EC:1.7.1.1 - FACTA Search

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Query: EC:1.7.1.1 (nitrate reductase)
3,728 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

Nitrate reductase was purified from and characterized in a bloom-forming unicellular calcifying alga, Emiliania huxleyi (Haptophyceae). The molecular masses of the native form and the subunit were 514 and 85 kDa, respectively, showing that the enzyme is a hexamer composed of 6 homologous subunits. The Km values for NADH and NO3- were 40 microM and 104 microM, respectively. Activity of the reduction of nitrate was very high with reduced methylviologen and NADH, but no activity was observed with NADPH or reduced flavin mononucleotide; oxidation of NADH was very high with cytochrome c but did not occur with ferricyanide. These results indicate that Emiliania nitrate reductase is NADH-specific (EC 1.6.6.1), and that among algae and plants its subunit structure and kinetic properties are unique.
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PMID:Characterization of NADH: nitrate reductase from the coccolithophorid Emiliania huxleyi (Lohman) Hay & Mohler (Haptophyceae). 1292 15

With respect to cofactor requirements, NADH, and FMNH(2) were equally effective as electron donors for nitrate reductase obtained from leaves of maize, marrow, and spinach, when the cofactors were supplied in optimal concentrations. The concentration of FMNH(2) required to obtain half-maximal activity was from 40- to 100-fold higher than for NADH. For maximal activity with the corn enzyme, 0.8 millimolar FMNH(2) was required. In contrast, NADPH was functional only when supplied with NADP:reductase and exogenous FMN (enzymatic generation of FMNH(2)).All attempts to separate the NADH(2)- and FMNH(2)-dependent nitrate reductase activities were unsuccessful and regardless of cofactor used equal activities were obtained, if cofactor concentration was optimal. Unity of NADH to FMNH(2) activities were obtained during: A) purification procedures (4 step, 30-fold); B) induction of nitrate reductase in corn seedlings with nitrate; and C) inactivation of nitrate reductase in intact or excised corn seedlings. The NADH- and FMNH(2)-dependent activities were not additive.A half-life for nitrate reductase of approximately 4 hours was estimated from the inactivation studies with excised corn seedlings. Similar half-life values were obtained when seedlings were incubated at 35 degrees in a medium containing nitrate and cycloheximide (to inhibit protein synthesis), or when both nitrate and cycloheximide were omitted.In those instances where NADH activity but not FMNH(2) activity was lost due to treatment (temperature, removal of sulfhydryl agents, addition of p-chloromercuribenzoate), the loss could be explained by inactivation of the sulfhydryl group (s) required for NADH activity. This was verified by reactivation with exogenous cysteine.Based on these current findings, and previous work, it is concluded that nitrate reductase is a single moiety with the ability to utilize either NADH or FMNH(2) as cofactor. However the high concentration of FMNH(2) required for optimal activity suggests that in vivo NADH is the electron donor and that nitrate reductase in higher plants should be designated NADH:nitrate reductase (E.C. 1.6.6.1).
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PMID:Some characteristics of nitrate reductase from higher plants. 1665 64

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

Total pyridine nucleotide concentration of root tissue for young soybean (Glycine max var. Bansei) and sunflower (Helianthus annuus L. var. Mammoth Russian) plants is the same with either ammonium or nitrate, but nitrate results in an increased proportion of total oxidized plus reduced NADP (NADP[H]) seemingly at the expense of NAD. The activity of NADH- and NADPH-dependent forms of glutamic acid dehydrogenase is correlated with the ratio of total oxidized plus reduced NAD to NADP(H). The low NAD: NADH ratio maintained in nitrate roots despite active NADH utilization via nitrate reductase and glutamic acid dehydrogenase may be the result of nitrate-stimulated glycolysis. Nitrate roots also maintain a high level of NADPH, presumably by the stimulatory effect of nitrate utilization on glucose-6-phosphate dehydrogenase activity. In the presence of nitrate rather than ammonium, the highly active nitrate-reducing leaves of soybean show a greater proportion of total pyridine nucleotide in the form of NADP(H) than do the inactive leaves of sunflower.For all tissues examined, ammonium nutrition yields a higher concentration of total adenine nucleotide than is found with nitrate. The data indicate the production of a higher level of metabolites that enter into purine synthesis with ammonium than with nitrate. Glutamine synthetase activity can be correlated with the concept that enzymes utilizing ATP for biosynthetic purposes increase in activity in accordance with the energy level of the cell.
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PMID:Influence of ammonium and nitrate nutrition on the pyridine and adenine nucleotides of soybean and sunflower. 1665 13

Nitrate simultaneously induced NADH- and NADPH-nitrate reductase activities in rice seedlings. Chloramphenicol, other organic nitro-compounds such as o-nitroaniline and 2,4-dinitrophenol and nitrite also induced nitrate reductase in rice seedlings. The nitrate- or nitrite-induced nitrate reductase could accept electrons more efficiently from NADH than NADPH. However, when this enzyme was induced by organic nitro-compounds, it could accept electrons more efficiently from NADPH than NADH.
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PMID:Nitrate reductase of rice seedlings and its induction by organic nitro-compounds. 1665 98

In a study on 3-day maize (Zea mays) seedlings, grown on nitrate, requirements were established for the maximum extraction and optimum stabilization of nitrate reductase in vitro. With the primary root, 5 mm cysteine were required in the extraction medium, but for the scutellum, which has a high level of endogenous thiol, the use of additional thiol resulted in a reduced yield of a more labile enzyme. Activity of the root and scutella nitrate reductase was obtained with either NADH or NADPH, but that of the root enzyme with NADPH was only demonstrated in the absence of phosphate.Before leaf expansion, the nitrate reductase in the maize seedling was mainly in the scutellum. The enzyme present in the primary root was predominantly in the apical region (0-2 mm). In contrast, glutamate dehydrogenase was concentrated in the mature basal region of the root (30-60 mm). A high level of nitrate (approximately 100 mm) was required to saturate the induction of nitrate reductase in the root tip, mature root, and scutellum. The concentration of nitrate required to give half the maximum level of enzyme induced was the same for each region (29 mm).After leaf expansion, more than 90% of the nitrate reductase was in the shoot, mainly in the leaf blade, and a marked decrease occurred in the level of the enzyme in the scutellum. A large proportion of the glutamate dehydrogenase was still found in the root.
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PMID:The distribution and characteristics of nitrate reductase and glutamate dehydrogenase in the maize seedling. 1665 30

Preliminary work revealed that nitrate reductase in crude extracts prepared from leaves of certain corn genotypes as well as soybeans could utilize NADPH as well as NADH as the electron donor. Isoelectric focusing and diethylaminoethyl cellulose chromatography confirmed previous findings that NADH and NADPH activities could not be separated, which suggests the involvement of a single enzyme. Nitrate reduction with both cofactors varies with plant species, plant age, and assay conditions. The ability of the nitrate reductase from a given genotype to utilize NADPH was associated with the amount of NADPH-phosphatase in the extract. While diethylaminoethyl cellulose chromatography of plant extracts separated nitrate reductase from the bulk (90%) of the phosphatase and caused a decrease in the NADPH activity, the residual level of phosphatase was sufficient to account for the apparent NADPH nitrate reductase activity. Addition of KH(2)PO(4) and KF, inhibitors of NADPH-phosphatase activity in in vitro assays, caused a drastic reduction or abolishment of NADPH-mediated nitrate reductase activity but were without effect on NADH nitrate reductase activity. It is concluded that NADPH-nitrate reduction, in soybean and certain corn genotypes, is an artifact resulting from the conversion of NADPH to NADH by a phosphatase and that the enzyme in leaf tissue is NADH-dependent (E.C.1.6.6.1).
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PMID:Specificity for nicotinamide adenine dinucleotide by nitrate reductase from leaves. 1665 48

Intercellular distribution of enzymes involved in amino nitrogen synthesis was studied in leaves of species representing three C(4) groups, i.e. Sorghum bicolor, Zea mays, Digitaria sanguinalis (NADP malic enzyme type); Panicum miliaceum (NAD malic enzyme type); and Panicum maximum (phosphoenolpyruvate carboxykinase type). Nitrate reductase, nitrite reductase, glutamine synthetase, and glutamate synthase were predominantly localized in mesophyll cells of all the species, except in P. maximum where nitrite reductase had similar activity on a chlorophyll basis, in both mesophyll and bundle sheath cells. NADH-glutamate dehydrogenase was concentrated in the bundle sheath cells, while NADPH-glutamate dehydrogenase was localized in both mesophyll and bundle sheath cells. The activities of nitrate-assimilating enzymes, except for nitrate reductase, were high enough to account for the proposed in vivo rates of nitrate assimilation.Based on the differential centrifugation of cell homogenates of P. miliaceum, mesophyll chloroplasts appear to be the major site of nitrate assimilation since nitrite reductase, glutamine synthetase, glutamate synthase, and NADPH-glutamate dehydrogenase were primarily localized in the chloroplast fraction. Both the glutamine synthetase-glutamate synthase and glutamate dehydrogenase pathways were considered as alternative routes of amino nitrogen synthesis.
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PMID:Distribution of Nitrate-assimilating Enzymes between Mesophyll Protoplasts and Bundle Sheath Cells in Leaves of Three Groups of C(4) Plants. 1665 90

The effect of various day temperatures on NADH-nitrate reductase, NADH- and NADPH-glutamate dehydrogenases, nitrate, protein and leaf area, measured at intervals during the ontogeny of the first trifoliolate soybean leaf, was determined. At 32.5 C and 25 C, nitrate concentration, nitrate reductase, and NADPH-glutamate dehydrogenase activities increased concurrently with leaf development and then decreased as leaf maturation progressed. At 40 C, these three components showed no initial increase and the concentration or activities decreased throughout the development of the leaf. The effects of temperature on NADH-glutamate dehydrogenase were the reverse. Rates of protein accumulation were higher at 40 C during the first 2 days of leaf development while higher rates were measured the first 5 days of leaf growth at 32.5 C. At 25 C, protein accumulation was low during the first 3 days of leaf growth, increased in the period of 3 to 5 days, and then declined up to 8 days of leaf development. Leaf expansion progressed at faster rates at 32.5 C and 25 C and at a much slower rate at 40 C. Leaf growth was essentially complete after the fifth day regardless of temperature.In crude leaf homogenates, apparent irreversible inactivation temperatures were 36 C for nitrate reductase and 65 C for NADPH-glutamate dehydrogenase. In vivo studies indicated a lower inactivation temperature for NADPH-glutamate dehydrogenase; however, it was still more heat-tolerant than nitrate reductase.We envisaged that reduced nitrogen supplied by NO(3) (-) assimilation is a factor in leaf expansion.
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PMID:Influence of Temperature on Nitrate Metabolism and Leaf Expansion in Soybean (Glycine max L. Merr.) Seedlings. 1665 11

Nitrate reductase of the salt-tolerant alga Dunaliella parva could utilize NADPH as well as NADH as an electron donor. The two pyridine nucleotide-dependent activities could not be separated by either ion exchange chromatography on DEAE-cellulose or gel filtration on Sepharose 4B. The NADPH-dependent activity was not inhibited by phosphatase inhibitors. NADPH was not hydrolyzed to NADH and inorganic phosphate in the course of nitrate reduction. Reduction of nitrate in vitro could be coupled to a NADPH-regenerating system of glycerol and NADP-dependent glycerol dehydrogenase. It is concluded that the nitrate reductase of D. parva will function with NADPH as well as NADH. This is a unique characteristic not common to most algae.
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PMID:Specificity for Nicotinamide Adenine Dinucleotide and Nicotinamide Adenine Dinucleotide Phosphate of Nitrate Reductase from the Salt-tolerant Alga Dunaliella parva. 1665 20

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