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: EC:1.17.3.2 (xanthine oxidase)
8,383 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

Milk xanthine oxidase possesses the nitrate reductase activity at pH 5.2; the pH optimum of the xanthine oxidase activity for the enzyme lies at 9.6. After removal of FAD and binding of Mo and Fe with a simultaneous measurement at the pH optima of the above activities it was found that only the Mo-containing site is necessary for the nitrate reductase activity. The switch-over of the enzyme from the xanthine oxidase to the nitrate reductase activity is associated with considerable conformational changes of the enzyme molecule.
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PMID:[Functional groups involved in the nitrate reductase activity of milk xanthine oxidase]. 668 66

Benznidazole (Bz) (N-benzyl-2-nitro-1-imidazole-acetamide) is a drug used against Chagas' disease. Rat liver microsomal and cytosolic fractions, but not mitochondria, exhibited Bz nitroreductase activity under anaerobic conditions in the presence of NADPH. Microsomal nitroreductase activity was enhanced by FAD and was inhibited totally by oxygen and partially by carbon monoxide. Liver cystosol fraction was able to reduce Bz nitrogroups in the presence of either N-methylnicotinamide or hypoxanthine as substrates. These enzyme activities were inhibited by menadione or allopurinol respectively. Under every experimental condition leading to enzymatic reduction of Bz nitrogroups and its inhibition or enhancement, reactive metabolites that bind covalently to proteins were also produced. This covalent binding was effectively prevented by reduced glutathione. Results suggest the participation of cytochrome P-450 and cytochrome c reductase in liver microsomal processes and of xanthine oxidase and aldehyde oxidase in liver cytosolic processes of Bz nitroreduction and activation to reactive metabolites that bind covalently to proteins. Possible pharmacological and toxicological implications of the described observations were discussed.
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PMID:Reductive metabolism and activation of benznidazole. 671 14

Milk xanthine oxidase reacted with fluorodinitrobenzene resulting in the modification of two lysine residues with a 6-fold decrease in catalytic activity. Continued reaction with fluorodinitrobenzene up to a total of 11 dinitrophenyl residues/equivalent of enzyme-bound FAD resulted in no further decrease in activity. Stopped flow studies revealed that the modification perturbed the reduction of the enzyme by xanthine; this was 6-fold lower with modified than with native enzyme. The reaction of the reduced modified enzyme with oxygen was qualitatively and quantitatively the same as with native enzyme. One nitro group of each dinitrophenyl lysine residue is slowly reduced by xanthine; reduction of both nitro groups is achieved by dithionite. The two dinitrophenyl lysine reduces can be distinguished on the basis of their kinetics of reduction. One appears to be located on the protein surface and is reduced in an intermolecular reaction, while the other appears to be located in a pocket of the enzyme and is reduced in a slow intramolecular reaction.
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PMID:Inhibition of milk xanthine oxidase by fluorodinitrobenzene. 680 72

The chemical reactivity of 8-chloroflavins and 8-mercaptoflavins has been exploited in order to examine the orientation of protein-bound flavins relative to solvent. The apoprotein form of a series of flavoproteins was prepared and the native flavin was replaced by either 8-Cl-flavin or 8-mercaptoflavin (FAD, FMN, or riboflavin form as was appropriate). The reconstituted proteins were exposed to reagents capable of reacting with the group at position 8. The 8-Cl-proteins were challenged with sodium sulfide and thiophenol, while the 8-mercaptoproteins were faced with iodoacetamide and iodoacetic acid. The kinetics of the ensuing reactions served as a measure of the solvent availability of position 8 for the protein-bound flavin. These studies indicated that position 8 of flavin bound to melilotate hydroxylase, D-amino acid oxidase, old yellow enzyme, p-OH-benzoate hydroxylase, and flavodoxin is accessible to solvent, while position 8 on L-lactate oxidase, glucose oxidase, putrescine oxidase, and riboflavin-binding protein appears to be inaccessible. For luciferase, D-lactate dehydrogenase, and xanthine oxidase, the data suggest that position 8 is exposed but the results are inconclusive. The effect of ligand binding on the accessibility of position 8 was also studied. NADPH binding to 8-mercapto old yellow enzyme and benzoate binding to 8-Cl-D-amino acid oxidase results in complete blockage of previously available position 8. On the other hand, p-OH-benzoate hydroxylase and melilotate hydroxylase bind their respective substrates (p-OH-benzoate and melilotate) without significantly altering the reactivity of position 8.
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PMID:Active site probes of flavoproteins. Determination of the solvent accessibility of the flavin position 8 for a series of flavoproteins. 689 55

A series of potentiometric titrations of xanthine oxidase have been performed at room temperature in the pH range 6.1-9.9. Reduction of the two Fe/S centers was monitored by CD, and that of the FAD and Mo center by EPR. The Fe/S centers behave as centers having a protonable group whose pKa changes with reduction state (E = -344 mV, pKo = 6.4, and pKr = 8.1 for Fe/S I; E = -249 mV, pKo = 6.4, and pKr = 8.0 for Fe/S II). The flavin and the two types of molybdenum centers show varying behavior, but, in all cases, electron addition is accompanied by protonation. The sequence for FAD is reduction, protonation, reduction, protonation with E1 = -398 mV, E2 = -240 mV, pK1 = 9.5, pK2 = 7.4. For "rapid" molybdenum, the sequence is protonation, reduction, protonation, reduction with E1 = -369 mV, E2 = -301 mV, pK1 = 7.9, pK2 = 8.4; and for slow molybdenum, protonation, reduction, protonation with E1 = 320 mV, E2 = -477 mV, pK1 = 7.5, pK2 = 9.5. Comparison to data obtained previously at cryogenic temperatures (Cammack, R., Barber, M. J., and Bray, R. C. (1976) Biochem. J. 157, 469-468 and Barber, M. J., and Seigel, L. M. (1982) in Flavins and Flavoproteins (Massey, V., and Williams, C. H., eds) pp. 796-804, Elsevier/North-Holland, New York) showed the centers to have significant temperature dependence, which calls for a re-evaluation of conclusions reached using cryogenic techniques (e.g. rapid-freeze). The optical absorbance characteristics of the enzyme were also investigated and a possible absorbance for molybdenum was suggested.
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PMID:The room temperature potentiometry of xanthine oxidase. pH-dependent redox behavior of the flavin, molybdenum, and iron-sulfur centers. 689 74

The present study demonstrated the metabolism of N-hydroxyurethane by cell-free preparations, i.e., 9000 X g supernatant, cytosol and microsomes, from guinea pig livers. Under anaerobic conditions, the metabolizing activities of these preparations were enhanced markedly by addition of both an NADPH- or NADH-generating system and FAD. When the 30-45% ammonium sulfate fraction from liver cytosol was combined with liver microsomes or milk xanthine oxidase, the metabolic reaction of N-hydroxyurethane proceeded to a greater extent. Thin-layer chromatographic examination showed that urethane was only a metabolite formed from N-hydroxyurethane by these preparations.
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PMID:Metabolism of N-hydroxyurethane by guinea pig liver preparations. 716 23

We have characterized a chemically reactive propranolol (PL) metabolite which binds to proteins in rat liver microsomes. During incubation with rat liver microsomes (1 mg of protein) fortified with an NADPH-generating system, 4-hydroxypropranolol (4-OH-PL) quickly disappeared from the reaction medium, but none of the possible metabolite peaks was detected under the high-performance liquid chromatographic conditions used. The consumption of 4-OH-PL depended on microsomes and NADPH. The reaction was not affected by inhibitors of cytochrome P450 or FAD monooxygenase, but was markedly diminished in the presence of cytosol and ascorbic acid. The effect of cytosol was inhibited by potassium cyanide but not by sodium benzoate or dimethyl sulfoxide, and was also not affected by heating at 60 degrees C for 30 min, suggesting that superoxide (SO) ion was involved in the reaction and that it was blocked by superoxide dismutase (SOD) present in the cytosol. Cu,Zn-SOD, purified from cytosol, effectively mimicked the suppressive effect of cytosol. Incubation of 4-OH-PL in an SO-generating system of xanthine and xanthine oxidase generated 1,4-naphthoquinone (1,4-NQ), which was identified by TLC, HPLC, and GC/MS. 1,4-NQ was also formed in microsomal incubates containing NADPH and small amounts of microsomes (below 0.1 mg of protein). These results indicate that 4-OH-PL is converted by SO, or some reactive oxygen species derived from it, to 1,4-NQ which binds to proteins and is one of the reactive metabolites of PL.
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PMID:Characterization of a chemically reactive propranolol metabolite that binds to microsomal proteins of rat liver. 754 55

Oxygen-derived free radicals (ODFR) appear to be involved in the pathogenesis of arthritic disorders. In order to gain new insight on their role in the phenomenon and as a basis for a therapeutic approach, the effect of ODFR (produced by the xanthine oxidase-hypoxantine system) on hyaluronic acid, on two HA ester derivatives, and on pig articular chondrocytes was investigated. High M(r) HA (1.1 x 10(6)) and low M(r) HA (16 x 10(4)) were depolymerized by ODFR but the methyl and hydrocortisone esters of HA (HYAFF 2P50 and HYC13) turned out to be nearly unaffected. When articular chondrocytes were treated with ODFR, a rapid nucleoside triphosphate (NTP) depletion, a transient appearance of pyrophosphate (PPi), and an increase of phosphomonoester and diphosphodiester concentrations have been observed. The NTP depletion and the DPDE increase are related to the concentration of free radicals. Glyceraldehyde-3-phosphate accumulation during ODFR treatment suggests that ATP depletion can occur as a consequence of the blockage of glycolysis at the level of glyceraldehyde-3-P dehydrogenase. The hypothesis is presented that PPi can be produced from the pathway of the FAD-NAD (DPDE) biosynthesis and then either hydrolyzed by endogenous pyrophosphatases or precipitated in the form of insoluble calcium salts. Long-term treatment (16 h) with ODFR causes a loss of chondrocyte membrane integrity which can be revealed both by an increased free LDH activity and by the characteristic signal of free phospholipids in the 31P-NMR spectra. While high M(r) HA shows a significant protective activity for chondrocytes against ODFR action, low M(r) HA and ester derivatives do not. It is suggested that the therapeutic activity of HA ester derivatives can be ascribed to their in vivo hydrolysis products.
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PMID:Oxygen-derived free radical (ODFR) action on hyaluronan (HA), on two HA ester derivatives, and on the metabolism of articular chondrocytes. 773 82

Although mammalian xanthine oxidase exists originally as a dehydrogenase form in freshly prepared samples, it is converted to an oxidase form during purification, either irreversibly by proteolysis or reversibly by sulfhydryl oxidation of the protein molecule. However, avoiding proteolysis the mammalian enzyme can be purified as an interconvertible form and thus can be used to compare directly the properties of xanthine dehydrogenase and the oxidase derived from the same enzyme molecule. The cDNAs encoding the enzyme have been cloned from several sources, and structural information is becoming available. The most significant difference between the two forms is the protein conformation around FAD, which changes the redox potential of the flavin and the reactivity of FAD with the electron acceptors, NAD and molecular oxygen. The flavin semiquinone is thermodynamically stable in xanthine dehydrogenase, but is unstable in xanthine oxidase. Detailed analyses by stopped-flow techniques suggest that the flavin semiquinone reacts with oxygen to form superoxide anion while the fully reduced flavin reacts to form hydrogen peroxide. Although xanthine dehydrogenase can produce greater amounts of superoxide anion than xanthine oxidase during xanthine-oxygen turnover, it seems to be physiologically insignificant because NAD inhibits almost completely the formation of superoxide anion. Although the involvement of this enzyme in reperfusion injury has been proposed, this seems to be more complex than originally envisaged and still remains to be established.
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PMID:The conversion of xanthine dehydrogenase to xanthine oxidase and the role of the enzyme in reperfusion injury. 779 66

Methanol-grown Amycolatopsis methanolica NCIB 11946 contains a molybdoprotein dehydrogenase, active with aldehydes and formate esters as substrates and with Wurster's blue as electron acceptor, the so-called formate ester dehydrogenase (FEDH) (van Ophem et al., 1992, Eur. J. Biochem. 206, 519-525). It appears now that another molybdoprotein dehydrogenase is present in this organism. This enzyme, indicated here as dye-linked aldehyde dehydrogenase (DL-AlDH), has the same set of cofactors and converts the same type of substrates but with different specificity, and uses 2,6-dichlorophenol-indophenol as sole artificial electron acceptor for those conversions. The enzymes also differ in their quaternary structure, FEDH having an alpha, beta, gamma and DL-AlDH having an alpha, beta, gamma 2 composition. Furthermore, differences exist with respect to the sizes and the N-terminal amino acid sequences of their subunits, indicating that the enzymes derive from different genes. However, neither their substrate specificity nor their induction pattern give a clear indication for distinct physiological roles. Just like other bacterial molybdoprotein dehydrogenases, DL-AlDH consists of three different subunits (87, 35, and 17 kDa) and contains FAD, molybdopterin-cytosine-dinucleotide cofactor, Fe, and acid-labile sulfide in a molar ratio of 1:1:4:4. Although eukaryotic xanthine oxidase and dehydrogenase differ from these prokaryotic dehydrogenases in size and number of their subunits, certain stretches of amino acid sequences show similarity and the magnetic coupling between the Mo and the [2Fe-2S]-1 cluster in DL-AlDH and bovine milk xanthine oxidase is of the same magnitude. In view of this similarity, the topology of the cofactors in the active site of this type of molybdoproteins might be conserved among enzymes from prokaryotic as well as eukaryotic organisms.
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PMID:A second molybdoprotein aldehyde dehydrogenase from Amycolatopsis methanolica NCIB 11946. 855 33


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