植物中硝酸还原酶和亚硝酸还原酶的作用

植物通过硝酸盐同化途径以硝酸盐和氨的形式吸收氮元素。硝酸盐的同化是一个受到严格控制的过程,其中两个先后参加反应的酶——硝酸还原酶(NR)和亚硝酸还原酶(NiR)对初级氮的同化起主要调控。在高等植物中,NR和NiR基因的转录及转录后加工受到各种内在和外在因素的影响,翻译后调控是消除亚硝酸盐积累的重要机制。随着分子生物学技术的发展,可以更容易地通过突变体和转基因方式来研究NR和NiR基因的调控。     

Nitrate Reductase Regulates Expression of Nitrite Uptake and Nitrite Reductase Activities in Chlamydomonas reinhardtii

In Chlamydomonas reinhardtii mutants defective at the structural locus for nitrate reductase (nit-1) or at loci for biosynthesis of the molybdopterin cofactor (nit-3, nit-4, or nit-5 and nit-6), both nitrite uptake and nitrite reductase activities were repressed in ammonium-grown cells and expressed at high amounts in nitrogen-free media or in media containing nitrate or nitrite. In contrast, wild-type cells required nitrate induction for expression of high levels of both activities. In mutants defective at the regulatory locus for nitrate reductase (nit-2), very low levels of nitrite uptake and nitrite reductase activities were expressed even in the presence of nitrate or nitrite. Both restoration of nitrate reductase activity in mutants defective at nit-1, nit-3, and nit-4 by isolating diploid strains among them and transformation of a structural mutant upon integration of the wild-type nit-1 gene gave rise to the wild-type expression pattern for nitrite uptake and nitrite reductase activities. Conversely, inactivation of nitrate reductase by tungstate treatment in nitrate, nitrite, or nitrogen-free media made wild-type cells respond like nitrate reductase-deficient mutants with respect to the expression of nitrite uptake and nitrite reductase activities. Our results indicate that nit-2 is a regulatory locus for both the nitrite uptake system and nitrite reductase, and that the nitrate reductase enzyme plays an important role in the regulation of the expression of both enzyme activities.     

Variation in Nitrate Reductase, Nitrite, and Nitrite Reductase in Some Grasses and Cereals

Nitrite accumulation may result from unbalance between nitratereductase which produces nitrite and nitrite reductase whichremoves it. In the first experiment, using three light levelsand three nitrate levels, on Lolium, maize, and oats, both enzymesresponded to increased light, though not always significantly.The effect of nitrate was more variable. Nitrate reductase activityincreased to the intermediate or highest level of nitrate, butthere was no clear response in nitrite reductase activity orin nitrite concentration. In the second experiment, using fournitrate levels but only one, high, light intensity on Loliumand barley, the results were clearer. With increasing nitratesupply, nitrate reductase activity increased more than nitritereductase activity. This was particularly marked in Lolium,in which nitrite accumulated at the highest nitrate supply.Thus high nitrate supply unbalances the two enzymes in the directionleading to nitrite accumulation.     

Comparative Induction of Nitrate Reductase by Nitrate and Nitrite in Barley Leaves

The comparative induction of nitrate reductase (NR) by ambient NO₃⁻ and NO₂⁻ as a function of influx, reduction (as NR was induced) and accumulation in detached leaves of 8-day-old barley (Hordeum valgare L.) seedlings was determined. The dynamic interaction of NO₃⁻ influx, reduction and accumulation on NR induction was shown. The activity of NR, as it was induced, influenced its further induction by affecting the internal concentration of NO₃⁻. As the ambient concentration of NO₃⁻ increased, the relative influences imposed by influx and reduction on NO₃⁻ accumulation changed with influx becoming a more predominant regulant. Significant levels of NO₃⁻ accumulated in NO₂⁻-fed leaves. When the leaves were supplied cycloheximide or tungstate along with NO₂⁻, about 60% more NO₃⁻ accumulated in the leaves than in the absence of the inhibitors. In NO₃⁻-supplied leaves NR induction was observed at an ambient concentration of as low as 0.02 mm. No NR induction occurred in leaves supplied with NO₂⁻ until the ambient NO₂⁻ concentration was 0.5 mm. In fact, NR induction from NO₂⁻ solutions was not seen until NO₃⁻ was detected in the leaves. The amount of NO₃⁻ accumulating in NO₂⁻-fed leaves induced similar levels of NR as did equivalent amounts of NO₃⁻ accumulating from NO₃⁻-fed leaves. In all cases the internal concentration of NO₃⁻, but not NO₂⁻, was highly correlated with the amount of NR induced. The evidence indicated that NO₃⁻ was a more likely inducer of NR than was NO₂⁻.     

Variation in Nitrate Accumulation, Nitrate Reductase Activity and Nitrite Reductase Activity along Primary and Nodal Roots of Corn (Zea mays L.) Seedlings

Significant differences in NO₃ accumulation and nitrate reductaseactivity (NRA) were noted in the successive segments of developingyoung primary and nodal roots. This variation was also foundto be a function of root age. Nitrite reductase activity (NiRA)on the other hand had little variation among various segmentsof primary and nodal roots and also as a function of root age.These data suggest root NO₃ accumulation and root NRA are twoprocesses which are not directly linked. ¹ Present address: Division of Plant Physiology, Indian AgriculturalResearch Institute, New Delhi-110012, India. (Received December 3, 1983; Accepted June 18, 1983)     

Role of Nitrate and Nitrite in the Induction of Nitrite Reductase in Leaves of Barley Seedlings

The role of NO₃⁻ and NO₂⁻ in the induction of nitrite reductase (NiR) activity in detached leaves of 8-day-old barley (Hordeum vulgare L.) seedlings was investigated. Barley leaves contained 6 to 8 micromoles NO₂⁻/gram fresh weight × hour of endogenous NiR activity when grown in N-free solutions. Supply of both NO₂⁻ and NO₃⁻ induced the enzyme activity above the endogenous levels (5 and 10 times, respectively at 10 millimolar NO₂⁻ and NO₃⁻ over a 24 hour period). In NO₃⁻-supplied leaves, NiR induction occurred at an ambient NO₃⁻ concentration of as low as 0.05 millimolar; however, no NiR induction was found in leaves supplied with NO₂⁻ until the ambient NO₂⁻ concentration was 0.5 millimolar. Nitrate accumulated in NO₂⁻-fed leaves. The amount of NO₃⁻ accumulating in NO₂⁻-fed leaves induced similar levels of NiR as did equivalent amounts of NO₃⁻ accumulating in NO₃⁻-fed leaves. Induction of NiR in NO₂⁻-fed leaves was not seen until NO₃⁻ was detectable (30 nanomoles/gram fresh weight) in the leaves. The internal concentrations of NO₃⁻, irrespective of N source, were highly correlated with the levels of NiR induced. When the reduction of NO₃⁻ to NO₂⁻ was inhibited by WO₄²⁻, the induction of NiR was inhibited only partially. The results indicate that in barley leaves NiR is induced by NO₃⁻ directly, i.e. without being reduced to NO₂⁻, and that absorbed NO₂⁻ induces the enzyme activity indirectly after being oxidized to NO₃⁻ within the leaf.     

Nitrate Reductase mRNA Regulation in Nicotiana plumbaginifolia Nitrate Reductase-Deficient Mutants

Light and substrate regulation of nitrate reductase (NR) expression were compared in wild type and mutant lines of Nicotiana plumbaginifolia. Mutants affected in the NR structural gene (nia) or in the biosynthesis of the NR molybdenum cofactor (cnx) were examined. nia mutants expressing a defective apoenzyme, as well as cnx mutants, overexpressed NR mRNA, whereas nia mutants devoid of detectable NR protein had reduced or undetectable NR mRNA levels. Diurnal fluctuations of NR mRNA were specifically abolished in nia and cnx mutants, suggesting that the integrity of NR catalytic activity is required for the expression of diurnal oscillations. Unlike some fungal mutants, the nia and cnx mutants examined retained nitrate inducibility of NR expression. The possibility of autogenous control of NR expression in higher plants is discussed.     

Accumulation of Demolybdo Nitrate Reductase during Induction and Its Separation from Active Nitrate Reductase in Chlorella

During induction of nitrate reductase in Chlorella vulgaris,synthesis of the precursor, demolybdo cytochrome c reductase,exceeds the synthesis of active enzyme. Evidence is also presentedwhich shows that the purification procedure of Funkhouser etal. [(1980) Plant Physiol. 65: 939] separates demolybdo cytochromec reductase from active nitrate reductase. ¹Supported in part by a grant to B. V. from the Deutsche Forschungsgemeinschaftand a contribution of the Texas Agricultural Experiment Station. (Received July 27, 1983; Accepted September 13, 1983)     

Effect of Chlorate Treatment on Nitrate Reductase and Nitrite Reductase Gene Expression in Arabidopsis thaliana

The herbicide chlorate has been used extensively to isolate mutants that are defective in nitrate reduction. Chlorate is a substrate for the enzyme nitrate reductase (NR), which reduces chlorate to the toxic chlorite. Because NR is a substrate (NO₃⁻)-inducible enzyme, we investigated the possibility that chlorate may also act as an inducer. Irrigation of ammonia-grown Arabidopsis plants with chlorate leads to an increase in NR mRNA in the leaves. No such increase was observed for nitrite reductase mRNA following chlorate treatment; thus, the effect seems to be specific to NR. The increase in NR mRNA did not depend on the presence of wild-type levels of NR activity or molybdenum-cofactor, as a molybdenum-cofactor mutant with low levels of NR activity displayed the same increase in NR mRNA following chlorate treatment. Even though NR mRNA levels were found to increase after chlorate treatment, no increase in NR protein was detected and the level of NR activity dropped. The lack of increase in NR protein was not due to inactivation of the cells' translational machinery, as pulse labeling experiments demonstrated that total protein synthesis was unaffected by the chlorate treatment during the time course of the experiment. Chlorate-treated plants still retain the capacity to make functional NR because NR activity could be restored by irrigating the chlorate-treated plants with nitrate. The low levels of NR protein and activity may be due to inactivation of NR by chlorite, leading to rapid degradation of the enzyme. Thus, chlorate treatment stimulates NR gene expression in Arabidopsis that is manifested only at the mRNA level and not at the protein or activity level.     

Nitrate Reductase and Nitrite Reductase Activity in Dark-Grown Radish Seedlings: Relation to the Supply of NADPH

Functioning of nitrate reductase and nitrite reductase was measured in intact cotyledons from radish seedlings (Raphanus sativus L.) grown in the dark in a nitrate medium. Reduction of nitrate to nitrate did proceed during the whole period of 45 h, whereas the reduction of nitrite in the intact cotyledons dropped abruptly between 20 and 23 h after exposing the roots to nitrate. The activity of the enzymes glucose-6-P dehydrogenase (G6PDH) and 6-P-gluconate dehydrogenase (6PGDH), measured in cotyledon extracts, showed a sharp decline simultaneously with the drop in nitrite reductase activity of the intact cotyledons. It was concluded that the amount of NADPH generated by the enzymes G6PDH and 6PGDH is not sufficient to allow continuous functioning of nitrite reductase after 20 h in cotyledons of seedlings grown in the dark. Therefore, the results from our experiments point to the functioning of nitrite reductase as the rate limiting step in the reduction pathway of nitrate in the dark.     

Variant Cell Lines of Haplopappus gracilis with Disturbed Activities of Nitrate Reductase and Nitrite Reductase

Selected variant cell lines of Haplopappus gracilis (Nutt) Gray that showed disturbed growth after transfer from an alanine medium to NO₃⁻ medium were characterized. The in vivo NO₃⁻ reductase activity (NRA) was lower in these lines than in the wild type. In vitro NRA assays suggest that decreased in vivo NRA was not caused by a lower amount of active enzyme. Cells of the variant lines revealed up to 75% lower extractable activity of NO₂⁻ reductase as compared with the wild type. This coincided with higher accumulation of NO₂⁻ by the variant than by the wild type cells after transfer from alanine medium to NO₃⁻ medium. NO₂⁻ accumulation was transient or continuous, depending on cell line, metabolic state of the cells, and light conditions.     

A Re-evaluation of the Nitrate Reductase Content of the Maize Root

The standard procedure for the in ritro extraction of nitrate reductase from the tip region (0-2 cm) of the primary root of the maize (Zea mays L.) seedling indicated an activity of the enzyme approximately 5-fold higher than that obtained with an in vivo assay. In more mature regions of the primary root the ratio of in vitro to in vivo activity was much lower and in older seedlings was less than unity. The mature root extracts had a more labile nitrate reductase and a higher level of an inactivating enzyme. The use of phenylmethylsulphonyl fluoride in the extraction medium gave only a partial protection of the nitrate reductase from the old root samples. Casein (3%) resulted in a greatly increased yield of nitrate reductase (36-fold with one sample) and a more constant in vitro-in vivo activity ratio for all root samples. With casein in the extraction medium, much higher levels of nitrate reductase were recovered from the mature root zone, and the root content of this enzyme was now shown to be quite a significant proportion of the total in the maize seedling. Casein was shown to inhibit the action of the inactivating enzyme on nitrate reductase. Evidence is also presented for a nitrate reductase inactivating enzyme in the maize scutella and leaf tissues and in the roots and shoots of pea seedlings.     

Studies on Nitrate Reductase in Plasma Membrane of Maize Roots

Nitrate reductase (NR) activity was identified in the right-side-out and inside-out of high purity plasma membrane (PM) vesicles in maize (Zea mays L. ) roots which was obtained by aqueous two-phase partitioning. The inducement property of the NR activity in PM could be confirmed through culturing the meterial with or without nitrate component. Analysis from experimentation with external electron donor indicated that the maize root NR in PM could utilize not only NADH but also NADPH directly or indirectly as its electron donor. Treatment with Triton X-100 combining with trypsin and inhibitor demonstrated that NR protein was a trans-PM protein mainly facing the apoplastic side, being specially sensitive to trypsin. The possible function of the NR in PM is also discussed.     

Influence of Abscisic Acid on Nitrate Accumulation and Nitrate Reductase Activity in Potato Tuber Slices

Abscisic acid (ABA) at concentrations of 1 to 10 µg.ml^–1suppressed development of nitrate reductase activity in freshtuber slices of Solanum tuberosum L. incubated in KNO₃. Suppressionof activity was evident after 3 hr and continued for 20 hr beforerecovery. This recovery may be due to inactivation of the hormone.Nitrate accumulation was enhanced by ABA. At exogenous NO₃ levelsof 0.1 to 5 mM, the hormone enhanced both NO₃ accumulation andnitrate reductase activity. When applied 24 hr after incubation in NO₃, ABA promoted a markeddecline in enzyme activity in the absence of exogenous NO₃,but was less effective in the presence of NO₃. Slices incubatedin NO₃ and ABA also exhibited increased loss of enzyme activityupon removal of NO₃. Preincubating slices in the hormone for24 hr in a NO₃- free medium resulted in stimulation of nitratereductase activity. Addition of NO₃ resulted in a marked stimulationof enzyme activity over a period of 8–10 hr. The ABA response is not related to tissue levels of free aminoacids and is not affected by different NO₃ sources. These resultssuggest the ABA effect on nitrate reductase activity is influencedby NO₃ status of the cells. Where external NO₃ levels are lowit stimulated NRA while it inhibited activity where NO₃ contentis high. (Received May 12, 1981; Accepted October 12, 1981)     

硝酸还原酶抑制剂钨酸钠对油菜硝态氮积累的影响

采用溶液培养方法,选取硝酸盐积累差异明显的两个油菜品种（低硝态氮积累品种‘红油3号’和高硝态氮积累品种‘中双6号’,研究苗期根系硝酸还原酶（NR）活性被抑制以后两个油菜品种叶片、叶柄和根系中NR活性和硝态氮含量的变化。结果表明：1.0mmol.L-1的NR活性抑制剂Na2WO4对两个油菜品种的根系NR活性抑制效果最佳;根系NR活性被抑制以后,两个油菜品种的根系NR活性、硝态氮吸收速率均显著下降,而硝态氮含量却显著上升;且Na2WO4对‘中双6号’硝态氮吸收的抑制程度强于其对‘红油3号’的抑制。叶片和叶柄的NR活性变化不显著,但叶柄硝态氮含量显著下降,叶片硝态氮含量稳定,且这一趋势在低积累品种‘红油3号’中表现得更为明显。     

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     

Frequencies,Timing, and Spatial Patterns of Co-Suppression of Nitrate Reductase and Nitrite Reductase in Transgenic Tobacco Plants

Frequencies, timing, and spatial patterns of co-suppression of the nitrate (Nia) and nitrite (Nii) genes were analyzed in transgenic tobacco (Nicotiana tabacum) plants carrying either Nia or Nii cDNAs under the control of the 35S promoter, or a Nii gene with its own regulatory signals (promoter, introns, and terminator) cloned downstream of two copies of the enhancer of the 35S promoter. We show that (a) the frequencies of transgenic lines affected by co- suppression are similar for the three constructs, ranging from 19 to 25%; (b) Nia and Nii co-suppression are triggered stochastically during a phenocritical period of 2 weeks between germination and flowering; (c) the timing of co-suppression (i.e. the percentage of isogenic plants affected by co-suppression reported as a function of the number of days of culture) differs from one transgenic line to another; (d) the percentage of isogenic plants affected by co-suppression is increased by growing the plants in vitro prior to their transfer to the greenhouse and to the field; and (e) at the end of the culture period, plants are either unaffected, completely co-suppressed, or variegated. Suppressed and nonsuppressed parts of these variegated plants are separated by a vertical plane through the stem in Nia co-suppression, and separated by a horizontal plane in Nii co-suppression.     

Nitrate Reductase Activity and Nitrite in Native Pyrenoids Purified from the Green Alga Bryopsis maxima

The native, starchless pyrenoids purified from Bryopsis maximashowed NADH-nitrate reductase [NR, EC 1.6.6.1 [EC] ] activity andcontained nitrite. The specific activity of NR was 0.024 µmolNO₂ formed per min per mg of protein. The value was 80 timesgreater than that in the crude extract of chloroplasts. Theamount of nitrite in the pyrenoids was 2.37 µmol per mgof protein, showing that nitrite was concentrated by a factorof 66 times. These results suggest a physiological role forpyrenoids in the assimilation of nitrate. (Received November 15, 1989; Accepted February 27, 1990)