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)

Induced wildtype cells of A. nidulans rapidly lost NADPH--linked nitrate reductase activity when subjected to carbon and or nitrogen starvation. A constitutive mutant at the regulatory gene for nitrate reductase, nir Ac 1, rapidly lost nitrate reductase activity upon carbon starvation. This loss of activity is thought to be due to a decrease in the NADPH concentration in the cells. Cell free extracts from wildtype cells grown in the presence of nitrate, rapidly lost their nitrate reductase activity when incubated at 25 degrees C. NADPH prevented this loss of activity. Wildtype cells grown in the presence of nitrate and urea have a higher initial NADPH:NADP+ ratio and cell free extracts from such cells lost their nitrate reductase activity slower than extracts of cells grown with nitrate alone. The Pentose Phosphate Pathway mutant, pppB-1, had a lower NADPH concentration compared with the wildtype grown under the same conditions and cell free extracts lost their nitrate reductase activity more rapidly than the wildtype. Cell free extracts of nirAc-1 and a non-inducible mutant for nitrate reductase, nirA- -14, upon incubation lost little of their nitrate reductase activity.
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PMID:In vivo and in vitro studies of nitrate reductase regulation in Asperillus nidulans. 1 26

Electron paramagnetic resonance spectra obtained during turnover of the Mo center of NADH:nitrate reductase at pH 8 were comprised of two Mo(V) species, signal A (g1 = 1.996, g2 = 1.969, g3 = 1.967, A1H = 1.25 mT, A2H = 1.18 mT, and A3H = 1.63 mT) and signal B (g1 = 1.996, g2 = 1.969, and g3 = 1.967), the former exhibiting superhyperfine interaction due to strong coupling with a single, exchangeable proton. Binding of halides and nitrite to the Mo center increased the proportion of signal A whereas phosphate had no effect on the EPR line shape. Halides decreased and phosphate increased the rates of enzyme activities involving the Mo center (NADH:nitrate reductase and reduced methyl viologen:nitrate reductase), but neither had any effect on activities involving FAD (NADH:ferricyanide reductase) or heme (NADH:cytochrome c reductase), indicating specific binding of halides to the Mo center. Halides were found to be weak, mixed competitive-noncompetitive inhibitors (Cl- KI = 39 mM, mu = 0.2 M, pH 8) of nitrate reductase forming a catalytically inactive ternary halide-nitrate-enzyme complex. Inhibition patterns changed from nearly noncompetitive (F-) to nearly competitive (I-). The weakening of nitrate binding due to halide binding correlated with increased halide electronegativity rather than ionic radius. In contrast, phosphate (Kd = 7.4 mM, mu = 0.2 M, pH 8) and arsenate were determined to be nonessential activators, characterized by a constant value of (Vmax/Km)app, increasing nitrate reductase activity by weakening nitrate binding without affecting the stability of the transition state. Phosphate had no effect on product inhibition by nitrite (KI = 0.33 mM) or the oxidation-reduction midpoint potentials of the Mo center.
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PMID:EPR and kinetic analysis of the interaction of halides and phosphate with nitrate reductase. 255 63

Initial velocity studies of Chlorella nitrate reductase showed that increased ionic strength stimulated NADH:nitrate reductase activity by increasing both Vmax and Km for nitrate. Examination of the effect of ionic strength on the various partial activities of nitrate reductase revealed that while NADH:ferricyanide and reduced methyl viologen:nitrate reductase activities were unaffected by ionic strength, NADH:cytochrome c and reduced flavin:nitrate reductase activities were inhibited and stimulated by increased ionic strength, respectively. Comparison of the rates for the partial activities indicated electron transfer from heme to molybdenum to be the rate-limiting step in enzyme turnover. The pH optimum for NADH:nitrate reductase activity was found to be 7.9 while values for the partial activities ranged from 5.5 to 8.1. Phosphate was found to stimulate both NADH:nitrate and reduced methyl viologen:nitrate reductase activities indicating the molybdenum center as the site of interaction.
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PMID:Assimilatory nitrate reductase from Chlorella. Effect of ionic strength and pH on catalytic activity. 377 27

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

Chlorella nitrate reductase catalyzes the reduction of nitrate to nitrite by NADH. Initial velocity studies showed that the kinetic mechanism is sequential, indicating that both substrates must bind to the enzyme before any products are released. Product inhibition with NAD and nitrite showed that competitive inhibition was observed when the inhibitor was similar to the varied substrate, while noncompetitive inhibition was observed when the inhibitor was dissimilar to the varied substrate. Likewise, dead-end inhibition with adenosine 5'-diphosphoribose and thiocyanate showed competitive inhibition when the inhibitor was similar to the varied substrate and noncompetitive inhibition when the inhibitor was dissimilar to the varied substrate. These results indicate that Chlorella nitrate reductase follows a random bi bi kinetic mechanism. Phosphate was found to stimulate NADH:nitrate reductase activity and 2-fold. The NADH:cytochrome c reductase activity associated with nitrate reductase was not affected by phosphate suggesting the effect of phosphate is on the nitrate-reducing moiety of the enzyme. Phosphate increases Vmax but has no effect on the apparent Km for nitrate.
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PMID:Kinetic mechanism of assimilatory NADH:nitrate reductase from Chlorella. 627 5

Escherichia coli expresses two different membrane-bound respiratory nitrate reductases, nitrate reductase A (NRA) and nitrate reductase Z (NRZ). In this review, we compare the genetic control, biochemical properties and regulation of these two closely related enzyme systems. The two enzymes are encoded by distinct operons located within two different loci on the E. coli chromosome. The narGHJI operon, encoding nitrate reductaseA, is located in the chlC locus at 27 minutes, along with several functionally related genes: narK, encoding a nitrate/nitrite antiporter, and the narXL operon, encoding a nitrate-activated, two component regulatory system. The narZYWV operon, encoding nitrate reductase Z, is located in the chlZ locus located at 32.5 minutes, a region which includes a narK homologue, narU, but no apparent homologue to the narXL operon. The two membrane-bound enzymes have similar structures and biochemical properties and are capable of reducing nitrate using normal physiological substrates. The homology of the amino acid sequences of the peptides encoded by the two operons is extremely high but the intergenic regions share no related sequences. The expression of both the narGHJI operon and the narK gene are positively regulated by two transacting factors Fnr and NarL-Phosphate, activated respectively by anaerobiosis and nitrate, while the narZYWV operon and the narU gene are constitutively expressed. Nitrate reductase A, which accounts for 98% of the nitrate reductase activity when fully induced, is clearly the major respiratory nitrate reductase in E. coli while the physiological role of the constitutively expressed nitrate reductase Z remains to be defined.
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PMID:Nitrate reductases in Escherichia coli. 774 40

Phosphate starvation compromises electron flow through the cytochrome pathway of the mitochondrial electron transport chain, and plants commonly respond to phosphate deprivation by increasing flow through the alternative oxidase (AOX). To test whether this response is linked to the increase in nitric oxide (NO) production that also increases under phosphate starvation, Arabidopsis thaliana seedlings were grown for 15 d on media containing either 0 or 1mM inorganic phosphate. The effects of the phosphate supply on growth, the production of NO, respiration, the AOX level and the production of superoxide were compared for wild-type (WT) seedlings and the nitrate reductase double mutant nia. Phosphate deprivation increased NO production in WT roots, and the AOX level and the capacity of the alternative pathway to consume electrons in WT seedlings; whereas the same treatment failed to stimulate NO production and AOX expression in the nia mutant, and the plants had an altered growth phenotype. The NO donor S-nitrosoglutathione rescued the growth phenotype of the nia mutants under phosphate deprivation to some extent, and it also increased the respiratory capacity of AOX. It is concluded that NO is required for the induction of the AOX pathway when seedlings are grown under phosphate-limiting conditions.
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PMID:Nitric oxide induces the alternative oxidase pathway in Arabidopsis seedlings deprived of inorganic phosphate. 2616 3

The saprophytic actinobacterium Streptomyces coelicolor A3(2) requires oxygen for filamentous growth. Surprisingly, the bacterium also synthesizes three active respiratory nitrate reductases (Nar), which are believed to contribute to survival, or general fitness, of the bacterium in soil when oxygen becomes limiting. In this study, we analysed Nar3 and showed that activity of the enzyme is restricted to stationary-phase mycelium of S. coelicolor. Phosphate limitation was shown to be necessary for induction of enzyme synthesis. Nar3 synthesis was inhibited by inclusion of 20 mM phosphate in a defined 'switch assay' in which highly dispersed mycelium from exponentially growing cultures was shifted to neutral MOPS-glucose buffer to induce Nar3 synthesis and activity. Quantitative assessment of nar3 transcripts revealed a 30-fold induction of gene expression in stationary-phase mycelium. Transcript levels in stationary-phase mycelium incubated with phosphate were reduced by a little more than twofold, suggesting that the negative influence of phosphate on Nar3 synthesis was mainly at the post-transcriptional level. Furthermore, it was demonstrated that oxygen limitation was necessary to induce high levels of Nar3 activity. However, an abrupt shift from aerobic to anaerobic conditions prevented appearance of Nar3 activity. This suggests that the bacterium regulates Nar3 synthesis in response to the energy status of the mycelium. Nitrate had little impact on regulation of the Nar3 level. Together, these data identify Nar3 as a stationary-phase nitrate reductase in S. coelicolor and demonstrate that enzyme synthesis is induced in response to both phosphate limitation and hypoxia.
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PMID:Phosphate and oxygen limitation induce respiratory nitrate reductase 3 synthesis in stationary-phase mycelium of Streptomyces coelicolor A3(2). 2749