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 reactions of various chromate pigments and ascorbate were investigated by an ESR spin trapping technique. Production of Cr(V) was detected directly and productions of very electrophilic reactive oxygen species (ROS) was detected via the oxidation of formate. We demonstrated previously that both dissolved oxygen and Cr (V) were essential in the production of ROS in this system, and that ROS production was inhibited by catalase. We studied here the effect of solubility of different chromate pigments: sodium, calcium, strontium, basic zinc, basic lead supported on silica, and lead and barium chromates on the production of ROS in buffered medium and cell culture medium (Dublecco's Modified Eagle medium + fetal calf serum). Sodium, calcium, basic zinc, and basic lead chromates were active in the production of ROS in presence of cell culture medium, whereas lead and barium chromates were inactive.
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PMID:Reactive oxygen species produced from chromate pigments and ascorbate. 784 6

Using ESR, a weak signal identified as the ascorbate free radical was observed in fresh cow's milk. The signal was unchanged after storage at 5 degrees C for 24 h but disappeared after storage at 25 degrees C. A marked increase in the steady-state ascorbate radical concentration was observed with the addition of H2O2 or xanthine; the increase was abolished in the presence of azide. Based on the xanthine-oxygen reductase activity and 2,2'-azino-di-(3-ethylbenzthiazoline-6-sulfonic acid) peroxidase activity, cow's milk contains 0.45 microM xanthine oxidase and 0.32 microM lactoperoxidase. The results suggest that H2O2- and xanthine-induced ascorbate radical formation was due to the ascorbate peroxidase activity of lactoperoxidase in cow's milk.
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PMID:Ascorbate radicals in fresh cow's milk. 785 81

Peroxynitrite [O = NOO-, oxoperoxonitrate(1-)bd is a strong oxidant that may be formed in vivo by the reaction of O2.- and NO(.). Oxoperoxonitrate(1-) reacts with molecules in aqueous acidic solutions via pathways that involve the highly reactive hydrogen oxoperonitrate either as an intermediate in a first-order reaction or as a reactive agent in a simple second-order reaction. ESR experiments show that hydrogen oxoperoxonitrate oxidizes monohydrogen L-ascorbate by one electron: when mixed at pH ca. 5 and passed through a flow cell within 0.1 s, the two-line ESR signal of the ascorbyl radical anion (aH = 0.18 T, g = 2.005) is observed. The overall stoichiometry of the reaction was 1 mol of ascorbate oxidized per mol of oxoperoxonitrate(1-) added. The kinetics of the reaction were studied over the pH range 4.0-7.5 by stopped-flow spectrometry. Hydrogen oxoperoxonitrate, observed between 300 and 350 nm, and the oxoperoxonitrate(1-) anion, at 302 nm, disappear faster than predicted for the first-order isomerization to NO3-. The rate increases from pH 4 to 5.8, and then decreases with increasing pH. The rate variation suggests a bimolecular reaction either between the oxoperoxonitrate(1-) anion and ascorbic acid or between hydrogen oxoperoxonitrate and the monohydrogen ascorbate anion. Although the two pathways are kinetically indistinguishable, the pKa values of ascorbic acid and hydrogen oxoperoxonitrate strongly suggest that the reacting species are hydrogen oxoperoxonitrate and monohydrogen ascorbate. The second-order rate constant for this reaction is 235 +/- 4 M-1s-1 at 25 degrees C.(ABSTRACT TRUNCATED AT 250 WORDS)
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PMID:The kinetics of the oxidation of L-ascorbic acid by peroxynitrite. 789 75

Antioxidant reactions of mixtures of vitamin E, vitamin C and phospholipids in autoxidizing lipids at 90 degrees C have been studied by ESR spectroscopy. When the phospholipid contained a tertiary amine (e.g. phosphatidylcholine), the vitamin C and the vitamin E radicals were successively observed as these two vitamins were sequentially oxidised during lipid oxidation. In the presence of the primary amine contained in phosphatidylserine, the vitamin E oxidation was delayed for a few hours. In this case neither the vitamin C, nor the vitamin E radicals but a nitroxide radical derived from the phospholipid was observed. Similar results to those obtained with PS were obtained in the presence of either phosphatidylethanolamine or soybean lecithin. The participation in the radical reactions of phospholipids possessing a primary amine can therefore explain the synergistic effect of these phospholipids in a mixture of vitamins E and C.
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PMID:Radical exchange reactions between vitamin E, vitamin C and phospholipids in autoxidizing polyunsaturated lipids. 788 50

The one-electron reduction of vanadate (vanadium(V)) by ascorbate and related free radical generation at physiological pH was investigated by ESR and ESR spin trapping. The spin trap used was 5,5-dimethyl-1-pyrroline N-oxide (DMPO). Incubation of vanadium(V) with ascorbate generated significant amounts of vanadium(IV) in phosphate buffer (pH 7.4) but not in sodium cacodylate buffer (pH 7.4) nor in water. The vanadium(IV) yield increased with increasing ascorbate concentration, reaching a maximum at a vanadium(V): ascorbate ratio of 2:1. Addition of formate to the incubation mixture containing vanadium(V), ascorbate, and phosphate generated carboxylate radical (.COO-), indicating the formation of reactive species in the vanadium(V) reduction mechanism. In the presence of H2O2 a mixture of vanadium(V), ascorbate, and phosphate buffer generated hydroxyl radical (.OH) via a Fenton-like reaction (vanadium(IV)+H2O2-->vanadium(V)+.OH+OH-). The .OH yield was favored at relatively low ascorbate concentrations. Omission of phosphate sharply reduced the .OH yield. The vanadium(IV) generated by ascorbate reduction of vanadium(V) in the presence of phosphate was also capable of generating lipid hydroperoxide-derived free radicals from cumene hydroperoxide, a model lipid hydroperoxide. Because of the ubiquitous presence of ascorbate in cellular system at relatively high concentrations, one-electron reduction of vanadium(V) by ascorbate together with phosphate may represent an important vanadium(V) reduction pathway in vivo. The resulting reactive species generated by vanadium(IV) from H2O2 and lipid hydroperoxide via a Fenton-like reaction may play a significant role in the mechanism of vanadium(V)-induced cellular injury.
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PMID:One-electron reduction of vanadate by ascorbate and related free radical generation at physiological pH. 805 39

Etoposide (VP-16) is an antitumor drug currently in use for the treatment of a number of human cancers. Mechanisms of VP-16 cytotoxicity involve DNA breakage secondary to inhibition of DNA topoisomerase II and/or direct drug-induced DNA strand cleavage. The VP-16 molecule contains a hindered phenolic group which is crucial for its antitumor activity because its oxidation yields reactive metabolites (quinones) capable of irreversible binding to macromolecular targets. VP-16 phenoxyl radical is an essential intermediate in VP-16 oxidative activation and can be either converted to oxidation products or reduced by intracellular reductants to its initial phenolic form. In the present paper we demonstrate that the tyrosinase-induced VP-16 phenoxyl radical could be reduced by ascorbate, glutathione (GSH) and dihydrolipoic acid. These reductants caused a transient disappearance of a characteristic VP-16 phenoxyl radical ESR signal which reappeared after depletion of the reductant. The reductants completely prevented VP-16 oxidation by tyrosinase during the lag-period as measured by high performance liquid chromatography; after the lag-period VP-16 oxidation proceeded with the rate observed in the absence of reductants. In homogenates of human K562 leukemic cells, the tyrosinase-induced VP-16 phenoxyl radical ESR signal could be observed only after a lag-period whose duration was dependent on cell concentration; VP-16 oxidation proceeded in cell homogenates after this lag-period. In homogenates of isolated nuclei, the VP-16 phenoxyl radical and VP-16 oxidation were also detected after a lag-period, which was significantly shorter than that observed for an equivalent amount of cells. In both cell homogenates and in nuclear homogenates, the duration of the lag period could be increased by exogenously added reductants. The duration of the lag-period for the appearance of the VP-16 phenoxyl radical signal in the ESR spectrum can be used as a convenient measure of cellular reductive capacity. Interaction of the VP-16 phenoxyl radical with intracellular reductants may be critical for its metabolic activation and cytotoxic effects.
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PMID:Tyrosinase-induced phenoxyl radicals of etoposide (VP-16): interaction with reductants in model systems, K562 leukemic cell and nuclear homogenates. 816 27

Ca(2+)-release channel or ryanodine receptor is known to be involved in physiologic Ca(2+)-release from sarcoplasmic reticulum in skeletal and cardiac muscle. A variety of chemical oxidants and in particular SH-oxidizing reagents have been shown to activate Ca2+ release. However, the role of the oxidative modification of the channel in the physiologic mechanism(s) of Ca2+ release and in pathologic states of the muscle remains to be elucidated. Ascorbate/iron redox couple is known to be an efficient generator of oxygen radicals and semidehydroascorbyl radicals. Ascorbate/iron was shown to be released from cardiomyocytes during ischemia-reperfusion and was suggested to be involved in the ischemia-reperfusion injury and cardiomyocyte death. To understand the potential contribution of ascorbate/iron to Ca2+ release mechanism(s), calcium release channels from skeletal sarcoplasmic reticulum (SR) were reconstituted in artificial planar bilayers to examine the effects of this redox couple on the channel activity. Ascorbate elicited a transient (about 2 min) but dramatic increase of open-time probability of the channel. At pCa = 7.0, the presence of EGTA blocked ascorbate induced activation of release channels. However, when exogenous iron was added, ascorbate activated Ca2+ release channels, even in the presence of EGTA. ESR measurements demonstrated that semidehydroascorbyl radicals were generated from ascorbate in the absence of EGTA. The semidehydroascorbyl radical ESR signal was quenched by EGTA in the absence (but not in the presence) of exogenous iron. Thus, the production of ascorbyl radicals was associated with increased channel activity. In the presence of heparin, ascorbate plus iron elicited a long-lasting activation of the channel which had conductance gCa2+ = 100 pS characteristic for the ryanodine receptor and which could be blocked by the ryanodine channel inhibitor, ruthenium red. In conclusion the physiologically relevant redox couple--ascorbate/iron--at physiologic concentrations can activate Ca2+ channels in sarcoplasmic reticulum vesicles.
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PMID:Ascorbate/iron activates Ca(2+)-release channels of skeletal sarcoplasmic reticulum vesicles reconstituted in lipid bilayers. 831 55

The exposure of DNA to H2O2 in the presence of Cu(II) and a reducing agent is known to result in the induction of a variety of oxidative lesions, including DNA strand breaks and base modifications. Since the reducing agent glutathione occurs in cell nuclei at relatively high concentrations, and copper exists in nuclei associated with chromatin, the present study was undertaken to evaluate the ability of GSH to promote copper-mediated free radical damage to DNA. When compared with ascorbate, GSH was found to be inefficient in the promotion of damage to DNA. Parallel ESR spin trapping measurements indicated that GSH inhibits free radical formation by copper ions in the presence of H2O2, ascorbate, and DNA. The protective effect of GSH is attributed to its stabilization of copper in the +1 oxidation state, thereby compromising its ability to participate in free radical generating reactions. Consequently, it is suggested that the GSH in cell nuclei serves to prevent, rather than promote, copper-dependent damage to DNA. In contrast, in the presence of 1,10-phenanthroline, GSH stimulated free radical formation and DNA damage. This is attributed to the failure of GSH to remove copper(I) from 1,10-phenanthroline. Therefore, under these conditions, GSH serves primarily to redox cycle the reactive 1,10-phenanthroline-copper complex.
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PMID:Effects of glutathione and chelating agents on copper-mediated DNA oxidation: pro-oxidant and antioxidant properties of glutathione. 832 75

The pyridoindole derivative stobadine [(-)-cis-2,8-dimethyl-2,3,4,4a,5,9b-hexahydro-1H-pyrido(4,3b)indole] has been described as a drug with antihypoxic and antiarrhythmic cardioprotective properties. Here its reactivity with peroxyl radicals in liposomes using a lipid-soluble azo-initiator of peroxyl radicals, 2,2'-azo-bis(2,4-dimethyl-valeronitrile) (AMVN), was examined. Stobadine exerted scavenging as evidenced by the inhibition of: (i) cis-parinaric acid fluorescence decay (half-maximal effect at 20 microM), or (ii) luminol-sensitized chemiluminescence (half-maximal effect at 33 microM). In rat liver microsomes, stobadine was equally efficient in inhibiting lipid peroxidation induced by lipid-soluble (AMVN) or water-soluble 2,2'-azo-bis(2-aminopropane)-HCl (AAPH), azo-initiators of peroxyl radicals with half-maximal effect at 17 microM. Stobadine partitions in a two-phase system (octanol-water) with the coefficient log P = 0.57 +/- 0.03, explaining its ability to quench peroxyl radicals in both lipid and aqueous phases. Stobadine is not an efficient scavenger of superoxide radicals. The second order rate constant for the reaction of stobadine with superoxide was estimated to be 7.5 x 10(2) M-1 sec-1 as measured by superoxide-induced lucigenin-amplified chemiluminescence. ESR measurements showed that stobadine in liposomes does not reduce the chromanoxyl radical of a vitamin E homologue with a 6-carbon side-chain, 2,5,7,8-tetramethyl-2-(4'-methylpentyl)chroman-6-ol(chromanol++ +-alpha-C6), in agreement with pulse-radiolysis results obtained using Trolox in homogeneous solution (Steenken et al., Chem Res Toxicol 5: 355-360, 1992). Stobadine increased the magnitude of the chromanoxyl and ascorbyl radical ESR signal generated by lipoxygenase+arachidonate. This was interpreted to be due to the interaction of stobadinyl radicals with the chromanol ring and ascorbate, respectively. It is suggested that high reactivity of stobadine radicals requires the presence of reducing antioxidants (vitamin E, vitamin C) to exhibit its antioxidant effects in physiological systems.
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PMID:Interaction of the pyridoindole stobadine with peroxyl, superoxide and chromanoxyl radicals. 838 64

Vitamin E, the major lipid chain-breaking antioxidant in erythrocyte membranes, is present in low concentration, suggesting that mechanisms should exist to protect against its loss. Enzymatic pathways for the recycling of vitamin E from its tocopheroxyl radical have been observed previously in inner membranes of mitochondria and microsomes. These pathways use electron transport enzymes and their substrates to regenerate vitamin E. Erythrocyte membranes also contain significant NADH-cytochrome c reductase activity, as well as cytochrome b5, the function of which is not yet known. Using an enzymatic oxidation system composed of lipoxygenase and arachidonic acid, free radicals were produced in human erythrocyte membranes, and their reaction with chromanols was followed by ESR and high performance liquid chromatography (HPLC). Since the endogenous vitamin E content of the membranes is very low, we used a vitamin E homologue lacking the hydrocarbon chain (2,2,5,7,8-pentamethyl-6-hydroxychromane) as a probe molecule for ESR measurements. However, parallel HPLC determinations of lipid hydroperoxides and of endogenous vitamin E confirmed the results obtained by ESR. It was found that protection against the loss of vitamin E can be provided either by NADH-cytochrome b5-dependent enzymatic recycling or by a nonenzymatic pathway involving ascorbate and dihydrolipoic acid.
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PMID:Vitamin E recycling in human erythrocyte membranes. 838 77

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