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)

To assess the effects of xanthine oxidase (XO) inhibition on ischemic injury, rats were pretreated with oxypurinol (OXY, 5 mg/kg) and subjected to 30 min of bilateral renal artery occlusion. OXY's effect on adenine nucleotide-nucleoside-purine base concentrations was determined at 10 and 30 min of ischemia and during reperfusion (5 and 30 min). To assess whether XO-mediated oxidant stress influences the severity of ischemic acute renal failure (IARF), the effects of 1) OXY pretreatment and 2) hypoxanthine infusion were assessed. During ischemia OXY inhibited XO activity (more than fourfold rise in hypoxanthine-xanthine ratios) and induced quantitatively trivial but significant increases in ATP and total adenine nucleotide concentrations (by 30 min). Increased OXY dosage (15 mg/kg) or allopurinol (40 mg/kg) had no greater effects. At 5 min of reflow, OXY maintained XO inhibition but did not influence adenine nucleotide levels. By 30 min of reflow, 17-20% increments in ATP-total adenine nucleotides resulted. Nevertheless, OXY did not lessen the severity of IARF (assessed by azotemia-histology at 24 h). Hypoxanthine infusion increased end-ischemic hypoxanthine concentrations by 47%, but it did not change the severity of renal damage. Conclusions include 1) OXY-allopurinol induces intrarenal XO inhibition; 2) XO inhibitors slightly increase late ischemic-reperfusion adenine nucleotide concentrations; and 3) neither XO inhibition nor intrarenal hypoxanthine loading alters the severity of IARF, suggesting that XO-mediated oxidant stress is not a critical, consistent mediator of ischemic renal injury.
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PMID:Effects of xanthine oxidase inhibition on ischemic acute renal failure in the rat. 260 62

Hypoxia usually decreases the formation of reactive oxygen species by oxidases and by autoxidation of components of cellular electron transfer pathways and of quinoid compounds such as menadione. In the case of menadione reactive oxygen species are liberated to a significant extent only at non-physiologically high oxygen partial pressures (PO2). At physiological and hypoxic PO2 values electron shuttling of menadione in the mitochondrial respiratory chain predominates. In contrast, lipid peroxidation induced by halogenated alkanes, such as carbon tetrachloride, in liver leads to an increase in the formation of reactive oxygen and thus in cell injury under hypoxic conditions. Reactive oxygen species may also be generated during reoxygenation of a previously hypoxic tissue. Based on experiments with isolated hepatocytes a three-zone-model of liver injury due to hypoxia and reoxygenation is presented; 1) a zone where the cells die by hypoxia; 2) a zone where the cells are destroyed upon reoxygenation, presumably mediated by an increase in the cellular ATP content; and 3) a zone where cell injury occurs upon reoxygenation, mediated by reactive oxygen species possibly liberated by xanthine oxidase.
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PMID:Hypoxia, reactive oxygen, and cell injury. 266 66

Despite efficient revascularisation procedures for vascular disease, the limb can occasionally be lost following reperfusion. One contributing factor might be the formation of oxygen free radicals. This study attempts to describe the conditions necessary for oxy-radical formation from adenine nucleotide breakdown products and the role of plasma creatine content as a marker of cellular injury. Twelve patients undergoing aortic reconstructive surgery were studied. Only partial ischaemia of the lower limbs was induced by the aortic clamping, since varying degrees of collateral circulation existed. Radial arterial and external iliac venous blood was obtained simultaneously before, during and after cross-clamping of the aorta, and plasma levels of ATP, ADP, hypoxanthine, phosphocreatine, creatine, creatinine and lactate measured using luminescence and spectrophotometry. Venous creatine content increased during ischaemia and was doubled 30 min after recirculation. This increase was possibly due to leakage following cellular injury agreeing with a previously observed decrease in muscle tissue creatine content. The iliac arterio-venous difference of hypoxanthine and lactate markedly increased immediately post-ischaemia, while the phosphocreatine difference decreased. Plasma hypoxanthine was abundant in the leg on reoxygenation. The existence of a xanthine oxidase system in skeletal muscle could produce favourable conditions for oxy-radical formation through hypoxanthine degradation, which may contribute to the known muscle tissue injury.
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PMID:Plasma metabolic disturbances and reperfusion injury following partial limb ischaemia in man. 271 61

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

Complete cessation of flow in isolated rat hearts for 90 min resulted in a gradual breakdown of ATP and concomitant accumulation of degradation products, such as adenosine, inosine (major break-down product), hypoxanthine, and, to a lesser extent, xanthine. After 45 min of ischemia, the content and relative composition of purines hardly changed, whereas the AMP content continued to rise. This finding points to constraints on AMP degradation and flux through the degradation pathway from adenosine to uric acid in the ischemic heart. In myocardial preparations, the cells of which were deliberately disrupted by freezing and thawing before anoxic incubation, AMP did not accumulate and was finally converted to hypoxanthine. These results indicate that compartmentalization of substrates and enzymes is responsible for the observed preferential accumulation of AMP and inosine in the ischemic heart. Inhibition of hypoxanthine degradation is explained by the absence of oxygen. Restoration of flow and oxygen supply abolished the inhibition of metabolic flux. Accumulated purines were released into the coronary effluent and, concomitantly, further metabolized. Comparison of tissue levels of hypoxanthine, xanthine, and uric acid before reperfusion and the amounts released during reperfusion indicates that in rat myocardium substantial amounts of potentially hazardous xanthine oxidase-derived reactive oxygen species are likely to be formed during the early reperfusion phase.
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PMID:Degradation of adenine nucleotides in ischemic and reperfused rat heart. 278 5

The existence of uric acid in mammalian brain was recently reported, but it has not yet become a consensus. The mammalian brain has been thought to lack xanthine oxidase, which catalyzes hypoxanthine to xanthine and xanthine to uric acid as the last steps of ATP degradation in other tissue. Using high-performance liquid chromatography, we performed assays for hypoxanthine, xanthine, and uric acid in rat brain after cerebral ischemia. It was confirmed that all three substances showed significant augmentation in the removed brains and that the chronological order of those increases corresponded to the order in the metabolic pathway. Allopurinol, a specific inhibitor of xanthine oxidase, significantly suppressed the increases in uric acid and xanthine, and a compensatory accumulation of hypoxanthine was observed. From these results, it was concluded that uric acid does exist in the brain, increases after ischemia, and is possibly the end product of purine degradation in the brain. Furthermore, it is suggested that xanthine oxidase exists in the brain and catalyzes the reaction from hypoxanthine to xanthine and then to uric acid. These reactions catalyzed by xanthine oxidase are considered to be a source of free radicals and may play important roles in the pathogenesis of cerebral ischemic injury.
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PMID:Cerebral uric acid, xanthine, and hypoxanthine after ischemia: the effect of allopurinol. 279 98

In the rabbit myocardium, ischemia (produced by ligation of the left circumflex coronary artery) is associated with a reduction in antioxidant capacity. This is reflected by an increased glutathione depletion and production of thiobarbituric acid reactive substances following in vitro oxidative challenge with t-butylhydroperoxide. This effect is greatly intensified by reperfusion following periods of ischemia longer than 20 mins, thereby paralleling the onset of irreversible injury. Chronic allopurinol pretreatment (1 mg/mL in drinking water or approximately 75 mg/kg/day for seven days prior to ligation) provides significant protection of the ischemic/reperfused myocardium to t-butylhydroperoxide induced glutathione depletion and production of thiobarbituric acid reactive substances. This protection was not associated with any significant alterations in levels of tissue ATP or in the activities of the myocardial antioxidant enzymes catalase, copper,zinc-superoxide dismutase or glutathione peroxidase, suggesting that allopurinol may exert its effects by direct radical scavenging or by some other mechanism unrelated to xanthine oxidase inhibition.
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PMID:Altered antioxidant status in the ischemic/reperfused rabbit myocardium: effects of allopurinol. 281 60

Using paraquat, adriamycin, and anthraquinone 6-sulfonate, we have investigated the ability of radical-driven Fenton reactions to oxidize formate or deoxyribose when catalyzed by iron complexed with citrate, ADP, ATP, or pyrophosphate. Radicals were generated either radiolytically or enzymatically with xanthine oxidase or ferredoxin reductase. With each radical source, the citrate, ADP, and ATP complexes were at least 50% as active as Fe(EDTA) at catalyzing deoxyribose oxidation, and slightly less active as catalysts of CO2 formation from formate. Fe(pyrophosphate) was less efficient and in some cases inactive. Although it is not possible to definitively identify the oxidant involved, it behaved more like the hydroxyl radical than the proposed ferryl or peroxoferrous species formed in equivalent reactions catalyzed by nonchelated iron, which can oxidize deoxyribose but not formate. Chelator concentrations of 1-2 mM were required for maximum effect, which implies that the major effect of the chelators is on the reactivity of Fe2+ in the Fenton reaction with H2O2. This also suggests that any iron available physiologically could participate in the Fenton reaction in a nonchelated form, and produce a ferryl species rather than the hydroxyl radical. Reactions of the organic radicals contrast with the equivalent reactions of superoxide (Haber-Weiss reaction) for which the same iron chelates are all very inefficient catalysts. Fenton reactions driven by organic reducing radicals may therefore contribute more to the toxicity of redox cycling compounds than equivalent reactions of superoxide.
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PMID:Radical-driven Fenton reactions: studies with paraquat, adriamycin, and anthraquinone 6-sulfonate and citrate, ATP, ADP, and pyrophosphate iron chelates. 282 82

In eucaryotic cells, immature mRNA is normally restricted to the nucleus, where it is posttranscriptionally processed to mature mRNA. The intranuclear binding site for both the immature and mature mRNA is thought to be the nuclear matrix which serves as a platform for posttranscriptional RNA maturation and transport. The selectivity of nucleocytoplasmic transport for mature mRNA species seems to be due to the selectivity of the ATP-caused release of mature mRNA from the nuclear matrix; the attachment of immature mRNA to the matrix is not altered in the presence of this nucleotide. Here we show that in the presence of superoxide radical anions (O2-), which are very likely one of the causative factors in ageing, the selection mechanism for mature mRNA at the level of nuclear matrix attachment is disturbed. In the presence of a superoxide radical-generating system (xanthine/xanthine oxidase), both the mature ovalbumin mRNA and the immature ovalbumin mRNA precursors were found to be released from the nuclear matrix of hen oviduct cells, in the absence as well as in the presence of ATP. This result was also obtained when whole, isolated nuclei preincubated with xanthine/xanthine oxidase were used. The superoxide radical-caused effect could be partially prevented by co-addition of superoxide dismutase (SOD) which dismutates O2- to H2O2 and O2. On the other hand, in the presence of antibodies against the SOD, the effect of superoxide anions on RNA-matrix attachment was enhanced and its inhibition by SOD was abolished. Our results suggest that cellular ageing may be partially caused by superoxide radical-induced release of immature mRNA from its intranuclear binding site resulting in the appearance of immature messengers in the cytoplasm. This may cause both qualitative and quantitative changes in protein synthesis. Thus, ageing may be associated not only with the expression of genes coding for proteins not characteristic for the proper state of differentiation of a given cell (as suggested by the dysdifferentiative hypothesis of ageing) but also with impaired maturation of the primary gene transcripts due to the interference of superoxide radicals, not sufficiently eliminated by antioxidant mechanisms with age, with RNA-matrix attachment.
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PMID:Superoxide radical-induced loss of nuclear restriction of immature mRNA: a possible cause for ageing. 282 75

Our recent studies have indicated that release of ATP/ADP from platelets causes enhanced O2-. responses in stimulated neutrophils. The current investigations were designed to provide further details of this phenomenon, to determine the structure-function correlates of the adenine compounds, and to assess if the results might be explained by the formation of a single metabolic product of ATP. ATP, ADP, AMP and adenosine enhanced O2-. responses of rat neutrophils stimulated with immune complexes or formyl chemotactic peptide (FMLP) but had no effect on responses of phorbol ester-stimulated neutrophils. Similar results were obtained in human neutrophils stimulated with immune complexes; when FMLP was the agonist, the results were divergent: ATP and ADP enhanced the responses, whereas AMP and adenosine were inhibitory. In structure-function studies, hydrolytically resistant forms of ATP (and other adenine nucleotides) containing blocked or cross-linked phosphate groups were active, suggesting that hydrolysis of these compounds to a common metabolic product is not required for their effects on O2-. responses. In contrast, other chemical modifications of the ribose ring or adenine base of ATP resulted in greatly diminished activity. To further pursue the question of whether metabolism of the adenine compounds via the adenosine pathway was related to the observed effects on O2-. responses, addition to rat neutrophils of inhibitors of adenosine deaminase, S-adenosyl homocysteine hydrolase, or xanthine oxidase failed to reproduce or augment the enhancement effects of the adenine compounds on O2-. responses, suggesting that metabolism of the adenine compounds to a common product may not be a requirement for the observed effects. Although the manner by which the adenine compounds affect O2-. responses is not known, the data suggest that adenosine and adenine nucleotides have important regulatory effects on oxygen radical responses of stimulated neutrophils.
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PMID:Regulatory effects of adenosine and adenine nucleotides on oxygen radical responses of neutrophils. 283 59


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