EC:1.10.3.3 - FACTA Search

Gene/Protein Disease Symptom Drug Enzyme Compound
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Query: EC:1.10.3.3 (ascorbate oxidase)
778 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

A recently developed procedure for the localization of D-amino acid oxidase (D-AAO) has been used to investigate the distribution of this enzyme in rat nervous tissue. Initial studies were carried out on kidney to validate the methods. The cytochemically demonstrable enzyme in kidney is inhibited by kojic acid, a known competitive D-AAO inhibitor. Omission of the catalse inhibitor, aminotriazole, from the cytochemical medium produces a marked diminution of D-AAO reaction product in kidney peroxisomes. This would be expected if catalase and D-AAO are present in the same particles. In brain, kojic acid-inhibitable D-AAO is demonstrable in numerous bodies within astrocytes especially in the cerebellum, a brain region known from biochemistry to contain particularly high levels of the oxidase. In preparations incubated for catalase, far fewer positive bodies are seen in the cerebellum. Moreover, omission of aminotriazole has little evident effect on the D-AAO reaction. Thus, the oxidase-containing cerebellar bodies may be relatively poor in catalse. In contrast, several nervous system cell types that contain relatively numerous catalase-positive bodies, contain none with detectable D-AAO. Such heterogeneity of peroxisome enzyme content is in accord with reports from biochemical studies of brain.
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PMID:Ultrastructural localization of D-amino acid oxidase in microperoxisomes of the rat nervous system. 3 97

This report describes a new specific colorimetric procedure for uric acid assay with AutoAnalyzer II and SMA (Technicon) systems, made specific by the application of uricase. Hydrogen preroxide, formed in this reaction, effects the oxidative coupling of 4-aminophenazone and 2,4-dichlorophenol under the catalytic influence of peroxidase. The red dye formed is measured at 505 or 520 nm. A sample blank measurement is not necessary, and the reagents show very good stability. The test shows linearity up to 714 mumol of uric acid per liter. Results of thie method correlate very well with those by the uricase-ultraviolet and uricase--catalase methods. There is no interference by hemoglobin, bilirubin, lipemia, and various drugs, except a minor interference by alpha-methyldopa. Interference from ascorbate is eliminated by ascorbate oxidase. This method can be regarded as a considerably improved routine test for uric acid on continuous-flow systems in clinical laboratories as compared with the commonly used phosphotungstate method.
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PMID:Determination of uric acid on continuous-flow (AutoAnalyzer II and SMA) systems with a uricase/phenol/4-aminophenazone color test. 62 57

The reaction of beta-N-methylaminoalanine (BMAA) with L-amino acid oxidase (L-AAO) in the presence of catalase yields ammonia and beta-N-methylaminopyruvate, which was trapped as its 2,4-dinitrophenylhydrazone, as products. Incubation of BMAA with L-AAO in the presence of semicarbazide led to the formation of a semicarbazone, indicating intermediate iminium ion formation; when potassium cyanide (5 mM) was added, semicarbazone formation was blocked. The formation of beta-N-methylaminopyruvate was decreased by omission of catalase and was reduced in the presence of hydrogen peroxide (100 mM). These results indicate that BMAA is converted by L-AAO to the corresponding alpha-imino acid, which undergoes hydrolysis to beta-N-methylaminopyruvate. The alpha-keto acid is readily oxidized to N-methylglycine by hydrogen peroxide.
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PMID:Enzymatic reaction of beta-N-methylaminoalanine with L-amino acid oxidase. 204 77

Desferrioxamine (DFO) nearly doubles alkaline phosphatase oxidative inactivation by the ascorbate system. The effect is dependent on ascorbate and desferrioxamine concentrations, exhibiting in both cases a saturation mechanism. Conversion of desferrioxamine to ferrioxamine abolishes the prooxidant action. Desferrioxamine also increases ascorbate-dependent oxygen consumption and nitroblue tetrazolium reduction. Superoxide dismutase, which blocks the desferrioxamine enhancing effect on enzyme inactivation, markedly slows down nitroblue tetrazolium reduction as well as oxygen consumption by ascorbate plus desferrioxamine, while it fails to protect against the ascorbate system alone. Therefore, in the presence of desferrioxamine, the metal-catalyzed ascorbate autooxidation becomes superoxide-dependent and thus inhibitable by superoxide dismutase. Catalase, peroxidase, and ascorbate oxidase protect alkaline phosphatase from inactivation by both ascorbate and ascorbate-desferrioxamine systems. Hemin shields the enzyme from ascorbate plus DFO attack but not from ascorbate alone. In air-saturated solution, desferrioxamine seems to mediate one electron transfer from ascorbate to oxygen, generating superoxide anions, which can either trigger a Fenton reaction or produce desferal nitroxide radicals. In the absence of oxygen, ascorbate alone is ineffective, but the ascorbate plus desferrioxamine system still inactivates the enzyme; catalase, peroxidase, and ascorbate oxidase, but not superoxide dismutase, afford protection.
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PMID:Prooxidant action of desferrioxamine: enhancement of alkaline phosphatase inactivation by interaction with ascorbate system. 215 77

It has been indicated recently that ascorbic acid is responsible for the hemoglobin-mediated oxidative damage to the central nervous system (Sadrzadeh & Eaton, J. Clin. Invest. 82:1510-1515, 1988). In this paper we describe the changes in chemiluminescence accompanying hemoglobin- and ascorbate-dependent oxidative injury to brain tissue. Addition of either hemoglobin (15 microM) or ascorbate (1 or 2 mM) to rat brain homogenates stimulated spontaneous chemiluminescence in a synergistic manner. This increase in chemiluminescence was inhibited by desferrioxamine indicating that free iron was involved in the reactions leading to lipid peroxidation. Preincubation with ascorbate oxidase inhibited both spontaneous and hemoglobin-dependent chemiluminescence, suggesting that ascorbate was required for the reactions leading to lipid peroxidation. Supplementation with aminotriazole (an irreversible inhibitor of the catalase-H2O2 complex) increased chemiluminescence in a time-dependent manner, as catalase reacted with accumulated H2O2, suggesting that ascorbic acid has a dual action being involved in the production of H2O2 and also maintaining Fe in the reduced state to catalyze a Fenton-like reaction. The excited species responsible for the chemiluminescence were partially characterized by adding specific fluorescent energy acceptors: dibromoanthracene (DBA) and diphenylanthracene (DPA). Both DBA and DPA stimulated chemiluminescence several-fold indicating that triplet and singlet species are responsible for the observed chemiluminescence. Excited singlet carbonyls (identified with DPA) may be produced during the collision of two ROO.. Singlet oxygen may also be generated during the same reaction. It decays to the triplet state (emitting chemiluminescence at 634 nm) and reacts with double bonds producing dioxetanes, which may breakdown generating triplet carbonyls (identified with DBA).(ABSTRACT TRUNCATED AT 250 WORDS)
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PMID:Ascorbate- and hemoglobin-dependent brain chemiluminescence. 237 61

Blue light irradiation of 2-deoxyribose (DOR) in the presence of uroporphyrin I (UP), ascorbate (AH-), trace iron, and phosphate buffer resulted in a strong stimulation of hydroxyl radical (OH.)-dependent oxidation of DOR. Photostimulated generation of H2O2 was monitored after removal of residual AH- (i) by ascorbate oxidase treatment, or (ii) by anion exchange on mini-columns of DEAE-Sephadex. Irradiation of the above mixture produced a strong burst of H2O2 which was intensified by desferrioxamine and suppressed by catalase or EDTA. The mechanism suggested by these observations is one in which photoreduction of UP to the radical anion initiates the formation of H2O2, which gives rise to OH. via Fenton chemistry. This is the first known investigation of H2O2 fluxes in a Type I (free radical) photoreaction involving AH- as the electron donor.
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PMID:Light-stimulated formation of hydrogen peroxide and hydroxyl radical in the presence of uroporphyrin and ascorbate. 285 16

Experiments were carried out to evaluate the production of hydroxyl radical-like species by intact rat liver cells by assaying for the production of ethylene from alpha-keto-4-thiomethylbutyric acid in the absence and presence of added iron. In the absence of iron, a low rate of ethylene production, which was not sensitive to superoxide dismutase, catalase, or competitive scavengers was observed. Ethylene was produced when KMBA was incubated with perfusates of rat liver or the suspension medium obtained after incubating liver cells for varying periods of time, followed by removal of the liver cells. Boiling the perfusate or suspension medium had no effect on ethylene production. This ethylene production does not appear to reflect an oxygen radical-mediated event. The addition of ferric-EDTA, but not ferric-desferrioxamine, increased ethylene production by the hepatocyte suspensions in a reaction sensitive to inhibition by catalase, ascorbate oxidase, and competitive scavengers, but not superoxide dismutase. The sensitivity to externally added catalase and ascorbate oxidase suggested that the ethylene production reflected an extracellular oxygen radical generating system. Ferric alone and several ferric chelates, for example, ferric-ATP, ADP, AMP, histidine, and citrate stimulated ethylene production using perfusates of liver or suspension medium after removal of the hepatocytes. The sensitivity of the added iron system to ascorbate oxidase suggested that during perfusion or incubation of liver cells, efflux of ascorbate occurs, followed by reduction of the iron and subsequently, extracellular production of oxygen radicals.(ABSTRACT TRUNCATED AT 250 WORDS)
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PMID:Ethylene production from alpha-keto-4-thiomethylbutyric acid by isolated rat liver cells, suspension medium, and perfusates in the absence and presence of iron. 301 75

Euglena gracilis was found to contain a peroxidase that specifically require L-ascorbic acid as the natural electron donor in the cytosol. The presence of an oxidation-reduction system metabolizing L-ascorbic acid was demonstrated in Euglena cells. Oxidation of L-ascorbic acid by the peroxidase, and the absence of ascorbic acid oxidase activity, suggests that the system functions to remove H2O2 in E. gracilis, which lacks catalase.
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PMID:Metabolism of hydrogen peroxide in Euglena gracilis Z by L-ascorbic acid peroxidase. 676 57

The effect of ascorbic acid on Ca2+ uptake in cultured rat astrocytes was examined in the presence of ouabain and monensin, which are considered to drive the Na(+)-Ca2+ exchanger in the reverse mode. Ascorbic acid at 0.1-1 mM inhibited Na(+)-dependent Ca2+ uptake significantly but not Na(+)-dependent glutamate uptake in the cells, although the inhibition required pretreatment for more than 30 min. The effect of ascorbic acid on the Ca2+ uptake was blocked by simultaneous addition of ascorbate oxidase (10 U/ml). Na(+)-dependent Ca2+ uptake was also inhibited by isoascorbate at 1 mM but not by ascorbate 2-sulfate, dehydroascorbate, and sulfhydryl-reducing reagents such as glutathione and 2-mercaptoethanol. The inhibitory effect of ascorbic acid was observed even in the presence of an inhibitor of lipid peroxidation, o-phenanthroline, or a radical scavenger, mannitol, and the degrading enzymes such as catalase and superoxide dismutase. On the other hand, the inhibitory effect was not observed under the Na(+)-free conditions that inhibited the uptake of ascorbic acid in astrocytes. When astrocytes were cultured for 2 weeks in a medium containing ascorbic acid, the content of ascorbic acid in the cells was increased and conversely Na(+)-dependent Ca2+ uptake was decreased. These results suggest that an increase in intracellular ascorbic acid results in a decrease of Na(+)-Ca2+ exchange activity in cultured astrocytes and the mechanism is not related to lipid peroxidation.
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PMID:Intracellular ascorbic acid inhibits the Na(+)-Ca2+ exchanger in cultured rat astrocytes. 789 Oct 80

Zitter rats develop a genetic spongiform encephalopathy characterized by edematous changes in their brains. In order to elucidate the involvement of reactive oxygen species in this process we examined age-related alterations of the activities of the enzymes which metabolize reactive oxygen species. Activities of superoxide dismutase (SOD), D-amino acid oxidase (D-AAO), glutathione peroxidase (GSH-Px) and catalase in the brain and the liver of zitter rats are compared with those of control SD/J rats. In the brain of adult zitter rats which show degenerative changes, significantly enhanced activities of SOD and D-AAO were obtained, whereas activity of catalase was lower than that of the SD/J rats. Prominent abnormalities in catalase and D-AAO but not in SOD activity were demonstrated before or at the same time as the appearance of the morphological vacuolation in the brain of suckling zitter rats. There was no difference in GSH-Px activity between the brains from zitter and SD/J rats. These results suggest that the alteration of hydrogen peroxide (H2O2)-metabolism in microperoxisomes may play an important role in the initiation of degenerative changes in the brain of zitter rats. Enhanced SOD activity observed in the brain of adult zitter rats may be a compensatory response to the high superoxide anion produced in the course of cell damage caused by the H2O2 stagnation. Also, more SOD might produce more H2O2.
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PMID:Antioxidant enzymes in the brain of zitter rats: abnormal metabolism of oxygen species and its relevance to pathogenic changes in the brain of zitter rats with genetic spongiform encephalopathy. 798 77

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