Enzymes of purine catabolism in soybean plants

Remarkable formation and utilization of allantoin is observedin soybean (Glycine max variety A62-1). To study this, variousenzymes involved in purine catabolism (i.e., xanthine oxidase,uricase and allantoinase) were measured in different regionsof soybean plants during development. Uricase, which catalyzesthe direct formation of allantoin from uric acid, was studiedin detail. The activities of these three enzymes were highest in the rootnodules, indicating that the nodules are the major site of allantoinmetabolism. Radicles only showed appreciable activity about80 hr after the seeds were planted. Allantoinase activity wasdetected in all regions tested, showing that allantoin translocatedfrom the nodules can be metabolized in the roots, stem and leaves.In the nodules, xanthine oxidase was localized in the nuclearfraction, while uricase was mainly restricted to the mitochondrialfraction and allantoinase to the soluble fraction. Uricase was partially purified from the nodules and radicles,respectively. The pH optimum of enzyme from the nodules was9.5, whereas that of enzyme from the radicles was 7.0. The enzymefrom the nodules did not require a cofactor, while that fromthe radicles showed an absolute requirement for a cofactor,which was a low molecular substance easily separable from theapoprotein. Thus, the uricase in nodules differs in chemicalproperties from that in the host plant. The results are discussedin relation to change in the allantoin level in soybean tissues. (Received November 1, 1974; )     

Effect of water stress on some enzymes of nitrogen metabolism in pigeonpea

Water stress created by withholding irrigation at flowering stage (70 days) in pigeonpea resulted in decreased water potential of roots,nodules and leaves. The decreased water potential in nodules resulted in decreased activities of nitrogenase, glutamine synthetase, glutamate dehydrogenase and uricase. However, the activity of allantoinase increased under mild stress with a slight decrease under severe stress. This corresponded with a simultaneous increase in allantoic acid content. Uricase and allantoinase could not be detected in roots and leaves of both control and stressed plants. In roots, the activities of GS and GDH decreased under stress, whereas in leaves, their activities were not affected. Although the water potential recovered in different organs of the stressed plant on re-irrigation, the recovery in the case of some enzymes was not complete.     

Effect of hydro- and osmopriming of chickpea (Cicer arietinum L.) seeds on enzymes of sucrose and nitrogen metabolism in nodules

Three year data on the effect of water- and mannitol (4%) priming of chickpea seeds (12 h at 25°C) showed higher number and biomass of nodules in the plants from primed seeds than from non-primed seeds. The biomass of nodules increased to 75 DAS but decreased by 90 DAS. Activities of sucrose metabolism enzymes (sucrose synthase (SS) and alkaline invertase) and of nitrogen metabolism (glutamine synthetase (GS), glutamate synthase (GOGAT) and glutamate dehydrogenase (GDH)) in nodules of primed and non-primed crops during development are reported. SS and alkaline invertase activities increased to 70 DAS and then decreased. In primed plants, the higher SS activity in nodules at 60 and 70 DAS might be responsible for providing more energy and carbon skeleton for nitrogen fixation and for ammonium assimilation in primed plants. At 85 DAS, though the SS activity decreased in comparison with the earlier growth stages, it was still higher in nodules of the primed crops than the non-primed crop. Activity of alkaline invertase was maximum at 70 DAS in the nodules of primed and non-primed crops. Priming increased nodule GS activity at 70 and 85 DAS. GOGAT activity was unaffected by priming but GDH activity was greater in nodules from primed crops at 50 DAS. Elevated SS and GS nodule activities in primed chickpeas might be responsible in increasing nodule biomass and metabolic activity thereby increasing seed fill.     

Effect of Nitrogen on Nitrate Reductase Activity in the Nodules and Leaves of Summer Moong (Vigna radiata)

The relation of the in vivo nitrate reductase (NR) activityto growth period was studied in the nodules and the leaves ofthe summer moong (Vigna radiata). The maximum NR activity wasobserved 31 days after sowing (DAS) in the leaves and 28 DASin the case of the nodules. In a pot experiment, the effectof the various nitrogen concentrations, namely 0, 3, 6, 9 and12 mg kg^–1 was studied on NR activity at three growthstages. The maximum NR activity was observed at 6 mg kg^–1N during the pre-flowering stage (26 DAS). Though the noduleshave higher NR activity, its expression was limited by substrateavailability. The NR activity in the leaf could be used as anindex of NR activity in the nodules. Nitrate reductase, nitrogen, nitrate, moong, Vigna radiata     

Growth and Metabolism of Senna as Affected by Salt Stress

Pot culture experiments were conducted using different NaCl concentrations to assess their impact on the growth and metabolic changes in senna (Cassia angustifolia Vahl.). Five treatments (0, 40, 80, 120, and 160 mM NaCl) were given to the plants at three phenological stages, i.e. at pre-flowering, (45 days after sowing, DAS); flowering (75 DAS) and post-flowering (90 DAS) stages. A significant reduction in the biomass and length of the roots and shoots, photosynthetic rate, stomatal conductance, the total chlorophyll content, protein content, nitrate reductase activity, and reduced nitrogen content of the leaves was observed at each phenological stage with each salt concentration applied. Contrary to this, proline and nitrate contents of the leaves increased markedly. The post-flowering stage was most sensitive to NaCl treatment.     

Ontogenetic interactions between photosynthesis and symbiotic nitrogen fixation in pigeonpea

Total nodule nitrogenase activity (TNA, μmols ethylene plant^-1 h^-1) in pigeonpea (Cajanus cajari) increased with plant growth to reach maximum at flowering (75 days after sowing), decreasing thereafter until maturity (120 days after sowing). However, specific nodule nitrogenase activity (SNA, μmols ethylene g^-1 nodule fresh wt h^-1) reached its maximum earlier (45 days after sowing). The rate of photosynthesis and shoot and nodule respiration followed a similar pattern to TNA. However, higest rates of root respiration were observed at flowering and again immediately before final harvest. ¹⁴CO₂ feeding studies showed that assimilates produced in leaves before flowering were retained in the vegetative parts. Assimilates produced after flowering were exported to the reproductive structure at the expense of the nodules. It is suggested that the decreased availability of photosynthate to nodules decreased nitrogen fixation.     

Ammonia Assimilation in Canavalia ensiformis Plants under Water and Salt Stress

Nitrogen fixation and ammonia assimilation in nodules have beenthoroughly studied under stress conditions, but the behaviorof enzymes involved in ammonia assimilation to organic compoundsin plants of the Leguminosae family subjected to stress stillremains to be conclusively established. We found that understress conditions, C. ensiformis plants can switch from theirusual pathway of assimilation to an alternative one dependingon the nature of the stress and the tissue in which the processtakes place. In roots, it switches from the glutamate dehydrogenase(GDH) pathway to the glutamine synthetase (GS)/glutamate synthase(GOGAT) cycle under water stress but not under salt stress.However, in leaves under salt stress, GDH activity is maintainedbut GS activity markedly decreases (Received March 24, 1987; Accepted March 4, 1988)     

The Assimilation of Ureides in Shoot Tissues of Soybeans : 1. CHANGES IN ALLANTOINASE ACTIVITY AND UREIDE CONTENTS OF LEAVES AND FRUITS

The ureides, allantoin and allantoic acid, are major forms of N transported from nodules to shoots in soybeans (Merr.). Little is known about the occurrence, localization, or properties of the enzymes involved in the assimilation of ureides in shoot tissues. We have examined the capacity of the shoot tissues to assimilate allantoin via allantoinase (EC 3.5.2.5) during leaf and fruit development in nodulated soybeans. Specific activity of allantoinase in leaves peaked during pod formation and early seed filling. In developing fruits allantoinase activity in the seeds was 2 to 4 times that in the pods when expressed on a fresh weight or organ basis. In seeds, the embryos contained the highest specific allantoinase activity. Stems and petioles also had appreciable allantoinase activity. With development, peaks in the amounts of allantoic acid, but not allantoin, were measured in both leaves and fruits suggesting that the assimilation of allantoic acid may be a limiting factor in ureide assimilation. Highest amounts of ureides were measured in the pith and xylem of stem tissues and in developing pod walls.     

Appearance of different phosphatase forms and phosphorus partitioning in nodules of chickpea (Cicer arietinum L.) during development

Acid and alkaline phosphatase and phytase activities were determined in the bacteroid free fractions of chickpea (Cicer arietinum L.) nodules at 15 days intervals, from 40 days after sowing (DAS) to 85 DAS. In general, the activities and specific activity of both the acid and alkaline phosphatases declined at 55 DAS. Out of the various substrates studied, ATP was the best substrate for both phosphatases. Activities of phosphatases with glucose-6-phosphate and fructose-6-phosphate were low in comparison to these with fructose 1,6 bisphosphate. The efficiency of acid phosphatase for utilizing fructose 1,6 bis phosphate as a substrate increased with nodule development. A fructose 1,6 bis phosphate specific acid phosphatase with elution volume to void volume (Ve/Vo) ratio of around 2.0 was observed in mature nodules (80 DAS). Acid phosphatase at 40 DAS was resolved into two peaks which were eluted at Ve/Vo of about 1.5 and 1.8. However, at 60 DAS the peak with Ve/Vo of 1.5 could not be detected. With ATP as substrate, a high (Ve/Vo of 1.2) and low MM form (Ve/Vo of 2.1) alkaline phosphatases were observed at 40 DAS however at 60 DAS stage only one peak with Ve/Vo of 1.7 was detected. Although, a low activity of acid phytase was observed in nodules at all stages of development but neither alkaline phytase nor phytic acid could be detected. It appears that the nodules acquire inorganic phosphate from the roots. The higher content of water soluble organic phosphorus in mature nodules could be due to the low activities of phosphatases at maturity.     

Partitioning of Carbon and Nitrogen During Growth and Development of Pigeonpea (Cajanus cajan L.)

Budgets for C and N were computed for pigeonpea (Cajanus cajanL.) at 15 d intervals, for the entire life cycle. Maximum Cand N in dry matter was observed at 90 d after sowing. Of theplants total respiratory loss during the vegetative phase, shoots,roots and nodules accounted for 65%, 23% and 12%, respectively.During the reproductive phases, the respiratory burden of theroots increased, while that of shoots and nodules decreased.Total respiratory loss as a proportion of net photosynthateremained more or less constant until ‘flowering and pod-setting’but increased heavily during seed filling, losing nearly 75%of the photosynthate in respiration. The efficiency of nitrogenfixation, in relation to respiratory output of the whole plantand nodulated roots, decreased during the period 60–90d after sowing, while that of nodules decreased from day 45onwards. Photosynthate supply to nodules and nodulated rootsincreased up to 75 d and 90 d after sowing, respectively. During45–90 d, nodules were fixing a constant proportion ofN per unit of C translocated (0.2 mg N mg^–1 C). Nodulatedroots, on an average, fixed 0.07 mg N mg^–1 C translocatedin the vegetative phase and this value decreased considerablyduring the subsequent phases. The crop produced during its lifecycle 50.4 g of glucose equivalents and yielded 3.8 g seed drymatter and 0.8 g seed protein giving an average of 13.2 g g^–1seed dry matter and 62.8 g g^–1 seed protein. Selectioncriteria for the improvement of C, N economy in pigeonpea havebeen suggested. Key words: Cajanus cajan, Carbon, Nitrogen, Dry weight, Plant parts, Growth, Development, Models     

Partitioning and Utilization of Carbon and Nitrogen for Dry Matter and Protein Production in Chickpea (Cicer arietinum L.)

The partitioning of N and utilization of C in various processesin chickpea (Cicer arielinum L.) was studied at 10 d intervalsfrom 35 to 135 d after sowing (DAS). Dry matter, C and N contentof the plant increased throughout the study period. The maximumamounts of C and N were fixed during the flowering and earlyfruiting phase (75–115 DAS) and the minimum during theseed filling phase (115–135 DAS). Efficiency of nitrogenfixation in relation to net C utilization and respiratory outputof the whole plant, nodules and nodulated root, varied widely,but was maximum during 75–115 DAS. The crop experiencedsevere respiratory losses, particularly during the vegetativephase, when 83% of the total fixed C was lost in respiration.The crop produced 54·6 g of glucose units, 2·36g of seed dry matter and 495 mg of seed protein. Possible reasonsfor the poor efficiency of chickpea, in terms of photosynthateutilization for dry matter and protein production are discussed. Key words: Cicer arietinum, C, N, economy     

Symbiotic nitrogen fixation and physiological performance of bean (Phaseolus vulgaris L.) plants as affected by Rhizobium inoculum position and bean rugose mosaic virus infection

Bean (Phaseolus vulgaris L. var. Tacarigua) plants were grownin sterilized Leonard jars under controlled conditions. Beforesowing, 1 g of gamma irradiated peat containing the Rhizobiumtropici strain CIAT899 was placed at either 2 or 10 cm belowthe sand surface. Mechanical infection of bean rugose mosaicvirus (BRMV) was carried out in 3-d-old seedlings. Thus, theearly events of nodulation occurred before the arrival of virusparticles to roots. Rhizobium inoculation at 2 cm deep resultedin the formation of nodule clusters close to the crown, in contrastto the homogeneous nodulation along the roots observed in plantsinoculated with Rhizobium at a depth of 10 cm. The uniform arrangementof nodules on the roots enhanced the plant shoot biomass, althoughthe total nodule mass per plant did not differ between Rhizobiuminoculation treatments. Nodules located on deeper roots resultedin higher ureide concentrations in shoots and leaves and inreduced carbohydrate concentrations in leaves. In healthy plants,nodules formed on deeper roots had higher allantoinase activityand a greater carbohydrate concentration when compared to thatof nodules located close to the crown. Deeper nodules had ureideconcentrations similar to those of upper nodules, probably asa consequence of increased translocation of N-compounds to aerialorgans. A similar pattern of nodule formation and response toinoculum position was observed in BRMV-infected plants at allharvests. However, virus infection resulted in reduced totalnodule mass, shoot biomass, total leaf area and induced transitoryalterations in the ureide, -amino-N and carbohydrate concentrationin the different plant compartments. The effect of BRMV infectionon plant parameters was more evident during the vegetative stagesof growth. Nevertheless, the magnitude of the effect was alwaysmore pronounced in plants inoculated with Rhizobium at a depthof 2 cm compared to those Inoculated at 10 cm due to a greateractivity of deeper nodules despite virus infection. Deeper nodulesin BRMV-infected plants showed higher carbohydrate concentrationas well as higher allantoinase and uricase activity than thosedeveloped close to the crown, at all harvests. This observationwas further supported by ultrastructural analysis of virus-infectednodules, since virus replication took place in cells containingbacteroids of upper and lower nodules, but only in the interstitialcells of the latter. BRMV infection did not hinder the allantoinaseactivity and the chlorophyll content of uppermost mature leavesregardless of inoculum position. At the flowering and fruitingstages, healthy and BRMV-infected plants did not differ withregard to any of the tested parameters. Only inoculum positionhad an effect. The nearly normal functioning of the symbioticprocess at these stages of growth was attributed to the formationof a new generation of nodules in BRMV-infected plants subjectedto each of the Rhlzobium inoculation treatments. Key words: Bean rugose mosaic virus, symbiotic nitrogen fixation, bean, Rhizobium inoculum position, nodule ultrastructure     

Mobilization of Nitrogen in Fruiting Plants of a Cultivar of Cowpea

Patterns of flow of nitrogen were constructed for the post-anthesisdevelopment of symbiotically-dependent cowpea (Vigna unguiculataWalp. cv. Vita 3-Rhizobium CB756). Nitrogen fixed after floweringcontributed 40% of the fruits' total intake of N, mobilizationof N fixed before flowering the remaining 60%. Leaflets, nodulatedroot, stem plus petioles, and peduncles contributed mobilizedN in the approximate proportions 5: 2: 1: 1 respectively. Eachfruit drew on all available current sources of N, but N fromleaves was distributed preferentially to closest fruit(s), andlower fruits monopolized the N exported from nodulated rootsduring late fruiting. Rates of nitrogen fixation declined parallel with decreasingnet photosynthesis of shoots. Leaflets at upper reproductivenodes mobilized 70–77% of their N and declined steeplyin net photosynthesis rate per unit chlorophyll or per unitribulose-l, 5-bisphosphate carboxylase (RuBPCase)² before abscisingduring mid- to late fruiting, whereas leaflets at lower vegetativenodes (1–3) mostly failed to abscise, lost 44–57%of their N and maintained photosynthetic activity throughoutfruiting. Peptide hydrolase activity was examined in extracts of leaflets,roots and nodules, by autodigestion of extracts, or in assaysusing bovine haemoglobin and purified RuBPCase isolated fromcowpea as substrates. Hydrolase activities during fruiting werebroadly related to N loss from plant organs, but asynchronyin peaks of activity against different protein substrates indicateddistinct groups of hydrolases within single organs. Hydrolaseactivity of leaflet extracts against RuBPCase was highly andpositively correlated with in vivo rates of loss of RuBPCasefrom the same leaflets, and preferential degradation of thisprotein occurred during leaflet senescence. Key words: Nitrogen, Mobilization: Cowpea     

Distribution and change in the contents of allantoin and allantoic acid in developing nodulating and non-nodulatng soybean plants

Distribution and change in contents of allantoin¹ in each organof nodulating variety, A62-1, and non-nodulating variety, A62-2,of soybean plants were measured over the growth period, andthe physiological significance of allantoin in soybean plantsis discussed. Allantoin in the cotyledons of both varieties increased andthen decreased in the germination stage. The allantoin levelin stems, roots and nodules of A62-1 was raised with the growthand attained a maximum at the green pod stage and then decreased.On the other hand, those organs of A62-2 accumulated littleallantoin over the growth period. The allantoin level in thestems of A62-1 was the highest compared with other organs. Inthe leaves of A62-1, the level was higher in the developingleaves than lower mature leaves. The level decreased just beforethe end of leaf development and became trace in the lower fullydeveloped leaves. The allantoin level in the pods of A62-1 duringthe young stage was fairly high; whereas that of A62-2 was lowbut significant, and then decreased with maturing. The dry seedsin both varieties showed low levels. Allantoin was concluded to be accumulated in roots and stemsof developing soybean plants bearing nodules and then decreasedin the stage of seed formation. ¹ In this article the sum of allantoin and allantoic acid ismeasured. Therefore, the expression "allantoin" in the textand abstract includes allantoic acid. (Received August 19, 1976; )     

Effective Nodulation of Micro-Propagated Shoots of the Non-Legume Parasponia andersonii by Bradyrhizobium

Stem explants of the non-legume Parasponia andersonii producedcallus which regenerated shoots when cultured on a high-cytokinin,Murashige and Skoog (1962) -based medium. After transfer toa high auxin containing medium followed by P medium (Benderand Rolfe, 1985), the shoots produced roots which developedeffective nodules when inoculated with Bradyrhizobium. Key words: Parasponia andersonii, micro-propagation, Bradyrhizobium, root nodules, acetylene reduction     

Changes in the Levels of Endogenous Growth Regulators during Development of the Flowers of Chrysanthemum morifolium

Gibberellin-like substances and an auxin similar to IAA weredetected by bioassays in extracts of flowers of Chrysanthemummorifolium. The activity of these substances was shown to reacha maximum early in the development of the flower when its relativegrowth-rate was at a maximum, and then to decline with the relativegrowth-rate. The leaves of lateral flowering shoots were found to containgibberellins similar to those detected in the flowers whilea different gibberellin, which appeared to decrease in activitywith the age of the shoot, was detected in the stem. An auxinsimilar to indol-3yl-acetic acid (IAA) was also detected inthese stems. Growth-promoting substances were not detected inthe old stems and leaves from the main shoot. Gas-liquid chromatographyrevealed the presence of a number of additional gibberellinsin the flowers. The chemical nature of the growth substances is discussed inrelation to their biological and chromatographic behaviour.     

Developmental and Biochemical Regulation of 'Constitutive' Nitrate Reductase Activity in Leaves of Nodulating Soybean

The developmental profile of ‘constitutive’ nitratereductase activity (cNRA) in leaves of soybean (Glycine max(L.) cv. Bragg) plants at different ages is described. The youngestleaves had most cNRA and the activity dropped off as a newerleaf developed above it. Each leaf had its distinct active periodof in vivo cNRA. This pattern was different in urea-grown andsymbiotically-grown plants (inoculated with Bradyrhizobium japonicumstrain USDA 110), where the latter had no detectable in vivocNRA in older leaves. Urea-grown plants maintained considerablein vivo NRA in such older leaves. When symbiotically-grown plantshad their nodules removed, in vivo cNRA reappeared in olderleaves within 1 d of removal, nearly reaching levels of youngleaves at 3 d after nodule excision. Allantoic acid (ALL), oneof the known transport ureides of soybeans, was implicated asa possible signal molecule from nodules to leaves. Allantoicacid (100 µM) inhibited in vitro c₁ NRA significantly,with 400 µM ALL resulting in complete inhibition. In contrast,allantoin (ALN) had no inhibitive effect on NRA. Inhibitionof c₁NRA by ALL was by a competitive process, judging from Lineweaver-Burkeplots against nitrate. Kinetics showed a constant Vmax of around105 nmol NO₂ mg^–1 protein h^–1 and a K_m for nitrateof 15 mM, which increased to 60 mM in the presence of 200 µMallantoic acid. Non-specific (ionic and pH-related) influenceswere eliminated. Allantoic acid also had a slight stimulatingeffect of in vitro NRA (up about 25% at 400 µM). Thesefindings suggest that c1NRA may be involved in ureide metabolism,rather than in vivo nitrate metabolism. Key words: Root-shoot interaction, nitrogen metabolism, nodulation, symbiosis     

Natural and dark-induced nodule senescence in chickpea: nodule functioning and H2O2 scavenging enzymes

An investigation was carried out on chickpea (Cicer arietinum L.) cv. C-235 inoculated withRhizobium sp.Cicer strain cv 4 Az^r. Nodule functioning was monitored at 15 d intervals starting from 45 days after sowing (DAS) and inoculation in order to study nodule development and senescence under natural and stress conditions (dark treatments of 18 and 66 h). Maximum rate of N₂-fixation was observed between 50 - 60 DAS. After this acetylene reducing activity (ARA) fell and it was negligible 75 DAS. This decline in ARA with ageing of plants and nodules was accompanied by a decline in leghemoglobin content and greening of the nodules. When 60 % of the nodule tissue had turned green 75 DAS, a sharp increase in nodule peroxidase activity (3.7 fold) was observed whereas the catalase activity was reduced by 50 % in comparison with the control. The glutathione-reductase and ascorbate-peroxidase activity followed a trend parallel to that in N₂-fixation, but the variation was much smaller. The changes in the total soluble carbohydrates, cytosolic proteins and nitrogen content per se were not expressive. Dark treatments induced premature senescence of the nodules as was evident from the marked decrease in ARA. However, the decline in leghemoglobin content was relatively small as compared to ARA. The changes in cytosolic proteins, total soluble carbohydrates, peroxidase activity, catalase activity, glutathione reductase activity and ascorbate peroxidase activity of nodules under dark-induced nodule senescence were almost parallel to those observed under natural senescence.     

Nitrogen Fixation and Allantoin Formation in Soybean Plants

The activity of nitrogenase and the concentration of ammonia and allantoin (+ allantoic acid) in root nodules were measured throughout the growth period of soybean plants. Nitrogenase activity measured by acetylene reduction increased with plant growth and reached a maximum level at the flowering period. The level of ammonia and allantoin concentration in nodules was parallel with increased nitrogenase activity. At the late reproductive stage (pod-forming period), nitrogenase activity showed a marked decrease, but the ammonia and allantoin in the nodules remained at a constant level. Detached nodules from 56 day-old soybean plants were exposed to ¹⁵N₂ gas, and the distribution of ¹⁵N among nitrogen compounds was investigated. Enrichment of ¹⁵N in allantoin and allantoic acid reached a fairly high level after 90 min of nitrogen fixation; ca. 22% of ¹⁵N in acid-soluble nitrogen compounds was incorporated into allantoin + allantoic acid. In contrast, enrichment of ¹⁵N in amide nitrogen was relatively low. No significant ¹⁵N was detected in the RNA fraction. The data suggested that ureide formation in nitrogen-fixing root nodules did not take place through the breakdown of nucleic acids, but directly associated with the assimilating system of biologically fixed nitrogen.     

Effect of applied nitrate on enzymes of ammonia assimilation in nodules ofCicer arietinum L.

Summary The relationship between N₂-fixation, nitrate reductase and various enzymes of ammonia assimilation was studied in the nodules and leaves ofC. arietinum. In the nodules of the plants growing on atmospheric nitrogen, maximum activities of glutamine synthetase (GS), glutamate synthase (GOGAT), glutamate dehydrogenase (GDH), asparagine synthetase (AS) and aspartate aminotransferase (AAT) were recorded just prior to maximum activity of nitrogenase. In nitrate fed plants, the first major peak of GDH and AS coincided with that of nitrate reductase in the nodules. With the exception of AS, application of nitrate decreased the activities of all these enzymes in nodules but not in leaves. Activities of GS, GOGAT and AAT were affected to much greater extent than that of GDH. On comparing the plants grown without nitrate and those with nitrate, the ratios of the activities of GDH/GS and GDH/GOGAT in nitrate given plants, increased by 4 and 12 fold, respectively. The results presented in this paper suggest that in nodules of nitrate fed plants, assimilation of ammonia via GDH assumes much greater importance.