Phosphorylation/dephosphorylation of Komatsuna (Brassica campestris) leaf nitrate reductase in vivo and in vitro in response to environmental light conditions: Effects of protein kinase and protein phosphatase inhibitors

Activity of nitrate reductase (NR; EC 1.6.6.1) in leaves of Komatsuna (Brassica campestris L. ssp. rapifera cv. Osome) was decreased by sudden darkness, and rapidly recovered upon reillumination. However, the amount of NR protein, estimated by western blots, did not fluctuate during short-term light/dark/light transitions. This suggests that rapid changes of NR activity in response to light/dark regimes are due to reversible modulation of the protein and not to de novo synthesis/degradation. In mannose-fed leaves, such light/dark changes in NR activity were not observed. When extracts from illuminated leaves were incubated with MgATP, NR activity decreased in a time-dependent manner. K-252a, a specific inhibitor of protein kinases, prevented the in vitro inactivation of NR. The radiolabel of [γ-³²P] ATP was incorporated into NR protein in vitro and the labelling of NR was blocked by K-252a. On the other hand, extractable NR from darkened leaves was activated by incubation at 30°C without further additions. The in vitro activation of NR was prevented by calyculin A, a potent and specific inhibitor of protein phosphatase. Moreover calyculin A abolished the in vivo activation of NR by illumination. Our results confirm a regulatory system by phosphorylation/dephosphorylation of NR. The data also suggest that the activity of NR depends on the relative phosphorylation/dephosphorylation activities subtly controlled in response to photon flux density.     

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.     

Correlation between apparent activation state of nitrate reductase (NR), NR hysteresis and degradation of NR protein

Nitrate reductase (NR) activity was measured in extracts fromspinach leaves exposed to light or prolonged darkness, and tovarious treatments provoking an artificial activation of theenzyme in the dark. NR activity was determined immediately eitherin the presence of Mg²⁺, which gives an estimation of the putative(actual) activity in situ (NR_act), or in EDTA without preincubation,which gives an intermediate activity (NR_int), or after a 30min preincubation with EDTA plus AMP plus Pi, which gives themaximum NR activity (NR_max). NR_max is thought to reflect totalNR protein contents. In the dark, NR_act was usually very low. Dark inactivation wasprevented or reversed by feeding AICAR (5-aminoimidazole-4-carboxiamideribonucleoside), or by anaerobiosis, acid treatment or additionof uncoupler. During prolonged darkness, NR_max decreased, indicatingnet protein degradation with a half-time of 21 h. Conditionswhich caused an activation (dephosphorylation) of NR in thedark, slowed down NR protein degradation. This was also confirmedby Western blotting. Blockage of cytosolic protein synthesis with cycloheximide (CHX)did not accelerate NR protein degradation. In contrast, after5 h in the dark, NR_act increased in CHX-treated leaves. As thisincrease was sensitive to PP2A-inhibitors, it was probably dueto NR dephosphorylation. However, extractable NR kinase andNR phosphatase activities were not changed by CHX treatment.Apparently, CHX interacted with the NR regulatory system indirectlyby affecting turnover of another protein. The increase from NR_int to NR_max which occurred during preincubationof the leaf extract with EDTA plus AMP plus Pi was insensitiveto PP2A inhibitors and was interpreted as a hysteretic conversionof NR from an inactive into an active form. Hysteretic activationwas positively correlated to the NR phosphorylation state. Amodel is presented to explain the hysteretic behaviour of NRin relation to NA phosphorylation/ dephosphorylation. Overall, the data indicate that NR protein phosphorylation notonly controls the catalytic activity of NR, but also acts asa signal for NR protein degradation, with phospho-NR probablybeing a better substrate for protein degradation than the dephospho-form. Key words: Enzyme hysteresis, nitrate reductase, posttranslational modification, protein phosphorylation, protein turnover     

Comparative studies of the light modulation of nitrate reductase and sucrose-phosphate synthase activities in spinach leaves

We recently obtained evidence that the activity of spinach (Spinacia oleracea L.) leaf nitrate reductase (NR) responds rapidly and reversibly to light/dark transitions by a mechanism that is strongly correlated with protein phosphorylation. Phosphorylation of the NR protein appears to increase sensitivity to Mg²⁺ inhibition, without affecting activity in the absence of Mg²⁺. In the present study, we have compared the light/dark modulation of sucrose-phosphate synthase (SPS), also known to be regulated by protein phosphorylation, and NR activities (assayed with and without Mg²⁺) in spinach leaves. There appears to be a physiological role for both enzymes in mature source leaves (production of sucrose and amino acids for export), whereas NR is also present and activated by light in immature sink leaves. In mature leaves, there are significant diurnal changes in SPS and NR activities (assayed under selective conditions where phosphorylation status affects enzyme activity) during a normal day/night cycle. With both enzymes, activities are highest in the morning and decline as the photoperiod progresses. For SPS, diurnal changes are largely the result of phosphorylation/dephosphorylation, whereas with NR, the covalent modification is super-imposed on changes in the level of NR protein. Accumulation of end products of photosynthesis in excised illuminated leaves increased maximum NR activity, reduced its sensitivity of Mg²⁺ inhibition, and prevented the decline in activity with time in the light seen with attached leaves. In contrast, SPS was rapidly inactivated in excised leaves. Overall, NR and SPS share many common features of control but are not identical in terms of regulation in situ.     

Regulation of nitric oxide (NO) production by plant nitrate reductase in vivo and in vitro.

NO (nitric oxide) production from sunflower plants (Helianthus annuus L.), detached spinach leaves (Spinacia oleracea L.), desalted spinach leaf extracts or commercial maize (Zea mays L.) leaf nitrate reductase (NR, EC 1.6.6.1) was continuously followed as NO emission into the gas phase by chemiluminescence detection, and its response to post-translational NR modulation was examined in vitro and in vivo. NR (purified or in crude extracts) in vitro produced NO at saturating NADH and nitrite concentrations at about 1% of its nitrate reduction capacity. The K(m) for nitrite was relatively high (100 microM) compared to nitrite concentrations in illuminated leaves (10 microM). NO production was competitively inhibited by physiological nitrate concentrations (K(i)=50 microM). Importantly, inactivation of NR in crude extracts by protein phosphorylation with MgATP in the presence of a protein phosphatase inhibitor also inhibited NO production. Nitrate-fertilized plants or leaves emitted NO into purified air. The NO emission was lower in the dark than in the light, but was generally only a small fraction of the total NR activity in the tissue (about 0.01-0.1%). In order to check for a modulation of NO production in vivo, NR was artificially activated by treatments such as anoxia, feeding uncouplers or AICAR (a cell permeant 5'-AMP analogue). Under all these conditions, leaves were accumulating nitrite to concentrations exceeding those in normal illuminated leaves up to 100-fold, and NO production was drastically increased especially in the dark. NO production by leaf extracts or intact leaves was unaffected by nitric oxide synthase inhibitors. It is concluded that in non-elicited leaves NO is produced in variable quantities by NR depending on the total NR activity, the NR activation state and the cytosolic nitrite and nitrate concentration.     

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.     

Light modulation and in vitro effects of adenine nucleotides on leaf nitrate reductase activity in cucumber (Cucumis sativus)

Nitrate reductase (NR, EC 1.6.6.1) activity in attached cucumber ( Cucumis sativus L. cv. Ashley) leaves changed rapidly and reversibly during light/dark transitions, especially when assayed in the presence of free Mg²⁺. Light decreased and darkness increased the sensitivity of the enzyme to inhibition by Mg²⁺. The NR activation state, i.e. activity in the presence of Mg²⁺ relative to activity in the absence of Mg²⁺, increased with light intensity up to 400 μmol m⁻² s⁻¹ PAR (photosynthetically active radiation). When a desalted crude extract from illuminated leaves was preincubated with ATP, NR was gradually inactivated. Inactivation was only observed when activity was assayed in the presence of Mg²⁺. The ATP-inactivated NR remained inactive after removing the excess of ATP by gel filtration and it did not occur in partially purified NR preparations. NR extracted from darkened attached leaves was markedly activated when preincubated with 5'-AMP. These results support the view that inactivation/activation of cucumber-leaf NR in response to light/dark signals most likely involves phosphorylation/dephosphorylation of the enzyme catalysed by endogenous proteins. A substantial activation of NR by preincubation with 5'-AMP was also observed when activity was assayed in the absence of Mg²⁺, thus indicating that 5'-AMP can directly activate NR. Irradiation of an extract from darkened leaves containing FAD promoted a partial activation of NR. This effect was observed both in the +Mg²⁺ and in the −Mg²⁺ assay, indicating that activation was caused by photoexcited flavin and did not involve dephosphorylation of the enzyme.     

Regulation of nitrate reductase in detached oat leaves by light and oxygen

Regulation of nitrate reductase (NR, EC 1.6.6.1) by oxygen concentration and light was studied in segments of oat ( Avena sativa L. cv. Suregrain) leaves, using the in vivo nitrate reductase assay. The activity of NR decreased after excision in either light or darkness; the addition of cycloheximide prevented this decrease. Treatments that increased tissue permeability (anoxia, Triton X-100) also increased NR activity. There was in general less NR activity in the light than in the dark and also less under aerobic (21–100% O₂) than under anaerobic (0.3% O₂) conditions. Treatments with antioxidants improved the activity in the light, but only at high O₂ levels (21–100% O₂).
The results suggest that NR may be regulated by inhibitory proteins synthesized in either light or darkness, by permeability changes and by light-induced oxidations that occur when O₂ is present. Oxygen may control the activity by stimulating the synthesis of inhibitory proteins in the light and in the dark and by promoting oxidation of SH-groups in the light.     

Nicotinamide Adenine Dinucleotide Phosphate Phosphatase Facilitates Dark Reduction of Nitrate: Regulation by Nitrate and Ammonia

Leaves of 15 - 30-d-old plants of sunflower and jute were harvested at 10.00 or 23.00 (local time) and measured immediately, or those harvested at 10.00 were incubated for one hour in sunlight either in water or 5 mM methionine sulfoximine (MSX) solution and then for three hours in dark either in water or 15 mM KNO3 solution. Nitrate feeding during dark incubation, in general, increased nitrate reductase (NR) and nitrite reductase (NiR) activities, and NADH and soluble sugar contents. Increase in tissue nitrate concentration in MSX fed but not in control samples suggested reduction of nitrate in dark. NADPH-dependent NR activity increased considerably upon feeding with nitrate in dark. Concomitantly, NADPH phosphatase activity was also increased in nitrate treated, dark incubated leaves. It is proposed that nitrate regulates dark nitrate reduction by facilitating generation of NADH from NADPH by NADPH phosphatase. High amounts of ammonia accumulated in MSX treated, but not in control leaves, upon dark incubation. Relative activities of NR and NADPH phosphatase, and amounts of soluble sugar and NADH were low in MSX fed samples compared to that of control. So, high amount of ammonia might partially repress NADPH phosphatase and consequently deprive NR of reducing equivalents. This revised version was published online in July 2006 with corrections to the Cover Date.     

Mutation of the regulatory phosphorylation site of tobacco nitrate reductase results in constitutive activation of the enzyme in vivo and nitrite accumulation

In wild-type Nicotiana plumbaginifolia and other higher plants, nitrate reductase (NR) is rapidly inactivated/activated in response to dark/light transitions. Inactivation of NR is believed to be caused by phosphorylation at a special conserved regulatory Ser residue, Ser 521, and interactions with divalent cations and inhibitory 14-3-3 proteins. A transgenic N. plumbaginifolia line (S(521)) was constructed where the Ser 521 had been changed by site-directed mutagenesis into Asp. This mutation resulted in complete abolishment of inactivation in response to light/dark transitions or other treatments known to inactivate NR. During prolonged darkness, NR in wild-type plants is in the inactivated form, whereas NR in the S(521) line is always in the active form. Differences in degradation rate between NR from S(521) and lines with non-mutated NR were not found. Kinetic constants like Km values for NADH and NO3(-) were not changed, but a slightly different pH profile was observed for mutated NR as opposed to non-mutated NR. Under optimal growth conditions, the phenotype of the S(521) plants was not different from the wild type (WT). However, when plants were irrigated with high nitrate concentration, 150 mM, the transgenic plants accumulated nitrite in darkness, and young leaves showed chlorosis.     

5-Aminoimidazole-4-carboxamide riboside activates nitrate reductase in darkened spinach and pea leaves

Nitrate reductase (NR) activity is modulated in vivo by phosphorylation (inactivation)/dephosphorylation (activation) in response to light/dark signals. The dephosphorylation of phospho-NR in vitro, catalyzed by endogenous protein phosphatases, is known to be stimulated by 5'-AMP suggesting that this metabolite may be an important regulator of the activity of NR, e.g. under anoxia. To determine whether 5'-AMP might be a regulatory metabolite in vivo, excised spinach ( Spinacia oleracea ) and pea ( Pisum sativum ) leaves were provided 5-aminoimidazole-4-carboxamide riboside (AICAR) via the transpiration stream, and the apparent phosphorylation status of NR was assessed by assay of activity in the presence of free Mg²⁺. NR was activated in darkened spinach leaves in a time- and concentration-dependent manner when leaves were fed AICAR; there was also an accumulation of nitrite in treated leaves in the dark. The activation by AICAR could be blocked by several type 2A protein phosphatase inhibitors (microcystin-LR, okadaic acid and cantharidin), and was not the result of a reduction of kinase activity by lack of ATP because cellular adenylates were unaffected. It was confirmed that AICAR-P, but not AICAR, mimicked 5'-AMP in the activation of phospho-NR in vitro. Our results are consistent with the notion that AICAR is converted to the monophosphorylated derivative, which accumulates in cells and acts as a structural analog of 5'-AMP. Our results suggest that a rise in cytosolic [5'-AMP] may be sufficient to activate NR in vivo. AICAR should be a useful compound for identifying AMP-regulated processes in plant systems.     

A protein kinase activated by darkness phosphorylates nitrate reductase in Komatsuna (Brassica campestris) leaves

Although it has been shown that leaf nitrate reductase (NR: EC 1.6.6.1) is phosphorylated by subjecting plants to darkness, there is no evidence for the existence of dark-activated or dark-induced NR kinase. This study was undertaken to investigate the occurrence of a protein kinase phosphorylating NR in response to dark treatments. Immediately after transferring Komatsuna (Brassica campestris L.) plants to darkness, we observed rapid increases in the phosphorylating activity of the synthetic peptide, which is designed for the amino acid sequence surrounding the regulatory serine residue of the hinge 1 region of Komatsuna NR, in crude extracts from leaves. The activity reached a maximum after 10 min of darkness. Inactivation states of NR estimated from relative activities with or without Mg2+ were correlated to activities of the putative dark-activated protein kinase. Using the synthetic peptide as a substrate, we purified a protein kinase from dark-treated leaves by means of successive chromatographies on Q-Sepharose, Blue Sepharose, FPLC Q-Sepharose, and ATP-gamma-Sepharose columns. The purified kinase had an apparent molecular mass of 150 kDa with a catalytic subunit of 55 kDa, and it was Ca2+-independent. The purified kinase phosphorylated a recombinant cytochrome c reductase protein, a partial protein of NR, and holo NR, and inactivated NR in the presence of both 14-3-3 protein and Mg2+. The kinase also phosphorylated synthetic peptide substrates designed for sucrose phosphate synthase and 3-hydroxy-3-methylglutaryl-Coenzyme A reductase. Among inhibitors tested, only K252a, a potent and specific serine/threonine kinase inhibitor, completely inhibited the activity of the dark-activated kinase. The activity of the purified kinase was also specifically inhibited by K252a. Taken together with these findings, results obtained suggest that the putative dark-activated protein kinase may be the purified kinase itself, and may be responsible for in vivo phosphorylation of NR and its inactivation during darkness.     

Rapid and slow modulation of nitrate reductase activity in the red macroalga <Emphasis Type="Italic">Gracilaria chilensis</Emphasis> (Gracilariales,Rhodophyta): influence of different nitrogen sources

Nitrate is one of the most important stimuli in nitrate reductase (NR) induction, while ammonium is usually an inhibitor. We evaluated the influence of nitrate, ammonium or urea as nitrogen sources on NR activity of the agarophyte Gracilaria chilensis. The addition of nitrate rapidly (2 min) induced NR activity, suggesting a fast post-translational regulation. In contrast, nitrate addition to starved algae stimulated rapid nitrate uptake without a concomitant induction of NR activity. These results show that in the absence of nitrate, NR activity is negatively affected, while the nitrate uptake system is active and ready to operate as soon as nitrate is available in the external medium, indicating that nitrate uptake and assimilation are differentially regulated. The addition of ammonium or urea as nitrogen sources stimulated NR activity after 24 h, different from that observed for other algae. However, a decrease in NR activity was observed after the third day under ammonium or urea. During the dark phase, G. chilensis NR activity was low when compared to the light phase. A light pulse of 15 min during the dark phase induced NR activity 1.5-fold suggesting also fast post-translational regulation. Nitrate reductase regulation by phosphorylation and dephosphorylation, and by protein synthesis and degradation, were evaluated using inhibitors. The results obtained for G. chilensis show a post-translational regulation as a rapid response mechanism by phosphorylation and dephosphorylation, and a slower mechanism by regulation of RNA synthesis coupled to de novo NR protein synthesis.     

Antibodies to assess phosphorylation of spinach leaf nitrate reductase on serine 543 and its binding to 14-3-3 proteins.

To monitor site-specific phosphorylation of spinach leaf nitrate reductase (NR) and binding of the enzyme to 14-3-3 proteins, serum antibodies were raised that select for either serine 543 phospho- or dephospho-NR. The dephospho-specific antibodies blocked NR phosphorylation on serine 543. The phospho-specific antibodies prevented NR binding to 14-3-3s, NR inhibition by 14-3-3s, NR dephosphorylation on serine 543, and did not precipitate 14-3-3s together with NR. Together, this confirms that 14-3-3s bind to NR at hinge 1 after it has been phosphorylated on serine 543. The amounts of individual NR forms were determined in leaf extracts by immunoblotting and immunoprecipitation. The phosphorylation state of NR on serine 543 increased 2-3-fold in leaves upon a light/ dark transition. Before the transition, one-third of NR was already phosphorylated on serine 543 but was not bound to 14-3-3s. Phosphorylation of serine 543 seems not to be enough to bind to 14-3-3s in leaves.     

In Vivo Regulation of Wheat-Leaf Phosphoenolpyruvate Carboxylase by Reversible Phosphorylation

Regulation of C3 phosphoenolpyruvate carboxylase (PEPC) and its protein-serine/threonine kinase (PEPC-PK) was studied in wheat (Triticum aestivum) leaves that were excised from low-N-grown seedlings and subsequently illuminated and/or supplied with 40 mM KNO3. The apparent phosphorylation status of PEPC was assessed by its sensitivity to L-malate inhibition at suboptimal assay conditions, and the activity state of PEPC-PK was determined by the in vitro 32P labeling of purified maize dephospho-PEPC by [[gamma]-32P]ATP/Mg. Illumination ([plus or minus]NO3-) for 1 h led to about a 4.5-fold increase in the 50% inhibition constant for L-malate, which was reversed by placing the illuminated detached leaves in darkness (minus NO3-). A 1 -h exposure of excised leaves to light, KNO3, or both resulted in relative PEPC-PK activities of 205, 119, and 659%, respectively, of the dark/0 mM KNO3 control tissue. In contrast, almost no activity was observed when a recombinant sorghum phosphorylation-site mutant (S8D) form of PEPC was used as protein substrate in PEPC-PK assays of the light plus KNO3 leaf extracts. In vivo labeling of wheat-leaf PEPC by feeding 32P-labeled orthophosphate showed that PEPC from light plus KNO3 tissue was substantially more phosphorylated than the enzyme in the dark minus-nitrate immunoprecipitates. Immunoblot analysis indicated that no changes in relative PEPC-protein amount occurred within 1 h for any of the treatments. Thus, C3 PEPC activity in these detached wheat leaves appears to be regulated by phosphorylation of a serine residue near the protein's N terminus by a Ca2+ -independent protein kinase in response to a complex interaction in vivo between light and N.     

Diurnal variations of nitrate reductase activity and stability in barley leaves

Diurnal variations of nitrate reductase (NR) activity and stability have been studied in leaves of barley seedlings ( Hordeum vulgare L. cv. Herta) grown in an 8 h light/16 h darkness regime. Stability (decay) of NR was tested both in the extracts and in the plants. In the morning, when the plants were transferred to light, NR activity increased rapidly during the first hour and then remained constant. After the photoperiod, activity decreased rapidly during the first hour of darkness and then remained fairly constant during the rest of the dark period. The high NR activity during the photoperiod was associated with low NR stability both in the extracts and in the plants. On the other hand the low NR activity during the dark period was associated with high stability in the extracts and in the plants.     

Nitrate reductase dephosphorylation is induced by sugars and sugar-phosphates in corn leaf segments

The in situ and in vitro regulation of nitrate reductase (NR; EC 1.6.6.1) activity by glucose (Glc) and glucose‐6‐phosphate (Glc‐6P) was studied in leaf segments of 7‐day‐old corn plants. In situ, Glc and Glc‐6P not only prevented NR inactivation, but also slightly activated the enzyme relative to that in fresh attached leaves in the light. Glc and Glc‐6P also reactivated NR that had previously been inactivated by incubating the segments for 30 min in the dark. Sugars were effective, even in the presence of cycloheximide, but not of cantharidin, an inhibitor of type 2A phosphoprotein phosphatase (PP2A). In segments kept in the dark, the inhibition of protein dephosphorylation by cantharidin showed that the phosphorylation of NR was not inhibited by either Glc or Glc‐6P, as the enzyme was inactivated to the same extent whether or not sugars (P) were present in the incubation medium. In vitro, as in situ, neither Glc nor Glc‐6P could prevent NR phosphorylation. In spite of some reports showing that sugar‐phosphates can act on kinases and prevent NR phosphorylation, the results presented here suggest that, in corn leaves, sugars and their phosphorylated derivatives probably activate NR in situ mainly by inducing protein dephosphorylation. The incubation of crude extract in a water bath at 27°C for 45 min resulted in the activation of NR that was blocked by cantharidin, but was not increased by either Glc or Glc‐6P. This result suggests that the presence of another metabolite(s) and the maintenance of cell functionality may be necessary for the sugar‐induced activation of NR. A sugar‐triggered signalling pathway independent of protein synthesis may be involved in the process. l ‐Glc and 6‐deoxyglucose were ineffective in reactivating NR in darkened segments, whilst 2‐deoxyglucose was as effective as Glc itself. The effect of sugar analogues shows that, although Glc has to enter the cell and be phosphorylated to activate NR, further metabolism is not necessary. As sugar‐phosphates, such as Glc‐6P and fructose‐6‐phosphate (Fru‐6P), also activate NR, it seems that hexokinases are not involved in the pathway that leads to the in situ dephosphorylation of NR. In vitro, Glc‐6P mildly but rapidly activated NR by a mechanism insensitive to cantharidin. The addition of an increasing concentration of Mg²⁺ to crude extract containing Glc‐6P increased the Mg²⁺ inhibition of NR. This result suggests that the hexose‐phosphate does not prevent Mg²⁺ association with NR. It is possible that Glc‐6P activates NR in vitro by inducing the dissociation of 14‐3‐3 from the phospho‐NR (pNR)/Mg/14‐3‐3 complex.     

Nitric oxide emission from tobacco leaves and cell suspensions: rate limiting factors and evidence for the involvement of mitochondrial electron transport

Quantitative data on nitric oxide (NO) production by plants, and knowledge of participating reactions and rate limiting factors are still rare. We quantified NO emission from tobacco (Nicotiana tabacum) wild-type leaves, from nitrate reductase (NR)- or nitrite reductase (NiR)-deficient leaves, from WT- or from NR-deficient cell suspensions and from mitochondria purified from leaves or cells, by following NO emission through chemiluminescence detection. In all systems, NO emission was exclusively due to the reduction of nitrite to NO, and the nitrite concentration was an important rate limiting factor. Using inhibitors and purified mitochondria, mitochondrial electron transport was identified as a major source for reduction of nitrite to NO, in addition to NR. NiR and xanthine dehydrogenase appeared to be not involved. At equal respiratory activity, mitochondria from suspension cells had a much higher capacity to produce NO than leaf mitochondria. NO emission in vivo by NiR-mutant leaves (which was not nitrite limited) was proportional to photosynthesis (high in light +CO(2), low in light -CO(2), or in the dark). With most systems including mitochondrial preparations, NO emission was low in air (and darkness for leaves), but high under anoxia (nitrogen). In contrast, NO emission by purified NR was not much different in air and nitrogen. The low aerobic NO emission of darkened leaves and cell suspensions was not due to low cytosolic NADH, and appeared only partly affected by oxygen-dependent NO scavenging. The relative contribution of NR and mitochondria to nitrite-dependent NO production is estimated.