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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)

We present a method for measuring ascorbic acid in methanol/trichloroacetic acid extracts prepared from human plasma after enzymatic oxidation of ascorbic acid to dehydroascorbic acid by ascorbate oxidase. Samples were assayed by spectrophotometrically monitoring the kinetics of the concentration-dependent absorbance changes of dehydroascorbic acid with phosphate-citrate-methanol buffers. Ascorbic acid was determined as the difference between dehydroascorbic acid and total ascorbic acid content. The detection limit was < 0.5 mumol/L. The calibration curve was linear (r > 0.995) over the range 0-1000 mumol/L. Analytical recovery of ascorbic acid added to plasma was 93-105%. The between-day variance was < 7%. Comparison of the spectrophotometric determination (y) with a chromatographic procedure (x) gave y = 1.02x - 0.653 (Sylx = 3.61) over the range of physiologically relevant concentrations. Total analysis time is < 10 min per sample and allows the simultaneous analysis of multiple samples.
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PMID:Spectrophotometric determination of ascorbic acid and dehydroascorbic acid. 762 94

Differentiated cultures of Caco-2 human colonic cells were used to examine the importance of reduction of nonheme ferric iron, Fe(III), for transport across the brush border surface. Cultures accumulated approximately 100 pmol Fe/(h.mg protein) when 10 mumol Fe(III) as the nitrilotriacetic acid complex (1Fe:2NTA) was added to the apical compartment. Ascorbic acid enhanced cellular acquisition of iron in a dose-dependent manner, with a concentration as low as 8 mumol/L ascorbate increasing iron uptake by 50%. Similarly, the rate of iron transport from the apical to the basolateral compartment increased 5.6- and 30-fold when 100 and 1000 mumol/L ascorbic acid, respectively, were present in the apical chamber. Ascorbate-mediated stimulation of iron uptake was temperature dependent and required the reduction of Fe(III) to Fe(II), because it was inhibited by ascorbate oxidase and chelators of Fe(II). Moreover, Caco-2 cells recycled dehydroascorbic acid to ascorbic acid. Ferricyanide and Fe(II) chelators also partially inhibited iron uptake from a medium devoid of ascorbic acid. Intact Caco-2 cells exhibited a ferrireductase activity on the apical surface that accounted for the majority of iron accumulated by cells incubated in the absence of exogenous reductant. These data suggest that reduction of Fe(III) within the lumen or at the cell surface is required for transfer of this essential micronutrient across the intestinal brush border surface.
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PMID:Reduction of Fe(III) is required for uptake of nonheme iron by Caco-2 cells. 773 89

Helicobacter pylori sonicate was shown to oxidize ascorbic acid. Ascorbic acid oxidation was determined by chromatography combined with electrochemical detection. Water soluble ascorbic acid oxidase activity was rather independent of pH with a pH optimum around 2. By gel filtration the oxidizing activity co-eluted with an absorbency peak at 408 nm. The relative molecular mass (Mr) was approximately 14,000. It is suggested that this oxidating activity was caused by a cytochrome c-like molecule. Ascorbic acid oxidating activity could also be extracted from bacterial membranes by detergents. Gel filtration showed several forms, the major one with a Mr = 19,000. pH optimum was 6-7. Other oxidase-positive bacterial strains like Campylobacter coli, Enterobacter cloacae and Pseudomonas aeruginosa could degrade ascorbic acid. Since ascorbic acid oxidation by Helicobacter pylori whole bacterial lysates has a pH optimum in the acidic range corresponding to pH in gastric fluid, the activity of the cytochrome c-like water soluble oxidant of Helicobacter pylori seems to be primarily important for the destruction of ascorbic acid in the gastric juice of infected patients.
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PMID:Investigation of Helicobacter pylori ascorbic acid oxidating activity. 777 46

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

Phenoxyl radicals are intermediates in the oxidation of phenolic compounds to quinoid derivatives (quinones, quinone methides), which are known to act as ultimate mutagenic, carcinogenic, and cytotoxic agents by directly interacting with macromolecular targets or by generating toxic reactive oxygen species. One-electron reduction of phenoxyl radicals may reverse oxidative activation of phenolic compounds to quinoids, thus preventing their cytotoxic effects. In the present work, we studied interactions of ascorbate, thiols (glutathione, dihydrolipoic acid, and metallothioneins), and combinations thereof with the phenoxyl radical generated by tyrosinase-catalyzed oxidation of VP-16 [etoposide, 4'-demethylepipodophyllotoxin-9-(4,6-O-ethylidene-beta-D-glucop yra noside)], a hindered phenol widely used as an antitumor drug. We found by liquid chromatography-ionspray mass spectrometry and electron spin resonance (ESR) that tyrosinase caused oxidation of VP-16 to its o-quinone and aromatized derivative via intermediate formation of the phenoxyl radical. Both ascorbate and thiols (GSH, dihydrolipoic acid, and metallothioneins) were able to directly reduce the VP-16 phenoxyl radical and prevent its oxidation. The characteristic ESR signal of the VP-16 phenoxyl radical was quenched by the reductants. The semidehydroascorbyl radical ESR signal was detected in the presence of ascorbate; thiols did not produce signals in the ESR spectra. In combinations, ascorbate plus GSH and ascorbate plus metallothionein acted independently and additively in reducing the VP-16 phenoxyl radical. Ascorbate was more reactive: the VP-16-dependent oxidation of GSH or metallothionein commenced only after complete oxidation of ascorbate. The semidehydroascorbyl radical ESR signal preceded the quenching of the VP-16 phenoxyl radical by GSH and metallothionein. In the presence of ascorbate plus dihydrolipoic acid, ascorbate was also more reactive toward the VP-16 phenoxyl radical than dihydrolipoic acid, but the ascorbate concentration was maintained at the expense of its regeneration from dehydroascorbate by dihydrolipoic acid. In ESR spectra, the semidehydroascorbyl radical ESR signal was continuously detected and then was abruptly substituted by the VP-16 phenoxyl radical signal. When VP-16 and tyrosinase were incubated in the presence of retina or hepatocyte homogenates, a two-phase lag period was observed by ESR for the appearance of the VP-16 radical signal: an ascorbate-dependent part (semidehydroascorbyl radical observable, sensitive to ascorbate oxidase) and thiol-dependent part (no radical signals in the spectra, sensitive to mersalyl acid). About 50% of the thiol-dependent part of the lag period could be accounted for by endogenous GSH (as revealed by treatment with GSH peroxidase+cumene hydroperoxide).(ABSTRACT TRUNCATED AT 400 WORDS)
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PMID:Ascorbate is the primary reductant of the phenoxyl radical of etoposide in the presence of thiols both in cell homogenates and in model systems. 806 42

The formation of ascorbate radicals, identified by ESR experiments, was observed in the ascorbate peroxidase reaction by thyroid microsomes. The steady-state concentration of ascorbate radicals decreased in the presence of NADH. The oxidation of NADH was followed optically. Using the ascorbic acid oxidase system, NADH-dependent electron transport in thyroid microsomes was examined. Ascorbate radicals competed with bound cytochrome b5 for the reaction with reduced NADH-cytochrome b5 reductase. The NADH-ascorbate radical reductase activity of thyroid microsomes was calculated to be 0.17 mumol/mg.s at 3.3 microM ascorbate radicals. Kinetic results show that the properties of NADH-cytochrome b5 reductase in thyroid microsomes were similar to those of the enzyme in liver microsomes. The formation of ascorbate radicals by thyroid microsomes was stimulated by the addition of thyroxine, and the stimulation was decreased also by NADH. The thyroxine-mediated oxidation of ascorbate is explained in terms of consecutive one-electron transfers initiated by bound thyroid peroxidase. These results, along with those described in our previous paper (M. Nakamura, I. Yamazaki, and S. Ohtaki, 1990, J. Biochem. 108, 804-810), support the idea that ascorbate protects thyroid hormones from oxidative degradation through the NADH-cytochrome b5 reductase system.
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PMID:Formation and reduction of ascorbate radicals by hog thyroid microsomes. 839 46

Recently, we reported the development of a sensitive continuous spectrophotometric assay for the ascorbate-dependent mammalian enzyme dopamine beta-monooxygenase based on the novel chromophoric electron donor 2-aminoascorbic acid [K. Wimalasena and D.S. Wimalasena (1991) Anal. Biochem. 197, 353-361]. We now report that ascorbate oxidase (EC 1.10.3.3, L-ascorbate:O2 oxidoreductase) also catalyzes the oxidation of 2-aminoascorbic acid to chromophoric 2,2'-nitrilodi-2(2')-deoxy-L-ascorbic acid (red pigment). The reaction is kinetically well behaved, displaying the expected stoichiometry for an oxidase-catalyzed reaction with respect to oxygen and the oxidation product (red pigment), demonstrating that 2-aminoascorbic acid is a well-behaved alternative substrate for the enzyme. Ascorbate oxidase is a very efficient enzyme toward its natural substrate, ascorbic acid. Although 2-amino-ascorbic acid is a significantly weak substrate for the enzyme in comparison to ascorbic acid, as indicated by the apparent initial rate kinetic parameters, the high extinction coefficient of the red pigment under our assay conditions suggests that this novel reactivity of the enzyme could be used to design a sensitive, convenient, and continuous spectrophotometric assay for ascorbate oxidase. While this assay is more convenient than the existing oxygen monitor assay, its adaptability to measure the activity of the enzyme in the immobilized form may be helpful in the development of technologies for the automated detection of ascorbic acid in biological fluids for industrial or clinical applications. In addition, this novel reactivity of the enzyme may be used to examine the substrate specificity and the mechanism of action of the enzyme.
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PMID:Continuous spectrophotometric assay for ascorbate oxidase based on a novel chromophoric substrate, 2-aminoascorbic acid. 848 25

Ole e 1, the major allergen from olive pollen, is a glycoprotein containing a single Asn-linked glycan moiety. Rabbit antiserum against this protein has been obtained; and its immunologic cross-reactivities in Western blotting with ascorbate oxidase, horseradish peroxidase, bromelain, ovalbumin, and honeybee venom phospholipase A2 have been studied. Ascorbate oxidase, peroxidase, and bromelain are recognized by the Ole e 1 antiserum. When these three proteins are deglycosylated by periodate treatment, such an immunologic reaction does not occur. The relative affinities of these proteins have been analyzed by direct and inhibition ELISA experiments. A commercially available antibody against horseradish peroxidase has also been considered in these studies. This antibody reacts with Ole e 1 but not with the periodate-deglycosylated allergen. Horseradish peroxidase, bromelain, and ascorbate oxidase are recognized by the IgE of sera from patients who are hypersensitive to olive tree pollen. This binding is also abolished by periodate treatment. The results are interpreted in terms of the presence of an epitope in the carbohydrate moiety of Ole e 1, which would contain a xylose involved in recognition by both IgE and IgG antibodies.
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PMID:Cross-reactivity between the major allergen from olive pollen and unrelated glycoproteins: evidence of an epitope in the glycan moiety of the allergen. 864 22

Ascorbate oxidase from the fungus Acremonium sp. HI-25 is a copper-containing glycoprotein that catalyzes the oxidation of ascorbic acid to dehydroascorbic acid. Monosaccharide composition analysis showed that the enzyme contains exclusively N-linked oligosaccharide chains. Following liberation by hydrazinolysis/re-N-acetylation, and fractionation by HPLC on anion exchange. Amide-80 and/or octadecyl silica columns after derivatization with p-aminobenzoic ethyl ester, the structures of the twelve major neutral oligosaccharides were identified by FAB-MS, 400 MHz 1H-NMR, methylation analysis, mild acid hydrolysis, and/or sequential exoglycosidase digestions. Acremonium sp. ascorbate oxidase was found to consist of high-mannose type oligosaccharides (76.3%) having 4 to 9 mannose residues and a series of novel D-galactofuranose-containing high-mannose type oligosaccharides (18.6%) with the following structure.
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PMID:Novel beta-D-galactofuranose-containing high-mannose type oligosaccharides in ascorbate oxidase from Acremonium sp. HI-25. 878 8

Ascorbic acid can recycle alpha-tocopherol from the tocopheroxyl free radical in lipid bilayers and in micelles, but such recycling has not been demonstrated to occur across cell membranes. In this work the ability of intracellular ascorbate to protect and to recycle alpha-tocopherol in intact human erythrocytes and erythrocyte ghosts was investigated. In erythrocytes that were 80% depleted of intracellular ascorbate by treatment with the nitroxide Tempol, both 2,2'-azobis(2-amidinopropane) dihydrochloride (AAPH) and ferricyanide oxidized alpha-tocopherol to a greater extent than in cells not depleted of ascorbate. In contrast, in erythrocytes in which the intracellular ascorbate concentration had been increased by loading with dehydroascorbate, loss of alpha-tocopherol was less with both oxidants than in control cells. Protection against AAPH-induced oxidation of alpha-tocopherol was not prevented by extracellular ascorbate oxidase, indicating that the protection was due to intracellular and not to extracellular ascorbate. Incubation of erythrocytes with lecithin liposomes also generated an oxidant stress, which caused lipid peroxidation in the liposomes and depleted erythrocyte alpha-tocopherol, leading to hemolysis. Ascorbate loading of the erythrocytes delayed liposome oxidation and decreased loss of alpha-tocopherol from both cells and from alpha-tocopherol-loaded liposomes. When erythrocyte ghosts were resealed to contain ascorbate and challenged with free radicals generated by AAPH outside the ghosts, intravesicular ascorbate was totally depleted over 1 h of incubation, whereas alpha-tocopherol decreased only after ascorbate was substantially oxidized. These results suggest that ascorbate within the erythrocyte protects alpha-tocopherol in the cell membrane by a direct recycling mechanism.
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PMID:Protection and recycling of alpha-tocopherol in human erythrocytes by intracellular ascorbic acid. 944 16

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