Roger A. Leigh

Pathways for the permeation of Na+ and Cl− into protoplasts derived from the cortex of wheat roots

Sodium permeation into cortex cells of wheat roots was examined under conditions of high external NaCI and low Ca(2+). Two types of K(+) inward rectifier were observed in some cells. The time-dependent K(+) inward rectifier was Ca(2+)-sensitive, increasing in magnitude as external Ca(2+) was decreased from 10 mM to 0.1 mM, but did not show significant permeability to Na(+). However, the spiky inward rectifier showed significant Na+ permeation at Ca(2+) concentrations of 1 and 10 mM. In cells that initially did not show K(+) inward rectifier channels, fast and sometimes slowly activating whole-cell inward currents were induced at membrane potentials negative of zero with high external Na(+) and low Ca(2+) concentrations. With 1 mM Ca(2+) in the external solution, large inward currents were carried by Rb(+), Cs(+), K(+), Li(+), and Na(+). The permeability sequence shows that K(+), Rb(+) and Cs(+) are all more permeant than Na(+), which is about equally as permeant as Li(+). When some K(+) was present with high concentrations of Na(+) the inward currents were larger than with K(+) or Na(+) alone. About 60% of the inward current was reversibly blocked when the external Ca(2+) activity was increased from 0.03 mM to 2.7 mM (half inhibition at 0.31 mM Ca(2+) activity). Changes in the characteristics of the current noise indicated that increased Ca(2+) reduced the apparent single channel amplitude. In outside-out patches inward currents were observed at membrane potentials more positive than the equilibrium potentials for K(+) and Cl(-) when the external Na(+) concentration was high. These channels were difficult to analyse but three analysis methods yielded similar conductances of about 30 pS.

Cell-Specific Vacuolar Calcium Storage Mediated by CAX1 Regulates Apoplastic Calcium Concentration, Gas Exchange, and Plant Productivity in Arabidopsis

Mineral elements are often preferentially stored in vacuoles of specific leaf cell types, but the mechanism and physiological role for this phenomenon is poorly understood. We use single-cell analysis to reveal the genetic basis underpinning mesophyll-specific calcium storage in Arabidopsis leaves and a variety of physiological assays to uncover its fundamental importance to plant productivity. The physiological role and mechanism of nutrient storage within vacuoles of specific cell types is poorly understood. Transcript profiles from Arabidopsis thaliana leaf cells differing in calcium concentration ([Ca], epidermis <10 mM versus mesophyll >60 mM) were compared using a microarray screen and single-cell quantitative PCR. Three tonoplast-localized Ca2+ transporters, CAX1 (Ca2+/H+-antiporter), ACA4, and ACA11 (Ca2+-ATPases), were identified as preferentially expressed in Ca-rich mesophyll. Analysis of respective loss-of-function mutants demonstrated that only a mutant that lacked expression of both CAX1 and CAX3, a gene ectopically expressed in leaves upon knockout of CAX1, had reduced mesophyll [Ca]. Reduced capacity for mesophyll Ca accumulation resulted in reduced cell wall extensibility, stomatal aperture, transpiration, CO2 assimilation, and leaf growth rate; increased transcript abundance of other Ca2+ transporter genes; altered expression of cell wall–modifying proteins, including members of the pectinmethylesterase, expansin, cellulose synthase, and polygalacturonase families; and higher pectin concentrations and thicker cell walls. We demonstrate that these phenotypes result from altered apoplastic free [Ca2+], which is threefold greater in cax1/cax3 than in wild-type plants. We establish CAX1 as a key regulator of apoplastic [Ca2+] through compartmentation into mesophyll vacuoles, a mechanism essential for optimal plant function and productivity.

Characterisation of a salt-stimulated ATPase activity associated with vacuoles isolated from storage roots of red beet (Beta vulgaris L.).

Ion stimulation and some other properties of an ATPase activity associated with vacuoles isolated from storage roots of red beet (Beta vulgaris L.) have been determined. The ATPase had a specific requirement for Mg2+ and in the presence of Mg2+ it was stimulated by salts of monovalent cations. The degree of stimulation by monovalent salts was influenced mainly by the anion and the order of effectiveness of the anions tested was Cl->HCO3->Br->malate>acetate>SO42-. For any given series of anions the magnitude of the stimulation obtained was influenced by the accompanying cation (NH4+≫ Na+>K+). This cation effect was abolished by 0.01% (v/v) Triton X-100 and it is suggested that it is the result of different permeabilities of membrane vesicles to the cations. There was no evidence of synergistic stimulation of the ATPase by mixtures of Na+ and K+. KCl- and NaCl-stimulation was maximal with salt concentrations in the range 60–150 mM. The true substrate of the enzyme was shown to be MgATP. It was shown that KCl stimulation was the result of an increase in Vmax rather than a change in the affinity of the enzyme for MgATP. The ATPase was inhibited by N,N′-dicyclohexylcarbodiimide, diethylstilbestrol, mersalyl and KNO3 but other inhibitors tested (azide, oligomycin, orthovanadate, K3[Cr(oxalate)6] and ethyl-3-[3-dimethylaminopropyl]carbodiimide) were without effect or caused only partial inhibition at the highest concentration tested. The ATPase activity was equally distributed between pellet and supernatant fractions obtained after the subfractionation of vacuoles but the properties of the ATPase in each fraction were the same. It is suggested that beet vacuoles possess only one ATPase. The properties of the ATPase are compared with those of ATPases associated with other plant membranes and organelles and its possible role in transport at the tonoplast is discussed.

Where do all the ions go? The cellular basis of differential ion accumulation in leaf cells

Leaf cells accumulate solutes differently depending on their cell type. The accumulation profiles of inorganic ions have been well documented for the mesophyll and epidermis, particularly in cereals. These cell types accumulate ions such as phosphate and calcium to strikingly different extents. Understanding the processes that control ion accumulation could reveal how plants respond to either a limiting supply of important micro- and macronutrient ions or to potentially toxic loads of salts or heavy metal ions. Research has recently begun to reveal the processes that underlie this remarkable sorting of nutrient ions within the leaf.

ATPase and acid phosphatase activities associated with vacuoles isolated from storage roots of red beet (Beta vulgaris L.).

Phosphatase activities were measured in preparations of vacuoles isolated from storage roots of red beet (Beta vulgaris L.). The vacuoles possessed both acid phosphatase and ATPase activities which could be distinguished by their susceptibility to inhibition by low concentrations of ammonium molybdate [(NH4)6Mo7O24·4H2O]. The acid phosphatase was completely inhibited by 100 μM ammonium molybdate but the ATPase was unaffected. The acid phosphatase was a soluble enzyme which hydrolysed a large number of phosphate esters and had a pH optimum of 5.5. In contrast, the ATPase was partially membrane-bound, had a pH optimum of 8.0 and hydrolysed ATP preferentially, although it was also active agianst PPi, GTP and GDP. At pH 8.0 both the ATPase and PPase activities were Mg2+-dependent and were further stimulated by KCl. The ATPase and PPase activities at pH 8.0 may be different enzymes. The recovery and purification of the ATPase during vacuole isolation were determined. The results indicate that the Mg2+-dependent, KCl-stimulated ATPase activity is not exclusively associated with vacuoles.

Assessment of glycinebetaine and proline compartmentation by analysis of isolated beet vacuoles

Vacuoles isolated from storage root tissue of red beet (Beta vulgaris L.) do not leak significant quantities of betanin, sucrose, Na+ or K+ during isolation. This indicates that analysis of vacuoles in vitro gives meanigful information about the compartmentation of solutes in vivo. Preparations of vacouoles were used to determine the distribution of glycinebetaine and proline between vacuole and cytoplasm in beet cells. Both compounds were detected in preparations of isolated beet vacuoles. In the case of glycinebetaine it was shown that this solute was associated with the vacuoles, not with the small number of other organelles which contaminated the preparations. The vacuolar pool accounted for 26 to 84% of the total tissue glycinebetaine and 17 to 57% of the proline. Concentrations of these compounds in vacuole and cytoplasm were calculated and were always higher in the cytoplasm than in the vacuole. The concentration gradient across the tonoplast varied considerably. The significance of these results is discussed in relation to the hypothesis that glycinebetaine and proline function as benign cytoplasmic osmotica.

Compartmental nitrate concentrations in barley root cells measured with nitrate-selective microelectrodes and by single-cell sap sampling

Nitrate-selective microelectrodes were used to measure intracellular nitrate concentrations (as activities) in epidermal and cortical cells of roots of 5-d-old barley (Hordeum vulgare L.) seedlings grown in nutrient solution containing 10 mol · m−3 nitrate. Measurements in each cell type grouped into two populations with mean (±SE) values of 5.4 ± 0.5 mol · m−3 (n=19) and 41.8 ± 2.6 mol · m−3 (n = 35) in epidermal cells, and 3.2 ± 1.2 mol · m−3 (n = 4) and 72.8 ± 8.4 mol · m−3 (n = 13) in cortical cells. These could represent the cytoplasmic and vacuolar nitrate concentrations, respectively, in each cell type. To test this hypothesis, a single-cell sampling procedure was used to withdraw a vacuolar sap sample from individual epidermal and cortical cells. Measurement of the nitrate concentration in these samples by a fluorometric nitrate-reductase assay confirmed a mean vacuolar nitrate concentration of 52.6 ± 5.3 mol · m−3 (n = 10) in epidermal cells and 101.2 ± 4.8 mol · m−3 (n = 44) in cortical cells. The nitrate-reductase assay gave only a single population of measurements in each cell type, supporting the hypothesis that the higher of the two populations of electrode measurements in each cell type are vacuolar in origin. Differences in the absolute values obtained by these methods are probably related to the fact that the nitrate electrodes were calibrated against nitrate activity but the enzymic assay against concentration. Furthermore, a 28-h time course for the accumulation of nitrate measured with electrodes in epidermal cells showed the apparent cytoplasmic measurements remained constant at 5.0 ± 0.7 mol · m−3, while the vacuole accumulated nitrate to 30–50 mol · m−3. The implications of the data for mechanisms of nitrate transport at the plasma membrane and tonoplast are discussed.

Potassium homeostasis and membrane transport

Cytosolic K + activity in plant cells is about 80 mM and is maintained during moderate K + -deprivation. It decreases to much lower values only in extreme K + -deficiency. In contrast, the vacuolar K + concentration responds directly to the K + supply and can fall to very low values in severely K + -deprived cells, However, there is good evidence for an upper limit for vacuolar K + concentration which is different in roots and leaves. Understanding of the molecular basis of active and passive K + transport in plants has increased enormously in recent years but the role of individual transporters in uptake has still to be fully resolved, as has their regulation in relation to the maintenance of cytosolic and vacuolar K + concentrations. In particular, the inverse relationship between the rate of K + uptake and internal K + concentration that was established over 25 years ago has still not been credibly explained at the molecular level.

Investigating glutamate receptor-like gene co-expression in Arabidopsis thaliana

There is increasing evidence of the important roles of glutamate receptors (GLRs) in plant development and in adaptation to stresses. However, the studies of these putative ion channels, both in planta and in Xenopus oocytes, may have been limited by our lack of knowledge of possible GLR heteromer formation in plants. We have developed a modification of the single-cell sampling technique to investigate GLR co-expression, and thus potential heteromer formation, in single cells of Arabidopsis thaliana leaves. Micro-EXpression amplification (MEX) has allowed us to amplify gene transcripts from a single cell, enabling expression of up to 100 gene transcripts to be assayed. We measured, on average, the transcripts of five to six different AtGLRs in a single cell. However, no consistent patterns of co-expression or cell-type-specific expression were detected, except that cells sampled from the same plant showed similar expression profiles. The only discernible feature was the detection of AtGLR3.7 in every cell examined, an observation supported by GUS staining patterns in plants stably expressing promoter::uidA fusions. In addition, we found AtGLR3.7 expression in oocytes induces a Ba2+-, Ca2+- and Na+-permeable plasma membrane conductance.

Concentrations of inorganic and organic solutes in extracts from individual epidermal, mesophyll and bundle-sheath cells of barley leaves

The distribution of solutes between epidermal, mesophyll and bundle-sheath cells in barley (Hordeum vulgare L. cv. Klaxon) leaves was studied by analysing extracts obtained from single cells with a modified pressure probe. Activity of the cytoplasmic marker enzyme, malate dehydrogenase, revealed that epidermal cell extracts were completely vacuolar in origin, but extracts from mesophyll cells also contained cytoplasmic constituents. The extracts were analysed for osmolality and the concentrations of K, Na, Ca, Cl, P, S, NO3−, sugars and total amino acids. Epidermal and mesophyll cell extracts had similar osmolalities but these varied between 420 and 565 mosmol, kg 1 depending on the leaf developmental stage; the osmolality of bundle-sheath extracts was approximately 100 mosmol, kg−1 lower. Under the growth conditions used, K and NO3−were found in all three cell types and their concentrations generally ranged between 180 and 230 mM. In contrast, Ca was almost restricted to epidermal cells, where it increased to 70 mM during leaf ageing. Phosphorus was only detectable (≥ 5 mM) in extracts from mesophyll and bundle-sheath cells, while Cl concentrations were highest in epidermal and lowest in mesophyll cell extracts. The concentrations of sugars and amino acids were close to the detection limit (approx. 2 mM) in epidermal cells but mesophyll cells contained total sugar (glucose, fructose and sucrose) of up to 78 mM and total amino-acid concentrations of up to 13.5 mM. Concentrations in bundle-sheath cells were intermediate between those in the epidermis and mesophyll.