DrugBank:EXPT00568 - FACTA Search

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Query: DrugBank:EXPT00568 (ascorbate)
23,072 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

The comparative study of the antiradical activity of carnosine and vitamin C was carried out by the means of the evaluation of quenching of ESR signals of 2,2-diphenyl-1-picrylhydrazyl (DFPH) and semiquinone radical of alpha-tocopherol. It was shown that carnosine is not able to quench the ESR signals of the stable radical of DFPH and semiquinone radical of alpha-tocopherol. It permits to conclude that: a) carnosine does not interact directly with highly active free radicals; b) carnosine is unable to regenerate the radical of alpha-tocopherol to form the antiradical synergistic couple. The data obtained are consistent with the idea that there is a difference between on the antioxidant mechanism action of vitamin C and carnosine due to the difference in the antiradical activity of these compounds.
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PMID:[Mechanism of antioxidant action of carnosine]. 187 59

The acetaminophen phenoxyl radical was generated by the oxidation of acetaminophen by horseradish peroxidase in a fast-flow ESR experiment, and its reaction with glutathione and ascorbate was studied. Glutathione reduces the phenoxyl radical of acetaminophen to regenerate acetaminophen and form the thiyl radical of glutathione. This thiyl radical reacts with the thiolate anion of glutathione to form the disulfide radical anion, which was detected and characterized by ESR spectroscopy. In the presence of ascorbate, the ascorbyl radical was produced by the reduction of the acetaminophen phenoxyl radical by ascorbate. This reaction results in the complete reduction of the free radical of acetaminophen, whereas the glutathione reduction of the phenoxyl radical of acetaminophen was not complete on the fast-flow ESR time scale of milliseconds. This suggests that ascorbate rather than glutathione is more likely to react with the acetaminophen phenoxyl free radical in vivo. In the presence of both ascorbate and higher concentrations of glutathione, the reaction with ascorbate is dominant. When cysteine was used in the place of reduced glutathione in the above assay system, the disulfide radical anion of cystine was observed in a manner similar to glutathione. These reactions may have significance in the detoxification of acetaminophen and the free radical metabolites of xenobiotics in general. Only in cells containing low levels of ascorbate can glutathione play a direct role in the detoxification of the acetaminophen phenoxyl radical.
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PMID:Glutathione and ascorbate reduction of the acetaminophen radical formed by peroxidase. Detection of the glutathione disulfide radical anion and the ascorbyl radical. 215 16

Guaiacol peroxidase from spinach catalyzes the oxidation of p-aminophenol to produce the aminophenoxy radical as the primary product which is converted further into a stable oxidation product with an absorption peak at 470 nm. The p-aminophenol radicals oxidize ascorbate (AsA) to produce monodehydroascorbate radicals. Kinetic analysis indicates that p-aminophenol radicals also oxidize monodehydroascorbate to dehydroascorbate. Incubation of AsA peroxidase from tea leaves and hydrogen peroxide with p-aminophenol, p-cresol, hydroxyurea, or hydroxylamine results in the inactivation of the enzyme. No inactivation of the enzyme was found upon incubation of the enzyme with these compounds either in the absence of hydrogen peroxide or with the stable oxidized products of these compounds. The enzyme was protected from inactivation by the inclusion of AsA in the incubation mixture. The radicals of p-aminophenol and hydroxyurea were produced by AsA peroxidase as detected by their ESR signals. These signals disappeared upon the addition of AsA, and the signal characteristic of monodehydroascorbate was found. Thus, AsA peroxidase is inactivated by the radicals of p-aminophenol, p-cresol, hydroxyurea, and hydroxylamine which are produced by the peroxidase reaction, and it is protected from inactivation by AsA via the scavenging of the radicals. Thus, these compounds are the suicide inhibitors for AsA peroxidase. Isozyme II of AsA peroxidase, which is localized in chloroplasts, is more sensitive to these compounds than isozyme I. In contrast to AsA peroxidase, guaiacol peroxidase was not affected by these various compounds, even though each was oxidized by it and the corresponding radicals were produced.
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PMID:Hydroxyurea and p-aminophenol are the suicide inhibitors of ascorbate peroxidase. 215 59

The reactive oxygen radicals produced from human polymorphonuclear leukocytes (PMN) stimulated with PMA (phorbol myristate acetate), hydroxyl radicals generated by a Fenton reaction, and superoxide anion radicals produced by irradiating solutions of riboflavin in the presence of EDTA have been taken as the models for production of oxygen radicals. With the use of the electron spin resonance spin trapping method, the scavenging effects of schizandrol A (solA) (5 x 10(-4) M) and schizandrin B (sinB) (5 x 10(-4) M) have been studied and compared with the effects of vitamin E (5 x 10(-4) M) and vitamin C (5 x 10(-4) M). It has been found that in cell system the scavenging effects of sinB and solA, as judged by ESR spin trappings, on hydrpxyl radicals (.OH) are greater than vitamin E and vitamin C and the scavenging effects on superoxide anion (O2) are greater than vitamin E but lower than vitamin C. With respect to the Fenton reaction, sinB has the strogest scavenging effect on .OH (77%) and solA has strong scavenging effect on .OH (63%), both of them larger than that of vitamin E (35%) and vitamin C (56%). In the riboflavin/EDTA system, the scavenging effect of sinB (46%) is smaller than that of vitamin C (96%) but larger than that of vitamin E (23%); the scavenging effect of solA is not obvious (14%). With the use of spin probe oximetry, the oxygen consumption during the respiratory burst of stimulated PMN has been measured when exposed to schizandrins. The experiment results demonstrated that they do not affect the activity of production of active oxygen radicals in the respiratory burst of PMN stimulated with PMA.
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PMID:Scavenging effect of schizandrins on active oxygen radicals. 215 32

The lipophilic o-naphthoquinones beta-lapachone, 3,4-dihydro-2-methyl-2-ethyl-2H-naphtho[1,2b]pyran-5,6-dione (CG 8-935), 3,4-dihydro-2-methyl-2-phenyl-2H-naphtho[1,2b]pyran-5,6-dione (CG 9-442), and 3,4-dihydro-2,2-dimethyl-9-chloro-2H-naphtho[1,2b]pyran-5,6-dione (CG 10-248) (a) inhibited NADPH-dependent, iron-catalyzed microsomal lipid peroxidation; (b) prevented NADPH-dependent cytochrome P-450 destruction; (c) inhibited microsomal aniline 4-hydroxylase, aminopyrine N-demethylase and 7-ethoxycoumarin deethylase; (d) did not inhibit the ascorbate- and tert-butyl hydroperoxide-dependent lipid peroxidation and the cumenyl hydroperoxide-linked aniline 4-hydroxylase reaction; and (e) stimulated NADPH oxidation, superoxide anion radical generation and Fe(III)ADP reduction by NADPH-supplemented microsomes. In the presence of ascorbate, the same o-naphthoquinones stimulated oxygen uptake and semiquinone formation, as detected by ESR measurements. The p-naphthoquinones alpha-lapachone and menadione were relatively less effective than the o-naphthoquinones. These observations support the hypothesis that, in the micromolar concentration range, o-naphthoquinones inhibit microsomal lipid peroxidation and cytochrome P-450-catalyzed reactions, by diverting reducing equivalents from NADPH to dioxygen.
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PMID:Inhibition of microsomal lipid peroxidation and cytochrome P-450-catalyzed reactions by beta-lapachone and related naphthoquinones. 215 43

Nine main organs in the mouse were studied by ESR spectroscopy at 77K. Manganese ions were readily detected in the pancreas, small intestine, stomach and kidney. In particular, the pancreas gave strong ESR signals for the transition metal, suggesting that Mn(II) plays an important role in pancreatic function. All organs reveal different ESR spectra indicating organ specificity. C-centered radical, R-OO radical and C0Q10 or ascorbate radical are stable in the tissue. In the brain, heart and pancreas, N-centered radical heme-NO adduct was detected at 6 and 24 h after excision since common process is involved in tissue degeneration and ESR is sensitive to proteolysis and necrosis of tissues. In endotoxemia and/or CDE-diet-induced pancreatic lesions, R-OO radical and Mn(II) ion were detected in the signal at 77K. By the spin-trapping method (DMPO) at 25 degrees C, DMPO-OH adduct and 3-Line and 6-Line were detected in CDE diet-induced acute pancreatitis. These results suggest that damaged pancreatic tissues are in a highly oxidative environment that probably contains oxygen radicals, and that free radicals are considered to play an important role in the development of pancreatic lesions.
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PMID:[Organ specific ESR features in mouse main organs and ESR application to the model of pancreatic disorders]. 215 46

Hindered phenols are widely used food preservatives. Their pharmacological properties are usually attributed to high antioxidant activity due to efficient scavenging of free radicals. Butylated hydroxytoluene (BHT) and butylated hydroxyanisole (BHA) also cause tissue damage. Their toxic effects could be due to the production of phenoxyl radicals. If phenoxyl radicals can be recycled by reductants or electron transport, their potentially harmful side reactions would be minimized. A simple and convenient method to follow phenoxyl radical reactions in liposomes and rat liver microsomes based on an enzymatic (lipoxygenase + linolenic acid) oxidation system was used to generate phenoxyl radicals from BHT and its homologues with substitutents in m- and p-positions. Different BHT-homologues display characteristic ESR signals of their radical species. In a few instances the absence of phenoxyl radical ESR signals was found to be due to inhibition of lipoxygenase by BHT-homologues. In liposome or microsome suspensions addition of ascorbyl palmitate resulted in disappearance of the ESR signal of phenoxyl radicals with concomittant appearance of the ascorbyl radical signal. After exhaustion of ascorbate, the phenoxyl radical signal reappears. Comparison of the rates of ascorbyl radical decay in the presence or absence of BHT-homologues showed that temporary elimination of the phenoxyl radical ESR signal was due to their reduction by ascorbate. Similarly, NADPH or NADH caused temporary elimination of ESR signals as a result of reduction of phenoxyl radicals in microsomes. Since ascorbate and NADPH might generate superoxide in the incubation system used, SOD was tested. SOD shortened the period, during which the phenoxyl radicals ESR signal could not be observed. Both ascorbyl palmitate and NADPH exerted sparing effects on the loss of BHT-homologues during oxidation. These effects were partly diminished by SOD. These data indicate that reduction of phenoxyl radicals was partly superoxide-dependent. It is concluded that redox recycling of phenoxyl radicals can occur by intracellular reductants like ascorbate and microsomal electron transport.
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PMID:Generation and recycling of radicals from phenolic antioxidants. 216 53

Catalytic transition metals are an absolute requirement for the aerobic oxidation of ascorbate monoanion. Thus, for example, the concentration of iron can be determined by the metal-dependent rate of ascorbate oxidation in near-neutral solutions. The lower limit of detection of iron, as Fe(III)EDTA, by monitoring the decrease in absorbance at 265 nm of ascorbate is about 200 nM. However, by measuring the concentration of the ascorbyl radical by ESR spectroscopy the lower limit is about 10 nM. Using these assays, I have shown that the typical microliter laboratory syringe can introduce significant iron into solutions. Thus, for studies involving iron, these two tests can be used to determine the amount of contaminating iron in reagents as well as iron from other sources such as laboratory equipment.
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PMID:Ascorbate oxidation: UV absorbance of ascorbate and ESR spectroscopy of the ascorbyl radical as assays for iron. 216 85

The oxidation mechanism of Trolox C (a vitamin E analogue) by peroxidases was examined by stopped flow and ESR techniques. The results revealed that during the oxidation of Trolox C, peroxidase Compound II was the catalytic intermediate. The rate constants for the reaction of Compound II with Trolox C, which should be the rate-determining step, were estimated to be 2.1 X 10(4) and 7.2 X 10(3) M-1.s-1 for horseradish peroxidase and lactoperoxidase, respectively, at pH 6.0. The formation of the Trolox C radical was followed by ESR. The time course of the signal was similar to that of the optical absorbance changes at 440 nm, assigned as the peak of the Trolox C radical. The signal exhibited a hyperfine structure characteristic of phenoxyl radicals. From an estimation of the radical concentration in the steady state and the velocity of the radical formation, the dismutation constant was calculated to be 5 X 10(5) M-1.s-1. The concentration of the signal in the steady state was reduced by the addition of GSH. The spectrum changed from that of the Trolox C radical to that of the ascorbate radical when the reaction was carried out in the presence of ascorbate.
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PMID:One-electron oxidation of Trolox C (a vitamin E analogue) by peroxidases. 217 26

Several structurally related ortho-naphthoquinones isolated from Mansonia altissima Chev (mansonones C, E and F) (a) inhibited NADPH-dependent, iron-catalyzed microsomal lipid peroxidation; (b) prevented NADPH-dependent cytochrome P450 destruction; (c) inhibited NADPH-supported aniline 4-hydroxylase activity; (d) inhibited Fe(III)ADP reduction by NADPH-supplemented microsomes; (e) stimulated superoxide anion generation by NADPH-supplemented microsomes; and (f) stimulated ascorbate oxidation. ESR investigation of ascorbate-reduced mansonone F demonstrated semiquinone formation. Mansonone C had a greater effect than mansonones E and F on NADPH-dependent lipid peroxidation, O2- production and ascorbate oxidation, whereas mansonone E was more effective than mansonones C and F on aniline 4-hydroxylase activity. Mansonones E and F did not inhibit hydroperoxide-dependent lipid peroxidation, cytochrome P450 destruction or microsomal aniline 4-hydroxylase activity. Mansonone C inhibited to a limited degree tert-butyl hydroperoxide-dependent lipid peroxidation, this inhibition being increased by NADPH. Mansonone A, a tetrahydro orthonapthoquinone derivative, was in all respects relatively less effective than mansonones C, E and F. It is postulated that mansonones C, E and F inhibited microsomal lipid peroxidation and cytochrome P450 catalyzed reactions by diverting reducing equivalents from NADPH to dioxygen, but mansonone C (including its reduced form) may also exert direct antioxidant activity.
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PMID:Effects of mansonones on lipid peroxidation, P450 monooxygenase activity, and superoxide anion generation by rat liver microsomes. 217 28

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