The formation of hydrogen peroxide during the oxidation of reduced nicotinamide adenine dinucleotide by cytochrome o from Vitreoscilla.

The formation of hydrogen peroxide during the oxidation of NADH by purified preparations of cytochrome o has been demonstrated by employing three independent methods: polarographic, colorimetric, and fluorometric. The first two methods were used to assay for the accumulation of hydrogen peroxide and showed that hydrogen peroxide did accumulate as a product, but only about 30% of the oxygen consumed or 15 to 20% of the NADH oxidized was recoverable as hydrogen peroxide. This lack of 1:1 stoichiometry was not due to residual catalase activity in these preparations which could be eliminated by freeze-thawing. Thus, hydrogen peroxide may not be the sole or primary product of the NADH-cytochrome o oxidase reaction. The fluorometric assay could be coupled directly to the NADH-cytochrome o oxidase reaction in one medium, and this method showed that hydrogen peroxide was generated continuously from the beginning of the reaction in a 1:1 stoichiometry, hydrogen peroxide generated to NADH oxidized. This result suggests that hydrogen peroxide is an intermediate that can be trapped efficiently under the conditions of the fluorometric assay, whereas under the conditions of the first two assays most of the hydrogen peroxide generated undergoes further reaction. Exogenously added FAD or FMN increased the percentage of hydrogen peroxide that accumulated in the NADHcytochrome o oxidase reaction. Flavin is believed to act on the reductase side of cytochrome o so the increased percentage of hydrogen peroxide is not likely to result from the direct reaction of reduced flavin with oxygen.     

Mutants of Neurospora deficient in nicotinamide adenine dinucleotide (phosphate) glycohydrolase.

A new screening technique has been developed for the rapid identification of Neurospora crassa mutants that are deficient in nicotinamide adenine dinucleotide glycohydrolase (NADase) and nicotinamide adenine dinucleotide phosphate glycohydrolase (NADPase) activities. Using this procedure, five single-gene mutants were isolated whose singular difference from wild type appeared to be the absence of NAD(P)ase (EC 3.2.2.6). All five mutants were found to be genetically allelic and did not complement in heterocaryons. This gene, nada [NAD(P)ase], was localized in linkage group IV. One of the nada alleles was found to specify an enzyme that was critically temperature sensitive and had altered substrate affinity. Mutations at the nada locus did not affect the genetic program for the expression of NAD(P)ase during cell differentiation, nor did they have a general effect on NAD catabolism. Nada mutations did not have simultaneous effects on other glycohydrolase activities. Tests of dominance (in heterocaryons) and in vitro mixing experiments did not provide evidence that nada mutations alter activators or inhibitors of NAD(P)ase. Thus, the nada gene appears to specify only the structure of N. crassa NAD(P)ase.     

Possible control of hydrogen peroxide production and degradation in microsomes during mixed function oxidation reaction

The fate of hydrogen peroxide has been investigated in rat liver microsomes. The net rate of formation of H₂O₂ appears to be independent of concomitant substrate hydroxylation in microsomes from controls and phenobarbital treated animals. If rats are pretreated with Pregnenolone-16α-carbonitrile, H₂O₂ formation increases significantly during N-demethylation of aminopyrine. However, H₂O₂ is consumed in microsomes from 3-Methylcholanthrene treated rats if aminopyrine and NADPH are present. Since the H₂O₂ formation and consumption are dependent on induction by different agents and on presence of substrates, its fate might be linked to the spin state of cytochrome P-450.     

Reduced nicotinamide adenine dinucleotide phosphate, a structural and conformational probe of chicken liver fatty acid synthetase.

Structural and conformational organization of chicken liver fatty acid synthetase has been probed using its fluorescent coenzyme, NADPH. Three NADPH binding sites per mole of the enzyme complex, of apparently identical dissociation constant (KD = 0.6 muM) can be titrated at temperatures above 12 degrees. These results are in disagreement with the earlier studies of Hsu and Wagner (Hsu, R. Y., and Wagner, B. J. (1970) Biochemistry, 9, 245-251) in which four such sites could be titrated. At 12 degrees, the composite sites split into two subsets: a pair of sites with a KD of 0.3 muM and a third site with a Kd of 1.1 muM. At lower temperatures (5 degrees or 2 degrees), the site with weak affinity disappears, leaving a pair of sites with a Kd of 0.5 muM. Similar observations were made when the enzyme was modified with phenylmethylsulfonyl fluoride, a specific and selective inhibitor of fatty acyl-CoA deacylase (s) of the pigeon liver enzyme complex (Kumar, S. (1975) J. Biol. Chem. 250, 5150-5158). Partial modification with phenylmethylsulfonyl fluoride elicits a NADPH binding response similar to the binding observed at 12 degrees, i.e. two sets of binding sites with nonidentical dissociation constants. Further modification corresponding to the complete loss of deacylase function results in a set of two apparently identical binding sites, and the third site is not available for titration. The modified enzyme retains the two reductase functions as measured by the model substrates, acetoacetyl-N-acetylcysteamine and crotonyl-CoA. Furthermore, the addition of acetyl- and malonyl-CoA (100 muM each) to the modified enzyme lowers the NADPH binding affinity by a factor of 3. Other observations show that the quantum yield, as measured by the ratio of fluorescence intensity of bound and free NADPH, changes with temperature and ionic strength. Lowering the temperature from 30 degrees to 2 degrees increases the enhancement ratio by 50%, whereas increase in ionic strength from 0.05 to 0.2 M potassium phosphate lowers it to 50% of the original level. Measurement of NADPH binding in the presence of NADP+, NADH, NAD+ and adenosine-2'-monophospho-5'-diphosphoribose demonstrates that NADP+ shows competitive behavior for NADPH sites (KD = 10.6 muM), whereas NADH and NAD+ show noncompetitive (KD (apparent) = nearly 600 muM) and rather complicated interactions implicating nonspecific conformational alteration of the enzyme complex. The behavior of adenosine 2'-monophospho-5'-diphosphoribose is intermediate between NADP+ and NADH. These data are discussed in terms of substrate-mediated conformational changes and the moles of each of the reductase enzymes per mole of the enzyme complex, the polarity of the NADPH binding region, and the probable structure of the nicotinamide moiety when bound to the enzyme.     

Developmental regulation of nicotinamide adenine dinucleotide (phosphate) glycohydrolase in Neurospora crassa.

The formation of nicotinamide adenine dinucleotide (phosphate) glycohydrolase [NAD(P)ase; EC 3.2.2.6] in Neurospora crassa was found to be both spatially and temporally programmed. Ascospores were devoid of the enzyme. Vegetative hyphae contained little or no NADase activity. During the differentiation of aerial cell types (aerial hyphae and macroconidia), the specific activity of the enzyme increased by at least three orders of magnitude. Although transiently associated with young aerial hyphae, the enzyme became an integral and stable part of the mature macroconidia. NAD(P)ase could also be “derepressed” under conditions that permitted aerialogenesis in the absence of conidiation. The increase in the specific activity of NAD(P)ase during cell differentiation required concomitant RNA and protein synthesis; in vitro mixing experiments revealed no cell-specific activators or inhibitors of enzyme activity. The temperature-critical period for the in vitro inactivation of a temperature-sensitive enzyme variant was restricted to the period of actual enzyme expression.The data reported in this paper combined with data reported in a previous paper (Nelson et al., 1975b) underscore an important distinction in studies of development, namely, developmental regulation of a macromolecule versus regulation of development by a macromolecule. This paper provides evidence that NAD(P)ase is developmentally regulated. The previous paper provides evidence that the appearance of this enzyme need not regulate development.     

Alpha reduced nicotinamide adenine dinucleotide-dependent reductase reactions of rat liver microsomes.

The kinetics of alpha-NADH-dichlorophenolindophenol (DCPIP) and alpha-NADH-cytochrome c reductase reactions of rat liver microsomes showed that the reactio ns proceeded by a ping-pong mechanism, and that the oxidation of alpha-NADH was the rate-determining reaction. The DCPIP-reducing activity with alpha-NADH in the presence of ADP was about 1% of that with beta-NADH. ADP inhibited the alpha-NADH-DCPIP reductase reaction in a competitive manner with respect to alpha-NADH and a value of 1.2 mM for the inhibition constant was obtained. ADP also inhibited cytochrome b5 reduction with alpha-NADH. More than 90% of cytochrome b5 was reduced under conditions where 90% of the alpha-NADH-DCPIP reductase activity was suppressed with ADP. The reduction of DCPIP with alpha-NADH preceded that of cytochrome b5, but the reductions partly overlapped. From these results, a diversed electron flow from alpha-NADH to cytochrome b5 and electron sharing between cytochrome b5 and DCPIP were indicated. alpha-NAD+ also inhibited the alpha-NADH-DCPIP reductase reaction. Analyses of the inhibition indicated that two types of alpha-NADH-DCPIP reductase reaction existed, one of which was resistant to alpha-NAD+ inhibition. In contrast to the reoxidation of beta-NADH-reduced cytochrome b5, the process was largely monophasic when cytochrome b5 was reduced with alpha-NADH.     

Reconstitution of the reduced nicotinamide adenine dinucleotide phosphate- and reduced nicotinamide adenine dinucleotide-peroxidase activities from solubilized components of rat liver microsomes.

The liver microsomal enzyme system that catalyzes the oxidation of NADPH by organic hydroperoxides has been solubilized and resolved by the use of detergents into fractions containing NADPH-cytochrome c reductase, cytochrome P-450 (or P-448), and microsomal lipid. Partially purified cytochromes P-450 and P-448, free of the reductase and of cytochrome b₅, were prepared from liver microsomes of rats pretreated with phenobarbital (PB) and 3-methylcholanthrene (3-MC), respectively, and reconstituted separately with the reductase and lipid fractions prepared from PB-treated animals to yield enzymically active preparations functional in cumene hydroperoxide-dependent NADPH oxidation. The reductase, cytochrome P-450 (or P-448), and lipid fractions were all required for maximal catalytic activity. Detergent-purified cytochrome b₅ when added to the complete system did not enhance the reaction rate. However, the partially purified cytochrome P-450 (or P-448) preparation was by itself capable of supporting the NADPH-peroxidase reaction but at a lower rate (25% of the maximal velocity) than the complete system. Other heme compounds such as hematin, methemoglobin, metmyoglobin, and ferricytochrome c could also act as comparable catalysts for the peroxidation of NADPH by cumene hydroperoxide and in these reactions, NADH was able to substitute for NADPH. The microsomal NADH-dependent peroxidase activity was also reconstituted from solubilized components of liver microsomes and was found to require NADH-cytochrome b₅ reductase, cytochrome P-450 (or P-448), lipid, and cytochrome b₅ for maximal catalytic activity. These results lend support to our earlier hypothesis that two distinct electron transport pathways operate in NADPH- and NADH-dependent hydroperoxide decomposition in liver microsomes.     

Pulse fluorimetry study of beef liver glutamate dehydrogenase reduced nicotinamide adenine dinucleotide phosphate complexes.

Single photon counting pulse fluorimetry has been used in order to study the two ternary complexes GDH-GTP-NADPH and GDH-L-glutamate-NADPH and the quaternary complex GDH-GTP-L-glutamate-NADPH. The fluorescence decay of the enzyme-bound NADPH is not monoexponential in any of these complexes. Moreover, it does not seem to be dependent on the coenzyme concentration. The experimental curves can be satisfactorily fitted with the sum of two exponentials, the relative amplitudes of which significantly depend on the complex studied. Thus, for dihydronicotinamide two possible environments might exist in the enzyme active sites. It is also shown that the fluorescence decay times of the enzyme are shortened by the bound NADPH.     

Stoichiometric cooperation of NADPH and hexobarbital in hepatic microsomes during the catalysis of hydrogen peroxide formation

The interaction of NADPH and hexobarbital during catalysis of microsomal mixed function oxidase-dependent hydrogen peroxide formation has been investigated in hepatic microsomes from phenobarbital-treated rabbits. The application of Job's method (25) of continuous variation revealed optimal conditions for the rate and extent of hydrogen peroxide formation when hexobarbital and NADPH were in equimolar amounts. The formation of a complex of 1 mol NADPH with cytochrome c-reductase and 1 mol hexobarbital with cytochrome P-450 seems to be responsible for limitation of hydrogen peroxide formation. Rate and extent of hydrogen peroxide formation are directly proportional to the amount of hexobarbital and NADPH present and are governed by the mass action equation in a manner similar to that reported for interaction of purified enzymes (G. T. Miwa, S. B. West, M. T. Huang, and A. H. Lu, 1979,J. Biol. Chem.254, 5695–5700). Depending on either the NADPH concentration maintained by a generating system or the hexobarbital concentration, the extent of hydrogen peroxide formation could be shown to be a function of either compound alone, as long as the other one is in excess. The question whether the formation of hydrogen peroxide depends on the availability of two independent one-electron transfer reactions forming O₂^? or of one simultaneous two-electron transfer forming O₂^2? might thus become rather a matter of association of substrate and cosubstrate to a catalytically active complex in which the substrate augments the availability of reducing equivalents.