Influence of Glyphosate on Nitrate Reductase Activity in Soybean (Glycine max)

Experiments were conducted to determine the influence of glyphosate[N-(phosphonomethyl)glycine] on extractable nitrate reductaseactivity during light and dark growth of soybean (Glycine max)seedlings. Glyphosate (5?10^–4 M), applied via root-feedingto three-day-old etiolated seedling, significantly reduced enzymeactivity in roots (48 to 96 h) and leaves (96 h) of seedlingsplaced in the light, but had little effect on enzyme activityin cotyledons compared to enzyme levels in tissues of untreatedseedlings. During dark-growth, nitrate reductase activity increasedwith time in cotyledons of untreated seedlings (activity about85-fold less than in cotyledons of light-grown plants) but muchlower enzyme levels were found in cotyledons of glyphosate-treatedseedlings after 72 and 96 h. In leaves of dark-grown seedlings,glyphosate reduced nitrate reductase levels by 95%. Most inhibitionof extractable enzyme activity occurred in newly developingorgans (leaves and roots) which correlates well with reportsthat glyphosate is rapidly translocated to these sites. However,the fact that glyphosate inhibits growth prior to lowering enzymeactivity levels indicates a secondary effect on nitrate reductase. (Received May 18, 1984; Accepted February 12, 1985)     

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。     

Developmental and Biochemical Regulation of 'Constitutive' Nitrate Reductase Activity in Leaves of Nodulating Soybean

The developmental profile of ‘constitutive’ nitratereductase activity (cNRA) in leaves of soybean (Glycine max(L.) cv. Bragg) plants at different ages is described. The youngestleaves had most cNRA and the activity dropped off as a newerleaf developed above it. Each leaf had its distinct active periodof in vivo cNRA. This pattern was different in urea-grown andsymbiotically-grown plants (inoculated with Bradyrhizobium japonicumstrain USDA 110), where the latter had no detectable in vivocNRA in older leaves. Urea-grown plants maintained considerablein vivo NRA in such older leaves. When symbiotically-grown plantshad their nodules removed, in vivo cNRA reappeared in olderleaves within 1 d of removal, nearly reaching levels of youngleaves at 3 d after nodule excision. Allantoic acid (ALL), oneof the known transport ureides of soybeans, was implicated asa possible signal molecule from nodules to leaves. Allantoicacid (100 µM) inhibited in vitro c₁ NRA significantly,with 400 µM ALL resulting in complete inhibition. In contrast,allantoin (ALN) had no inhibitive effect on NRA. Inhibitionof c₁NRA by ALL was by a competitive process, judging from Lineweaver-Burkeplots against nitrate. Kinetics showed a constant Vmax of around105 nmol NO₂ mg^–1 protein h^–1 and a K_m for nitrateof 15 mM, which increased to 60 mM in the presence of 200 µMallantoic acid. Non-specific (ionic and pH-related) influenceswere eliminated. Allantoic acid also had a slight stimulatingeffect of in vitro NRA (up about 25% at 400 µM). Thesefindings suggest that c1NRA may be involved in ureide metabolism,rather than in vivo nitrate metabolism. Key words: Root-shoot interaction, nitrogen metabolism, nodulation, symbiosis     

Changes in Leaf Nitrate Reductase Activity In Vivo and In Vitro During Light-Dark Transitions

Nitrate reductase activity in the leaves of a number of plants after transfer from light to dark was assayed both by in vivo and in vitro methods. The initial activity persisted during the dark phase for a considerable length of time and declined gradually. After exposure to light again, the NR activity increased rapidly. The possibility of nitrate assimilation in complete darkness is discussed.     

Regulation of Nitrate Reductase Activity in Leaves of Soybean Bragg and Its Nodulated Mutants

The extracts from leaves of nodulated soybean (Glycine max (L.) Merr. ) cv. Bragg and its nodulated mutants i. e. non-nodulated Nod 49, supernodulated nts 382 and nts 246 contained inhibitors of activities iNR, c1NR and c2NR in vitro. Both white light illumination of 300 μE · m-2 · s-1 and inoculation with strain USDAll0 were essential conditions for ac- cumulating these inhibitors in leaves. Comparing inhibiting activities of the extracts from different varieties indicated that Nod 49 extract showed stronger inhibition than Bragg extract did, but nts 382 extract had only weakest inhibitory effect. The inoculated Bragg root extract possessed the same inhibitory activity as its leaf extract. The inoculated nts 382 root extract, like its leaf extract, showed only a little inhibitory activity. However inoculated Nod 49 root extract lead to an inhibition of leaf c2NR activity, which was different from its leaf extract that inhibited three kinds of NR activities. The above results suggested that both leaf and root extracts contained common inhibitory factor which was accumulated after inoculation.     

Nitric Oxide Emissions from Soybean Leaves during in Vivo Nitrate Reductase Assays

Recent work identified acetaldehyde oxime as the predominant product purged by inert gases from anaerobic in vivo nitrate reductase (NR) assays of soybean (Glycine max [L.] Merr.) leaves. Another recent study supported earlier research findings which identified the primary product evolved from soybean leaves as nitric oxide (NO). This paper provides evidence that eliminates acetaldehyde oxime and confirms that NO is the primary nitrogenous product purged from the in vivo NR assay system. A portion of the evidence is based on the high water solubility of acetaldehyde oxime. Other evidence presented is the failure by chemical and spectrophotometric means to detect oximes in gases emitted in the purging of the reaction medium or in the leaf tissues. The gaseous product from the in vivo NR assay system reacted identically to NO standards and did not resemble acetaldehyde oxime standards. It was concluded that the predominant N product within the leaves was nitrite and that the predominant gaseous N product evolved from the assay was NO.     

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)     

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.     

施氮和去除子叶对大叶桃花心木幼苗叶片硝酸还原酶活性的影响

研究了热带落叶乔木大叶桃花心木(Swietenia macrophylla)在施氮和去除子叶后幼苗叶片的硝酸还原酶活性(NRA)变化。结果表明,在非施氮(对照)条件下,NRA随着幼苗叶片的发育先升高后降低;施氮后幼苗叶片NRA在各取样时期(除35 d外)均显著高于非施氮处理(P<0.05),并随着取样时期的延续,叶片NRA逐渐降低。在幼苗发育的不同时期去除子叶,4周后,叶片NRA均显著升高(P<0.05)。     

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     

Primary Analysis of Components in Different Soybean Nodulating Mutants and their Effects on Nitrate Reductase Activity and Nodulation

The water extracts of leaves and roots from supernodulating soybean (Glycine max (L.) Merr. ) nts 382 and nonnodulating soybean Nod 49 have been chromatographed using filtering method through the column (25 cm × 2 cm) Sephadex G25 and 4 fractions, namly, nts 382 (Nod 49) F1, nts 382 (Nod 49) F2, nts 382 (Nod 49) F3, and nts 382 (Nod 49) F4 could be distinguished according to nitrate reductase (NR) activities inhibited by the eluate. The inhibition of NR activity by the noninoculated nts 382 F2 and the nts 382 F4 in vitro were much stronger than that by the inoculated nts 382 F2 and nts 382 F4. On the contrary, the obvious inhibition of NR activity in vitro by the noninoculated Nod 49 F2 and Nod 49 F4 were substantialy strengthed again by the innoculated Nod 49 F2 and Nod 49 F4. The facts indicated that the quantity of NR inhibitors in the leaf cells of soybean nts 382 reduced after the inoculation but was that in the inoculated Nod 49 leaf cells further more accumulated. Both nodulations assays, the nodulation of soybean "Bragg " injected with inoculated nts 382 Fl, nts 382 F2, nts 382 F3 and nts 382 F4 from leaves and roots and the nodulation of soybean nts 382 injected with inoculated Nod 49 F2, Nod 49 F3 and Nod 49 F4 from leaves only showed that nts 382 Fl and nts 382 F2 increased nodules of soybean "Bragg" by 1 to 3 times but nts 382 F3 and nts 382 F4 did not. Inhibition of soybeannts 382 nodulation by inoculated Nod 49 F2 Nod 49 F3 and Nod 49 F4 expressed that the Nod 49 F4 only inhibited the nodulation strongly by one time in the experiments with nts 382 plants with leaves, and by 15 times in the experiments with nts 382 plants without leaves at 10 d of inoculation and injection and this inhibition was nonreversible even after stopping injection from the 11th day to the 15th day after inoculation.     

硝酸盐对球形棕囊藻生长和硝酸还原酶活性的影响

以我国南海海域分离的赤潮原因种——球形棕囊藻(Phaeocystisglobosa)为材料,研究了不同硝酸盐浓度下藻细胞生长及硝酸还原酶活性的变化。当培养基中不含硝酸盐时,藻细胞内硝酸还原酶的活性保持在非常低的水平,藻细胞的生长受到限制,不能形成正常的生长曲线:当培养基中硝酸盐浓度为3.62μmol.L-1时,藻细胞的硝酸还原酶活性和比生长速率达到最大。在含有硝酸盐的培养基中,接种培养后第9天藻细胞硝酸还原酶活性达到最大值,并且在4种不同硝酸盐浓度下,藻细胞硝酸还原酶活性的差异性达到极显著水平(P<0.01)。在接种培养第16天藻细胞密度达到最大值,并且4种不同硝酸盐浓度培养的藻细胞密度之间的差异性也达到极显著水平(P<0.01)。实验结果表明,在培养基中添加不同浓度的硝酸盐,对球形棕囊藻细胞硝酸还原酶的活性和藻细胞的生长有极显著的影响,含有较高硝酸盐的富营养化海域有利于球形棕囊藻细胞的持续生长。     

硝酸盐对球形棕囊藻生长和硝酸还原酶活性的影响

以我国南海海域分离的赤潮原因种——球形棕囊藻(Phaeocystis globosa)为材料, 研究了不同硝酸盐浓度下藻细胞生长及硝酸还原酶活性的变化。当培养基中不含硝酸盐时, 藻细胞内硝酸还原酶的活性保持在非常低的水平, 藻细胞的生长受到限制, 不能形成正常的生长曲线: 当培养基中硝酸盐浓度为3.62 mmol.L-1时, 藻细胞的硝酸还原酶活性和比生长速率达到最大。在含有硝酸盐的培养基中, 接种培养后第9天藻细胞硝酸还原酶活性达到最大值, 并且在4种不同硝酸盐浓度下, 藻细胞硝酸还原酶活性的差异性达到极显著水平(P<0.01)。在接种培养第16天藻细胞密度达到最大值, 并且4种不同硝酸盐浓度培养的藻细胞密度之间的差异性也达到极显著水平(P<0.01)。实验结果表明, 在培养基中添加不同浓度的硝酸盐, 对球形棕囊藻细胞硝酸还原酶的活性和藻细胞的生长有极显著的影响, 含有较高硝酸盐的富营养化海域有利于球形棕囊藻细胞的持续生长。     

Seedling Nitrate Reductase Activity and Nitrate Partitioning in Maize (Zea mays L.) Strains Divergently Selected For Post-anthesis Leaf-Lamina Nitrate Reductase Activity

Two experiments were conducted to evaluate the effects of phenotypicrecurrent selection for high and low post-anthesis leaf-laminain vivo NRA on nitrate uptake, nitrate partitioning and in vitroNRA of seedling roots and leaves. In Experiment 1, intact plantsof cycle 0, 4, and 6 of the high and low NRA strains were grownon NH₄-N for 11 d, then exposed to 1.0 mol m^–3 KNO₃, andcultures sampled at 6 h and 28 h (induction and post-inductionperiods). Nitrate uptake, tissue nitrate concentration and invitro NRA were determined. The pattern of response to selectionin seedling leaf NRA was similar to that observed for in vivoNRA of field grown plants. Leaf NRA increased between 6 h and28 h. Root NRA was not affected by selection or sampling time.Treatments differed in total fresh weight but not in reductionor uptake of nitrate per unit weight, indicating a lack of correspondencebetween NRA and reduction and supporting the idea that concomitantreduction by NR is not obligatorily linked to nitrate influxin the intact plant. In Experiment 2, dark-grown plants of cycle 0, and 6 of thehigh and low NRA strains were cultured without N, detopped onday 6, transferred the following day to 0-75 mol m^–3 KNO₃and sampled at 6 h and 28 h. In contrast to Experiment 1, selectionpopulations differed in nitrate reduction and root NRA, whichby 28 h reached higher average levels than root NRA of intactplants. Translocation and reduction were inversely related amongstrains within each sampling time. The high level of translocationin detopped plants of the low NRA strain was difficult to reconcilewith its low leaf NRA level of Experiment 1. It is suggestedthat nitrate transport in detopped roots is altered relativeto the intact system in a way which permits greater NRA inductionand nitrate reduction. The results indicate that nitrate partitioningby detopped root systems should be interpreted with caution. Key words: Zea, nitrate reductase activity, nitrate uptake, nitrate reduction, nitrate partitioning, selection     

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.     

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.     

Time-course of Nitrate Uptake and Nitrate Reductase Activity in Nitrogen-depleted Dwarf Bean

The rate of nitrate uptake by N-depleted French dwarf bean (Phaseolus vulgaris L. cv. Witte Krombek) increased steadily during the first 6 h after addition of NO₃ -After this initial phase the rale remained constant for many hours. Detached root systems showed the same time-course of uptake as roots of intact plants. In vivo nitrate reductase activity (NRA) was assayed with or without exogenous NO₃^- in the incubation medium and the result ing activities were denoted potential and actual level, respectively. In roots the difference between actual and potential NRA disappeared within 15 min after addition of nitrate, and NRA increased for about 15 h. Both potential and actual NRA were initially very low. In leaves, however, potential NRA was initially very high and was not affected by ambient nitrate (0.1–5 mol m^-3) for about 10 h. Actual and potential leaf NRA became equal after the same period of time. In the course of nitrate nutrition, the two nitrate reductase activities in leaves were differentially inhibited by cycloheximide (3.6 mmol m^-3) and tungstate (1 mol m^-3). We suggest that initial potential NRA reflects the activity of pre-existing enzyme, whereas actual NRA depends on enzyme assembly during NO₃^- supply. Apparent induction of nitrate uptake and most (85%) of the actual in vivo NRA occurred in the root system during the first 6 h of nitrate utilization by dwarf bean.