Influence of ammonium and nitrate nutrition on enzymatic activity in soybean and sunflower

Oxalate synthesis in leaves is associated with root uptake of nitrate and its assimilation in spinach (Spinacia oleracea L.) plants

BACKGROUND

Excessive accumulation of oxalate in numerous vegetables adversely affects their quality as food. While it is known that nitrate could effectively stimulate oxalate accumulation in many vegetables, little information is available about the mechanism of nitrate-induced oxalate accumulation. In this study, we examined the association of oxalate synthesis with nitrate uptake and assimilation in two genotypes of spinach (Spinacia oleracea L.), Heizhenzhu and Weilv.

RESULTS

Increasing nitrate levels resulted in enhanced synthesis of oxalate, as well as increased root uptake of nitrate and leaf activities of nitrate reductase (NR) and glutamine synthetase (GS) for both genotypes. Correlation analysis revealed that oxalate accumulation in spinach leaves was positively related with rate of nitrate uptake by roots, as well as leaf activities of NR and GS. Addition of plasmalemma H(+)-ATPase inhibitor sodium vanadate (Na3VO4) significantly decreased leaf oxalate accumulation in both genotypes. Presence of NR or GS inhibitors led to reduction of leaf oxalate contents, GS/NR activities and decreased nitrate uptake rate. Significantly higher levels of nitrate root uptake, leaf NR and GS activities were observed in the high-oxalate genotype Heizhenzhu than in Weilv.

CONCLUSION

Oxalate synthesis in leaves of spinach is not only positively associated with root uptake of nitrate, but also with its assimilation within the plants.

Oats Tolerant of Pseudomonas syringae pv. tabaci Contain Tabtoxinine-beta-Lactam-Insensitive Leaf Glutamine Synthetases

Pseudomonas syringae pv. tabaci, a commonly recognized leaf pathogen of tobacco, can infest the rhizosphere of many plants, including oats. Normal oat plants do not survive this infestation as a consequence of the complete and irreversible inactivation of all of their glutamine synthetases by tabtoxinine-beta-lactam (TbetaL), a toxin released by pv. tabaci. We have identified a population of oat (Avena sativa L. var Lodi) plants that are tolerant of pv. tabaci. The tolerant plants had no detectable TbetaL-detoxification mechanisms. Pathogen growth on these plant roots was not inhibited. These plants contain leaf glutamine synthetases (GS(1) and GS(2)) that were less sensitive to inactivation by TbetaL in vitro; these GSs have normal K(m) values for glutamate and ATP when compared with those of GS in control plants. Root glutamine synthetase of the tolerant plants was inactivated in vivo during infestation by the pathogen or by TbetaL in vitro. When growing without pv. tabaci, the tolerant plants contained normal levels of glutamine synthetase in their roots and leaves and normal levels of protein, ammonia, glutamate, and glutamine in their leaves. However, when the tolerant plants' rhizosphere was infested with pv. tabaci, the plant leaves contained elevated levels of glutamine synthetase activity, protein, ammonia, glutamate, and glutamine. No changes in glutamate dehydrogenase activity were detected in leaves and roots of pathogen-infested tolerant plants.

A study of the role of glutamate dehydrogenase in the nitrogen metabolism of Arabidopsis thaliana

Glutamate-dehydrogenase (GDH, EC 1.4.1.2) activity and isoenzyme patterns were investigated in Arabidopsis thaliana plantlets, and parallel studies were carried out on glutamine synthetase (GS, EC 6.3.1.2). Both NADH-GDH and NAD-GDH activities increased during plant development whereas GS activity declined. Leaves deprived of light showed a considerable enhancement of NADH-GDH activity. In roots, both GDH activities were induced by ammonia whereas in leaves nitrogen assimilation was less important. It was demonstrated that the increase in GDH activity was the result of de-novo protein synthesis. High nitrogen levels were first assimilated by NADH-GDH, while GS was actively involved in nitrogen metabolism only when the enzyme was stimulated by a supply of energy, generated by NAD-GDH or by feeding sucrose. When methionine sulfoximine, an inhibitor of GS, was added to the feeding solution, NADH-GDH activity remained unaffected in leaves whereas NAD-GDH was induced. In roots, however, there was a marked activation of GDH and no inactivation of GS. It was concluded that NADH-GDH was involved in the detoxification of high nitrogen levels while NAD-GDH was mainly responsible for the supply of energy to the cell during active assimilation. Glutamine synthetase, on the other hand was involved in the assimilation of physiological amounts of nitrogen. A study of the isoenzyme pattern of GDH indicated that a good correlation existed between the relative activity of the isoenzymes and the ratio of aminating to deaminating enzyme activities. The NADH-GDH activity corresponded to the more anodal isoenzymes while the NAD-GDH activity corresponded to the cathodal ones. The results indicate that the two genes involved in the formation of GDH control the expression of enzymes with different metabolic functions.

The supply of reducing power for nitrite reduction in plastids of seedling pea roots (Pisum sativum L.)

Plastids were separated from extracts of pea (Pisum sativum L.) roots by sucrose-density-gradient centrifugation. The incubation of roots of intact pea seedlings in solutions containing 10 mM KNO3 resulted in increased plastid activity of nitrite reductase and to a lesser extent glutamine synthetase. There were also substantial increases in the activity of glucose-6-phosphate and 6-phosphogluconate dehydrogenases. No other plastid-located enzymes of nitrate assimilation or carbohydrate oxidation showed evidence of increased activity in response to the induction of nitrate assimilation. Studies with [1-(14)C]-and [6-(14)C]glucose indicated that there was an increased flow of carbon through the plastid-located pentose-phosphate pathway concurrent with the induction of nitrate assimilation. It is suggested that there is a close interaction through the supply and demand for reductant between the pathway of nitrite assimilation and the pentose-phosphate pathway located in the plastid.

Nitrate Reductase Activity in Shoots and Roots of Maize Seedlings as Affected by the Form of Nitrogen Nutrition and the pH of the Nutrient Solution

The effect of nitrogen form (NH(4)-N, NH(4)-N + NO(3) (-), NO(3) (-)) on nitrate reductase activity in roots and shoots of maize (Zea mays L. cv INRA 508) seedlings was studied. Nitrate reductase activity in leaves was consistent with the well known fact that NO(3) (-) increases, and NH(4) (+) and amide-N decrease, nitrate reductase activity. Nitrate reductase activity in the roots, however, could not be explained by the root content of NO(3) (-), NH(4)-N, and amide-N. In roots, nitrate reductase activity in vitro was correlated with the rate of nitrate reduction in vivo. Inasmuch as nitrate reduction results in the production of OH(-) and stimulates the synthesis of organic anions, it was postulated that nitrate reductase activity of roots is stimulated by the released OH(-) or by the synthesized organic anions rather than by nitrate itself. Addition of HCO(3) (-) to nutrient solution of maize seedlings resulted in a significant increase of the nitrate reductase activity in the roots. As HCO(3) (-), like OH(-), increases pH and promotes the synthesis of organic anions, this provides circumstantial evidence that alkaline conditions and/or organic anions have a more direct impact on nitrate reductase activity than do NO(3) (-), NH(4)-N, and amide-N.

Nitrate Reduction by Roots of Soybean (Glycine max [L.] Merr.) Seedlings

Studies were conducted with 9 to 12 day-old soybean (Glycine max [L.] Merr. cv. Williams) seedlings to determine the contribution of roots to whole plant NO(3) (-) reduction. Using an in vivo -NO(3) (-) nitrate reductase (NR) assay (no exogenous NO(3) (-) added to incubation medium) developed for roots, the roots accounted for approximately 30% of whole plant nitrate reductase activity (NRA) of plants grown on 15 mm NO(3) (-).Nitrogen analyses of xylem exudate showed that 53 to 66% of the total-N was as reduced-N, depending on the time of day of exudate collection. These observations supported enzyme data that suggested roots were contributing significantly to whole plant NO(3) (-) reduction. In short-term feeding studies using (15)N-NO(3) (-) significant and increasing atom percent (15)N excess was found in the reduced-N fraction of xylem exudate at 1.5 and 3 hours after feeding, respectively, which verified that roots were capable of reducing NO(3) (-).Estimated reduced-N accumulation by plants based on in vivo -NO(3) (-) NR assays of all plant parts substantially over-estimated actual reduced-N accumulation by the plants. Thus, the in vivo NR assay cannot be used to accurately estimate reduced-N accumulation but still serves as a useful assay for relative differences in treatment conditions.

Restricted nitrate influx and reduction in corn seedlings exposed to ammonium

The effect of ambient ammonium (0.5 millimolar [(14)NH(4)](2)SO(4)) added to a nutrient solution containing 1.0 millimolar K(15)NO(3), 99 atom per cent (15)N, upon [(15)N]nitrate assimilation and utilization of previously accumulated [(14)N]nitrate was investigated. Corn seedlings, 5-day-old dark-grown decapitated (experiment I) and 10-day-old light-grown intact (experiment II), which had previously been grown on K(14)NO(3) nutrient solution, were used. In both experiments, the presence of ambient ammonium decreased [(15)N]nitrate influx (20% after 6 hours) without significantly affecting the efflux of previously accumulated [(14)N]nitrate. In experiment I, relative reduction of [(15)N]nitrate (reduction as a percentage of influx) was inhibited more than was [(15)N]nitrate influx. Nevertheless, in experiment I, where all reduction could be assigned to the root system, the absolute inhibition of reduction during the 12 hours (13 micromoles/root) was less than the absolute inhibition in influx (24 micromoles/root). The data suggest that the influence of ammonium on [(15)N]nitrate influx could not be totally accounted for by the decrease in the potential driving force which resulted from restricted reduction; an additional impact on the influx process is indicated. Reduction of [(15)N]nitrate in experiment II after 6 hours accounted for 30 and 18% of the tissue excess (15)N in the control and ammonium treatments, respectively. Relative distribution of (15)N between roots and exudate (experiment I), or between roots and shoots (experiment II) was not affected by ammonium. On the other hand, the accumulation of [(15)N]nitrate in roots, shoots, and xylem exudate was enhanced by ammonium treatment compared to the control, whereas the accumulation of reduced (15)N was inhibited.

Enzymes of nitrogen assimilation in maize roots

The enzymes nitrate reductase (NR), glutamate dehydrogenase (GDH), glutamate synthase (GOGAT), glutamine synthetase (GS) and asparagine synthetase (AS) have been assayed in various regions along the seedling root ofZea mays L. In the intact attached root and calculated on a protein basis NR, GOGAT, and GS are found to have slightly higher specific activities in the apical 5 mm than in more mature regions of the root. GDH and AS, on the other hand, are much more active in extracts prepared from mature regions of the root than in the apical region. In excised root tips incubated in the presence of NH4 (+) and NO3 (-) there was a marked increase in GDH and AS, and a slight decrease in GOGAT and GS. Additions of NO3 (-) are required for NR activity but neither NO3 (-) nor NH4 (+) additions altered the activity levels of the other four enzymes. Additions of glucose to the medium inhibited the development of AS and GDH activities and resulted in higher activity levels of NR, GS and GOGAT. Glucose additions also enhanced the incorporation of acetate-(14)C and leucine-(14)C into protein. Additions of cycloheximide inhibit the development of NR, AS and GDH activities and also the incorporation of acetate-(14)C and leucine into protein.

Enzymes of nitrogen assimilation in maize roots

The enzymes nitrate reductase (NR), glutamate dehydrogenase (GDH), glutamate synthase (GOGAT), glutamine synthetase (GS) and asparagine synthetase (AS) have been assayed in various regions along the seedling root ofZea mays L. In the intact attached root and calculated on a protein basis NR, GOGAT, and GS are found to have slightly higher specific activities in the apical 5 mm than in more mature regions of the root. GDH and AS, on the other hand, are much more active in extracts prepared from mature regions of the root than in the apical region. In excised root tips incubated in the presence of NH4 (+) and NO3 (-) there was a marked increase in GDH and AS, and a slight decrease in GOGAT and GS. Additions of NO3 (-) are required for NR activity but neither NO3 (-) nor NH4 (+) additions altered the activity levels of the other four enzymes. Additions of glucose to the medium inhibited the development of AS and GDH activities and resulted in higher activity levels of NR, GS and GOGAT. Glucose additions also enhanced the incorporation of acetate-(14)C and leucine-(14)C into protein. Additions of cycloheximide inhibit the development of NR, AS and GDH activities and also the incorporation of acetate-(14)C and leucine into protein.

Interrelationships between carbohydrate metabolism and nitrogen assimilation in cultured plant cells : III. Effect of the nitrogen source on the pattern of carbohydrate oxidation in cells of Acer pseudoplatanus L. grown in culture

In sycamore cells grown on nitrate as opposed to glutamate there is a higher pentose phosphate pathway carbon flux relative to glycolysis in the early stages of cell growth when nitrate assimilation is most active. The high pentose phosphate pathway activity compared with glycolysis in nitrate grown cells is accompanied by enhanced levels of hexokinase, pyruvate kinase, glucose-6-phosphate de-hydrogenase, 6-phosphogluconate dehydrogenase and transketolase. There is no significant increase in activity of the solely glycolytic enzyme, phosphofructokinase. It is suggested that the increased pentose phosphate pathway activity in nitrate grown cells is correlated with a demand by nitrite assimilation for NADPH.

Glutamine synthetase regulation by energy charge in sunflower roots

Energy charge [(ATP) + (1/2) (ADP)]/[(ATP) + (ADP) + (AMP)] and glutamine synthetase activity (transferase reaction) of roots increase in a near congruent manner when decotyledonized sunflower plants (Helianthus annuus L. var. Mammoth Russian) are grown in nitrate for 9 days. Replacement of nitrate with ammonium for the final 2 days leads to a higher energy charge and increased enzyme activity. Similar correlations occur when nitrate plants are placed on a zero nitrogen regimen and when they are subjected to continuous darkness. A rank order correlation of 0.72 is obtained for all data. Control concepts such as adenylylation-deadenylylation and ammonium inhibition of enzyme synthesis are not supported by the data. Energy charge-enzyme activity plots support the view that glutamine synthetase of sunflower roots is subject to control by end products of glutamine metabolism. Alanine appears to exert a modulating effect on the regulation of glutamine synthetase by energy charge.

Interrelationships between carbohydrate metabolism and nitrogen assimilation in cultured plant cells : I. Effects of glutamate and nitrate as alternative nitrogen sources on cell growth

Suspension cultured sycamore (Acer pseudoplatanus L.) cells will grow with either nitrate or glutamate as sole nitrogen source. Under the particular culture conditions used, cell growth is nitrogen limited. Within the range of initial nitrogen concentrations used (7-14 mM), cell growth on nitrate or glutamate at the same initial nitrogen concentrations is generally comparable. The rate of cell growth on these two nitrogen sources is also comparable with that observed when urea or urea plus nitrate is the prime nitrogen source. Increased nitrogen concentrations result in proportional increases in the final yield of numbers of cells, soluble protein and fresh weight. Dry weight yield by contrast shows both an absolute and relative decline with increasing nitrogen concentrations. At higher initial nitrogen concentrations differences are apparent in the pattern of cell growth between nitrate and glutamate grown cells.

Interrelationship between nitrate assimilation and carbohydrate metabolism in plant roots

The effect of nitrate incubation on the pattern of carbohydrate metabolism in different regions of the pea (Pisum sativum L. var. Kelvedon Wonder) root has been studied. Roots were incubated in a 10 mM potassium nitrate solution for 4, 8 and 12 h. Marked increases were noted in the activities of nitrate assimilation enzymes after 4 h. Increased activities were also recorded for hexokinase, pyruvate kinase, glucose-6-phosphate dehydrogenase, 6-phosphogluconate dehydrogenase and transketolase. No consistent changes were observed in the activities of phosphofructokinase and glyceraldehyde-3-phosphate dehydrogenase. Experiments with [1-(14)C] and [6-(14)C]glucose indicated a relative shift in the pattern of carbohydrate oxidation from glycolysis to the pentose phosphate pathway. The data are interpreted as indicating a close interrelationship between nitrate assimilation and carbohydrate metabolism, particularly in relation to the supply of NADPH by the pentose phosphate pathway for nitrite reductase.

The influence of inorganic nitrogen supply on carbohydrate and related metabolism in the blue-green alga, Anabaena cylindrica Lemm

Enzymes representative of, and related to, the pentose phosphate pathway, glycolysis, and the tricarboxylic acid cycle have been demonstrated in supernatant and lamellar fractions of Anabaena cylindrica cultured in the presence of atmospheric nitrogen, ammonia, nitrite, and nitrate. Nitrogen-fixing and ammonia-assimilating algae contained essentially similar levels of most enzymes tested, with the notable exception of glyceraldehyde-3-phosphate dehydrogenase which showed increased NADPH-linked activity with concomitant diminution of NADH-linked activity when ammonia was supplied. The provision of nitrite or nitrate caused significant enhancements of glucose-6-phosphate dehydrogenase, 6-phosphogluconate dehydrogenase, and the related hexokinase and phosphohexoisomerase. Reduced activities of pyruvate kinase, malate dehydrogenase, phosphoenolpyruvate carboxylase, and both NADH and NADPH oxidoreductases were recorded for nitrate-grown alga.The stimulation of the pentose phosphate pathway, at the partial expense of glycolysis and the tricarboxylic acid cycle, in algae cultured with nitrite and nitrate was interpreted to be due to additional NADPH requirements imposed by induced nitrite reductase. Modification of the pyridine nucleotide linkage of glyceraldehyde-3-phosphate dehydrogenase and the oxidoreductases was attributed to diversion of reductant to nitrite and nitrate reductases and nitrogenase. The results are considered to indicate regulation of blue-green algal metabolism determined by the availability of pyridine nucleotides.

[Organ specific multiple forms of glutamic dehydrogenase in Medicago sativa]

The alteration of the multiple forms of NAD-dependent glutamic dehydrogenase (GDH) during the development of Medicago sativa is investigated by means of polyacrylamide electrophoresis. Seed germination is accompanied by a characteristic change of the GDH-isoenzyme pattern. Seeds contain seven isoenzymes, which gradually decrease in number during germination. At the same time a pattern of new isoenzymes becomes visible. The seed pattern is called GDH-I and the later appearing pattern GDH-II. GDH-I is characteristic for the cotyledons, whereas GDH-II is the typical pattern of the root system. Shoots produce a mixed pattern composed of the GDH-II isoenzymes as well as some GDH-I isoenzymes.These isoenzyme patterns are organ specific. No qualitative change occurs during further development of the plants and during growth in the presence of different inorganic and organic N-sources in the culture medium.All the individual isoenzymes are found predominantly in the particulate fraction. They represent stable forms which are not altered by variation of the conditions of enzyme extraction or during enzyme purification. Re-electrophoresis of the individual isoenzymes following elution from the polyacrylamide gels reveals only one specific band. The molecular weights of all the distinctive isoenzymes are identical.There is some evidence that the different isoenzymes represent conformational forms of one enzyme, and it is postulated that the GDH-I isoenzymes are correlated to a normal metabolic (or catabolic) function of the enzyme, whereas the GDH-II isoenzymes are responsible for a primarily anabolic function of glutamic dehydrogenase.

Influence of ammonium and nitrate nutrition on the pyridine and adenine nucleotides of soybean and sunflower

Total pyridine nucleotide concentration of root tissue for young soybean (Glycine max var. Bansei) and sunflower (Helianthus annuus L. var. Mammoth Russian) plants is the same with either ammonium or nitrate, but nitrate results in an increased proportion of total oxidized plus reduced NADP (NADP[H]) seemingly at the expense of NAD. The activity of NADH- and NADPH-dependent forms of glutamic acid dehydrogenase is correlated with the ratio of total oxidized plus reduced NAD to NADP(H). The low NAD: NADH ratio maintained in nitrate roots despite active NADH utilization via nitrate reductase and glutamic acid dehydrogenase may be the result of nitrate-stimulated glycolysis. Nitrate roots also maintain a high level of NADPH, presumably by the stimulatory effect of nitrate utilization on glucose-6-phosphate dehydrogenase activity. In the presence of nitrate rather than ammonium, the highly active nitrate-reducing leaves of soybean show a greater proportion of total pyridine nucleotide in the form of NADP(H) than do the inactive leaves of sunflower.For all tissues examined, ammonium nutrition yields a higher concentration of total adenine nucleotide than is found with nitrate. The data indicate the production of a higher level of metabolites that enter into purine synthesis with ammonium than with nitrate. Glutamine synthetase activity can be correlated with the concept that enzymes utilizing ATP for biosynthetic purposes increase in activity in accordance with the energy level of the cell.