Vacuolar Na/K Exchange, its Occurrence in Root Cells of Hordeum, Atriplex and Zea and its Significance for K/Na Discrimination in Roots

Using excised low-salt roots of barley and Atriplex hortenslsthe transport of endogenous potassium through the xylem vesselswas studied It was enhanced by nitrate and additionally by sodiumions which apparently replaced vacuolar potassium which wasthen available in the symplasm of root cells for transport tothe shoot Vacuolar Na/K exchange also has been investigatedby measurements of longitudinal ion profiles in single rootsof both species. In Atriplex roots a change in the externalsolution from K⁺ to Na⁺ induced an exchange of vacuolar K⁺ forNa⁺, in particular in the subapical root tissues and led toincreased K⁺ transport and loss of K⁺ from the cortex. In inverseexperiments a change from Na⁺ to K⁺ did not induce an exchangeof vacuolar Na⁺; merely in meristematic tissues Na⁺—apparentlyfrom the cytoplasm—was extruded in exchange for K⁺. Inroots of barley seedlings without caryopsis, as in excised roots,a massive exchange of K⁺ for Na⁺ was observed in the continuouspresence of external 1.0 mM Na and 0.2 mM K. This exchange alsowas attributed to the vacuole and was most pronounced in theyoung subapical tissues. It did not occur, however, in the correspondingtissues in roots of fully intact barley seedlings. In these,the young tissues retained a relatively high K/Na ratio alsoin their vacuoles. Similarly, contrasting results were obtainedwith intact and excised roots of Zea mays L. Based on theseresults a scheme of the events that lead to selective cationuptake in intact barley roots is proposed. In this scheme acrucial factor of selectivity is sufficient phloem recirculationof K⁺ by the aid of which K⁺ rich cortical cells are formednear the root tip. When matured these cells are suggested tomaintain a high cytoplasmic K/Na ratio due to K⁺ dependent sodiumextrusion at the plasmalemma and due to recovery of vacuolarK⁺ by Na/K exchange across the tonoplast. Key words: Potassium/Sodium selectivity, Vacuolar exchange, Xylem transport, Hordeum, Zea, Atriplex     

Light-Induced H+ Accumulation in the Vacuole of Nitellopsis obtusa

The effects of light on the pH in the vacuole and the electricpotential difference across the plasmalemma and the tonoplastof Nitellopsis obtusa were investigated by means of conventionaland H⁺-specific glass or antimony microelectrodes. Illuminationis found to bring about a decrease in the pH of the vacuolarsap by 0.1–0.5 units concomitant with a depolarizationof the cell. The light-induced changes of the potential differenceand the vacuolar pH depend in different ways on the pH of theexternal medium (pH_o). At pH_o 9.0 cells exhibit great light-inducedpotential changes (up to 100 mV), but only small pH changesof the vacuolar sap. At neutral or slightly acidic pH_o valuesthe amplitude of the light-induced pH changes in the vacuoleincreases up to 0.3–0.5 pH units, but the amplitudes ofthe potential changes at the plasmalemma are relatively small.At pH_o 9.0 a transient acidification of the medium is observedupon illumination whereas at lower pH values light-induced alkalinizationwas only seen. Transfer of the cells from pH_o 9.0 to pH_o 7.5results in a cell hyperpolarization by 60–80 mV and adecrease of the vacuolar pH by 0.4–0.5 units under lightconditions but has no significant effect on the potential andthe vacuolar pH in the darkness. It is proposed that mechanismsof active H⁺ extrusion from the cytoplasm are located both inthe plasmalemma and the tonoplast. The observed acidificationin the vacuole appears to be determined by a light-induced increaseof the concentration of H⁺ in the cytoplasm. The H⁺ conductionof the plasmalemma seems to increase on illumination. The patternof the light-induced H⁺ fluxes across the tonoplast and theplasmalemma depends crucially on the extent of the light-inducedchanges in the H⁺ conductance and on the electrochemical gradientfor H⁺ at the plasmalemma.     

Determination of Unidirectional Sodium Fluxes in Roots of Intact Sunflower Seedlings

The method of compartmental analysis was applied to study sodiumfluxes in roots of intact seedlings of Helianthus annuus L.By measuring sodium uptake and transport to the shoots of theseedlings in parallel experiments, transport of tracer sodiumto shoots and net accumulation of Na⁺ in the roots during theflux measurements was accounted for. The steady-state sodiumfluxes in the intact sunflower roots were similar in size tothose in excised roots but in general they were somewhat higher.This indicates more metabolic activity in the intact tissues.Using whole plants it is possible to study the response of ionfluxes in roots to ecophysiological stimuli received by theshoots, and in the present experiments the effect of continuouslight versus long-day growth conditions was investigated. Potassium,when continually present, depressed all fluxes and the cytoplasmiccontent of sodium but tended to increase the vacuolar sodiumcontent, in particular when this was related to the cytoplasmiccontent. When added to sodium-loaded roots, potassium stimulatedthe plasmalemma sodium efflux but slightly, suggesting a lowefficiency of K⁺-Na⁺ exchange across the plasmalemma in intactas well as excised sunflower roots. Subsequently, however, potassiuminduced a transient decrease in the ²²Na efflux that was followedby oscillations in tracer efflux. These changes were attributedto potassium-induced transfer of sodium to vacuoles. Moreover,the oscillations seem to indicate the operation of negativefeedback control of sodium fluxes.     

Effect of Exogenous Glycinebetaine on Na+ Transport in Barley Roots

Ahmad, N., Wyn Jones, R. G. and Jeschke, W. D. 1987. Effectof exogenous glycinebetaine on Na⁺ transport in barley roots.—J.exp. Bot. 38: 913–921. A comparison has been made of the kinetics of 22Na⁺ uptake intoexcised barley roots and roots pre-loaded with glycinebetaine.The elevated intracellular glycinebetaine or a metabolic consequencethereof increased the Na⁺ influx, and the effect was relatedto the level of internal glycinebetaine and or Na⁺ [Cl^–].The quasi-steady-state Na⁺ influx at the tonoplast rather thanthe plasmalemma influx was apparently influenced by glycinebetaineloading. The tonoplast fluxes and vacuolar Na⁺ content wereconsistently higher in glycinebetaine-loaded roots than unloadedroots. A membrane-modifying role of glycinebetaine in relationto ion compartmentation is discussed. Key words: Excised roots, glycinebetaine, Na⁺, ion fluxes, barley     

Effect of K+, its Counter Anion, and pH on Sodium Efflux from Barley Root Tips

Sodium efflux from ²²Na⁺-loaded root tips root tips of Hordeumvulgare L. was markedly increased by replacing 10mM Na₂SO₄ inthe washing solution by K₂SO₄ with the same electrical conductivity.This increase was inhibited by both an uncoupler and an inhibitorof oxidative phosphorylation but not by ouabain. Potassium ionsdid not enhance Na⁺ efflux in the presence of a rapidly absorbedcounter anion, such as Cl^–, instead of . Efflux of ²²Na⁺ could also be enhanced by a low pH in theabsence of K⁺; this was prevented by uncouplers, but not byan inhibitor of the mitochondrial ATPase. It seems that K⁺ indirectly enhances Na⁺ efflux. It is suggestedthat metabolic K⁺ uptake in excess of the counter anion resultsin a proton gradient across the plasmalemma (acid outside) inducingH⁺/Na⁺ antiport.     

Intracellular pH Regulation in the Giant-Celled Marine Alga Chaetomorpha darwinii

The vacuolar pH (pH_v) and the cytoplasmic pH (pH_c) of the marinegiant-celled green alga Chaetomorpha darwinii were measuredby pH microelectrode techniques on extracted vacuolar sap, andby the [^I4C]DMO distribution method respectively. Equilibrationof DMO occurred with a half-time of about 2 h, with an apparentP_DMO of 3.6 x 10^–5 cm s^–1, but the vacuolar concentrationof free, undissociated DMO was always less than the externalconcentration. The explanation offered for freshwater giant-celledalgae of net DMO^– leakage across the plasmalemma cannotapply to Chaetomorpha darwinii, since electrically-driven DMO^–exit from the cytoplasm should be similar across the plasmalemmaand the tonoplast in these cells with large, vacuole-positivepotential differences across the tonoplast. pHc was accordinglycomputed assuming either tonoplast or plasmalemma equilibrationof DMO, with correction for DMO metabolism within the cell.pH_c was 8.0–8.3 in the light in artificial seawater (pH_oabout 8.0), was some 0.5 units lower in the dark, and was slightlylower with an external pH of 7. Vacuolar pH was 6.5–6.9,without consistent effects of illumination or of external pHof 7 rather than 8. While µ_H+ at the tonoplast was similarto that in giant-celled freshwater algae (although with a greatercontribution from relative to pH), µ_H+ at the plasmalemmawas less than 8 kJ mol^–1, i.e. less than one-third ofthe value in freshwater green algae. µ_Na+ was some 13kJ mol^–1 at the plasmalemma. The possibility that theprimary active transport process at the plasmalemma of Chaetomorphadarwinii (and certain other marine algae) is Na⁺ efflux ratherthan H⁺ efflux is discussed.     

Effects of Light/Dark on Anion Fluxes in Isolated Guard Cells of Commelina communis L.

The effects of light/dark on anion fluxes in isolated guardcells of Commelina communis L. have been studied, using ⁸²Brand ³⁶Cl. Transfer of open guard cells from light to dark hasno effect on the ⁸²Br influx, but produces a marked transientstimulation of ⁸²Br or ³⁶Cl efflux, similar to the effect ofsuch transfer on the ⁸⁶Rb fluxes, and to the effects on both⁸⁶Rb and ⁸²Br fluxes of adding ABA. On return of guard cellsto light, after the transient, there is a further reductionin Cl/Br efflux. It is argued that control of a specific processof ion extrusion is important in regulating the ability of guardcells to stay open. In three out of four batches of steady-statetissue labelled with ⁸²Br, the plasmalemma fluxes were highenough, relative to the tonoplast fluxes, for the efflux kineticsto be separable into two exponential components, allowing estimationof bromide contents in cytoplasm and vacuole (Q_c and Q_v), andfluxes at plasmalemma and tonoplast. With opening in light,Q_c increased by 3.9 ± 0.4 pmol mm^–2 µm^–1and Qy by 5.2 ± 0.6 pmol mm^–2 µm^–1(change in content per mm² of epidermis perµm change inaperture). Using rough estimates for the volumes of cytoplasmand vacuole these figures suggest that at 6.1 µm in thedark the concentrations were about 63 mol m^–3 in the cytoplasmand 35 mol m^–3 in the vacuole, rising to about 185 molm^–3 in the cytoplasm and 125 mol m^–3 in the vacuole,at 16.7 µm aperture in light. Neither increase can providean adequate increase in salt concentration to account for theosmotic change required, and some solute other than potassiumsalt must also be involved. In one experiment with 82Br andin the only experiment with 36Cl the plasmalemma flux was lower,and not high enough relative to the tonoplast flux to allowseparation of two phases in the efflux curves, and calculationof cytoplasmic and vacuolar contents and fluxes. The effectsof transfer from light to dark were, nevertheless, similar inboth types of tissue. Key words: Commelina communis L., Light/dark effects, Anion fluxes, Guard cells     

Ionic Relations of Garden Orache, A triplex hortensis L.: Growth and Ion Distribution at Moderate Salinity and the Function of Bladder Hairs

The growth of garden orache, A triplex hortensis was studiedunder conditions of mild NaCl or Na₂SO₄ salinity. Growth, drymatter production and leaf size were substantially stimulatedat 10 mM and 50 mM Na⁺ salts. Increased growth, however, appearedto be due to a K⁺-sparing effect of Na⁺ rather than to salinityper se. The distribution of K⁺ and Na⁺ in the plant revealeda remarkable preference for K+ in the roots and the hypocotyl.In the shoot the K/Na ratio decreased strongly with leaf age.However, the inverse changes in K⁺ and Na⁺ content with leafage were dependent on the presence of bladder hairs, which removedalmost all of the Na⁺ from the young leaf lamina. Measurementsof net fluxes of K⁺ and Na⁺ into roots and shoots of growingAtriplex plants showed a higher K/Na selectivity of the netion flux to the root compared to the shoot. With increasingsalinity the selectivity ratio S_{K, Na}^* of net ion fluxes tothe roots and to the shoots was increased. The data suggestthat recirculation of K⁺ from leaves to roots is an importantlink in establishing the K/Na selectivity in A. hortensis plants.The importance of K⁺ recirculation and phloem transport forsalt tolerance is discussed. Key words: Atriplex hortensis, Salinity, Potassium, Sodium, K⁺ retranslocation, Bladder hairs, Growth stimulation     

The Ionic Relations of Acetabularia mediterranea

The concentrations of K⁺, Na⁺, and Cl^– in the cytoplasmand the vacuole of Acetabularia mediterranea have been measured,as have the vacuolar concentrations of SO₄^–– andoxalate. The electrical potential difference between externalsolution, and vacuole and cytoplasm has been measured. The resultsindicate that Cl^– and SO₄^–– are probably transportedactively into the cell, and that active transport of Na⁺ isoutwards. The results for K⁺ are equivocal. The fluxes of K⁺,Na⁺, Cl^–, and S0₄^–– into the cell and theeffluxes of Na⁺ and Cl^– have been determined. The Cl^–fluxes are extremely large. In all cases the plasmalemma isthe rate-limiting membrane for ion movement. A technique isdescribed for the preparation of large, completely viable cellfragments containing only cytoplasm, with no vacuole.     

Influence of abscisic acid on unidirectional fluxes and intracellular compartmentation of K+ and Na+ in excised barley root segments

Using compartmental analysis, unidirectional fluxes of K⁺ and Na⁺ and their intracellular compartmentation in excised barley (Hordeum distichon L. cv. Kocher-perle) root segments have been measured during a steady state in the presence or absence of ABA. Almost all flux rates were altered in the presence of external ABA, in particular the xylem transport R’ and the plasmalemma influx Ø_oc (see below) were strongly inhibited in the steady state. At the same time the presence of ABA induced a strong increase in the vacuolar K⁺ and Na⁺ content Q_v and a decrease in the cytoplasmic one (Q_c). Since the fluxes of an ion and its vacuolar or, in particular, cytoplasmic concentrations are interrelated, the ratios of fluxes originating from the cytoplasm and the cytoplasmic ion content were taken into account. On this basis ABA had the following effects: a) the secretion of K⁺ or Na⁺ to the xylem vessels was drastically inhibited; b) the plasmalemma K⁺ or Na⁺ efflux Ø_co was moderately stimulated and c) the tonoplast influx Ø_cv of Na⁺ was stimulated, while the tonoplast influx of K⁺ appeared to be unchanged (the decrease in Ø_cv being due to the decreased cytoplasmic K⁺ content). By a similar argument, also the apparent inhibition of the plasmalemma influx Ø_oc of K⁺ and Na⁺ in the steady state merely is an indirect effect of ABA. It only reflects the strong ABA-induced decrease in the xylem transport, that governs the magnitude of Ø_oc in the steady state. The results are discussed with reference to possible regulatory functions of ABA. In this respect it is suggested that – in particular under conditions of stress – ABA might regulate cellular metabolic processes by changing the cytoplasmic K⁺ level.     

An Examination, by Compartmental Flux Analysis, of the Development of Sodium and Chloride Absorption Capacities in Beetroot Disks

Using beetroot, Beta vulgaris L. var. Avon Early, grown in radioactivelylabelled nutrient solutions, concentrations and fluxes of Na⁺and Cl^– were estimated for cells of freshly cut storageroot disks, by compartmental analysis of radioisotope elutionmeasurements. These values were compared with results obtainedin a similar manner from beetroot grown in non-labelled nutrientsolution and loaded instead during an aging period in ²²Na-or ³⁶Cl- labelled 1 mM NaCl solution. In accord with the generallyaccepted, but never properly tested, view, it was found thatnet Na⁺ influx followed from a reduction in efflux with agingand net Cl^– uptake depended on a marked increase in influx.However, both these important changes took place at the tonoplast,and, although aging led to a reduction of plasmalemma fluxes,at no time was entry of Cl^– into the cytoplasm, or lossof Na⁺ from the cytoplasm, significantly restricted.     

Effects of Growth and Assay Temperatures on Unidirectional K+ Fluxes in Roots of Rye (Secale cereale)

The effects of growth and assay temperature on unidirectionalK⁺ fluxes in excised roots of rye (Secale cereale cv. Rheidol)were studied using ⁸⁶Rb⁺ as a tracer. Both K⁺ influx to thevacuole, estimated as K⁺ uptake between 3 and 12 h after transferof unlabelled roots to radioactive solution, and movement ofK⁺ to the xylem were determined directly. Other fluxes weredetermined on excised roots of plants, which had been labelledwith ⁸⁶Rb⁺ since germination, by conventional triple exponentialefflux analysis. When assayed at 20°C, roots of plants previously grown at20°C(WG roots) had lower rates of net K⁺ uptake than rootsof low temperature-acclimated plants, grown with a temperaturediferential between roots (87°C) and shoots (20°C) eithersince germination (DG roots) or for 3 d prior to experiments(DT roots). This resulted from a greater unidirectional K⁺ effluxacross the plasma membrane and a reduced K⁺ flux to the xylemin WG roots, compared to DG or DT roots, rather than a decreasein unidirectional K⁺ influx or a decrease in the net K⁺ fluxto the vacuole. Indeed, although WG roots had lower rates ofK⁺ influx and K⁺ efflux across the tonoplast at 20°C thanDG or DT roots, roots of plants from all growth temperaturetreatments showed an equivalent net K⁺ flux to the vacuole. Although all unidirectional K⁺ fluxes in roots from plants grownunder all temperature regimes were reduced by lowering the temperatureof the root, these fluxes were differentially affected in rootsof plants from contrasting growth temperature treatments. Rapidcooling to 8°C of WG roots resulted in a lower rate of K+influx and a transient increase in K⁺ efflux across both theplasma membrane and tonoplast, compared to DG and DT roots.Furthermore, since the K⁺ flux to the xylem was lower in WGroots, the net K⁺ uptake at 8°C into WG roots was considerablyreduced compared to DG and DT roots. These results suggest thatlow temperature-acclimation of K⁺ fluxes in rye roots may involvea reduction in the temperature sensitivity of K⁺ influx anda curtailment of K⁺ efflux across both the plasma membrane andtonoplast at low temperatures. Key words: K⁺influx, K⁺ efflux, low temperature, potassium, rye (Secale cereale cv. Rheidol)     

The Influence of Nitrate and Ammonium Nutrition on the Growth of Wheat (Triticum aestivum) and Maize (Zea mays) Plants

The effects of NO^-₃ and NH⁺₄ nutrition on hydroponically grownwheat (Triticum aestivum L.) and maize (Zea mays L.) were assessedfrom measurements of growth, gas exchange and xylem sap nitrogencontents. Biomass accumulation and shoot moisture contents ofwheat and maize were lower with NH⁺₄ than with NO^-₃ nutrition.The shoot:root ratios of wheat plants were increased with NH⁺₄compared to NO^-₃ nutrition, while those of maize were unaffectedby the nitrogen source. Differences between NO^-₃ and NH⁺₄-fedplant biomasses were apparent soon after introduction of thenitrogen into the root medium of both wheat and maize, and thesedifferences were compounded during growth. Photosynthetic rates of 4 mM N-fed wheat were unaffected bythe form of nitrogen supplied whereas those of 12 mM NH⁺₄-fedwheat plants were reduced to 85% of those 12 mM NO^-₃-fed wheatplants. In maize supplied with 4 and 12 mM NH⁺₄ the photosyntheticrates were 87 and 82% respectively of those of NO^-₃-fed plants.Reduced photosynthetic rates of NH⁺₄ compared to NO^-₃-fed wheatand maize plants may thus partially explain reduced biomassaccumulation in plants supplied with NH⁺₄ compared to NO^-₃ nutrition.Differences in the partitioning of biomass between the shootsand roots of NO^-₃-and NH⁺₄-fed plants may also, however, arisefrom xylem translocation of carbon from the root to the shootin the form of amino compounds. The organic nitrogen contentof xylem sap was found to be considerably higher in NH⁺₄- thanin NO^-₃-fed plants. This may result in depletion of root carbohydrateresources through translocation of amino compounds to the shootin NH⁺₄-fed wheat plants. The concentration of carbon associatedwith organic nitrogen in the xylem sap of maize was considerablyhigher than that in wheat. This may indicate that the shootand root components of maize share a common carbon pool andthus differences induced by different forms of inorganic nitrogenare manifested as altered overall growth rather than changesin the shoot:root ratios.Copyright 1993, 1999 Academic Press Triticum aestivum, wheat, Zea mays, maize, nitrogen, growth, photosynthesis, amino acids, xylem     

Effect of Sudden Salt Stress on Ion Fluxes in Intact Wheat Suspension Cells

Although salinity is one of the major problems limiting agriculturalproduction around the world, the underlying mechanisms of highNaCl perception and tolerance are still poorly understood. Theeffects of different bathing solutions and fusicoccin (FC),a known activator of plasma membrane ATPase, on plasma membranepotential (E_m) and net fluxes of Na⁺, K⁺and H⁺were studied inwheat suspension cells (Triticum aestivum) in response to differentNaCl treatments. E_mof cells in Murashige and Skoog (MS) mediumwas less negative than in cells exposed to a medium containing10 mM KCl + 0.1 m M CaCl₂(KSM) and to a basic salt medium (BSM),containing 1 m M KCl and 0.1 m M CaCl₂. Multiphasic Na⁺accumulationin cells was observed, peaking at 13 min after addition of 120m M NaCl to MS medium. This time scale was in good agreementwith net Na⁺flux changes measured non-invasively by moving ion-selectivemicroelectrodes (the MIFE system). When 120 m M NaCl was addedto all media studied, a quick rise of Na⁺influx was reversedwithin the first 20 min. In both 120 and 20 m M NaCl treatmentsin MS medium, net Na⁺efflux was observed, indicating that activeNa⁺transporters function in the plant cell response to saltstress. Lower external K⁺concentrations (KSM and BSM) and FCpre-treatment caused shifts in Na⁺fluxes towards net influxat 120 m M NaCl stress. Copyright 2000 Annals of Botany Company Sodium, potassium, proton, membrane potential, fusicoccin, salt stress, wheat, Triticum aestivum     

Na+, K+ and Cl- in Xylem Sap Flowing to Shoots of NaCl-Treated Barley

Munns, R. 1985. Na⁺, K⁺ and Cl^– in xylem sap flowing toshoots of NaCl-treated barley.—J. exp. Bot. 36: 1032–1042. Na⁺, Cl^– and K⁺ concentrations were measured in xylemsap obtained by applying pressure to the roots of decapitatedbarley plants grown at external [NaCl] of 0, 25, 50, 100, 150and 200 mol m^–3. For any given NaCl treatment, ion concentrationsin the xylem sap were hyperbolically related to the flux ofwater. Ion concentrations in sap collected at very low volumefluxes (without applied pressure) were 5–10 times higherthan in sap collected at moderate fluxes (under pressure). Fora given moderate volume flux, Na+ concentration in the xylemsap, [Na⁺]_x, was only 4.0 mol m^–3 at external [NaCl] of25–150 mol m^–3, and increased to 7.0 mol m^–3at 200 mol m^–3. [Cl-]x showed a similar pattern. Thisshows there would be little difference in the rate of uptaketo the shoot of plants at 25–150 mol m^–3 externalNaCl and indicates little change even at 200 mol m^-3 NaCl becausetranspiration rates would be much lower. Thus the reduced growthof the shoot of plants at high NaCl concentrations is not dueto higher uptake rates of Na⁺ or Cl^–. The fluxes of Na⁺, Cl^– and K^– increased non-linearlywith increasing volume flux indicating little movement of saltin the apoplast. The flux of K⁺ increased even when [K⁺]_x wasgreater than external [K⁺], indicating that membrane transportprocesses modify the K⁺ concentration in the transpiration streamas it flows through the root system. Key words: -Xylem sap, Na⁺, K⁺, Cl^– fluxes, salinity, barley     

Effect of Potassium on Photosynthate Unloading from Seed Coats of Phaseolus vulgaris L. Specificity and Membrane Location

Rates of ¹⁴C-photosynthate unloading from excised seed-coathalves of Phaseolus vulgaris L. plants were stimulated by externalKCI concentrations in excess of 10 mM with an optimal responseat 100–150 mM KCI. The cellular pattern of ¹⁴C-photosynthatemetabolism was not altered by KCI but the treatment preferentiallystimulated the release of sucrose from the seed-coats. Photosynthateunloading was insensitive to Cl^– and was stimulated bya range of membrane-permeable cations (Na⁺, Mg²⁺ and tetraphenylphosphoniumion) in addition to K⁺. The K⁺ ionophore, valinomycin, abolishedthe K⁺ stimulation of ¹⁴C-photosynthate unloading. A switchto a wash solution containing K⁺ elicited a rapid burst of ¹⁴C-photosynthateunloading; the rate constant for the final phase of ¹⁴C-efflux(probably across the tonoplast) was unaffected by K⁺. The KCItreatment did not change the passive permeability of eitherthe plasmalemma or tonoplast. While sucrose influx across theplasmalemma was insensitive to K⁺, sucrose transfer to the vacuolewas slowed. The results obtained support the postulate thatK⁺ (and other membrane permeable cations) preferentially stimulatesucrose efflux across the plasmalemma of the unloading cellsby serving to carry positive charge in the opposite direction. Phaseolus vulgaris, bean, photosynthate unloading, potassium stimulation, seed-coat     

Na+/H+ Antiporter in Tonoplast Vesicles from Rice Roots

The Na⁺/H ⁺ antiporter in vacuolar membranes transports Na⁺from the cytoplasm to vacuoles using a pH gradient generatedby proton pumps; it is considered to be related to salinitytolerance. Rice (Oryza sativa L.) is a salt-sensitive crop whosevacuolar antiporter is unknown. The vacuolar pH of rice roots,determined by ³¹P-nuclear magnetic resonance (NMR), increasedfrom 5.34 to 5.58 in response to 0.1 M NaCl treatment. Transportof protons into the tonoplast vesicles from rice roots was fluorometricallymeasured. Efflux of protons was accelerated by the additionof Na⁺. Furthermore, the influx of ²²Na⁺ into the tonoplastvesicles was accelerated by a pH gradient generated by proton-translocatingadenosine 5'-triphosphatase (H⁺-ATPase) and proton-translocatinginorganic pyro-phosphatase (H⁺-PPase). We concluded that thisNa⁺/H⁺antiporter functioned as a Na⁺ transporter in the vacuolarmembranes. The antiporter had a K_m of 10 mM for Na⁺ and wascompetitively inhibited by amiloride and its analogues. TheKⁱ values for 5-(N-methyl-N-isobutyl)-amiloride (MIA), 5-(N-ethyl-N-isopropyI)-amiloride(EIPA), and 5-(N, N-hexamethylene)-amiloride (HMA) were 2.2,5.9, and 2.9 µ M, respectively. Unlike barley, a salt-tolerantcrop, NaCl treatment did not activate the antiporter in riceroots. The amount of antiporter in the vacuolar membranes maybe one of the most important factors determining salt tolerance. ¹This work was supported by a grant from Bio-Media Project ofthe Japanese Ministry of Agriculture, Forestry and Fisheries(BMP96-III-1).     

Ca Fluxes and Membrane Potentials in Nitella translucens

The concentrations of Ca have been measured in the flowing cytoplasmand the vacuole of the single cells of Nitella translucens,the cells being immersed in an artificial pond Water (composition:NaCl, 1.0 mM; KCl, 0.1 mM; CaCl₂, 0. mM). In the flowing cytoplasmthe total concentration is 8 mM and in the vacuole 12 mM. Measurementsof the electrical potential differences across the plasmalemmaand tonoplast membranes show that the cytoplasm is at a potentialof —134 mV with respect to the bathing medium and —24mV with respect to the vacuole. An attempt has been made tomeasure the tracer fluxes of Ca and it is shown that the cellsare not in flux equilibrium. The influx is 0.046 µµmoles cm^–2 sec^–1; the efflux was too small to measurewith any degree of accuracy. The observed potential differences across both membranes arecompared with the Nernst potentials for Ca. This analysis showsthat Ca is not in electrochemical equilibrium across eithermembrane and that the driving forces on Ca are directed fromthe bathing medium and the vacuole into the cytoplasm. It issuggested that there is no necessity for a metabolically drivenCa pump at the plasmalemma because the low cytoplasmic Ca contentcould be due to the low permeability of the plasmalemma; theGoldman flux equation gives a value of P_Ca = 4.3x10^–8cm sec^–1. A Ca pump at the tonoplast appears to be necessaryto explain the steep electrochemical potential gradient fromthe vacuole to the cytoplasm. The efflux of Ca from the isolated cell wall has been measured.From these measurements it was possible to estimate the concentrationof indiffusible anions in the Donnan Free Space; the value obtainedwas 0.74 equiv. 1.^–1.     

The Import and Redistribution of Several Cations and Anions in Tomato Leaves

Wolterbeek, H. Th. and De Bruin, M. 1986. The import and redistributionof several cations and anions in tomato leaves.—J. exp.Bot. 37: 331–340. The upward movements in the xylem and redistribution from theleaf of Na⁺ , K⁺ , Rb⁺, Cs⁺ and four anions were examined insub-systems of tomato plants (Lycopersicon esculentum, Mill.cv. Tiny Tim). There was a delay with respect to the redistributionof newly imported elements from the source leaf of about 16–20h for all four alkali ions. This is considerably less than theapparent delay for the anions Sb(SO₄)^– WO₄^2– Mo₇O₂₄^6–and AsO₄^3– The prolonged delay for the anions is suggestedto be a consequence of metabolic transformation in the leaf.Reduction of the source-sink activity ratio did not decreasethe delay period from the source leaf, but apparently causedincreased Na⁺ transfer from the xylem. It is concluded thatthe application of a detailed mathematical descnption of upwardelement movement has considerable potential possibilities forunderstanding circulation of nutrients in the plant. Key words: Alkali ions, anions, xylem, phloem, redistribution, tomato     

Wirkung von K+ auf die Fluxe und den Transport von Na+ in Gerstenwurzeln,K+-stimulierter Na+-Efflux in der Wurzelrinde

Summary Barley roots grown on a nutrient solution containing 1 mM Na⁺ but no K⁺ are capable of a considerable Na⁺ transport via the symplasm of the root and the xylem vessels. K⁺ added to the medium surrounding the root cortex severely inhibits this transport after a lag period at a high rate constant (Fig. 3).It is likely that the fluxes of Na⁺ are changed drastically during this transition from low to high K⁺ status. Although originally limited to steady state fluxes, the extended method of efflux analysis for excised roots (Pitman, 1971) has been applied to the non-steady fluxes which occur upon the addition of K⁺ to the roots. It is shown that besides other changes the efflux of ²²Na⁺ through the cortex of barley roots is stimulated instantaneously (Fig. 5) by the addition of K⁺ and presumably by an influx of K⁺ ions. From this a transient, K⁺-stimulated Na⁺ efflux at the plasmalemma of the cortical cells can be estimated. It amounts to 10.9 moles/g fw · h compared to the control efflux of 3.3 moles/g fw · h without K⁺.The stimulated efflux is attributed to a Na⁺ efflux pump at the plasmalemma and is thus related to the K-Na-selectivity of barley plants. The inhibition of the Na⁺ transport by K⁺ is probably a consequence of this increased efflux of Na⁺ from the symplasm through the root cortex.