +/- 3.9% for control cells. When endothelial cells were exposed to 25 and 50 mU/ml glucose oxidase for 60 min, the percentage of double-stranded DNA was significantly (p less than 0.05) reduced to 35.0 +/- 1.5% and 9.9 +/- 7.7%, respectively, compared to 73.2 +/- 2.4% for control cells. ATP and NAD levels declined simultaneously with DNA damage. Because activation of the DNA-repairing enzyme poly ADP-ribose polymerase can consume NAD sufficient to interfere with ATP synthesis, we studied NAD and ATP levels after oxidant injury when ADP-ribose polymerase was inhibited with 3-aminobenzamide and nicotinamide. When poly ADP-ribose polymerase was inhibited, NAD levels remained normal, but ATP depletion was not prevented. We conclude that oxidant injury to human umbilical vein endothelial cells results in profound DNA damage and NAD and ATP depletion. NAD depletion results from activation of poly ADP-ribose polymerase, but this phenomenon is not the mechanism of ATP depletion in human umbilical vein endothelial cells.
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PMID:Mechanisms of endothelial cell ATP depletion after oxidant injury. 252 33


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