UNIPROT:Q8NEX9 - FACTA Search

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Query: UNIPROT:Q8NEX9 (reductase)
26,410 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

The biotransformation of glycerol trinitrate (GTN), isosorbide dinitrate (ISD), pentaerythritol tetranitrate (PETN), erythritol tetranitrate (ETN), and mannitol hexanitrate (MHN) by extracts from human liver, small intestine mucosa, kidney, and blood serum was investigated. The glutathione-dependent organic nitrate ester reductase activity of the intestinal mucosa was 21, 4, 4, and 2 times higher than the liver activity for ISD, PETN, GTN, and ETN, respectively. The liver enzymatic activity for MHN was 35% higher than the intestinal activity and 56% higher than kidney enzyme activity. The order of increasing enzymatic rates was: ISD = PETN less than GTN less than ETN less than MHN in the intestinal mucosa; ISD less than PETN less than GTN less than ETN less than MHN in the liver; and ISD less than PETN = GTN less than ETN less than MHN in the kidney. Human serum also metabolized these organic nitrates at lower rates than the studied organs. Thus, the serum specific activities were 1/5 for MHN, 1/30 for ETN, 1/40 for GTN, 1/44 for ISD, and 1/2000 for PETN of the activity present in kidney. On the other hand, the activity of human albumin was lower than that of blood serum. The serum and albumin activities were not modified by reduced glutathione or sulfhydryl inhibitors. These results suggest that small intestine may play an important role in the biotransformation of these drugs at their absorption site, after oral administration. They also demonstrate the possible participation of various human tissues in the overall metabolism of organic nitrate esters.
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PMID:Biotransformation of organic nitrate esters in vitro by human liver, kidney, intestine, and blood serum. 290 Jul 44

The NAD(P)H-dependent nitrate reductase system in Clostridium perfringens was reconstituted with rubredoxin (Rd), nitrate reductase (NaR), and an unadsorbed fraction, on a DEAE-cellulose column, of the extract (designated as fraction A), under nitrogen gas. Ferredoxin in place of Rd was not effective as an electron carrier in this reconstituted system. NAD(P)H-dependent nitrate reducing activity was also obtained by replacing fraction A with ferredoxin-NADP+ reductase from spinach. We propose the following scheme for the electron transfer in this NAD(P)H dependent nitrate reduction system. NAD(P)H----NAD(P)H-Rd reductase----Rd----NaR----NO3-.
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PMID:Rubredoxin as an intermediary electron carrier for nitrate reduction by NAD(P)H in Clostridium perfringens. 290 73

1. A Clark-type electrode that responds to nitric oxide has been used to show that cytoplasmic membrane vesicles of Paracoccus denitrificans have a nitric-oxide reductase activity. Nitrous oxide is the reaction product. NADH, succinate or isoascorbate plus 2,3,5,6-tetramethyl-1,4-phenylene diamine can act as reductants. The NADH-dependent activity is resistant to freezing of the vesicles and thus the NADH:nitric-oxide oxidoreductase activity of stored frozen vesicles provides a method for calibrating the electrode by titration of dissolved nitric oxide with NADH. The periplasmic nitrite reductase and nitrous-oxide reductase enzymes are absent from the vesicles which indicates that nitric-oxide reductase is a discrete enzyme associated with the denitrification process. This conclusion was supported by the finding that nitric-oxide reductase activity was absent from both membranes prepared from aerobically grown P. denitrificans and bovine heart submitochondrial particles. 2. The NADH: nitric-oxide oxidoreductase activity was inhibited by concentrations of antimycin or myxothiazol that were just sufficient to inhibit the cytochrome bc1 complex of the ubiquinol--cytochrome-c oxidoreductase. The activity was deduced to be proton translocating by the observations of: (a) up to 3.5-fold stimulation upon addition of an uncoupler; and (b) ATP synthesis with a P:2e ratio of 0.75. 3. Nitrite reductase of cytochrome cd1 type was highly purified from P. denitrificans in a new, high-yield, rapid two- or three-step procedure. This enzyme catalysed stoichiometric synthesis of nitric oxide. This observation, taken together with the finding that the maximum rate of NADH:nitric-oxide oxidoreductase activity catalysed by the vesicles was comparable with that of NADH:nitrate-oxidoreductase, is consistent with a role for nitric-oxide reductase in the physiological conversion of nitrate or nitrite to dinitrogen gas. 4. Intact cells of P. denitrificans also reduced nitric oxide in an antimycin- or myxothiazol-sensitive manner. However, nitric oxide was not detected by the electrode during the reduction of nitrate. Nitric-oxide synthesis from nitrate could be detected with cells in the presence of very low concentrations of Triton X-100 which selectively inhibits nitric-oxide reductase activity. 5. Nitric oxide was detected as an intermediate in denitrification by including haemoglobin with an anaerobic suspension of cells that was reducing nitrate. The characteristic spectrum of the nitric oxide derivative of haemoglobin was observed.(ABSTRACT TRUNCATED AT 400 WORDS)
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PMID:The energy-conserving nitric-oxide-reductase system in Paracoccus denitrificans. Distinction from the nitrite reductase that catalyses synthesis of nitric oxide and evidence from trapping experiments for nitric oxide as a free intermediate during denitrification. 292 Jul 32

Assimilatory nitrate reductase from Chlorella is a homotetramer which contains one of each of the prosthetic groups FAD, heme, and molybdenum per subunit. Besides the reduction of nitrate by NADH, nitrate reductase also catalyzes the partial activities NADH:cytochrome c reductase, NADH:ferricyanide reductase, and reduced methyl viologen:nitrate reductase. Incubation of native nitrate reductase with either trypsin, Staphylococcus aureus V8 protease, or a natural inactivator protease from corn results in a loss of NADH:nitrate reductase and NADH:cytochrome c reductase activities but no loss of reduced methyl viologen:nitrate reductase activity. Incubation of nitrate reductase with V8 protease or corn inactivator protease resulted in two different products, each of which retained a different partial activity. Reduced methyl viologen:nitrate reductase activity was associated with a homotetrameric fragment of about 260 kDa which contained heme and molybdenum but no FAD. The molecular mass of native nitrate reductase determined under the same conditions was 375 kDa. NADH:ferricyanide reductase activity was associated with a monomeric species of approximately 30 kDa which contained FAD and the NADH-binding site. These results are consistent with a structure-function model of nitrate reductase which has the following features: FAD/NADH-binding domains exposed on the surface of the molecule, a protease-sensitive hinge region which connects the nitrate-reducing and NADH dehydrogenase moieties, and the quaternary structure maintained via association sites on the heme/molybdenum domain.
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PMID:Functional domains of assimilatory NADH:nitrate reductase from Chlorella. 301 63

The endogenous formation of apparent total N-nitroso compounds (ATNC) has been investigated in germ-free (GF) and conventional (CV) microflora rats as a function of the drinking-water nitrate concentration. ATNC levels were below the 40 micrograms (N-NO)/kg detection limit in the blood, liver, kidney, spleen and small intestine of all CV and GF rats. For the CV rats ATNC were detected in concentrations of up to 370 micrograms (N-NO)/kg in the large intestine and up to 50 micrograms (N-NO)/kg in the stomach and there was a significant positive correlation between ATNC formation and the drinking-water nitrate level. Comparison of these results with those from GF rats showed that the ATNC in the stomach and large intestine of the CV animals were formed by microbial action, most probably involving bacterial nitrate-reductase activity.
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PMID:An investigation of the endogenous formation of apparent total N-nitroso compounds in conventional microflora and germ-free rats. 318 35

Fumarate reductase catalyzes the terminal step of anaerobic electron transport with fumarate as a terminal electron acceptor. Transcription of the fumarate reductase (frdABCD) operon in Escherichia coli is repressed in the presence of the preferred terminal electron acceptors, oxygen and nitrate. To identify trans-acting genes involved in regulation by nitrate, a number of E. coli mutants were generated in which expression of a frdA'-'lacZ protein fusion was no longer fully repressed by nitrate. One of these mutants, strain LK23R35, exhibited 17-fold higher beta-galactosidase activity than the wild-type strain when grown anaerobically in the presence of nitrate. When grown aerobically in the presence of nitrate, it contained three- to fourfold more beta-galactosidase activity than the wild-type strain did. Oxygen regulation of frd expression, however, was unaffected by the mutation, since the level of beta-galactosidase activity in both strains was nearly identical when they were grown in the absence of nitrate either aerobically or anaerobically. To confirm that the mutation acts in trans to frdABCD, we measured fumarate reductase levels and found them to parallel FrdA'-beta-galactosidase activity under all growth conditions tested. The effect of the mutation is pleiotropic, since the levels of nitrate reductase in LK23R35 were not induced by the addition of nitrate. The frdR mutant was also derepressed for nitrate control of the trimethylamine-N-oxide reductase and alcohol dehydrogenase enzymes. The mutation maps in a region between trp and hemA at 27 min on the E. coli chromosome. This gene, where we call frdR, is involved in both positive and negative regulation of electron transport and fermentation associated genes. A cloned 4.9-kilobase fragment of chromosomal DNA was found to complement the frdR mutation; both repression of fumarate reductase gene expression and activation of nitrate reductase gene expression were restored.
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PMID:The frdR gene of Escherichia coli globally regulates several operons involved in anaerobic growth in response to nitrate. 327 62

1. The b-type haem centres of the three (alpha, beta and gamma) subunit nitrate reductase from Paracoccus denitrificans have been analysed by redox potentiometry. Two components were identified with mid-point potentials +95 mV and +210 mV. 2. Washing, in the absence of Mg2+ ions, of cytoplasmic membrane vesicles from P. denitrificans promoted selective release of nitrate reductase activity. The released enzyme was purified by chromatography and shown to contain alpha and beta, but not gamma polypeptides. A haem spectrum was absent, consistent with the lack of the gamma subunit. The alpha and beta polypeptides of the water-soluble nitrate reductase had molecular masses that were identical to those of the detergent-purified enzyme and also of the nitrate reductase in cytoplasmic membranes. This observation, together with the failure of protease inhibitors to prevent release from the membrane, indicates that the release is not related to limited proteolysis of the alpha and/or beta polypeptides. The relative molecular mass of the water-soluble alpha beta enzyme was estimated to be approximately 200,000. 3. The water-soluble nitrate reductase was released from intact inverted cytoplasmic membrane vesicles as judged by loss of NADH-NO3- reductase activity and retention by the vesicles after washing of uncoupler-sensitive NADH-oxidase activity. These observations show that alpha and beta polypeptides, and therefore the active site for nitrate reduction, are located on the cytoplasmic side of the membrane. 4. Attempts to reverse the nitrate reductase activity of the enzyme, using nitrate as reductant plus ferricyanide or chlorate as tested oxidants, were unsuccessful. The implications for the mechanism of the enzyme are discussed.
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PMID:Respiratory nitrate reductase from Paracoccus denitrificans. Evidence for two b-type haems in the gamma subunit and properties of a water-soluble active enzyme containing alpha and beta subunits. 337 62

Fumarate reductase (encoded by frd) and succinate dehydrogenase (encoded by sdh) of Escherichia coli are both known to catalyze the interconversion of fumarate and succinate. Fumarate reductase, however, is not inducible aerobically and therefore cannot participate in the dehydrogenation of succinate. Three classes of suppressor mutants, classified as frd oxygen-resistant [frd(Oxr)], constitutive [frd(Con)], and gene amplification [frd(Amp)] mutants, were selected from an sdh strain as pseudorevertants that regained the partial ability to grow aerobically on succinate. All contained increased aerobic levels of fumarate reductase activity. In frd(Oxr) mutants expression of the operon showed increased resistance to aerobic repression. Under anaerobic conditions expression of the operon became less dependent on the fnr+ gene product, a pleiotropic activator protein for genes encoding anaerobic respiratory enzymes. Exogenous fumarate, however, was still required for full induction, and repression by nitrate was undiminished. Thus, aerobic repression and anaerobic nitrate repression appear to involve separate mechanisms. In frd(Con) mutants expression of the operon became highly resistant to aerobic repression. Under anaerobic conditions expression of the operon no longer required the fnr+ gene product or exogenous fumarate and became immune to nitrate repression. In partial diploids bearing an frd(Oxr) or an frd(Con) allele and phi(frd+-lac) there was no mutual regulatory influence between the two genetic loci. Thus, the frd mutations act in cis and hence are probably in the promoter region. In frd(Amp) mutants the frd locus was amplified without significant alteration in the pattern of regulation.
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PMID:Three classes of Escherichia coli mutants selected for aerobic expression of fumarate reductase. 353 78

During anaerobic growth, Escherichia coli can reduce phosphomolybdate. The reduction can also be carried out by washed cells suspended in buffer at pH 5.7. Phosphate, molybdate, glucose, cells, and anaerobic conditions are required. Reduction is inhibited by 200 microM chromate, 290 microM nitrite, 10 mM tungstate, or 20 mM cysteine. Wild-type (chl+) cells are inhibited by addition of 200 microM nitrate, but chlA, chlB, and chlE mutants are not. The inhibition of chl+ cells results from reduction of nitrate to nitrite. This nitrate reduction is not catalyzed by nitrate reductase. Wild-type cells are more sensitive than chl mutants to inhibition by nitrite and cysteine but more resistant to chromate. Pregrowth of chlD cells in 1 mM Na2MoO4 increases their sensitivity to nitrite and cysteine, and pregrowth of chl+ cells in 1 mM Na2MoO4 increases their resistance to these agents. Assays of biotin sulfoxide reductase show that the tightness of the chlD block depends on growth conditions; chlD cells grown aerobically in tryptone broth make about 50% as much active enzyme as chl+ cells, whereas chlD cells grown anaerobically with tryptone plus glucose make less than 10%. The effect of anaerobic pregrowth on the inhibition of molybdate reduction by added nitrate indicates that in vivo nitrate reduction responds to growth conditions in the same manner as biotin sulfoxide reductase does.
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PMID:Molybdate reduction by Escherichia coli K-12 and its chl mutants. 388 54

Escherichia coli grew anaerobically on a minimal medium with glycerol as the carbon and energy source and dimethyl sulfoxide (DMSO) as the terminal electron acceptor. DMSO reductase activity, measured with an artificial electron donor (reduced benzyl viologen), was preferentially associated with the membrane fraction (77 +/- 10% total cellular activity). A Km for DMSO reduction of 170 +/- 60 microM was determined for the membrane-bound activity. Methyl viologen, reduced flavin mononucleotide, and reduced flavin adenine dinucleotide also served as electron donors for DMSO reduction. Methionine sulfoxide, a DMSO analog, could substitute for DMSO in both the growth medium and in the benzyl viologen assay. DMSO reductase activity was present in cells grown anaerobically on DMSO but was repressed by the presence of nitrate or by aerobic growth. Anaerobic growth on DMSO coinduced nitrate, fumarate, and and trimethylamine-N-oxide reductase activities. The requirement of a molybdenum cofactor for DMSO reduction was suggested by the inhibition of growth and a 60% reduction in DMSO reductase activity in the presence of 10 mM sodium tungstate. Furthermore, chlorate-resistant mutants chlA, chlB, chlE, and chlG were unable to grow anaerobically on DMSO. DMSO reduction appears to be under the control of the fnr gene.
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PMID:Dimethyl sulfoxide reductase activity by anaerobically grown Escherichia coli HB101. 388 58

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