Fluctuations in Spinach Leaf Nitrate Reductase During Light-Dark Transitions

In vivo nitrate reductase (NR) activity declined gradually either in absence or presence of Mg²⁺ In dark grown plants of spinach. The increased sensitivity of the extracted NR from the dark grown plants to Mg²⁺ and ATP is indicative of the post-translational modification as one of the mechanisms to control NR activity. The response of extracted NR was gradual and not instantaneous suggesting a complex interplay of NR regulation, as the dark acclimatized plants when exposed to light caused significant nitrate reduction within 15 min of light exposures even in the presence of Mg²⁺ and ATP.     

Soyabean Stem In Vivo Nitrate Reductase Activity

Stem from three- and four-week-old Soyabean [Glycine max (L.)Merr. cv. Tracy] plants reduced from 0.3 to 0.7 µmol nitrateh^–l g^–l f. wt. Leaf activity was 4.7–7.6 µmolnitrate h^–l g^–l f. wt. Outer stem was two to fourtimes more active at reducing nitrate than was inner stem. Plantnitrate nutrition had a strong effect upon the ratio of activitypresent in stem and leaf. More nitrate increased the proportionpresent in leaves. Glycine max L., soyabean, nitrate assimilation, nitrogen metabolism, Rhizobium japonicum     

Blue Light-Induced In Vivo Absorbance Changes and In Vitro Activation of Nitrate Reductase in a Nitrate-Starved Chlorella Mutant

Illuminating a colorless mutant of Chlorella vulgaris 11h (M125)with blue light caused a reversible photoreduction of b-typecytochrome, i.e., absorbance increases at 423, 525 and 557 nm.This light-induced reduction of cytochrome b was most pronouncedin nitrate-starved cells, which showed some blue light responsesin carbon metabolism, including enhancement of respiration byblue light as reported previously. Prolonged illumination withblue light caused a decrease in the rate of the reduction. The photoactivation of nitrate reductase in the mutant cellswas studied in both cell-free crude extract and purified enzyme.The absorption spectrum of purified enzyme showed three peaksat 423, 525 and 557 nm after the addition of a reductant, indicatingthat the spectrum is that of cytochrome b associated with nitratereductase. Nitrate reductase activity was easily enhanced byblue light illumination after 1 min; red light had no effecton it. The blue light activation of nitrate reductase was notsignificant in growing cells, which showed its high activity. The relationship between the blue light-induced reduction ofcytochrome b and carbon metabolism is discussed. (Received September 30, 1987; Accepted February 9, 1988)     

Regulation of Nitrate Reductase Activity by Nitrate during Light-Dark Transition in Detached Oat Leaves

In oat (Avena sativa L. cv. Suregrain) leaf segments, light-darkmodulation of nitrate reductase (NR) activity could be observedonly when segments were kept in –NO₃ conditions. We presenthere evidence that nitrate would regulate NR activity by modulatingthe phosphorylation status of the enzyme. (Received June 19, 1995; Accepted August 14, 1995)     

Decrease of Nitrate Reductase Activity in Spinach Leaves during a Light-Dark Transition

In leaves of spinach plants (Spinacia oleracea L.) performing CO₂ and NO₃⁻ assimilation, at the time of sudden darkening, which eliminates photosystem I-dependent nitrite reduction, only a minor temporary increase of the leaf nitrite content is observed. Because nitrate reduction does not depend on redox equivalents generated by photosystem I activity, a continuation of nitrate reduction after darkening would result in a large accumulation of nitrite in the leaves within a very short time, which is not observed. Measurements of the extractable nitrate reductase activity from spinach leaves assayed under standard conditions showed that in these leaves the nitrate reductase activity decreased during darkening to 15% of the control value with a half-time of only 2 minutes. Apparently, in these leaves nitrate reductase is very rapidly inactivated at sudden darkness avoiding an accumulation of the toxic nitrite in the cells.     

In Vivo Blue-Light Activation of Chlamydomonas reinhardii Nitrate Reductase

Chlamydomonas reinhardii cells, growing photoautotrophically under air, excreted to the culture medium much higher amounts of NO₂⁻ and NH₄⁺ under blue than under red light. Under similar conditions, but with NO₂⁻ as the only nitrogen source, the cells consumed NO₂⁻ and excreted NH₄⁺ at similar rates under blue and red light. In the presence of NO₃⁻ and air with 2% CO₂ (v/v), no excretion of NO₂⁻ and NH₄⁺ occurred and, moreover, if the bubbling air of the cells that were currently excreting NO₂⁻ and NH₄⁺ was enriched with 2% CO₂ (v/v), the previously excreted reduced nitrogen ions were rapidly reassimilated. The levels of total nitrate reductase and active nitrate reductase increased several times in the blue-light-irradiated cells growing on NO₃⁻ under air. When tungstate replaced molybdate in the medium (conditions that do not allow the formation of functional nitrate reductase), blue light activated most of the preformed inactive enzyme of the cells. Furthermore, nitrate reductase extracted from the cells in its inactive form was readily activated in vitro by blue light. It appears that under high irradiance (90 w m⁻²) and low CO₂ tensions, cells growing on NO₃⁻ or NO₂⁻ may not have sufficient carbon skeletons to incorporate all the photogenerated NH₄⁺. Because these cells should have high levels of reducing power, they might use NO₃⁻ or, in its absence, NO₂⁻ as terminal electron acceptors. The excretion of the products of NO₂⁻ and NH₄⁺ to the medium may provide a mechanism to control reductant level in the cells. Blue light is suggested as an important regulatory factor of this photorespiratory consumption of NO₃⁻ and possibly of the whole nitrogen metabolism in green algae.     

In vivo Characterization of Nitrate Reductase Activity in Cotton

The in vivo nitrate reductase activity in leaf tissue of cotton (Gossypium hirsutum L.) was characterized. Enzymatic activity was linear with time up to 60 min. The assay for nitrate reductase activity was optimized in leaf slices 400 μm wide incubated in an anaerobic system at 30°C, in a 0.02 M KNO₃ medium at pH 7.0 with 1 % propanol. In vivo activity was highest in recently matured leaves at the top of the plant. Both light and nitrate enhanced in vivo enzymatic activity. The activity was highest after 9 hours in the light and then decreased steadily for several more hours even in the presence of light. The nitrate reductase activity was more strongly correlated to the levels of NO₃-N in the culture solution than to the NO₃-N level in the tissue. The utility of this technique in nitrate reductase assay in a tissue containing large amounts of phenolic compounds is discussed.     

Regulation of Nitrate Reductase in Neurospora crassa: Stability In Vivo

Nicotinamide adenine dinucleotide phosphate, reduced form (NADPH)-nitrate reductase and its related enzyme activities, NADPH-cytochrome c reductase and reduced benzyl viologen-nitrate reductase, are all induced following the transfer of ammonia-grown wild-type Neurospora mycelia to nitrate medium. After nitrate reductase is induced to the maximal level, the addition of an ammonium salt to, or the removal of nitrate from, the cultures results in a rapid inactivation of nitrate reductase and its two partial component activities. This rapid inactivation is slowed down by the protein synthesis inhibitor, cycloheximide. Experiments on the mixing of extracts in vitro rule out the presence of an inhibitor of nitrate reductase in free form in extracts containing inactivated nitrate reductase. Ammonia does not inhibit the uptake of nitrate by the mycelia. Inactivation of nitrate reductase in vivo by ammonia depends on the concentration of the ammonium salt and is not reversed by increasing the nitrate concentration of the medium. The nitrate-inducible NADPH-cytochrome c reductase activity and reduced benzyl viologen-nitrate reductase activity respectively of the nitrate-nonutilizing mutants nit-1 and nit-3 are not inactivated in vivo by the addition of an ammonium salt or the withdrawal of nitrate. This finding suggests that the integrity of the nitrate reductase complex is required for the in vivo inactivation of nitrate reductase and its associated activities.     

Limitations on Leaf Nitrate Reductase Activity during Flowering and Podfill in Soybean

The objective of this study was to identify factors which limit leaf nitrate reductase (NR) activity as decline occurs during flowering and beginning seed development in soybean (Glycine max [L.] Merr. cv Clark). Level of NR enzyme activity, level of reductant, and availability of NO₃⁻ as substrate were evaluated for field-grown soybean from flowering through leaf senescence. Timing of reproductive development was altered within one genotype by (a) exposure of Clark to an artificially short photoperiod to hasten flowering and podfill, and (b) the use of an early flowering isoline. Nitrogen (N) was soil-applied to selected plots at 500 kilograms per hectare as an additional variable. Stem NO₃⁻ concentration and in vivo leaf NR activity were significantly correlated (R² = 0.69 with nitrate in the assay medium and 0.74 without nitrate in the medium at P = 0.001) across six combinations of reproductive and soil N-treatment. The supply of NO₃⁻ from the root to the leaf tissue was the primary limitation to leaf NR activity during flowering and podfill. Levels of NR enzyme and reductant were not limiting to leaf NR activity during this period.     

硝酸盐对硝酸还原酶活性的诱导及硝酸还原酶基因的克隆

硝酸盐在植物体内的积累过多已成为影响蔬菜品质并影响人类健康的重要因素。硝酸还原酶（NR）是硝酸盐代谢中的关键酶,提高其活性有利于硝酸盐的降解。为了解植物不同组织中NR的活性,用活体测定法检测了经50mmol/L的KNO₃诱导不同时间后的油菜、豌豆和番茄幼苗根茎叶中NR活性,同时为了明确外源诱导剂浓度与植物体内NR活性的关系,检测了经不同浓度KNO₃诱导2h后的矮脚黄、抗热605、小白菜和番茄叶片中的NRA。结果表明,不同植物组织NR活性有很大差异,叶中NR活性较高,根其次,茎最低;不同植物的NR活性随诱导时间呈不同的变化趋势,相同植物不同组织的NR活性变化趋势相似;不同植物叶片NRA为最高时KNO₃浓度不同。用30mmol/L的KNO3诱导番茄苗2h后,从番茄根和叶中提取总RNA,用RT-PCR方法获得NR cDNA,全长2736bp,编码911个氨基酸。为进一步利用该基因提高植物对硝酸盐的降解能力打下基础。     

In Vitro Studies of Nitrate Reductase Activity in Cotton Cotyledons: Effects of Dowex 1-Cl and BSA

Germinating cotton (Gossypium hirsutum L. cv. Deltapine 16) cotyledons developed two peaks of in vitro nitrate reductase activity; the first was stable in vitro and appeared 24 hours after imbibition; and the second, which was extremely labile in vitro, began to develop after the seedlings had emerged and developed chlorophyll. Nitrite reductase activity peaked only after the seedlings had emerged. Dowex 1-Cl (10%, w/v) and bovine serum albumin (3%, w/v) significantly improved the activity of extracted enzyme; greater improvement occurred as expansion of the cotyledons progressed. The major effect of bovine serum albumin on nitrate reductase activity in cotyledon extracts appeared to be that of making the extracted enzyme more active rather than increasing the amount of nitrate reductase extracted or improving the stability of the extracted enzyme.     

Rapid Modulation of Spinach Leaf Nitrate Reductase by Photosynthesis : II. In Vitro Modulation by ATP and AMP

Assimilatory nitrate reductase activity (NRA) in crude spinach leaf (Spinacia oleracea) extracts undergoes rapid changes following fluctuations in photosynthesis brought about by changes in external CO₂ or by water stress (WM Kaiser, E Brendle-Behnisch [1991] Plant Physiol 96:363-367). A modulation of NRA sharing several characteristics (stability, response to Mg²⁺ or Ca²⁺, kinetic constants) with the in vivo modulation was obtained in vitro by preincubating desalted leaf extracts with physiological concentrations of Mg²⁺ and ATP (deactivating) or AMP (activating). When nitrate reductase (NR) was inactivated in vivo by illuminating leaves at the CO₂ compensation point, it could be reactivated in vitro by incubating leaf extracts with AMP. For the in vitro inactivation, ATP could be replaced by GTP or UTP. Nonhydrolyzable ATP analogs (β, γ-imido ATP, β, γ-methyl-ATP) had no effect on NR, whereas γ-S-ATP caused an irreversible inactivation. This suggests that NR modulation involves ATP hydrolysis. In contrast to NR in crude leaf extracts, partially purified NR did not respond to ATP or AMP. ATP and AMP levels in whole leaf extracts changed in the way predicted by the modulation of NRA when leaves were transferred from photosynthesizing (low ATP/AMP) to photorespiratory (high ATP/AMP) conditions. Adenine nucleotide levels in leaves could be effectively manipulated by feeding mannose through the leaf petiole. NRA followed these changes as expected from the in vitro results. This suggests that cytosolic ATP/AMP levels are indeed the central link between NRA in the cytosol and photosynthesis in the chloroplast. Phosphorylation/dephosphorylation of NR or of NR-regulating protein factors is discussed as a mechanism for a reversible modulation of NR by ATP and AMP.     

Cytoglobin Exhibits Anti-Fibrosis Activity on Liver In Vivo and In Vitro

Cytoglobin, generated using genetic engineering method, is a kind of recombinant human stellate cell activation-associated protein. We speculate that it could influence the development of hepatic fibrosis like Sellate cell activation-associated protein which was discovered by Kawada et al. Therefore, we investigated its anti-fibrosis effect on liver both in vivo and in vitro. During our research, we found that cytoglobin showed obvious effect compared with the control group on Thioacetamide-induced liver fibrosis in SD rats, including significantly decrease in aspartate aminotransferase, Hyaluronic acid, laminin and collagen I(Col I) levels in serum and hydroxyproline in livers, which are the important indices reflecting the degree of hepatic fibrosis. Meanwhile, the viability of rat hepatic stellate cell line T6 (HSC-T6) cells was inhibited by cytoglobin and the apoptosis induced by cytoglobin in HSC-T6 cells was detected by Annexin V/PI double staining. Activation of the caspase cascade including caspase-3 for the intrinsic pathways was demonstrated. The results also showed that the expression of Bcl-2 protein decreased whereas that of Bax protein increased, leading to an increase of the Bax/Bcl-2 ratio. Our results demonstrated that cytoglobin exhibited anti-fibrosis activity on livers in vivo and in vitro, involving apoptosis induction.     

In Vitro and In Vivo Activity of Hamycin Against Blastomyces dermatitidis

Clinical responses of patients with blastomycosis to treatment with hamycin have been variable. An explanation for this was sought in a series of studies in which in vitro and in vivo susceptibilities to hamycin of five strains of Blastomyces dermatitidis were compared. Minimal inhibitory concentrations of hamycin for the five strains indicated uniformly high levels of in vitro susceptibility (0.008 to 0.016 μg/ml). In vivo activity was measured in infected mice treated intraperitoneally for a period of 28 days with doses of the drug ranging from 0.001 to 0.030 mg per mouse. Significant differences in response to treatment among the five strains were noted (P < 0.001), and protective doses were found to vary from 0.001 to >0.030 mg per mouse per day. Further observations of infected mice after treatment revealed marked rates of relapsing infection, and several strains caused death. Persistent inapparent infections were also detected on culture of selected organs. Toxicity due to hamycin alone was not observed. These results suggest that variations in clinical responses to hamycin therapy in treatment of blastomycosis reflect differences in pathogenesis and host response in vivo to the infecting organism rather than differences in susceptibility of B. dermatitidis to hamycin.     

Rapid Modulation of Spinach Leaf Nitrate Reductase Activity by Photosynthesis : I. Modulation in Vivo by CO(2) Availability

It has been shown recently that in spinach leaves (Spinacia oleracea) net photosynthesis and nitrate reduction are closely linked: when net photosynthesis was low because of stomatal closure, rates of nitrate reduction decreased (WM Kaiser, J Förster [1989] Plant Physiol 91: 970-974). Here we present evidence that photosynthesis regulates nitrate reduction by modulating nitrate reductase activity (NRA, EC 1.6.6.1). When spinach leaves were exposed to low CO₂ in the light, extractable NRA declined rapidly with a half-time of 15 minutes. The inhibition was rapidly reversed when leaves were brought back to air. NRA was also inhibited when leaves were wilted in air; this inhibition was due to decreased CO₂ supply as a consequence of stomatal closure. The modulation of NRA was stable in vitro. It was not reversed by gel filtration. In contrast, the in vitro inhibition of nitrate reductase (NR) by classical inhibitors such as cyanide, hydroxylamin, or NADH disappeared after removal of free inhibitors by gel filtration. The negative modulation of NRA in —CO₂-treated leaves became manifest as a decrease in total enzyme activity only in the presence of free Mg²⁺ or Ca²⁺. Mg²⁺ concentrations required for observing half-maximal inhibition were about 1 millimolar. In the presence of EDTA, the enzyme activity was always high and rather independent of the activation status of the enzyme. NRA was also independent of the pH in the range from pH 7 to pH 8, at saturating substrate and Mg²⁺ concentrations. The apparent substrate affinities of NR were hardly affected by the in vivo modulation of NR. Only V_max changed.     

Variation in Nitrate Reductase Activity in Lolium

Nitrate reductase activity was studied in the leaves and rootsof Lolium perenne. Growth temperatures of 8, 15, or 20 °Cdid not affect activity, but the same temperatures during assayhad differential effects on the nitroso couple used to measureenzyme activity. Activity increased with increasing light intensity,reaching a high plateau value at around 40 W m^–2. Nitratecontent of leaves, also measured in this experiment, did notvary significantly with different light intensities. Increasingnitrate in the nutrient solution up to 0.5 mM N also increasedactivity. Adding ammonium chloride at similar levels to thenitrate caused no marked repression of activity. Removal ofnitrate from the nutrient solution decreased enzyme activitywithin 24 h. Marked diurnal fluctuations occurred in activity,apparently in response to light intensity, since the nitratelevel in the plant varied little. The enzyme activity of rootswas much less than that of leaves. In the parents and progeny from a half diallel cross, the parentalgenotypes differed significantly in activity, but the numberof families involved was too small for the regression of progenyon parents (b = 1.74) and the correlation coefficient (r = 0.44NS) to achieve significance. In this experiment a significantpositive regression was obtained between nitrate reductase activityand dry matter yield.     

Regulation of Maize Leaf Nitrate Reductase Activity Involves Both Gene Expression and Protein Phosphorylation

Nitrate reductase (NR; EC 1.6.6.1) activity increased at the beginning of the photoperiod in mature green maize (Zea mays L.) leaves as a result of increased enzyme protein level and protein dephosphorylation. In vitro experiments suggested that phosphorylation of maize leaf NR affected sensitivity to Mg2+ inhibition, as shown previously in spinach. When excised leaves were fed 32P-labeled inorganic phosphate, NR was phosphorylated on seryl residues in both the light and dark. Tryptic peptide mapping of NR labeled in vivo indicated three major 32P-phosphopeptide fragments, and labeling of all three was reduced when leaves were illuminated. Maize leaf NR mRNA levels that were low at the end of the dark period peaked within 2 h in the light and decreased thereafter, and NR activity generally remained high. It appears that light signals, rather than an endogenous rhythm, account primarily for diurnal variations in NR mRNA levels. Overall, regulation of NR activity in mature maize leaves in response to light signals appears to involve control of gene expression, enzyme protein synthesis, and reversible protein phosphorylation.     

Triadimenol Increases Nitrate Levels and Nitrate Reductase Activity in Canola Leaves

Nitrate reductase activity in the first true leaves of canola(Brassica napus L.) seedlings grown in one-quarter strengthHoagland's solution from seeds pretreated with triadimenol (0.3or 30 g (a.i.) kg^–1 of seed) was higher than controlsduring the growth period of 15 to 25 d after planting. Triadimenolalso increased chlorophyll levels, the increase being more pronouncedat its lower concentration. The treatment also increased theweight and nitrate content of the leaves. When seedlings weregrown in nutrient solution containing 1 to 20 mM nitrate, theincrease in nitrate reductase activity by triadimenol was higherat lower rather than at higher nitrate concentrations. The nitratelevels and Kjeldahl nitrogen in the triadimenol-treated leaveswas higher than the controls at concentrations of added nitrateabove 2 mM. Addition of nitrate to plants grown in ammonium,increased nitrate reductase activity more in plants grown fromtriadimenol-treated seeds than controls. However, addition of10µM triadimenol for 24 h to ammonium-grown plants hadlittle effect on enzyme activity, both in the absence as wellas the presence of nitrate. This study demonstrates that triadimenolincreases nitrate reductase activity and nitrate accumulationin the leaves and at least part of the increased enzyme activityis independent of nitrate accumulation. Key words: Triazoles, nitrate content, nitrate reductase activity