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)

Human colostrum manifests antioxidant properties, being capable of spontaneous reduction of cytochrome c, depletion of polymorphonuclear leukocyte-produced H2O2 and protection of epithelial cells from PMN-mediated detachment. These activities can be electrophoretically concentrated at either 3.5 kD or 50 kD dialysis membranes at mildly alkaline pH. They are progressively lost under increasingly alkaline conditions. They are resistant to 1-mM N-ethylmaleimide. Examination of a series of antioxidant compounds showed that ascorbate manifests several characteristics of colostrum, being able to reduce cytochrome c and deplete H2O2 but not altering PMN-mediated HEp2 cell detachment. Addition of ascorbate oxidase to colostrum decreased its cytochrome c-reducing activity by more than 85%, decreased its H2O2-depleting activity by nearly 50%, but did not alter its ability to protect HEp2 cells, all suggesting heterogeneity of colostral antioxidant activities. Treatment of colostrum with an enzymatic system (xanthine + xanthine oxidase) known to destroy ascorbate's cytochrome c-reducing activity yielded paradoxical results, decreasing colostral cytochrome c reduction in a dose-related manner, while increasing its H2O2-depleting activity. These studies demonstrate that a colostral component similar to ascorbate, a known antioxidant compound is responsible for the majority of colostral cytochrome c-reducing activity, for about half of its H2O2-depleting activity, and little, if any, of its protective effect on HEp2 cells. Thus colostral antioxidant activity is heterogeneous.
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PMID:Further characterization of human colostral antioxidants: identification of an ascorbate-like element as an antioxidant component and demonstration of antioxidant heterogeneity. 253 79

To verify whether lipid peroxidation is associated with focal cerebral ischemia, a unilateral middle cerebral artery occlusion was carried out in rats. The concentrations of various endogenous antioxidants in the ischemic center were measured, including alpha-tocopherol and ubiquinones as lipid-soluble antioxidants and ascorbate as a water-soluble antioxidant. At 30 minutes after ischemia, alpha-tocopherol decreased to 79% of baseline, reduced ubiquinone-9 to 73%, ubiquinone-10 to 66%, and reduced ascorbate to 76%. Six hours after ischemia, alpha-tocopherol decreased to 63% and reached a plateau, whereas reduced ubiquinones and reduced ascorbate declined further to 16% and 10%, respectively, 12 hours after ischemia and then reached plateau levels. These results suggest functional and durational differences between antioxidants and lipid peroxidation in this ischemic model. Although the reciprocal increase in oxidized ubiquinones during ischemia was not observed, that of oxidized ascorbate was noted. The complementary antioxidant system between cytoplasmic and membranous components, the combination alpha-tocopherol/ascorbate, was estimated from the calculated consumption ratio of these antioxidants on the basis that the loss of these reduced antioxidants is due to neutralization of free radicals. This system is suggested to play an important role in the early ischemic period. Urate also increased during ischemia. The possible involvement of the xanthine-xanthine oxidase system in initiating free radical reactions in cerebral ischemia is also discussed.
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PMID:Lipid peroxidation in focal cerebral ischemia. 276 92

To verify the lipid peroxidation in the focal cerebral ischemia, the levels of alpha-tocopherol, ubiquinone and ascorbate were measured in the ischemic center in rats. The former two were endogeneous lipid soluble antioxidants and the last was a water soluble antioxidant. alpha-Tocopherol, reduced ubiquinone-9 and -10, and reduced ascorbate decreased to 79%, 73%, 66%, and 76% 0.5 hour after ischemia, respectively. alpha-Tocopherol decreased to 63% 6 hours after ischemia, and then reached a plateau, while reduced ubiquinones and reduced ascorbate declined further to 16% and 10% 12 hours after ischemia, respectively, and then reached plateau levels. These results suggest their functional and durational differences as antioxidants against lipid peroxidation in this ischemic model. Although the reciprocal increase in oxidized ubiquinones during ischemia was not observed, that in oxidized ascorbate was noted. The complementary antioxidant system between cytoplasmic and membranous components, the combination alpha-tocopherol/ascorbate, was estimated from the calculated consumption ratio of these antioxidants, assuming that the loss of these reduced antioxidants is due to neutralization of free radicals. This system was suggested to play an important role in an early ischemic period. Urate also markedly increased during ischemia. Therefore, xanthine oxidase activity was measured in rats both in normal brain and in ischemic brain induced by four-vessel occlusion method. In the control rat, the enzyme activity was 0.87 +/- 0.13 nmol/g wet brain/min at 25 degrees C (mean +/- S.D.): 92.4% was associated with the NAD-dependent dehydrogenase form and only 7.6% with the oxygen-dependent superoxide-producing oxidase form. However, the ratio of the latter form increased to 43.7% after 0.5 hour of global ischemia despite the same level in total xanthine oxidase activity. This result suggests the involvement of the oxygen free radicals generated from the xanthine oxidase pathway in the pathogenesis of the ischemic injury of the rat brain.
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PMID:[Lipid peroxidation and changes in xanthine oxidase in cerebral ischemia]. 280 15

Although a number of reducing systems can release iron from ferritin, there is debate as to whether the process additionally requires a chelator. We have studied ferritin iron release by microsomes, paraquat and NADPH, by dialuric acid and by hypoxanthine and xanthine oxidase, using ferrozine to complex the released iron. In each case, Fe2+ (ferrozine) formation was detectable when the ferrozine was added at the beginning of the 10 min reaction period, but not at the end. However, with catalase present, up to 0.7 times as much Fe2+ could be measured with ferrozine added at the end. Further Fe2+ could be recovered by adding ascorbate with the ferrozine. These results indicate that an iron chelator is not required for reductive iron release from ferritin. However, the released iron will not be detectable as Fe2+ unless it forms a complex that is resistant to oxidation by H2O2 or other oxidants.
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PMID:An iron chelator is not required for reductive iron release from ferritin by radical generating systems. 280 53

S-thiolation of cardiac creatine kinase and skeletal muscle glycogen phosphorylase b was initiated by reduced oxygen species in reaction mixtures containing reduced glutathione. Both proteins were extensively modified at similar rates under conditions in which the oxidation of glutathione was inadequate to cause S-thiolation by thiol-disulfide exchange. Creatine kinase was both S-thiolated and non-reducibly oxidized at the same time at low glutathione concentration. The amount of each modification was decreased by adding additional reduced glutathione, and with adequate glutathione oxidation was prevented while S-thiolation was still very active. S-thiolation of glycogen phosphorylase b was not significantly affected by glutathione concentration and non-reducible oxidation of glycogen phosphorylase b was not observed. These experiments suggest that oxyradical or H2O2-initiated processes may be an important mechanism of protein S-thiolation during oxidative stress, and that the cellular concentration of glutathione may be an important factor in S-thiolation of different proteins. Both creatine kinase and glycogen phosphorylase b competed favorably with ferricytochrome c for superoxide anion in the standard xanthine oxidase system for the generation of oxyradicals and H2O2. These proteins were as effective as ascorbate and much more effective than reduced glutathione in this regard. Ascorbate was also an effective inhibitor of oxyradical-initiated S-thiolation of creatine kinase, suggesting a role of superoxide anion in protein S-thiolation. Other experiments showed that both catalase and superoxide dismutase could partially inhibit protein S-thiolation. Thus, reduced oxygen species may react with protein sulfhydryls resulting in S-thiolation by a mechanism that involves the reaction of an activated protein thiol with reduced glutathione.
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PMID:S-thiolation of creatine kinase and glycogen phosphorylase b initiated by partially reduced oxygen species. 282 73

Seven flavonoids and three non-flavonoid antioxidants, i.e. butylated hydroxyanisole, chlorpromazine and BW 755 C, were studied as potential scavengers of oxygen free radicals. Superoxide anions were generated enzymatically in a xanthine-xanthine oxidase system and non-enzymatically in a phenazine methosulphate-NADH system, and assayed by reduction of nitro blue tetrazolium. The generation of malonaldehyde (MDA) by the ascorbate-stimulated air-oxidised boiled rat liver microsomes was considered as an index of the non-enzymatic formation of hydroxyl radicals. Flavonoids but not non-flavonoid antioxidants lowered the concentration of detectable superoxide anions in both enzymic and non-enzymic systems which generated these SOD-sensitive radicals. The most effective inhibitors of superoxide anions were quercetin, myricetin and rutin. Four out of seven investigated flavonoids seemed also to suppress the activity of xanthine oxidase as measured by a decrease in uric acid biosynthesis. All ten investigated compounds inhibited the MDA formation by rat liver microsomes. Non-flavonoid antioxidants were more potent MDA inhibitors than flavonoids. It is concluded that antioxidant properties of flavonoids are effected mainly via scavenging of superoxide anions whereas non-flavonoid antioxidants act on further links of free radical chain reactions, most likely by scavenging of hydroxyl radicals.
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PMID:Flavonoids are scavengers of superoxide anions. 283 Aug 82

Mixed-function oxidation systems comprised of Fe3+, O2, and electron donors such as thiol compounds, ascorbate, NAD(P)H/NAD(P)H oxidase, and xanthine oxidase/hypoxanthine, catalyze the inactivation of many enzymes. This report describes the isolation and purification of a soluble protein from Saccharomyces cerevisiae, which specifically inhibits the inactivation of various enzymes by a nonenzymatic Fe3+/O2/thiol mixed-function oxidase system. When thiol is replaced with another electron donor (e.g. ascorbate), this specific protein no longer protects against iron (or copper)/O2-dependent radical-induced enzyme inactivation. Purification steps included a polyethylene glycol precipitation followed sequentially by a chromatography on DE52 and high pressure liquid chromatography on phenyl, DEAE, and gel-filtrated columns. The final gel filtration step yielded two protein peaks exhibiting protector activity and possessing a Mr of 500,000 and 90,000. Sodium dodecyl sulfate-polyacrylamide gel electrophoresis of these two fractions gave a single band at 27 kDa suggesting that these protein species simply represent different oligomeric structures. The protector protein did not possess catalase, glutathione peroxidase, superoxide dismutase, or iron chelation activities. Since the protection activity reported herein is specific for mixed-function oxidation systems containing thiols, we propose that the protector protein functions as a sulfur radical scavenger.
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PMID:The isolation and purification of a specific "protector" protein which inhibits enzyme inactivation by a thiol/Fe(III)/O2 mixed-function oxidation system. 289 5

The damaging effects of ascorbate (AH-) and superoxide (O-2) on resealed erythrocyte ghosts containing predetermined levels of lipid hydroperoxides (LOOHs) have been studied. Continuous blue light irradiation of membranes in the presence of protoporphyrin resulted in steadily increasing LOOH levels and enhanced release of a trapped marker, glucose 6-phosphate (G6P), after a 3- to 4-h lag. Neither superoxide dismutase (SOD) nor catalase inhibited these effects, ruling out O-2 and H2O2 as reactive intermediates. A 1-h light dose produced partially photoperoxidized ghosts, which, in the dark at 37 degrees C, released G6P no faster than unirradiated controls (approximately 7%/h). When xanthine oxidase plus xanthine (XO/X) was introduced as a source of O-2 and H2O2, the irradiated membranes lysed rapidly (t1/2 approximately 2 h). EDTA or SOD inhibited the reaction, whereas catalase had little or no effect. Unirradiated ghosts were not lysed by XO/X unless the system was supplemented with Fe(III), in which case total protection was afforded by SOD or catalase. In all experiments there was an excellent correlation between postirradiation lipid peroxidation (thiobarbituric acid reactivity) and G6P release. Similar observations were made with AH-. For example, dark incubation of photooxidized ghosts in the presence of 0.5 mM AH- resulted in rapid lysis (t1/2 approximately 1 h), which was stimulated approximately twofold by 50 microM Fe(III) and was inhibited by EDTA. By comparison, unirradiated ghosts showed no net peroxidation or lysis after 3 h exposure to Fe(III)/AH-. Neither SOD nor catalase protected against AH--stimulated damage. AH--promoted lipid peroxidation was inhibited by butylated hydroxytoluene, a lipophilic antioxidant, but was unaffected by 2,5-dimethylfuran or ethanol, singlet oxygen, and hydroxyl radical traps, respectively. These results suggest that a mechanism exists by which photogenerated LOOHs undergo redox metal-mediated reduction to alkoxy radicals (LO.), which trigger a burst of membrane-disrupting lipid peroxidation.
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PMID:Lipid photooxidation in erythrocyte ghosts: sensitization of the membranes toward ascorbate- and superoxide-induced peroxidation and lysis. 298 6

Oxygen-derived free radicals such as the hydroxyl radical (.OH) have been shown to mediate the oxidation of ethanol by a variety of oxy radical-generating systems. Among these are microsomal electron transport systems (both intact and purified, reconstituted systems), the coupled oxidation of hypoxanthine or xanthine by xanthine oxidase, and the model iron-ascorbate system. The sequence of reactions leading to the oxy radical-dependent oxidation of ethanol as well as other hydroxyl radical-scavenging agents by these various systems is believed to proceed through the formation of a common intermediate, namely, hydrogen peroxide (H2O2), after dismutation of the superoxide anion radical (O2-.). The presence of iron, especially chelated iron, greatly enhances the production of .OH by serving as an oxidant for O2-. or a reductant for H2O2. Experiments were carried out to evaluate the role of iron, the chelating agent, O2-., and H2O2 in the oxidation of ethanol by a variety of in vitro systems (chemical, enzymatic, and intact membrane bound) that can produce oxy radicals via different mechanisms. The generation of .OH by all the systems studied was sensitive to catalase, which indicates that H2O2 is the precursor of .OH. Superoxide radical appears to be the reducing agent in the hypoxanthine-xanthine oxidase system, indicating an iron-catalyzed Haber-Weiss reaction. In the ascorbate, reductase, and microsomal systems, superoxide radical does not appear to be the reducing agent. However, superoxide radical probably is the precursor of H2O2. While iron plays an important role in the production of .OH by the various systems, the effect of iron depends on the nature of the iron chelate.(ABSTRACT TRUNCATED AT 250 WORDS)
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PMID:Ethanol oxidation by hydroxyl radicals: role of iron chelates, superoxide, and hydrogen peroxide. 298 64

Xanthine oxidase (XaO) was injected into the anterior chamber of rabbit eyes by a closed circuit perfusion system. Doses of 1.5 milliunits (mU) or greater produced a maximal leucocyte accumulation after 4 hr, with an initial elevation of ocular pressure in the first 15 min. Similar experiments on rats with intravitreal injections of 0.1-1.5 mU of XaO resulted in a significant accumulation of leucocytes after 5 hr which, at the highest dose of XaO, was partly due to traces of bacterial endotoxin in the XaO. However, in endotoxin-desensitized rats the response to 1.5 milliunits XaO was seven-fold greater than the response to endotoxin alone. Simultaneous administration of xanthine (Xa) substrate with XaO was not required to elicit cell infiltration into the anterior chamber. Dialyzed enzyme was also effective but boiling abolished the response. Addition of XaO to rabbit aqueous humor in vitro decreased the ascorbate content, consistent with the generation of superoxide from an endogenous substrate. The results suggest that enzymatically active XaO, which can cause intraocular generation of superoxide from an XaO substrate present in aqueous humor, initiates the chemotactic response. A chemotactic agent may be generated from superoxide reacting with endogenous precursors in aqueous humor or by selective activation of the lipoxygenase pathway of arachidonic acid metabolism in adjacent tissues.
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PMID:Ocular responses to superoxide generated by intraocular injection of xanthine oxidase. 299 48


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