Age-dependent conversion of nitrate reductase to cytochrome c reductase species in barley leaf extracts

The stability of nitrate reductase (NR) in extracts from 4-, 5- and 6-day-old primary leaves of barley was examined. The half-time of loss of NR activity was found to be 358, 107 and 70 min, respectively. Bovine serum albumin (BSA) and phenylmethylsulphonylfluoride (PMSF) stabilized NR in extracts from 5- and 6-day-old primary leaves, but BSA was much more effective. The increased instability of NR with age correlated with increased conversion of the MW 203 000 NR complex to smaller NADH cytochrome c reductase (CR) species of MW 163 000, 61 000 and 40 000. The MW 163 000 CR species also possessed NR activity. BSA prevented and PMSF retarded the conversion of NR to the smaller CR species. The increased instability of NR in extracts from older tissue may be due to increased conversion of NR to smaller CR species. The ability of PMSF and BSA to stabilize NR and inhibit conversion of NR to the smaller CR species indicates that these phenomena are probably due to proteolytic degradation of NR. This suggestion is supported by the observation that trypsin cleaved NR to 3–4 S CR species and that cleavage was retarded by the presence of BSA. Endogenous proteinase attack at specific sites between domains of the barley NR complex may generate the CR species seen in barley extracts. The MW 40 000 CR species probably carries at least the FAD domain.     

Activation and stabilization of nitrate reductase by NADH in wheat and maize

Preincubation of nitrate reductase (NR) extracted from wheat shoot tips with NADH in vitro, activated and stabilized activity at both O° and 25°. However, preincubation with potassium ferricyanide inactivated the NR in vitro. NADH also stabilized the NR activity in extracts from maize shoot tips. It was observed that NR from both wheat and maize was active at low temperatures.     

Properties of nitrate reductase from seedling leaves of selected barley genotypes

Crude extracts from leaves of 6-day barley seedlings of parental genotypes (cv. Aramir and primitive line R567) and selected doubled haploid (DH) lines were not found to have significant differences in the NADH:NR activity, while considerable differences between these genotypes were shown by the NAD(P)H:NR activity. The cv. Aramir and DH lines did not differ by nitrate accumulation in the leaves. However, the primitive line R567, as compared to the remaining genotypes, was characterized by an appreciably lower ability to accumulate nitrates. In partially purified leaf extracts, significant differences in total NADH:NR activity and in distal activity dependent on methyl viologen (MV:NR) were found between the parental genotypes and selected DH lines. The studied genotypes differed also in dehydrogenase NR activity, i.e. cytochrome c reductase activity in crude extracts. In the studied genotypes, the NADH:NR activity in partially purified leaf extracts did not substantially differ by Km values for nitrates. Calculated Vmax values for NADH:NR in these genotypes were similar to total NR activity in partially purified extracts. Significant differences between the parental genotypes and selected DH lines were found in the thermal NADH:NR stability in crude and partially purified leaf extracts. From the performed studies it follows that different NR stability was one of the reasons of revealed differences in total activity and in partial NR activities in the leaf extracts between the studied genotypes of spring barley. Besides, it is suggested that varied NR gene expression in the leaves of these barley genotypes could also influence NR activity.     

Substrates regulate the phosphorylation status of nitrate reductase

The effect of substrates on the phosphorylation status of nitrate reductase (NR; EC 1.6.6.1) was studied. The enzyme was obtained from the first leaf of 7-day-old oat (Avena sativa L. cv. Suregrain) plants, grown in the light. When desalted crude extracts were incubated with ATP, NR was strongly phosphorylated, as evidenced by the inhibition of the enzyme's activity in the presence of Mg²⁺. NR sensitivity to Mg²⁺ remained unchanged when 10 mM nitrate was added to crude extracts after ATP. Addition of nitrate before or simultaneously with ATP slightly decreased Mg²⁺ inhibition of NR, which was strongly diminished in the presence of 10 mM NO₃^?+ 100 µM NADH. Incubation with NADH alone did not affect the enzyme's susceptibility to Mg²⁺ inhibition. When ammonium sulfate was added to crude extracts, NR was recovered in a 0-40% saturation fraction (F1). After incubation of F1 with ATP, the sensitivity of the enzyme to Mg²⁺ inhibition remained low, but it strongly increased after mixing F1 with a 45-60% saturation fraction (F2) suggesting that also in oats an additional factor (inactivating protein, IP), which probably binds to phospho-NR, would be required to keep the phosphorylated enzyme inactive in a +Mg²⁺ medium. Addition of 10 mM NO₃^?+ 100 µM NADH together with desalted F2 did not prevent Mg²⁺ inhibition suggesting that NO₃^? did not interfere with IP binding to phospho-NR. Again, incubation of F1 with both substrates during in vitro phosphorylation kept the enzyme active after adding F2, even in the presence of Mg²⁺, After in vitro phosphorylation, NR in crude extract was hardly reactivated when incubated alone or in the presence of 10 mM NO₃^? at 30°C. On the other hand, a strong and very rapid reactivation was found when the extract was incubated with both nitrate and NADH. Microcystine, an inhibitor of types 1 and 2A phosphoprotein phosphatases, inhibited the reactivation of phospho-NR induced by the substrates. The results presented here show that the substrates could prevent NR phosphorylation and induce the enzyme's dephosphorylation, but they were effective only after their binding to the NR protein. Thereby, they seemed to affect the NR protein itself and not the phosphatase- or the kinase-proteins. It has been reported that nitrate binding to the enzyme's active site induces conformational changes in the NR protein. We propose that this conformational change would prevent NR phosphorylation, by converting the enzyme into a form in which the site recognized by the protein kinase is no longer accessible, and, simultaneously, stimulate NR dephophorylation by allowing the specific phosphatases to recognize NR.     

Post-translational control of nitrate reductase activity responding to light and photosynthesis evolved already in the early vascular plants

Regulation of nitrate reductase (NR) by reversible phosphorylation at a conserved motif is well established in higher plants, and enables regulation of NR in response to rapid fluctuations in light intensity. This regulation is not conserved in algae NR, and we wished to test the evolutionary origin of the regulatory mechanism by physiological examination of ancient land plants. Especially a member of the lycophytes is of interest since their NR is candidate for regulation by reversible phosphorylation based on sequence analysis. We compared Selaginella kraussiana, a member of the lycophytes and earliest vascular plants, with the angiosperm Arabidopsis thaliana, and also tested the moss Physcomitrella patens. Interestingly, optimization of assay conditions revealed that S. kraussiana NR used NADH as an electron donor like A. thaliana, whereas P. patens NR activity depended on NADPH. Examination of light/darkness effects showed that S. kraussiana NR was rapidly regulated similar to A. thaliana NR when a differential (Mg²⁺ contra EDTA) assay was used to reveal activity state of NR. This implies that already existing NR enzyme was post-translationally activated by light in both species. Light had a positive effect also on de novo synthesis of NR in S. kraussiana, which could be shown after the plants had been exposed to a prolonged dark period (7 days). Daily variations in NR activity were mainly caused by post-translational modifications. As for angiosperms, the post-translational light activation of NR in S. kraussiana was inhibited by 3-(3,4-dichlorophenyl)-1*1-dimethylurea (DCMU), an inhibitor of photosynthesis and stomata opening. Evolutionary, a post-translational control mechanism for NR have occurred before or in parallel with development of vascular tissue in land plants, and appears to be part of a complex mechanisms for coordination of CO₂ and nitrogen metabolism in these plants.     

Modifications of the activity of nitrate reductase from cucumber roots

The regulatory properties of NADH-dependent nitrate reductase (NR) in desalted root extracts from hydroponically grown cucumber (Cucumis sativus L.) seedlings were examined. The lowest activity of NR was detected in extracts incubated with Mg²⁺ and ATP. An inhibitory effect of Mg-ATP was cancelled in the presence of staurosporine (the protein kinase inhibitor) and completely reversed after addition of ethylenediaminetetraacetate (EDTA) as well as AMP into reaction mixture. Reactivation of enzyme due to AMP presence, contrary to the chelator-dependent NR activation, was sensitive to microcystin LR (the protein phosphatase inhibitor). Above results indicated that the nitrate reductase in cucumber roots was regulated through reversible phosphorylation of enzyme protein. A drop in the activity of NR was also observed after incubation of enzyme at low pH. At low pH, the presence of ATP alone in the incubation medium was sufficient to inactivate NR, indicating that H⁺ can substitute the Mg²⁺ in formation of an inactive complex of enzyme. ATP-dependent inactivation of NR at low pH was prevented by staurosporine and reversed by AMP. However, AMP action was not altered by microcystin LR suggesting that in low pH the nucleotide induced reactivation of NR is not limited to the protein phosphorylation.     

The activity and stability of wheat nitrate reductase in vitro

The activity and decay characteristics of nitrate reductase from wheat (Triticum aestivum) were studied in crude, partially-purified and highly-purified preparations. The decay of nitrate reductase activity in crude extracts was due to spontaneous dissociation of the enzyme and to the effects of two decay factors, one present in the 0–30% and the other in the 50–70% saturated (NH₄)₂SO₄ fraction of a crude extract. Low rates of factor-mediated NR decay in vitro were associated with high levels of NR activity in vivo.     

The activation state of nitrate reductase is not always correlated with total nitrate reductase activity in leaves

The relation between nitrate reductase (NR; EC 1.6.6.1) activity, activation state and NR protein in leaves of barley (Hordeum vulgare L.) seedlings was investigated. Maximum NR activity (NRA_max) and NR protein content (Western blotting) were modified by growing plants hydroponically at low (0.3 mM) or high (10 mM) nitrate supply. In addition, plants were kept under short-day (8 h light/16 h dark) or long-day (16 h light/8 h dark) conditions in order to manipulate the concentration of nitrate stored in the leaves during the dark phase, and the concentrations of sugars and amino acids accumulated during the light phase, which are potential signalling compounds. Plants were also grown under phosphate deficiency in order to modify their glucose-6-phosphate content. In high-nitrate/long-day conditions, NRA_max and NR protein were almost constant during the whole light period. Low-nitrate/long-day plants had only about 30% of the NRA_max and NR protein of high-nitrate plants. In low-nitrate/long-day plants, NRA_max and NR protein decreased strongly during the second half of the light phase. The decrease was preceded by a strong decrease in the leaf nitrate content. Short daylength generally led to higher nitrate concentrations in leaves. Under short-day/low-nitrate conditions, NRA_max was slightly higher than under long-day conditions and remained almost constant during the day. This correlated with maintenance of higher nitrate concentrations during the short light period. The NR activation state in the light was very similar in high-nitrate and low-nitrate plants, but dark inactivation was twice as high in the high-nitrate plants. Thus, the low NRA_max in low-nitrate/long-day plants was slightly compensated by a higher activation state of NR. Such a partial compensation of a low NR_max by a higher dark activation state was not observed with phosphate-depleted plants. Total leaf concentrations of sugars, of glutamine and glutamate and of glucose-6-phosphate did not correlate with the NR activation state nor with NRA_max. Received: 24 March 1999 / Accepted: 31 May 1999     

Rhythms in magnesium ion inhibition and hysteretic properties of nitrate reductase in the CAM plant Bryophyllum fedtschenkoi

Nitrate reductase (NR, EC 1.6.6.1) was tested in crude extracts of leaves from Bryophyllum fedtschenkoi plants growing under alternating light/darkness as well as in excised leaves kept in continuous light or darkness. In most extracts NR activity was inhibited 20–80% by 5 m M Mg²⁺ A light or darkness shift (30 min darkness) during the first part of the photoperiod gave an increase in the Mg²⁺ inhibition and a decrease in NR activity. Magnesium ion inhibition of NR also showed diurnal variations. Strongest inhibition was found in extracts made during the latter part of the photoperiod and start of the dark period. Pre-incubation of crude extracts with ATP increased Mg²⁺ inhibition, indicating that phosphorylation of NR is involved in regulation of NR in Crassulacean acid metabolism (CAM) plants. In continuous light an increase in Mg²⁺ inhibition occurred after 20 h and 40 h, indicating a rhythm in the phosphorylation of NR. A delay in the production of nitrite in the assay (hysteresis) was generally seen in extracts susceptible to Mg²⁺ inhibition. The rhythms related to NR activity showed the same period length (20 h) as the rhythm in CO₂ exchange. However, in contrast to the rhythm in CO₂ exchange, NR rhythms were strongly damped in continuous light. In constant darkness the rhythms were even more damped. The results show that post-translational modification of CAM NR is influenced by light/darkness and by an endogenous rhythm.     

Activation of nitrate reductase by extracts from corn scutella

NADH-nitrate reductase (NR) from the primary leaves and root tips of corn seedlings (var. W64A × W182E) were activated by extracts from corn scutella. The activator extracted in potassium phosphate buffer (pH 7.5) or 80% (v/v) ethanol and fractionated by Dowex 1 (acetate) and Dowex 50 (H⁺) resins was recovered in the cationic fraction. The activator was not detected in extracts from shoots, roots, or endosperm of the seedlings. It activated the nitrate-induced cytochrome c reductase of NR complex but had slight inhibitory effects on the activities of FMNH₂-NR and reduced methylviologen-NR. In addition the activator inhibited the activities of purified NR-inactivating proteins from corn roots (var. Wf9 × 38-11) and rice cell cultures.     

Distribution of nitrate reductase activity in Vicia faba: Effect of nitrate and plant genotype

The short term effect of NO₃⁻ (12 mM) on nitrate reductase (NR. EC 1.6.6.1) activity has been studied in the roots, nodules and leaves of different genotypes of Vicia faba L. at the end of vegetative growth. Root and leaf NR activity responded positively to NO₃⁻ while nodule activity, where detected, proved to he strongly inhibited. The withdraw of this NO₃⁻ from the solution consistently reduced activity in the roots and leaves but surprising, promoted a significant increase in nodule activity, which matched or surpassed that of control plants On the other hand, nodules developed in the presence of 8 mM NO₃⁻ expressed an on average 141% higher level of NR activity than did controls. This effect was observed even in nodules with negligible control activity. In any case, a naturally occurring mutant (VF17) lacking root and nodule NR activity is described. The results indicate that in V. faba. the effects of NO₃⁻ and plant genotype on NR activity depended on plant organ and time of NO₃⁻ application, hut the distribution of NO₃⁻ reduction through the plain was mainly dependent on plant genotype, and to a lesser extent on NO: supply and plant age.     

Temperature dependence of nitrate reductase activity in marine phytoplankton: biochemical analysis and ecological implications

The temperature dependence of NADH:NR activity was examined in several marine phytoplankton species and vascular plants. These species inhabit divergent thermal environments, including the chromophytes Skeletonema costatum (12–15° C), Skeletonema tropicum (18–25° C), Thalassiosira antarctica (?2 to 4° C), and Phaeocystis antarctica (?2 to 4° C), the green alga Dunaliella tertiolecta (14–28° C), and the vascular plants Cucurbita maxima (20–35° C) and Zea mays (20–25° C). Despite the difference in growth habitats, similar temperature response curves were observed among the chromophytic phytoplankton, with temperatures optimal for NR activity being between 10–20° C. In contrast, the chlorophyll b‐containing alga and vascular plants exhibited optimal temperatures for NR activity above 30° C. Such dramatic differences in NR thermal characteristics from the two taxonomic groups reflect a divergence in NR structure that may be associated with the evolutionary diversification of chromophytes and chlorophytes. Further, it suggests a potential contribution of the thermal performance of NR to the geographic distributions, seasonal abundance patterns, and species composition of phytoplankton communities. NR partial activities, which assess the individual functions of Mo‐pterin and FAD domains, were evaluated on NR purified from S. costatum to determine the possible causes for high temperature (>20° C) inactivation of NR from chromophytes. It was found that the FAD domain and electron transport among redox centers were sensitive to elevated temperatures. S. costatum cells grown at 5, 15, and 25° C exhibited an identical optimal temperature (15° C) for NADH:NR activity, whereas the maximal NR activity and NR protein levels differed and were positively correlated with growth temperature and growth rate. These findings demonstrate that thermal acclimation of NO₃^? reduction capacity is largely at the level of NR protein expression. The consequences of these features on NO₃^? utilization are discussed.     

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.     

Effect of ammonium and nitrate on ferric chelate reductase and nitrate reductase in Vaccinium species

BACKGROUND AND AIMS: Most Vaccinium species have strict soil requirements for optimal growth, requiring low pH, high iron availability and nitrogen primarily in the ammonium form. These soils are limited and are often located near wetlands. Vaccinium arboreum is a wild species adapted to a wide range of soils, including high pH, low iron, and nitrate-containing soils. This broader soil adaptation in V. arboreum may be related to increased efficiency of iron or nitrate uptake compared with the cultivated Vaccinium species. METHODS: Nitrate, ammonium and iron uptake, and nitrate reductase (NR) and ferric chelate reductase (FCR) activities were compared in two Vaccinium species grown hydroponically in either nitrate or ammonia, with or without iron. The species studied were the wild V. arboreum and the cultivated V. corymbosum interspecific hybrid, which exhibits the strict soil requirements of most Vaccinium species. RESULTS: Ammonium uptake was significantly greater than nitrate uptake in both species, while nitrate uptake was greater in the wild species, V. arboreum, compared with the cultivated species, V. corymbosum. The increased nitrate uptake in V. arboreum was correlated with increased root NR activity compared with V. corymbosum. The lower nitrate uptake in V. corymbosum was reflected in decreased plant dry weight in this species compared with V. arboreum. Root FCR activity increased significantly in V. corymbosum grown under iron-deficient conditions, compared with the same species grown under iron-sufficient conditions or with V. arboreum grown under either iron condition. CONCLUSIONS: V. arboreum appears to be more efficient in acquiring nitrate compared with V. corymbosum, possibly due to increased NR activity and this may partially explain the wider soil adaptation of V. arboreum.     

Effect of sodium chloride on the nitrate reductase of Suaeda maritima var. macrocarpa

The nitrate reductase (NR) activity extracted from Suaeda maritima is reduced by half in the presence of 0.1 M sodium chloride. This effect of sodi     

Monoclonal antibodies to a higher-plant nitrate reductase: Differential inhibition of enzyme activities

A set of monoclonal antibodies has been raised against NADH-nitrate reductase (NR; EC 1.6.6.1) from spinach (Spinacea oleracea L.) leaves. Antibodies were screened by enzyme-linked immunosorbent assay and by their ability to inhibit various activities of the enzyme. The six monoclonals selected (AFRC MAC 74 to 79) are all gamma globulins; four (MAC 74 to 77) inhibit all terminal donating activities (NADH-NR; flavin mononucleotide, reduced form (FMNH₂)-NR; and methyl viologen, reduced form (MV)-NR) and two (MAC 78 and 79) inhibit the acceptor activities (NADH-NR, and NADH-cytochrome c reductase). MAC 74 to 77 inhibit the NADH-NR activity of crude extracts of a variety of species (mono- and dicotyledoneae) while MAC 78 and 79 are effective against spinach and marrow, but not oil-seed rape, cucumber, oats, wheat and barley.Abbreviations Cyt c Rase cytochrome c reductase - ELISA enzyme-linked immunosorbent assay - FAD(H₂) flavin adenine dinucleotide (reduced form) - FMN(H₂) flavin mononucleotide (reduced form) - McAb monoclonal antibody - MV methyl viologen reduced form - NR nitrate reductase     

Atrazine induced changes in elemental and biochemical composition and nitrate reductase activity in Chlamydomonas reinhardtii

Herbicides play an important role in agricultural practices but the introduction of these compounds into the aquatic environment can have severe consequences for non-target organisms such as microalgae. The ubiquitous green freshwater microalga Chlamydomonas reinhardtii, a model species in all aspects of microalgal physiology, was used to assess the toxicity of atrazine, one of the most widely used herbicides throughout the world. Atrazine acts on photosynthesis and therefore can affect non-target primary producers, such as microalgae.

Growth, dry weight, elemental composition, photosynthetic pigments and protein contents and nitrate reductase activity were studied. After 96 h of exposure to different atrazine concentrations all the parameters studied were affected, but different sensitivities to the herbicide were shown. Nitrate reductase (NR) activity was strongly affected even at an atrazine concentration that did not affect growth (0.1 µM); the lowest concentrations of atrazine assayed (0.1 and 0.25 µM) provoked a > 40% decrease in NR activity and NR decreased > 80% with atrazine concentrations of 0.5 µM. C/N ratio was also affected by all the atrazine concentrations assayed. Nitrate reductase activity and C/N ratio were better indicators of the cellular stress state than data on other biochemical components or growth rate. Among cell parameters assayed, the NR activity stood out as a sensitive cytotoxicity endpoint and the activity of this enzyme can be suggested as a sensitive biomarker of stress induced by atrazine in C. reinhardtii.     

Light/dark regulation of higher plant nitrate reductase related to hysteresis and calcium/magnesium inhibition

Examination of nitrate reductase (NR, EC 1.6.6.1) activity in crude extracts made from squash leaves before and after a light/dark transition, indicates the existence of two different forms of nitrate reductase; a 'light form' with a pH optimum of 7.8 that is not inhibited by calcium or magnesium, and a 'dark form' with a pH optimum of 7.6 that is strongly inhibited by calcium or magnesium. The same properties also characterise purified NR. The 'light and dark forms' of NR correspond to the two kinetically different forms of purified NR showing (1) linear product formation and (2) delayed product formation, i.e. hysteretic behaviour.