Transient nitrate uptake and assimilation in Skeletonema costatum cultures subject to nitrate starvation under low irradiance

Batch cultures of the nitrate-grown marine diatom, Skeletonemacostatum, were grown in various levels of nitrate supply, fromfull sufficiency of nitrate to 96 h of nitrate starvation Allthe cultures were maintained at low light intensity (50 µEm^–2 s^–1) to simulate the light regime of naturalphytoplankton populations in turbid waters or at the edge ofthe photic zone. The response of S costatum cells to perturbationswith 10 µM nitrate after variable starvation periods wasstudied At the deficiency-starvation borderline, the specieswas able to both increase its uptake rate and store intracellularnitrate pools. Surge, or initially high, uptake is characteristicof this situation. After long starvation periods the cells neededto acclimate to a nitrate environment before being able to utilizeit The time required for this was proportional to the previousstarvation period. Time courses of nitrate uptake and reductionwere strongly non-linear. Nitrate excretion was high (up to3 µM) under intermediate (24 and 36 h) starvation periods.Differences in the rates and times of uptake, reduction andassimilation produced strong uncoupling of the three processesThe results suggest that there is an adaptation to nitrate utilizationunder low light, nitrate shortage and discontinuous, suddennitrate inputs.     

Nitrogen Utilization in N-limited Barley During Vegetative and Generative Growth: III. POST-ANTHESIS KINETICS OF NET NITRATE UPTAKE AND THE ROLE OF THE RELATIVE ROOT SIZE IN DETERMINING THE CAPACITY FOR NITRATE ACQUISITION

Barley (Hordeum vulgare L., cvs Golf, Mette, and Laevigatum)was grown under nitrogen limitation in solution culture untilnear maturity. Three different nitrogen addition regimes wereused: in the ‘HN’ culture the relative rate of nitrate-Naddition (RA) was 0·08 d^–1 until day 48 and thendecreased stepwise to, finally, 0·005 d^–1 duringgrain-filling; the ‘LN’ culture received 45% ofthe nitrogen added in HN; the ‘CN’ culture was maintainedat RA 0·0375 d^–1 throughout. Kinetics of net nitrateuptake were measured during ontogeny at 30 to 150 mmol m^–3external nitrate. V_max (which is argued to reflect the maximuminflux rate in these plants) declined with age in both HN andLN cultures. A pronounced transient drop was observed just beforeanthesis, which correlated in time with a peak in root nitrateconcentration. Similar, but less pronounced, trends were observedin CN. The relative V_max (unit nitrogen taken up per unit nitrogenin plants and day) in all three cultures declined from 1·3–2·3d^–1 during vegetative growth to 0·1–0·7d^–1 during generative growth. These values are in HN andLN cultures 15- to more than 100-fold in excess of the demandset by growth rates throughout ontogeny. Predicted balancingnitrate concentrations (defined as the nitrate concentrationrequired to support the observed rate of growth) were below6·0 mmol m^–3 in HN and LN cultures before anthesisand then decreased during ontogeny. In CN cultures the balancingnitrate concentration increased during grain-filling. Apartfrom the transient decline during anthesis, most of the effectof ageing on relative V_max can be explained in terms of reducedcontribution of roots to total biomass (R:T). The loss in uptakeper unit root weight is largely compensated for by the declinewith time in average tissue nitrogen concentrations. The quantitativerelationships between relative V_max and R:T in ageing plantsare similar to those observed for vegetative plants culturedat different RAs. The data support the contention that the capacity for nitrateacquisition in N-limited plants is under general growth control,rather than controlled by specific regulation of the biochemicalpathway of nitrate assimilation. Key words: Barley, nitrogen concentration, root: total plant biomass ratio, V_max     

Modelling Nitrogen Content and Distribution in Cauliflower (Brassica oleracea L.botrytis )

A model of nitrogen uptake and distribution is presented whichdescribes these processes in relation to the amount of availablesoil nitrate and the rate of plant growth. Nitrogen uptake iseither sink or source limited. Sink limitation is based on maximumN-concentrations of plant compartments. The N-uptake model iscombined with a photosynthesis model based on the productivity-nitrogenrelationship at the single-leaf level. The model is parameterizedusing cauliflower as an example crop. Applied to an independentdata set, the combined model was able to predict leaf, stemand inflorescence nitrogen concentrations with correlation coefficientsbetween predicted and simulated values of 0.89, 0.66 and 0.86,respectively. The influence of nitrogen supply and light intensityon leaf nitrate-N could also be predicted with good accuracy(r² = 0.87). Dry matter production based on the productivity-Nrelationship and the partitioning into leaf, stem and inflorescencewas also reproduced satisfactorily (r² = 0.91, 0.93 and 0.92,respectively). Copyright 2000 Annals of Botany Company Brassica oleracea L. botrytis, cauliflower, nitrogen, nitrate, nitrogen supply, nitrogen uptake, nitrogen distribution, model     

Ageing of Cucumber and Onion Seeds: Phospholipase D, Lipoxygenase Activity and Changes in Phospholipid Content

Cucumber (Cucumis sativus L. cv. Mesa) and onion (Allium cepaL. cv. Rijnsburger Heldis) seeds were rapidly aged at 40 °Cand 74% relative humidity. Onion seeds were also slowly agedat 40 °C with 15% relative humidity for 11 months and onemore month at 28% relative humidity. Significant loss of totaland individual phospholipids was an early event during bothstorage treatments. With slow ageing of onion, loss of phosphatidylcholineoccurred several months before loss of viability and vigourwas detected. Phosphatidic acid, the lipid product of phospholipaseD action, increased during rapid ageing of both cucumber andonion. Phosphatidic acid was present in onion seeds before theageing treatments and its content remained unchanged in theslowly aged seeds. There was 1600 (cucumber) and 2000 (onion)times more phospholipase D activity (6 x 10⁵ and 2·9x 10⁵ nmol g^–1 d^–1 in cucumber and onion, respectively)in crude extracts from non-aged seeds than was required to accountfor the fastest fall in phospholipids (72, 372 and 144 nmolg^–1 d^–1 for cotyledons and radicles of cucumberand onion, respectively, over the first 9 d [cucumber] or 1d [onion] of ageing) and fastest increase in phosphatidic acid(7, 162 and 37 nmol g^–1 d^–1). How accurate a guidethe in vitro activity of phospholipase D was to the in vivoactivity was unclear. However, the considerable excess activityseen with the formation of phosphatidic acid supports the proposalthat hydrolysis of phospholipids by phospholipase D is a firststep in deterioration during ageing. Substantial lipoxygenaseactivity was also detected (58 x 10³ and 54 x 10³ nmol g^–1d^–1 respectively, for non-aged cucumber and onion seeds).However, the increase in conjugated dienes (an early productof peroxidation) in ageing cucumber seeds was comparativelysmall (90 nmol g^–1 d^–1 over 21 d ageing), and increasein malondialdehyde could not be detected, indicating that peroxidationmay not have been a major factor in cucumber. The increase inconjugated dienes during rapid ageing of onion seeds was larger(1·5 x 10³ nmol g^–1 d^–1 over days 0–2of rapid ageing), much greater than the decrease in phospholipidacyl groups (260 nmol g^–1 d^–1 over days 0–2of rapid ageing) indicating the occurrence of peroxidation offatty acids released from reserve as well as from membrane lipids.This higher level of conjugated dienes during onion ageing wasthe main difference between cucumber and onion, indicating thatthe level of peroxidation could be an important difference betweenfast and slow ageing seeds. However, peroxidation is not theonly possible deleterious process since hydrolysis of the normalmembrane phospholipids to phosphatidic acid increased the contentof non-bilayer-forming lipids and this too could be a directmembrane-destabilizing consequence of phospholipase D actionduring ageing. Key words: Cucumis sativus L. (cucumber), Allium cepa L. (onion), seed ageing, phospholipase D, lipoxygenase, phospholipids     

Growth of harmful marine algae in multispecies cultures

Mixtures of harmful and harmless algae were grown in discontinuouslydiluted batch cultures under ammonium, nitrate and phosphatelimitation, and at different irradiances (20–500 µjnolquanta m^–2 s^–1). The species used were Chrysochromulinapolylepis, Emiliania huxleyi type B, Rhodomonas sp., the dinoflagellalesFibrocapsa japonica, Gymnodinium simplex, Gyrodinium aure-olum,Heterocapsa triquetra, Heterosigma carterae, Prorocentrum micansand Alexandrium tamarense, the diatoms Chaetoceros socialis,Cymatosira belgica, Ditylum brightwellii, Laudcria borealis,Odon-telta aunla, Pseudonitzschia pungens, Streptotheca tamesis,and the cyanobacterium Synechococcus. Their growth responsein the mixed algal cultures is discussed in relation to theirabundance in different natural habitats. In comparison withthe other non-diatoms, the mixotrophic C.polylepis grew fastunder all tested nutrient and light limitations.Emiliania huxleyigrew well under nitrogen (N) limitation (with nitrate as N source)and at irradiance levels from 15 up to 500 µmol quantam^–2 s^–1. No growth of calcifying cells could bedetected under N limitation when ammonium was used as N source.Rhodomonas grew reasonably well under ammonium-N limitationand grew fast at the highest irradi-ance. The dinoflagellateswere poor competitors compared to the Prymnesiophyceae. Theenvironmental fitness of the Prymnesiophyceae appears to beclosely related to the reproductive capacity of the vegetativestage, whereas the natural distribution of dinoflagellates seemsmore closely dependent on the generative reproduction-relatedspecific life cycle characteristics of the individual species.The marine diatoms include a mixture of both types of species.Some marine diatom species clearly have the capability to outcompetenon-diatoms under different types of nutrient and light limitationswhen silicate is in excess. Other diatoms seem to be poor competitors.     

Effect of nitrate on nitrogen-fixation by the blue-green alga Anabaena cylindrica

The effect of nitrate on nitrogen-fixation in the blue-greenalga Anabaena cylindrica Lemm (Fogg strain) was investigated.At concentrations up to 2x10^–2 M, nitrate neither inhibitedthe activity of nitrogenase nor repressed its formation. Atthe late logarithmic phase, more than 50% of cell nitrogen wasprovided by nitrogen-fixation when the cells were grown in thepresence of nitrate. Ammonia at a concentration of 1x10^–3M completely repressed the formation of nitrogenase, but hadno effect on its activity. Nitrogen-fixing activity in the algavaried to a considerable extent during growth on N₂ and themaximum activity was attained at the middle logarithmic phase.However, atmospheric nitrogen did not directly affect the inductionof nitrogenase. The formation of nitrogenase in A. cylindricaappears to be controlled by the intracellular level of a certainnitrogenous metabolite. ¹ This work was supported by grant No. 38814 from the Ministryof Education. (Received January 26, 1972; )     

Rapid Ethylene Production in Soybean in Response to the Cupric Ion

Very rapid accumulation of free 1-aminocyclopropane-1-carboxylicacid (ACC), followed by stimulation of ethylene production wereinduced by a Cu²⁺ in soybean cuttings. The accumulation mustbe attributed to an increase in ACC synthesis, because: (1)it was completely inhibited by aminoethoxyvinylglycine (AVG);and (2) the ethylene stimulation was inhibited by AVG, indicatingthat free ACC cannot be released from its conjugated form. Theactivity of the ethylene-forming enzyme slightly decreased followingthe Cu²⁺ pulse, and this event was accompanied by a slight increasein electrolyte leakage from the treated soybean tissues. Glycine max L., soybean, ethylene, cupric ion     

Nitrogen Utilization in N-limited Barley during Vegetative and Generative Growth: I. GROWTH AND NITRATE UPTAKE KINETICS IN VEGETATIVE CULTURES GROWN AT DIFFERENT RELATIVE ADDITION RATES OF NITRATE-N

Growth and nitrate uptake kinetics in vegetatively growing barley(Hordeum vulgare L., cvs Laevigatum, Golf, and Mette) were investigatedin solution culture under long-term limitations of externalnitrogen availability. Nitrate was fed to the cultures at relativeaddition rates (RA) ranging from 0.02 to 0.2 d^–1. Therelative growth rate (RG, calculated for total plant dry weight)correlated well with RA in the range 0.02 to 0.07 d^–1.In the RA range from 0.07 to 0.2 d^–1 RG continued to increase,but an increasing fraction of nitrogen, added and absorbed,was apparently stored rather than used for structural growth.The RG of the roots was less affected by RA. V_max, for net nitrateuptake increased with RA up to 0.11 d^–1, but decreasedat higher RA. The decline in V_max coincided with a build-upof nitrate stores in both roots and shoots. V_max, expressedper unit nitrogen in the plants (the relative V_max, was higherthan required for maintenance of growth (up to 30-fold) at lowRA, whereas at higher RA the relative V_max decreased. Kineticpredictions of steady-state external nitrate concentrationsduring N-limited growth ranged from 0.2 to 5.0 mmol m^–3over the RG range 0.02 to 0.11 d_–1. It is suggested thatthe nitrate uptake system is not under specific regulation atlow RA, but co-ordinated with root protein synthesis and growthin general. At RA higher than 0.11 d_–1, however, specificregulation of nitrate uptake, possibly via root nitrate pools,become important. The three cultivars showed very similar growthand nitrate uptake characteristics. Key words: Barley, growth, nitrogen limitation, nitrate uptake, kinetics     

Effects of Temperature on Growth and Nitrogen Fixation by Swards of Subterranean Clover

Subterranean clover (Trifolium subterraneum L.) cv. ‘Woogenellup’ swards were grown at 10, 15, 20 and 25 Cwith a 12 h photoperiod of 500 or 1000 µmol m^–2s^–1 [low and high photosynthetic photon flux density (PPFD)].Nitrogen-fixing swards received nutrient solution lacking combinednitrogen while control swards received a complete nutrient solution.Growth was measured by infra-red analysis of carbon dioxideexchange and by accumulation of dry matter. Swards were harvestedat intervals between 95 and 570 g d. wt m^–2 for estimationof nitrogenase activity by acetylene reduction and hydrogenevolution assays. Nitrogen fixation was also measured by increasein organic nitrogen. The growth rate was highest at 10 C at low PPFD, and at 10–15C at high PPFD. Nitrogen-fixing swards grew slower than thosereceiving combined nitrogen. Nitrogen fixation measured by increasein organic nitrogen responded similarly to the growth rate,as did acetylene reduction between 10 and 20 C. At 25 C therelationship between acetylene reduction and nitrogen fixationwas distrupted. The difference between the rates of acetylenereduction and hydrogen evolution, theoretically proportionalto nitrogen fixation, was not a reliable indicator of nitrogenfixation because hydrogen uptake developed. Trifolium subterraneum L, subterranean clover, growth, nitrogen fixation, temperature, acetylene reduction     

Effects of nitrogen and phosphorus starvation on nucleic acid and protein content of Heterocapsa sp.

Changes in the protein, RNA and DNA content related to nitrogen(N) and phosphorus (P) starvation were studied in the marinedinoflagellate Heterocapsa sp. grown in batch cultures. In bothcases of nutrient starvation, metabolic adaptations affectedprotein and RNA pools, while the DNA content per cell remainedapproximately constant. N starvation led to a parallel decreasein protein and RNA concentration which caused the protein/RNAratios to remain constant. A dramatic decrease in the RNA contentcharacterized the P-starved cultures, although protein synthesiscontinued. The ribosomal RNA content was lower than expectedgiven the continuation of protein synthesis. It is suggestedthat protein/RNA ratios could be used as an indicator of P starvation,while protein/chlorophyll ratios would characterize N starvation ¹Present address: University of Hawaii at Manoa Soest, BiologicalOceanography, 1000 Pope Road, Honolulu, HI 96822, USA     

Acetate metabolism in the process of "acetate-bleaching" of Chlorella protothecoides

Green cells of Chlorella protothecoides when incubated in amedium containing acetate but no nitrogen source, have beenshown to be bleached as strongly as in glucose-induced bleaching.Using U-¹⁴C-acetate as tracer, the acetate metabolism of algalcells during the process of acetate-induced bleaching was investigated.Changes in algal cell activities for respiration and assimilationof added ¹⁴C-acetate were followed during bleaching processesin "acetate-adapted" and "non-adapted" green cells. As in glucose-inducedbleaching of algal cells, algal cell activity for incorporating¹⁴C into lipids showed the most characteristic change, suggestingthat lipogenesis is causally related to the occurrence of bleachingin algal cells. (Received March 5, 1969; )     

Inhibition of Nodule Development in Soybean by Nitrate or Reduced Nitrogen

Imsande, J. 1986. Inhibition of nodule development in soybeanby nitrate or reduced nitrogen.—J. exp. Bot. 37: 348–355. Nodulation of hydroponically grown soybean plants [Glycine max(L.) Merr.] is inhibited by continuous growth in the presenceof 4· mol m^–3 KNO₃ The presence of 4·0 molm^–3 ‘starter nitrate’ for 3-6 d during noduledevelopment, however, subsequently stimulates nodule dry weightaccumulation and nitrogenase activity. These stimulations occureven though 4· mol m^–3 nitrate temporarily delaysnodule development, i.e. the late steps of nodule developmentare reversibly inhibited by a short-term exposure to 4·0mol m^–3 nitrate. On the other hand, treatment with 4·0mol m^–3 nitrate in excess of 14 d significantly reducesnodule dry weight Thus, extended growth in the presence of 4·0mol m^–3 KNO₃ seems to block both early and late stepsof nodule development. Nodulation of hydroponically grown soybeansis also inhibited by continuous growth in the presence of 2·0mol m^–3 (NH₄)₂SO₄ This inhibition is not caused by acidityof the growth medium. On the other hand, nodule development6 d after inoculation with Rhizoblum japonicum is not delayedby a 7-d exposure to 2·0 mol m^–3 (NH₄)₂SO₄ butis partially inhibited by a prolonged exposure to (NH₄)₂SO₄Because repression of nodulation by 4·0 mol m^–3KNO₃ is more severe than that by 2·0 mol m^–3 (NH₄)₂SO₄and because ammonium taken up by the soybean plant is not activelyoxidized to nitrate, it is suggested that there are at leasttwo mechanisms by which nitrate utilization represses noduleformation in soybean. Key words: Glycine max, nitrogen, nitrogen fixation, nodulation     

Cytokinin Regulation of Flower and Pod Set in Soybeans (Glycine max(L.) Merr.)

Exogenous application of cytokinin to raceme tissues of soybean(Glycine max(L.) Merr.) has been shown to stimulate flower productionand to prevent flower abortion. The effects of these hormoneapplications have been ascertained for treated tissues, butthe effects of cytokinins on total seed yields in treated plantshave not been evaluated. Our objectives were to examine theeffects of systemic cytokinin applications on soybean yieldsusing an experimental line of soybeans, SD-87001, that has beenshown to be highly sensitive to exogenous cytokinin application.Soybeans were grown hydroponically or in pots in the greenhouse,and 6-benzylaminopurine (BA) was introduced into the xylem streamthrough a cotton wick for 2 weeks during anthesis. After theplants had matured, the number of pods, seeds per pod, and thetotal seed weight per plant were measured. In the greenhouse,application of 3.4 x 10^-7 moles of BA resulted in a 79% increasein seed yield compared with controls. Results of field trialsshowed much greater variability within treatments, with consistent,but non-significant increases in seed number and total yieldsof about 3%. Data suggest that cytokinin levels play a significantrole in determining total yield in soybeans, and that increasingcytokinin concentrations in certain environments may resultin increased total seed production. Copyright 2001 Annals ofBotany Company Glycine max, soybean, flower abortion, cytokinin, 6-benzylaminopurine, hydroponic, seed yield, wicking     

Nitrogen Assimilation in Barley (Hordeum vulgare L. cv. Mazurka) in Response to Nitrate and Ammonium Nutrition

Barley plants (Hordeum vulgare L. cv. Mazurka) were grown inaerated solution cultures with 2 mM or 8 mM inorganic nitrogensupplied as nitrate alone, ammonium alone or 1:1 nitrate+ammonium.Activities of the principal inorganic nitrogen assimilatoryenzymes and nitrogen transport were measured. Activities ofnitrate and nitrite reductases, glutamine synthetase and glutamatesynthase were greater in leaves than in roots but glutamatedehydrogenase was most active in roots. Only nitrate and nitritereductases changed notably (4–10 times) in response tothe different nitrogen treatments. Nitrate reductase appearedto be rate-limiting for nitrate assimilation to glutamate inroots and also in leaves, where its total in vitro activitywas closely related to nitrate flux in the xylem sap and wasslightly in excess of that needed to reduce the transportednitrate. Xylem nitrate concentration was 13 times greater thanthat in the nutrient solution. Ammonium nitrogen was assimilatedalmost completely in the roots and the small amount releasedinto the xylem sap was similar for the nitrate and the ammoniumtreatments. The presence of ammonium in the nutrient decreasedboth export of nitrate to the xylem and its accumulation inleaves and roots. Nitrate was stored in stem bases and was releasedto the xylem and thence to the leaves during nitrogen starvation.In these experiments, ammonium was assimilated principally inthe roots and nitrate in the leaves. Any advantage of this divisionof function may depend partly on total conversion of inorganicnitrogen to amino acids when nitrate and ammonium are givenin optimal concentrations. Hordeum vulgare L., barley, nitrate, ammonium, nitrate reductase, nitrite reductase, glutamine synthetase, glutamate synthase, glutamate dehydrogenase, nitrogen transport     

Taurine Transport in N-deprived Chlorella fusca

The development of taurine uptake into the unicellular greenalga Chlorella fusca 211-8b was characterized as a specificresponse to either nitrate or sulphate limitation. Taurine transportunder nitrogen starvation was stimulated by low pH and showeda biphasic kinetics with K_m-values of 1.1 x 10^–3 mol dm^–3and 1.0 x 10^–2 mol dm^–3. Uptake was substantiallyinhibited by all - and ß-amino acids tested, whereassulphonate analogues failed to diminish taurine accumulation.Thus, uptake seemed to be mediated by a ‘general aminoacid permease’, unable to discriminate between carboxyland sulphonyl groups. However, Chlorella fusca could not catabolizethis unusual ß-amino acid and mobilize the amino-boundnitrogen for growth. Only a small group of -amino acids supportedthe growth of Chlorella fusca as an efficient nitrogen source. Key words: Taurine uptake, nitrogen starvation, amino acid uptake, Chlorella fusca.     

Cell Cycle Timing of Replication of the Nuclear Gene Encoding Chloroplastic NADP-Specific Glutamate Dehydrogenase Isoenzymes in Chlorella sorokiniana

In synchronized Chlorella sorokiniana cells, the NH₄⁺ inducibleNADP-specific glutamate dehydrogenase enzyme (NADP-GDH) accumulatedin a linear manner throughout the first cell cycle. Early inthe following second cell cycle, an increase in its rate ofaccumulation occurred that was proportional to the increasein total cellular DNA in the previous cell cycle. In synchronizedbacterial cells, increases in rate of linear accumulation ofinducible enzymes coincide with the time of replication of theirstructural genes. To determine whether the rate change in NADPGDHaccumulation resulted from a delay in replication of its nuclearstructural gene (gdhN) in fully induced C. sorokiniana cells,the cell cycle timing of replication of this gene was comparedto that of another nuclear gene, nitrate reductase (nia), andof a chloroplast gene, ribulose bisphosphate carboxylase large-subunit(rbcL), in synchronized cells cultured in NH₄⁺ or NO₃^–(uninduced) medium. The gdhN and nia genes replicated withinthe period of nDNA synthesis and rbcL within the period of ctDNAsynthesis in cells growing in either nitrogen source. Therefore,the delayed rate change in enzyme accumulation results froma process that regulates expression of the gdhN gene after itsreplication. (Received July 16, 1994; Accepted November 28, 1994)     

Post-transcriptional Control of Nitrate Reductase Formation in Green Algae

Cycloheximide (2·0 µg ml^–1) inhibits theincorporation of [¹⁴C]phenylalanine and [¹⁴C]adenine into insolublecompounds in Ankistrodesmus braunii. 6-Methylpurine (1·0mM) inhibits only the incorporation of [14C]adenine and it isconcluded that it inhibits RNA synthesis. When ammonium-growncells of Ankistrodesmus or Chlorella are nitrogen-starved orwhen ammonium-grown cells of Dunalitlla are resuspended in nitratemedium, the appearance of nitrate reductase in these organismsis not inhibited by 6-methylpurine. The appearance of nitratereductase activity in Ankistrodesmus or Chlorella is inhibitedby 6-methylpurine when ammonium-grown organisms are preincubatedwith this substance for 1-2 h before nitrogen starvation. Itis concluded that cells growing with ammonium and lacking nitratereductase activity nevertheless contain preformed mRNA for nitratereductase synthesis.     

Responses of nitrate assimilation and N translocation in tomato (Lycopersicon esculentum Mill) to reduced ambient air humidity

The impact of low humidity in ambient air on water relations,nitrate uptake, and translocation of recently absorbed nitrogen,was investigated in 5-week-old tomato (Lycopersicon esculentumMill cv. Ailsa Craig) plants grown hydroponically in a completenutrient solution. Plants were subjected to dry air (relativehumidity 2–4% for 6 h. The transpiration rate increasedseveral-fold and the shoot water content decreased by almost20%, whereas root water content was unaffected. No effect onin vitro nitrate reductase (NR) activity was detected when usingan EDTA-contraining assay buffer. Replacement of EDTA with Mg²⁺revealed a significant decline in shoot NR activity, which suggestsphosphorylation of the enzyme during the stress treatment. Plantswere grown in a split-root system, in which one root half wasfed ¹⁵N-nitrate during the treatment, in order to determinenitrate uptake and translocation of recently absorbed nitrogenin the plants. Uptake of nitrate was substantially inhibited,but the proportion of absorbed ¹⁵N that was translocated tothe shoots was only slightly affected. In untreated plants,71% of the ¹⁵N recovered in roots had been retranslocated fromthe shoots, whereas in plants subjected to stress the deliveryof ¹⁵N from shoots to roots appeared to be completely inhibited.The data show that lowered humidity in air has significant effectson both uptake of nitrate as well as translocation of nitrogenwithin the plants. Some of these effects appear to be commonwith those observed in plants subjected to reduced water potentialsin the root environment and point to the possibility of theshoot water relations being highly influential on nitrogen uptakeand translocation. Key words: Air humidity, nitrate assimilation, nitrate reductase activity, nitrogen translocation, tomato, water stress     

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