EC:1.7.1.2 - FACTA Search

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Query: EC:1.7.1.2 (nitrate reductase)
3,861 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

1. Respiratory nitrate reductase of Bacillus licheniformis was extracted from the bacterial membranes by treatment with deoxycholate and purified to a homogeneous state by means of gel chromatography and anion-exchange chromatography. 2. The enzyme (Mr = 193,000, s20, w = 8.6) consists of two subunits, having apparent molecular weight of 150,000 (alpha subunit) and 57,000 (beta subunit), which are present in an equimolar ratio. It does not contain carbohydrate. Ageing of the enzyme appears to result in splitting of the polypeptide chains at specific sites followed by dissociation and reassociation of the digestion products in various combinations. 3. In contrast to Klebsiella aerogenes repiratory nitrate reductase, which is isolated in a tetrameric form that can be reversibly dissociated into a monomeric form by detergents, B. licheniformis nitrate reductase, after isolation, is always present in a monomeric form. This property is related to the difference in membrane localization of the enzyme in the two organisms. 4. B licheniformis nitrate reductase contains 6.9 atoms of non-heme iron, 6.7 atoms of acid-labile sulfide and 0.93 atoms of molybdenum per molecule of enzyme. The molybdenum seems to be part of a low-molecular weight peptide Mo-cofactor) to which it may be bound by interaction with thiol-groups. 5. Antiserum against the native enzyme contains antibodies against both subunits as well as the Mo-cofactor. The Mo-cofactor does not have any antigenic determininants in common with either the alpha or the beta subunit. Also neither subunit cross-reacts with antiserum against the other subunit. Whereas the respiratory nitrate reductases from K. aerogenes and Escherichia coli are immunologically related, the native enzyme from B. licheniformis does not show any cross-reaction with antiserum prepared against either the K. aerogenes or the E. coli enzyme.
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PMID:Purification and characterization of the respiratory nitrate reductase of Bacillus licheniformis. 10 96

Five temperature-sensitive chlC mutants were isolated from Escherichia coli by the technique of localized mutagenesis. All of the mutants produced severely reduced levels of both nitrate reductase and formate dehydrogenase when grown at 43 degrees C. In three of the mutants, the nitrate reductase activity produced at the permissive temperature was shown to be thermolabile compared with the activity produced by the parent wild-type strain, both in membrane preparations and in preparations released from the membrane by deoxycholate. In each case, formate dehydrogenase activity was similar to the wild-type activity in its stability to heat. It is concluded that the chlC gene codes for at least one of the polypeptide chains of nitrate reductase and that the chlC mutations affect indirectly the formation of formate dehydrogenase.
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PMID:Role of the chlC gene in formation of the formate-nitrate reductase pathway in Escherichia coli. 34 99

The cytoplasmic nitrate reductase in heme mutant H-14 of Staphylococcus aureus was partially purified by steps which included ammonium sulfate fractionation and chromatography on Bio-Gel A 1.5m and ion-exchange columns. The active fractions from the ion-exchange columns showed two forms of the enzyme upon electrophoresis in nondenaturing gels of polyacrylamide; these corresponded to proteins of R(f) 0.16 and 0.28. Each form contained a predominant polypeptide of molecular weight 140,000, as shown by sodium dodecyl sulfate-polyacrylamide gel electrophoresis. The R(f) 0.16 form contained another major polypeptide of molecular weight 57,000, but the R(f) 0.28 form contained several other polypeptides. The sedimentation properties of the enzyme were examined after partial purification on Bio-Gel A 1.5m. In sucrose gradients containing Triton X-100 the enzyme sedimented as a homogeneous peak with an estimated molecular weight of 225,000; without detergent a heterogeneous profile was observed of molecular weight greater than 250,000. Treatment of the enzyme with trypsin increased the specific activity, and the enzyme sedimented as a homogeneous peak in sucrose gradients without Triton X-100, with an estimated molecular weight of 202,000. Sodium dodecyl sulfate-polyacrylamide gel electrophoresis indicated that trypsin treatment converted the polypeptide of molecular weight 140,000 to a polypeptide of molecular weight 112,000. We conclude that the cytoplasmic nitrate reductase of S. aureus has a large subunit of molecular weight 140,000, which can be modified by trypsin to a polypeptide of molecular weight 112,000 without loss of catalytic activity.
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PMID:Partial purification and some properties of the Staphylococcus aureus cytoplasmic nitrate reductase. 45 98

Mutants of A. nidulans at several loci lack detectable NADPH-nitrate reductase activity. These loci include niaD, the structural gene for the nitrate reductase polypeptide, and five other loci termed cnxABC, E, F, G and H which are presumed to be involved in the formation of a molybdenum-containing component (MCC) necessary for nitrate reductase activity. When forzen mycelia from A. nidulans deletion mutant niaD26 were homogenized in a Ten Broeck homogenizer together with frozen mycelia from either cnxA6, cnxE29, cnsF12, cnxG4 or cnxH3 strains grown on urea + nitrate as the nitrogen source, nitrate reductase activity was detectable in the extract. Similar results were obtained by co-homogenizind niaD mycelia with Neurospora crassa nit-1 mycelia induced on nitrate. Thus, all A. nidulans cnx mutants are similar to the N. crassa nit-1 strain in their capacity to yield NADPH-nitrate reductase in the presence of the presumed MCC. As judged by the amounts of nitrate reductase formed, niaD26 mycelia grown on urea +/- nitrate contained much more available MCC than ammonium-grown mycelia. No NADPH-nitrate reductase activity was found in extracts prepared by co-homogenizing mycelia from all five A. nidulans cnx strains. Wild-type A. nidulans NADPH-nitrate reductase acid dissociated by adjustment to pH 2.0-2.5 AND RE-ADJUSTED TO PH 7 could itself re-assemble to form active nitrate reductase and thus was not a useful source of MCC for these experiments. These results are consistent with the conclusion that the active nitrate reductase complex is composed of polypeptide components which are the niaD gene product, plus the MCC which is formed through the combined action of the cnx gene products. Further, the production of MCC may be regulated in response to the nitrogen nutrition available to the organism.
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PMID:Formation of NADPH-nitrate reductase activity in vitro from Aspergillus nidulans niaD and cnx mutants. 79 78

DNA probes from the narG gene of Escherichia coli, which encodes the large polypeptide of respiratory nitrate reductase, show cross-hybridization at low stringency to a single region of the genome of the cyanobacterium Synechococcus PCC6301. This segment of cyanobacterial DNA was cloned as the insert of plasmid pDN1 and characterized. RNA complementary to pDN1 was shown to be substantially more abundant in nitrate grown cells of Synechococcus PCC6301 than in ammonium grown cells, thus parallelling the nitrate induction and ammonium repression of nitrate reductase activity in cultures of this cyanobacterium. A mutant of Synechococcus PCC6301 deficient in nitrate reductase activity was obtained after a potentially mutagenic transformation treatment using pDN1 as a donor. This mutant was restored to the wild type phenotype following stable integrative transformation with pDN1 DNA. Taken together these data suggest that pDN1 might encode a polypeptide of nitrate reductase. pDN1 is distinct from three clones of genes involved in nitrate assimilation that were isolated previously from the related cyanobacterium Synechococcus PCC7942 (Kuhlemeier et al., 1984a, J. Bact. 159, 36-41, and 1984b, Gene 31, 109-116).
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PMID:A nitrate reductase gene of the cyanobacterium Synechococcus PCC6301 inferred by heterologous hybridization, cloning and targeted mutagenesis. 137 36

The nitrate reductase (NR) structural gene (nitA) of Volvox carteri has been cloned and characterized. There is a single copy of this gene in the genome, and RFLP (restriction-fragment length polymorphism) analysis assigns it to the previously defined nitA/chlR locus on linkage group IX, 20-30 cM from the two beta-tubulin-encoding loci. Determination of the 5871-nt sequence of the coding region of genomic clones, and comparisons to a cDNA sequence, revealed ten introns and eleven exons that encode a 864-aa polypeptide. Detailed comparisons with higher-plant and fungal NRs indicate that, whereas the aa sequence is strongly conserved within functional domains for the flavin adenine dinucleotide-, heme- and molybdenum-pterin cofactor-binding sites, substantial differences in the aa sequence occur in the N-terminal end and the two inter-domain regions. Two potential transcription start points 439 and 452 nt upstream from the start codon and a polyadenylation signal 355 nt downstream from the stop codon have been identified by primer-extension analysis and cDNA sequencing, respectively. Accumulation of the nitA transcript is both induced by nitrate and repressed by ammonium and urea: after the organism is transferred from ammonium to nitrate as the nitrogen source, a 3.6-kb NR transcript is readily detectable on Northern blots by 10 min, reaches maximum abundance by 30 min, and then rapidly declines to an intermediate level that is subsequently maintained. Substantial induction by nitrate is observed at the end of the dark portion of the daily light/dark cycle, but the inductive response peaks in the first hour of the light period.(ABSTRACT TRUNCATED AT 250 WORDS)
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PMID:The nitrate reductase-encoding gene of Volvox carteri: map location, sequence and induction kinetics. 139 26

A biochemical and immunological study has revealed a new formate dehydrogenase isoenzyme in Escherichia coli. The enzyme is an isoenzyme of the respiratory formate dehydrogenase (FDH-N) which forms part of the formate to nitrate respiratory pathway found in the organisms when it is grown anaerobically in the presence of nitrate. The new enzyme, termed FDH-Z, cross reacts with antibodies raised to FDH-N and possesses a similar polypeptide composition to FDH-N. FDH-Z catalyses the phenazine methosulphate-linked formate dehydrogenase activity present in the aerobically-grown bacterium. FDH-Z and FDH-N exhibit distinct regulation. Like formate dehydrogenase N, formate dehydrogenase Z is a membrane-bound molybdoenzyme. With nitrate reductase it can catalyse electron transfer between formate and nitrate. Quinones are required for the physiological electron transfer to nitrate. It seems likely that like FDH-N, FDH-Z functions physiologically as a formate: quinone oxidoreductase.
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PMID:A second phenazine methosulphate-linked formate dehydrogenase isoenzyme in Escherichia coli. 150 73

Two membrane-bound nitrate reductases, NRA and NRZ, exist in Escherichia coli. Both isoenzymes are composed of three structural subunits, alpha, beta, and gamma encoded by narG/narZ, narH/narY and narI/narV, respectively. The genes are in transcription units which also contain a fourth gene encoding a polypeptide, delta, which is not part of the final enzyme. A strain which is devoid of, or does not express, the nar genes, was used to investigate the role of the delta and gamma polypeptides in the formation and/or processing of the nitrate reductase. When only the alpha and beta polypeptides are produced, an (alpha beta) complex exists which is inactive and soluble. When the alpha, beta and delta polypeptides are produced, the (alpha beta) complex is active with artificial donors such as benzyl viologen but is soluble. When the alpha, beta and gamma polypeptides are produced, the (alpha beta) complex is inactive but partially binds the membrane. It was concluded that the gamma polypeptide is involved in the binding of the (alpha beta) complex to the membrane while the delta polypeptide is indispensable for the (alpha beta) nitrate reductase activity. The activation by the delta polypeptide does not seem to involve the insertion of the redox centres of the enzyme since the purified inactive (alpha beta) complex was shown to contain the four iron-sulphur centres and the molybdenum cofactor, which are normally present in the native purified enzyme. The extreme sensitivity of this inactive complex to thermal denaturation or tryptic treatment favours the idea that the delta polypeptide promotes the correct assembly of the alpha and beta subunits. Although this corresponds to the definition of a chaperone protein this possibility has been rejected. In this study we have also demonstrated that the delta or gamma polypeptide encoded by one nar operon can be substituted successfully for by its respective counterpart from the other nar operon to give an active membrane bound heterologous nitrate reductase enzyme.
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PMID:Involvement of the narJ or narW gene product in the formation of active nitrate reductase in Escherichia coli. 154 6

Barley (Hordeum vulgare L.) has both NADH-specific and NAD(P)H-bispecific nitrate reductases. Genomic and cDNA clones of the NADH nitrate reductase have been sequenced. In this study, a genomic clone (pMJ4.1) of a second type of nitrate reductase was isolated from barley by homology to a partial-length NADH nitrate reductase cDNA and the sequence determined. The open reading frame encodes a polypeptide of 891 amino acids and its interrupted by two small introns. The deduced amino acid sequence has 70% identity to the barley NADH-specific nitrate reductase. The non-coding regions of the pMJ4.1 gene have low homology (ca. 40%) to the corresponding regions of the NADH nitrate reductase gene. Expression of the pMJ4.1 nitrate reductase gene is induced by nitrate in root tissues which corresponds to the induction of NAD(P)H nitrate reductase activity. The pMJ4.1 nitrate reductase gene is sufficiently different from all previously reported higher plant nitrate reductase genes to suggest that it encodes the barley NAD(P)H-bispecific nitrate reductase.
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PMID:Characterization and sequence of a novel nitrate reductase from barley. 189 7

The nucleotide sequence of the Aspergillus nidulans crnA gene for the transport of the anion nitrate has been determined. The crnA gene specifies a predicted polypeptide of 483 amino acids (molecular weight 51,769). A hydropathy plot suggests that this polypeptide has 10 membrane-spanning helices with an extensive hydrophilic region between helices six and seven. No striking homology was observed between the crnA protein and other reported membrane proteins of either prokaryotic or eukaryotic organisms, indicating that the crnA transporter may represent another class of membrane protein. Northern blotting results with wild-type cells show that (i) control of crnA expression is subject to nitrate (and nitrite) induction as well as nitrogen metabolite repression and (ii) regulation of the crnA gene is exerted at the level of mRNA accumulation, most likely at transcription, in response to the nitrogen source in the growth medium. Furthermore, similar studies with mutants of nirA and areA control genes and the niaD nitrate reductase structural gene show that crnA expression is mediated by the products of nirA (nitrate induction control gene), areA (nitrogen metabolite repression control gene), and niaD (involved in autoregulation of nitrate reductase).
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PMID:crnA encodes a nitrate transporter in Aspergillus nidulans. 198 67

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