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)

Isolated perfused livers from fasted, but not from fed rats showed hepatotoxic responses when subjected to 30 min of hypoxia followed by 60 min of reoxygenation. Toxicity was evident by a release of glutamate-pyruvate-transaminase, lactate dehydrogenase and glutathione into the perfusate, by a depletion of hepatic glutathione and by an accumulation of calcium in the liver. This indicates, that the liver is resistant to hypoxic injury as long as glycogen is present to maintain anaerobic ATP-synthesis. This is substantiated by the fact that addition of fructose--but not glucose--to the medium resulted in a protection of the liver against hypoxic injury concomitant with its degradation to lactate + pyruvate. Superoxide dismutase, catalase, desferrioxamine and allopurinol prevented hypoxic liver injury suggesting a substantial role of reactive oxygen species formed via the xanthine oxidase reaction in mediating hypoxic liver injury.
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PMID:The involvement of reactive oxygen species in hypoxic injury to rat liver. 336 21

Myocardial ischemia initiates a series of cellular reactions which unless checked will culminate in cell death and tissue necrosis. Although reperfusion provides a means of preventing cell death it is not without hazard. In cases of mild ischemia, where tissue injury is in its reversible phase, reperfusion may precipitate potentially lethal ventricular arrhythmias and in cases of severe injury it may actually accelerate the process of cell death leading to hemorrhage and other forms of severe injury. The identity of mediators of cellular injury, and particularly the critical transition from reversible to irreversible injury, remains controversial. Whereas for a number of years ATP depletion, calcium overload and catecholamines have been considered as key factors in tissue injury, attention has recently been directed towards oxygen-derived free radicals (e.g. superoxide and the hydroxyl radical). In this article we discuss sources of free radicals in the mammalian heart (xanthine oxidase, mitochondria, leucocytes, and catecholamines) and present arguments based on quantitative and temporal considerations that the xanthine oxidase-mediated degradation of hypoxanthine is the most important source of free radicals and as such is the most appropriate target for therapeutic intervention. To support our arguments we present data from two species, the dog and the rat, in which we have shown how allopurinol, the specific inhibitor of xanthine oxidase, can afford a reduction of infarct size in the dog and can dramatically reduce the incidence of potentially lethal reperfusion-induced arrhythmias in the rat. Arising from these and other studies is the proposition that anti-free radical interventions (particularly those directed towards xanthine oxidase inhibition) may provide an important new therapeutic principle in the management of ischemia and reperfusion.
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PMID:Xanthine oxidase: a critical mediator of myocardial injury during ischemia and reperfusion? 352 23

The hepatocarcinogen acetamide, in single doses of 100 and 400 mg/kg b.wt., was shown to act as an initiator in a dose-dependent fashion in rat liver using the Solt-Farber method. Acetamide and its putative metabolite N-hydroxy-acetamide did not cause liver necrosis in single dose experiments. Acetamide showed no evidence for genotoxicity in tests for mutations in Salmonella typhimurium, for DNA damage in rat hepatoma cells or for DNA repair in isolated rat hepatocytes. In contrast, N-hydroxy-acetamide displayed genotoxic activity in all 3 test systems. Neither acetamide nor N-hydroxy-acetamide induced transformation of primary Syrian hamster embryo cells or gave evidence of inhibition of metabolic cooperation in V79 cells. Radiolabelled acetamide and N-hydroxy-acetamide were not bound covalently to proteins in the presence of various metabolic activation systems (microsomes plus NADPH or xanthine/xanthine oxidase, cytosol or cytosol plus acetyl CoA or proline plus ATP). N-Hydroxy-acetamide was cytotoxic to monolayers of isolated hepatocytes at concentrations above 2.5 mM. This cytotoxicity was increased after diethyl maleate treatment, but N-hydroxy-acetamide did not deplete cellular glutathione. A HPLC system was developed for the separation and quantification of acetamide, N-hydroxy-acetamide and acetic acid. No significant excretion of N-hydroxy-acetamide or acetic acid in the urine could be demonstrated after treatment of rats with 100 or 1,000 mg/kg b.wt. of acetamide. The underlying mechanism for the observed initiating effect of acetamide is obscure.
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PMID:Studies on the mechanism of acetamide hepatocarcinogenicity. 355 Jul 69

We have suggested that red blood cell proteolytic systems can degrade oxidatively damaged proteins, and that both damage and degradation are independent of lipid peroxidation (Davies, K. J. A., and Goldberg, A. L. (1987) J. Biol. Chem. 262, 8220-8226. These ideas have now been tested in cell-free extracts of rabbit erythrocytes and reticulocytes. Exposure to oxygen radicals or H2O2 increases the degradation of endogenous proteins in cell-free extracts, as in intact cells. Various radical-generating systems (acetaldehyde or xanthine + xanthine oxidase, ascorbic acid + iron, H2O2 + iron) and H2O2 alone enhanced the rates of proteolysis severalfold. Since these extracts were free of membrane lipids, protein damage and degradation must be independent of lipid peroxidation. An antioxidant buffer consisting of HEPES, glycerol, and dithiothreitol inhibited the increased proteolysis by 60-100%. Mannitol caused a 50-80% reduction in proteolysis suggesting that the hydroxyl radical (.OH), or a species with similar reactivity, may be the initiator of protein damage. When casein or bovine serum albumin were exposed to .OH (generated by H2O2 + Fe2+, or COCo radiation) these proteins were degraded up to 50 times faster than untreated proteins during subsequent incubations with red cell extracts. Mannitol inhibited this increase in proteolysis only if present during .OH exposure; mannitol did not affect the degradative system. Although ATP increased the degradation of untreated proteins 4- to 6-fold in reticulocyte extracts, it had little or no effect on the degradation of proteins exposed to .OH. ATP also did not stimulate hydrolysis of .OH-treated proteins in erythrocyte extracts. Leupeptin did not affect the degradative processes in either extract; thus lysosomal or Ca2+-activated thiol proteases were not involved. We propose that red cells contain a soluble, ATP-independent proteolytic pathway which may protect against the accumulation of proteins damaged by .OH or other active oxygen species.
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PMID:Proteins damaged by oxygen radicals are rapidly degraded in extracts of red blood cells. 359 73

Equilibrium dialysis studies on competitive binding of 59FeCl3 to xanthine oxidase and citrate or ATP have been carried out. Iron binding to the enzyme was observed in the presence of 0.1 mM of either chelator, suggesting that xanthine oxidase is likely to have iron bound in many in vitro experimental systems and raising the possibility that it may be able to compete for intracellular chelatable iron. One high-affinity-binding site per monomer was found, with an affinity constant of 5 X 10(12) M-1. The significance of this iron as a Fenton reaction catalyst is discussed.
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PMID:High-affinity iron binding by xanthine oxidase. 359 68

Using isolated hemoglobin-free perfused rat livers we investigated the hepatotoxic effects of hypoxia, ethanol or the combination of both. Hypoxia only (90 min) led to a weak toxicity as evidenced by the efflux of the enzymes glutamate-pyruvate-transaminase (GPT) and sorbitol dehydrogenase (SDH). This toxic effect was slightly higher in livers treated with ethanol (3 g/l) under normoxic conditions. Ethanol added under hypoxic conditions, however, showed a strong hepatotoxic effect. Under hypoxic conditions, lactate + pyruvate production was increased fivefold over control, indicating that glycolysis was more effectively undergone as main source of energy. Addition of ethanol suppressed this effect, indicating that ethanol inhibited glycolysis. These results indicate that ethanol potentiates hypoxic liver damage by inhibiting the main metabolic pathway yielding ATP under low oxygen tension resulting in a severe energy deficit. Allopurinol (100 mg/l) inhibited the toxic effects seen with ethanol + hypoxia. Also, the inhibitory action of ethanol on glycolysis was antagonized. Our results are consistent with the following model: hypoxia converts NAD-dependent xanthine dehydrogenase (XD) into the oxygen-dependent xanthine oxidase (XO). Due to hypoxia and ethanol, purine metabolites and acetaldehyde accumulate and are metabolized via XO. This process leads to the production of oxygen radicals which most probably mediate both the inhibition of glycolysis and the direct toxic effects towards liver cells.
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PMID:Enhancement of hypoxic liver damage by ethanol. Involvement of xanthine oxidase and the role of glycolysis. 363 22

Little is known about postnatal changes in myocardial purine metabolism. We therefore studied how ATP catabolism was affected by hypothermia and ischaemia in neonatal and adult hearts. Hypothermia during ischaemia protected isolated adult and newborn hearts against ATP decline. Reperfusion after normothermic ischaemia resulted in higher ATP levels in newborn hearts with less release of ATP-catabolites. During normoxia adult hearts released mainly urate (80% of total purine release), while newborns released mainly hypoxanthine (64%). During early reperfusion adult and newborn hearts released mainly inosine (50-60%). The very low xanthine oxidase activity in the neonatal heart could be an important factor in the observed ATP preservation during reperfusion.
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PMID:Developmental differences in myocardial ATP metabolism. 366 14

We applied a sensitive, precise liquid-chromatographic method of analysis for inosine, hypoxanthine, and xanthine to the study of fructose metabolism in humans and in rats. In the rat, intravenous loading with fructose induced, within minutes, substantial increases in the concentrations of inosine, hypoxanthine, and xanthine in plasma and urine. In plasma, these concentrations peaked after 5 min, then practically disappeared within 10 min. As expected, the fructose-induced increase in hypoxanthine was greatly amplified by pretreating the rats with allopurinol, an inhibitor of xanthine oxidase. In a healthy human subject, intravenous administration of fructose also induced prompt, substantial, and rapidly reversing increases in the concentrations of these metabolites of adenine nucleotides in plasma. The finding that fructose induced almost-immediate increases in the plasma concentrations of inosine, hypoxanthine, and xanthine is consistent with previous studies in rats, in which parenteral administration of fructose induced almost-immediate decreases of total adenine nucleotides (ATP + ADP + AMP) in the liver, and increased concentrations of uric acid and allantoin in the plasma.
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PMID:Liquid-chromatographic measurements of inosine, hypoxanthine, and xanthine in studies of fructose-induced degradation of adenine nucleotides in humans and rats. 369 69

Human red blood cells (RBC) were exposed to oxygen-based free-radicals, and other activated oxygen species generated during incubation with xanthine plus xanthine oxidase (X+XO). Oxygen-radical exposure induced up to 30 fold increases in human RBC protein degradation, compared to 12 fold increases in rabbit RBC protein degradation. Protein degradation increased as a function of X+XO, but demonstrated saturation kinetics at higher XO concentrations. The presence or absence of an energy substrate (glucose) had no effect on protein degradation, indicating the possible role of ATP-independent proteinolytic systems. It is proposed that human RBC proteins can be oxidatively damaged by certain free-radicals, and that the oxidized proteins are specifically recognized and degraded by intracellular proteinolytic systems.
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PMID:Free radicals and protein degradation in human red blood cells. 384 May 96

Cardiac ischemia is characterized by rapid deterioration of cardiac function, which has been linked to the fall in intracellular pH, increased levels of inorganic phosphate and reduction in free energy change of ATP-hydrolysis. Biochemical events responsible for irreversible myocardial injury involve various mechanisms which change the properties of the cardiac cell membrane (disorders in lipid metabolism, free radical formation). Recent evidence suggests that in the heart, xanthine oxidase is a major source of free radical formation. During ischemia, adenine-nucleotide breakdown in the cardiomyocyte proceeds only to the stage of inosine. Due to the localisation of nucleoside phosphorylase and xanthine-oxidase in vascular endothelium, further degradation of inosine to hypoxanthine, xanthine and uric acid occurs predominantly in the vascular space. It is therefore conceivable that the primary site of reperfusion injury in the ischemic heart may be the coronary endothelium damaged by free radicals.
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PMID:Mechanisms of ischemic injury in the heart. 390 19


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