Nitrite accumulation and nitric oxide emission in relation to cellular signaling in nitrite reductase antisense tobacco.

An antisense nitrite reductase (NiR, EC 1.7.7.1) tobacco ( Nicotiana tabacum L.) transformant (clone 271) was used to gain insight into a possible correlation between nitrate reductase (NR, EC 1.6.6.1)-dependent nitrite accumulation and nitric oxide (NO(.)) production, and to assess the regulation of signal transduction in response to stress conditions. Nitrite concentrations of clone 271 leaves were 10-fold, and NO(.) emission rates were 100-fold higher than in wild type leaves. Increased protein tyrosine nitration in clone 271 suggests that high NO(.) production resulted in increased peroxynitrite (ONOO(-)) formation. Tyrosine nitration was also observed in vitro by adding peroxynitrite to leaf extracts. As in mammalian cells, NO(.) and derivatives also increased synthesis of proteins like 14-3-3 and cyclophilins, which are both involved in regulation of activity and stability of enzymes.

Characterization of the sink/source transition in tobacco ( Nicotiana tabacum L.) shoots in relation to nitrogen management and leaf senescence.

The metabolic, biochemical and molecular events occurring during tobacco (Nicotiana tabacum) leaf ageing are presented, with a particular emphasis on nitrogen metabolism. An integrated model describing the source/sink relationship existing between leaves of different developmental stages along the main plant axis is proposed. The results of our study show that a tobacco plant can be divided into two main sections with regards to sink/source relationships. Sink-to-source transition occurs at a particular leaf stage in which a breakpoint corresponding to an accumulation of carbohydrates and a depletion of both organic and inorganic nitrogen is observed. The sink/source transition is also marked by the appearence of endoproteolytic activities and the induction of both cytosolic glutamine synthetase and NAD(H)-dependent glutamate dehydrogenase transcripts, proteins and activities. The role of the newly induced enzymes and the nature of the potential metabolic and developmental signals involved in the regulation of their expression during leaf senescence are discussed.

Abolition of Posttranscriptional Regulation of Nitrate Reductase Partially Prevents the Decrease in Leaf NO3- Reduction when Photosynthesis Is Inhibited by CO2 Deprivation, but Not in Darkness.

The activity of nitrate reductase (NR) in leaves is regulated by light and photosynthesis at transcriptional and posttranscriptional levels. To understand the physiological role of these controls, we have investigated the effects of light and CO2 on in vivo NO3- reduction in transgenic plants of Nicotiana plumbaginifolia lacking either transcriptional regulation alone or transcriptional and posttranscriptional regulation of NR. The abolition of both levels of NR regulation did not modify the light/dark changes in exogenous 15NO3- reduction in either intact plants or detached leaves. The same result was obtained for 15N incorporation into free amino acids in leaves after 15NO3- was supplied to the roots, and for reduction of endogenous NO3- after transfer of the plants to an N-deprived solution. In the light, however, deregulation of NR at the posttranscriptional level partially prevented the inhibition of leaf 15NO3- reduction resulting from the removal of CO2 from the atmosphere We concluded from these observations that in our conditions deregulation of NR in the transformants investigated had little impact on the adverse effect of darkness on leaf NO3- reduction, and that posttranscriptional regulation of NR is one of the mechanisms responsible for the short-term coupling between photosynthesis and leaf NO3- reduction in the light.

Adaptations of Photosynthetic Electron Transport, Carbon Assimilation, and Carbon Partitioning in Transgenic Nicotiana plumbaginifolia Plants to Changes in Nitrate Reductase Activity.

Transgenic Nicotiana plumbaginifolia plants that express either a 5-fold increase or a 20-fold decrease in nitrate reductase (NR) activity were used to study the relationships between carbon and nitrogen metabolism in leaves. Under saturating irradiance the maximum rate of photosynthesis, per unit surface area, was decreased in the low NR expressors but was relatively unchanged in the high NR expressors compared with the wild-type controls. However, when photosynthesis was expressed on a chlorophyll (Chl) basis the low NR plants had comparable or even higher values than the wild-type plants. Surprisingly, the high NR expressors showed very similar rates of photosynthesis and respiration to the wild-type plants and contained identical amounts of leaf Chl, carbohydrate, and protein. These plants were provided with a saturating supply of nitrate plus a basal level of ammonium during all phases of growth. Under these conditions overexpression of NR had little impact on leaf metabolism and did not stimulate growth or biomass production. Large differences in photochemical quenching and nonphotochemical quenching components of Chl a fluorescence, as well as the ratio of variable to maximum fluorescence, (FV/FM), were apparent in the low NR expressors in comparison with the wild-type controls. Light intensity-dependent increases in nonphotochemical quenching and decreases in FV/FM were greatest in the low NR expressors, whereas photochemical quenching decreased uniformly with increasing irradiance in all plant types. Nonphotochemical quenching was increased at all except the lowest irradiances in the low NR expressors, allowing photosystem II to remain oxidized on its acceptor side. The relative contributions of photochemical and nonphotochemical quenching of Chl a fluorescence with changing irradiance were virtually identical in the high NR expressors and the wild-type controls. Zeaxanthin was present in all leaves at high irradiances; however, at high irradiance leaves from the low NR expressors contained considerably more zeaxanthin and less violaxanthin than wild-type controls or high NR expressors. The leaves of the low NR expressors contained less Chl, protein, and amino acids than controls but retained more carbohydrate (starch and sucrose) than the wild type or high NR expressors. Sucrose phosphate synthase activities were remarkably similar in all plant types regardless of the NR activity. In contrast phosphoenolpyruvate carboxylase activities were increased on a Chl or protein basis in the low NR expressors compared with the wild-type controls or high NR expressors. We conclude that large decreases in NR have profound repercussions for photosynthesis and carbon partitioning within the leaf but that increases in NR have negligible effects.

Expression of characteristics of ammonium nutrition as affected by pH of the root medium.

To study the effect of root-zone pH on characteristic responses of NH4+ -fed plants, soybeans (Glycine max¿L.¿ Merr. cv. Ransom) were grown in flowing solution culture for 21 d on four sources of N (1.0 mol m-3 NO3-, 0.67 mol m-3 NO3- plus 0.33 mol m-3 NH4+, 0.33 mol m-3 NO3- plus 0.67 mol m-3 NH4+, and 1.0 mol m-3 NH4+) with nutrient solutions maintained at pH 6.0, 5.5, 5.0, and 4.5. Amino acid concentration increased in plants grown with NH4+ as the sole source of N at all pH levels. Total amino acid concentration in the roots of NH4+ -fed plants was 8 to 10 times higher than in NO3(-)-fed plants, with asparagine accounting for more than 70% of the total in the roots of these plants. The concentration of soluble carbohydrates in the leaves of NH4+ -fed plants was greater than that of NO3(-)-fed plants, but was lower in roots of NH4+ -fed plants, regardless of pH. Starch concentration was only slightly affected by N source or root-zone pH. At all levels of pH tested, organic acid concentration in leaves was much lower when NH4+ was the sole N source than when all or part of the N was supplied as NO3-. Plants grown with mixed NO3- plus NH4+ N sources were generally intermediate between NO3(-)- and NH4+ -fed plants. Thus, changes in tissue composition characteristic of NH4+ nutrition when root-zone pH was maintained at 4.5 and growth was reduced, still occurred when pH was maintained at 5.0 or above, where growth was not affected. The changes were slightly greater at pH 4.5 than at higher pH levels.

Estimation of Carbon and Nitrogen Allocation during Stalk Elongation by C and N Tracing in Zea mays L.

Zea mays L. (cv Dea) plants grown to the stage of stalk elongation, were allowed to assimilate (13)CO(2) and (15)N-nitrates from 45 to 53 days after sowing. Isotopic abundances in labeled nutrients were slightly enriched compared to natural abundances. The new C in plant was acropetally distributed and the new N was preferentially accumulated in the sheath and stalk in the medium region. C input was 25-fold higher than N input. The new C in total plant C was 20%, whereas it was 10% for N. The stalk acted as a major sink because it accumulated, respectively, 27.5 and 47.5% of the C and N inputs. The new C in soluble carbohydrates was 76% in growing organs (upper stalk) and only 39% in source leaves, whereas it was 43% and 13% in starch, respectively. New N in nitrates+amino-acids spanned in the range from 20% (leaf) to 50% (stalk). New C and N in soluble proteins were, respectively, 13.4 and 3.8% in leaves, 8.8 and 9.6% in stalk, and 8.7 and 14.3% in roots. In the middle stalk and leaves, the proteins and carbohydrates represent an equivalent C and N source for remobilization.

Biochemical aspect of photoassimilated carbon partitioning at late kernel fill in maize under climatic stress.

The aim of this work was to describe the incorporation of 14CO2 into maize at the late kernel fill under chilling and the subsequent movement of the photoassimilated 14C out the fed ear leaf. Cool temperatures were observed to decrease the photosynthetic rate and to alter the operation of the carbon assimilation pathway with 14C accumulation in alpha-alanine. They were shown also to affect the rate of photoassimilated carbon out of the fed area, and especially by delaying the seed import processes.

Consequence of Absence of Nitrate Reductase Activity on Photosynthesis in Nicotiana plumbaginifolia Plants.

Chlorate-resistant Nicotiana plumbaginifolia (cv Viviani) mutants were found to be deficient in the nitrate reductase apoprotein (NR(-)nia). Because they could not grow with nitrate as sole nitrogen source, they were cultivated as graftings on wild-type Nicotiana tabacum plants. The grafts of mutant plants were chlorotic compared to the grafts of wild type. Mutant leaves did not accumulate nitrogen and nitrate but contained less malate and more glutamine than wild leaves. They exhibited a slight increase of the proportion of the light-harvesting chlorophyll a/b protein complexes and a lowering of the efficiency of energy transfer between these complexes and the active centers. After a 3 second (14)CO(2) pulse, the total (14)C incorporation of the mutant leaves was approximately 20% of that of the control. The (14)C was essentially recovered in ribulose bisphosphate in these plants. It was consistent with a decline of ribulose bisphosphate carboxylase activity observed in the mutant. After a 3 second (14)CO(2) pulse followed by a 60 second chase with normal CO(2), (14)C was mainly accumulated in starch which was labeled more in the mutant than in the wild type. These results confirm the observation that in the nitrate reductase deficient leaves, chloroplasts were loaded with large starch inclusions preceding disorganization of the photosynthetic apparatus.

Relationship between Photosynthesis and Protein Synthesis in Maize: I. Kinetics of Translocation of the Photoassimilated Carbon from the Ear Leaf to the Seed.

To gain a better understanding of the biochemical basis for partitioning of photosynthetically fixed carbon between leaf and grain, a (14)CO(2) labeling study was conducted with field-grown maize plants 4 weeks after flowering. The carbon flow was monitored by separation and identification of (14)C assimilates and (14)C storage components within each tissue during the chase period (from 4 to 96 hours) following a 5 minute (14)CO(2) pulse. In the labeled ear leaf, the radioactivity strongly decreased to reach, at the end of the experiment, about 12% of the total incorporated radioactivity, mostly associated with sucrose and proteins. Nevertheless, an unexpected reincorporation of radioactivity was observed either in leaf starch or proteins, the day following the pulse. Conversely, the radioactivity in the grain increased to attain 66% of the total incorporated (14)C after a 96 hour chase. The photosynthates, mostly sucrose, organic and free amino acids, rapidly translocated towards the developing seeds, served as precursors for the synthesis of seed storage compounds, starch, and proteins. They accumulate in free form for 24 hours before being incorporated within polymerized storage components. This delay is interpreted as a necessary prerequisite for interconversions prior to the polycondensations. In the grain, the labeling of the storage molecules, either in starch or in storage protein groups (salt-soluble proteins, zein, and glutelin subgroups), was independent of their chemical nature but dependent on their pool size.

Relationship between Photosynthesis and Protein Synthesis in Maize: II. Interconversions of the Photoassimilated Carbon in the Ear Leaf and in the Intermediary Organs to Synthesize the Seed Storage Proteins and Starch.

The mechanisms priming the production, the movement, and the transient and final storage of the photoassimilated carbon in the maize plant were examined at the metabolic level during the formation of the seed, with the ultimate aim to identify metabolic steps restricting grain yield and explaining the delay of formation of the reserve molecules. Under normal field conditions, we show that maize directly supplies the developing seed with the photoassimilated carbon which undergoes numerous interconversions from the ear leaf to the grain. The proteins, either in the leaf or in the seed, are primarily synthesized from incoming amino acids. Nevertheless, a secondary in situ synthesis of amino acids provides the proteins with new amino acids. The amino acids of this second set, slowly synthesized in the seed from the photosynthetic carbon skeletons, are not detected in their free form but immediately and regularly incorporated into the seed proteins, in such a way that, after 4 days of chase, the proportion of the radioactive labeling of the amino acids of the different storage protein groups corresponds to their amino acid composition. In the leaf, the labeling of proteins also arises from different metabolisms, but mainly from the photosynthetic metabolism. Contrary to the seed proteins, the time course of the labeled leaf proteins implies a rapid turnover. The second labeling of starch and proteins in the ear leaf involves a reassimilation of CO(2), a process optimizing the carbon uptake in maize.

Evidence for the Glutamine Synthetase/Glutamate Synthase Pathway during the Photorespiratory Nitrogen Cycle in Spinach Leaves.

Spinach leaf (Spinacia oleracea L.) discs infiltrated with [(15)N]glycine were incubated at 25 degrees C in the light and in darkness for 0, 30, 60 and 90 minutes. The kinetics of (15)N-incorporation into glutamine, glutamate, asparagine, aspartate, and serine from [(15)N]glycine was determined. At the beginning of the experiment, just after infiltration (0 min incubation) serine, and the amido-N of glutamine and asparagine were the only compounds significantly labeled in both light- and dark-treated leaf discs. Incorporation of (15)N-label into the other amino acids was observed at longer incubation time. The per cent (15)N-enrichment in all amino acids was found to increase with incubation. However, serine and the amido-N of glutamine remained the most highly labeled products in all treatments. The above pattern of (15)N-labeling suggests that glutamine synthetase was involved in the initial refixation of (15)NH(3) derived from [(15)N]glycine oxidation in spinach leaf discs.The (15)N-enrichment of the amino-N of glutamine was found to increase rapidly from 0 to 19% during incubation in the light. There was a comparatively smaller increase (4-9%) in the (15)N-label of the amino-N of glutamine in tissue incubated in darkness. Furthermore the total flux of (15)N-label into each of the amino acids examined was found to be greater in tissue incubated in the light than those in the dark. The above evidence indicates the involvement of the glutamine synthetase/glutamate synthase pathway in the recycling of photorespiratory NH(3) during glycine oxidation in spinach leaves.

Oxygen effect on photosynthetic and glycolate pathways in young maize leaves.

To study the effect of O(2) on the photosynthetic and glycolate pathways, maize leaves were exposed to (14)CO(2) during steady-state photosynthesis in 21 or 1% O(2). At the two O(2) concentrations after a (14)CO(2) pulse (4 seconds) followed by a (12)CO(2) chase, there was a slight difference in CO(2) uptake and in the total amount of (14)C fixed, but there were marked changes in (14)C distribution especially in phosphoglycerate, ribulose bisphosphate, glycine, and serine. The kinetics of (14)C incorporation into glycine and serine indicated that the glycolate pathway is inhibited at low O(2) concentrations. In 1% O(2), labeling of glycine was reduced by 90% and that of serine was reduced by 70%, relative to the control in 21% O(2). A similar effect has been observed in C(3) plants, except that, in maize leaves, only 5 to 6% of the total (14)C fixed under 21% O(2) was found in glycolate pathway intermediates after 60 seconds chase. This figure is 20% in C(3) plants. Isonicotinyl hydrazide did not completely block the conversion of glycine to serine in 21% O(2), and the first carbon atom of serine was preferentially labeled during the first seconds of the chase. These results supported the hypothesis that the labeled serine not only derives from glycine but also could be formed from phosphoglycerate, labeled in the first carbon atom during the first seconds of photosynthesis.Another noticeable O(2) effect concerned differential labeling of phosphoglycerate and ribulose bisphosphate. Phosphoglycerate is more labeled than ribulose bisphosphate in air; the reverse is observed in 1% O(2). Changes in ribulose bisphosphate and phosphoglycerate pools exhibit similar trends. To understand the effect of O(2) on the distribution of (14)C in these two intermediates, it was postulated that, in air, there remains an oxygenase function which produces additional phosphoglycerate at the expense of ribulose bisphosphate.