KEGG:D02011 - FACTA Search

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Query: KEGG:D02011 (FAD)
5,530 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

Chlorella vulgaris was cultured on an ammonia-mineral salts medium until the nitrate reductase content reached a minimal level. These ammonia-grown cells were then induced by nitrate in the absence of molybdenum and of tungsten. A demolybdo nitrate reductase developed and reached high levels. This protein contained very little nitrate-reducing capacity, but had the full cytochrome c-reducing capacity of normal nitrate reductase. It was purified to homogeneity by the same procedures previously developed for the purification of nitrate reductase. The purified enzyme contained 1 molecule of heme and 1 molecule of FAD/subunit, but no detectable molybdenum or tungsten. This cytochrome c reductase was completely inhibited by antibodies raised against purified nitrate reductase of Chlorella. Mixtures prepared from normal nitrate reductase and the demolybdoenzyme could not be resolved by disc gel electrophoresis or by centrifugation in a density gradient. By a two-step enzyme induction (1, incubation with nitrate in absence of Mo; 2, incubation with Mo in absence of nitrate) the process of nitrate reductase synthesis could be cleanly separated from growth into two steps: Step 1, induction of cytochrome c reductase, was completely inhibited by cycloheximide. Step 2 was unaffected by cycloheximide, and most of the nitrate reductase synthesized accumulated in the form of the reversibly inactivated HCN complex of the enzyme.
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PMID:Purification and characterization of demolybdo nitrate reductase (NADH-cytochrome c oxidoreductase) of Chlorella vulgaris. 719 74

Desulfovibrio desulfuricans (ATCC 27774), a strictly anaerobic sulfate-reducing bacteria, is able to perform anaerobic nitrate respiration in which nitrate is first reduced to nitrite by the action of nitrate reductase, and nitrite reductase then catalyzes the six-electron reduction of nitrite to ammonia. The nitrite reductase was found to be a membrane-bound enzyme and has been purified to electrophoretic homogeneity. The purified enzyme has a minimal Mr = 66,000 as judged by sodium dodecyl sulfate gel electrophoresis and contains 6 c-type heme groups/molecule. Pure nitrite reductase exhibits a typical c-type cytochrome absorption spectrum with reduced alpha-band at 552.5 nm. NADH and NADPH do not function as direct electron donors for the nitrite reductase. Desulfovibrio vulgaris hydrogenase, however, is able to transfer electrons from H2 to the nitrite reductase using FAD as the electron transfer mediator. The dithionite-reduced nitrite reductase was demonstrated to be auto-oxidizable even in the presence of potassium cyanide. On addition of nitrite, the dithionite-reduced enzyme is re-oxidized immediately. Hydroxylamine, however, can only partially re-oxidize the reduced enzyme. Ascorbate reduces the enzyme to a limited extent and the partially reduced enzyme is neither auto-oxidizable nor re-oxidizable by nitrite or hydroxylamine. Purified nitrite reductase has a pH optimum in the range of 8.0-9.5 and optimal activity at 57 degrees C. Purified nitrite reductase also has hydroxylamine reductase activity, and the Km for nitrite was determined to be 1.14 mM and that for hydroxylamine is 113.5 mM. The difference in Km values seems to exclude the possibility of hydroxylamine being a free intermediate in the reduction of nitrite.
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PMID:The isolation of a hexaheme cytochrome from Desulfovibrio desulfuricans and its identification as a new type of nitrite reductase. 730 57

We report a simple, enzymatic, end point method for determining nitrate in serum and urine with use of nitrate reductase from Aspergillus sp. (EC 1.6.6.2). The decrease in absorbance at 340 nm as a result of the oxidation of beta-NADPH is measured. We used FAD as a supplementary electron carrier and added an internal standard to avoid interference from possible inhibitors of the enzymatic reaction. The method was linear from 5 to 200 mumol/L nitrate in serum. Within-run (n = 12) and total (n = 14 days) imprecisions (CV) were 5.1-7.7% and 6.2-9.8%, respectively, at 20-90 mumol/L nitrate in serum. Recoveries of added nitrate were 80-106%. The median (range) concentration in serum of 20 healthy subjects was 16 (0-42) mumol/L.
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PMID:Nitrate determination in biological fluids by an enzymatic one-step assay with nitrate reductase. 776 10

Differences in the amino acid sequence between the bispecific NAD(P)H-nitrate reductase of birch (Betula pendula Roth) and the monospecific NADH-nitrate reductases of a variety of other higher plants have been found at the dinucleotide-binding site in the FAD domain. To pinpoint amino acid residues that determine the choice of reducing substrate, we introduced mutations into the cDNA coding for birch nitrate reductase. These mutations were aimed at replacing certain amino acids of the NAD(P)H-binding site by conserved amino acids located at identical positions in NADH-monospecific enzymes. The mutated cDNAs were integrated into the genome of tobacco by Agrobacterium-mediated transformation. Transgenic tobacco (Nicotiana tabacum) plants were grown on a medium containing ammonium as the sole nitrogen source to keep endogenous tobacco nitrate reductase activity low. Whereas some of the mutated enzymes showed a slight preference for NADPH, as does the nonmutated birch enzyme, the activity of some others greatly depended on the availability of NADH and was low with NADPH alone. Comparison of the mutations reveals that replacement of a single amino acid in the birch sequence (alanine871 by proline) is critical for the use of reducing substrate.
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PMID:The choice of reducing substrate is altered by replacement of an alanine by a proline in the FAD domain of a bispecific NAD(P)H-nitrate reductase from birch. 778 4

Nitrate reductase is a multiredox enzyme possessing three functional domains associated with the prosthetic groups FAD, heme iron, and molybdopterin. In Aspergillus nidulans, it is encoded by the niaD gene. A homologous transformation system has been used whereby a major deletion at the niiAniaD locus of the host was repaired by gene replacement. Employing site-directed mutagenesis and this transformation system, nine niaD mutants were generated carrying specific amino acid substitutions. Mutants in which alanine replaced cysteine 150, which is thought to bind the molybdenum atom of the molybdenum-pterin, and in which alanine replaced histidine 547, which putatively binds heme iron, had no detectable nitrate reductase (NAR) activity. This clearly establishes an essential catalytic role for these residues. Of the remaining mutants, all altered in the NADPH/FAD domain, two were temperature-sensitive for NAR activity, two had reduced NAR activity levels, and three had normal levels. Since some of these mutants change residues conserved between homologous nitrate reductases from a wide range of species, it is clear that such amino acid identities do not necessarily signify essential roles for the activity of the enzyme. These findings are considered in the light of predicted structural/functional roles for the altered amino acids.
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PMID:Site-directed mutagenesis of nitrate reductase from Aspergillus nidulans. Identification of some essential and some nonessential amino acids among conserved residues. 789 4

The structure of phthalate dioxygenase reductase (PDR), a monomeric iron-sulfur flavoprotein that delivers electrons from NADH to phthalate dioxygenase, is compared to ferredoxin-NADP+ reductase (FNR) and ferredoxin, the proteins that reduce NADP+ in the final reaction of photosystem I. The folding patterns of the domains that bind flavin, NAD(P), and [2Fe-2S] are very similar in the two systems. Alignment of the X-ray structures of PDR and FNR substantiates the assignment of features that characterize a family of flavoprotein reductases whose members include cytochrome P-450 reductase, sulfite and nitrate reductases, and nitric oxide synthase. Hallmarks of this subfamily of flavoproteins, here termed the FNR family, are an antiparallel beta-barrel that binds the flavin prosthetic group, and a characteristic variant of the classic pyridine nucleotide-binding fold. Despite the similarities between FNR and PDR, attempts to model the structure of a dissociable FNR:ferredoxin complex by analogy with PDR reveal features that are at odds with chemical crosslinking studies (Zanetti, G., Morelli, D., Ronchi, S., Negri, A., Aliverti, A., & Curti, B., 1988, Biochemistry 27, 3753-3759). Differences in the binding sites for flavin and pyridine nucleotides determine the nucleotide specificities of FNR and PDR. The specificity of FNR for NADP+ arises primarily from substitutions in FNR that favor interactions with the 2' phosphate of NADP+. Variations in the conformation and sequences of the loop adjoining the flavin phosphate affect the selectivity for FAD versus FMN. The midpoint potentials for reduction of the flavin and [2Fe-2S] groups in PDR are higher than their counterparts in FNR and spinach ferredoxin, by about 120 mV and 260 mV, respectively. Comparisons of the structure of PDR with spinach FNR and with ferredoxin from Anabaena 7120, along with calculations of electrostatic potentials, suggest that local interactions, including hydrogen bonds, are the dominant contributors to these differences in potential.
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PMID:Structural prototypes for an extended family of flavoprotein reductases: comparison of phthalate dioxygenase reductase with ferredoxin reductase and ferredoxin. 829 60

1. A soluble reduced Methyl Viologen-dependent assimilatory nitrate reductase from Azotobacter vinelandii strain UW136 grown aerobically on nitrate was purified to homogeneity by the criteria of nitrate reductase activity staining, and coincidence of a Coomassie Blue-staining protein band on polyacrylamide gels run under non-denaturing conditions. The specific activity was 3 mumol of NO2- formed/min per mg of protein. 2. Gel filtration on Superose-12 and SDS/PAGE showed that the enzyme had an M(r) of 105,000 and was monomeric. The enzyme contained 1 Mo atom, 4 Fe atoms and 4 acid-labile sulphide atoms per molecule; no evidence for the presence of cytochrome or FAD was found. 3. Mo was present in a molybdenum cofactor, which on extraction was capable of activating apo-(nit-1) nitrate reductase present in crude extracts of nit-1 mutants of Neurospora crassa. 4. As isolated, the enzyme had e.p.r. signals assigned to Mo(V) with g-values g1 = 2.023; g2 = 1.998; g3 = 1.993 and with gav. = 2.004 indicating an unusual environment of Mo in this enzyme. 5. Reduction with S2O4(2-) bleached the e.p.r. signals which, on reoxidation after the addition of NO3(2-) to initiate enzyme turnover, exhibited at short times Mo(V) signals similar to those of dissimilatory nitrate reductases, with g1 = 1.998; g2 = 1.989; g3 = 1.981 and gav. = 1.989. Prolonged incubation subsequently gave a mixture of both e.p.r. species. 6. Neither NADH nor NADPH was effective as an electron donor, but reduced Methyl Viologen (apparent Km 998 microM) and reduced Bromophenol Blue (apparent Km 158 microM) were effective. With these donors the apparent Km values for nitrate were 70 microM and 217 microM respectively.
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PMID:Purification and characterization of the assimilatory nitrate reductase of Azotobacter vinelandii. 838 Sep 91

Cell-free extracts of Pseudomonas sp. strains KB 740 and K 172 both contained high levels of glutaryl-CoA dehydrogenase when grown anaerobically on benzoate or other aromatic compounds and with nitrate as electron acceptor. These aromatic compounds have in common benzoyl-CoA as the central aromatic intermediate of anaerobic metabolism. The enzymatic activity was almost absent in cells grown aerobically on benzoate regardless whether nitrate was present. Glutaryl-CoA dehydrogenase activity was also detected in cell-free extracts of Rhodopseudomonas, Rhodomicrobium and Rhodocyclus after phototrophic growth on benzoate. Parallel to the induction of glutaryl-CoA dehydrogenase as measured with ferricenium ion as electron acceptor, an about equally high glutaconyl-CoA decarboxylase activity was detected in cell-free extracts. The latter activity was measured with the NAD-dependent assay, as described for the biotin-containing sodium ion pump glutaconyl-CoA decarboxylase from glutamate fermenting bacteria. Glutaryl-CoA dehydrogenase was purified to homogeneity from both Pseudomonas strains. The enzymes catalyse the decarboxylation of glutaconyl-CoA at about the same rate as the oxidative decarboxylation of glutaryl-CoA. The green enzymes are homotetramers (m = 170 kDa) and contain 1 mol FAD per subunit. No inhibition was observed with avidin indicating the absence of biotin. The N-terminal sequences of the enzymes from both strains are similar (65%).
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PMID:Purification of glutaryl-CoA dehydrogenase from Pseudomonas sp., an enzyme involved in the anaerobic degradation of benzoate. 843 37

Nitrate reductase from the yeast Candida nitratophila was found to contain one molecule of cytochrome b557 and one atom of molybdenum per subunit. FAD/haem-dependent diaphorase activity (haem domain) was associated with a 40 kDa tryptic fragment of the subunit. The 50 amino-terminal residues of this fragment were determined, and the sequence did not show significant similarity to deduced sequences of other nitrate reductases previously published. Increasing ionic strength in vitro had a stimulatory effect on enzymic activity via stimulation of the molybdenum-dependent terminal nitrate-reducing activity. Stimulation of activity by exogenous protein (bovine serum albumin or casein) also appeared to be an ionic effect. Stimulation of catalytic activity by phosphate was a separate effect.
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PMID:Further characterization of the assimilatory nitrate reductase from the yeast Candida nitratophila. 847 56

The nitrate reductase gene (niaD) and nitrite reductase gene (niiA) of Aspergillus parasiticus are clustered and are divergently transcribed from a 1.6-kb intergenic region (niaD-niiA). The deduced aminoacid sequence of the A. parasiticus nitrate reductase demonstrated a high degree of homology to those of other Aspergillus species, as well as to Leptosphaeria maculans, Fusarium oxysporum, Gibberella fujikuroi and Neurospora crassa, particularly in the cofactor-binding domains for molybdenum, heme and FAD. A portion of the deduced nitrite reductase sequence was homologous to those of A. nidulans and N. crassa. The nucleotide sequences in niaD-niiA of A. parasiticus and of A. oryzae were 95% identical, indicating that these two species are closely related. Several GATA motifs, the recognition sites for the N. crassa positive-acting global regulatory protein NIT2 in nitrogen metabolism, were found in A. parasiticus niaD-niiA. Two copies of the palindrome TCCGCGGA and other partial palindromic sequences similar to the target sites for the pathway specific regulatory proteins, N. crassa NIT4 and A. nidulans NirA, in nitrate assimilation, were also identified. A recombinant protein containing the A. nidulans AreA (the NIT2 equivalent) zinc finger and an adjacent basic region was able to bind to segments of niaD-niiA encompassing the GATA motifs. These results suggest that the catalytic and regulatory mechanisms of nitrate assimilation are well conserved in Aspergillus.
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PMID:Characterization of the Aspergillus parasiticus niaD and niiA gene cluster. 866 12

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