DrugBank:EXPT00568 - FACTA Search

Gene/Protein Disease Symptom Drug Enzyme Compound
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Query: DrugBank:EXPT00568 (ascorbate)
23,072 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

The mechanism by which lipid peroxidation progresses has been known for years, but there is disagreement regarding the mode of its initiation. The aim of this study was to examine: (a) the role of endogenous iron in the initiation of ascorbate-induced lipid peroxidation in microsomal and liposomal membranes; (b) the role of oxygen-free radicals in this process; and (c) the redox state of ascorbate during the course of lipid peroxidation. Ascorbate-induced lipid peroxidation was assessed by measuring hydroperoxide and thiobarbituric acid reactive substances (TBARS) formation in membranes after incubation in Tris-HCl buffer (pH 7.4) for 15 min. To confirm the role of endogenous iron and oxygen-free radicals, the effect of iron chelating agents (EDTA and thiourea) and radical scavengers (benzoate, mannitol, catalase and SOD) on lipid peroxidation was examined. Spectrophotometric measurements and ESR spectra have made it possible to determine ascorbate concentration and its redox state. Ascorbate promoted lipid peroxidation in both rat liver microsomes and liposomes without addition of exogenous iron. Iron chelating agents such as EDTA and thiourea inhibited lipid peroxidation, while SOD, catalase, mannitol and benzoate had no effect. The addition of 5 microM Fe2+ (or Fe3+) to the incubation mixture did not significantly alter hydroperoxide production, but that of TBARS was increased. Lipid peroxidation significantly altered the fatty acid profile in microsomes and liposomes, the most affected being the C20:4 and C22:6 species. Ascorbate in Tris-HCl buffer (pH 7.4) autoxidized very slowly. Its oxidation was catalyzed by Fe3+ ions at a rate determined by incubation time and iron concentration. In contrast, no ascorbate oxidation occurred in the presence of microsomes when lipid peroxidation was proceeding at a maximal rate. Under these conditions a typical ascorbyl radical ESR spectrum signal greater than that arising from ascorbate alone was obtained and the magnitude of this signal was unchanged by variations of microsome or ascorbate concentrations. A ferrous ion ascorbyl radical complex was responsible for this signal. These results suggest that an ascorbate-microsomal iron complex is responsible for the initiation of lipid peroxidation, and that during this process ascorbate remains in its reduced form.
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PMID:A possible mechanism for initiation of lipid peroxidation by ascorbate in rat liver microsomes. 872 1

The kinetics and mechanism of cleavage of DNA by the insulin-mimetic peroxo-vanadate NH4[VO(O2)2(phen)], pV, are described. In the presence of low energy UV radiation or biologically common reducing agents, pV decomposes into the monomer, dimer, and tetramer of vanadate and an uncharacterized compound of V4+ as shown by 51V NMR, ESR, and absorption spectra. The rate of photodecomposition of pV is reduced in the presence of calf thymus DNA, indicating that a decomposition product of the peroxo-vanadate, that is important in the destruction pathway of the complex, is interacting with DNA. This species, probably a short-lived complex of V4+, may also be responsible for the observed catalytic decomposition of pV in the absence of DNA by ascorbate. If closed circular pBR322 DNA is present when the peroxo-vanadate is destroyed by either UV radiation or reducing agents, the polymer may have its sugar-phosphate backbone broken. Closed circular DNA (form I) is converted into nicked circular DNA (form II) and linear DNA (form III). The amounts of the various forms produced as a function of irradiation time and peroxo-vanadate concentration were fit to a kinetic model to derive rate constants for the conversions. The kinetic analysis shows that pV is a single-strand nicking agent which exhibits some base and/or sequence preference. Furthermore, the pH dependences of the rates for conversion of form I to form II and for conversion of form II to form III are different, indicating that the nature of the chemistry at the site of cleavage on DNA influences further cutting by activated pV. Reduced amounts of DNA breakage in the presence of various salts and metal binding ligands indicate that a short-lived reactive complex of V4+, not the V4+ species detected by ESR at long irradiation times, is important in the cleavage process. The susceptibility of pV to decomposition by biologically common reducing agents suggests that metabolites of the agent, and not the compound itself, are responsible for its insulin-mimetic effects.
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PMID:Cleavage of DNA by the insulin-mimetic compound, NH4[VO(O2)2(phen)]. 882 70

The reaction kinetics between 4-palmitoyloxy-2,2,6,6-tetramethylpiperidine-1-oxyl (TEMPO-16) and vitamin C (VC) and its lipophilic derivative ascorbyl-6-palmitate (VC-16) was studied by stopped-flow ESR spectroscopy in a synthetic surfactant vesicle sodium 1-pentadecyl hexadecyl sulfate (SPHS). TEMPO-16 reacted with VC very slowly and showed a biphasic first-order kinetics with rate constants of 9.6 x 10(-4) and 2.5 x 10(-4) s-1, corresponding to diffusion of TEMPO-16 from the external monolayer of SPHS to the bulk water and flip-flop of TEMPO-16 from the internal to external monolayer of the vesicle, respectively. On the other hand, the reaction of TEMPO-16 with VC-16 was second-order and over three orders of magnitude faster than that with VC, presumably due to VC-16 induced fusion of the vesicle.
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PMID:Remarkable enhancement of antioxidant activity of vitamin C in an artificial bilayer by making it lipo-soluble. 885 31

Ascorbic acid and its related compounds were compared for their ascorbyl radical intensity and apoptosis-inducing activity. Sodium L-ascorbate, L-ascorbic acid, D-isoascorbic acid, sodium 6-beta-O-galactosyl-L-ascorbate and sodium 5,6-benzylidene-L-ascorbate, at the concentration of 1-10 mM, induced apoptotic cell death characterized by cell shrinkage, nuclear fragmentation and internucleosomal DNA cleavage in human promyelocytic leukemic HL-60 cells. On the other hand, L-ascorbic acid-2-phosphate magnesium salt and L-ascorbic acid 2-sulfate did not induce any of these apoptosis-associated characteristics. ESR measurements revealed that all the active compounds were progressively degraded, producing the ascorbyl radical (g = 2.0064, hfc = 0.17 mT) in culture medium, whereas the inactive compounds were stable and did not produce the ascorbyl radical. Cytotoxicity began to appear when the radical intensity exceeded a certain threshold level. In the presence of N-acetyl-L-cysteine, both ascorbyl radical intensity and apoptosis-inducing activity were significantly reduced. These data suggest the possible involvement of the ascorbyl radical in apoptosis induction by ascorbic acid-related compounds. Exposure of HL-60 cells to ascorbic acid or its active derivatives resulted in the rapid elevation of intracellular Ca2+ concentration, which might serve as the initial signal leading to the cell death pathway.
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PMID:Relationship between ascorbyl radical intensity and apoptosis-inducing activity. 891 63

Alkali-lignin stimulated the degradation of sodium ascorbate in phosphate-buffered saline, fetal bovine serum and culture medium, but not in distilled water. ESR spectroscopy revealed that alkali-lignin stimulated ascorbyl radical production even in distilled water. Similar stimulation activity was found in several other plant extracts, commercial and natural lignified materials. These data suggest that the lignin-stimulated degradation process of ascorbate might be separated into two processes, the first being the ascorbyl radical production process and the second the degradation process.
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PMID:Stimulation of two step degradation of sodium ascorbate by lignins. 891 96

ESR spectroscopy revealed that high molecular weight natural substances, such as protein-bound polysaccharide PSK, alkali-lignin and lignin sulfonate, significantly enhanced the ascorbyl radical intensity derived from sodium ascorbate or ascorbic acid in culture medium. Enhancement of the ascorbyl radical intensity was coupled with rapid degradation of ascorbate. These substances synergistically enhanced the ascorbate-induced cytotoxicity against human leukemic and glioblastoma cell lines. These data suggest the possible role of the ascorbyl radical in cytotoxicity induction.
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PMID:Enhancement of radical intensity and cytotoxic activity of ascorbate by PSK and lignins. 891 16

ESR spectroscopy revealed that the radical intensity of sodium ascorbate and ascorbic acid was significantly higher under hyperthermic conditions. The enhancement of ascorbyl radical intensity was coupled with the accelerated degradation of ascorbate and cytotoxicity induction against human leukemic and glioblastoma cell lines. Sodium ascorbate produced higher ascorbyl radical intensity and more potent cytotoxicity, as compared with ascorbic acid. These data demonstrate that ascorbic acid does not inhibit, but rather stimulates the cytotoxic action of hyperthermia. The combination of hyperthermia and ascorbate treatment might produce higher antitumor activity.
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PMID:Enhancement of radical intensity and cytotoxic activity of ascorbate by hyperthermia. 891 17

We describe real-time measurement of myocardial oxygen consumption during ischemia in the intact heart. Measurement of extracellular oxygen concentration during myocardial ischemia by spin label oximetry has been limited by ischemia-induced reduction of the neutral, water-soluble nitroxide TEMPONE. We have overcome this problem by encapsulating the nitroxides. Isolated immature (7-10 d old) rabbit hearts (n = 8) were perfused aerobically within the cavity of a loop gap resonator with bicarbonate buffer containing an oxygen-sensitive, lipid-soluble nitroxide (14N-TEMPO laurate in FC-43 perfluorocarbon micelles) and a much less oxygen-sensitive and positively charged nitroxide (15N-TEMPO choline in multilamellar vesicles) as an internal standard. The ratio of the ESR signal amplitudes of these nitroxides was used as a sensitive index of oxygen concentration. Sequestration of the nitroxides decreased their reduction rate by ascorbate in comparison with nonsequestered nitroxides. Hearts were subjected to 60 min of global no-flow ischemia at 20 degrees C. Extracellular oxygen content (mean +/- SD) during aerobic perfusion was 1195 +/- 55 mumol/liter. The electron spin resonance signal from TEMPO laurate increased with the onset and progression of ischemia, consistent with a decrease in extracellular oxygen, while the signal for TEMPO choline was relatively unchanged. Extracellular oxygen content after 40 and 60 min of ischemia was reduced to 393 +/- 27 mumol/liter (p < .05) and 61 +/- 5 mumol/liter (p < .05), respectively. We conclude that spin-label oximetry can directly and precisely measure myocardial oxygen consumption at constant temperature during ischemia in the intact heart.
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PMID:Spin label oximetry to assess extracellular oxygen during myocardial ischemia. 895 35

The superoxide-dismutase (SOD) enzyme, isolated from the halophilic halotolerant bacterium Ba1, was found to be a dimer with a molecular weight of 40 kD and a subunit weight of 23.5 kD. The partial N-terminal sequence showed significant homology to SODs isolated from various sources. Metal analysis showed that SOD from Ba1 contains manganese and iron with the following stoichiometries: 0.9 +/- 0.4 Mn/dimer and 0.6 +/- 0.2 Fe/dimer. Two bands were obtained by isoelectric-focusing, at pI of 4.45 and at 4.40. Native SOD from Ba1 at room temperature was ESR silent. An ESR spectrum of hydrated Mn(II) was obtained from denaturated enzyme. Native enzyme cooled to 97 K showed an ESR spectrum identified as being due to Fe(III). The spectrum was pH-independent. SOD from Ba1 was not inactivated by H2O2. On the basis of these observations, SOD from Ba1 was characterized as MnSOD. The excitation fluorescence spectrum of SOD from Ba1 showed four main peaks in the visible region. The effects on the spectra of KSCN, NaN3, NaF, and ascorbate were examined. Measurements of H2(17)O-nmr relaxation times T1 and T2, for solutions containing E. coli MnSOD and FeSOD, showed no paramagnetic contribution. These results support the assumption that the water molecule at the active site is strongly bound.
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PMID:Mn-superoxide dismutase from the halophilic halotolerant bacterium Ba1--isolation and active site spectroscopic studies. 898 69

CYP2B1 and 2E1 oxidized toluene, aniline and monochlorobenzene (MCB) to water-soluble metabolites and to products covalently binding to microsomal proteins from male Wistar rats at high efficiency. Oxidation of benzene to covalently binding metabolites was catalysed by CYP2B1 and 2E1 more effectively than the formation of water-soluble metabolites, especially at low benzene levels. Thus, the formation of covalently binding products was inversely related but formation of soluble metabolites was proportional to benzene concentration. 1,4-Benzoquinone was responsible for the majority of covalent binding to microsomal proteins, being suppressed by ascorbate; 1,4-semiquinone was not important, since alpha-tocopherol did not inhibit the covalent binding and ESR showed its rapid decay, if NADPH was available. Specific antibodies and inhibitors confirmed the role of CYP2B1 and 2E1 induction. Covalent binding of benzene to DNA was largely due to benzene oxide; approximately 50% was due to N-7 guanine adduct. CYP2E1 oxidizing benzene via phenol to 1,4-hydroquinone appeared to mediate its further oxidation to 1,4-benzoquinone, which also occurred spontaneously, but was reversed in a reducing environment of microsomes with NADPH. Production of OH radicals in microsomes with NADPH was greatly stimulated by HQ and less by BQ, especially in CYP2E1 induced microsomes, although the quinones themselves failed to produce OH radicals. The quinones could act by simulation of the CYP futile cycle. Therefore, CYP2B1 and 2E1 in rats appeared essential for metabolic activation of benzene derivatives to potentially genotoxic products; BQ dominated the covalent binding of benzene to proteins, whereas DNA adducts were largely due to benzene oxide.
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PMID:The role of CYP2E1 and 2B1 in metabolic activation of benzene derivatives. 901 May 85

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