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)

The formation of aminoacids and proteins from the nitrogen which enters the roots as nitra t involves a complex reaction requiring energy. The first step requires a metalloflavoprotein, the nitrate reductase and the successive intervention of NADPH, FAD and reduced molybdenum which transfers electrons to nitrate and reduces it to nitrite. The following steps involve NADPH, FAD, Copper, Iron and Manganese, the last steps of the successive reductions being ammonia, needed for the aminoacids synthesis. The activity of the different enzymes are under the dependence of the genetic equipment of the plant, of the nitrogen and oligo-element nutrition and of the different factors acting on the photosynthesis.
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PMID:[Nitrates and nitrites in plants]. 2 19

Partially purified soluble rat liver guanylate cyclase [GTP pyrophosphate-lyase (cyclizing), EC 4.6.1.2] was activated by superoxide dismutase (superoxide: superoxide oxidoreductase, EC 1.15.1.1). This activation was prevented with KCN or glutathione, inhibitors of superoxide dismutase. Guanylate cyclase preparations formed superoxide ion. Activation by superoxide dismutase was further enhanced by the addition of nitrate reductase. Although guanylate cyclase activity was much greater with Mn2+ than with Mg2+ as sole cation cofactor, activation with superoxide dismutase was not observed when Mn2+ was included in incubations. Catalase also decreased the activation induced with superoxide dismutase. Thus, activation required the formation of both superoxide ion and H2O2 in incubations. Activation of guanylate cyclase could not be achieved by the addition of H2O2 alone. Scavengers of hydroxyl radicals prevented the activation. It is proposed that superoxide ion and hydrogen peroxide can lead to the formation of hydroxyl radicals that activate guanylate cyclase. This mechanism of activation can explain numerous observations of altered guanylate cyclase activity and cyclic GMP accumulation in tissues with oxidizing and reducing agents. This mechanism will also permit physiological regulation of guanylate cyclase and cyclic GMP formation when there is altered redox or free radical formation in tissues in response to hormones, other agents, and processes.
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PMID:Activation of guanylate cyclase by superoxide dismutase and hydroxyl radical: a physiological regulator of guanosine 3',5'-monophosphate formation. 2 77

Millimolar concentrations of tervalent manganese pyrophosphate can partially activate nitrate reductase which has been inactivated with NADH and HCN. The tervalent manganese complex is nevertheless not reduced by NADH in the presence of the enzyme, that is, it is not a substrate for the diaphorase moiety of the nitrate reductase. Ferric o-phenanthroline, on the other hand, is a good diaphorase substrate, but fails to activate the inactive enzyme.
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PMID:Nitrate reductase from Chlorella vulgaris. Reaction with manganese (III) pyrophosphate and with ferric o-phenanthroline. 18 Dec 48

Nitrate reductase (NaR) linked to reduced methyl viologen from Clostridium perfringens was purified by ammonium sulfate precipitation. DEAE-cellulose chromatography, disc electrophoresis on polyacrylamide gel, and triple DEAE-Sephadex chromatography. The specific activity was increased 1,200-fold with a yield of 9%. The purified preparation was nearly homogeneous in disc electrophoresis. It was brown, and its spectrum showed a slight shoulder near 420 nm as well as a peak at 280 nm. The molecular weight was found to be 90,000 based on s020,w (5.8S) and 80,000 by Sephadex G-100 gel filtration. In SDS-polyacrylamide electrophoresis, it showed only a single band with a molecular weight of 90,000; it had no subunit structure. The isoelectric point was pH 5.5, and the optimum pH was 9. Mn2+, Fe2+, Mg2+, and Ca2+ stimulated the activity. Km for nitrate was 0.10 mM, and nitrate was stoichiometrically reduced to nitrite in the presence of 2 mM Mn2+. Ferredoxin fraction obtained from extracts of the bacterium was utilizable as an electron donor at pH 8. Cyanide and azide inhibited the enzyme. The formation of NaR was induced by nitrate and inhibited by 0.5 mM tungstate, but recovered in the presence of 0.1 mM molybdate; NaR of C. perfringens appears to be a molybdo-iron-sulfur protein.
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PMID:Studies on nitrate reductase of Clostridium perfringens. Purification, some properties, and effect of tungstate on its formation. 20 90

Escherichia coli growing anaerobically respond to NO3- with a approximately 3-fold induction of active FeSOD and a approximately 5.5-fold induction of an inactive, but activatable form of MnSOD (pro-MnSOD). Paraquat, which mediates anaerobic electron flow to NO3-, increased the induction of pro-MnSOD to approximately 2.5-fold. Strains with defects in the SOD genes or which lacked nitrate reductase activity failed to accumulate active or pro-forms of SODs in response to NO3- +/- PQ++. Diamide caused anaerobic induction of active MnSOD and this effect was also observed in a glutathione-negative strain. These inductions required de novo synthesis of protein, even when cell content of pro-MnSOD had been elevated by exposure to NO3- +/- PQ++ prior to addition of diamide. These results indicate that oxidation of a cell component increases biosynthesis of the SOD gene product and this postulated oxidation can be caused by terminal electron acceptors, such as dioxygen or NO3-. In addition, it appears that insertion of the correct metal can be rate-limiting, leading to competition by other metals and to the accumulation of inactive, incorrectly substituted pro-forms. Metal insertion may be dependent upon the valence of the metal, which may be influenced, in turn, by the redox status of the cells. Diamide and redox active agents such as ferricyanide may thus allow anaerobic production of active MnSOD by favoring the production of a complexed form of Mn(III) which can compete favorably with other metal cations for the active site of nascent MnSOD.
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PMID:Anaerobic inductions of active forms of superoxide dismutases in Escherichia coli. 207 Oct 46

The toxicity of chromium and tin on growth, uptake of NO3- and NH4+, nitrate reductase and glutamine synthetase activity of Anabaena doliolum, and its interaction with bivalent cations, viz. Ca2+, Mg2+, Mn2+, Ni2+, Co2+, and Zn2+, has been studied. Some interacting cations, viz. Ca, Mg, and Mn, substantially antagonized the toxic effects of chromium and tin with reference to growth and nutrient (NO3- and NH4+) uptake in the hierarchical sequence Ca greater than Mg greater than Mn, whereas the sequence of hierarchy was Mn greater than Mg greater than Ca for nitrate reductase and glutamine synthetase activity of A. doliolum. A synergistically inhibitory pattern of interaction was noted for all the parameters, viz. growth, uptake of NO3- and NH4+, nitrate reductase and glutamine synthetase activity of A. doliolum, when Ni, Co, and Zn were used in combination with test metals in the growth medium. These bivalent cations followed the synergistic inhibition sequence Ni greater than Co greater than Zn and potentiated the toxicity of test metals in the N2-fixing cyanobacterium under study.
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PMID:Impact of chromium and tin on a nitrogen-fixing cyanobacterium Anabaena doliolum: interaction with bivalent cations. 256 5

Escherichia coli growing anaerobically respond to NO3- plus PQ2+ with a 20-30-fold induction of an inactive form of the manganese-containing superoxide dismutase (MnSOD). Mutants lacking a functional nitrate reductase fail to show this response. This inactive enzyme can be activated by addition of Mn(II) salts to cell extracts in the presence of acidic guanidinium chloride, followed by dialysis against neutral buffer. Direct addition of Mn(II) to cell extracts does not result in activation. However, addition of Mn(II) to purified apo-MnSOD results in partial activation. Inactive, reconstitutable MnSOD is induced 13-fold within 15 min of exposure to NO3- plus PQ2+. Western blot analysis revealed a 15-fold increase in immunoreactive MnSOD under these conditions, suggestive of de novo synthesis of this protein. A strain of E. coli bearing a multicopy plasmid carrying the MnSOD gene (sodA) overproduces inactive MnSOD 19-fold compared to the parent strain under anaerobic conditions. Strains of E. coli with an inactivating insertion in the sodA gene do not induce inactive, reconstitutable MnSOD in response to NO3- plus PQ2+ and lack the immunoreactive MnSOD band. These results, in toto, suggest that the inactive protein synthesized under anaerobic conditions in the presence of NO3- plus PQ2+, acting as an electron sink, is a product of the sodA gene and is devoid of activity due to occupation of the manganese site by another metal.
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PMID:Anaerobic induction of ProMn-superoxide dismutase in Escherichia coli. 264 72

Escherichia coli growing anaerobically respond to NO3- with a 3-fold induction of the iron-containing superoxide dismutase. Mutants lacking nitrate reductase do not show this response. Anaerobically grown cells also contain an inactive form of the manganese-containing superoxide dismutase (MnSOD) which can be activated by addition of Mn(II) salts in the presence of acidic guanidinium chloride, followed by dialysis against neutral buffer. Direct addition of Mn(II) to a neutral solution of the inactive MnSOD does not impart activity. This inactive MnSOD thus behaves as would the apoenzyme or the enzyme bearing a metal other than Mn(II) at its active sites. Terminal electron acceptors, such as NO3- or trimethylamine N-oxide, increase the amount of inactive MnSOD produced by anaerobic E. coli. Paraquat, which is itself ineffective in this regard, markedly augments the effect of these terminal electron acceptors. It appears that flow of electrons to sinks such as NO3- or trimethylamine N-oxide, facilitated by paraquat, is sufficient to elicit biosynthesis of the MnSOD protein and that O2- is not needed for this process. Yet, oxygenation and concomitant O2- production do appear important for the insertion of manganese into the growing MnSOD polypeptide, possibly because O-2 oxidizes Mn(II) to Mn(III), and the latter is the valence state most effective in combining with the apoenzyme.
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PMID:Inductions of superoxide dismutases in Escherichia coli under anaerobic conditions. Accumulation of an inactive form of the manganese enzyme. 327 33

In this report we address two questions regarding the regulation of phosphorylated nitrate reductase (pNR; EC 1.6.6.1) by 14-3-3 proteins. The first concerns the requirement for millimolar concentrations of a divalent cation in order to form the inactive pNR:14-3-3 complex at pH 7.5. The second concerns the reduced requirement for divalent cations at pH 6.5. In answering these questions we highlight a possible general mechanism involved in the regulation of 14-3-3 binding to target proteins. We show that divalent cations (e.g. Ca2+, Mg2+ and Mn2+) bind directly to 14-3-3s, and as a result cause a conformational change, manifested as an increase in surface hydrophobicity. A similar change is also obtained by decreasing the pH from pH 7.5 to pH 6.5, in the absence of divalent cations, and we propose that protonation of amino acid residues brings about a similar effect to metal ion binding. A possible regulatory mechanism, where the 14-3-3 protein has to be "primed" prior to binding a target protein, is discussed.
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PMID:Biological significance of divalent metal ion binding to 14-3-3 proteins in relationship to nitrate reductase inactivation. 987 66

Shewanella putrefaciens MR-1 has emerged as a good model to study anaerobic respiration and electron transport-linked metal reduction. Its remarkable respiratory plasticity suggests the potential for a complex regulatory system to coordinate electron acceptor use in the absence of O(2). It had previously been suggested that EtrA (electron transport regulator A), an analog of Fnr (fumarate nitrate regulator) from Escherichia coli, may regulate gene expression for anaerobic electron transport. An etrA knockout strain (ETRA-153) was isolated from MR-1 using a gene replacement strategy. Reverse transcription-PCR analysis of total RNA demonstrated the loss of the etrA mRNA in ETRA-153. ETRA-153 cells retained the ability to grow on all electron acceptors tested, including fumarate, trimethylamine N-oxide (TMAO), thiosulfate, dimethyl sulfoxide, ferric citrate, nitrate, and O(2), as well as the ability to reduce ferric citrate, manganese(IV), nitrate, and nitrite. EtrA is therefore not necessary for growth on, or the reduction of, these electron acceptors. However, ETRA-153 had reduced initial growth rates on fumarate and nitrate but not on TMAO. The activities for fumarate and nitrate reductase were lower in ETRA-153, as were the levels of fumarate reductase protein and transcript. ETRA-153 was also deficient in one type of ubiquinone. These results are in contrast to those previously reported for the putative etrA mutant METR-1. Molecular analysis of METR-1 indicated that its etrA gene is not interrupted; its reported phenotype was likely due to the use of inappropriate anaerobic growth conditions.
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PMID:Isolation and characterization of a Shewanella putrefaciens MR-1 electron transport regulator etrA mutant: reassessment of the role of EtrA. 1146 98

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