Changes in the Root System of Wheat Seedlings Following Root Anaerobiosis I. Anatomy and Respiration in Triticum aestivum L.

Anatomical changes in roots of wheat seedlings (Triticum aestivumL. cv. Hatri) following oxygen deficiency in the rooting mediumwere investigated. The response of the plant to stress was testedat a very early developmental stage when the first adventitiousroots had just emerged. In order to analyze the adaptation ofdifferent roots, respiration rates of the roots 1–3 and4–n were compared with the respiration rates of the totalroot system. Oxygen deficiency was induced either by flushingnutrient solution with nitrogen or flooding of sand. In contrast to plants grown in well aerated media, both stressvariants led to a significant increase of the intercellularspace of the root cortex in seminal and first adventitious roots.Radial cell enlargement of cortical cells near the root tip,cell wall thickenings in flooded sand cultures and an increasein phloroglucinol-stainable substances were found to be furtherindicators of low oxygen supply. The roots 4–n which were promoted in growth under hypoxiashowed higher respiration rates; hence the total root respirationwas not restricted. Triticum aestivum L. cv. Hatri, wheat, roots, anatomy, anaerobiosis, stress, root respiration, intercellular space     

Changes in the Root System of Wheat Seedlings Following Root Anaerobiosis: III. Oxygen Concentration in the Roots

The oxygen status in roots of wheat seedlings (Triticum aestivum)was determined by a volumetric micro-absorption method. Plantsgrew in nutrient solution (aerated or nitrogen-flushed) or onflooded sand up to the 10th day. The roots were then exposedto aerated or hypoxic conditions for several hours before gaswas extracted by reducing the pressure within a concentratedsalt solution or by physical crushing. The oxygen content ofthe extracted gas bubbles was measured with pyrogallol. Comparativeexperiments with the helophytes Phalaris arundinacea and Carexacutiformis yielded similar oxygen concentrations to those alreadydescribed in literature. The concentrations of oxygen (13–16%)in young wheat roots were surprisingly high when exposed tonutrient solution flushed with nitrogen gas. Removal of the shoots decreased the oxygen concentration inthe roots, indicating some internal oxygen transport from shootsto roots. Detached, submerged roots of wheat still contained6% oxygen following 20 h of submergence in nitrogen-flushedsolution. A linear relationship was found between the oxygenconcentration in roots of Triticum aestivum, Zea mays and thetwo helophytes and the volume of extractable gas per volumeof root. This ratio corresponded to the extent of aerenchymaformation. Hence, a certain amount of oxygen may have been adsorbedonto the inner surfaces of the lacunae of the roots. However, the large amount of oxygen in the roots of intact wheatplants suggest that some parts of the root system are unlikelyto suffer from the oxygen shortage imposed by oxygen-deficientexternal conditions such as flooded soil. Triticum aestivum L. cv. Hatri, wheat, helophytes, roots, micro-absorption method, oxygen concentration, hypoxia, intercellular space     

Root Development and Aerenchyma Formation in Two Wheat Cultivars and One Triticale Cultivar Grown in Stagnant Agar and Aerated Nutrient Solution

Stagnant nutrient solution containing 0.1% agar and with anextremely low oxygen level (‘stagnant agar solution’)was used to simulate the gaseous composition and slow gas diffusionof waterlogged soils. Comparisons were made between the growthof two wheat cultivars(Triticum aestivum,cvs. Gamenya and Kite)and one triticale cultivar(Triticosecale,cv. Muir) grown instagnant relative to aerated solution. For all genotypes tested,immersion of roots in stagnant agar solution resulted in thedeath of the entire seminal root system and led to profuse branchingof the laterals of the nodal roots. In the stagnant agar solutionaerenchyma, as a percentage of the total cross sectional areaof nodal roots, was 18% for Muir, 14% for Kite and 12% for Gamenya;the roots of species with more aerenchyma also attained a longermaximum root length as predicted by the model of Armstrong (in:Woolhouse HW, ed.Advances in botanical research, vol. 7. London:Academic Press, 1979). Muir also had a nodal root/shoot freshweight ratio of 0.5 compared with 0.2–0.3 in Kite andGamenya. The greater number and length of nodal roots of Muirdid not lead to better shoot growth than in the other genotypes;one possible reason for this lack of improvement is a low efficiencyof aerenchymatous roots in wheat.Copyright 1998 Annals of BotanyCompany Root development; aerenchyma; stagnant agar;Triticum aestivumcv. Gamenya;Triticum aestivumcv. Kite;Triticosecalecv. Muir.     

Changes in the Root System of Wheat Seedlings Following Root Anaerobiosis II. Morphology and Anatomy of Evolution Forms

Morphological and anatomical parameters which are variable underroot anaerobiosis in Triticum aestivum were checked on fivetaxa of primitive and modern wheats (and the related genus Aegilops).The plants were grown in nutrient solution which was eitheraerated or flushed with nitrogen. When the plants were flushedwith nitrogen a general retardation in longitudinal root growthoccurred in all of them, but only Triticum aestivum showed aclear promotion of growth of later appearing roots enablingit to maintain the same root/shoot ratio even under stress conditions.There was an increase in the volume of intercellular space inthe root cortex of nearly all the plants investigated. The diameterand the lignin content of the roots and the form of their corticalcells also varied. All these changes were expressed in the primitivewheats to a lesser extent than in the advanced Triticum aestivumindicating that there is a clear increase in the adaptive responsein the latter. Triticum species, Aegilops species, wheat, roots, anatomy, anaerobiosis, stress, intercellular space, selection     

Root Respiration and Carbohydrate Status of Two Wheat Genotypes in Response to Hypoxia

To investigate root respiration and carbohydrate status in relationto waterlogging or hypoxia tolerance, root respiration rateand concentrations of soluble sugars in leaves and roots weredetermined for two wheat (Triticum aestivum L.) genotypes differingin waterlogging-tolerance under hypoxia (5% O₂) and subsequentresumption of full aeration. Root and shoot growth were reducedby hypoxia to a larger extent for waterlogging-sensitive Coker9835. Root respiration or oxygen consumption rate declined withhypoxia, but recovered after 7 d of resumption of aeration.Respiration rate was greater for sensitive Coker 9835 than fortolerant Jackson within 8 d after hypoxia. The concentrationsof sucrose, glucose and fructose decreased in leaves for bothgenotypes under hypoxia. The concentration of these sugars inroots, however, increased under hypoxia, to a greater degreefor Jackson. An increase in the ratio of root sugar concentrationto shoot sugar concentration was found for Jackson under hypoxicconditions, suggesting that a large amount of carbohydrate waspartitioned to roots under hypoxia. The results indicated thatroot carbohydrate supply was not a limiting factor for rootgrowth and respiration under hypoxia. Plant tolerance to waterloggingof hypoxia appeared to be associated with low root respirationor oxygen consumption rate and high sugar accumulation underhypoxic conditions.Copyright 1995, 1999 Academic Press Oxygen consumption rate, sugar accumulation, Triticum aestivum L., waterlogging tolerance     

Effect of Root and Shoot Meristem Temperature on Shoot to Root Dry Matter Partitioning and the Internal Concentrations of Nitrogen and Carbohydrates in Maize and Wheat

Maize (Zea mays L.) and spring wheat (Triticum aestivum L.)were grown in nutrient solution at uniformly high air temperature(20 °C), but different root zone temperatures (RZT 20, 16,12 °C). To manipulate the ratio of shoot activity to rootactivity, the plants were grown with their shoot base includingthe apical meristem either above (i.e. at 20 °C) or withinthe nutrient solution (i.e. at 20, 16 or 12 °C). In wheat, the ratio of shoot:root dry matter partitioning decreasedat low RZT, whereas the opposite was true for maize. In bothspecies, dry matter partitioning to the shoot was one-sidedlyincreased when the shoot base temperature, and thus shoot activity,were increased at low RZT. The concentrations of non-structuralcarbohydrates (NSC) in the shoots and roots were higher at lowin comparison to high RZT in both species, irrespective of theshoot base temperature. The concentrations of nitrogen (N) inthe shoot and root fresh matter also increased at low RZT withthe exception of maize grown at 12 °C RZT and 20 °Cshoot base temperature. The ratio of NSC:N was increased inboth species at low RZT. However this ratio was negatively correlatedwith the ratio of shoot:root dry matter partitioning in wheat,but positively correlated in maize. It is suggested that dry matter partitioning between shoot androots at low RZT is not causally related to the internal nitrogenor carbohydrate status of the plants. Furthermore, balancedactivity between shoot and roots is maintained by adaptationsin specific shoot and root activity, rather than by an alteredratio of biomass allocation between shoot and roots.Copyright1994, 1999 Academic Press Wheat, Triticum aestivum, maize, Zea mays, root temperature, shoot meristem temperature, biomass allocation, shoot:root ratio, carbohydrate status, nitrogen status, functional equilibrium     

Condensed Tannin Formation by Agrobacterium rhizogenes Transformed Root and Shoot Organ Cultures of Lotus corniculatus

Root cultures of Lotus corniculatus L. cv. Leo transformed withAgrobacterium rhizogenes (C58Cl-pRi15834) grew rapidly in liquidmedium when cultured in the dark and produced large numbersof shoots when illuminated. The shoots, which could be regeneratedto produce fertile plants, were maintained in liquid mediumas shoot-organ cultures The accumulation and cellular distribution of condensed tanninswas determined during the growth of these root and shoot organcultures and in primary callus from non-transformed explants.Root and shoot cultures predominantly accumulated insolublepolymeric tannins which yielded both cyanidin and delphinidinon hydrolysis at ratios equivalent to control plants. Methanol-solublevanillin-positive compounds were isolated but no free oligomericproanthocyanidins, monomeric flavans or dihydroflavonols weredetected in these extracts. Condensed tannin accumulation waslinearly related to root growth and had a similar spatial distributionin ‘tannin’ cells in roots and leaves as comparedto control plants. Tannin-containing cells were absent frommeristematic cells of the root tip and root/shoot interface.Primary callus cultures failed to accumulate condensed tanninson media containing auxins, and exogenously supplied auxinswere found to inhibit tannin accumulation by transformed rootand shoot cultures Key words: Lotus corniculatus, Agrobacterium rhizogenes, hairy roots, condensed tannins, shoot and root cultures.     

Anatomy of the Root-Shoot Junction in Wheat Seedlings with Respect to Internal Oxygen Transport and Root Growth Retardation by External Oxygen Shortage

Anatomical alterations in the root-shoot junction followinghypoxic conditions were studied in young wheat plants (Triticumaestivum L. cv. Hatri) grown in nutrient solution flushed withair or nitrogen gas. The root-shoot junction was characterizedby densely packed tissues with only small intercellular spaces.Seven days of hypoxia did not alter the anatomy of this region,suggesting that it does not constitute an important pathwayfor oxygen diffusion from aerial shoot to the aerenchymatousroots. A likely alternative path for oxygen movement is thegas-filled interspace between coleoptile and shoot base. Rootsemerging from more apical parts of the stem elongated more quicklyin hypoxic conditions than those from more basal parts. Thiswas related to the path length from the main point of entryof atmospheric oxygen into the plant. Additionally, oxygen shortagein the ambient root medium decreased the number of mitoses perroot tip, as determined by the Feulgen method. This effect wasmost severe in the basally inserted roots, that are presumedto be the most oxygen deficient. Triticum aestivum L. cv. Hatri, wheat, hypoxia, root-shoot junction, anatomy, internal oxygen transport, root tip, mitosis     

Morphological, Anatomical and Physiological Responses Related to Differential Shoot vs. Root Growth Inhibition at Low Temperature in Spring and Winter Wheat

Several morphological, anatomical and physiological changesand their relationship with differential root vs. shoot growthinhibition at low temperature (5°C) were studied in springand winter wheat cultivars. Root:shoot ratios, expressed eitheras a function of root and shoot fresh weight or as a functionof root and leaf areas, increased at low temperature and thisincrement was more pronounced in spring cultivars than in winterones. Although winter cultivars developed relatively smallerroot systems at 5°C, this characteristic was counterbalancedby a lower stomatal frequency and increased thickness of epidermalcell walls in leaves unfolded at this temperature, relativeto spring cultivars. Likewise, at 5°C a decrease in theosmotic potential of shoots and roots was observed in parallelwith sugar accumulation; this decrease was more marked in wintercultivars. These results indicate a differential morpho-anatomicaland physiological plasticity of winter and spring cultivarsduring development at low temperature. The possible associationbetween these changes and plant water economy at low temperaturesis discussed. Copyright 2001 Annals of Botany Company Spring wheat, winter wheat, Triticum aestivum, low temperature, root:shoot ratio, root surface area, stomatal frequency, osmotic potential     

Morphological and Anatomical Characterization of the Coleoptile of Triticum aestivum with Regard to the Evolution of Forms with Different Ploidy Levels

Details of the morphology and anatomy of the coleoptile of wheatplants are given; these have not been described adequately previously.The investigations focussed on the hexaploid summer wheat Triticumaestivum L. cv. Hatri, and three taxa with different ploidylevels. In darkness the longitudinal growth of the coleoptile was delayedby nearly 24 h but the final length, reached after 120 h, wasdouble that of coleoptiles of plants cultivated under continuouslight. As soon as the coleoptile has grown, the primary leafpushes through a pore pre-formed during the meristematic stageand located 1–1·5 mm behind the apex. The poreis stabilized mechanically by anastomosing of the originallyfree ends of the vascular bundles, as well as by increased lignificationin this region. The species investigated differ in length, f.wt and d. wt, size of epidermal cells, and especially in thesize of guard cells of the coleoptiles. The number of parenchymalayers, however, shows no specificity. Triticum aestivum L. cv. Hatri, wheat, coleoptile, morphology, anatomy, Aegilops spp     

Growth Responses of Sweet Orange Seedlings to Shoot and Root Pruning

Following combined shoot- and root-pruning treatments the growthof Citrus sinensis (L.) Osbeck seedlings was analysed into responsesto post-pruning size and to the part pruned. The treatmentswere shoots pruned by removing O, , or of their estimated weightin all combinations with roots pruned by removing O, , or oftheir estimated weight. Responses were measured a year laterand are discussed in terms of the mechanisms controlling increment.Total increment was linearly related to initial pruned weightboth within and between treatments and there were no interactionsbetween shoot and root pruning in increment of leaf, new stem,old stem, thorn, fibre-root, or tap-root. Root pruning, pergramme of pruned material, reduced increment more than did shootpruning. With increasing shoot pruning the ratio of new stem to old stemincreased while with increasing root pruning the ratio of fibre-rootto tap-root increased. Following shoot pruning the new-stemincrement was disproportionately large while following rootpruning the increment of top growth was proportionately largerthan that of roots. The results suggest that pruning citrus trees to a constantsize at planting could lead to a uniform tree size in the subsequentorchard but that maximum growth would occur on un-pruned trees.     

Depletion of Oxygen in Roots of Wheat and Maize by Respiration Following Encasement in Olive Oil

The extent to which isolated root systems of 14-d-old seedlingsof wheat (Triticum aestivum) and maize (Zea mays) were depletedof oxygen by respiration was measured after immersing them inoutgassed olive oil to exclude oxygen entry from the air. Atintervals over 45 min, gas from the roots was removed underpartial vacuum and oxygen partial pressures measured by gaschromatography. Contrary to earlier findings (Erdmann and Wiedenroth,1988), roots were able to utilize almost all of their oxygenwithin 20 min at 25°C, including that dissolved in the thinwater covering interposed between roots and oil. The rate ofaerobic respiration could be estimated readily from the timecourse of oxygen depletion.Copyright 1993, 1999 Academic Press Triticum aestivum, Zea mays, roots, anaerobiosis, respiration, oxygen, methods     

Differential Inhibition of Shootvs.Root Growth at Low Temperature and its Relationship with Carbohydrate Accumulation in Different Wheat Cultivars

Shoot and root growth rate, carbohydrate accumulation (includingfructan), reducing sugar content and dry matter percentage weremeasured in six wheat cultivars, ranging from winter to springtypes, grown at either 5 or 25 °C. At 5 °C (comparedwith 25 °C), the relative growth rate (RGR) of shoots wassimilarly reduced in all cultivars, but the RGR of shoots wasmore affected in winter wheats. This difference resulted insmaller root:shoot ratios than in spring wheats, which alsodeveloped more first-order lateral roots. A direct relationshipbetween carbohydrate accumulation at low temperatures and reductionin root growth was established. These results suggest that differentialshootvs.root growth inhibition at low temperature may play akey role in carbohydrate accumulation at chilling temperatures.This differential response might lead to improvements in survivalat temperatures below 0 °C, regrowth during spring, andwater and nutrient absorption at low temperatures.Copyright1997 Annals of Botany Company Wheat; Triticum aestivum; low temperatures; root growth; root: shoot ratio; sugar accumulation     

Effects of Low Temperature on the Development and Morphology of Rye (Secale cereale) and Wheat (Triticum aestivum)

Seedlings of Secale cereale cv. Rheidol and Triticum aestivumcv. Mardler were grown at shoot/root temperatures of 20/20 °C,20/8 °C and 8/8 °C. During vegetative growth both cerealsproduced leaves, tillers and roots in a defined pattern, ata species-specific rate which was linearly related to the temperatureof the shoot meristem. Thus, plant development could be standardizedon a temperature x time (°C d) basis despite contrastinggrowth-temperature treatments. When compared at a similar developmentalstage, the cooling of whole plants or of plant roots resultedin an increase in the d. wt: f. wt ratio of both shoot and roottissues, a decrease in the length of both the longest shootand root, and the development of broader and thicker leaves.Although the effects of temperature on developmental characteristicscould be accurately predicted by an empirical relationship,the effects on morphological characteristics could not. Development, phyllochron, rye, Secale cereale cv. Rheidol, temperature, thermal time, Triticum aestivum cv. Mardler, wheat     

In vitro Shoot Regeneration from Seedling Root Segments of Brassica oleracea and Brassica napus Cultivars

Root segments taken from aseptically-grown seedlings of Brassicaoleracea var. italica cv. Green Comet were used in an investigationof factors affecting in vitro regeneration. Shoot regenerationwas found to increase with seedling age and to be highest inroot segments adjacent to the hypocotyl and lowest in segmentsadjacent to the root tip. In a comparison of a range of mediaand agar concentrations shoot formation was favoured by complexmedia containing reduced nitrogen and was higher on gelled mediathan in liquid medium. The effects of various cytokinins andauxins were investigated; KN was the best cytokinin and IAAand Picloram the best auxins for shoot induction. Root segmentsfrom six other Brassica cultivars were grown on the medium devisedfor Green Comet; shoots were regenerated from two B. oleraceacultivars and two B. napus cultivars, but not from the B. campestriscultivars tested. Brassica oleracea var. italica, Brassica napus, Brassica campestris, seedling root culture, shoot regeneration     

Site, Scale and Time-course for Adjustments in Lateral Root Initiation in Wheat Following Changes in C and N Supply

The pattern of lateral root initiation in seminal roots of wheat(Triticum aestivumL. cv. Alexandria) and the location, scaleand time-course for adjustments in initiation were studied afterchanges in C and N supply. Macroscopically visible primordiaappeared in a non-acropetal sequence with the frequency (numberper unit length) increasing with distance behind the main rootapex to a maximum at 40–50 mm behind the root tip. Pruningthe root system to a single seminal axis increased the primordiafrequency by 23% within 15 h. After longer periods, the effectof root-pruning was greater. The enhanced primordia frequencywas first observed in tissue located 0–10 mm behind theapex at the start of treatment. Feeding glucose (50 mM) alsoincreased primordia frequency within 15 h, but to a greaterextent, and here additional primordia were initiated in tissuelocated 0–10and10–20 mm behind the apex at the startof treatment. Withdrawing NO₃^-from one part of a split-rootsystem, whilst maintaining the supply to the other, reducedprimordia frequency in the non-fed roots and, in some cases,a compensatory increase in the NO₃^--fed roots was observed.The location and scale of the adjustments were similar to thosefound with root-pruning and glucose-feeding, but were slightlyslower to appear. In spite of some differences in detail, therewas a broad similarity in site, scale and time-course for adjustmentsin lateral root initiation with these treatments, which is consistentwith the operation of a common mechanism. Whenever an increasein primordia frequency was observed, it was associated withan increase in the ethanol-soluble sugar content of the tissue.However, the reduction in frequency in NO₃^--deprived roots wasalso accompanied by an increase in sugar content. There wasno consistent relationship between total N content of the tissueand primordia frequency, but there was between primordia frequencyand the rate of net NO₃^-uptake. The possible mechanisms controllinglateral root initiation are discussed. Compensatory growth; correlative growth; glucose; initiation; lateral root; nitrate; primordium; split-root; Triticum aestivum; wheat     

Differential modulation of root formation in wheat embryogenic callus culture by indoleacetic acid-degrading compounds

Root overproduction in embryogenic calli of wheat cv. ‘ChineseSpring’ was controlled by the addition of IAA-degradingcompounds (citric acid, MnSO4 or EDTA) to the culture media.In the presence of 20 gl^–1 sucrose, the number of rootson calli decreased significantly when media for either callusmaintenance or plant regeneration were amended with citric acid.EDTA was less effective in reducing the number of roots thancitric acid. An increase in the amount of a 31kDa (P1) polypeptideunder conditions which favoured a reduction in root formationwas observed. Key words: Wheat, Triticum aestivum, IAA-degrading compounds, indoleacetic acid, root number.     

Effects of Low Temperature on Growth and Nutrient Accumulation in Rye (Secale cereale) and Wheat (Triticum aestivum)

Rye (Secale cereale cv. Rheidol) and wheat (Triticum aestivumcv. Mardler) were grown at shoot/root temperatures of 20/20°C (warm grown, WG plants), 8/8 °C (cold grown, CG plants)and 20/8 °C (differential grown, DG plants). Plants fromcontrasting growth temperature regimes were standardized andcompared using a developmental timescale based on accumulatedthermal time (°C d) at the shoot meristem. Accumulationof dry matter, nitrogen and potassium were exponential overthe time period studied (150–550 °C d). In rye, therates of plant dry matter and f. wt accumulation were linearlyrelated to the temperature of the shoot meristem. However, inwheat, although the rates of plant dry matter and f. wt accumulationwere temperature dependent, the linear relationship with shootmeristem temperature was weaker than in rye. The shoot/rootratio of rye was stable irrespective of growth temperature treatment,but the shoot/root ratio of wheat varied with growth temperaturetreatment. The shoot/root ratio of DG wheat was 50% greaterthan WG wheat. In both cereals, nutrient concentrations anddry matter content tended to be greater in organs exposed directlyto low temperatures. The mean specific absorption rates of nutrientswere calculated for the whole period studied for each species/temperaturecombination and were positively correlated with both plant shoot/rootratio and relative growth rate. The data suggest that nutrientuptake rates were influenced primarily by plant demand, withno indication of specific nutrient limitations at low temperatures. Nutrient accumulation, relative growth rate (RGR), rye, Secale cereale cv. Rheidol, temperature, thermal time, Triticum aestivum cv. Mardler, wheat     

Distribution of alcohol dehydrogenase in roots and shoots of rice (Oryza sativa) and Echinochloa seedlings

Abstract Aerobically germinated seedlings of rice and Echinochloa were found to survive when placed in an anaerobic environment for 4 d, whereas pea and maize seedlings did not. Although root and shoot growth were inhibited in rice and Echinochloa under anaerobiosis, growth resumed when the seedlings were returned to aerobic conditions. Alcohol dehydrogenase (ADH) activity increased more, and protein synthesis was greater, in the shoots than in the roots under anaerobic conditions. These results suggest that, in anaerobiosis-tolerant species, ADH activity and protein synthesis in the shoots represents or results from metabolic adaptations to low oxygen. These results are discussed in terms of plant establishment and growth in a low-oxygen environment.     

Root growth and nitrate uptake by wheat (Triticum aestivum L.) following wetting of dry surface soil

The nitrate uptake capacity of surface roots of spring wheat(Triticum aestivum L. cv. Kulin) was investigated followingwetting of dry surface soil. Plants were grown to stem elongationstage with adequate watering at depth while the surface soilwas allowed to dry. Eight weeks after sowing, water or a ¹⁵N-nitratesolution was added to the surface soil to simulate rainfall.Root growth and nitrate uptake were measured up to 4 d afterwetting on plants with unconfined nodal root growth and on plantswith the majority of nodal roots confined within small vials.Prior to wetting, plants from both nodal treatments had seminalroots with collapsed cortices along the upper 10 cm and manyshort, viable lateral roots. Nodal roots, where present, wereonly a few cm long and unbranched. Only plants with unconfinednodal roots were able to take up nitrate within the 24 h beforeany new root growth. By 2 d after wetting there was significantgrowth of the seminal lateral roots, and rapid growth and branchingof nodal roots. From 2 d after wetting, plants with confinednodal roots also took up nitrate, presumably due to the growthof the seminal lateral roots. Hence it appears as though thenodal roots in the unconfined treatment could immediately takeup nitrate, but the seminal roots required new lateral rootgrowth to become active in nitrate uptake. The plants with confinednodal roots had a lower nitrate uptake than those with unconfinednodal roots 4 d after wetting, indicating that the seminal rootsystem was not able to compensate for lack of nodal roots. Insufficientnitrate was taken up after 4 d, by plants from either nodalroot treatment, to increase the shoot N concentration significantly. Key words: Triticum aestivum, nitrate uptake, drought, seminal roots, nodal roots