硝态氮(NO-3)对水稻侧根生长及其氮吸收的影响

侧根是植物吸收利用土壤养分的重要器官,其生长发育受内部遗传因子和外部环境矿质养分的影响.通过琼脂分层培养发现:局部供应NO-3可以诱导水稻( Oryza sativa L.)主根或不定根上侧根的生长.为研究旱种条件下NO-3对水稻侧根发育及其N吸收的影响,设置了3个蛭石培养实验:分根处理、全株缺N、全株供N处理.分根处理(一半根系供应3 mmol/L KNO3,另一半根系供应3 mmol/L KCl)结果表明:局部供应NO-3 能够促进水稻侧根生长.而在全株处理下,N饥饿诱导了侧根的伸长.水稻根系对NO-3的这两种反应都存在着显著的基因型差异.同时对地上部N浓度、可溶性总糖含量及N含量分析表明,这些生理指标在分根处理与全株加N处理中的差异均不显著,表明分根处理也能基本满足植株正常生长对N的需求.在分根处理中,水稻的N含量与分根处理中供N一侧的平均侧根长度存在显著正相关,这表明在养分不均一的介质中,侧根长度对水稻N素吸收具有十分重要的作用.而在N素充足的条件下,两者之间的相关性并不显著,这暗示在养分充足的环境下,侧根长度可能并不是决定根系吸收N素的主要因素.     

硝态氮（NO3^—）对水稻侧根生长及其氮吸收的影响

侧根是植物吸收利用土壤养分的重要器官 ,其生长发育受内部遗传因子和外部环境矿质养分的影响。通过琼脂分层培养发现 :局部供应NO-3 可以诱导水稻 (OryzasativaL .)主根或不定根上侧根的生长。为研究旱种条件下NO-3 对水稻侧根发育及其N吸收的影响 ,设置了 3个蛭石培养实验 :分根处理、全株缺N、全株供N处理。分根处理 (一半根系供应 3mmol/LKNO3,另一半根系供应 3mmol/LKCl)结果表明 :局部供应NO-3 能够促进水稻侧根生长。而在全株处理下 ,N饥饿诱导了侧根的伸长。水稻根系对NO-3 的这两种反应都存在着显著的基因型差异。同时对地上部N浓度、可溶性总糖含量及N含量分析表明 ,这些生理指标在分根处理与全株加N处理中的差异均不显著 ,表明分根处理也能基本满足植株正常生长对N的需求。在分根处理中 ,水稻的N含量与分根处理中供N一侧的平均侧根长度存在显著正相关 ,这表明在养分不均一的介质中 ,侧根长度对水稻N素吸收具有十分重要的作用。而在N素充足的条件下 ,两者之间的相关性并不显著 ,这暗示在养分充足的环境下 ,侧根长度可能并不是决定根系吸收N素的主要因素     

黄腐酸对水稻幼苗根系生长的影响及其与生长素的关系北大核心CSCD

该研究以水稻品种‘宁粳6号’为材料,通过外源使用黄腐酸(FA)与生长素抑制剂共同处理水稻,探究FA对水稻根系生长的影响及其与生长素之间的关系。结果表明:(1)50~800 mg·L^(-1) FA处理水稻幼苗6 d后,当FA浓度超过100 mg·L^(-1)时显著促进水稻种子根的伸长生长;FA浓度超过400 mg·L^(-1)时,与对照组相比水稻的平均侧根长和侧根密度显著增加。(2)与对照相比,低浓度FA处理对水稻幼苗根尖生长素的含量无显著影响,但400 mg·L^(-1) FA处理后显著提高了内源生长素的含量。(3)3μmol·L^(-1)生长素合成抑制剂4-联苯硼酸(BBo)、4-苯氧基苯基硼酸(PPBo)或30μmol·L^(-1)生长素信号转导抑制剂2-(对-氯苯氧)-异丁酸(PCIB)处理均可显著抑制水稻根和侧根的发生;1μmol·L^(-1)生长素极性运输抑制剂三碘苯甲酸(TIBA)可显著抑制水稻种子根的伸长生长与侧根发生,但对侧根长度无显著作用。(4)FA与BBo或PPBo共同处理可显著抑制FA对水稻根系伸长生长与侧根发生的促进作用;TIBA和PCIB分别和FA共同处理水稻,可显著抑制FA对种子根伸长生长的促进作用,且PCIB可显著抑制FA对侧根发生的促进作用,但TIBA对此没有显著影响。研究发现,外源FA可能通过调控植物内源生长素的合成、极性运输或信号转导来调控水稻根的伸长生长和侧根的发育。     

茉莉酸对水稻侧根发生的影响

实验材料为水稻(Oryza sativa L.)栽培品种"IR8"(国际水稻所8号)及其少侧根突变体MT10.将2 d水稻幼苗种子根全部浸入0.016～50 μmol/L 茉莉酸(JA)溶液处理2 d,结果表明JA显著抑制种子根的伸长,其抑制程度与JA浓度成正比.不高于2 μmol/L的JA显著促进侧根的发生,每cm的侧根数目随浓度的增加而增加,最多可增加到原来的168%("IR8")和285%(MT10).10 μmol/L的JA仍促进处理过程中和处理后生成根区段的侧根数目的增加,但明显抑制处理前生成根区段侧根的发生,每cm的侧根数目有所下降.     

茉莉酸对水稻侧根发生的影响

实验材料为水稻 (OryzasativaL .)栽培品种“IR8”(国际水稻所 8号 )及其少侧根突变体MT10。将 2d水稻幼苗种子根全部浸入 0 .0 16～ 5 0 μmol/L茉莉酸 (JA)溶液处理 2d ,结果表明JA显著抑制种子根的伸长 ,其抑制程度与JA浓度成正比。不高于 2 μmol/L的JA显著促进侧根的发生 ,每cm的侧根数目随浓度的增加而增加 ,最多可增加到原来的 16 8% (“IR8”)和 2 85 % (MT10 )。 10 μmol/L的JA仍促进处理过程中和处理后生成根区段的侧根数目的增加 ,但明显抑制处理前生成根区段侧根的发生 ,每cm的侧根数目有所下降     

镉对花生幼苗生长及生理生态特性的影响

通过溶液培养,研究不同浓度镉(Cd2 ,0～1.00mmoL/L)时花生幼苗生长及生理生态特性的影响.结果表明,Cd2 影响花生种子的萌发和幼苗的生长.当Cd2 浓度高于0.50mmol/L时,显著抑制种子的发芽率,随Cd2 浓度的增加,苗高、根长和侧根数减少;叶绿素含量随Cd2 浓度的增加而下降,过氧化物酶(POD)活性随Cd2 浓度增加而增加;丙二醛(MDA)含量同样呈上升趋势;超氧化物歧化酶(SOD)与根系活力表现为低浓度下升高、超过0.5mmoL/L后下降的变化趋势.     

玉米氮素吸收的基因型差异及其与根系形态的相关性

采用溶液培养的方法,选用在田间、土培试验中对氮反应有典型差异的玉米自交系：478、H21、Wu312、Zong31、Baici,在4个供N水平（0.04、0.4、2.4mmol/L）下,研究了玉米苗期氮素吸收、分配的基因差异以及与根系形态之间的相关关系,结果表明：在一定的NO3^-浓度范围内（0.04-2mmol/L）,根系生物量随N水平的提高而增加,而高N不同程度地降低了5个自交系根系干重。低N下（0.04mmol/L）,与其它自交系相比,N高效基因型478具有较大的根系生物量,其根系干重分别为H21、Wu312、Zong31、Baici的1.1、1.74、1.6、1.18倍,并往根系分配了较大比例的N素,根系N累积占总N量的百分率比Wu312、Zong31分别高18.34％、17.08％,而N低效基因型Wu312、Zong31则往地上部分配了较大比例的氮素。随N水平的增加,显著促进了地上部的生长,并在地上部分配了较大比例的N素。当N水平增至4mmol/L时,地上部N素分配的基因型差异减小。低N下,5个自交系根系干重、总根长、根轴总长与总吸N量显著线性相关,而高N下不表现相关关系,说明在N素胁迫的条件下,根系形态对N吸收效率起重要作用。     

化感物质对枯草芽孢杆菌(Bacillus subtilis)在厌氧条件下的生长及反硝化作用的影响

研究由秸秆腐解产生的化感物质 :阿魏酸 ( t-FA)、对羟基苯甲酸 ( p-HA)和苯甲酸 ( BA)在不同浓度下对厌氧培养的枯草芽孢杆菌 ( Bacillussubtilis)的生长及其反硝化活性的影响。结果表明 ,3种浓度的阿魏酸 ( 5.1 5、2 .58、0 .2 6mmol/L)均表现出对枯草芽孢杆菌的生长有抑制作用。对羟基苯甲酸 ( 0 .3 6、3 .62、7.2 4 mmol/L )对生长影响不明显。 8.1 9mmol/L和 4 .0 9mmol/L的苯甲酸有一定的刺激作用 ,而 0 .4 1 mmol/L的苯甲酸与对照无差别。实验表明枯草芽孢秆菌不仅能转化 NO- 3生成 NO- 2 ,而且还能转化 NO- 2 生成 N2 O。 3种化感物质对 NO- 3的转化均表现抑制作用 ,其抑制作用强弱依次为阿魏酸 >对羟基苯甲酸 >苯甲酸。高浓度的抑制作用强于低浓度。阿魏酸在 5.1 5mmol/L和 2 .58mmol/L浓度下 ,其抑制作用的差异显著性分别为 P<0 .0 1 ,P<0 .0 5。 NO- 2 的生成与 NO- 3的减少相互有关联 ,第 3天测定时 ,各处理中NO- 3急剧减少 ,而 NO- 2 急剧增加。在阿魏酸、苯甲酸处理中的 NO- 2 积累高峰在第 3天、第 4天 ,然后下降。而在对羟基苯甲酸的处理中 NO- 2 的积累一直上升 ,在第 6天的观察中仍未出现下降趋势。 3种化感物质均能抑制 N2 O的生成 ,至于在田间的抑制效果尚需进一步试验     

硝酸镧浸种对NaCl胁迫下柳枝稷种子萌发及幼苗生理特性的影响

为探讨镧对NaCl胁迫下柳枝稷种子萌发及幼苗生理特性的影响,该研究以柳枝稷(Panicum virgatum L.)种子为研究材料,通过不同浓度(0、0.05、0.1、0.5和1.0mmol/L)La(NO3)3溶液浸种24h处理后,添加100mmol/L NaCl溶液,以蒸馏水为对照,在种子发芽箱中培养并观察柳枝稷种子萌发和幼苗生长,测定幼苗叶片相对电导率、丙二醛、脯氨酸和叶绿素的含量。结果显示:(1)0.05mmol/L La(NO3)3浸种处理可缓解100mmol/L NaCl对种子发芽的影响。(2)不同处理对幼苗苗长无显著影响,0.1mmol/L La(NO3)3浸种显著增加了幼苗的鲜重和叶面积,当浓度≥0.5mmol/L时根长、根冠比、鲜重和叶面积受到抑制。(3)幼苗叶片相对电导率和脯氨酸含量随La(NO3)3浓度的增加呈先降低后增加的趋势,其中0.05和0.1mmol/L La(NO3)3浸种处理下效果较好,丙二醛含量随La(NO3)3浓度的增加持续降低,但各浓度处理间差异不显著,叶绿素含量在0.05mmol/L La(NO3)3浸种处理下较NaCl处理显著增加,当浓度≥0.5mmol/L随着浸种浓度的增加呈下降趋势。(4)不同指标间发芽势与发芽率、根长和叶绿素含量间呈极显著正相关关系,与根冠比、电导率和脯氨酸含量均呈极显著负相关关系,而与苗长不相关。研究表明,低浓度(0.05mmol/L)La(NO3)3可缓解NaCl胁迫对柳枝稷种子萌发及幼苗生长的影响,而高浓度(1.0mmol/L)的La(NO3)3则会加重NaCl的胁迫危害。     

翠菊根系养分捕获形态塑性及其生理机制

为验证以下3个假设: 1) NO₃ ^-和NH₄ ⁺及其不同供给方式显著影响根系生长; 2) NO₃ ^-和NH₄ ⁺以及不同供给方式对根内激素含量影响显著; 3)根构型(1级根长、单位2级根上1级侧根密度(分枝强度)和1级根在2级根上的根间距)与根内激素(生长素(IAA)、脱落酸(ABA)和细胞分裂素(玉米素核苷+玉米素) (CK (ZR + Z))含量显著相关, 采用营养液培养方法, 使实验植物翠菊(Callistephus chinensis)在两种氮肥(NO₃ ^-和NH₄ ⁺)、不同施氮浓度(NO₃ ^-: 0.2、1.0和18.0 mmol·L ^-1; NH₄ ⁺: 0.2、4.0和20.0 mmol·L ^-1), 以及脉冲和稳定两种施用方式处理下生长。在处理35天后收获植物, 测定根系生物量、根系构型指标(根系1级根长、单位2级根上1级侧根数和1级根在2级根上的根间距)和根系中激素含量(IAA、ABA和CK (ZR + Z))。结果显示: 1)实验处理对根生物量和根系中IAA、ABA和CK (ZR + Z)含量均有不同程度的显著影响: 施用NH₄ ⁺使根生物量和根内IAA含量显著低于施用NO₃ ^-; 高浓度NO₃ ^-和NH₄ ⁺处理亦使根生物量和IAA降低; 相对于稳定处理, 脉冲施氮显著降低根生物量和根内IAA含量; NO₃ ^-使根内CK (ZR + Z)含量显著高于施用NH₄ ⁺, 且与施氮浓度及施氮方式无关; NO₃ ^-处理下, 高浓度使根内ABA含量提高, 且脉冲处理使ABA含量升高。NH₄ ⁺处理下, 高浓度使根内ABA含量降低, 而施氮方式对其没有显著影响。2)根构型因素与根内激素关系各异: 各激素与1级根间距无显著关系; IAA和CK (ZR + Z)与1级根长和侧根密度有显著回归关系。3)根构型因素与根生物量的关系是根生物量与1级根长和侧根密度有显著正回归关系, 与1级根间距无显著回归关系。实验结果表明翠菊根生长的 “反常”可能是由于其对脉冲高浓度NH₄ ⁺耐受阈值低所致。该研究通过实验建立了氮养分种类/供应方式通过改变激素、影响根构型而影响根生长的联系, 进一步探究了植物根养分捕获塑性机制。     

Possible Involvement of Cytokinin in Nitrate-mediated Root Growth in Maize

Response of root system architecture to nutrient availability in soils is an essential way for plants to adapt to soil environments. Nitrate can affect root development either as a result of changes in the external concentration, or through changes in the internal nutrient status of the plant. Nevertheless, less is known about the physiological mechanisms. In the present study, two maize (Zea mays L.) inbred lines (478 and Wu312) were used to study a possible role of cytokinin in nitrate-mediated root growth in nutrient solutions. Root elongation of 478 was more sensitive to high nitrate supply than that of Wu312. Medium high nitrate (5 mM) inhibited root elongation in 478, while, root elongation in Wu312 was only inhibited at high NO ₃ ⁻ supply (20 mM). Under high nitrate supply, the root elongation zone in 478 became swollen and the site of lateral root elongation was close towards the root tip. Both of the phenomena are typical of root growth induced by exogenous cytokinin treatments. Correspondingly, zeatin and zeatin nucleotide (Z + ZR) concentrations were increased at higher nitrate supply in 478, whereas they were constant in Wu312. Furthermore, exogenous cytokinin 6-benzylaminopurine (6-BA) completely reversed the stimulatory effect of low nitrate on root elongation. Therefore, it is supposed that the inhibitory effect of high concentration of nitrate on root elongation is, at least in part, mediated by increased cytokinin level in roots. High nitrate supply may have negative influences on root apex activity by affecting cytokinin metabolism so that root apical dominance is weakened and, therefore, root elongation is suppressed and lateral roots grow closer to the root apex. Nitrate suppressed lateral root elongation in Wu312 at concentration higher than 5 mM. In 478, however, this phenomenon was not significant even at 20 mM nitrate. Although exogenous 6-BA (20 nM) could suppress lateral root elongation as well, the inhibitory effect of high NO ₃ ⁻ concentration of nitrate on lateral root growth cannot be explained by changes in endogenous cytokinin alone.     

A central role for the nitrate transporter NRT2.1 in the integrated morphological and physiological responses of the root system to nitrogen limitation in Arabidopsis

Up-regulation of the high-affinity transport system (HATS) for NO(3)(-) and stimulation of lateral root (LR) growth are two important adaptive responses of the root system to nitrogen limitation. Up-regulation of the NO(3)(-) HATS by nitrogen starvation is suppressed in the atnrt2.1-1 mutant of Arabidopsis (Arabidopsis thaliana), deleted for both NRT2.1 and NRT2.2 nitrate transporter genes. We then used this mutant to determine whether lack of HATS stimulation affected the response of the root system architecture (RSA) to low NO(3)(-) availability. In Wassilewskija (Ws) wild-type plants, transfer from high to low NO(3)(-) medium resulted in contrasting responses of RSA, depending on the level of nitrogen limitation. Moderate nitrogen limitation (transfer from 10 mm to 1 or 0.5 mm NO(3)(-)) mostly led to an increase in the number of visible laterals, while severe nitrogen stress (transfer from 10 mm to 0.1 or 0.05 mm NO(3)(-)) promoted mean LR length. The RSA response of the atnrt2.1-1 mutant to low NO(3)(-) was markedly different. After transfer from 10 to 0.5 mm NO(3)(-), the stimulated appearance of LRs was abolished in atnrt2.1-1 plants, whereas the increase in mean LR length was much more pronounced than in Ws. These modifications of RSA mimicked those of Ws plants subjected to severe nitrogen stress and could be fully explained by the lowered NO(3)(-) uptake measured in the mutant. This suggests that the uptake rate of NO(3)(-), rather than its external concentration, is the key factor triggering the observed changes in RSA. However, the mutation of NRT2.1 was also found to inhibit initiation of LR primordia in plants subjected to nitrogen limitation independently of the rate of NO(3)(-) uptake by the whole root system and even of the presence of added NO(3)(-) in the external medium. This indicates a direct stimulatory role for NRT2.1 in this particular step of LR development. Thus, it is concluded that NRT2.1 has a key dual function in coordinating root development with external NO(3)(-) availability, both indirectly through its role as a major NO(3)(-) uptake system that determines the nitrogen uptake-dependent RSA responses, and directly through a specific action on LR initiation under nitrogen-limited conditions.     

土施L-蛋氨酸、L-苯基丙氨酸、L-色氨酸对玉米生长和养分吸收的影响

通过盆栽试验,研究了3种植物生长调节剂前体物质对玉米生长发育和养分吸收的影响,并确定了其适宜用量.结果表明,土施L蛋氨酸(L-MET)、L-苯基丙氨酸(L-PHE)和L-色氨酸(L-TRP)能不同程度地增加玉米株高、地上部和地下部干重,提高玉米根系活力、体内硝酸还原酶和过氧化氢酶的活性,促进玉米对氮、磷、钾、锌养分的吸收.在所有供试浓度中,以土施L-MET0.0185～0.185mg·kg^-1、L-PHE0.2mg·kg^-1和L-TRP0.03～0.3mg·kg^-1效果最佳,而且L-PHE和L-TRP对玉米生长的促进作用和提高养分的吸收能力均优于L-MET.     

Elevated pCO(2 )favours nitrate reduction in the roots of wild-type tobacco (Nicotiana tabacum cv. Gat.) and significantly alters N-metabolism in transformants lacking functional nitrate reductase in the roots

The impact of elevated pCO(2 )on N-metabolism of hydroponically grown wild-type and transformed tobacco plants lacking root nitrate reduction was studied in order to elucidate the effects on (i) nitrate uptake, (ii) long-distance transport of N, (iii) nitrate reduction with emphasis on root-NR, and (iv) the allocation of N between the root and shoot. The findings were related to alterations of growth rates. At elevated pCO(2 )the wild type exhibited higher growth rates, which were accompanied by an increase of NO(3)(-)-uptake per plant, due to a higher root:shoot ratio. Furthermore, elevated pCO(2 )enhanced nitrate reduction in the roots of the wild type, resulting in enhanced xylem-loading of organic N (amino-N) to supply the shoot with sufficient nitrogen, and decreased phloem-transport of organic N in a basipetal direction. Transformed tobacco plants lacking root nitrate reduction were smaller than the wild type and exhibited lower growth rates. Nitrate uptake per plant was decreased in transformed plants as a consequence of an impeded root growth and, thus, a significantly decreased root:shoot ratio. Surprisingly, transformed plants showed an altered allocation of amino-N between the root and the shoot, with an increase of amino-N in the root and a substantial decrease of amino-N in the shoot. In transformed plants, xylem-loading of nitrate was increased and the roots were supplied with organic N via phloem transport. Elevated pCO(2 )increased shoot-NR, but only slightly affected the growth rates of transformed plants, whereas carbohydrates accumulated at elevated pCO(2 )as indicated by a significant increase of the C/N ratio in the leaves of transformed plants. Unexpectedly, the C/N balance and the functional equilibrium between root and shoot growth was disturbed dramatically by the loss of nitrate reduction in the root.     

Diurnal variation in uptake and xylem contents of inorganic and assimilated N under continuous and interrupted N supply to Phleum pratense and Festuca pratensis

Compensation by dark-period uptake of NH(4)(+) and NO(3)(-) in the grasses Phleum pratense L. and Festuca pratensis Huds. following N deprivation during the preceding light period was investigated in flowing solution culture under an artificial 10/14 h light/dark cycle. N was supplied as either NO(3)(-), NH(4)(+) or NH(4)NO(3) at 20+/-5 mmol m(-3), available continuously or only during the dark period, for 5-10 d. Intermittent N supply did not affect total daily N uptake, growth rate or net partitioning of dry matter. Net uptake and influx of NO(3)(-) varied similarly throughout the diurnal cycle when NO(3)(-) was supplied continuously, with a marginal contribution by NO(3)(-) efflux. Influx was significantly higher and efflux slightly higher following interruption of NO(3)(-) supply during the light period. Nitrate accounted for 80% of N in xylem exudate except between hours 6-9 of the light period when the amino acid concentration increased 3-fold, primarily as glutamine. Diurnal variation in relative NO(3)(-) uptake exhibited five phases of constant acceleration/deceleration, described reasonably well assuming NO(3)(-) influx was subject to metabolic co-regulation by NO(3)(-) and amino acid levels in the cytoplasmic compartment of the roots. Accordingly, influx is determined by variation in root NO(3)(-) levels throughout the dark period and the first half of the light period, but is down-regulated by increased amino acid levels during the second half of the light period. The sharp light/dark transitions affect transpiration rate and hence xylem N flux which, in turn, affect NO(3)(-) levels in the cytoplasmic compartment of the roots and the rate of NO(3)(-) assimilation in the shoot.     

Overexpressing the ANR1 MADS-box gene in transgenic plants provides new insights into its role in the nitrate regulation of root development

The expression of the ANR1 MADS-box gene was manipulated in transgenic plants to investigate its role in the NO(3)(-)-dependent regulation of root development in Arabidopsis thaliana. Constitutive overexpression of ANR1 in roots, achieved using GAL4 enhancer trap lines, resulted in more rapid early seedling development, increased lengths and numbers of lateral roots and increased shoot fresh weight. Based on results obtained with five different enhancer trap lines, the overexpression of ANR1 in the lateral root tips appears to be more important for this phenotype than its level of expression in the developing lateral root primordia. Dexamethasone-mediated induction of ANR1 in lines expressing an ANR1-GR (glucocorticoid receptor) fusion protein stimulated lateral root growth but not primary root growth. Short-term (24 h) dexamethasone treatments led to prolonged stimulation of lateral root growth, whether the lateral roots were already mature or still unemerged at the time of treatment. In split-root experiments, localized application of dexamethasone to half of the root system of an ANR1-GR line elicited a localized increase in both the length and numbers of lateral roots, mimicking the effect of a localized NO(3)(-) treatment. In both types of transgenic line, the root phenotype was strongly dependent on the presence of NO(3)(-), indicating that there are additional components involved in ANR1 function that are NO(3)(-) regulated. The implications of these results for our understanding of ANR1's mode of action in the root response to localized NO(3)(-) are discussed.     

Morphological compatibility of white clover and perennial ryegrass cultivars grown under two nitrate levels in flowing solution culture

The effects of nitrate (NO3-) supply on shoot morphology, vertical distribution of shoot and root biomass and total nitrogen (N) acquisition by two perennial ryegrass (Lolium perenne L.) cultivars (AberElan and Preference) and two white clover (Trifolium repens L.) cultivars (Grasslands Huia and AberHerald) were studied in flowing nutrient culture. Cultivars were grown from seed as monocultures and the clovers inoculated with Rhizobium. The 6-week measurement period began on day 34 (grasses) and day 56 (clovers) when the NO3- supply was adjusted to either 2 mmol m-3 (low nitrogen, LN) or 50 mmol m-3 (high nitrogen, HN). These treatments were subsequently maintained automatically. Plants were harvested at intervals to measure their morphology and N content. Cultivars of both species differed significantly in several aspects of their response to NO3- supply. In the grasses, the LN treatment increased the root : shoot ratio of AberElan but did not affect the distribution of root length in the root profile. In contrast, this treatment changed the root distribution of Preference compared with HN, resulting in a larger proportion of root length being distributed further down the root profile. The morphology of white clover Grasslands Huia was for the most part unaffected by the level of NO3- supply. In contrast, AberHerald exhibited different growth strategies, with LN plants increasing their stolon weight per unit length at the expense of leaf production, leaf area and stolon length, whereas HN plants showed reduced stolon thickness, greater leaf area production and stolon length per plant. Cultivars with different morphological/physiological strategies in response to NO3- supply may be of value in the construction of 'compatible mixtures' aimed at reducing oscillations in sward clover content by extending the range of conditions that allow balanced coexistence of species to occur.