UMLS:C0027960 - FACTA Search

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Query: UMLS:C0027960 (mole)
21,279 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

The enzyme preparation of L(+)-lactatoxydase (K.F. 1.1.3.2) with molecular weight of 230 000 has been isolated from the soluble fraction of the C. lipolytica cells and purified similar 360 times. The enzyme oxydizes L(+)-lactate, the optimum activity of the enzyme being observed at pH 8.0. Oxydation of the substrate is followed by accumulation of H2O2. Silver ions, p-chloromercurybenzoate and dicumarol inhibit the activity of L(+)-lactatoxydase. Iron complexones, cyanide and L-malate do not inhibit oxydation of the substrate. Pyruvate and its fluorine derivative practically do not produce any inhibiting effects either. The enzyme preparation contains 0.6 moles of flavin and 2 moles of nonhaem iron per a mole of the enzyme. Km value for the substrate is equal to 4-10(-4) M, Vmax--4.5 mkatom O/min/mg. Acidation of incubation medium leads to a decrease both of Km and Vmax. Km value for oxygen is equal to 3.1 mkM O2. Beside oxygen, ferricyanide, 2.6-dichlorphenolindophenol, phenazine methosulphate and cytochrome C may also serve as acceptors of L(+)-lactatoxydase electrons. The oxydized enzyme preparation is characterized by a spectrum absorption maximum at 410 nm. Upon L(+)-lactatoxydase reduction the maximum is shifted up to 420 nm.
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PMID:[Isolation and properties of cytoplasmic L(+)-lactatoxydase of Candida lipolytica yeasts]. 1 33

1) It was demonstrated by colorimetric as well as EPR measurements that the native (aerobic, resting state) Rhus vernicifera laccase contains both Cu2+ and Cu+ (total Cu content was 4.0 gram atoms/mole). The ratio of Cu2+ to total Cu in laccase varied (42-90%) in samples of latex collected from various districts. The absorption maximum at 615 nm was proportional to the content of total Cu in the enzyme sample. Laccase activity was found to almost parallel the content of the Cu2+ form. The oxidized minus reduced difference absorbance of the enzyme at 330 nm shoulder was proportional to the amount of Cu2+. 2) Steady state level of oxidation of laccase copper during the laccase copper catalytic action, the rates of reduction by substrates and the oxidation by O2 were determined by following absorbance changes at 615 and 330 nm by the stopped flow method. 3) All the results from titrimetric and kinetic experiments were consistent with the laccase model previously proposed by Makino and Ogura in which a laccase molecule contains 1 Cu(615) and 3 Cu(330). Our expanded model states that a laccase sample originally contains active as well as inactive enzymes. In the active enzyme, Cu ions are reactive to O2 but in the inactive enzyme, Cu can be oxidized only by oxidizing agents such as H2O2 or ferricyanide, or by a slow intermolecular electron transfer from Cu(615) to the active enzyme. In both species of enzyme rapid reduction of Cu2+ ions by substrate takes place. In comparative studies of the reactivities of Cu ions in various copper proteins, we would like to suggest that oxidatic activity of a copper protein is due to the Cu+ form of the enzyme ions with O2.
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PMID:Oxidation and reduction of copper ions in catalytic reactions of Rhus laccase. 13 27

DPNH peroxidase is a flavin adenine dinucleotide-containing flavoprotein. Anaerobic titration of enzyme with dithionite has shown that the active site of the enzyme contains 2 mol of flavin and in addition 1 mol of a non-flavin electron acceptor that is tentatively identified as a disulfide group. Thus complete reduction of the enzyme requires 3 mol of dithionite per mole of active site. The first mole of dithionite reduces the non-flavin acceptor; complex formation between the reduced acceptor and one of the bound flavin molecules causes the formation of a long wavelength absorption band between 500 and 670 nm. The second mole of dithionite reduces the flavin that interacts with the reduced non-flavin group, and the long wavelength band disappears. The third mole of dithionite reduces the second mole of flavin. All groups are reoxidized in the presence of air. DPNH reacts with only two of the enzyme-bound electron acceptors. The first mole of DPNH reduces the non-flavin group to form an intermediate (I) that is almost identical with that formed by dithionite. The second mole of DPNH complexes with the second flavin of Intermediate I to form Intermediate II. This reaction causes a further absorbance increase in the long wavelength region; the tail of the absorption band now extends to 960 nm. The titration data (potassium phosphate, 0.05 M, pH 7.0) can be fitted with dissociation constants of 1 times 10-7 M for the formation of I, and 3 times 10-6 M for the conversion of I to II. In air, species II is oxidized to I; I is stable in air, but is oxidized stoichiometrically to oxidized enzyme by H2O2. Present evidence suggests that bound DPN-plus is responsible for the air stability of species I. Intermediate I, but not oxidized enzyme, reacts slowly with phenylmercuric acetate. This reaction causes loss of the air-stable intermediate and parallel loss in enzyme activity. The inactive enzyme cannot be reduced by DPNH to Species I; DPNH can, however, still react with the second flavin to form the autoxidizable complex. With other methods of enzyme inactivation there is also a direct correlation between residual enzyme activity and the ability of enzyme to form the air-stable intermediate. It is concluded that the air-stable intermediate is an important catalytic species.
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PMID:Reduced diphosphopyridine nucleotide peroxidase. Intermediates formed on reduction of the enzyme with dithionite or reduced diphosphopyridine nucleotide. 16 90

A new method for the determination of guanase is described. Xanthine, the product of the guanase reaction, is oxidized by xanthine oxidase, forming uric acid and hydrogen peroxide. Hydrogen peroxide is further reduced to water by catalase in the presence of ethanol. The acetaldehyde formed in this reaction step is dehydrogenated NAD or NADP dependent by aldehyde dehydrogenase. The NADH or NADPH production is measured and utilized for the calculation of the guanase activity. The sensitivity of the method can be doubled by the addition of uricase, which oxidizes uric acid to permit the formation of another mole of hydrogen peroxide.
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PMID:A new spectrophotometric assay for enzymes of purine metabolism. II. Determination of guanase activity. 48 57

Mitochondrial monoamine oxidase isolated from bovine brain stem and purified to electrophoretic homogeneity contained 15 SH groups per mole (100000) of protein. The enzyme deaminated tyramine, p-nitro-beta-phenylethylamine, dopamine, 5-hydroxytryptamine, tryptamine but did not deaminate histamine, GABA or spermidine. Oxidation of 9-II SH groups in the MAO by air oxygen was accompanied by appearance of the properties to deaminate histamine or GABA. This qualitative alteration (transformation) in catalytic properties of the enzyme was readily reversed by treatment with reducing agents (dithiothreitol or GSH). No structural alterations detectable by electrophoresis in polyacrylamide gel were observed in course of the qualitative reversible modifications in catalytic activity of MAO. The qualitative alterations in substrate specificity were also initiated by treatment with H2O2 of the monoamine oxidases tightly bound with membrane structures of mitochondria from bovine brain stem.
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PMID:[Changes in substrate specificity of brain mitochondrial monoamine oxidase]. 88 99

Glutathione peroxidase (glutathione:H2O2 oxidoreductase, E.C. 1.11.1.9), isolated from ovine and bovine erythrocytes, has recently been shown to contain 4 selenium atoms per mole, an average of 1 Se per protein subunit of about 22,000 molecular weight. Selenium deficiency in the rat, chick and sheep causes dramatic decreases in the activity of this enzyme in the tissues, but certain sites such as liver are affected more than others. Decreases in glutathione peroxidase correlate with lesions caused by selenium deficiency and appear useful in diagnosing selenium deficiency. Glutathione peroxidase is an important enzyme in destroying H2O2 and organic hydroperoxides such as lipid hydroperoxides. It therefore guards against oxidative damage to the cell membranes and other oxidant-sensitive sites in the cell. While this selenium-dependent system destroys lipid hydroperoxides and other peroxides, vitamin E is believed to protect against oxidant damage to membranes by preventing the formation of lipid hydroperoxides. A scheme is proposed, based on oxidant damage and its prevention, which accounts for the interaction between selenium, vitamin E, unsaturated lipids, sulfur-containing amino acids, and cell damaging agents such as oxidant stressors and toxicants such as silver and tri-o-cresyl phosphate. The background for such a scheme is reviewed.
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PMID:Biochemical function of selenium and its relation to vitamin E. 110 Apr 37

The lactoperoxidase-catalyzed oxidation of glutathione (GSH) and thiocyanate (SCN-) was studied. Oxidation of SCN- was recorded by ultraviolet spectroscopy and by electron spin resonance (ESR). Consumption of GSH was measured by amperometric titration. One or two moles of GSH was oxidized per mole of H2O2 added, depending on the reaction conditions. Omission of SCN- prevented the oxidation of GSH. The oxidation of GSH required only catalytic amounts of SCN-, which was therefore recycled. Iodide (I-) could replace SCN-, while chloride or bromide were ineffective. The apparent Michaelis constant for SCN- was 17 microM. Oxidation of SCN- gave rise to two reactive intermediates, one stable and one unstable. The stable intermediate (-OSC. = N-(?)) decayed by a second-order reaction with a rate constant of 1.1 M-1 s-1. The decay of the unstable radical was very fast. The data (a) explain the short- and long-term antibacterial effects of lactoperoxidase-halide-H2O2 system, (b) point to possible deleterious effects due to glutathione depletion, (c) are of relevance for free radical diseases involving sulphur-centered free radicals, and (d) support previous observations on lipid peroxidation/halogenation in biological membranes, liposomes, and unsaturated fatty acids.
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PMID:Free radical generation and coupled thiol oxidation by lactoperoxidase/SCN-/H2O2. 132 2

The mechanism of inhibition of the veratryl alcohol oxidase activity of lignin peroxidase H2 (LiPH2) by EDTA was investigated. It was found that EDTA was decarboxylated and that cytochrome c, nitro blue tetrazolium, ferric iron, and molecular oxygen were reduced in a reaction mixture containing LiPH2, H2O2, veratryl alcohol, and EDTA. The reductive activity observed with LiPH2 followed first order kinetics with respect to the concentration of EDTA. Stoichiometry studies showed that in the presence of sufficient EDTA, 1.7 mol of ferric iron were reduced per mole of H2O2 added to the reaction mixture. Superoxide- and EDTA-derived radicals were detected by ESR spin trapping upon incubation of LiPH2 with H2O2, veratryl alcohol, and EDTA. The Km values of veratryl alcohol and H2O2 remained the same for both the oxidative and reductive activities of LiPH2. Reductive activity was also observed with LiPH2 and EDTA using other free radical mediators in the place of veratryl alcohol, such as 1,4-dimethoxybenzene, 1,2,3- and 1,2,4-trimethoxybenzenes, and 1,2,4,5-tetramethoxybenzene. EDTA reduced the cation radical of 1,2,4,5-tetramethoxybenzene formed by LiPH2 in the presence of H2O2. Hence, it is proposed that the apparent inhibition of the veratryl alcohol oxidase activity of LiPH2 by EDTA is due to the reduction of the veratryl alcohol cation radical intermediate back to veratryl alcohol by EDTA. The reduction of cytochrome c, nitro blue tetrazolium, ferric ion, and molecular oxygen appears to be mediated by the EDTA radical formed by reduction of the veratryl alcohol cation radical.
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PMID:On the mechanism of inhibition of the veratryl alcohol oxidase activity of lignin peroxidase H2 by EDTA. 132 38

The reason for the differences in phototoxic potential between the 5 quinolone antibacterial agents lomefloxacin, enoxacin, ciprofloxacin, ofloxacin and DR-3355 (the s-isomer of ofloxacin) in mice was investigated. Superoxide anion, hydrogen peroxide (H2O2), and bleaching of p-nitrosodimethylaniline (B-NDMA) were detected in quinolone solutions during irradiation with ultraviolet-A (UVA). Apparent levels of H2O2 and the B-NDMA per mole of quinolone paralled the phototoxic potentials in the mice. The N-NDMA induced by quinolones and UVA was inhibited partially by treatment with D-mannitol and dimethylsulfoxide, and also with diethylenetriamine-pentaaceticacid (DTPA), suggesting that Haber-Weiss and Fenton reactions occurred. UVA concentration-dependently increased the level of the B-NMDA in H2O2 solution and the swelling in the ear pretreated by intra-auricular injection of H2O2. Both augmentations were inhibited by DTPA or DMSO. The swelling induced by the 5 quinolones and UVA was completely inhibited by pretreatment with dimethylsulfoxide. Oxygen consumption was detectable during the photodegradation, and increased with time. These results showed that the phototoxic potentials of the 5 quinolones were probably related to the amounts of toxic oxygens generated in the target cells during irradiation.
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PMID:Possible reasons for differences in phototoxic potential of a 5 quinolone antibacterial agents: generation of toxic oxygen. 133 37

The oxidation of NADPH catalyzed by horseradish peroxidase (HRP) and hydrogen peroxide (H2O2) is markedly increased by the presence of acetaminophen in a concentration-dependent manner. The oxidation follows pseudo-first order kinetics with respect to acetaminophen concentration. The product of the oxidation is enzymatically active NADP+. The stoichiometry of the reaction shows that 1.4 mol of NADPH are oxidized per mole of H2O2 added, and the addition of superoxide dismutase to the reaction mixture increases the ratio of NADPH oxidized:H2O2 consumed, which suggests formation of superoxide as a product. Monitoring cytochrome c reduction in the presence and absence of superoxide dismutase further suggests formation of superoxide. These results indicate that the HRP-H2O2 system oxidizes acetaminophen to the phenoxyl radical, N-acetyl-p-benzosemiquinone imime, which undergoes a rapid electron transfer reaction with NADPH. The NADP thus formed reacts with molecular oxygen to produce superoxide.
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PMID:Mechanism of acetaminophen-stimulated NADPH oxidation catalyzed by the peroxidase-H2O2 system. 167 96

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