Combined Effects of Partial Defoliation and Nutrient Availability on Cloned Betula pendula Saplings: I CHANGES IN GROWTH, PARTITIONING AND NITROGEN UPTAKE

The combined effects of partial defoliation and nutrient availabilityon dry matter accumulation and partitioning, and on nitrogenuptake and partitioning, were studied in cloned Betula pendulaRoth saplings. The saplings were randomly assigned to differentnutrient levels (5, 1·5 and 0·5 mol Nm^–3)in aerated nutrient culture and to the following defoliationtreatments: (1) control (no damage), (2)damage of the developingmain stem leaves (half of the leaf lamina removed), and (3)removalof the developing main stem leaves (entire leaf lamina removed).Measured in terms of cumulative whole-plant dry weight (includingremoved leaf tissue), the birch saplings were unable to compensatefor the loss of the developing leaves (treatment 3) during the14 d study period. In response to leaf removal (treatment 3)the mean final percentage reduction in whole-plant dry weightwas actually greater than the initial mean percentage reductioncaused by the removal itself; the magnitude of the final reductionwas independent of nutrient availability. After removal of thedeveloping leaves, branch growth was favoured at the expenseof the growth of the rest of the shoot; the relative branchgrowth was most pronounced at the highest nutrient level. Atthe two highest nutrient levels the nitrogen uptake of the saplingswith the developing leaves removed was less than that of undamagedsaplings. We suggest, however, that the incapacity of the saplingsfor compensatory growth after removal of the developing leaveswas primarily due to the decreased total carbon gain of thesaplings rather than to the decreased nitrogen uptake rate. Key words: Partial defoliation, nutrient availability, birch sapling, dry matter, nitrogen     

Pre-flowering Growth and Development of the Inflorescences of Maize: I. PRIMORDIA PRODUCTION AND APICAL DOME VOLUME

The growth and development of the main stem and the two uppermostaxillary apices of maize were studied during the period fromemergence until flowering. Plants were grown in the field undervarying levels of applied nitrogen fertilizer at two times ofsowing. The effects of daylength were isolated from those oftemperature by making comparisons of growth and developmenton a thermal time basis. The growth and development of the terminal (male) apex and thetwo uppermost axillary (female) apices followed the same patterns,with apex volumes increasing curvilinearly with increase innumber of leaf or husk primordia. The RGR(relative growth rateof volume) of the terminal apex was, however, only approximatelyone-tenth of the axillary apices. There was no difference ingrowth and development between the first and second axillaryapices before flowering: other factors, such as accumulationof dry weight, rather than primordia production, must be responsiblefor an axillary apex's potential to bear grain. Applied N, andto a lesser extent short days, increased the rates of growthand development of all the apices. For example, applied N increasedthe RGR (volume) of the apical domes, and the rate of productionof spikelet primordia, by about 25%. All axillary apices and treatments showed a single relationshipbetween number of spikelets and surface area of the ear: a favourableenvironment (e.g. high N) simply accelerated the progressionof spikelet production and area expansion along this singlepath. We conclude that this path is probably determined geneticallyand that N and time of sowing influence potential yield of maizethrough effects on the surface area of the ear but not on thedensity of spikelets formed. Key words: Maize, inflorescence, N application, daylength, temperature, apex volume     

Partitioning and Utilization of Carbon and Nitrogen in Nodulated Roots and Nodules of Chickpea (Cicer arietinum) Grown at Two Moisture Levels

The partitioning and utilization of carbon (C) and nitrogen(N) in nodulated roots and nodules of chickpea (Cicer arietinumL.) was studied at two moisture levels at 10-d intervals 40–140d after sowing (DAS). More C was used in respiration and lessin growth of nodulated roots and nodules under water stresscompared to controls during all growth stages except at theearly vegetative stage. Similarly, less nitrogen was investedin dry matter of both nodules and nodulated roots under stress,except during the vegetative stage where more nitrogen was used.Calculated over the entire growth period, as much as 14 and20% of the total nitrogen and 3 and 4% of the total carbon fixedby the plant was lost to the rooting medium under controlledand stressed conditions, respectively. The efficiency of nitrogen fixation with respect to net C utilizationwas maximal during seed filling under both control and stressconditions However, the efficiency of nitrogen fixation wasalways greater under drier conditions. Carbon, chickpea (Cicer arietinum L.), nitrogen, nitrogen fixation, partitioning     

The Influence of the Rht1 and Rht2 Alleles on the Growth of Wheat Stems and Ears

A field experiment was carried out with a set of near-isogenicspring wheat lines (cv. Triple Dirk) to determine the influenceof the Rht₁ and Rht₂ alleles on the partitioning of dry matterbetween the developing stem and the ear. Each line was sampledtwice weekly and dissected into its component above-ground parts.The rate of change of the dry mass of the individual plant organswas expressed as a proportion of the rate of change of the totalplant dry mass. This ratio was used to assess the relative sinkstrengths of the stem and ear during crop growth. The Rht₁ andRht₂ alleles reduced plant height, but increased grain yield.The greater yield was achieved through a greater grain numberper ear in the Rhtl line, a greater ear number per plant inthe Rht₂ line, and a greater allocation of assimilate to thedeveloping ear than to the developing stem in both Rht lines,particularly at the time of maximum stem growth (17 d beforeanthesis). From the earliest stages of detectable ear growthuntil anthesis, the ear masses per unit area of the Rht₁ andRht₂ lines exceeded that of Triple Dirk (Rht). It was not possibleto determine whether the Rht₁ and Rht₂ alleles were directlyresponsible for increasing grain number per ear and ear numberper plant, respectively, since the increase in these componentsof yield could equally be explained by a greater partitioningof assimilate to developing ears and tillers caused simply bya reduction in plant height. Triticum aestivum L., wheat Rht genes, stem and ear development, dry matter partitioning, allocation ratio     

Effects of Nitrogen on the Development and Growth of the Potato Plant. 2. The Partitioning of Dry Matter, Nitrogen and Nitrate

Potatoes (Solanum tuberosum L.) were planted in pots in a temperature-controlledglasshouse The treatments consisted of three levels of nitrogensupply, ie 25, 8 and 16 g N per pot (treatments called N1, N2and N3) The accumulation rates of dry matter and nitrogen showedan upper limit of response to nitrogen supply, N3 plants continuedto accumulate dry matter and N at a constant rate for a longerperiod of time than N2 and N1 plants The uptake of nitrogenslowed earlier in time than the rate of dry matter accumulationin all treatments. The proportion of the dry matter in tubersof mature plants was not affected by nitrogen treatment, butthe start of tuber bulking was delayed in the N3 plants Thefinal proportion of total plant nitrogen in the tubers was similarfor all treatments The concentration of nitrogen in the drymatter of mature plants increased with the level of N supplyMaximum haulm weight increased with the level of N supply Apicallateral branches of the first and second order made up largerproportions of the total haulm dry weight and total leaf areaas more nitrogen was supplied. Yet, the distribution of drymatter over stems and leaves was not different between nitrogentreatments Stems were the most responsive to N treatment interms of N concentrations In each of the component organs (stems, leaves, tubers) theconcentration of nitrogen declined with time Fairly strong associationswere observed between the concentrations of N in component organs.The concentration of nitrate in leaves usually increased initiallywith leaf age, peaked and declined. A substantial part of thedifferences between treatments in the concentrations of N inleaf dry matter were attributable to differences in nitrateconcentration Nitrate in stems and tubers fell virtually belowthe limit of detection at total nitrogen concentrations of lessthan 1%, but increased in proportion to total N above that threshold,especially in stems Potato, Solanum tuberosum L, dry matter production, dry matter distribution, nitrogen nutrition, nitrogen distribution, nitrogen concentration     

Dry Matter Assimilation and Partitioning in Pepper Cultivars Differing in Susceptibility to Stress-induced Bud and Flower Abscission

Stress-induced abscission of buds and flowers is a constraintto the production of peppers (Capsicum annuum L.). Susceptibilityof pepper cultivars to stress-induced abscission may be relatedto assimilate levels and partitioning. Growth analysis experimentswere conducted in the field to determine whether cultivars differingin susceptibility to stress-induced abscission showed correspondingdifferences in growth rates and dry matter partitioning whensubjected to low light stress. With the stress susceptible cultivar'Shamrock', reduction in net assimilation rate (NAR) and relativegrowth rate (RGR) was greater under low light stress than withthe more tolerant cultivar 'Ace'. Compared to 'Ace', 'Shamrock'partitioned a smaller proportion of dry matter into reproductiveorgans and a larger proportion into expanded leaves. Cultivarsdid not differ in the amount of dry matter partitioned to youngleaves or in the extent to which accumulation of dry matterby young leaves was reduced by low light stress. Other experimentsconducted in growth chambers and greenhouse examined the effectof removal of leaves less than 3 cm long on high temperatureand low light stress-induced bud and flower abscission. Forboth 'Ace' and 'Shamrock', abscission was not altered by removalof these leaves. Preferential partitioning of assimilate toyoung leaves does not appear to be involved in stress-inducedabscission in these pepper cultivars.Copyright 1994, 1999 AcademicPress Pepper (Capsicum annuum L.), abscission, low light stress, high temperature stress, assimilate partitioning, assimilation/growth rate, growth analysis, defoliation     

Nitrogen Uptake and Plant Growth II. An Empirical Model of Vegetative Growth and Partitioning

An empirical model of vegetative plant growth is presented.The model is based on experimental data on Polygonum cuspidatum,which showed (1) that the partitioning of dry matter and nitrogenamong organs was linearly related to the nitrogen concentrationof the whole plant and (2) that leaf thickness was negativelycorrelated with leaf nitrogen concentration. The model properlydescribes the behaviour of plants. Steady-state solutions ofthe model give the relative growth rate, specific leaf weight,and partitioning of dry matter and nitrogen among organs withthe net assimilation rate and the specific absorption rate asenvironmental variables. The effect of nitrogen removal on drymatter and nitrogen partitioning was examined as non-steady-statedynamic solutions of the model. The model predicted not onlyreduced leaf growth and enhanced root growth but also a fluxof nitrogen from the leaf to the root, which agreed with theexperimental results. Mathematical model, partitioning of dry matter and nitrogen, plant nitrogen, relative growth rate, shoot: root ratio, specific leaf weight     

油菜地上部干物质分配与产量形成模拟模型

利用油菜器官生长与发育进程及环境因子之间的定量关系,构建了基于分配指数的油菜地上部器官干物质分配动态模拟模型.各器官干物质分配指数随着生理发育时间而变化,基因型、播期、氮素及水分水平影响各器官干物质在地上部分配的大小.其中,氮素营养水平对绿色叶片干物质分配影响最大,氮素营养水平越高,绿色叶片分配指数越大;播期影响角果分配指数,晚播的角果分配指数高于早播.模型引入氮素营养指数、水分及播期影响因子来定量油菜各器官在实际生产条件下的分配强度,同时考虑了品种遗传特性的影响.通过不同品种氮肥处理试验建立模型,利用不同品种播期试验资料对模型进行了初步检验,表明模型具有较好的预测性和适用性.     

Partitioning of Dry Matter and the Deposition and Use of Stem Reserves in a Semi-dwarf Wheat Crop

An experiment was carried out within a crop of spring wheat(cv. Condor) to examine dry matter partitioning between thedeveloping stem and ear, and to estimate the magnitude of carbonstored in the stem both before and after anthesis, and the subsequentutilization of these reserves during grain growth. The amount of reserve laid down and mobilized was estimatedfrom analysis of data for changes in masses of stem and leaffrom frequent harvests. The rate of change of the dry mass ofthe individual plant organs was expressed as a proportion ofthe rate of change of the total dry mass of the large culm.This value was called the Allocation Ratio (AR). It was assumedthat assimilate was transferred directly from the stem intothe growing ear, and not into other organs. This paper providesevidence for the idea that the stem intemodes of wheat are ableto accumulate and subsequently mobilize a dry matter reserve.The accumulation and subsequent mobilization of fructans inthe stem was demonstrated using ascending thinlayer chromatography.On a dry matter basis the large culms of the wheat crop accumulatedall of their stem reserves after anthesis (0–41 g perlarge culm; 98·4 g m^–1). After adjusting the lossof mass by 33% to allow for respiration, it was concluded thatpost-anthesis stem reserves may have contributed at least 21%of the final grain yield of this crop. Triticum aestivum L., semi-dwarf spring wheat, dry matter partitioning, stem reserves, fructans     

The effect of sowing date and plant density on barley

Proctor and Maris Puma barleys were sown in October, early March, and late April at 50, 100, 200, 400 and 800 plants per m²and at low and high fertilizer levels. Shoot dry matter and grain dry matter showed no significant response to density for the first two sowings, but increased with increasing density in the last sowing. In all sowings the ear number per m²rose with increasing density, and grain number per ear fell, and there were only small interactions between density and sowing date, but the effect on weight per grain differed markedly in the last sowing from that in the first two sowings. Nitrogen concentration per cent of dry matter in the grain and in the straw showed little response to density and the values for both grain and straw were highest in the last sowing. Nitrogen content per m²for both shoot and grain at first rose, and then fell with increasing density. The maximum amount of nitrogen per m²was found at about 100 plants per m²in the early sowings, and at 400 plants per m²in the last sowing. The nitrogen data indicated a loss of nitrogen from the plant at high densities.     

Seed Weight inLolium perenneas Affected by Interactions among Seeds within the Inflorescence

Little is known about interactions between seeds within theinflorescence of perennial ryegrass (Lolium perenneL.) and theireffect on final seed weight. These relations were investigatedin two glasshouse experiments using two genotypes, by reducingthe number of seeds in an inflorescence at anthesis. In thefirst experiment, entire spikelets were removed to study therelations between seeds in different spikelets. The effectson seed dry weight were not proportional to the number of spikeletsremoved. In one genotype, removal of two-thirds of the spikeletsincreased seed dry weight of the remaining seeds by 15%. Inthe other genotype, such treatment did not increase seed dryweight. In the second experiment, investigating seed interactionswithin a spikelet, either two proximal seeds or two centralseeds were maintained in a spikelet by removing the other ovulesin combination with no or 75% shading. Shading by 75% reducedseed dry weight by about 10%. In the unshaded treatment, seeddry weight was not affected by ovule removal. Under shading,the central seeds in a spikelet were about 12% heavier if theygrew alone, in contrast to the proximal seeds. The effects ofa reduction in seed number on seed dry weight were not relatedto the final nitrogen concentration of seeds. These experimentsshow that assimilate partitioning and the relationship betweenseeds in the inflorescence of perennial ryegrass are alreadylargely determined at anthesis; increasing seed yield by manipulationsafter anthesis is not feasible.Copyright 1998 Annals of BotanyCompany. Lolium perenne, perennial ryegrass, seed growth, seed interactions, shading, spikelet removal.     

Consequences of Wheat Breeding on Nitrogen and Phosphorus Yield, Grain Nitrogen and Phosphorus Concentration and Associated Traits

Several studies have analysed the effects of wheat breedingon dry matter accumulation and partitioning, but little hasbeen done to understand the effects on nutrient economies. Theobjective of this study was to identify the changes producedby wheat breeding in the economy of nitrogen and phosphorusunder field conditions. Two experiments were carried out withseven genotypes (including a commercial hybrid) representingdifferent eras of plant breeding. Wheat breeding has increased grain nitrogen and phosphorus yieldbut total absorbed nutrients have not shown any trend duringthis century. The main attribute closely related to the increasein grain nitrogen and phosphorus yields was their harvest indices.The higher nutrient partitioning in the newer cultivars wasassociated with lower grain nitrogen and phosphorus concentrationsin their grains. Therefore, there was a negative effect of geneticimprovement in grain nitrogen and phosphorus concentrations.The main cause for the decreased concentration of these nutrientsin the grains of the modern cultivars appeared to be a dilutionby an even more increased dry matter partitioning. It is suggestedthat future breeding should be aimed to select for higher nitrogenuptake as a way to increase the level of this nutrient in grain.Copyright1995, 1999 Academic Press Triticum aestivum L., wheat breeding, genetic improvement, nitrogen, phosphorus, wheat, grain nitrogen concentration, grain phosphorus concentration     

Uptake and Partitioning of Nitrogen by Maize Infected withStriga hermonthica

The uptake and partitioning of nitrogen (N) by maize infectedwith the parasitic angiosperm,Striga hermonthicawas investigatedin sand culture in a glasshouse. The purpose was to determinethe effect ofStrigaon N uptake and partitioning in maize. Maizewas grown at 22, 66 and 133 mg N per plant and sampled fivetimes. There was no significantStrigaxN interaction in any measuredresponse. Leaf dry matter ofStriga-infected maize, averagedover all N treatments, was 92% that of uninfected maize at thefour-leaf stage but by the 18-leaf stage it had decreased to58%. Similarly, stem dry matter of infected maize which was91% that of uninfected maize at the four-leaf stage was only42% at the 18-leaf stage. Root dry matter was similar for infectedand uninfected maize. N concentration in the leaf, stem androot declined asymptotically from the first to the last samplingdate for both infected and uninfected maize. The asymptoticvalue of N concentration inStriga-infected maize was 16% greaterin the leaf, 55% in the stem, and 21% in the root than in uninfectedmaize. The concentration of N inStrigawas higher than in maizeat the 16- and 18-leaf stages. Uptake of N was similar for infectedand uninfected plants at the four–eight leaf stage butat the eight–12 leaf stage, N uptake by infected maizewas 52% that of uninfected maize. However, the proportion oftotal plant nitrogen partitioned to the root was greater (P<0.001)forStriga-infected maize. These results showed that the extentto whichS. hermonthicareduced maize growth and N uptake, butincreased the proportion of N partitioned to the roots, didnot depend on the rate of N fertilizer applied.Copyright 1998Annals of Botany Company Maize; nitrogen; partitioning;Striga hermonthica; uptake.     

Mixed Nitrogen Nutrition and Productivity of Wheat Grown in Hydroponics

The objective of this study was to study the effects of nitrogen(N) supplied as either mixtures of NO₃ and NH₄ or as all NO₃on the final yield of spring wheat. Two separate greenhouseexperiments evaluated the durum spring wheat (Triticum durumL.) cultivar ‘Inbar’ in 1986, and the hard red springwheat (Triticum aestmum L.) cultivar ‘Len’ in 1987.Nitrogen treatments consisted of all NO, or mixtures (75/25or 50/50) of NO₃ and NH₄. At maturity, plants were harvested,separated into leaves, stems, roots, and grain, and each partanalysed for dry matter and chemical composition Compared to plants receiving only NO₃ as the source of N, mixedN nutrition resulted in greater accumulation of whole plantreduced-N (49 to 108% more), phosphorus (38 to 69% more), andpotassium (25% more) for both cultivars. In all cases, plantsproduced higher grain yields (28% for Len to 78% for Inbar)when grown with mixed N nutrition than with only NO₃. The yieldincrease was not associated with heavier grains or more grainsper ear, but rather with an increase in the number of ear-bearingtillers per plant. For both cultivars, the higher yields withmixed N resulted from the production of more total biomass (36to 76%) as the partitioning of dry matter between plant partswas not altered by N treatment. Under the hydroponic conditionsof this experiment, the utilization of both NO₃ and NH₄ resultedin greater growth, nutrient absorption, and yield than NO₃ alone,which was primarily associated with an enhancement in tillerdevelopment Triticum aestivum L., Triticum durum L., spring wheat, hydroponics, ammonium nutrition, nitrate nutrition, tillering, yield components, partitioning     

The Influence of Genes for Vernalization Response on Development and Growth in Wheat

Studies were made of the influence of genes for vernalizationresponse on the growth and development of four near-isogeniclines of bread wheat (Triticum aestivum L.). The duration from sowing of flower initiation, terminal spikeletformation and ear emergence all increased with increasing vernalizationresponse. There was a close positive relationship between thedays from sowing to flower initiation and from sowing to earemergence, indicating that the duration of either phase of developmentis a useful measure of relative vernalization when daylengthdoes not limit the rate of development. Total spikelet number per ear and the duration of spikelet initationincreased with increasing vernalization response and there wasa correspondingly higher rate of spikelet initiation in thetwo lines with stronger vernalization response. Most of the differences in growth between the lines were associatedwith diferences in development caused by the vrn genes. Maximumtotal above-ground dry matter and total leaf area per plantincreased with increasing vernalization repsonse but relativegrowth rate and leaf area per plant were not significantly differentbetween the lines. There were no differences in net assimilationrate between the four lines until 40 d from sowing; thereafterit decreased, with the greatest decrease in the line with thestrongest vernalization response. Flower initiation, terminal spikelet formation, spikelet initiation, ear emergence, growth rate     

Accumulation and Partitioning of Dry Matter in Taro [Colocasia esculenta (L.) Schott]

A field study was conducted as part of an ongoing effort tocollect data on patterns of leaf area development and dry matteraccumulation and partitioning among various plant parts duringgrowth and development of two taro cultivars. Plants were harvestedfor biomass about every 6 weeks during the growing season. Ateach harvest, plants were separated into various plant parts,and their dry matter content was determined. The first 80 dafter planting were characterized by low rates of dry matteraccumulation, with only leaves, petioles, and roots showingsubstantial growth. Afterwards, increases in total dry matterwere mainly the result of corm and sucker growth. Corm bulkingoccurred after the attainment of maximal leaf area indices.The absence of an optimal leaf area index for a longer periodof time may have prevented the realization of higher dry matteryields. The partitioning of dry matter to the corms of bothcultivars remained almost constant especially after 150 d afterplanting. This process was in contrast to the partitioning ofdry matter to the suckers, which increased significantly untilthe end of the growing cycle.Copyright 1995, 1999 Academic Press Taro, Colocasia sp., growth, dry matter partitioning     

氮素对日光温室独本菊品种‘神马’干物质分配影响的模拟

 为定量研究氮素对日光温室独本菊(Dendranthema morifolium)干物质分配的影响, 该研究以独本菊品种‘神马’为试验材料, 于2005年10月～2006年7月在北京日光温室内进行了不同定植期和不同氮素水平的栽培试验, 以生理辐热积为发育尺度, 定量分析了氮素对独本菊品种‘神马’干物质分配指数动态的影响, 建立了氮素对日光温室独本菊品种‘神马’干物质分配影响的模拟模型, 并用与建立模型相独立的数据对模型进行了检验。结果表明, 独本菊品种‘神马’叶片累积氮含量最大值出现在现蕾期, 现蕾期叶片累积氮含量适宜值为1.62 g&#8226;m^–2。模型对日光温室独本菊品种‘神马’各器官干重预测结果较好, 茎、叶和花干重的预测值与实测值之间基于1:1线的决定系数分别为0.94、0.97和0.94, 相对预测误差分别为10.3%、5.76%和4.02%。该研究建立的模型可以根据温室内的气温、太阳辐射、日长和现蕾期叶片累积氮含量预测日光温室独本菊品种‘神马’各个器官干重随生育时期的动态变化, 从而为日光温室独本菊品种‘神马’生产中氮素的优化管理提供决策支持。     

Regulation of Growth at Steady-state Nitrogen Nutrition in Lettuce (Lactuca sativa L.): Interactive Effects of Nitrogen and Irradiance

The morphological and physiological adaptation of Lactuca sativaL. (‘Vegas’) to different irradiance levels andrates of nitrogen supply was analysed in such a way that effectsof irradiance were clearly distinguished from the effects ofnitrogen. Lettuce was grown in a glasshouse in aerated nutrientsolutions containing all necessary nutrients except nitrogen.Nitrogen was supplied in excess and at limiting rates in relationto plant growth to provide steady state nutrition. Shading theplants created the low irradiance level. The effects of nitrogensupply and irradiance on growth showed a marked interaction.Dry matter production decreased strongly with decreasing nitrogensupply at high irradiance, but decreased only slightly at lowirradiance. Nitrogen had no effect on radiation use efficiencyexcept for the lowest nitrogen treatment at high irradiance.The effect of nitrogen on growth was mainly mediated by itseffect on leaf area development and hence on light interception.Decreases in leaf area were due to decreases in specific leafarea and dry matter partitioning towards the leaves, while thedecrease in specific leaf area was the result of an increasein leaf dry matter percentage at low nitrogen supply. Dry matterand nitrogen partitioning, and nitrate concentration were closelyrelated to plant nitrogen concentration. Irradiance did notaffect these relationships. Irradiance influenced partitioningonly indirectly by affecting plant nitrogen concentration. Thedemand for organic nitrogen per unit leaf area was lower atlower irradiance. Organic nitrogen per unit leaf area appearedto be adjusted to the irradiance level, independently of thenitrogen supply, suggesting priority of nitrogen usage in photosynthesis.Copyright 2000 Annals of Botany Company Lactuca sativa L., lettuce, growth, irradiance, leaf area, nitrogen, radiation use efficiency, partitioning     

Nitrogen Uptake and Plant Growth I. Effect of Nitrogen Removal on Growth of Polygonum cuspidatum

Polygonun cuspidatum was grown hydroponically to examine theeffect of nitrogen removal from the nutrient solution upon plantgrowth and the partitioning of dry matter and nitrogen amongorgans. Nitrogen removal reduced the growth rate mainly dueto the reduced growth of leaf area. Accelerated root growthwas observed only in plants which earlier had received highlevels of nitrogen. Nitrogen removal caused almost exclusiveallocation of available nitrogen to root growth. Nitrogen fluxfrom the shoot to the root occurred in plants which had receivedlow nitrogen. Not only was net assimilation rate (NAR) littleaffected by nitrogen removal, but it also was not correlatedwith the concentration of leaf nitrogen on an area basis. Light-saturatedCO₂ exchange rate (CER) was highly correlated with the concentrationof leaf nitrogen. Nitrogen use efficiency (NUE) in CER (CERdivided by leaf nitrogen) remained constant against leaf nitrogen,indicating efficient use of nitrogen under light saturation,while NUE in terms of NAR decreased with higher concentrationof leaf nitrogen. Polygonum cuspidatum Sieb. et Zuce., CO₂ exchange rate, growth analysis, leaf nitrogen, net assimilation rate, nitrogen use efficiency, partitioning of dry matter and nitrogen     

Effect of nodulation on assimilate remobilization in soybean

The objectives of this work were to determine the effect of nodulation on dry matter, reduced-N, and phosphorus accumulation and partitioning in above-ground vegetative parts and pods of field-grown soybean (Glycine max [L.] Merr. cv Harosoy).

From comparison of nodulated and nonnodulated isolines, it was estimated that nodulated plants attained 81 and 71% of total-plant (above ground) N from uptake of soil N in 1981 and 1982, respectively. These data, along with visibly greener leaves of nodulated plants, led us to assume that nonnodulated plants were under a moderate N stress relative to nodulated plants. Nonnodulated plants accumulated less total-plant N and partitioned less dry matter and N to the pods, compared with nodulated plants. This occurred even though net photosynthesis, as estimated by rate and amount of dry matter accumulation, was the same for both nonnodulated and nodulated plants. Rate of dry matter and reduced-N accumulation in pods was less for nonnodulated than for nodulated plants while duration of podfill was similar for both isolines. From these data we concluded that moderate N stress affected partitioning of photosynthate rather than net photosynthesis, and that N played a role in translocation of photosynthate to the pods. Total plants (above-ground portion) and pods of both nodulated and nonnodulated plants accumulated similar amounts of phosphorus, which indicated that phosphorus and N accumulation were independent.

Remobilization of nitrogen and phosphorus from vegetation to pods preceded dry matter remobilization. It appeared that either more nitrogen accumulation prior to podfill, or continued nitrogen assimilation during podfill would increase nitrogen and dry matter partitioning to pods, but that increasing photosynthesis without concomitantly increasing nitrogen input may not necessarily result in enhanced seed production.