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.     

Nitrate assimilation in the forage legume Lotus japonicus L.

Nitrate assimilation in the model legume, Lotus japonicus, has been investigated using a variety of approaches. A gene encoding a nitrate-inducible nitrate reductase (NR) has been cloned and appears to be the only NR gene present in the genome. Most of the nitrate reductase activity (NRA) is found in the roots and the plant assimilates the bulk of its nitrogen in that tissue. We calculate that the observed rates of nitrate reduction are compatible with the growth requirement for reduced nitrogen. The NR mRNA, NRA and the nitrate content do not show a strong diurnal rhythm in the roots and assimilation continues during the dark period although export of assimilated N to the shoot is lower during this time. In shoots, the previous low NR activity may be further inactivated during the dark either by a phosphorylation mechanism or due to reduced nitrate flux coincident with a decreased delivery through the transpiration stream. From nitrate-sufficient conditions, the removal of nitrate from the external medium causes a rapid drop in hydraulic conductivity and a decline in nitrate and reduced-N export. Root nitrate content, NR and nitrate transporter (NRT2) mRNA decline over a period of 2 days to barely detectable levels. On resupply, a coordinated increase of NR and NRT2 mRNA, and NRA is seen within hours.     

Nitrate reductase induction and molecular characterization in rice (Oryza sativa L.)

Summary Barley nitrate reductase cDNA clone bNRp10 was used as a hybridization probe to screen a genomic DNA library of rice (Oryza sativa L.) cultivar M201. Two different lambda clones were isolated, subcloned to plasmids, and partially characterized. The subclone pHBH1 was tentatively identified as encoding a NADH nitrate reductase. Southern and dot blot analysis suggest that, in rice, nitrate reductase is encoded by a small gene family. Regulation of NADH nitrate reductase was investigated in rice cultivars Labelle and M201 representing the subspecies indica and japonica, respectively. In the absence of nitrate, only trace levels of nitrate reductase activity and mRNA were detected in seedling leaves. Upon addition of nitrate to seedling roots, nitrate reductase activity and mRNA increased rapidly in leaves. Nitrate reductase activity continued to increase over a 24 h period, but the mRNA accumulation peaked at about 6 h and then declined. Western blot analysis with a barley NADH nitrate reductase antiserum showed the presence of two bands of approximately 115 and 105 kDa. These protein bands were not detected in extracts of tissue grown in the absence of nitrate.     

The Mechanism of Nitrate Accumulation in Pakchoi [Brassica Campestris L.ssp. Chinensis(L.)]

Decreased nitrate in vegetables can improve crop nitrogen utilization efficiency and lessen the human health risk caused by the reduction of nitrate to nitrite in vegetables. This paper studied the mechanisms of differences in nitrate accumulation and distribution within organs of two cultivars of pakchoi (Brassica campestris L.ssp. Chinensis (L.) previously screened in hydroponic experiments from 12 cultivars popularly grown in China at present. The two typical cultivars used in this experiment were Shanghaiqing with low nitrate accumulation and Liangbaiye 1 with high nitrate accumulation. There was no significant difference of total nitrate uptake but a significant difference in nitrate content existed between the two cultivars. Compared with Liangbaiye 1, Shanghaiqing showed a significantly higher photosynthetic rate and nitrate reductase activity. Determination of nitrate concentration (activity) in vacuoles with double-barrelled nitrate-selective microelectrodes showed that Shanghaiqing had lower vacuolar nitrate activity than Liangbaiye 1. Two putative nitrate reductase genes, nia1 and nia2, were amplified from the leaf blades of these two cultivars. Nia1 mRNA fragments (887 bp, accession numbers DQ082868 and DQ082869) were amplified using degenerate primer and nia2 mRNA fragment was amplified using one pair of generate primers designed according to DQ001901. Sequence analysis of DQ082868 and DQ082869 both showed 97% and 87% similarity with two nitrate reductase mRNA sequences of Brassica napus, accession numbers D38219 and D38220, respectively. The results of real time PCR to compare the relative expression of the putative nitrate reductase genes (nia1 and nia2) showed that Shanghaiqing had significantly higher expression level than Liangbaiye 1 and nia2 was significantly higher than nia1 in leaf blade and petiole. Both the nitrate reductase activity and the relative expression level of nia1 were in the order of leaf blade > root > petiole, while that of nia2 was leaf blade > petiole > root. There was no statistically significant difference of nitrate activity stored in vacuoles between the different organs of the two cultivars. It can be concluded that Shanghaiqing took up slightly less nitrate, but had significantly higher nitrate reductase activity in cytosol and had a higher relative expression of the putative nitrate reductase genes than Liangbaiye 1; this leads to the fact that Shanghaiqing has a lower nitrate content than Liangbaiye 1.     

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     

Isolation and characterization of Nicotiana plumbaginifolia nitrate reductase-deficient mutants: genetic and biochemical analysis of the NIA complementation group

Summary Two hundred and eleven nitrate reductase-deficient mutants (NR^–) were isolated from mutagenized Nicotiana plumbaginifolia protoplast cultures by chlorate selection and regenerated into plant. More than 40% of these clones were classified as cnx and presumed to be affected in the biosynthesis of the molybdenum cofactor, the remaining clones being classified as nia mutants. A genetic analysis of the regenerated plants confirmed this proportion of nia and cnx clones. All mutants regenerated were found to carry monogenic recessive mutations that impaired growth on nitrate as sole nitrogen source. Mutants propagated by grafting on N. tabacum systematically displayed a chlorotic leaf phenotype. This chlorosis was therefore related to the NR deficiency. The observation of leaves with NR^– chlorotic sectors surrounded by NR⁺ wild-type tissues suggeests that an NR deficiency is not corrected by diffusible factors. Periclinal chimeras between wild-type tobacco and the NR^– graft were also observed. In this type of chimeric tissue chlorosis was no longer detectable when NR⁺ cells were in the secondmost (L2) layer, but was still detectable when NR^– cells were in the secondmost layer. The genetic analysis of nia mutants revealed that they belong to a single complementation group. However three nia mutants were found to complement some of the other nia mutants. The apoenzyme of nitrate reductase was immunologically detected in several nia mutants but not in other members of this complementation group. Some of the nia mutants, although they were NR^–, still displayed methylviologenitrate reductase activity at a high level. These data show that the nia complementation group corresponds to the structural gene of nitrate reductase. Some of the mutations affecting this structural gene result in the overproduction of an inactive nitrate reductase, suggesting a feedback regulation of the level of the apoenzyme in the wild type.     

Evidence for nitrate reductase expression during initiation of lateral roots by NAA in chicory

The supply of -naphthaleneacetic acid (NAA), to excised chicory roots induced the formation of lateral root meristems mainly localized proximal to the pre-existing apical root meristem, in a region which does not initiate any lateral roots in control conditions. Inhibition of root elongation and concomitant enlargement of the apices were also observed. Quantification of NAA and cytokinin levels showed that the most reproducible and significant changes occurring after the NAA treatment consisted of a decrease in the level of zeatin-O-glucoside conjugates. Hydrolysis of these conjugates might deliver free zeatin-type compounds which were consumed during the lateral root growth. After 5 d, control excised roots contained a high level of amino acids, mainly as asparagine and arginine, probably issued from proteolysis associated to a senescent-like process. Conversely, in the presence of NAA, neither accumulation of amino acids nor a decrease of the total protein content of the tissue could be detected. Newly initiated meristems expressed the nia gene which encodes nitrate reductase, the first enzyme of the nitrate assimilatory pathway. Thus the increased expression of nitrate reductase which was observed in excised roots of chicory supplied with NAA (Vuylsteker et al., 1997b) may be ascribed to lateral root formation and development. The reinduction of nitrate reduction activity was driven by the increased demand for reduced nitrogen. Thus, the nia gene is one of the genes expressed during the early stages of root meristem formation.Keywords: Auxins, chicory, in situ hybridization, lateral root, nitrate reductase.      

Relationship of nitrate supply with growth rate, plasma membrane-bound and cytosolic nitrate reductase, and tissue nitrate content in tobacco plants

cNR, cytosolic nitrate reductase
PM-NR, plasma membrane-bound nitrate reductase

Activities of plasma membrane-bound nitrate reductase (PM-NR) and cytosolic nitrate reductase (cNR) in tobacco (Nicotiana tabacum L. cv. Samsun) are regulated differently, depending upon the nitrate supply to the culture medium (in sand culture). The cNR activity of roots was higher at low nitrate concentrations with the maximum at 5 mM nitrate supply and declined to low values beyond 5 mM . In contrast, the PM-NR activity of roots increased with higher nitrate concentrations with the maximum at 25 mM nitrate and clearly decreased only at 40 mM . This high PM-NR activity correlated with a low growth rate and might be one of the responses to excess nitrate. Internal nitrate and total nitrogen content of the tissues, however, showed a relative minimum in shoots and in roots of between 15 and 25 mM external nitrate. With declining PM-NR activities beyond 25 mM external nitrate, the nitrate content in the tissue increased indicating an inverse relationship between tissue nitrate content and root PM-NR activity. In leaves both NR activities (cNR and PM-NR) correlated with the internal nitrate content, but with a different response at low nitrate.     

Daily changes in nitrate uptake and metabolism in Capsicum annuum

The diurnal pattern of nitrate uptake by Capsicum annuum L. cv. California Wonder in a constant environment is described by a Fourier harmonic, with the maximum uptake in the middle of the photoperiod and the minimum in the middle of the dark period. Comparison of the uptake pattern with that of nitrate reductase (EC 1.6.6.1.) activity suggests against a direct control of one process by the other. This was confirmed by the observation that the pattern of nitrate reductase activity was not altered by restricting nitrate uptake to one hour per day. Translocation of ¹⁵N from the roots is much greater in the lightperiod than in the dark period. Reduction of ¹⁵N in the leaves occurs in the lightperiod but very little is reduced in the dark period. Amino acid levels showed marked daily fluctuations but in the roots neither amino acids, sucrose, fructose, glucose nor malate showed fluctuations. The amino acid composition of roots and leaves differed: glutamine+glutamate were relatively more important in leaves than in roots whereas alanine was a more important constituent of roots than of leaves.Abbreviation NR nitrate reductase     

Nitrate reductase activity of two leafy vegetables as affected by nickel and different nitrogen forms

The author studied the effect of different nickel concentrations (0, 0.4, 40 and 80 μM Ni) on the nitrate reductase (NR) activity of New Zealand spinach (Tetragonia expansa Murr.) and lettuce (Lactuca sativa L. cv. Justyna) plants supplied with different nitrogen forms (NO₃ ⁻–N, NH₄ ⁺–N, NH₄NO₃). A low concentration of Ni (0.4 μM) did not cause statistically significant changes of the nitrate reductase activity in lettuce plants supplied with nitrate nitrogen (NO₃ ⁻–N) or mixed (NH₄NO₃) nitrogen form, but in New Zealand spinach leaves the enzyme activity decreased and increased, respectively. The introduction of 0.4 μM Ni in the medium containing ammonium ions as a sole source of nitrogen resulted in significantly increased NR activity in lettuce roots, and did not cause statistically significant changes of the enzyme activity in New Zealand spinach plants. At a high nickel level (Ni 40 or 80 μM), a significant decrease in the NR activity was observed in New Zealand spinach plants treated with nitrate or mixed nitrogen form, but it was much more marked in leaves than in roots. An exception was lack of significant changes of the enzyme activity in spinach leaves when plants were treated with 40 μM Ni and supplied with mixed nitrogen form, which resulted in the stronger reduction of the enzyme activity in roots than in leaves. The statistically significant drop in the NR activity was recorded in the aboveground parts of nickel-stressed lettuce plants supplied with NO₃ ⁻–N or NH₄NO₃. At the same time, there were no statistically significant changes recorded in lettuce roots, except for the drop of the enzyme activity in the roots of NO₃ ⁻-fed plants grown in the nutrient solution containing 80 μM Ni. An addition of high nickel doses to the nutrient solution contained ammonium nitrogen (NH₄ ⁺–N) did not affect the NR activity in New Zealand spinach plants and caused a high increase of this enzyme in lettuce organs, especially in roots. It should be stressed that, independently of nickel dose in New Zealand spinach plants supplied with ammonium form, NR activity in roots was dramatically higher than that in leaves. Moreover, in New Zealand spinach plants treated with NH₄ ⁺–N the enzyme activity in roots was even higher than in those supplied with NO₃ ⁻–N.     

Relationships between external nitrate availability,nitrate uptake and expression of nitrate reductase in roots of barley grown in N-limited split-root cultures

Despite the large number of studies of nitrate metabolism in plants, it remains undetermined to what extent this key plant system is controlled by overall plant N nutrition on the one hand, and by the nitrate ion itself on the other hand. To investigate these questions, V _max for nitrate uptake (high-affinity range), and nitrate reductase (NR) mRNA and activity, were measured in roots of N-limited barley (Hordeum vulgare L. cv. Golf) grown under conditions of constant relative addition of nitrate, with the seminal roots split between two culture compartments. The total amount of nitrate added per unit time (0.09·d^-1) was distributed between the two root parts (subroots) in ratios of 1000, 982, 955, 9010, 8020, and 5050. These nitrate-addition ratios resulted in nitrate fluxes ranging from 0 to 23 mol nitrate·g^-1 DW root·h^-1, while the external nitrate concentrations varied between 0 and 1.2 M. The apparent V _max for net nitrate uptake showed saturation-type responses to nitrate flux maintained during preceding growth. The flux resulting in half-maximal induction of nitrate uptake was approximately 4 mol nitrate·g^-1 DW root·h^-1, corresponding to an external nitrate concentration of 0.7 M. The activity of NR and levels of NR mRNA did not saturate within the range of nitrate fluxes studied. None of the parameters studied saturated with respect to the steady-state external nitrate concentration. At the zero nitrate addition — the 0%-root — initial uptake activity as determined in short-term ¹⁵N-labelling experiments was insignificant, and NR activity and NR mRNA were not detectable. However, nitrate uptake was rapidly induced, showing that the 0%-root had retained the capacity to respond to nitrate. These results suggest that local nitrate availability has a significant impact on the nitrate uptake and reducing systems of a split-root part when the total plant nitrate nutrition is held constant and limiting.Abbreviation NR nitrate reductase This work was supported by the Lars Hierta Memory Foundation, the Royal Swedish Academy of Sciences, and by the Swedish Natural Science Research Council via project grants (to C.-M.L. and B.I.) and visiting scientist grant (to W.H.C.). We thank Mrs. Ellen Campbell for technical advice, and Mrs. Judith V. Purves, Long Ashton Research Station, Long Ashton, UK, for analyses of ¹⁵N-labelling in tissue samples.     

Inhibition of maize root growth by high nitrate supply is correlated with reduced IAA levels in roots

The plant root system is highly sensitive to nutrient availability and distribution in the soil. For instance, root elongation is inhibited when grown in high nitrate concentrations. To decipher the mechanism underlying the nitrate-induced inhibition of root elongation, the involvement of the plant hormone auxin in nitrate-dependent root elongation of maize was investigated. Root growth, nitrogen and nitrate concentrations, and indole-3-acetic acid (IAA) concentrations in roots and in phloem exudates of maize grown under varying nitrate concentrations were analyzed. Total N and nitrate concentrations in shoots and roots increased and elongation of primary, seminal and crown roots were inhibited with increasing external nitrate from 0.05 to 5 mM. High nitrate-inhibited root growth resulted primarily from the reduced cell elongation and not from changes in meristem length. IAA concentrations in phloem exudates reduced with higher nitrate supply. Inhibition of root growth by high nitrate was closely related to the reduction of IAA levels in roots, especially in the sections close to root tips. Exogenous NAA and IAA restored primary root growth in high nitrate concentrations. It is concluded that the inhibitory effect of high nitrate concentrations on root growth may be partly attributed to the decrease in auxin concentrations of roots.     

Expression of a chimeric nitrate reductase gene in transgenic lettuce reduces nitrate in leaves

 Transgenic plants of four glasshouse-grown lettuce cultivars ('Cortina', 'Evola', 'Flora' and 'Luxor') were obtained by co-cultivating excised cotyledons with Agrobacterium tumefaciens. The Agrobacterium strain LBA4404 contained the binary vector pBCSL16, which carried a nitrate reductase (nia) cDNA linked to CaMV promoter and terminator sequences, and the neomycin phosphotransferase II (nptII) gene. Transformed shoots were selected by their ability to root on medium containing kanamycin sulphate, by a positive NPTII assay and by PCR analysis. The presence of the nia cDNA in transgenic lettuce was confirmed by nitrate reductase (NR) enzymatic assay, a reduction in the nitrate content of leaves and by Southern hybridisation. PCR analysis of cDNA fragments from transgenic plants confirmed that both nia and nptII genes were expressed in first seed-generation (T1) lettuce plants. The commercial importance of reduced nitrate concentrations in lettuce is discussed. Received: 7 January 1998 / Revision received: 24 February 1998 / Accepted: 22 March 1999     

Inheritance and expression of NAD(P)H nitrate reductase in barley

Summary NADH-specific and NAD(P)H bispecific nitrate reductases are present in barley (Hordeum vulgare L.). Wild-type leaves have only the NADH-specific enzyme while mutants with defects in the NADH nitrate reductase structural gene (nar1) have the NAD(P)H bispecific enzyme. A mutant deficient in the NAD(P)H nitrate reductase was isolated in a line (nar1a) deficient in the NADH nitrate reductase structural gene. The double mutant (nar1a;nar7w) lacks NAD(P)H nitrate reductase activity and has xanthine dehydrogenase and nitrite reductase activities similar to nar1a. NAD(P)H nitrate reductase activity in this mutant is controlled by a single codominant gene designated nar7. The nar7 locus appears to be the NAD(P)H nitrate reductase structural gene and is not closely linked to nar1. From segregating progeny of a cross between the wild type and nar1a;nar7w, a line was obtained which has the same NADH nitrate reductase activity as the wild type in both the roots and leaves but lacks NADPH nitrate reductase activity in the roots. This line is assumed to have the genotype Nar1Nar1nar7nar7. Roots of wild type seedlings have both nitrate reductases as shown by differential inactivation of the NADH and NAD(P)H nitrate reductases by a monospecific NADH-nitrate reductase antiserum. Thus, nar7 controls the NAD(P)H nitrate reductase in roots and in leaves of barley.Scientific Paper No. 7617, College of Agriculture Research Center and Home Economics, Washington State University, Pullman, WA, USA. Project Nos. 0233 and 0745     

Nitrate reductase activity of free-living and symbiotic uptake hydrogenase-positive and uptake hydrogenase-negative strains of Bradyrhizobium japonicum

The nitrate reductase activity (NR) of selected uptake hydrogenase-positive (hup ⁺) and uptake hydrogenase-negative (hup ^-) strains of Bradyrhizobium japonicum were examined both in free-living cells and in symbioses with Glycine max L. (Marr.) cv. Williams. Bacteria were cultured in a defined medium containing either 10 mM glutamate or nitrate as the sole nitrogen source. Nodules and bacteriods were isolated from plants that were only N₂-dependent or grown in the presence of 2 mM KNO₃. Rates of activity in nodules were determined by an in vivo assay, and those of cultured cells and bacteriods were assayed after permeabilization of the cells with alkyltrimethyl ammonium bromide. All seven strains examined expressed NR activity as free-living cells and as symbiotic forms, regardless of the hup genotype of the strain used for inoculation. Although the presence of nitrate increased nitrate reduction by cultures cells and nodules, no differences in NR activity were observed between bacteroids isolated from nodules of plants fed with nitrate or grown on N₂-fixation exclusively. Cultured cells, nodules and bacteriods of strains with hup ^- genotype (USDA 138, L-236, 3. 15B3 and PJ17) had higher rates of NR activity than those with hup ⁺ genotype (USDA 110, USDA 122 DES and CB1003). These results suggest that NR activity is reduced in the presence of a genetic determinant associated with the hup region of B. japonicum.Abbreviations EDTA ethylene-diamine tetraacetic acid - Hup hydrogen uptake - MOPS 3-(N-morpholino)-propane sulfonic acid - NR nitrate reductase - PVP polyvinyl-polypyrrolidone - Tris Tris(hydroxymethyl)-aminomethane     

Nitrate reduction and nitrate content in ash trees (Fraxinus excelsior L.): distribution between compartments,site comparison and seasonal variation

Summary Nitrate reductase activity (NRA), nitrate content and biomass components of leaflets, leaf stalks, old stem, current-year stem and roots of ash trees (Fraxinus excelsior L.) growing in their natural habitats were investigated. In addition, NRA, total nitrogen and nitrate concentration were analyzed in the leaves and roots of ash trees from four different field sites. The highest NRA per gram biomass and also per total compartment biomass was found in the leaflets, even though root biomass was much higher than total leaflet biomass. The highest nitrate concentrations were found in the leaf stalks. Correlations between nitrate availability in the soil and NRA in leaves were not significant due to high variability of the actual soil nitrate concentrations. The seasonal variation in foliar NRA, nitrate concentration and total nitrogen concentration is much smaller in F. excelsior than reported for herbaceous species and is mainly caused by changes in the actual soil nitrate availability and by senescence of the leaves.     

Transformation of a nitrate reductase deficient mutant of Penicillium chrysogenum with the corresponding Aspergillus niger and A. nidulans niaD genes

Summary A heterologous gene mediated transformation system based on niaD, the structural gene encoding nitrate reductase, has been developed for Penicillium chrysogenum. Transformation frequencies of up to 20 transformants per microgram DNA were obtained using the Aspergillus nidulans gene and 9 transformants per microgram using the A. niger gene. Vector constructs carrying the A. nidulans ans-1 sequence and the A. niger niaD gene did not show increased transformation frequencies. Southern blot hybridisation analysis demonstrated that vector sequences had integrated into the recipient genome. The control of heterologous niaD gene expression generally agreed with that found in the wild-type strain, that is, induction by nitrate and repression in the presence of ammonium.