Root production and root mortality of winter barley and its implication with regard to phosphate acquisition

Winter barley was grown in a long-term fertilizer experiment (14 years) using two P treatments: (i) no P fertilization over the whole time (–P) and (ii) an annual fertilization of 44 kg P ha^–1 (+P). The objective of the study was to investigate the influence of the P supply on total root production and root mortality (i.e., root turnover) and to assess the benefit of a more rapid root turnover on P acquisition. Shoot development and grain yield was reduced in the – treatment, whereas the standing root system had nearly the same size as in the +P treatment. Gross root growth was measured using the ingrowth core method. Mesh bags filled with root-free soil were buried into the rooting zone (0–30 cm) and root growth into the bags over periods of 2–3 weeks was determined. Assuming that no root mortality occured inside the bags during this short period, root length in the bags will be a measure of total root production. Total root production between April and June exceeded the size of the standing root system by a factor of 2 to 3 and was significantly higher at P deficiency. Root mortality as the difference between total root production and the size of the standing root system was also increased at P shortage. P uptake was calculated by using a mechanistic transport and uptake model. Calculations based on gross root growth and root mortality resulted in a higher uptake than calculations based on the development of the standing root system, although the length of the active roots were the same in both calculations. This was due to a better exploitation of undepleted soil areas by the growing root system. The root renewal by a continuous root growth and root mortality is discussed as a mechanism of P uptake efficiency.     

Genotypic differences in phosphorus efficiency of wheat

In an attempt to evaluate whether breeding and selection for high yielding capacity did change the P requirements of modern wheat cultivars, the response of two wheat cultivars to different levels of P supply was investigated. A traditional cultivar ("Peragis") and a modern cultivar ("Cosir") were cultivated in a C-loess low in available P and high in CaCO₃ in 120 cm high PVC pots. Shoot and root growth at different developmental stages was compared. The grain yield of the modern cultivar Cosir was higher at limiting and non-limiting P supply and, therefore, this cultivar can be considered as more P-efficient than the traditional cultivar. From the results it can be concluded that the main factors contributing to the higher P efficiency of the modern cultivar are (i) efficient use of assimilates for root growth characteristics which enhance P acquisition: smaller root diameter, and longer root hairs, (ii) efficient remobilization of P from vegetative plant organs to the grains, and (iii) lower P requirement for grain yield formation because of lower ear number per plant but higher grain number per ear.     

Do Casuarina cunninghamiana seedlings dependent on symbiotic N2 fixation have higher phosphorus requirements than those supplied with adequate fertilizer nitrogen?

P requirements of Casuarina cunninghamiana seedlings inoculated with Frankia and reliant on symbiotic N2 fixation were compared with those of uninoculated seedlings grown with 4 levels of fertilizer N in a solution culture system.Growth responses to increasing P supply depended on the N treatment that had been imposed. At the two lowest levels of N supply (0 t M and 100 t M) growth was relatively poor and there was no response to increasing P supply above 10 t M and 50 t M P respectively. In contrast, inoculated seedlings and those with higher levels of combined N (500 t M and 1000 t M) had significantly greater shoot dry weights (except at 0.1 t M P), and they responded to increasing P supply to between 50 and 100 t M P. At each level of P supply, the dry weights of seedlings in these 3 N treatments were similar. Nitrogen concentrations in shoots of seedlings provided with fertilizer N decreased with increasing P supply to 50 t M and then remained unchanged. In contrast, N concentrations in shoots of inoculated seedlings increased with increasing P supply to 25 t M P. At the 2 highest levels of P supply, N concentrations in shoots of inoculated plants were significantly higher than those in seedlings provided with fertilizer N. In all N treatments, P concentrations in shoots increased with increasing P supply; concentrations were similar in inoculated seedlings and those with the 2 highest levels of fertilizer N across all levels of P supply.Alleviation of P deficiency in inoculated seedlings increased nodule number, nodule dry weight, N2 fixation g-1 nodule dry weight (nodule 'efficiency'), P concentration in nodules, proportion of total seedling biomass allocated to nodules and average nodule size. However, all these parameters reached their maximum values at levels of P supply at, or below, those required for maximum host-plant growth (50 to 100 t M P).The results indicate that the P requirement for host plant growth per se is similar to, or higher than, that required for symbiotic N2 fixation processes.     

不同磷浓度对玉米生长及磷、锌吸收的影响

在不同磷水平(0.1、1.0、5.0、10和100μmol·L^-1P)的水培液中培养玉米苗,测定不同培养时期玉米的生长和玉米植株对P、Zn吸收和利用效率.结果表明,玉米在100μmol·L^-1P的溶液中生长速率最大,而根冠比在0.1μmol·L^-1P的溶液中为最大.随着水培液中P水平的增加,植株对P的吸收速率增加,而利用效率降低;玉米根系含Zn量增加,而冠层含Zn量变化不大,说明增P使Zn在根内富集,Zn向冠层转移速率较小,玉米幼苗根系中P和Zn的浓度呈正相关关系.     

Changes in root-shoot ratio and ion uptake of maize (Zea mays L.) from soil as influenced by a plant growth regulator

A pot experiment with maize cv. Limac was conducted to investigate the influence of BAS 110.. W, a plant growth regulator (PGR), on root and shoot development and nutrient uptake. The PGR was applied via the soil with 0, 5, 10, 20, and 40 mg a.i. per pot. Shoot dry matter production was reduced to a higher degree than root length, resulting in a higher root-shoot ratio (RSR) of the treated plants. Shoots of treated plants contained higher concentrations of N, P, Ca, Mg, and unchanged K concentrations. The alterations in concentration could be explained by the changes in RSR induced by the plant growth retardant. The effect was strongest with P (+40%) which was limited by soil supply. N, Ca, and Mgconcentrations were positively influenced (+20%), there was no increase for Kvs RSR.     

The effect of soil phosphorus on the external mycelium growth of arbuscular mycorrhizal fungi during the early stages of mycorrhiza formation

The effects of soil P amendments and time of application on the formation of external mycelium by different arbuscular mycorrhizal (AM) fungi were studied. In the first experiment the external mycelium produced in the soil by the AM fungus Glomus etunicatum Beck. and Gerd., during the early stages of root colonization (7 and 14 days after inoculation), was quantified by the soil-agar film technique. A Brazilian Oxisol was used with three different phosphate levels, varying from deficient to supra-optimal for the plant. Significant differences were observed in the phosphate and inoculation treatments for plant dry weight, P content in the tissue, root length and root colonization, at fourteen days after planting. At 7 days, mycelium growth, root colonization and their relationship were reduced at supra-optimal P concentrations. Applications of P one week after planting reduced mycelium growth and root colonization more than when applied to the soil before planting. In a second experiment the arbuscular mycorrhizal (AM) fungi, Scutellospora heterogama (Nicol. and Gerd.) Walker and Sanders and E3 were tested and compared with Glomus etunicatum. For the species studied, the length of external hyphae per unit of colonized root length was affected by small P additions but no further significant differences were observed at high P levels. The three AM endophytes showed marked differences in their response to P in the soil: Scutellospora heterogama, although producing external mycelium more profusely than the Glomus spp., showed a higher sensitivity to soil P supply.     

Root morphology and its contribution to a large root system for phosphorus uptake by <Emphasis Type="Italic">Rytidosperma</Emphasis> species (wallaby grass)

Aims

Rytidosperma species are native Australian grasses which have different growth rates and phosphorus (P) requirements. This study examined the role of root morphology traits in response to P supply.

Methods

Nine Rytidosperma species ranging from slow- to fast-growth were examined along with Lolium perenne and Bromus hordeaceus. Plants were grown in a glasshouse for 47 days in soil supplied with six levels of P between 0 and 60 mg P per pot. Root mass, length and diameter, root hair length and density, and extent of mycorrhizal colonisation were measured.

Results

Across all species there was a positive correlation (P < 0.001) between P uptake and root mass, length and root hair cylinder volume (RHCV; estimated using root diameter, root hair length and root length) at all levels of P supply. An exception was the RHCV of B. hordeaceus, where expected P uptake was not achieved due to a markedly reduced root length at low-P supply. For the Rytidosperma species, morphological plasticity for specific root length, root mass fraction and root hair length ranged from 1.5-fold to 2.7-fold between high- and low-P supply. However, across all species and P levels no single root morphological trait was identified for universally increasing the size of the root system and P uptake.

Conclusions

Fast-growing species took up more P as a result of an overall larger root mass, greater root length and larger RHCV.

     

Phosphorus efficiency and the forms of soil phosphorus utilized by upland rice cultivars

Experimental measurements of phosphorus (P) uptake and the forms of soil P depleted from an Ultisol by 6 upland rice cultivars are reported. In both P-fertilized and-unfertilized soil, the majority of P taken up was solubilized from a 0.1 M NaOH-soluble pool by root-induced changes. The soil pH within 4 mm of the roots was lowered by up to 0.5 units (from 4.6), but this by itself could not account for the P solubilized, and nor could increased phosphatase activity near the roots. The possible role of root-released low molecular weight organic acid anions in P solubilization is discussed. No significant differences in the extent of solubilization by a given root mass could be detected between cultivars. In P-unfertilized soil, but not in P-fertilized soil, there were significant differences between cultivars in internal P efficiency as measured by shoot dry weight per unit total plant P. In unfertilized soil, root growth and P uptake were strongly correlated with the P content of the seeds from which the plants were grown.     

Nitrate supply and plant development influence nitrogen uptake and allocation under elevated CO<Subscript>2</Subscript> in durum wheat grown hydroponically

Growth in elevated CO₂ often leads to decreased plant nitrogen contents and down-regulation of photosynthetic capacity. Here, we investigated whether elevated CO₂ limits nitrogen uptake when nutrient movement to roots is unrestricted, and the dependence of this limitation on nitrogen supply and plant development in durum wheat (Triticum durum Desf.). Plants were grown hydroponically at two N supplies and ambient and elevated CO₂ concentrations. Elevated CO₂ decreased nitrate uptake per unit root mass with low N supply at early grain filling, but not at anthesis. This decrease was not associated with higher nitrate or amino acid, or lower non-structural carbohydrate contents in roots. At anthesis, elevated CO₂ decreased the nitrogen content of roots with both levels of N and that of aboveground organs with high N. With low N, elevated CO₂ increased N allocation to aboveground plant organs and nitrogen concentration per unit flag leaf area at anthesis, and per unit aboveground dry mass at both growth stages. The results from the hydroponic experiment suggest that elevated CO₂ restricts nitrate uptake late in development, high N supply overriding this restriction. Increased nitrogen allocation to young leaves at low N supply could alleviate photosynthetic acclimation to elevated CO₂.     

Physiological changes in, and phosphate uptake by potato plants during development of, and recovery from phosphate deficiency

The development of phosphate deficiency (P-stress) was observed in rooted sprouts of Solanum tuberosum L. cv. Desiree growing in solutions without phosphate. Shoot growth was inhibited by P-stress within 3 to 5 days of terminating the phosphate supply, while significant effects on root growth were not recorded until 7 to 9 days. Thus, the shoot:root dry weight ratio decreased from 4.3 to 2.6 over a 10-day period. Growth in the absence of an exogenous phosphate supply progressively diluted the phosphorus in the plant. The proportional decrease in concentration was similar in roots and shoots over a 7-day period, even though the former were growing more quickly. The potential for phosphate uptake per unit weight of root increased rapidly during the first 3 days of P-stress. When the plants were provided subsequently with a labelled, 1 mol m^?3 phosphate solution, the absorption rate was 3 to 4-fold greater than that of control plants which had received a continuous phosphate supply. The increased rate of uptake by P-stressed plants was accounted for by an increase (3-fold) in the V_max of system 1 for phosphate transport and by a marked increase in the affinity of the system for phosphate (decrease in K_m). In the early stages of P-stress, before marked changes in growth were measured, the proportion of labelled phosphate translocated to the shoots increased slightly relative to the controls when a phosphate supply was restored. In the later stages of stress a greater proportion was retained in the root system of P-stressed plants than in that of controls. In plants with roots divided between solutions containing or lacking a phosphate supply, the increased absorption rate was determined by the general demand for phosphate in the plant and not by the P-status of the particular root where uptake was measured. By contrast, the poportion translocated was strongly dependent on the P-status of the root. The restoration of a phosphate supply to P-stressed plants was marked by a rapid increase in the P concentration in snoots and roots which returned to levels similar to unstressed controls within 24 h. The enhanced uptake rate persisted for at least 5 days, resulting in supra-normal concentrations of P in both shoots and roots, and in the formation of extensive necrotic areas between the veins of mature leaves. Autoradiographs showed accumulations of ³²P in these lesions and at the points where guttation droplets formed on leaves.     

Impact of phosphorus supply on root exudation, aerenchyma formation and methane emission of rice plants

This study evaluated the impact of P supply on rice plant development and the methane budget of rice fields by 2 different approaches: (1) root growth, exudation and aerenchyma formation were recorded in an experiment with hydroponic solution; (2) dissolved CH₄ concentration and CH₄ emission were investigated in a pot experiment. In both approaches, we used three different cultivars and three levels of P supply. In the experiment with solution culture (0.5 ppm, 5 ppm, and 10 ppm P), root exudation ranged between 0.5 to 36.7 mol C plant^–1 h^–1 and increased steadily with plant growth at given P level. Low P supply resulted in

Effect of soil moisture and phosphate level on root hair growth of corn roots

Summary Root hairs have been shown to enhance P uptake by plants growing in low P soil. Little is known of the factors controlling root hair growth. The objective of this study was to investigate the influence of soil moisture and P level on root hair growth of corn (Zea mays L.). The effect of volumetric soil moistures of 22% (M₀), 27% (M₁), and 32% (M₂) and soil (Raub silt loam, Aquic Argiudoll) P levels of, 0.81 (P₀), 12.1 (P₁), 21.6 (P₂), 48.7 (P₃), and 203.3 (P₄) mol P L^–1 initially in the soil solution, on shoot and root growth, P uptake, and root hair growth of corn was studied in a series of pot experiments in a controlled climate chamber. Root hair growth was affected more by soil moisture than soil P. The percentage of total root length with root hairs and the density and length of root hairs on the root sections having root hairs all increased as soil moisture was reduced from M₂ to M₀. No relationship was found between root hair length and soil P. Density of root hairs, however, was found to decrease with an increase in soil P. No correlation was found between root hair growth parameters and plant P content, further suggesting P plays a secondary role to moisture in regulating root hair growth in soils. The increase in root hair growth appears to be a response by the plant to stress as yield and P uptake by corn grown at M₀ were only 0.47 to 0.82, and 0.34 to 0.74, respectively, of that measured at M₁ across the five soil P levels. The increase in root hair growth at M₀, which represents an increase of 2.76 to 4.03 in root surface area, could offset, in part, the reduced rate of root growth, which was the primary reason for reduced P uptake under limited soil moisture conditions.Journal Paper No. 10,066 Purdue Univ. Agric. Exp. Stn., W. Lafayette, IN 47907. Contribution from the Dep. of Agron. This paper was supported in part by a grant from the Tennessee Valley Authority.     

Grain Yield of Pennisetum americanum Adjusts to Nitrogen Supply by Changing Rates of Grain Filling and Root Uptake of Nitrogen

Coaldrake, P. D., Pearson, C. J. and Saffigna, P. G. 1987. Grainyield of Pennisetum americanum adjusts to nitrogen supply bychanging rates of grain filling and root uptake of nitrogen.–J.exp. Bot 38: 558–566. Pearl millet (Pennisetum americanum(L.)Leeke) was grown in containers at three constant rates of nitrogensupply or with the nitrogen supply increased from the lowestto the highest rate during panicle differentiation or at anthesis.We measured the rate and duration of nitrogen and dry weightgain by individual grains and nitrogen (¹⁵N) uptake by rootsand its distribution during grain filling. The total amountsof nitrogen and dry weight in all grain per plant at the lowestnitrogen supply were 8% and 14% respectively of plants growncontinuously at the highest rate of nitrogen. This was becauselow rates of nitrogen supply reduced grain number, mean grainweight and the nitrogen content of each individual grain. Theamino acid composition of the grain protein was affected onlyslightly by nitrogen treatments. Rates of grain growth were sensitive to nitrogen supply whereasthe duration of nitrogen movement to the grain was not. Nitrogenuptake by roots continued throughout grain filling; rates ofuptake per g root in plants given least nitrogen were one-halfthose of plants given the highest amount of nitrogen. A changefrom lowest to highest nitrogen supply at panicle differentiationincreased the uptake of nitrogen by roots and the rates of growthof individual grains, to the rates observed in plants whichhad been supplied continuously with the highest nitrogen. Whenthe change in supply was made at anthesis there was rapid movementof nitrogen into the plant but this was not translated intomore rapid grain growth. Key words: Nitrogen supply, Pennisetum americanum, grain yield, root uptake     

Top and root growth and nutrient absorption of Prunus avium L. at two soil pH and P levels

One-year-old Prunus avium L. were grown under greenhouse conditions in a Countesswells soil in all combinations of 2 pH and 2 P levels. The soil, obtained from a long-term liming and fertilizer experiment, provided pH values throughout the experiment of 3.75–3.99 (pH 1) and 4.81–5.41 (pH 2). The P treatments had 0.43% acetic acid extractable P of 31–44 g g^-1 (P1) and 145–173 g g^-1 (P2). The trees were harvested 92 (H1), 134 (H2), and 168 (H3) days after initiation of growth.Top (leaf+new stem) dry weight was significantly increased for pH 2 and P2 at H2 and H3. P2 also increased leaf weight (H1), the weight of the original stem-root (H2 and H3), and root length but decreased root diameter at both soil pHs (H2 and H3). Total tree uptake of N, P, K, Ca, and Mg was also increased by pH-P combinations which had significantly greater dry matter production and root length. Total Mn uptake decreased at pH2. Root nutrient inflows (uM m^-1 day^-1) were increased for Ca at pH2 and for P at P2. Mn inflow decreased at pH2 and at pH1 P2 although the increased root length associated with the latter treatmen resulted in increased total tree Mn uptake. In general, high nutrient inflows occurred in all trees at H1 and in severely stunted trees at pH1 P1; both had larger than average root diameters.     

Effect of soil solution phosphorus in Volcanic Ash soils on the response of tomato (Lycopersicum esculentum) to added phosphate

Summary Sorption isotherms of six Volcanic Ash soils were used to determine Optimum P, i.e. the amount of added P required to produce a soil solution concentration of 0.2 µg P per ml. In a pot test, application of these amounts of P to the soils led to maximum or near maximum growth of tomato plants, (Lycopersicum esculentum), harvested at 35 days. After harvest the soil solution concentration of P in all the soils had fallen below 0.2 µg per ml whatever the rate of P added initially. The amount of P required to restore the soil solution to 0.2 µg P per ml was linearly related to the fertilizer P originally applied to the soil; the higher the P applied originally the lower was the future P requirement. The regression coefficients suggested that the applied P would be twice as effective at reducing subsequent P requirement in a Recent Volcanic Ash soil than in the other more developed soils. Measurement of extractable Al (NH₄OAc at pH 4.2) showed that lack of growth at low levels of added P on a high P fixing soil could be caused by insufficient P due to high levels of Al, although with a soil of pH 6 this would not have been expected. re]19760217     

Responses of various crop species and cultivars to fertilizer application

Summary Crop response to fertilizer application depends not only on the level of available plant nutrients in the soil but is also related to crop physiology and morphology. For a well balanced nutrition the rate of nutrient supply to the roots must correspond with the rate of nutrient required for growth. Species or cultivars with a high growth rate generally respond more favourably to fertilizer application than those with low growth rates. An analogous relationship holds for the biomass produced per unit soil surface. Thus modern rice and wheat cultivars tolerate a more dense spacing than older ones. Due to the dense stand the yield and particularly the grain yield of the modern varieties may be several times higher than those of older cultivars, and therefore also the nutrient requirement, especially the demand for N and P, is higher for the modern cultivars.Modern cereal cultivars are characterized by a high crop index which means that after flowering a high proportion of grain filling material must be produced by photosynthesis. Assimilation and translocation of photosynthates are favoured by K⁺. Thus in particular modern cultivars require a high K⁺ content for optimum grain filling.Nutrient exploitation of soils by plant roots depends on root morphology and root physiology. Grasses generally have much longer roots than dicots. Thus the rate of K⁺ and phosphate uptake per unit root length is lower for grasses than for dicots. It is for this reason that dicots respond earlier to a K⁺ and phosphate dressing than grasses.Species living symbiotically with Rhizobium may depress the rhizosphere pH considerably and thus promote the dissolution of phosphate rock.     

Adaptive shoot and root responses collectively enhance growth at optimum temperature and limited phosphorus supply of three herbaceous legume species

Background and Aims

Studies on the effects of sub- and/or supraoptimal temperatures on growth and phosphorus (P) nutrition of perennial herbaceous species at growth-limiting P availability are few, and the impacts of temperature on rhizosphere carboxylate dynamics are not known for any species.

Methods

The effect of three day/night temperature regimes (low, 20/13 °C; medium, 27/20 °C; and high, 32/25 °C) on growth and P nutrition of Cullen cinereum, Kennedia nigricans and Lotus australis was determined.

Key Results

The highest temperature was optimal for growth of C. cinereum, while the lowest temperature was optimal for K. nigricans and L. australis. At optimum temperatures, the relative growth rate (RGR), root length, root length per leaf area, total P content, P productivity and water-use efficiency were higher for all species, and rhizosphere carboxylate content was higher for K. nigricans and L. australis. Cullen cinereum, with a slower RGR, had long (higher root length per leaf area) and thin roots to enhance P uptake by exploring a greater volume of soil at its optimum temperature, while K. nigricans and L. australis, with faster RGRs, had only long roots (higher root length per leaf area) as a morphological adaptation, but had a higher content of carboxylates in their rhizospheres at the optimum temperature. Irrespective of the species, the amount of P taken up by a plant was mainly determined by root length, rather than by P uptake rate per unit root surface area. Phosphorus productivity was correlated with RGR and plant biomass.

Conclusions

All three species exhibited adaptive shoot and root traits to enhance growth at their optimum temperatures at growth-limiting P supply. The species with a slower RGR (i.e. C. cinereum) showed only morphological root adaptations, while K. nigricans and L. australis, with faster RGRs, had both morphological and physiological (i.e. root carboxylate dynamics) root adaptations.     

Changes in root size and distribution in relation to nitrogen accumulation during maize breeding in China

Background and aims

Modern maize breeding has increased maize yields worldwide. The changes in above-ground traits accompanying yield improvement are well-known, but less information is available as to the effect of modern plant breeding on changes in maize root traits.

Methods

Root growth, nitrogen uptake, dry matter accumulation and yield formation of six maize hybrids released from 1973 to 2000 in China were compared. Experiments were conducted under low and high nitrogen supply in a black soil in Northeast China in 2010 and 2011.

Results

While nitrogen accumulation, dry matter production and yield formation have been increased, modern maize breeding in China since 1990 has reduced root length density in the topsoil without much effect on root growth in the deeper soil. The efficiency of roots in acquiring N has increased so as to match the requirement of N accumulation for plant growth and yield formation. The responses of root growth, nitrogen and dry matter accumulation, and grain yield to low-N stress were similar in the more modern hybrids as in the older ones.

Conclusions

Modern maize breeding has constitutively changed root and shoot growth and plant productivity without producing any specific enhancement in root responsiveness to soil N availability.     

In vitro organogenesis and somatic embryogenesis from punctured leaf of Populus nigra × P. maximowiczii

Various explant sources of Populus nigra × P. maximowiczii were used to examine the effects of growth hormones on morphogenesis in vitro. Initial experiments indicated that punctured leaves were superior to non-punctured ones for both callus growth and formation of shoots and roots on MS medium containing various types and concentrations of growth hormones. After 6 weeks in culture, an average of 178 shoots, 129 roots and 3.1 g fresh weight of callus were directly produced from the abaxial side of each punctured leaf. The best combinations of growth hormones for shoot, root and callus proliferation were 0.88 M BA plus 0.05 M 2,4-D, 0.44 M BA plus 2.69 M NAA and 0.44 M BA plus 2.26 M 2,4-D, respectively. Embryoids were also formed on callus derived from punctured leaves. The number of embryoids varied from 0 to 30 per punctured leaf. Adventitious shoots also developed simultaneously with the embryos. Embryoids were removed with a scalpel at the early developmental stages and placed on MS medium lacking growth regulators. Regenerated plantlets were transferred to pots containing vermiculite for normal growth in the greenhouse.     

Interaction between aluminium and phosphorus in sorghum plants

A solution culture experiment was carried out to study the effects of interactions between aluminium (Al) and phosphorus (P) on Al-toxicity under conditions of suboptimal P supply. The experiment was conducted in a growth chamber with seedlings of the Al-sensitive sorghum genotype TAM428 (Sorghum bicolor (L.) Moench). Phosphorus deficiency differed from Al toxicity in its effect on shoot/root ratio and root morphological charateristics. Results indicated that there were positive effects of Al on the uptake and assimilation of P. Therefore, it was unlikely that an Al-induced P deficiency could account for the observed reduction in plant biomass. Plants suffered more from Al toxicity at very low P supply. Moreover, decreasing P supply resulted in increased root H-ion efflux density. In the soil, where a rhizosphere can be formed, this would make the plant even more susceptible to Al. Dry matter yield of the plants was affected more severely by Al at the first harvest (14 days) than at the second (35 days), but the opposite was true for P. Aluminium-inhibited root development and reduced uptake of N, K and Mg (but not Ca) may be partly responsible for the growth depression. Increasing the P supply exerted certain roles in eliminating Al phytotoxicity, possibly through improved root development and nutrient uptake. The detrimental influence of Al on biomass could be overcome by doubling the P supply.