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A low-cost assay method that is able to measure H2O2 concentrations as low as the nano-molar range is described. The assay solution contains NADH, horseradish peroxidase, and superoxide dismutase at PH 7.5. After the addition of the sample, the decrease in NADH concentration measured by spectrophotometry is proportional to the H2O2 concentration. Because of superoxide dismutation, a high amplification factor defined as moles NADH oxidised per mole H2O2 added is obtained, which allows the sensitivity limit of the method to be greatly improved. We have established the conditions under which the amplification factor can be stabilised at a high level: the best compromise is to increase both the horseradish peroxidase and superoxide dismutase concentrations. Finally, we have also shown that coupled to specific oxidases, our assay method is suitable for measuring very low concentrations of biochemicals that can be oxidized by oxygen with H2O2 production.
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PMID:Experimental procedure for a hydrogen peroxide assay based on the peroxidase-oxidase reaction. 870 81

Interactions of NAD-dependent dehydrogenases (glyceraldehyde-3-phosphate dehydrogenase, GAPDH, and lactate dehydrogenase, LDH) with band 3 erythrocyte membrane protein and tubulin were characterized. At low ionic strength and un-saturating substrate concentrations, LDH tightly binds to tubulin and is thus inactivated. The Kd of the LDH-tubulin complex was calculated in inhibition and direct binding experiments (15.0 and 13.6 nM, respectively); the stoichiometry of the complex was 1.66 moles of tubulin dimer bound per mole of LDH tetramer. In the presence of 0.15 M NaCl, LDH does not bind to tubulin and tubulin-dependent inhibition of LDH activity is not detected. At low ionic strength, erythrocyte membranes affect both dehydrogenases similarly. GAPDH activity is completely inhibited by excess of erythrocyte membranes (or by excess of cytoplasmic fragment of band 3 protein). Under similar conditions, LDH activity was inhibited by 70% by erythrocyte membranes. In these experiments, 14.8.10(6) GAPDH tetramers or 25.6.10(6) LDH tetramers bound to one erythrocyte ghost (Kd is 0.13 and 0.6 microM, respectively). Increase in ionic strength (0.15 m NaCl) completely abolished the membrane-dependent inhibition of dehydrogenases; however, membranes still bound GAPDH and LDH. Under these conditions, the Kd for GAPDH was increased (up to 4.43 microM), whereas the number of membrane-bound enzyme molecules has not been significantly affected (0.75 nmoles of tetramer per 100 micrograms membrane protein). The Kd for LDH was not changed (0.76 microM), whereas the number of membrane-bound enzyme molecules was decreased (down to 0.48 nmoles of tetramer per 100 micrograms membrane protein). It is suggested that at low ionic strength, the "acidic tails" of band 3 protein and tubulin can interact with positively charged NAD-binding domains of both dehydrogenases thus inhibiting their activity. Increase in ionic strength reduces these interactions, decreasing the binding and inhibition of enzyme activities. At "physiological" ionic strength, catalytically active GAPDH and LDH can possibly bind to various sites of the erythrocyte membrane. This can be important in regulation of the transfer of the common cofactor (NAD/NADH) between their active sites.
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PMID:[Effect of erythrocyte membranes and tubulin on the activity of NAD-dependent dehydrogenases]. 896 25

Cells of Saccharomyces cerevisiae were permeabilized by ether for the isolation of coenzyme NADH. A 4-fold increase in the ether fraction to aqueous fraction resulted in the recovery of 80% of total NADH present in the cell. NADH was separated and purified by affinity ultrafiltration using yeast alcohol dehydrogenase as an affinity ligand. The binding characteristics of the enzyme and coenzyme were established at different pH and ionic strengths using gel filtration. The number of moles of NADH bound per mole of alcohol dehydrogenase (r) was found to be 5.7 at pH 8 and ionic strength (I) 0.1 M. The binary complex of NADH and alcohol dehydrogenase was cleaved by lowering the pH to 6.0. The crude cell permeate on purification by ultrafiltration with 2-fold dilution, gave NADH with an absorbance ratio (A260/A340) of 2.3 and overall yield of 68%. Alcohol dehydrogenase was recovered as retentate with 93% recovery and 15% loss in activity.
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PMID:Isolation of NADH from Saccharomyces cerevisiae by ether permeabilization and its purification by affinity ultrafiltration. 905 54

Isoflavonoid derivatives including prunetin (4',5-dihydroxy-7-methoxyisoflavone) were shown to be potent inhibitors of human aldehyde dehydrogenases (Keung W-M and Vallee BL, Proc Natl Acad Sci USA 90: 1247-1251, 1993). The inhibition reaction was reinvestigated using recombinantly expressed human aldehyde dehydrogenases. The kinetic analyses showed that prunetin inhibits competitively against both NAD and propionaldehyde with the mitochondrial and cytoplasmic enzymes. The Ki value for the mitochondrial enzyme was much lower than for the cytoplasmicenzyme. A mixed pattern of inhibition was obtaiend with the mitochondrial enzyme in the presence of Mg2+. Only one mole of prunetin binds per mole of tetrameric mitochondrial enzyme, which remains unaltered in the presence of Mg2+. Prunetin did not displace NADH from the enzyme-NADH complex. Propionaldehyde did not reverse the loss of fluorescence obtained due to enzyme-prunetin complex formation, indicating that prunetin may not be interacting at the substrate site. The esterase activity of the mitochondrial enzyme was also inhibited by prunetin in a competitive manner. The replacement of lysine 192 by glutamine resulted in a mutant with a 20% kcat and a 100-fold increase in the Km for NAI) compared with the native enzyme. However, the Ki value of prunetin against NAD was similar to that observed with the native enzyme. Prunetin, even at a very high concentration, was not an inhibitor of alcohol and malate dehydrogenase. It was concluded that prunetin may act as an allosteric inhibitor of aldehyde dehydrogenase.
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PMID:Allosteric inhibition of human liver aldehyde dehydrogenase by the isoflavone prunetin. 910 97

Ascorbate and complexes of Cu(II) and Fe(III) are capable of generating significant levels of oxygen free radicals. Exposure of erythrocytes to such oxidative stress leads to increased levels of methemoglobin and extensive changes in cell morphology. Cu(II) per mole is much more effective than Fe(III). However, isolated hemoglobin is oxidized more rapidly and completely by Fe(III)- than by Cu(II)-complexes. Both Fe(III) and Cu(II) are capable of inhibiting a number of the key enzymes of erythrocyte metabolism. The mechanism for the enhanced activity of Cu(II) has not been previously established. Using intact erythrocytes and hemolysates we demonstrate that Cu(II)-, but not Fe(III)-complexes in the presence of ascorbate block NADH-methemoglobin reductase. Complexes of Cu(II) alone are not inhibitory. The relative inability of Fe(III)-complexes and ascorbate to cause methemoglobin accumulation is not owing to Fe(III) association with the membrane, or its failure to enter the erythrocytes. The toxicity of Cu(II) and ascorbate appears to be a result of site-specific oxidative damage of erythrocyte NADH-methemoglobin reductase and the enzyme's subsequent inability to reduce the oxidized hemoglobin.
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PMID:Copper-specific damage in human erythrocytes exposed to oxidative stress. 916 68

The assimilatory nitrate reductase from the phototrophic bacterium Rhodobacter capsulatus has been purified to electrophoretic homogeneity and its molecular and kinetic parameters determined. The native nitrate reductase is a dimer of 144 kDa composed of two subunits of 46 and 95 kDa. The purified enzyme catalyzes the electron transfer from NADH, reduced bromophenol blue or reduced viologens to nitrate. The nitrate reductase contains 1 mol FAD per mole of enzyme and also reduces cytochrome c or dichlorophenol indophenol with NADH as the electron donor. The diaphorase activity is located in the small subunit.
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PMID:The assimilatory nitrate reductase from the phototrophic bacterium, Rhodobacter capsulatus E1F1, is a flavoprotein. 930 29

DCMV++ (1,1'-dimethyl-2,2'-dicyano-4,4'-bipyridinium, bis-methylsulfate) promotes the aerobic oxidation of the NAD(P) dimers (NADP)2 and (NAD)2 with the formation of 2 mol of NADP+ or NAD+ per mole of dimers. The reaction appears to follow a pseudo-first-order kinetics with respect to the dimer concentration. One mole of oxygen was consumed in the reaction per mole of NAD(P) dimer oxidized and hydrogen peroxide was produced. The monomers NADPH and NADH under the same reaction conditions were not oxidized by DCMV++. In anaerobiosis NAD(P) dimers but not NAD(P)H rapidly reduced DCMV++ to its radical cation DCMV++, which was rapidly back-oxidized by air to its parent dication. Paraquat (MV++) was also able to catalyze the aerobic oxidation of NAD(P) dimers and, at a much lower extent, NADPH and NADH, but only under light irradiation. In anaerobiosis and upon light irradiation all the above nucleotides were able to convert paraquat to its radical cation MV++, reoxidized to MV++ by air admission. This study shows the different ability of NAD(P) dimers and NAD(P)H to undergo one-electron and two-electron oxidation reactions, with different viologens.
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PMID:Reactions of pyridine coenzyme dimers and monomers with viologens. 963 99

5'-Deoxy-5'-difluoromethylthioadenosine (DFMTA) 1a and 5'-deoxy-5'-trifluoromethyl-thioadenosine (TFMTA) 1b are inhibitors of beef liver S-adenosyl-L-homocysteine hydrolase. DFMTA and TFMTA are time-dependent and irreversible inhibitors of the enzyme. Both 1a and 1b are oxidized by E-NAD+ to produce E-NADH and fluoride anion is formed in the inactivation reaction (2.2 mol of fluoride/mole of enzyme subunit and 3.1 fluoride/mole of enzyme subunit from DFMTA and TFMTA respectively). Using [8-3H]-1a or [8-3H]-1b no trace of labelled adenosine was detected during the inactivation reaction but adenine was formed. The mechanism of inhibition of S-adenosyl-L-homocysteine hydrolase by these two fluorinated nucleosides is discussed.
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PMID:The mechanism of inactivation of S-adenosylhomocysteine hydrolase by fluorinated analogs of 5'-methylthioadenosine. 982 7

At pH 7.05 NADH-X prepared by incubating NADH with glyceraldehyde-3-phosphate dehydrogenase (E.C. 1.2.1.12) was a potent noncompetitive inhibitor, with respect to coenzyme, of NADPH oxidation by pure rabbit muscle cytosolic glycerol-3-phosphate dehydrogenase (E.C. 1.1.1.8) and also a potent inhibitor of NADPH oxidation catalyzed by this enzyme in a rat pancreatic islet cytosolic fraction. It was a much less potent inhibitor of NADPH oxidation catalyzed by this enzyme in a rat liver cytosolic fraction and of NADH oxidation catalyzed by this enzyme from all three sources. Glycerol-3-phosphate dehydrogenase purified from muscle cytosol contains tightly bound NADH-X, NAD, and ADP-ribose, each in amounts of about 0.1 mol per mole of enzyme polypeptide chain. A deproteinized supernatant of this enzyme contained these three ligands and produced the same type of inhibition of the enzyme described above for prepared NADH-X with a Ki, in the reaction with NADPH at pH 7.05, in the range of 0.2 microM with respect to the total concentration of ligands ([ADP-ribose] + [NAD] + [NADH-X] = 0. 2 microM). However, only the NADH-X component could account for the potent inhibition because NAD, ADP-ribose, and the primary acid product (which can be produced from NADH-X) each had a Ki considerably higher than 0.2 microM. Although at pH 7.05 NADH-X inhibited NADPH oxidation considerably more than NADH oxidation, the reverse was the case at pH 7.38. Since the enzyme purified from muscle contains tightly bound NADH-X, NADH-X might become attached to the enzyme in vivo where it could play a role in regulating the ratio of NADH to NADPH oxidation of the enzyme.
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PMID:Effect of NADH-X on cytosolic glycerol-3-phosphate dehydrogenase. 985 31

NAD(P)H:rubredoxin oxidoreductase (NROR) has been purified from the hyperthermophilic archaeon Pyrococcus furiosus. The enzyme is exceedingly active in catalyzing the NADPH-dependent reduction of rubredoxin, a small (5.3-kDa) iron-containing redox protein that had previously been purified from this organism. The apparent Vmax at 80 degrees C is 20,000 micromol/min/mg, which corresponds to a kcat/Km value of 300,000 mM(-1) s(-1). The apparent Km values measured at 80 degrees C and pH 8.0 for rubredoxin, NADPH, and NADH were 50, 5, and 34 microM, respectively. The enzyme did not reduce P. furiosus ferredoxin. NROR is a monomer with a molecular mass of 45 kDa and contains one flavin adenine dinucleotide molecule per mole but lacks metals and inorganic sulfide. The possible physiological role of this hyperactive enzyme is discussed.
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PMID:A hyperactive NAD(P)H:Rubredoxin oxidoreductase from the hyperthermophilic archaeon Pyrococcus furiosus. 1046 33

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