Effects of monovalent cations on phosphate accumulation and storage of the ectomycorrhizal fungus Suillus bovinus

Comparative in vivo ³¹P-NMR studies of the fungus Suillus bovinus (L.: Fr.) O. Kuntze in pure culture have produced interesting new data. To investigate the response of phosphate metabolism to a change in external monovalent cations, samples were exposed to a Hoagland solution containing different monovalent cations Li⁺, Na⁺, K⁺, or Rb⁺ at 10 mM concentration. A method of nutrient cycling during analysis where the cation was changed and the phosphate kept constant allowed us to determine the kinetics of phosphate accumulation, storage and incorporation into polyphosphate following exposure to the range of test cations. Different external monovalent cations had different effects upon changes in the content of both phosphate and polyphosphate. Treatment with Li⁺, Na⁺, or Rb⁺ resulted in a change in phosphate accumulation to 60, 73, and 107% and in content of the intracellular mobile polyphosphate (polyP) to 119, 112, and 94%, respectively, compared with the control taken as 100%. The effect of each cation is related to its position in the periodic table. Reversing this process, i.e., exchanging with K⁺, returned phosphate metabolism to normal. Although, the increase in depolarization of the cell membrane should affect the internal pH, fungal metabolism using energy requiring mechanisms appeared necessary to maintain the intracellular pH. Thus, increasing contents of mobile polyP were the consequence of an increasing energy demand. On the other hand, the increasing depolarization of the cell membrane following the sequence Rb⁺ < K⁺ < Na⁺ < Li⁺ inhibited the net P_i accumulation. Furthermore, it is postulated that the P_i accumulation was also regulated by the intracellular content in polyP.     

Characterization of a proton-translocating ATPase in microsomal vesicles from corn roots

Sealed microsomal vesicles were prepared from corn (Zea mays, Crow Single Cross Hybrid WF9-Mo17) roots by centrifugation of a 10,000 to 80,000g microsomal fraction onto a 10% dextran T-70 cushion. The Mg²⁺-ATPase activity of the sealed vesicles was stimulated by Cl⁻ and NH₄⁺ and by ionophores and protonophores such as 2 micromolar gramicidin or 10 micromolar carbonyl cyanide p-trifluoromethoxyphenyl hydrazone (FCCP). The ionophore-stimulated ATPase activity had a broad pH optimum with a maximum at pH 6.5. The ATPase was inhibited by NO₃⁻, was insensitive to K⁺, and was not inhibited by 100 micromolar vanadate or by 1 millimolar azide.

Quenching of quinacrine fluorescence was used to measure ATP-dependent acidification of the intravesicular volume. Quenching required Mg²⁺, was stimulated by Cl⁻, inhibited by NO₃⁻, was insensitive to monovalent cations, was unaffected by 200 micromolar vanadate, and was abolished by 2 micromolar gramicidin or 10 micromolar FCCP. Activity was highly specific for ATP. The ionophore-stimulated ATPase and ATP-dependent fluorescence quench both required a divalent cation (Mg²⁺ ≥ Mn²⁺ > Co²⁺) and were inhibited by high concentrations of Ca²⁺. The similarity of the ionophore-stimulated ATPase and quinacrine quench and the responses of the two to ions suggest that both represent the activity of the same ATP-dependent proton pump. The characteristics of the proton-translocating ATPase differed from those of the mitochondrial F₁F₀-ATPase and from those of the K⁺-stimulated ATPase of corn root plasma membranes, and resembled those of the tonoplast ATPase.

     

Evidence that arbuscular mycorrhizal and phosphate-solubilizing fungi alleviate NaCl stress in the halophyte Kosteletzkya virginica: nutrient uptake and ion distribution within root tissues

The effects of an arbuscular mycorrhizal (AM) fungus, Glomus mosseae, and a phosphate-solubilizing microorganism (PSM), Mortierella sp., and their interactions, on nutrient (N, P and K) uptake and the ionic composition of different root tissues of the halophyte Kosteletzkya virginica (L.), cultured with or without NaCl, were evaluated. Plant biomass, AM colonization and PSM populations were also assessed. Salt stress adversely affected plant nutrient acquisition, especially root P and K, resulting in an important reduction in shoot dry biomass. Inoculation of the AM fungus or/and PSM strongly promoted AM colonization, PSM populations, plant dry biomass, root/shoot dry weight ratio and nutrient uptake by K. virginica, regardless of salinity level. Ion accumulation in root tissues was inhibited by salt stress. However, dual inoculation of the AM fungus and PSM significantly enhanced ion (e.g., Na⁺, Cl^?, K⁺, Ca²⁺, Mg²⁺) accumulation in different root tissues, and maintained lower Na⁺/K⁺ and Ca²⁺/Mg²⁺ ratios and a higher Na⁺/Ca²⁺ ratio, compared to non-inoculated plants under 100 mM NaCl conditions. Correlation coefficient analysis demonstrated that plant (shoot or root) dry biomass correlated positively with plant nutrient uptake and ion (e.g., Na⁺, K⁺, Mg²⁺ and Cl^?) concentrations of different root tissues, and correlated negatively with Na⁺/K⁺ ratios in the epidermis and cortex. Simultaneously, root/shoot dry weight ratio correlated positively with Na⁺/Ca²⁺ ratios in most root tissues. These findings suggest that combined AM fungus and PSM inoculation alleviates the deleterious effects of salt on plant growth by enabling greater nutrient (e.g., P, N and K) absorption, higher accumulation of Na⁺, K⁺, Mg²⁺ and Cl^? in different root tissues, and maintenance of lower root Na⁺/K⁺ and higher Na⁺/Ca²⁺ ratios when salinity is within acceptable limits.     

Mechanisms of Aluminum Tolerance in Wheat : An Investigation of Genotypic Differences in Rhizosphere pH, K, and H Transport, and Root-Cell Membrane Potentials

Control of rhizosphere pH and exclusion of Al by the plasma membrane have been hypothesized as possible mechanisms for Al tolerance. To test primarily the rhizosphere pH hypothesis, wheat cultivars (Triticum aestivum L. `Atlas 66' and `Scout'), which differ in Al tolerance, were grown in either complete nutrient solution, or 0.6 millimolar CaSO₄, with and without Al at pH 4.50. A microelectrode system was used to simultaneously measure rhizosphere pH, K⁺, and H⁺ fluxes, and membrane potentials (E_m) along the root at various distances from the root apex. In complete nutrient solution, the rhizosphere pH associated with mature root cells (measured 10-40 millimeters from the root apex) of Al-tolerant `Atlas 66' was slightly higher than that of the bulk solution, whereas roots of Al-sensitive `Scout' caused a very small decrease in the rhizosphere pH. In CaSO₄ solution, no significant differences in rhizosphere pH were found between wheat cultivars, while differential Al tolerance was still observed, indicating that the rhizosphere pH associated with mature root tissue is not directly involved in the mechanism(s) of differential Al tolerance. In Al-tolerant `Atlas 66', growth in a CaSO<sub>4</sub> solution with 5 micromolar Al (pH 4.50) had little effect on net K<sup>+</sup> influx, H<sup>+</sup> efflux, and root-cell membrane potential measured in cells of mature root tissue (from 10-40 mm back from apex). However, in Al-sensitive `Scout', Al treatment caused a dramatic inhibition of K⁺ influx and both a moderate reduction of H⁺ efflux and depolarization of the membrane potential. These results demonstrate that increased Al tolerance in wheat is associated with the increased ability of the tolerant plant to maintain normal ion fluxes and membrane potentials across the plasmalemma of root cells in the presence of Al.     

Influx and efflux of p in roots of intact maize plants : double-labeling with p and p

Rates of P influx and efflux were determined in whole plants at ambient P concentrations comparable to those found in soil solutions. Maize (Zea mays L. var NC+59) seedlings were trimmed (endosperm and adventitious roots removed) and grown in a greenhouse in solution cultures at P concentrations of approximately 0.4 and 1.8 micromolar. Roots of intact plants previously exposed to ³²P-labeled solutions at 0.2 and 2.0 micromolar P for 48 hours were rinsed 10 minutes in P-free solution and exposed to ³³P solutions at 0.2 and 2.0 micromolar for 10 minutes. Net depletion of ³³P from and appearance of ³²P in the ambient solution were used to measure influx and efflux. The ration of ³²P efflux to ³³P influx was about 0.68 at 0.2 micromolar and 0.08 at 2.0 micromolar. When plants were allowed to deplete P from solutions, the P concentration in the medium dropped to about 0.15 micromolar within 24 hours and 0.05 micromolar within 60 hours. Results indicate that P efflux is a substantial component of net P accumulation at P concentrations normally found in soil solutions.     

Sodium-dependent succinate uptake in purple bacterium Ectothiorhodospira shaposhnikovii

Succinate, malate and fumarate uptake in purple sulfur bacterium Ectothiorhodospira shaposhnikovii, strain 1 K MSU, obligatorily depends on the presence of Na⁺. Other monovalent cations such as K⁺, Li⁺, NH₄⁺ could not replace Na⁺. Experiments with energy-depleted cells have shown that succinate uptake against its concentration gradient can be energized by artificially imposed sodium gradients (ΔpNa).An artificial membrane potential (inside negative) inhibited ΔpNa-driven succinate uptake at pH 7.0 but stimulated it at pH 9.0.The results confirm the suggestion that succinate uptake in E. shaposhnikovii is carried out in symport with Na⁺.     

Correlation between monovalent cation-induced decreases in chlorophyll a fluorescence and chloroplast structural changes

Low concentrations (~ 3 mm) of salts of monovalent cations such as Na⁺, K⁺, and tetraethylammonium were found to decrease the turbidity of chloroplast suspensions. The turbidity changes (Δ₅₄₀) had the same kinetics, salt concentration dependence, and pH dependence as the monovalent cation-induced decreases in chlorophyll a fluorescence (9), suggesting that structural changes are the cause of the associated increases in spillover. Electron microscopy revealed that the grana are stacked when spillover is inhibited (in the absence of salts or the presence of divalent cations) and that monovalent cations cause the grana to unstack, thereby promoting spillover.     

Rubidium transport in Neurospora crassa

Rb⁺ transport in low-K⁺ cells of Neurospora crassa is biphasic, transport at millimolar Rb⁺ being added to a transport process which saturates in the micromolar range. Both processes exhibit Michaelis-Menten kinetics, but in the micromolar phase the kinetic parameters depend on the K⁺ content of the cell (the lower the K⁺ content the lower the K_m and the higher the V_max). Normal-K⁺ cells, suspended in a buffer with millimolar K⁺, do not present Rb⁺ transport in the micromolar range. Millimolar transport in these cells presents kinetics which depend on the K⁺ in buffer (the higher the K⁺ the higher the K_m), although the K⁺ content of the cells is constant. Na⁺ inhibits competitively Rb⁺ transport in low-K⁺ and normal-K⁺ cells, but, even when the differences between the Rb⁺K_m values are more than three orders of magnitude, the apparent dissociation constant for Na⁺ is the same, and millimolar, in both cases.     

Influences of phosphorus starvation on OsACR2.1 expression and arsenic metabolism in rice seedlings

The effects of phosphorus (P) status on arsenate reductase gene (OsACR2.1) expression, arsenate reductase activity, hydrogen peroxide (H₂O₂) content, and arsenic (As) species in rice seedlings which were exposed to arsenate after ?P or +P pretreatments were investigated in a series of hydroponic experiments. OsACR2.1 expression increased significantly with decreasing internal P concentrations; more than 2-fold and 10-fold increases were found after P starvation for 30 h and 14 days, respectively. OsACR2.1 expression exhibited a significant positive correlation with internal root H₂O₂ accumulation, which increased upon P starvation or exposure to H₂O₂ without P starvation. Characterization of internal and effluxed As species showed the predominant form of As was arsenate in P-starved rice root, which contrasted with the +P pretreated plants. Additionally, more As was effluxed from P-starved rice roots than from non-starved roots. In summary, an interesting relationship was observed between P-starvation induced H₂O₂ and OsACR2.1 gene expression. However, the up-regulation of OsACR2.1 did not increase arsenate reduction in P-starved rice seedlings when exposed to arsenate.     

Boron induces hyperpolarization of sunflower root cell membranes and increases membrane permeability to k

Although many studies have alluded to a role for boron (B) in membrane function, there is little evidence for a direct effect of B on the plasmalemma of higher plant cells. These studies were conducted to demonstrate, by electrophysiological techniques, a direct effect of B on the membrane potential (E_m) of sunflower (Helianthus annuus [L.], cv Mammoth Grey Stripe) root tip cells and to determine if the response to B occurs rapidly enough to account for the previously observed effects of B on ion uptake. By inserting a glass microelectrode into an individual cell in the root tip, the E_m of the cell was determined in basal salt medium (BSM), pH 6.0. The perfusion solution surrounding the root tissue was then changed to BSM + 50 micromolar H₃BO₃, pH 6.0. The exposure to B induced a significant plasmalemma hyperpolarization in sunflower root cells within 20 minutes. After just 3 minutes of exposure to B, the change in E_m was already significantly different from the negligible change in E_m observed over time in root cells never exposed to B. Membrane hyperpolarization could be caused by a stimulation of the proton pump or by a change in the conductance of one or more permeable ions. Since B has been shown to affect K⁺ uptake by plants, the electrophysiological techniques described above were used to determine if B has an effect on membrane permeability to K⁺, and could thereby lead to an increased diffusion potential. When sunflower root tips were pretreated in 50 micromolar B for 2 hours, cell membranes exhibited a significantly greater depolarization with each 10-fold increase in external [K⁺] than minus-B cells. Subsequent studies demonstrated that the depolarization due to increased external [K⁺] was also significantly greater when tissue was exposed to B at the same time as the 10-fold increase in [K⁺], indicating that the effect of B on K⁺ permeability was immediate. Analysis of sunflower root tips demonstrated that treatment in 50 micromolar B caused a significantly greater accumulation of K⁺ after 48 hours. The B-induced increase in K⁺ uptake may cause a subsequent stimulation of the H⁺-ATPase (proton pump) and lead to the observed hyperpolarization of root cell membranes. Alternatively, B may stimulate the proton pump, with the subsequent hyperpolarization resulting in an increased driving force for K⁺ influx.     

Influence of the level of nitrate nutrition on ion uptake and assimilation, organic Acid accumulation, and cation-anion balance in whole tomato plants

Tomato plants (Lycopersicon esculentum L. var. Ailsa Craig) were grown in water culture in nutrient solution in a series of 10 increasing levels of nitrate nutrition. Using whole plant data derived from analytical and yield data of individual plant parts, the fate of anion charge arising from increased NO₃ assimilation was followed in its distribution between organic anion accumulation in the plant and OH⁻ efflux into the nutrient solution as calculated by excess anion over cation uptake. With increasing NO₃ nutrition the bulk of the anion charge appeared as organic anion accumulation in the plants. OH⁻ efflux at a maximum accounted for only 20% of the anion charge shift. The major organic anion accumulated in response to nitrate assimilation was malate. The increase in organic anion accumulation was paralleled by an increase in cation concentration (K⁺, Ca²⁺, Mg²⁺, Na⁺). Total inorganic anion levels (NO₃⁻, SO₄²⁻, H₂PO₄⁻, Cl⁻) were relatively constant. The effect of increasing NO₃ nutrition in stimulating organic anion accumulation was much more pronounced in the tops than in the roots.     

Increased cucumber salt tolerance by grafting on pumpkin rootstock and after application of calcium

Self-grafted and pumpkin rootstock-grafted cucumber plants were subjected to the following four treatments: 1) aerated nutrient solution alone (control), 2) nutrient solution with 10 mM Ca(NO₃)₂ (Ca), 3) nutrient solution with 90 mM NaCl (NaCl), and 4) nutrient solution with 90 mM NaCl + 10 mM Ca(NO₃)₂ (NaCl+Ca). The NaCl treatment decreased the plant dry mass and content of Ca²⁺ and K⁺ but increased the Na⁺ content in roots and shoots. Smaller changes were observed in pumpkin rootstock-grafted plants. Supplementary Ca(NO₃)₂ ameliorated the negative effects of NaCl on plant dry mass, relative growth rate (RGR), as well as Ca²⁺, K⁺, and Na⁺ content especially for pumpkin rootstock-grafted plants. Supplementary Ca(NO₃)₂ distinctly stimulated the plasma membrane (PM) H⁺-ATPase activity which supplies the energy to remove excess Na⁺ from the cells. The expressions of gene encoding PM H⁺-ATPases (PMA) and gene encoding a PM Na⁺/H⁺ antiporter (SOS1) were up-regulated when Ca(NO₃)₂ was applied. The pumpkin rootstock-grafted plants had higher PM H⁺-ATPase activity as well as higher PMA and SOS1 expressions than the self-grafted plants under NaCl + Ca treatment. Therefore, the addition of Ca²⁺ in combination with pumpkin rootstock grafting is a powerful way to increase cucumber salt tolerance.     

A Ca/H Antiport System Driven by the Proton Electrochemical Gradient of a Tonoplast H-ATPase from Oat Roots

Two types of ATP-dependent calcium (Ca²⁺) transport systems were detected in sealed microsomal vesicles from oat roots. Approximately 80% of the total Ca²⁺ uptake was associated with vesicles of 1.11 grams per cubic centimeter and was insensitive to vanadate or azide, but inhibited by NO₃⁻. The remaining 20% was vanadate-sensitive and mostly associated with the endoplasmic reticulum, as the transport activity comigrated with an endoplasmic reticulum marker (antimycin A-insensitive NADH cytochrome c reductase), which was shifted from 1.11 to 1.20 grams per cubic centimeter by Mg²⁺.

Like the tonoplast H⁺-ATPase activity, vanadate-insensitive Ca²⁺ accumulation was stimulated by 20 millimolar Cl⁻ and inhibited by 10 micromolar 4,4′-diisothiocyano-2,2′-stilbene disulfonic acid or 50 micromolar N,N′-dicyclohexylcarbodiimide. This Ca²⁺ transport system had an apparent K_m for Mg-ATP of 0.24 millimolar similar to the tonoplast ATPase. The vanadate-insensitive Ca²⁺ transport was abolished by compounds that eliminated a pH gradient and Ca²⁺ dissipated a pH gradient (acid inside) generated by the tonoplast-type H⁺-ATPase. These results provide compelling evidence that a pH gradient generated by the H⁺-ATPase drives Ca²⁺ accumulation into right-side-out tonoplast vesicles via a Ca²⁺/H⁺ antiport. This transport system was saturable with respect to Ca²⁺ (K_m apparent = 14 micromolar). The Ca²⁺/H⁺ antiport operated independently of the H⁺-ATPase since an artifically imposed pH gradient (acid inside) could also drive Ca²⁺ accumulation. Ca²⁺ transport by this system may be one major way in which vacuoles function in Ca²⁺ homeostasis in the cytoplasm of plant cells.

     

Induction of Myxospore Formation in Stigmatella aurantiaca (Myxobacterales) by Monovalent Cations

Suspension cultures of Stigmatella aurantiaca can be induced to form myxospores by addition of the monovalent cations Li⁺, Na⁺, NH₄⁺, K⁺, or Rb⁺.     

Temporal variation in nutrient uptake capacity by intact roots of mature loblolly pine

Nutrient uptake is generally thought to exhibit a simple seasonal pattern, but few studies have measured temporal variation of nutrient uptake capacity in mature trees. We measured net uptake capacity of K, NH⁺₄, NO₃^–, Mg and Ca across a range of solution concentrations by roots of mature loblolly pine at Calhoun Experimental Forest in October 2001, July 2001, and April 2002. Uptake capacity was generally lowest in July; rates in October were similar to those in April. Across a range of concentrations, antecedent nutrient solution concentrations affected the temporal patterns in uptake in July but not in October or April. In July, uptake of NH⁺₄, Mg and Ca was positively correlated with concentration when roots were exposed to successively lower concentrations, but negatively correlated with concentration when exposed to successively higher concentrations. In contrast, uptake in October was constant across the range of concentrations, while uptake increased with concentration in April. As in studies of other species, we found greater uptake of NH⁺₄ than NO₃^–. Temporal patterns of uptake capacity are difficult to predict, and our results indicate that experimental conditions, such as experiment duration, antecedent root conditions and nutrient solution concentration, affect measured rates of nutrient uptake.     

Cadmium uptake kinetics in intact soybean plants

The absorption characteristics of Cd²⁺ by 10- to 12-day-old soybean plants (Glycine max cv Williams) were investigated with respect to influence of Cd concentration on adsorption to root surfaces, root absorption, transport kinetics and interaction with the nutrient cations Cu²⁺, Fe²⁺, Mn²⁺, and Zn²⁺. The fraction of nonexchangeable Cd bound to roots remained relatively constant at 20 to 25% of the absorbed fraction at solution concentration of 0.0025 to 0.5 micromolar, and increased to 45% at solution concentration in excess of 0.5 micromolar. The exchangeable fraction represented 1.4 to 32% of the absorbed fraction, and was concentration dependent. Using dinitrophenol as a metabolic inhibitor, the `metabolically absorbed' fraction was shown to represent 75 to 80% of the absorbed fraction at concentration less than 0.5 micromolar, and decreased to 55% at 5 micromolar. At comparatively low Cd concentrations, 0.0025 to micromolar 0.3, root absorption exhibited two isotherms with K₂ values of 0.08 and 1.2 micromolar. Root absorption and transfer from root to shoot of Cd²⁺ was inhibited by Cu²⁺, Fe²⁺, Mn²⁺, and Zn²⁺. Analyses of kinetic interaction of these nutrient cations with Cd²⁺ indicated that Cu²⁺, Fe²⁺, Zn²⁺, and possibly Mn²⁺ inhibited Cd absorption competitively suggesting an involvement of a common transport site or process.     

Electropotential in excised pea epicotyls

In contrast to intact etiolated pea seedling tissue (Pisum sativum L.), excised segments immersed in a complete nutrient solution show marked increases in ion content, largely of K⁺ and NO₃⁻, over a 72-hour period. During this time there is increase in cell electropotential difference, PD. During the initial 6 to 8 hours there is a lag in ion uptake; cell PD, however, increases rapidly from approximately −50 to −100 mv then increases more slowly. The increase in PD precedes and thus may be a prerequisite for the rapid ion accumulation phase. Cell PD increases in either water or nutrient solution but eventually reaches higher levels in the latter. Following water pretreatment of sufficient duration K⁺ accumulation shows no lag period. The lag phase noted here appears dissimilar to that of storage tissues.     

Effectiveness of potassium sulfate in mitigating salt-induced adverse effects on different physio-biochemical attributes in sunflower (Helianthus annuus L.)

To assess whether foliar application of K+S as potassium sulfate (K₂SO₄) could alleviate the adverse effects of salt on sunflower (Helianthus annuus L. cv. SF-187) plants, a greenhouse experiment was conducted. There were two NaCl levels (0 and 150 mM) applied to the growth medium and six levels of K+S as K₂SO₄ (NS (no spray), WS (spray of water+0.1% Tween 20 solution), 0.5% K+0.21% S, 1.0% K+0.41% S, 1.5% K+0.62% S, and 2.0% K+0.82% S in 0.1% Tween-20 solution) applied two times foliarly to non-stressed and salt-stressed sunflower plants. Salt stress markedly repressed the growth, yield, photosynthetic pigments, water relations and photosynthetic attributes, quantum yield (F_v/F_m), leaf and root K⁺, Mg²⁺, P, Ca²⁺, N as well as K⁺/Na⁺ ratios, while it enhanced the cell membrane permeability, and leaf and root Na⁺ and Cl⁻ concentrations. Foliar application of potassium sulfate significantly improved growth, achene yield, photosynthetic and transpiration rates, stomatal conductance, water use efficiency, leaf turgor and enhanced shoot and leaf K⁺ of the salt-stressed sunflower plants, but it did not improve leaf and root Na⁺, Cl⁻, Mg²⁺, P, Ca²⁺, N as well as K⁺/Na⁺ ratios. The most effective dose of K+S for improving growth and achene yield was found to be 1.5% K+0.62% S and 1% K+0.41% S, respectively. Improvement in growth of sunflower plants due to exogenously applied K₂SO₄ was found to be linked to enhanced photosynthetic capacity, water use efficiency, leaf turgor and relative water content.     

Multiphasic accumulation of nutrients by plants

Seedlings of rice (Oryza sativa), soybean (Glycine max) and sour orange (Citrus aurantium) were grown for 20 to 125 days under controlled conditions in nutrient solutions wiht up to 16 different concentrations of NH⁴₊, H₂PO₄^-, K⁺, Ca²⁺, Mg²⁺ or Zn²⁺. Nutrient concentrations differed by up to 4 orders of magnitude (H₂PO₄^- and Zn²⁺) and were kept constant or within certain limits by changing solutions daily. Dry weights and concentrations of N, P, K, Ca, Mg or Zn were determined for roots and tops (or roots, stems and leaves). The relationship between tissue concentration of an element and external concentration of the corresponding nutient ion was invariably multiphasic, with phases separated by sharp breaks or jumps. The kinetics of accumulation were similar to those of short-term uptake of the same ions. Reanalysis of previously published data (including data for Mn²⁺) for other plants yielded, similarly, bi- or multiphasic isotherms for accumulation. Accumulation patterns and growth were in several instances correlated, with separate phases coinciding with regions of poverty adjustment, luxury consumption and toxicity. Implications of multiphasic kinetics of long-term nutrient accumulation for membrane properties, fluxes and regulation include: (i) Membranes and uptake mechanisms must remain relatively constant throughout the life of the plant with respect to affinities for ions and concentrations at which transitions occur. (ii) Rate-limitation occurs at the plasmalemma of the root cortical cells. (iii) Uptake is at all times under multiphasic control by the external solution.