Assimilatory nitrate reductase from Acinetobacter calcoaceticus

A soluble nitrate reductase from the bacterium Acinetobacter calcoaceticus grown on nitrate has been characterized. The reduction of nitrate to nitrite is mediated by an enzyme of 96000 molecular weight that can use as electron donors either viologen dyes chemically reduced with dithionite or enzymatically reduced with NAD(P)H, through specific diaphorases which utilize viologens as electron acceptors. Nitrate reductase activity is molybdenum-dependent as shown by tungstate antagonistic experiments and is sensitive to -SH reagents and metal chelators such as KCN.The enzyme synthesis is repressed by ammonia. Moreover, nitrate reductase activity undergoes a quick inactivation either by dithionite and temperature or by dithionite in the presence of small amounts of nitrate. Cyanate prevents this inactivating process and can restore the activity once the inactivation had occurred, thus suggesting that an interconversion mechanism may participate in the regulation of Acinetobacter nitrate reductase.Abbreviations EDTA ethylenediaminetetraacetate - BV benzyl viologen - MV methyl viologen - MW molecular weight - NEM N-ethylmaleimide - p-HMB p-hydroxymercuribenzoate - DCPIP 2,6-dichlorophenol-indophenol - FMN flavin mononucleotide - FAD flavin adenine dinucleotide - KCNO potassium cyanate     

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.     

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.     

A cyanobacterial narB gene encodes a ferredoxin-dependent nitrate reductase

The narB gene from the cyanobacterium Synechococcus sp. PCC 7942 was cloned downstream from the LacI-regulated promoter P_trc in the Escherichia coli vector pTrc99A, rendering plasmid pCSLM1. Addition of isopropyl--D-thiogalactoside to E. coli (pCSLM1) resulted in the parallel expression of a 76 kDa polypeptide and a nitrate reductase activity with properties identical to those known for nitrate reductase isolated from Synechococcus cells. As is the case for nitrate reductase from Synechococcus cells, either reduced methyl viologen or reduced ferredoxin could be used as an electron donor for the reduction of nitrate catalyzed by E. coli (pCSLM1) extracts. This data shows that narB is a cyanobacterial structural gene for nitrate reductase.     

Characterization of purified nitrate reductase A and chlorate reductase C from Proteus mirabilis

Nitrate reductase A has been solubilized from purified cytoplasmic membranes by extraction with terl-amyl alcohol. The resulting aqueous solution contained monomeric reductase which polymerized slowly to dimers and tetramers with sedimentation coefficients of respectively 10.5, 16 and 23 Svedbergunits. The polymerization could be stopped to some extent by addition of a small amount of Triton X-100. These distinct entities of nitrate reductase A were separable on electro-focusing, DEAE-column chromatography and polyacrylamide gel electrophoresis, and have been proved to consist of similar subunits with molecular weights of 104000, 63000, and 56000 daltons. The molecular weights of monomeric nitrate reductase A was found to be about 240000 daltons.Chlorate reductase C has been solubilized by a similar procedure, resulting in only monomeric enzyme. Chlorate reductase C exhibited a sedimentation coefficient of 7.7 Svedbergunits, an isoelectric point of pH=4.55 and a molecular weight of approx. 180000 daltons. It was found to consist of three subunits with molecular weights of 75000, 63000 and 56000 daltons. The latter two subunits are most probably common in nitrate reductase A and chlorate reductase C.     

Evidence for a plasma-membrane-bound nitrate reductase involved in nitrate uptake of Chlorella sorokiniana

Anti-nitrate-reductase (NR) immunoglobulin-G (IgG) fragments inhibited nitrate uptake into Chlorella cells but had no affect on nitrite uptake. Intact anti-NR serum and preimmune IgG fragments had no affect on nitrate uptake. Membrane-associated NR was detected in plasma-membrane (PM) fractions isolated by aqueous two-phase partitioning. The PM-associated NR was not removed by sonicating PM vesicles in 500 mM NaCl and 1 mM ethylenediaminetetraacetic acid and represented up to 0.8% of the total Chlorella NR activity. The PM NR was solubilized by Triton X-100 and inactivated by Chlorella NR antiserum. Plasma-membrane NR was present in ammonium-grown Chlorella cells that completely lacked soluble NR activity. The subunit sizes of the PM and soluble NRs were 60 and 95 kDa, respectively, as determined by sodium-dodecyl-sulfate electrophoresis and western blotting.Abbreviations EDTA ethylenediaminetetraacetic acid - FAD flavine-adenine dinucleotide - IgG immunoglobulin G - NR nitrate reductase - PM plasma membrane - TX-100 Triton X-100     

In-situ localization of nitrate reductase in maize roots

The localization of nitrate reductase (NR; EC 1.6.6.2) in cells of root tissues ofZea mays L. (W64A W182L) was determined using post-embedding immunogold labeling at the electron-microscopy level and using silver enhancement of the colloidal-gold signal for light microscopy. Nitrate reductase is located in the cytoplasm of root epidermal and cortical cells, and in the cells of the parenchyma and pericycle within the vascular cylinder. A weaker signal was also obtained in parenchymal cells of the pith lying next to the xylem. A positive signal for NR protein was seen in the chloroplast fraction of maize leaves and in the plastid fraction of roots. This signal was lost when affinity-purified antibodies were used. Sections of Lowicryl-embedded tissue were found to be suitable for the localization of the non-abundant NR protein when adequate controls and signal-enhancement procedures were used.Abbreviations IgG immunoglobulin G - NR nitrate reductase - PEPCase phosphoenolpyruvate carboxylase This research was funded by Natural Sciences and Engineering Research Council (NSERC) of Canada grants ISE0125461 (AO), OGP0106265 (JSG) and an NSERC Visiting Scientist Award to E.F.     

Rapid modulation of nitrate reductase in pea roots

The regulatory properties of nitrate reductase (NR; EC 1.6.6.1) in root extracts from hydroponically grown pea (Pisum sativum L. cv. Kleine Rheinländerin) plants were examined and compared with known properties of NR from spinach and pea leaves. Nitrate-reductase activity (NRA) extracted from pea roots decreased slowly when plants were kept in the dark, or when illuminated plants were detopped, with a half-time of about 4 h (= slow modulation in vivo). In contrast, the half-time for the dark-inactivation of NR from pea leaves was only 10 min. However, when root tip segments were transferred from aerobic to anaerobic conditions or vice versa, changes in NRA were as rapid as in leaves (= rapid modulation in vivo). Nitrate-reductase activity was low when extracted from roots kept in solutions flushed with air or pure oxygen, and high in nitrogen. Okadaic acid, a specific inhibitor of type-1 and type-2A protein phosphatases, totally prevented the in vivo activation by anaerobiosis of NR, indicating that rapid activation of root NR involved protein dephosphorylation. Under aerobic conditions, the low NRA in roots was also rapidly increased by incubating the roots with either uncouplers or mannose. Under these conditions, and also under anaerobiosis, ATP levels in roots were much lower than in aerated control roots. Thus, whenever ATP levels in roots were artificially decreased, NRA increased rapidly. The highly active NR extracted from anaerobic roots could be partially inactivated in vitro by preincubation of desalted root extracts with MgATP (2 mM), with a half-time of about 20 min. It was reactivated by subsequently incubating the extracts with excess AMP (2 mM). Thus, pea root NR shares many of the previously described properties of NR from spinach leaves, suggesting that the root enzyme, like the leaf enzyme, can be rapidly modulated, probably by reversible protein phosphorylation/ dephosphorylation.     

Light and nitrate induction of nitrate reductase in kinetin-and gibberellic acid-treated mustard cotyledons

Nitrate reductase activity in gibberellic acid and kinetin treated mustard (Brassica juncea Coss. cv. T-59 ‘Varuna’) seedlings, grown in the presence or absence of light and/or NO₃ was investigated. While both light and NO₃, alone could induce NR activity, their combination showed additive effects. Kinetin treatment significantly promoted both light- and NO₃- induced NR activities, assayed by either in vivo or in vitro techniques, whereas, gibberellic acid was almost ineffective. In the absence of both light and NO₃, however, phytohormones alone could not induce NR activity. Both light-induced and NO₃ induced NR fractions had a pH optima of 7.5, preferred NADH as an electron donor (NADH: NADPH ratio 2.5) and K_m values for NO₃ was 0.2 mM. Actinomycin D, cycloheximide and tungstate were equally effective in suppressing the development of NR activity after exposure to light or NO₃. These results indicate that two independent NR fractions operate, with apparently identical properties but separate control mechanisms.     

Seasonal and diurnal variation in nitrate reductase activity of cowpeas

The seasonal and diurnal variations in nitrate reductase activity (NRA) of cowpea cultivars were determined. Mean activity per gram fresh weight per hour averaged 31% higher in the 20 mg N/plant treatment than the control throughout the growing period. The highest activity occurred in the seedling stage and declined towards anthesis. Diurnal variations were marked by an increase in the NRA from 0600 to 1800 hours and then declined to a minimum at 2400 hours.     

Studies of nitrate reductase in the fresh water dinoflagellatePeridinium cinctum

Nitrate reduction was studied in the dinoflagellatePeridinium cinctum collected from extensive algal blooms in Lake Kinneret (Israel).Among several methods tested for the preparation of cell free extracts, only the use of a ground-glass tissue culture homogenizer was found to be efficient. The assimilatory nitrate reductase ofP. cinctum was located in a particulate fraction. In this respect,P. cinctum did not behave like other eukaryotes, such as green algae, but as a prokaryote. Nitrite reductase activity was found in the soluble fraction.Nitrate reductase used NADH as a preferable electron donor; it reacted also with NADPH but only to give 16.5% of the NADH dependent rate. Methyl viologen and benzyl viologen could also serve as electron donors, with rates higher than the NADH dependent activity (3–6 times and 1.5–3 times, respectively). The Km of nitrate reductase for NADH was 2.8×10^–4 M and for NO₃-1.9×10^–4 M. Flavins did not stimulate the activity, nor was ferricyanide able to activate it. Carboxylic anions stimulated nitrate reductase activity 3–4 fold, an effect which was not mimicked by other anions.Chlorate, azide and cyanide were competitive inhibitors ofP. cinctum, nitrate reductase withK _i values of 1.79×10^–3 M, 2.1×10^–5 M and 8.9×10^–6 M respectively.     

The effect of vanadium on nitrate reductase of Chlorella vulgaris

Added vanadate ions inhibit purified nitrate reductase from Chlorella vulgaris by reacting with the enzyme in a manner rather similar to that of HCN. Thus vanadate, like HCN, forms an inactive complex with the reduced enzyme, and this inactivated enzyme can be reactivated rapidly by adding ferricyanide. The inactive vanadate enzyme complex is less stable than the inactive HCN complex, and the two can be distinguished by the fact that EDTA causes a partial reactivation of the former, but not of the latter. Vanadate can also cause an increase in HCN formation by intact Chlorella vulgaris cells. When these cells were incubated with vanadate, their nitrate reductase was reversibly inactivated, and all of this inactive enzyme could be shown to be the HCN complex rather than the vanadate complex. When HCN and vanadate are both present, the HCN-inactivated enzyme, being more stable, will be formed in preference to the vanadate-inactivated enzyme.Abbreviation EDTA ethylenediamine tetraacetate     

Short-term modulation of nitrate reductase activity by exogenous nitrate in Nicotiana plumbaginifolia and Zea mays leaves

Maize (Zea mays L.) grown on low (0.8 mM) NO ₃ ^- , as well as untransformed and transformed Nicotiana plumbaginifolia constitutively expressing nitrate reductase (NR), was used to study the effects of NO ₃ ^- on the NR activation state. The NR activation state was determined from the relationship of total activity extracted in the presence of ethylenediaminetetracetic acid to that extracted in the presence of Mg²⁺. Light activation was observed in both maize and tobacco leaves. In the tobacco lines, NO ₃ ^- did not influence the NR activation state. In excised maize leaves, no correlation was found between the foliar NO ₃ ^- content and the NR activation state. Similarly, the NR activation state did not respond to NO ₃ ^- . Since the NR activation state determined from the degree of Mg²⁺-induced inhibition of NR activity is considered to reflect the phosphorylation state of the NR protein, the protein phosphatase inhibitor microcystin LR was used to test the importance of protein phosphorylation in the NO ₃ ^- -induced changes in NR activity. In-vivo inhibition of endogenous protein phosphatase activity by microcystin-LR decreased the level of NR activation in the light. This occurred to the same extent in the presence or absence of exogenous NO ₃ ^- . We conclude that NO ₃ ^- does not effect the NR activation state, as modulated by protein phosphorylation in either tobacco (a C₃ species) or maize (a C₄ species). The short-term regulation of NR therefore differs from the NO ₃ ^- -mediated responses observed for phosphoenolpyruvate carboxylase and sucrose phosphate synthase.Abbreviations Chl chlorophyll - MC microcystin-LR - PEP-Case phosphoenolpyruvate carboxylase - SPS sucrose-phosphate synthase We are indebted to Madeleine Provot and Nathalie Hayes for excellent technical assistance. This work was funded by EEC Biotechnology Contract No. BI02 CT93 0400, project of technical priority, Network D — Nitrogen Utilisation and Efficiency.     

Characterization of a chlorate-hypersensitive,high nitrate reductase Arabidopsis thaliana mutant

Summary A population of A. thaliana, produced by self-fertilization of ethylmethane sulfonate treated plants, was exposed to chlorate in the watering solution, and plants showing early susceptibility symptoms were rescued. Among the progeny lines of these plants five were shown to be repeatably chlorate-hypersusceptible. One of these lines (designated C-4) possessed elevated activity of nitrate reductase (NR). The NR activity of mutant C-4 was higher than that of normal plants throughout the life cycle. Nitrite reductase and glutamine synthetase activities of C-4 were normal, as were chlorate uptake rate and tissue nitrate content. The elevated NR activity apparently was responsible for the chlorate hypersusceptibility of C-4. Inheritance studies of NR indicated that the elevated activity of C-4 was probably controlled by a single recessive allele.     

Reversible inactivation of nitrate reductase in Chlorella vulgaris in vivo

Summary The NADH-nitrate oxidoreductase of Chlorella vulgaris has an inactive form which has previously been shown to be a cyanide complex of the reduced enzyme. This inactive enzyme can be reactivated by treatment with ferricyanide in vitro. In the present study, the activation state of the enzyme was determined after different prior in vivo programs involving environmental variations. Oxygen, nitrate, light and CO₂ all affect the in vivo inactivation of the enzyme in an interdependent manner. In general, the inactivation is stimulated by O₂ and inhibited by nitrate and CO₂. Light may stimulate or inhibit, depending on conditions. Thus, the effects of CO₂ and nitrate (inhibition of reversible inactivation) are clearly manifested only in the light. In contrast, light stimulates the inactivation in the presence of oxygen and the absence of CO₂ and nitrate. Since the inactivation of the enzyme requires HCN and NADH, and it is improbable that O₂ stimulates NADH formation, it is reasonable to conclude that HCN is formed as the result of an oxidation reaction (which is stimulated by light). The formation of HCN is probably stimulated by Mn²⁺, since the formation of reversibly-inactivated enzyme is impaired in Mn²⁺-deficient cells. The prevention of enzyme inactivation by nitrate in vivo is in keeping with previous in vitro results showing that nitrate prevents inactivation by maintaining the enzyme in the oxidized form. A stimulation of nitrate uptake by CO₂ and light could account for the effect of CO₂ (prevention of inactivation) which is seen mainly in the presence of nitrate and light. Ammonia added in the presence of nitrate has the same effect on the enzyme as removing nitrate (promotion of reversible inactivation). Ammonia added in the absence of nitrate has little extra effect. It is therefore likely that ammonia acts by preventing nitrate uptake. The uncoupler, carbonylcyanide-m-chloro-phenylhydrazone, causes enzyme inactivation because it acts as a good HCN precursor, particularly in the light. Nitrite, arsenate and dinitrophenol cause an enzyme inactivation which can not be reversed by ferricyanide in crude extracts. This suggests that there are at least two different ways in which the enzyme can be inactivated rather rapidly in vivo.     

Activation,synthesis and turnover of nitrate reductase controlled by nitrate and ammonium in Chlorella vulgaris

Cells of Anacystis nidulans grown at 25 or 30°C were examined both by thin-section and freeze-fracture electron microscopy. Cells grown at either temperature appeared similar when fixed at the growth temperature prior to observation. When cells were chilled to near 0°C for 30 min prior to fixation, those previously grown at 25° appeared unchanged as judged by thin sectioning while those grown at 39° showed considerable morphological alteration. Freeze fracture showed particle aggregation (more pronounced in 39°-grown cells) indicating lipid-phase separation in cells chilled prior to fixation. The phase separation was totally reversed by rewarming the chilled, 25°-grown cells to their growth temperature but was only partially reversed by rewarming chilled, 39°-grown cells. These results correlate with other effects of chilling seen in Anacystis cells grown at different temperatures.     

Studies on the regulation of assimilatory nitrate reductase in Ankistrodesmus braunii

In the green alga Ankistrodesmus braunii, all the activities associated with the nitrate reductase complex (i.e., NAD(P)H-nitrate reductase, NAD(P)H-cytochrome c reductase and FMNH₂-or MVH-nitrate reductase) are nutritionally repressed by ammonia or methylamine. Besides, ammonia or methylamine promote in vivo the reversible inactivation of nitrate reductase, but not of NAD(P)H-cytochrome c reductase. Subsequent removal of the inactivating agent from the medium causes reactivation of the inactive enzyme. Menadione has a striking stimulation on the in vivo reactivation of the inactive enzyme. The nitrate reductase activities, but not the diaphorase activity, can be inactivated in vitro by preincubating a partially purified enzyme preparation with NADH or NADPH. ADP, in the presence of Mg²⁺, presents a cooperative effect with NADH in the in vitro inactivation of nitrate reductase. This effect appears to be maximum at a concentration of ADP equimolecular with that of NADH.Abbreviations ADP Adenosine-5-diphosphate - AMP Adenosine-5-monophosphate - ATP Adenosine-5-triphosphate - FAD Flavin adenine dinucleotide - FMNH₂ Flavin adenine mononucleotide, reduced form - GDP Guanosine-5-diphosphate - MVH Methyl viologen, reduced form - NADH Nicotinamide adenine dinucleotide, reduced form - NADPH Nicotinamide adenine dinucleotide phosphate, reduced form     

Characterization and sequence of a novel nitrate reductase from barley

Summary Barley (Hordeum vulgare L.) has both NADH-specific and NAD(P)H-bispecific nitrate reductases. Genomic and cDNA clones of the NADH nitrate reductase have been sequenced. In this study, a genomic clone (pMJ4.1) of a second type of nitrate reductase was isolated from barley by homology to a partial-length NADH nitrate reductase cDNA and the sequence determined. The open reading frame encodes a polypeptide of 891 amino acids and its interrupted by two small introns. The deduced amino acid sequence has 70% identity to the barley NADH-specific nitrate reductase. The non-coding regions of the pMJ4.1 gene have low homology (ca. 40%) to the corresponding regions of the NADH nitrate reductase gene. Expression of the pMJ4.1 nitrate reductase gene is induced by nitrate in root tissues which corresponds to the induction of NAD(P)H nitrate reductase activity. The pMJ4.1 nitrate reductase gene is sufficiently different from all previously reported higher plant nitrate reductase genes to suggest that it encodes the barley NAD(P)H-bispecific nitrate reductase.Scientific Paper No. 9101-14. College of Agriculture and Home Economics Research Center, Washington State University, Research Project Nos. 0233 and 0745     

Induction of nitrate reductase, nitrite reductase, and glutamine synthetase isoforms in sunflower cotyledons as affected by nitrate, light, and plastid integrity

Summary We investigated the inducibility of nitrate reductase (NR; EC 1.6.6.1), nitrite reductase (NiR; EC 1.7.7.1), and glutamine synthetase (GS; EC 6.3.1.2) isoforms in cotyledons of 7-day-old seedlings of sunflower (Helianthus annuus L.) in relation to light, nitrogen source (NO ₃ ^– , NO ₂ ^– or NH ₄ ⁺ ), and the involvement of plastids. Nitrate was absolutely (and specifically) required for NR induction, and stimulated more effectively than NO ₂ ^– or NH ₄ ⁺ the synthesis of NiR and chloroplastic GS (GS₂) over the constitutive levels present in N-free-grown seedlings. In vivo inhibition of NR activity by tungsten application to seedlings and measurements of tissue NO ₃ ^– concentration indicate that NO ₃ ^– -dependent enzyme induction is elicited by NO ₃ ^– per se and not by a product of its assimilatory reduction, e.g., NO ₂ ^– or NH ₄ ⁺ . In the presence of NO ₃ ^– , light remarkably enhanced the appearance of NR, NiR, and GS₂, while the activity of the cytosolic GS isoform (GS₁) was adversely affected. Cycloheximide suppressed much more efficiently than chloramphenicol the light- and NO ₃ ^– -dependent increase of GS₂ activity, indicating that sunflower chloroplastic GS is synthesized on cytoplasmic 80S ribosomes. When the plastids were damaged by photooxidation in cotyledons made carotenoid-free by application of norflurazon, the positive action of light and NO ₃ ^– on the appearance of NR, NiR, and GS₂ isoform was greatly abolished. Therefore, it is suggested that intact chloroplasts are required for the inductive effect of light and NO ₃ ^– and/or for the accumulation of newly formed enzymes in the organelle.Abbreviations CAP chloramphenicol - CHX cycloheximide - GS glutamine synthetase - GS₁ cytosolic GS - GS₂ plastidic (chloroplastic) GS - NF norflurazon - NiR nitrite reductase - NR nitrate reductase