Gene/Protein Disease Symptom Drug Enzyme Compound
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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. Starved cells of a glucose-grown strain of Staphylococcus aureus are resistant to the action of staphylococcin 1580. Reinitiation of sensitivity is readily obtained upon the addition of glucose, but only weakly with L-lactate, although the latter induces higher ATP levels and supports L-glutamic acid uptake better than glucose does. The NADH/NAD+ ratio correlates with the staphylococcin sensitivity. 2. Starved pyruvate-grown cells remain partially susceptible and full sensitivity is restored both in the presence of glucose and L-lactate. 3. Arsenate but not dicyclohexylcarbodiimide (DCCD) blocks the reinitiation of sensitivity in the presence of glucose. Both arsenate and DCCD block sensitivity in the presence of L-lactate. 4. Aerobically grown cells are sensitive to staphylococcin 1580 under anaerobic conditions. Anaerobically grown cells are less susceptible, but sensitivity can be restored by glucose and also by L-lactate plus nitrate when cells are previously induced for nitrate reductase. 5. Starved cells of a mutant strain defective in the maintenance of a high-energy state of the membrane are normally sensitive in the presence of glucose, but resistant in the presence of L-lactate. A strain lacking a functional respiratory chain (men-) is also sensitive with glucose but resistant in the presence of L-lactate. 6. It is concluded that the initiation of the staphylococcin 1580 action is under control of a mechanism regulating the energy flow in the cell, and involving the presence of a high-energy phosphorylated compound.
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PMID:Energy requirements for the action of staphylococcin 1580 in Staphyloccus aureus. 20 62

Incubation of the complex metalloflavoprotein, assimilatory nitrate reductase with N-ethylmaleimide, or a spin-labeled analog, 4-maleimido-2,2,6,6-tetramethylpiperidinooxyl, resulted in a time-dependent inactivation of NADH:nitrate reductase and NADH: cytochrome-c reductase activity with no effect on reduced methyl viologen:nitrate reductase activity. Inactivation of the enzyme, which could be prevented by incubation in the presence of NADH, was achieved following modification of a single sulfhydryl group determined from [3H]N-ethylmaleimide incorporation and quantitation of the EPR spectrum of the spin-labeled enzyme. Sulfhydryl group modification precluded reduction of the enzyme by NADH and NAD+ binding. The EPR spectrum of the spin-labeled enzyme revealed the presence of a single species with the nitroxide retaining substantial motional freedom. Cleavage of the spin-labeled enzyme using corn-inactivating protease and separation into its flavin and molybdenum/heme domains followed by EPR spectroscopy revealed the modified sulfhydryl group to be associated with the latter fragment suggesting a close interaction of these domains in the region of the nucleotide-binding site.
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PMID:The role of the essential sulfhydryl group in assimilatory NADH: nitrate reductase of Chlorella. 300 65

The oxidation-reduction midpoint potential for the heme prosthetic group present in assimilatory nitrate reductase from Chlorella vulgaris has been determined by optical potentiometric titrations in the presence of dye mediators. At pH 7, the midpoint potential was determined to be -160 mV and corresponds to a reversible n = 1 redox process. The midpoint potential was unaltered by the use of NADH as reductant, unaffected by the presence of NAD+, cytochrome c, phosphate, cyanide, or alkaline pH. In addition, the redox potential of the heme was independent of modifications to the enzyme such as substitution of the molybdenum center with tungsten, or cleavage and separation of the enzyme into its flavin and heme/molybdenum domains. In contrast, the midpoint potential increased on decreasing the pH yielding a pH dependence of approximately 20 mV/pH unit within the range 5.5 to 7, suggesting the presence of a single, redox-associated, ionizable functional group on the protein with pKox = 5.8 and pKred = 6.1. At pH 7 and within the range 12 to 38 degrees C, the midpoint potential of the heme decreased by approximately 1 mV/degree. Values for delta S0 and delta H0 were calculated to be -25.6 e.u. and -4.0 kcal/mol.
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PMID:Thermodynamic properties of the heme prosthetic group in assimilatory nitrate reductase. 370 Mar 73

The reduction of nitrate by reduced nicotinamide-adenine dinucleotides, catalysed by extract of Candida utilis, exhibits an apparent high degree of stereospecificity for the 'B' methylene hydrogen atom of NADPH and mixed stereospecificity for the methylene hydrogen atoms of NADH. Purified nitrate reductase, on the other hand, exhibits 'A' stereospecificity for NADH and NADPH. The apparent switch of stereospecificity from the 'B' to the 'A' side of NADPH, which occurs after purification of the enzyme, is partly explained by the fact that in crude extracts nitrate is reduced completely to ammonia. Nitrite does not accumulate but is reduced to ammonia by nitrite dehydrogenase, which is 'B'-specific, so that up to 75% of hydrogen removed from NADPH during the reduction of nitrate could occur from the 'B' side. A further increase in the removal of hydrogen from the 'B' side of NADPH could be the kinetic isotope effect that is observed when ['A'-3H]NADPH is the reductant, the H--C bond being cleaved 2.3 times faster than the 3H--C bond. The mixed stereospecificity observed with NADH has been traced to an uncharacterized enzyme that catalyses a 'B'-specific exchange between NAD+ and NADH. This reaction is discussed in relation to the possibility that it may explain other cases of apparent mixed stereospecificity that have been reported.
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PMID:The stereospecificity of the reduction of nitrate by reduced nicotinamide-adenine dinucleotides catalysed by Candida utilis preparations. 689 Aug 12

Spectroscopic and kinetic studies comparing the behavior of the recombinant cytochrome b reductase fragment of corn leaf nitrate reductase and a mutant in which cysteine 242 is replaced with a serine residue (C242S) have been carried out. The visible and circular dichroism spectra of the wild-type and mutant protein are virtually identical and compare well with those reported for nitrate reductases from other sources. The reduced wild-type protein forms a charge-transfer complex with NAD+ that has an absorption envelope that extends into the near infrared, with a maximum around 800 nm. The C242S mutant forms a similar charge-transfer complex with NAD+ but to a lesser extent than the wild-type. The reduction potential of the flavin for the wild-type protein is -287 mV, and that for the mutant is -279 mV. The rate of reduction by NADH of the C242S mutant is 7-fold slower than that for the wild-type protein, and the Kd is larger by a factor of 2. These results indicate that the cysteine 242 residue plays a role principally in facilitating electron transfer from NADH to the flavin rather than in binding of NADH to the enzyme.
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PMID:Spectroscopic and kinetic characterization of the recombinant wild-type and C242S mutant of the cytochrome b reductase fragment of nitrate reductase. 759 6

Assimilatory nitrate reductase from Chlorella vulgaris catalyzes the rate-limiting step, the conversion of nitrate to nitrite, in nitrate assimilation. Initial rate studies of nitrate reductase activity, performed under optimum conditions of constant ionic strength (mu = 0.2) and pH (8.0) and using NADH as reductant, indicated the absence of substrate inhibition at NADH concentrations below 300 microM and NO3- concentrations less than 3 mM. Chlorella nitrate reductase exhibited a marked preference for NADH (Vmax = 9.2 mumol NADH/min/nmol heme and Km = 2.3 microM) as the physiological electron donor but could also utilize alpha-NADH (Vmax = 5.6 mumol NADH/min/nmol heme and Km = 131 microM) and NADPH (Vmax = 0.6 mumol NADPH/min/nmol heme and Km = 910 microM) though with significantly decreased efficiency. Examination of various NADH-analogs indicated that reduced nicotinamide hypoxanthine dinucleotide (NHDH) was used most efficiently (Vmax = 9.3 mumol NHDH/min/nmol heme and Km = 7.9 microM), while reduced nicotinamide mononucleotide (NMNH) was utilized least efficiently (Vmax = 0.07 mumol NMNH/min/nmol heme and Km = 676 microM). Overall, modifications to the nicotinamide moiety or the addition of a phosphate group were observed to result in the most significant decreases in Vmax, indicating poor reducing substrates. Product inhibition studies indicated both NAD+ (Ki = 2.2 mM) and NADP+ (Ki = 10.5 mM) to be competitive inhibitors of Chlorella NR. A variety of NAD+ analogs were also determined to act as competitive inhibitors with varying degrees of efficiency. 3-Pyridinealdehyde adenine dinucleotide was the most efficient inhibitor (Ki = 0.74 mM) while nicotinamide was the least efficient (Ki = 18.1 mM). Overall, changing substituents on the nicotinamide ring or its complete deletion produced the most effective inhibitors compared to NAD+. In contrast, changes in the adenine or ribose moieties produced less effective inhibitors when compared to NAD+. These results represent the most comprehensive analysis of the effect of modifications of the physiological reductant (NADH) and product (NAD+) on nitrate reductase activity.
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PMID:Assimilatory nitrate reductase: reduction and inhibition by NADH/NAD+ analogs. 797 4

The C-terminal 268 residues of the spinach assimilatory NADH:nitrate reductase amino acid sequence that correspond to the flavin-containing domain of the enzyme have been selectively amplified and expressed as a recombinant protein in Escherichia coli. The recombinant protein, which was produced in both soluble and insoluble forms, was purified to homogeneity using a combination of ammonium sulfate precipitation, affinity chromatography on 5'-ADP-agarose and FPLC gel filtration. The purified domain exhibited a molecular weight of approximately 30 kDa, estimated by polyacrylamide gel electrophoresis, and a molecular mass of 30,169 for the apoprotein determined by mass spectrometry, which also confirmed the presence of FAD. The UV/visible spectrum was typical of a flavoprotein, with maxima at 272, 386, and 461 nm in the oxidized form while CD spectroscopy yielded both positive and negative maxima at 313 and 382 nm and 461 and 484 nm, respectively. The purified domain showed immunological cross-reactivity with anti-spinach nitrate reductase polyclonal antibodies while both N-terminal and internal amino acid sequencing of isolated peptides confirmed the fidelity of the domain's primary sequence. The protein retained NADH-ferricyanide reductase activity (Vmax=84 micromol NADH consumer/min/nmol FAD) with Km's of 17 and 34 microM for NADH and ferricyanide, respectively, with a pH optimum of approximately 6.5 A variety of NADH-analogs could also function as electron donors, though with decreased efficiency, the most effective being reduced nicotinamide hypoxanthine dinucleotide (V(max) = 35 micromol NHDH consumer/min/nmol FAD) and Km = 22 microM). NAD+ was demonstrated to be a competitive inhibitor (Ki = 1.9 mM) while analysis of inhibition by a variety of NAD+-analogs indicated the most efficient inhibitor to be ADP (Ki = 0.2 mM), with analogs devoid of either the phosphate, ribose, or adenine moieties proving to be markedly less-efficient inhibitors. The isolated domain was also capable of reducing cytochrome b5 directly (V(max) = 1.2 micromol NADH consumed/min/nmol FAD, Km (cyt. b5) = 6 microM), supporting the FAD -> b557 -> Mo electron transfer sequence in spinach nitrate reductase.
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PMID:Spectroscopic and kinetic properties of a recombinant form of the flavin domain of spinach NADH: nitrate reductase. 861 85

Direct electrochemical studies, utilizing two voltammetric methods-square-wave voltammetry (SWV) and cyclic voltammetry (CV)-have been performed on recombinant forms of the flavin domain of spinach assimilatory nitrate reductase in the presence of NAD+ analogs. The reduction potentials (E degrees ') of the flavin domains have been determined at an edge pyrolytic graphite electrode utilizing MgCl2 as a redox-inactive promoter. Under identical experimental conditions (pH 7.0, 25 degrees C), the two-electron reduction potential for the FAD/FADH2 couple has been determined to be -274 and -257 mV by SWV and CV, respectively. In contrast, the reduction potentials of free FAD have been determined to be -234 and -227 mV by SWV and CV, respectively. The reduction potentials of the complex formed between the FAD prosthetic group in the recombinant flavin domain and various NAD+ analogs have been determined to be as follows: NAD+ (E degrees ' = -192 mV), 5'-ADP ribose (E degrees ' = -199 mV), ADP (E degrees ' = -154 mV), AMP (E degrees ' = -196 mV), adenosine (E degrees ' = -192 mV), adenine (E degrees ' = -220 mV), and NMN (E degrees ' = -208 mV). In contrast to these positive shifts in reduction potential, nicotinamide (E degrees ' = -268 mV) had very little effect on the reduction potential of this flavin complex. Moreover, addition of NAD+ to the FAD prosthetic group in a variety of mutant forms of the recombinant flavin domain resulted in positive shifts in the reduction potential of the complex, although the magnitude of the shifts varied from a minimum of 6 mV obtained for the C240A mutant to a maximum of 79 mV obtained for the C62S mutant. These results represent the first extensive application of direct electrochemistry to examine the redox properties of assimilatory nitrate reductase and indicate that complex formation with NAD+, or various NAD+ analogs, results in a positive shift in the flavin reduction potential, with the magnitude of the shift correlating well with the efficiency of the inhibitor.
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PMID:Direct electrochemistry of the flavin domain of assimilatory nitrate reductase: effects of NAD+ and NAD+ analogs. 928 15

Integrated bioelectrocatalytically active electrodes are assembled by the deposition of enzymes onto respective electrically contacted affinity matrices and further cross-linking of the enzyme monolayers. A catalyst-NAD(+)-dyad for the binding of the NAD(+)-dependent enzymes and cytochrome-like molecules for the binding of the heme-protein-dependent enzymes are used to construct integrated electrically contacted biocatalytic systems. NAD(+)-dependent lactate dehydrogenase (LDH) is assembled onto a pyrroloquinoline quinone-NAD+ monolayer. The redox-active monolayer is organized via covalent attachment of pyrroloquinoline quinone (PQQ) to a cystamine monolayer associated with a Au-electrode, followed by covalent linkage of N6-(2-aminoethyl)-NAD+ to the monolayer. The interface modified with the PQQ-NAD(+)-dyad provides temporary affinity binding for LDH and allows cross-linking of the enzyme monolayer. The cross-linked LDH is bioelectrocatalytically active towards oxidation of lactate. The bioelectrocatalyzed process involves the PQQ-mediated oxidation of the immobilized NADH. Integrated, electrically contacted bioelectrodes are produced by the affinity binding and further cross-linking of nitrate reductase (NR) (cytochrome-dependent, E.C. 1.9.6.1 from E. coli) or CoII-protoporphyrin IX reconstituted myoglobin (CoII-Mb) atop the microperoxidase-11 (MP-11) monolayer associated with a Au-electrode. The MP-11 monolayer provides an affinity interface for the temporary binding of the enzymes, that allows the cross-linkage of the enzyme molecules. The MP-11 assembly acts as electron transfer mediator for the reduction of the secondary enzyme layer. The integrated bioelectrodes consisting of NR and CoII-Mb show catalytic activities for NO3- reduction and acetylene-dicarboxylic acid hydrogenation, respectively. Two FeIII-protoporphyrin IX units are reconstituted into a four alpha-helix bundle de novo protein assembled as a monolayer on a Au-electrode. Vectorial electron transfer proceeds in the synthetic heme-protein monolayer. Cross-linking of an affinity complex generated between the FeIII-protoporphyrin IX reconstituted de novo protein monolayer and NR yields an integrated, electrically contacted enzyme electrode that stimulates the bioelectrocatalyzed reduction of nitrate.
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PMID:Fully integrated biocatalytic electrodes based on bioaffinity interactions. 982 68

In order to better understand the effects of heavy metals on the growth of plants, we decided to perform recovering experiments by following both chemical and physiological parameters in cadmium pre-stressed tomato seedlings after cadmium had been removed from the nutrient solution. The work shows that cadmium suppression results in resumption of growth activity. The biomass of leaves and stems rose steadily. The increase in root biomass exceeded those of leaves and stems. At the same time, nitrate content was increased to reach the level obtained with unstressed controls. In all the organs studied, the activities of the enzymes involved in the anabolic nitrogen primary assimilation pathways (nitrate reductase (NR), nitrite reductase (NiR) and glutamine synthetase (GS) soared after that cadmium had been removed. While NAD(+)-dependent glutamate dehydrogenase (GDH-NAD+) activity also rose progressively during the recovering time, the cognate NADH-dependent glutamate dehydrogenase (GDH-NADH) activity decreased. This result allows us to propose that the ammonia produced by the stress-induced protein catabolism is detoxified and re-assimilated by the GDH-NADH isoenzyme. On the basis of these results, we will discuss the ability of the plant to dilute the effects of pollutants during the recovering period. An important outcome of this work is that a transient contamination of the culture medium by pollutants is not necessarily followed by a significant depreciation in product yield or quality.
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PMID:[Reversibility of the effects of cadmium on the growth and nitrogen metabolism in the tomato(Lycopersicon esculentum)]. 1289 45


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