A method for the determination of nitrate reductase

A procedure for the assay of nitrate reductase based on Szekely's diaminodiphenylsulphone method of nitrate determination (Szekely, E. (1967) Talanta 14, 941–950) is described. The method is simple and sensitive, allowing determination of 1 μg of nitrate in a volume of 1 ml or less. It is particularly suited to the determination of nitrate reductase.     

Characterization of NADH: nitrate reductase from the coccolithophorid Emiliania huxleyi (Lohman) Hay & Mohler (Haptophyceae)

Abstract 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 K _m values for NADH and NO3− were 40 μM and 104 μM, 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.     

The activation state of nitrate reductase is not always correlated with total nitrate reductase activity in leaves

The relation between nitrate reductase (NR; EC 1.6.6.1) activity, activation state and NR protein in leaves of barley (Hordeum vulgare L.) seedlings was investigated. Maximum NR activity (NRA_max) and NR protein content (Western blotting) were modified by growing plants hydroponically at low (0.3 mM) or high (10 mM) nitrate supply. In addition, plants were kept under short-day (8 h light/16 h dark) or long-day (16 h light/8 h dark) conditions in order to manipulate the concentration of nitrate stored in the leaves during the dark phase, and the concentrations of sugars and amino acids accumulated during the light phase, which are potential signalling compounds. Plants were also grown under phosphate deficiency in order to modify their glucose-6-phosphate content. In high-nitrate/long-day conditions, NRA_max and NR protein were almost constant during the whole light period. Low-nitrate/long-day plants had only about 30% of the NRA_max and NR protein of high-nitrate plants. In low-nitrate/long-day plants, NRA_max and NR protein decreased strongly during the second half of the light phase. The decrease was preceded by a strong decrease in the leaf nitrate content. Short daylength generally led to higher nitrate concentrations in leaves. Under short-day/low-nitrate conditions, NRA_max was slightly higher than under long-day conditions and remained almost constant during the day. This correlated with maintenance of higher nitrate concentrations during the short light period. The NR activation state in the light was very similar in high-nitrate and low-nitrate plants, but dark inactivation was twice as high in the high-nitrate plants. Thus, the low NRA_max in low-nitrate/long-day plants was slightly compensated by a higher activation state of NR. Such a partial compensation of a low NR_max by a higher dark activation state was not observed with phosphate-depleted plants. Total leaf concentrations of sugars, of glutamine and glutamate and of glucose-6-phosphate did not correlate with the NR activation state nor with NRA_max. Received: 24 March 1999 / Accepted: 31 May 1999     

Phytochrome regulation of nitrate reductase in wheat

In excised wheat leaves, the activity of nitrate reductase was enhanced by a brief pulse of red light and this increase was reversed by far-red light irradiation. Even under continuous far-red light, nitrate reductase activity increased by 258% after 18 h. When leaves were kept in distilled water during exposure to red light and then transferred to potassium nitrate, there was no difference in endogenous nitrate concentration. The nitrate reductase activity was the same whether leaves were floated in potassium nitrate or in distilled water during irradiation. Partial to complete inhibition of enzyme activity was observed when leaves were incubated in actinomycin-D and cycloheximide respectively, following 4 h of red light irradiation.In vitro irradiation of extract had no significant effect on nitrate reductase activity     

Nitrate reductase and nitrate accumulation in relation to nitrate toxicity in Boronia megastigma

Moderate levels of N were toxic to the native Australian plant boronia (Boronia megastigma Nees). As NO^-₃ is the major N form available for plants under cultivated conditions, NO^-₃ reduction and accumulation patterns in boronia were examined following the supply of various levels of NO^-₃ to understand the physiological basis of this toxicity. At a low level of supplied NO^-₃ [15 mmol (plant)^-1], NO^-₃ was reduced without any detectable accumulation and without nitrate reductase activity (NRA) reaching its maximum capacity. When higher NO^-₃ levels [≥25 mmol (plant)^-1] were supplied, both NRA and NO^-₃ accumulation increased further. However, NRA increased to a maximum of ca 500 nmol NO^-₃ (g fresh weight)^-1 h^-1, both in the roots and leaves, irrespective of a 4-fold difference in the levels of supplied NO^-₃, whereas NO^-₃ continued to accumulate in proportion to the level of supplied NO^-₃. Chlorotic toxicity symptoms appeared on the leaves at an accumulation of ca 32 μmol NO^-₃ (g fresh weight)^-1. High endogenous NO^-₃ concentrations inhibited NRA. The low level of NRA in boronia was not limited by NO^-₃ or electron donor availability. It is concluded that the low NR enzyme activity is a genetic adaptation to the low NO^-₃ availability in the native soils of boronia. Thus, when NO^-₃ supply is high, the plat cannot reduce it at high rates, leading to large and toxic accumulations of the ion in the leaf tissues.     

Critical evaluation of thein situ nitrate reductase assay

Anin situ method, derived from anin vivo method, was used to determine nitrate reductase activity (NRA) in:i) excised barley and corn shoots and excised soybean leaves during a N-depletion experiment and; ii) roots and shoots of N-depleted barley and corn seedlings during induction of nitrate, reductase (NR). Nitrate reduction, calculated from thesein situ RNA measurements, was compared with estimates of each organ's nitrate reduction in light aerobic conditions from NO ₃ ⁻ consumption and a¹⁵N model (Gojonet al., 1986b). Thein situ RNA of roots strongly underestimated their¹⁵NO ₃ ⁻ reduction. In contrast, in barley and corn shoots and in the first trifoliolate leaves from 26-day-old, soybean, thein situ NRA assay gave a fair approximation of the true NO ₃ ⁻ reduction rate (relative differences ranging from −14 to +32%). In young soybean leaves (from 20-day-old plants), however, thein situ NRA strongly underestimated the actual NO ₃ ⁻ reduction. The physiological significance of thein situ NRA assay in shoots and roots, and its value for field studies are discussed from these results.     

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.     

Circadian rhythmicity of nitrate reductase activity in barley leaves

Nitrate reductase (EC 1.6.6.1) activity showed circadian rhythmicity in the first leaf of 8–11 days old barley ( Hordeum vulgare L. cv. Herta) plants. Circadian rhythms were found using both the in vitro and in vivo method for testing the enzyme activity. When the light intensity was reduced from 65 to 20 W m⁻², the amplitude was smaller and the oscillations were damped sooner. In continuous darkness nitrate reductase activity decreased in a two step process. Three different light qualities were tested which all gave the same results.     

The influence of cytokinins in nitrate regulation of nitrate reductase activity and expression in barley

The responses of nitrate reductase (NR) activity and levels of NR-mRNA to environmental nitrate and exogenous cytokinins are characterised in roots and shoots of barley ( Hordeum vulgare L., cv. Golf), using a chemostate-like culture system for controlling nitrate nutrition. Experiments were mainly performed with split root cultures where nitrate-N was supplied at a constant relative addition rate of 0.09 day⁻¹, and distributed between the subroots in a ratio of 20%:80%. The subroot NR-mRNA level and NR activity, as well as the endogenous level of zeatin riboside (ZR), increased when the local nitrate supply to one of the subroots was increased 4-fold by reversing the nitrate addition ratio (i.e. from 20%:80% to 80%:20%). Also shoot levels of ZR, NR-mRNA and NR activity increased in response to this treatment, even though the total nitrate supply remained unaltered. External supply of ZR at 0.1 μ M caused an approximately 3-fold increase in root ZR levels within 6 h. which is comparable to the nitrate-induced increase in root ZR. External application of ZR. zeatin. isopentenyl adenine or isopentenyl adenosine at 0.1 μ M caused from insignificant to 25% increases in NR-mRNA and activity in roots and up to 100% stimulation in shoots, whereas adenine or adenosine had no effect. No synergistic effects of perturbed nitrate supply and cytokinin application were detected in either roots or shoots. The translocation of nitrate from the root to the shoot was unaffected by application of ZR or switching the nitrate distribution ratio between subroots. The data give arguments for a physiological role of cytokinins in the response of root and shoot NR to environmental nitrate availability. The nature and limitations of the physiological role of cytokinins are discussed.     

Effect of ammonium and nitrate on ferric chelate reductase and nitrate reductase in Vaccinium species

BACKGROUND AND AIMS: Most Vaccinium species have strict soil requirements for optimal growth, requiring low pH, high iron availability and nitrogen primarily in the ammonium form. These soils are limited and are often located near wetlands. Vaccinium arboreum is a wild species adapted to a wide range of soils, including high pH, low iron, and nitrate-containing soils. This broader soil adaptation in V. arboreum may be related to increased efficiency of iron or nitrate uptake compared with the cultivated Vaccinium species. METHODS: Nitrate, ammonium and iron uptake, and nitrate reductase (NR) and ferric chelate reductase (FCR) activities were compared in two Vaccinium species grown hydroponically in either nitrate or ammonia, with or without iron. The species studied were the wild V. arboreum and the cultivated V. corymbosum interspecific hybrid, which exhibits the strict soil requirements of most Vaccinium species. RESULTS: Ammonium uptake was significantly greater than nitrate uptake in both species, while nitrate uptake was greater in the wild species, V. arboreum, compared with the cultivated species, V. corymbosum. The increased nitrate uptake in V. arboreum was correlated with increased root NR activity compared with V. corymbosum. The lower nitrate uptake in V. corymbosum was reflected in decreased plant dry weight in this species compared with V. arboreum. Root FCR activity increased significantly in V. corymbosum grown under iron-deficient conditions, compared with the same species grown under iron-sufficient conditions or with V. arboreum grown under either iron condition. CONCLUSIONS: V. arboreum appears to be more efficient in acquiring nitrate compared with V. corymbosum, possibly due to increased NR activity and this may partially explain the wider soil adaptation of V. arboreum.     

Substrates regulate the phosphorylation status of nitrate reductase

The effect of substrates on the phosphorylation status of nitrate reductase (NR; EC 1.6.6.1) was studied. The enzyme was obtained from the first leaf of 7-day-old oat (Avena sativa L. cv. Suregrain) plants, grown in the light. When desalted crude extracts were incubated with ATP, NR was strongly phosphorylated, as evidenced by the inhibition of the enzyme's activity in the presence of Mg²⁺. NR sensitivity to Mg²⁺ remained unchanged when 10 mM nitrate was added to crude extracts after ATP. Addition of nitrate before or simultaneously with ATP slightly decreased Mg²⁺ inhibition of NR, which was strongly diminished in the presence of 10 mM NO₃^?+ 100 µM NADH. Incubation with NADH alone did not affect the enzyme's susceptibility to Mg²⁺ inhibition. When ammonium sulfate was added to crude extracts, NR was recovered in a 0-40% saturation fraction (F1). After incubation of F1 with ATP, the sensitivity of the enzyme to Mg²⁺ inhibition remained low, but it strongly increased after mixing F1 with a 45-60% saturation fraction (F2) suggesting that also in oats an additional factor (inactivating protein, IP), which probably binds to phospho-NR, would be required to keep the phosphorylated enzyme inactive in a +Mg²⁺ medium. Addition of 10 mM NO₃^?+ 100 µM NADH together with desalted F2 did not prevent Mg²⁺ inhibition suggesting that NO₃^? did not interfere with IP binding to phospho-NR. Again, incubation of F1 with both substrates during in vitro phosphorylation kept the enzyme active after adding F2, even in the presence of Mg²⁺, After in vitro phosphorylation, NR in crude extract was hardly reactivated when incubated alone or in the presence of 10 mM NO₃^? at 30°C. On the other hand, a strong and very rapid reactivation was found when the extract was incubated with both nitrate and NADH. Microcystine, an inhibitor of types 1 and 2A phosphoprotein phosphatases, inhibited the reactivation of phospho-NR induced by the substrates. The results presented here show that the substrates could prevent NR phosphorylation and induce the enzyme's dephosphorylation, but they were effective only after their binding to the NR protein. Thereby, they seemed to affect the NR protein itself and not the phosphatase- or the kinase-proteins. It has been reported that nitrate binding to the enzyme's active site induces conformational changes in the NR protein. We propose that this conformational change would prevent NR phosphorylation, by converting the enzyme into a form in which the site recognized by the protein kinase is no longer accessible, and, simultaneously, stimulate NR dephophorylation by allowing the specific phosphatases to recognize NR.     

Nitrate regulation of nitrate uptake and nitrate reductase expression in barley grown at different nitrate:ammonium ratios at constant relative nitrogen addition rate

Barley (Hordeum vulgare L. cv. Golf) was cultured using the relative addition rate technique, where nitrogen is added in a fixed relation to the nitrogen already bound in biomass. The relative rate of total nitrogen addition was 0.09 day^?1 (growth limiting by 35%), while the nitrate addition was varied by means of different nitrate: ammonium ratios. In 3- to 4-week-old plants, these ratios of nitrate to ammonium supported nitrate fluxes ranging from 0 to 22 μmol g^?1 root dry weight h^?1, whereas the total N flux was 21.8 ± 0.25 μmol g^?1 root dry weight h^?1 for all treatments. The external nitrate concentrations varied between 0.18 and 1.5 μM. The relative growth rate, root to total biomass dry weight ratios, as well as Kjeldahl nitrogen in roots and shoots were unaffected by the nitrate:ammonium ratio. Tissue nitrate concentration in roots were comparable in all treatments. Shoot nitrate concentration increased with increasing nitrate supply, indicating increased translocation of nitrate to the shoot. The apparent V_max for net nitrate uptake increased with increased nitrate fluxes. Uptake activity was recorded also after growth at zero nitrate addition. This activity may have been induced by the small, but detectable, nitrate concentration in the medium under these conditions. In contrast, nitrate reductase (NR) activity in roots was unaffected by different nitrate fluxes, whereas NR activity in the shoot increased with increased nitrate supply. NR-mRNA was detected in roots from all cultures and showed no significant response to the nitrate flux, corroborating the data for NR activity. The data show that an extremely low amount of nitrate is required to elicit expression of NR and uptake activity. However, the uptake system and root NR respond differentially to increased nitrate flux at constant total N nutrition. It appears that root NR expression under these conditions is additionally controlled by factors related to the total N flux or the internal N status of the root and/or plant. The method used in this study may facilitate separation of nitrate-specific responses from the nutritional effect of nitrate.     

Appearance of nitrate reductase, nitrite reductase and glutamine synthetase in different organs of the Scots pine (Pinus sylvestris) seedling as affected by light, nitrate and ammonium

Appearance of nitrate reductase (NR, EC 1.6.6.1–3), nitrite reductase (NiR, EC 1.7.7.1) and glutamine synthetase (GS, EC 6.3.1.2) under the control of nitrate, ammonium and light was studied in roots, hypocotyls and needles (cotyledonary whorl) of the Scots pine ( Pinus sylvestris L.) seedling. It was found that appearance of NiR was mainly controlled by nitrate whereas appearance of GS was strongly controlled by light. In principle, the NR activity level showed the same dependency on nitrate and light as that of NiR. In the root, both nitrate and ammonium had a stimulatory effect on GS activity whereas in the whorl the induction was minor. The level of NiR (NR) activity is high in the root and hypocotyl and low in the cotyledonary whorl, whereas the GS activity level per organ increases strongly from the root to the whorl. Thus, in any particular organ the operation of the glutamine synthetase/glutamate synthase (GS/GOGAT) cycle is not closely connected to the operation of the nitrate reduction pathway. The strong control of GS/GOGAT by light and the minor sensitivity to induction by nitrate or ammonium indicate a major role of the GS/GOGAT cycle in reassimilation of endogeniously generated ammonium.     

Factors affecting in vivo nitrate reductase activity in triticale

Factors influencing in vivo nitrate reductase activity in triticale (×Triticosecale Wittmack) primary leaves were investigated. Nitrate reductase activity was found to be a function of reaction time or tissue weight. In the range of 1–10 mm, the optimum slice width for nitrate reductase activity in triticale was found to be 1–2 mm. The optimum exogenous nitrate concentration is 300 mM. Substantial nitrite production was obtained even when exogenous nitrate was omitted from the assay. Of the five low molecular weight organic solvents tested, n-propanol is the most effective in enhancing enzyme activity. The optimum n-propanol concentration is 1% (v/v). The concentration of phosphate buffer (pH 6) does not affect nitrate reductase activity. Enzyme activity drops significantly below or above pH 6. In our system, nitrite production is enhanced by incubating under nitrogen, instead of air. The highest level of in vivo activity of nitrate reductase was found to be 10–15 cm from tip, which is close to the basal meristem of triticale primary leaves. Younger but physiologically mature leaves have higher nitrate reductase activity than old leaves.     

植物氮代谢硝酸还原酶水平调控机制的研究进展

氮代谢是植株体内最基本的物质代谢之一,硝酸还原酶是植物氮代谢的关键酶。主要对植物氮代谢在硝酸还原酶水平上调控的研究新进展,尤其是其合成／降解及活性调控机制进行了较为系统的综述。硝酸还原酶合成的调控主要发生在转录水平和翻译水平上,硝酸还原酶降解的调控主要发生在翻译后水平上,同时NO3^-及光在硝酸还原酶转录水平调控上的作用重大,硝酸还原酶编码基因转录的mRNA的稳定性强弱影响植物的氮代谢,而影响mRNA稳定性的因素很多,机理复杂;磷酸化／去磷酸化在硝酸还原酶活性调控中占举足轻重的地位,研究也比较深入。钝化蛋白也能够影响硝酸还原酶活性,许多小分子物质对硝酸还原酶活性有影响。     

Ammonium can stimulate nitrate and nitrite reductase in the absence of nitrate in Clematis vitalba

Nitrogen assimilation was studied in the deciduous, perennial climber Clematis vitalba. When solely supplied with NO₃^– in a hydroponic system, growth and N-assimilation characteristics were similar to those reported for a range of other species. When solely supplied with NH₄⁺, however, nitrate reductase (NR) activity dramatically increased in shoot tissue, and particularly leaf tissue, to up to three times the maximum level achieved in NO₃^– supplied plants. NO₃^– was not detected in plant material that had been solely supplied with NH₄⁺, there was no NO₃^– contamination of the hydroponic system, and the NH₄⁺-induced activity did not occur in tobacco or barley grown under similar conditions. Western Blot analysis revealed that the induction of NR activity, either by NO₃^– or NH₄⁺, was matched by NR and nitrite reductase protein synthesis, but this was not the case for the ammonium assimilation enzyme glutamine synthetase. Exposure of leaf disks to N revealed that NO₃^– assimilation was induced in leaves directly by NO₃^– and NH₄⁺ but not glutamine. Our results suggest that the NH₄⁺-induced potential for NO₃^– assimilation occurs when externally sourced NH₄⁺ is assimilated in the absence of any NO₃^– assimilation. These data show that the potential for nitrate assimilation in C. vitalba is induced by a nitrogenous compound in the absence of its substrate and suggest that NO₃^– assimilation in C. vitalba may have a significant role beyond the supply of reduced N for growth.     

Reversible inactivation of maize leaf nitrate reductase

Preincubation of maize leaves crude extracts with NADH resulted in a progressive accumulation of nitrite which mimicked a rapid and lineal activation of nitrate reductase. Nevertheless, in partially purified preparations it was found that preincubation at pH 8.8 with NADH promoted a gradual inactivation of nitrate reductase. At pH 7.5, the enzyme was not inactivated by the presence of NADH alone, but, with the simultaneous presence of a low concentration of cyanide, a fast inactivation took place. The NADH-cyanide-inactivated nitrate reductase remained inactive after removing the excess of NADH and cyanide by filtration through Sephadex G-25. However, it could be readily reactivated by incubation with ferricyanide or by a short exposure to light in the presence of FAD. Prolonged irradiation caused a progressive inactivation of the photoreactivated enzyme.     

Three nitrate reductase activities in Alcaligenes eutrophus

Three nitrate reductase activities were detected in Alcaligenes eutrophus strain H16 by physiological and mutant analysis. The first (NAS) was subject to repression by ammonia and not affected by oxygen indicating a nitrate assimilatory function. The second (NAR) membrane-bound activity was only formed in the absence of oxygen and was insensitive to ammonia repression indicating a nitrate respiratory function. The third (NAP) activity of potential respiratory function occurred in the soluble fraction of cells grown to the stationary phase of growth. In contrast to NAR and NAS, expression of NAP did not require nitrate for induction and was independent of the rpoN gene product. Genes for the three reductases map at different loci. NAR and NAS are chromosomally encoded whereas NAP is a megaplasmid-borne activity in A. eutrophus.     

Regulation of nitrate reductase in suspension culture of Silene alba Immunochemical approach

Silene alba cells grown on nitrate, usually develop NADH-nitrate reductase activity only at the beginning of their growth cycle. Immunodiffusion assays, with a specific nitrate reductase antiserum, revealed the presence of cross-reacting material in cells harvested at any time during their culture. Cells grown on ammonium lacked NADH-nitrate reductase activity but contained cross-reacting material. It is suggested that S. alba cells contain an enzymically inactive, antigenic form of nitrate reductase regardless of the nitrogen source.