UNIPROT:P47989 - FACTA Search

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Query: UNIPROT:P47989 (xanthine oxidase)
8,633 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

A new spectrophotometric method for the determination of adenosine deaminase is described. Adenosine is deaminated to inosine, the latter is cleaved by an inosine-guanosine specific nucleoside phosphorylase to hypoxanthine and ribose-1-phosphate. Hypoxanthine can be oxidized further to uric acid by xanthine oxidase or to allantoin by xanthine oxidase and uricase. The hydrogen peroxide formed in these reactions is reduced by catalase to water. In the presence of high concentrations of ethanol, equivalent amounts of acetaldehyde are produced. The acetaldehyde is oxidized NAD(P) dependent and the production rate of NAD(P)H is recorded at 334 nm. The new method is suitable for the detection of adenosine deaminase in whole blood, lymphocytes, sera and tissues.
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PMID:A new spectrophotometric assay for enzymes of purine metabolism. IV. Determination of adenosine deaminase. 736 76

We describe an enzymic, one-step kinetic method for determination of guanine deaminase (guanase, EC 3.5.4.3) in serum with a centrifugal analyzer. A combined enzyme-substrate system consists of the enzymes xanthine oxidase, catalase, and aldehyde dehydrogenase, the coenzyme NAD+, the substrate guanine, and ethanol in tris(hydroxymethyl)methylamine buffer, with KCl added as activator for aldehyde dehydrogenase. The method requires only 40 microL of sample. Guanase activity in 28 samples can be determined within 10 min by setting a 4-min lag period. The increase in absorbance at 340 nm is linearly proportional to the activity of guanase to 60 U/L. Within-run precision (CV) was 1.32 to 4.50% over the range studied. Day-to-day precision corresponds to CVs of 4.8 to 7.2% over the same range of guanase activity. The reference interval, as calculated from data on 25 healthy humans, was 0 to 1.02 U/L. The enzymic automated method shows good correlation with Caraway's (Clin. Chem. 12: 187, 1966) method (r = 0.949).
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PMID:Kinetic measurement of guanine deaminase in serum with a centrifugal analyzer. 747 21

Hypoxia-induced hepatocyte injury results not only from ATP depletion but also from reductive stress and oxygen activation. Thus the NADH/NAD+ ratio was markedly increased in isolated hepatocytes maintained under 95% N2/5% CO2 in Krebs-Henseleit buffer well before plasma membrane disruption occurred. Glycolytic nutrients fructose, dihydroxyacetone or glyceraldehyde prevented cytotoxicity, restored the NADH/NAD+ ratio, and prevented complete ATP depletion. However, the NADH generating nutrients sorbitol, xylitol, glycerol and beta-hydroxybutyrate enhanced hypoxic cytotoxicity even though ATP depletion was not affected. On the other hand, NADH oxidising metabolic intermediates oxaloacetate or acetoacetate prevented hypoxic cytotoxicity but did not affect ATP depletion. Restoring the cellular NADH/NAD+ ratio with the artificial electron acceptors dichlorophenolindophenol and Methylene blue also prevented hypoxic injury and partly restored ATP levels. Ethanol which further increased the cellular NADH/NAD+ ratio increased by hypoxia also markedly increased toxicity whereas acetaldehyde which restored the normal cellular NADH/NAD+ ratio, prevented toxicity even though hypoxia induced ATP depletion was little affected by ethanol or acetaldehyde. The viability of hypoxic hepatocytes is therefore more dependent on the maintenance of normal redox homeostasis than ATP levels. GSH may buffer these redox changes as hypoxia caused cell injury much sooner with GSH depleted hepatocytes. Hypoxia also caused an intracellular release of free iron and cytotoxicity was prevented by desferoxamine. Furthermore, increasing the cellular NADH/NAD+ ratio markedly increased the intracellular release of iron. Hypoxia-induced hepatocyte injury was also prevented by oxypurinol, a xanthine oxidase inhibitor. Polyphenolic antioxidants or the superoxide dismutase mimic, TEMPO partly prevented cytotoxicity suggesting that reactive oxygen species contributed to the cytotoxicity. The above results suggests that hypoxia induced hepatocyte injury results from sustained reductive stress and oxygen activation.
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PMID:Modulating hypoxia-induced hepatocyte injury by affecting intracellular redox state. 748 48

The effect of metabolic activation on the mutagenicity of nitrodibenzofurans (NDF) by rat liver S9 was evaluated with S. typhimurium tester strains. Except for 1-nitrodibenzofuran (NDF), five tested NDFs were mutagenic in strains TA98 and TA98/1,8-DNP6 without S9 mix but were not mutagenic in strain TA98NR. NDFs mutagenized strain TA98NR with S9 mix, and the NAD(P)H system plus 3-methylcholanthrene-induced S9 (3-MC-S9) was the most effective. The specificity of S9 enzyme(s) participating in the activation of NDFs was different from that of endogenous enzyme(s) in strain TA98, i.e., the order of mutagenic potency of NDFs in strain TA98 without S9 mix was 2,8- = 2,7-->3-->2-->4-->1-nitrated dibenzofuran and 2-NDF and 2,8-dinitrodibenzofuran (DNDF) were more mutagenic than 3-NDF and 2,7-DNDF, respectively, in strain TA98NR with S9 mix. The mutagenic potency of 2-NDF, 4-NDF, 2,7-DNDF and 2,8-DNDF in strain TA98NR with S9 mix was stronger than those in strain TA98 without S9 mix and the cytosolic fraction of the 3-MC-S9 accounted for more of the activation than the microsomal fraction. Studies with electron donors and inhibitors indicated that xanthine oxidase and/or NAD(P)H-quinone oxido-reductase (NQOR) participated in the activation of NDFs. The mutagenic potency of NDFs in strain TA98NR with S9 mix (3-MC-S9) was reflected in the induction of NQOR by pretreatment of rats with 3-MC.
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PMID:Metabolic activation of nitrodibenzofurans by rat liver in Salmonella/mutagenicity test. 752 Oct 8

Liver cytosolic fractions are known to catalyze the reduction of certain C-nitroso compounds to their corresponding hydroxylamines and amines. Alcohol dehydrogenase (ADH), NAD(P)H:quinone oxidoreductase, and xanthine and aldehyde oxidases have been implicated as C-nitroso reductases. To probe the role of these cytosolic enzymes in the reduction of C-nitroso compounds we have studied the effects of classical inhibitors of these enzymes on the ability of liver cytosolic fractions from ADH+ and ADH- deermice to reduce p-nitrosophenol to p-aminophenol. Pyrazole, a potent inhibitor of ADH, inhibited NADH-p-nitrosophenol reduction by ADH+ cytosol by > 85%. Thus, ADH contributes substantially to NADH-C-nitroso reduction by cytosol from ADH+ deermice. The NAD(P)H:quinone oxidoreductase inhibitor, dicumarol, inhibited NADH-dependent p-aminophenol formation by about 25%; however, dicumarol potently inhibited the NADPH-dependent formation (90-95%). As expected, cytosol from ADH- deermice did not catalyze pyrazole-sensitive (ADH-dependent) C-nitroso reduction with NADH as the cofactor. Both NADPH- and NADH-p-nitrosophenol reduction by ADH- cytosol were inhibited > 90% by dicumarol. The xanthine oxidase/aldehyde oxidase inhibitor, allopurinol, was without effect on NAD(P)H cytosolic p-nitrosophenol reduction from ADH- and ADH+ deermice under either aerobic or anaerobic conditions. Our findings suggest that in the ADH+ animal, ADH contributes significantly to NADH-dependent C-nitroso reduction by cytosol relative to NAD(P)H:quinone oxidoreductase. NADPH-dependent p-nitrosophenol reduction by liver cytosol of ADH+ animals is mostly dicumarol-sensitive, which implicates NAD(P)H:quinone oxidoreductase as the major NADPH-dependent activity. In ADH- deermice, both NADH- and NADPH-dependent p-nitrosophenol reduction are essentially dicumarol-sensitive (NAD(P)H:quinone oxidoreductase-dependent). Because the toxic expression of C-nitroso compounds is mediated by hydroxylamine intermediates, the present data indicate the importance of considering the role of ADH in the toxic sequelae of nitro and nitroso arenes.
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PMID:p-nitrosophenol reduction by liver cytosol from ADH-positive and -negative deermice (Peromyscus maniculatus). 753 87

The properties of the molybdenum iron-sulfur flavoprotein, aldehyde oxidase from rabbit livers, have been further investigated in comparison with bovine milk xanthine oxidase. In agreement with earlier work, the ultraviolet/visible spectra indicate that the flavin and iron-sulfur centres of the enzymes are quite similar to one another. The molybdenum centres have been compared by EPR spectroscopy of molybdenum(V) and regarding re-insertion of the sulfido ligand of molybdenum into the desulfo enzyme forms. The pH optimum for sulfide insertion is approximately 2 lower for aldehyde oxidase than for xanthine oxidase. A detailed comparison of molybdenum(V) EPR signals has been made for the signals known as Arsenite, Slow and Rapid. Computer simulation of spectra in 1H2O and 2H2O, at 9 and 35 GHz was used. Slow signals from the two enzymes are scarcely distinguishable from one another. Under the conditions used, aldehyde oxidase yielded only the Rapid type 2 signal, whereas xanthine oxidase gives both the Rapid type 1 and 2 signals. The nature of the structural difference between the Rapid type 1 and type 2 signal-giving species is discussed. It is concluded that the molybdenum centres of xanthine oxidase and aldehyde oxidase are indeed similar to one another and that such differences as exist between their molybdenum(V) EPR signals and re-sulfuration properties are related to differences only in the substrate-binding sites. N-terminal amino acid analyses have been performed on peptides obtained by trypsin cleavage of aldehyde oxidase. Comparison with a sequence previously deduced [Wright, R. M., Vaitaitis, G. M., Wilson, C. M., Repine, T. B., Terada, L. S. & Repine, J. E. (1993) Proc. Natl Acad. Sci. USA 90, 10690-10694] makes it clear that the latter is not, as was assumed, that of a xanthine dehydrogenase but of an aldehyde oxidase. In contrast to the situation with xanthine oxidase, attempts to convert non-proteolysed aldehyde oxidase to a dehydrogenase form by treatment with dithiothreitol were unsuccessful. The reason for this is considered in the light of sequence data in the literature. The location of the NAD(+)-binding site is discussed, and the sequence data are also discussed in relation to the molybdenum, iron-sulfur and substrate-binding sites.
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PMID:Properties of rabbit liver aldehyde oxidase and the relationship of the enzyme to xanthine oxidase and dehydrogenase. 755 19

By correlating lactate/pyruvate ratios and ATP levels, cytotoxicity induced by the mitochondrial respiratory inhibitors or hypoxia:reoxygenation injury can be attributed not only to ATP depletion but also to reductive stress and oxygen activation. Thus hypoxia, cyanide or antimycin markedly increases reductive stress, non-heme Fe release and H2O2 formation in hepatocytes. Cytotoxicity was partly prevented with the ferric chelator desferoxamine, the xanthine oxidase inhibitor oxypurinol and the hydrogen peroxide scavenger glutathione. No lipid peroxidation could be detected and phenolic anti-oxidants had little effect. However, polyphenolic antioxidants or the superoxide dismutase mimics TEMPO or TEMPOL partly prevented cytotoxicity. Furthermore, increasing the hepatocyte NADH/NAD+ ratio with NADH generating compounds such as ethanol, glycerol, or beta-hydroxybutyrate markedly increased cytotoxicity (prevented by desferoxamine) and further increased the intracellular release of non-heme iron. Cytotoxicity could be prevented by glycolytic substrates (eg. fructose, dihydroxyacetone, glyceraldehyde) or the NADH utilising substrates acetoacetate or acetaldehyde which decreased the reductive stress and prevented intracellular iron release. These results suggest that liver injury resulting from insufficient respiration involves reductive stress which releases intracellular Fe, converts xanthine dehydrogenase to xanthine oxidase and causes mitochondrial oxygen activation. The cell's antioxidant defences are compromised and ATP catabolism contributes to oxygen activation.
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PMID:Hepatocyte injury resulting from the inhibition of mitochondrial respiration at low oxygen concentrations involves reductive stress and oxygen activation. 758 49

The conversion of xanthine dehydrogenase to xanthine oxidase that produces oxygen radicals has been implicated in the ischemic injury to the myocardium and to the kidney. Xanthine dehydrogenase uses NAD as the electron acceptor to catalyze a reaction which does not produce any oxygen free radicals and may depress the conversion of xanthine dehydrogenase to xanthine oxidase. Nicotinamide is the preferred precursor for NAD. This study was conducted to examine the effect of an 18% casein diet supplemented with 0.5% nicotinamide on the activity of oxidoreductase and its two enzyme forms, xanthine dehydrogenase and xanthine oxidase, in kidney, heart and liver of female obese Zucker rats that spontaneously develop glomerulosclerosis, cardiomegaly and fatty liver. Lean litter mates were used as controls. Nicotinamide supplementation had no effect on the activities of these enzyme forms in the liver of either obese rats or lean rats. Obese rats fed the nicotinamide supplemented diet had higher activities of these enzyme forms in kidneys and hearts than unsupplemented diet fed obese rats, but this difference was not observed in lean rats. In unsupplemented rats, xanthine oxidase activity in the kidney was greater in lean rats than obese rats. Thus, the abnormalities observed in obese rats are unlikely attributable to the xanthine oxidase-mediated oxidant stress.
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PMID:Dietary nicotinamide supplementation increases xanthine oxidoreductase activity in the kidney and heart but not liver of obese Zucker rats. 761 99

Xanthine oxidase and xanthine dehydrogenase are enzymes involved in the metabolism of purines and pyrimidines in various organisms. Their relationship to one another has been the subject of considerable debate, primarily because of their proposed roles in ischemia/reperfusion damage in tissues. Differences in the kinetics and oxidation-reduction behavior of the two forms are accounted for by the presence in the dehydrogenase of a binding site for NAD+, as well as a substantially lower reduction potential for the flavin FADH./FADH2 couple of the dehydrogenase relative to the oxidase. This review presents recent advances of our understanding of the biochemistry and molecular biology of these systems, including a model for the overall morphology of xanthine oxidizing enzymes. The evidence that the two enzymes represent alternate forms of the same gene product, in some cases reversibly interconvertible between one another, is discussed.
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PMID:Flavoprotein structure and mechanism. 4. Xanthine oxidase and xanthine dehydrogenase. 764 15

The ability of O2 metabolites derived from the xanthine-xanthine oxidase system to inhibit mitochondrial function was examined using freshly isolated rat liver mitochondria. Under 2,4-dinitrophenol-uncoupled conditions, mitochondria exposed to free radicals exhibited a significant decrease in O2 consumption supported by NAD(+)-linked substrates, but showed almost no change in O2 consumption in the presence of succinate and ascorbate. Oxidative stress caused the loss of intramitochondrial nicotinamide nucleotides, and addition of NAD+ fully prevented any fall in O2 consumption with NAD(+)-linked substrates. The activity of electron-transfer complex I (NADH oxidase and NADH-cytochrome c oxidoreductase) and the energy-dependent reduction of NAD+ by succinate were unaltered by oxidative stress. Exposure to free radicals also had an uncoupling effect at all three coupling sites. The degree of mitochondrial swelling was closely correlated with the inhibition of State-3 oxidation of site-I substrates and with the increase in State-4 oxidation of succinate. The immunosuppressive agent cyclosporin A completely prevented the mitochondrial damage induced by oxygen free radicals (swelling, Ca2+ release, sucrose trapping, uncoupling and selective inhibition of the mitochondrial respiration of site-I substrates). The same protective effect was found when Ca2+ cycling was prevented, either by chelating Ca2+ with EGTA or by inhibiting Ca2+ reuptake with Ruthenium Red. These findings suggest that the deleterious effect of free radicals on mitochondria in the present experimental system was triggered by the cyclosporin A-sensitive and Ca(2+)-dependent membrane transition, and not by direct impairment of the mitochondrial inner-membrane enzymes.
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PMID:Oxidative damage to mitochondria is mediated by the Ca(2+)-dependent inner-membrane permeability transition. 769 Oct 56

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