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)

Lysozyme digestion and sonication of sodium dodecyl sulfate (SDS)-purified Klebsiella aerogenes murein sacculi resulted in the quantitative release of both subunits of nitrate reductase, as well as a number of other cytoplasmic membrane polypeptides (5.2%, by weight, of the total membrane proteins). Similar results were obtained after lysozyme digestion of SDS-prepared peptidoglycan fragments, which excluded the phenomenon of simple trapping of the polypeptides by the surrounding peptidoglycan matrix. About 28% of membrane-bound nitrate reductase appears to be tightly associated with the peptidoglycan. Additional evidence for this association was demonstrated by positive immunogold labeling of SDS-murein sacculi and thin sections of plasmolyzed bacteria. Qualitative amino acid analysis of trypsin-treated sacculi, a tryptic product of holo-nitrate reductase, and amino- and carboxypeptidase digests of both nitrate reductase subunits indicated the possible existence of a terminal anchoring peptide containing the following amino acids: (Gly)n, Trp, Ser, Pro, Ile, Leu, Phe, Cys, Tyr, Asp, and Lys.
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PMID:Part of respiratory nitrate reductase of Klebsiella aerogenes is intimately associated with the peptidoglycan. 354 73

NADH-dependent nitrate reductase (E.C. 1.6.6.1) was ultrastructurally localized in norflurazon-treated and control soybean cotyledons [Glycine max (L.) Merr.] by a method based upon the increase in osmiophilia due to the formation of an azo dye. The reaction product was observed in small vesicles throughout the cytoplasm. An apparent transport of nitrite to the plastid, the site of nitrite reduction, may occur through fusion of the nitrite-containing vesicles with the chloroplast envelope. Plants grown in tungstate lacked nitrate reductase activity as measured by standard assay procedures, and showed no increase in osmiophilia, suggesting a degree of specificity of this cytochemical procedure.
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PMID:Histochemical localization of nitrate reductase. 719 1

Incubation of either Chlorella nitrate reductase or the recombinant flavin domain of spinach nitrate reductase with reagents specific for modification of cysteine residues, such as N-ethylmaleimide, resulted in a time-dependent inactivation of NADH:ferricyanide reductase activity which could be prevented by incubation in the presence of NADH. At 25 degrees C and employing a fixed enzyme:modifier ratio, the rate of inactivation for both the Chlorella and spinach enzymes followed the order p-chloromercuribenzoate > methyl methanethiosulfonate > 2-(4'-maleimidylanilino)naphthalene-6-sulfonic acid > N-ethylmaleimide. For the spinach flavin domain, inactivation by methyl methanethiosulfonate or p-chloromercuribenzoate was found to be concentration independent suggesting the absence of nonspecific modifications. Initial rate studies of the methyl methanethiosulfonate-modified flavin domain indicated a reduction in NADH:ferricyanide activity (Vmax) from 85 to 44 micromol NADH consumed/min/nmol FAD and an increase in the Km for NADH from 12 to 35 microM when compared to the native enzyme, confirming a role for cysteine residue(s) in maintaining diaphorase activity. Site-directed mutagenesis of the four individual cysteines (residues 17, 54, 62, and 240) in the recombinant spinach flavin domain resulted in mutant proteins with visible and CD spectra very similar to those of the wild-type domain. Initial rate studies indicated that only substitutions of serine for cysteine 240 decreased diaphorase activity with maximal NADH:ferricyanide activity for the C240S mutant corresponding to 51 micromol NADH consumed/min/nmol FAD with a Km for NADH of 14 microM. Mutation of C240 to Ala or Gly resulted in greater loss of activity. The thermal stability of the four serine mutants was slightly decreased compared to the wild-type domain with the C62S mutant exhibiting the greatest instability. In contrast to the effects on diaphorase activity, square wave voltammetric studies indicated changes in the oxidation-reduction midpoint potential for the FAD/FADH2 couple in the C54S (E0'= -197 mV), C62S (E0' = -226 mV), and C240S (E0' = -219 mV) mutants compared to the wild-type domain (E0' = -268 mV). These results indicate that of the four cysteine residues in the spinach nitrate reductase flavin domain, only C240 plays a role in maintaining diaphorase activity, while C54 has the greatest influence on flavin redox potential and that no correlation between changes in catalytic activity and flavin redox potential was observed.
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PMID:Thiol modification and site directed mutagenesis of the flavin domain of spinach NADH:nitrate reductase. 866 Jun 90

We describe the primary structure of eukaryotic molybdopterin synthase small and large subunits and compare the sequences of the lower eukaryote, Aspergillus nidulans, and a higher eukaryote, Homo sapiens. Mutants in the A. nidulans cnxG (encoding small subunit) and cnxH (large subunit) genes have been analyzed at the biochemical and molecular level. Chlorate-sensitive mutants, all the result of amino acid substitutions, were shown to produce low levels of molybdopterin, and growth tests suggest that they have low levels of molybdoenzymes. In contrast, chlorate-resistant cnx strains have undetectable levels of molybdopterin, lack the ability to utilize nitrate or hypoxanthine as sole nitrogen sources, and are probably null mutations. Thus on the basis of chlorate toxicity, it is possible to distinguish between amino acid substitutions that permit a low level of molybdopterin production and those mutations that completely abolish molybdopterin synthesis, most likely reflecting molybdopterin synthase activity per se. Residues have been identified that are essential for function including the C-terminal Gly of the small subunit (CnxG), which is thought to be crucial for the sulfur transfer process during the formation of molybdopterin. Two independent alterations at residue Gly-148 in the large subunit, CnxH, result in temperature sensitivity suggesting that this residue resides in a region important for correct folding of the fungal protein. Many years ago it was proposed, from data showing that temperature-sensitive cnxH mutants had thermolabile nitrate reductase, that CnxH is an integral part of the molybdoenzyme nitrate reductase (MacDonald, D. W., and Cove, D. J. (1974) Eur. J. Biochem. 47, 107-110). Studies of temperature-sensitive cnxH mutants isolated in the course of this study do not support this hypothesis. Homologues of both molybdopterin synthase subunits are evident in diverse eukaryotic sources such as worm, rat, mouse, rice, and fruit fly as well as humans as discussed in this article. In contrast, molybdopterin synthase homologues are absent in the yeast Saccharomyces cerevisiae. Precursor Z and molybdopterin are undetectable in this organism nor do there appear to be homologues of molybdoenzymes.
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PMID:Eukaryotic molybdopterin synthase. Biochemical and molecular studies of Aspergillus nidulans cnxG and cnxH mutants. 1038 38

Mycobacterium tuberculosis is able to persist in the human host for decades in an apparently dormant state where it is presumed to reside in an hypoxic environment. This can be mimicked by the Wayne culture model in which progressive oxygen depletion causes the bacteria to shift into a non-replicating state. We investigated global gene expression in aerobic (roller), microaerophilic (NRP1) and anaerobic (NRP2) cultures. A number of genes were significantly up-regulated as compared to aerobic culture; 178 in NRP1, 210 in NRP2, 88 in both. The two states showed distinct gene expression profiles, although a number of membrane and transmembrane proteins were induced in both conditions. A number of regulatory proteins were up-regulated in NRP2. Glycine dehydrogenase, nitrate reductase and alpha-crystallin were induced in both stages, as were fatty acid metabolism genes including fadD26 and mas and genes of the DosR regulon. In a comparison with other stress conditions, there were more similarities between anaerobic conditions and carbon starvation or heat shock than between microaerophilic conditions and carbon starvation or heat shock, but as expected microaerophilic and anaerobic conditions showed the most similar profile. Our results indicate that a large number of genes are up-regulated during the shift into the persistent state.
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PMID:Gene expression profile of Mycobacterium tuberculosis in a non-replicating state. 1520 93

Nitrogen metabolism is not only one of the basic processes of plant physiology, but also one of the important parts of global chemical cycle. Plant nitrogen assimilation directly takes part in the synthesis and conversion of amino acid through the reduction of nitrate. During this stage, some key enzymes, e.g., nitrate reductase (NR), glutamine synthetase (GS), glutamate dehydrogenase (GDH), glutamine synthase (GOGAT), aspargine synthetase (AS), and asparate aminotransferase (AspAT) participate these processes. The protein is assimilated in plant cell through amino acid, and becomes a part of plant organism through modifying, classifying, transporting and storing processes, etc. The nitrogen metabolism is associated with carbonic metabolism through key enzyme regulations and the conversion of products, which consists of basic life process. Among these amino acids in plant cell, glutamic acid (Glu), glutamine (Gln), aspartic acid (Asp) and asparagines (Asn), etc., play a key role, which regulates their conversion each other and their contents in the plant cell through regulating formation and activity of those key enzymes. Environmental factors also affect the conversion and recycle of the key amino acids through regulating gene expression of the key enzymes and their activities. Nitrate and light intensity positively regulate the gene transcription of NR, but ammonium ions and Glu, Gln do the negative way. Water deficit is a very serious constraint on N2 fixation rate and soybean (Glycine max Merr.) grain yield, in which, ureide accumulation and degradation under water deficit appear to be the key issues of feedback mechanism on nitrogen fixation. Water stress decreases NR activity, but increases proteinase activity, and thus, they regulate plant nitrogen metabolism, although there are some different effects among species and cultivars. Water stress also decreases plant tissue protein content, ratio of protein and amino acid, and reduces the absorption of amino acid by plant. On the contrary, soil flooding decreases the content and accumulation amount of root nitrogen in winter wheat by 11.9% from booting to flowering stages and 39.1% during grain filling stage, and reduces the ratio of carbon and nitrogen by 79.6%. The results misadjust the metabolism between carbon and nitrogen, and result in the end of the root growth. Elevated CO2 level could decrease plant leaf nitrogen content under well-watered condition, but almost maintain stable under water deficit condition. The radiation of UV-B significantly reduces the partitioning coefficient and synthetic rate of Rubisco, which significantly decreases the photosynthetic rate. This paper reviewed the pathway of plant nitrogen assimilation, characteristics of key enzymes and their regulating mechanisms with picturing the regulating mode of NR, and described the signal sensing and conduct of plant nitrogen metabolism and the formation, transportation, storage and degradation of plant cell protein with picturing the schedule of protein transport of membrane system in plant cell. Seven key tasks are emphasized in this paper in terms of the review on the effects and mechanisms of key ecological factors including water stress on plant nitrogen metabolism. They are: 1) the absorption mechanism of plant based on different nitrogen sources and environmental regulations, 2) the localization and compartmentalization of the key enzymes of nitrogen mechanism in plant cell, 3) the gene and environmental regulating model and their relationships in various key enzymes of nitrogen metabolism, 4) the function of main cell organs and their responses to environmental factors in nitrogen metabolism process, 5) physiological and chemical mechanism of nitrogen and the relationship between the mechanism and protein formation during crop grain filling, 6) improving gene structure of special species or cultivars using gene engineering methods to enhance the resistance to environmental factor stress and the efficiency of absorption and transportation of nitrogen, and 7) the mechanism of natural nitrogen cycle and its response to human activity disturbance.
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PMID:[Research advance in nitrogen metabolism of plant and its environmental regulation]. 1522 8

Plant roots are gravitropic, detecting and responding to changes in orientation via differential growth that results in bending and reestablishment of downward growth. Recent data support the basics of the Cholodny-Went hypothesis, indicating that differential growth is due to redistribution of auxin to the lower sides of gravistimulated roots, but little is known regarding the molecular details of such effects. Here, we investigate auxin and gravity signal transduction by demonstrating that the endogenous signaling molecules nitric oxide (NO) and cGMP mediate responses to gravistimulation in primary roots of soybean (Glycine max). Horizontal orientation of soybean roots caused the accumulation of both NO and cGMP in the primary root tip. Fluorescence confocal microcopy revealed that the accumulation of NO was asymmetric, with NO concentrating in the lower side of the root. Removal of NO with an NO scavenger or inhibition of NO synthesis via NO synthase inhibitors or an inhibitor of nitrate reductase reduced both NO accumulation and gravitropic bending, indicating that NO synthesis was required for the gravitropic responses and that both NO synthase and nitrate reductase may contribute to the synthesis of the NO required. Auxin induced NO accumulation in root protoplasts and asymmetric NO accumulation in root tips. Gravistimulation, NO, and auxin also induced the accumulation of cGMP, a response inhibited by removal of NO or by inhibitors of guanylyl cyclase, compounds that also reduced gravitropic bending. Asymmetric NO accumulation and gravitropic bending were both inhibited by an auxin transport inhibitor, and the inhibition of bending was overcome by treatment with NO or 8-bromo-cGMP, a cell-permeable analog of cGMP. These data indicate that auxin-induced NO and cGMP mediate gravitropic curvature in soybean roots.
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PMID:Nitric oxide mediates gravitropic bending in soybean roots. 1568 61

The highly conserved family of 14-3-3 proteins function in the regulation of a wide variety of cellular processes. The presence of multiple 14-3-3 isoforms and the diversity of cellular processes regulated by 14-3-3 suggest functional isoform specificity of 14-3-3 isoforms in the regulation of target proteins. Indeed, several studies observed differences in affinity and functionality of 14-3-3 isoforms. However, the structural variation by which isoform specificity is accomplished remains unclear. Because other reports suggest that specificity is found in differential expression and availability of 14-3-3 isoforms, we used the nitrate reductase (NR) model system to analyse the availability and functionality of the three barley 14-3-3 isoforms. We found that 14-3-3C is unavailable in dark harvested barley leaf extract and 14-3-3A is functionally not capable to efficiently inhibit NR activity, leaving 14-3-3B as the only characterized isoform able to regulate NR in barley. Further, using site directed mutagenesis, we identified a single amino acid variation (Gly versus Ser) in loop 8 of the 14-3-3 proteins that plays an important role in the observed isoform specificity. Mutating the Gly residue of 14-3-3A to the alternative residue, as found in 14-3-3B and 14-3-3C, turned it into a potent inhibitor of NR activity. Using surface plasmon resonance, we show that the ability of 14-3-3A and the mutated version to inhibit NR activity correlates well with their binding affinity for the 14-3-3 binding motif in the NR protein, indicating involvement of this residue in ligand discrimination. These results suggest that both the availability of 14-3-3 isoforms as well as binding affinity determine isoform-specific regulation of NR activity.
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PMID:Single amino acid variation in barley 14-3-3 proteins leads to functional isoform specificity in the regulation of nitrate reductase. 1635 92

Soybean seeds [Glycine max (L.) Merr. ev. Bragg] were mutagenized with ethyl methanesulfonate. The M(2) progeny (i.e., the first generation after mutagenesis) of these seeds were screened for increased nodulation under high nitrate culture conditions. Fifteen independent nitrate-tolerant symbiotic (nts) mutants were obtained from 2500 M(2) families. In culture on sand with KNO(3), nodule mass and nodule number in mutant lines were several-fold those of the wild type cultured under the same conditions. Inheritance of the nts character through to subsequent generations was observed in the 10 mutants tested. Mutant nts382 also nodulated more than the wild type in the absence of nitrate. Furthermore, nitrate stimulated growth in both the wild type and nts382, and these lines had similar nitrate reductase activity. These results indicate that nts382 is affected in a nodule-development regulatory gene and not in a gene related to nitrate assimilation.
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PMID:Isolation and properties of soybean [Glycine max (L.) Merr.] mutants that nodulate in the presence of high nitrate concentrations. 1659 77

Under conditions of controlled pH, nitrate and ammonium are equally effective in supporting the growth of young soybean (Glycine max var. Bansei) and sunflower (Helianthus annuus L. var., Mammoth Russian) plans. Soybean contains an active nitrate reductase in roots and leaves, but the low specific activity of this enzyme in sunflower leaves indicates a dependency upon the roots for nitrate reduction. Suppression of nitrate reductase activity in sunflower leaves may be due to high concentrations of ammonia received from the roots. Nitrate reductase activity in leaves of nitrate-supplied soybean and sunflower follows closely the distribution of nitrate reductase. For the roots of both species, glutamic acid dehydrogenase activity was greater with ammonium than with nitrate. The glutamic acid dehydrogenase of ammonium roots is wholly NADH-dependent, whereas that of nitrate roots is active with NADH and NADPH. In leaves, an NADPH-dependent glutamic acid dehydrogenase appears to be responsible for the assimilation of translocated ammonia and ammonia formed by nitrate reduction.In soybean roots ammonia is actively incorporated into amides, much of which remains in the roots. Sunflower roots are less active in amide formation but transfer much of it, together with ammonia, into the shoots. Glutamine synthetase activity in leaves is 20- to 40-fold lower than in roots.Glucose-6-phosphate dehydrogenase activity appears to be correlated with the activity of the nitrate reducing system in roots, but not in leaves.
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PMID:Influence of ammonium and nitrate nutrition on enzymatic activity in soybean and sunflower. 1665 12

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