Nitrate reductase and its role in nitrate assimilation in plants

Nitrate reductase (EC 1.6.6.1) is an enzyme found in most higher plants and appears to be a key regulator of nitrate assimilation as a result of enzyme induction by nitrate. The biochemistry of nitrate reductase has been elucidated to a great extent and the role that nitrate reductase plays in regulation of nitrate assimilation is becoming understood.     

Effect of applied nitrate on growth and N2-fixation inCicer arietinum L.

Summary Application of nitrate, either weekly or at the time of nodulation and pod-filling, significantly retarded nodule development and exerted a delay effect on the rate of N₂-fixating. However, after a certain period of time, its effect on nitrogenase became less conspicuous. Nitrate enhanced nitrate reductase activity in leaves as well as in nodules. At the initial stages, nitrate treated plants accumulated dry mass at a higher rate than those growing exclusively on atmospheric nitrogen. Nitrate induced premature senescence of plants towards the final stages of growth and lowered both the seed number per plant as well as weight of individual seed.     

Seasonal and diurnal variations in nitrate reductase activity of soybean (Glycine max (L.) Merr.)

Summary The seasonal and diurnal variations in nitrate reductase (NR) activity of field grown Altona soybean, with and without applied nitrogen, were determined. The NR activity in the fortnightly collected leaf samples was, on the average, 20 percent higher throughout the season in N-treated plants, the highest being early in the season and declining gradually in the samples of subsequent dates. Diurnal variations were marked by increase in the NR activity from 7 a.m. to 7 p.m. and then declining gradually to a minimum at 7 a.m. the next morning.     

Accumulation and reduction of nitrate in cereal plants dependent on N supply

Summary In pot experiments the NO ₃ ^– accumulation and the occurrence of nitrate reductase (NR) capacity of wheat plants were investigated depending on late N applications at tillering, shooting and heading. NO ₃ ^– is preferentially accumulated in the stems, while NR dominates in the leaves. NO ₃ ^– accumulation is enhanced by late N treatments especially if N supply at seeding is sufficient. NR capacity of the plants is stimulated by late nitrogen supply, but its increment rates decrease with increasing NO ₃ ^– accumulation.     

An evaluation of the stoichiometry ofin vitro nitrate assimilation inZea mays

Summary Reported non-stoichiometry in the reduction of nitrate to nitrite was investigated in leaves ofZea mays L.. The nitrogen balance sheet forin vitro nitrate assimilation was influenced by enzyme protectants in the extraction media and by the method employed to terminate the reaction. A number of limitations were found in the generally acceptedin vitro nitrate reductase assay, in particular the presence of endogenous components which interfered with the assay of nitrite were considered. A stoichiometric balance for thein vitro reduction of nitrate to nitrite was obtained when interfering factors were minimized. The absence of back reactions from ammonia in the assay was confirmed.     

Iron assimilation in plants: reduction of a ferriphytosiderophore by NADH:nitrate reductase from squash

NADH:nitrate reductase (EC 1.6.6.1) from squash (Cucurbita maxima Duch., cv. Buttercup) can catalyze the reduction of a ferriphytosiderophore from barley (Hordeum vulgare L. cv. Europa). Maximal activity occurs at pH 6, with an apparentK _m andV _max of 76 M and 21 nmol·min^-1·(mg protein)^-1, respectively. The ferriphytosiderophore strongly inhibits nitrate reduction catalyzed by nitrate reductase at the optimal pH for nitrate reduction, i.e. 7.5. On the contrary, nitrate is a poor inhibitor of ferriphytosiderophore reduction catalyzed by nitrate reductase at the optimal pH for this reaction, pH 6.0. Thus, squash has the potential to assimilate the iron from a ferriphytosiderophore synthesized by another plant.     

Mutants of Azotobacter vinelandii altered in the regulation of nitrate assimilation

The two enzymes involved in the assimilatory pathway of nitrate in Azotobacter vinelandii are corregulated. Nitrate reductase and nitrite reductase are inducible by nitrate and nitrite. Ammonium represses induction by nitrate of both reductases. Repression by ammonium is higher in media containing 2-oxo-glutarate as carbon source than in media containing sucrose. Mutants in the gene ntrC lost nitrate and nitrite reductase simultaneously. Ten chlorate-resistant mutants with a new phenotype were isolated. In media without ammonium they had a normal phenotype, being sensitive to the toxic effect of chlorate. In media containing low ammonium concentrations they were resistant to chlorate. These mutants seem to be affected in the repression of nitrate and nitrite reductases by ammonium.     

Alleviation of nitrate inhibition of soybean nodulation by high inoculum does not involve bacterial nitrate metabolism

Inoculation of soybean (Glycine max. cv. Bragg) plants with high level inoculum partially alleviated the nitrate inhibition of nodule formation (3 to 4 fold), but not nodule growth. This alleviation did not require the bacterial nitrate reductase asBradyrhizobium japonicum mutant strains 110CR1 and 110CR2 (both lacking assimilatory nitrate reductase activity) gave the same results as the wild type parent 311b110. The study was carried out in the glasshouse, thereby confirming preliminary field data by Herridgeet al. (1984) using a wild type bacterial inoculant.     

Nitrite activation of nitrate reductase in higher plants

Comparative studies of nitrate-activated nitrate reductase (NR-NO₂) and nitrate-induced nitrate reductase (NR-NO₃) (EC 1.6.6.2) indicate that the enzymes differ in structure, heat stability, and pH dependence, but have the same cofactor requirment. NR-NO₂ developes in barley (Hordeum vulgare L. var. Dvir) seedlings as NR-NO₃ disappears. A transition from the active to the inactive form of nitrate reductase takes place. Nitrite seems to activate the inactive form of the enzyme.     

Molecular approaches to the analysis of nitrate assimilation

Abstract. The application of molecular approaches such as mutant analysis and recombinant DNA technology, in conjunction with immunology, are set to revolutionize our understanding of the nitrate assimilation pathway. Mutant analysis has already led to the identification of genetic loci encoding a functional nitrate reduction step and is expected to lead ultimately to the identification of genes encoding nitrate uptake and nitrite reduction. Of particular significance would be identification of genes whose products contribute to regulatory networks controlling nitrogen metabolism. Recombinant DNA techniques are particularly powerful and have already allowed the molecular cloning of the genes encoding the apoprotein of nitrate reductase and nitrite reductase. These successes allow for the first lime the possibility to study directly the role of environmental factors such as type of nitrogen source (NO₃⁻ or NH₄⁺) available to the plant, light, temperature water potential and CO₂ and O₂ tensions on nitrate assimilation gene expression and its regulation at the molecular level. This is an important advance since our current understanding of the regulation of nitrate assimilation is based largely on changes of activity of the component steps. The availability of mutants, cloned genes, and gene transfer systems will permit attempts to manipulate the nitrate assimilation pathway.     

pH对土壤中土著快、慢生大豆根瘤菌结瘤的影响

1　引　　言土壤 ｐＨ对根瘤菌结瘤的影响一直是微生物学和微生物生态学研究的内容之一[4] .在对大豆根瘤菌的研究中 ,早期的研究主要集中于生长慢、产碱的大豆慢生根瘤菌 (Ｂｒａｄｙｒｈｉｚｏｂｉｕｍｊａｐｏｎｉｃｕｍ) [1,2 ] .1982年 ,Ｋｅｙｓｅｒ等[3] 报道了一类生长快、产酸的大豆根瘤菌 ,并命名为费氏中华根瘤菌 (Ｓｉｎｏｒｈｚｏｂｉｕｍ ｆｒｅｄｉ ｉ) .由于它们在生理特性方面存在着明显的差异 ,其结瘤能力以及环境的生物、物理和化学等因素对结瘤的影响一直受到广泛的重视 .本文研究了偏酸、偏碱的 ｐＨ对费氏中华根瘤菌…     

Isolation and characterization of Anacystis nidulans R2 mutants affected in nitrate assimilation: Establishment of two new mutant types

Summary Eighteen mutant strains of the unicellular cyanobacterium Anacystis nidulans R2 that are unable to assimilate nitrate have been isolated after transposon Tn901 mutagenesis. Characterization of phenotypes and transformation tests have allowed the distinction of five different mutant types. The mutants exhibiting a nitrate reductase-less phenotype were identified as being affected in previously defined loci, as they could be transformed to the wild type by one of the plasmids pNR12, pNR63 or pNR193, which contain cloned genes of A. nidulans R2 involved in nitrate reduction. The mutations in strains FM2 and FM16 appear to affect two other genes involved in nitrate assimilation. Strain FM2 apparently bears a single mutation which results in both lack of nitrite reductase activity and loss of ammonium-promoted repression of nitrate reductase synthesis. FM16 has a low but significant level of nitrate reductase that is also freed from repression by ammonium, and an increased level of nitrite reductase activity. FM16 exhibited properties which indicate that this mutant strain might also be affected in the transport of nitrate into the cell.Abbreviations EDTA ethylenediamine-tetraacetic acid - MTA mixed alkyltrimethylammonium bromide - TES N-tris (hydroxymethyl)methyl-2-aminoethane sulfonic acid - Tricine N-[2-hydroxy-1,1-bis (hydroxymethyl)ethyl]-glycine - Tris Tris(hydroxymethyl)aminomethane     

Effect of changing the nanoscale environment on activity and stability of nitrate reductase

Nitrate reductase (NR) is employed for fabrication of nitrate sensing devices in which the enzyme in immobilized form is used to catalyze the conversion of nitrate to nitrite in the presence of a suitable cofactor. So far, instability of immobilized NR due to the use of inappropriate immobilization matrices has limited the practical applications of these devices. Present study is an attempt to improve the kinetic properties and stability of NR using nanoscale iron oxide (nFe₃O₄) and zinc oxide (nZnO) particles. The desired nanoparticles were synthesized, surface functionalized, characterized and affixed onto the epoxy resin to yield two nanocomposite supports (epoxy/nFe₃O₄ and epoxy/nZnO) for immobilizing NR. Epoxy/nFe₃O₄ and epoxy/nZnO support could load as much as 35.8 ± 0.01 and 33.20 ± 0.01 μg/cm² of NR with retention of about 93.72 ± 0.50 and 84.81 ± 0.80% of its initial activity respectively. Changes in surface morphology and chemical bonding structure of both the nanocomposite supports after addition of NR were confirmed by scanning electron microscopy (SEM) and fourier transform infrared spectroscopy (FTIR). Optimum working conditions of pH, temperature and substrate concentration were ascertained for free as well as immobilized NR preparations. Further, storage stability at 4 °C and thermal stability between 25–50 °C were determined for all the NR preparations. Analytical applications of immobilized NR for determination of soil and water nitrates along with reusability data has been included to make sure the usefulness of the procedure.     

Glutamine synthetase of Chlamydomonas: its role in the control of nitrate assimilation

Work is described which suggests that glutamine synthetase (GS) could play an important and direct regulatory role in the control of NO₃ assimilation by the alga. In both steady-state cells and ones disturbed physiologically by changes in light or nitrogen supply the assimilation of NO₃ appears to be limited by the activity of GS. Moreover although in normal cells NH₃ can completely inhibit NO₃ uptake, promote the deactivation of nitrate reductase (NR) and repress the synthesis of NR and nitrite reductase (NIR), these controls are relaxed in cells in which GS is deactivated by treatment with L-methionine-DL-sulfoximine (MSO). It is proposed that the reversible deactivation of GS may play an important part in the regulation of NO₃ assimilation although it is still not clear whether the enzyme itself or products of its metabolism are responsible.Abbreviations GS glutamine synthetase - GS_s glutamine synthetase, synthetase activity - GS_t glutamine synthetase, transferase activity - NR nitrate reductase - NIR nitrite reductase - GDH glutamate dehydrogenase - CHX cycloheximide - MSO L-methionine-DL-sulfoximine - FAD flavine adenine dinucleotide     

Nitrate,nitrate reduction and organic nitrogen in plants from different ecological and taxonomic groups of Central Europe

Summary 48 plant species of the families Asteraceae, Chenopodiaceae, Ericaceae, Fabaceae, Lamiaceae, Polygonaceae and Urticaceae were investigated in 14 natural habitats of Central Europe having different nitrate supplies, with respect to their nitrate content, nitrate reductase activity (NRA) and organic nitrogen content. Plants that were flowering were selected where possible for analysis. The plants were subdivided into flowers, laminae, petioles+shoot axes and below-ground organs. Each organ was analyzed separately. Differences among species were found for the three variables investigated. Apart from the Fabaceae, which had particularly high concentrations of organic N, these differences reflect mainly the ecological behaviour, i.e. high nitrate and organic N contents and NRA values per g dry weight were found in species on sites rich in nitrate, and vice versa. Nitrate content, NRA and organic N content were correlated with nitrogen figures of Central European vascular plants defined by Ellenberg (1979). By use of regression equations this correlation was tested with species from other systematic groups. Some species were attributed with calculated N figures for the first time.     

Effect of nitrate pulses on the nitrate-uptake rate,synthesis of mRNA coding for nitrate reductase,and nitrate-reductase activity in the roots of barley seedlings

Using pulses of nitrate, instead of the permanent presence of external nitrate, to induce the nitrate-assimilating system in Hordeum vulgare L., we demonstrated that nitrate can be considered as a trigger or signal for the induction of nitrate uptake, the appearance of nitratereductase activity and the synthesis of mRNA coding for nitrate reductase. Nitrate pulses stimulated the initial rate of nitrate uptake, even after subsequent cultivation in N-free medium, and resulted in a higher acceleration of the uptake rate in the presence of nitrate than in its absence.Abbreviations NR nitrate reductase     

Effect of localized nitrate application on isoflavonoid concentration and nodulation in split-root systems of wild-type and nodulation-mutant soybean plants

Although isoflavonoids are known to be inducers of nod genes in Bradyrhizobium japonicum, it was recently proposed that internal root levels of isoflavonoids may be important in nodule development on soybean (Glycine max [L.] Merr.). The hypernodulating soybean mutants were shown to accumulate higher root concentrations of isoflavonoid compounds (daidzein, genistein, and coumestrol) and to be more extensively nodulated than was the Williams parent when inoculated with B. japonicum. The hypernodulating mutants and the parent line, Williams, also showed decreased isoflavonoid concentrations and decreased nodule development if N was applied. The current study evaluated the effect of localized NO(3) (-) application on root isoflavonoid concentration and on nodulation in split-root systems of the Williams wild type and a hypernodulating mutant (NOD1-3). Nitrate application markedly decreased isoflavonoid concentrations in non-inoculated soybean roots. When roots were inoculated, nodule number, weight, and nitrogenase activity were markedly suppressed on the root-half receiving 5 millimolar NO(3) (-) compared with the other root-half receiving 0 millimolar NO(3) (-). High performance liquid chromatographic analyses of root extracts showed that the root-half receiving 5 millimolar NO(3) (-) was markedly lower in isoflavonoid concentrations in both soybean lines. This was partially due to the localized stimulatory effect of NO(3) (-) on root growth. The inoculated NOD1-3 mutant had higher isoflavonoid concentrations than did the Williams control in both the presence and absence of NO(3) (-). These results provide evidence that the site of N application primarily controls the site of nodulation inhibition, possibly through decreasing isoflavonoid levels. Although the effect of NO(3) (-) on nodule development and root isoflavonoid concentration was strongly localized, there was evidence that NO(3) (-) also resulted in a systemic effect on root isoflavonoids. The results are consistent with previous speculation that internal levels of root isoflavonoids may affect nodule development.     

Glutamine synthetase activity,ammonia assimilation and control of nitrate reduction in the unicellular red algaCyanidium caldarium

Addition ofl-methionine-dl-sulphoximine to cells ofCyanidium caldarium brings about a loss of glutamine synthetase activity. Concomitantly ammonia assimilation is prevented.Under physiological conditions nitrate reductase [NAD(P)H: nitrate oxidoreductase EC 1.6.6.2] is reversibly converted into an inactive enzyme upon addition of ammonia. In the presence of methionine sulphoximine, when glutamine synthetase activity is lost, nitrate reductase is no longer inactivated by ammonia. It is suggested that ammonia itself is not the actual effector of nitrate reductase inactivation.Concomitantly with the failure of nitrate reductase to undergo ammonia-inactivation, in the presence of methionine sulphoximine nitrate reduction is an uncontrolled process, thus, in media with nitrate ammonia continues to be produced and excreted into the external medium at a constant rate.Abbreviations NR Nitrate reductase - GS Glutamine synthetase - GOGAT Glutamate syntase - MSX l-methionine-dl-sulphoximine