Acidification and Alkalinization of Culture Medium by Catharanthus roseus cellsIs Anoxic Production of Lactate a Cause of Cytoplasmic Acidification?

Catharanthus roseus(L.) G. Don cells acidified Mura-shige-Skoogmedium rapidly. Upon transfer to fresh medium, the medium pH(initially5.3) dropped below 4 within 2 d. This acidificationwas reversed under hypoxic conditions. The cells induced a similaracidification in a simple medium consisting of CaCl₂, KCl, andglucose: medium pH dropped below 4 within 6 h. The acidificationwas accompanied by an influx of K⁺ at a H⁺(efflux)/K⁺ ratioof ca 0.6 as well as by an expansion of endogenous organic acidpool, in which malic and citric acids were the major components.Anoxia reversed all these processes: the direction of both K⁺and H⁺ fluxes reversed with a H⁺/K⁺ ratio of 1.70. Anoxia induceda cytoplasmic acidification from pH 7.6 (aerobic) to 7.4 asmeasured by 31P-NMR, accompanied by a rapid, long-lasting lactateaccumulation at expense of malic and citric acids. Evidencesuggested that accumulation of lactic acid was not a cause ofcytoplasmic acidification under anoxia, but a result of pH regulationby the biochemical pH-stat [Davies (1973) Symp. Soc. Exp. Biol.27: 513]. The anoxic acidification of the cytoplasm was ascribedto the influx of H⁺ from the medium. (Received April 18, 1997; Accepted July 8, 1997)     

Uptake of Imidazole and its Effects on the Intracellular pH and Ionic Relations of Chara corallina

Ammonia (pK_a 9.25) and methylamine (pK_a, 10.65) increase cytoplasmicpH and stimulate Cl^– influx in Chara corallina, theseeffects being associated with influx of the amine cations ona specific porter. The weak base imidazole (pK_a 6.96) has similareffects but diffuses passively into the cell both as an unionizedbase and as a cation. When the external pH is greater than 6.0influx of the unionized species predominates. Imidazole accumulates to high concentrations in the vacuole,where it is protonated. Cytoplasmic pH and vacuolar pH riseby only 0.2–0.3 units, suggesting a large balancing protoninflux across the plasma membrane. Balance of electric chargeis partially maintained by net efflux of K⁺ and net influx ofCl^–. Calculation of vacuolar concentrations of imidazole(from (¹⁴C] imidazole uptake, assuming that there is no metabolism)plus K⁺ and Na⁺ indicates an excess of cations over inorganicanions (Cl^–). However, although the osmotic potentialof the cells increases, also indicating increased solute concentrations,the increase is less than that predicted by the calculated ionicconcentrations. This discrepancy remains to be resolved. Becausethe osmotic potential also increases when imidazole is absorbedfrom Cl^–-free solutions it is likely that maintenanceof charge-balance can also involve synthesis and vacuolar storageof organic or amino acids. Key words: Imidazole, potassium, intracellular pH, membrane transport, Chara     

Effect of External pH on the Cytoplasmic and Vacuolar pHs in Mung Bean Root-Tip Cells: A 31P Nuclear Magnetic Resonance Study

The effect of the external pH on the intracellular pH in mungbean (Vigna mungo (L.) Hepper) root-tip cells was investigatedwith the ³¹P nuclear magnetic resonance (NMR) method. The ³¹PNMR spectra showed three peaks caused by cytoplasmic G-6-P,cytoplasmic P_i and vacuolar P_i. The cytoplasmic and vacuolarpHs could be determined by comparing the P_i chemical shiftswith the titration curve. When the external pH was changed overa range from pH 3 to 10, the cytoplasmic pH showed smaller changesthan the vacuolar pH, suggesting that the former is regulatedmore strictly than the latter. The H⁺-ATPase inhibitor, DCCD,caused the breakdown of the mechanism that regulates the intracellularpH. H⁺-ATPase appears to have an important part in the regulationof the intracellular pH. (Received January 4, 1984; Accepted August 27, 1984)     

Role for the Vacuolar H+-ATPase in Regulating the Cytoplasmic pH: An in Vivo Study Carried out in chl1, an Arabidopsis thaliana Mutant Impaired in NO-3 Transport

The effects of the growth in a medium containing NH₄NO₃ as nitrogensource were studied on cell sap pH, cytoplasmic pH and malatecontent in chl1, an Arabidopsis thaliana mutant impaired inchlorate and nitrate transport. In all the conditions testedthe pH of the cytoplasm in chl1 was more alkaline, and thatof the vacuole was more acidic as compared with those measuredin wt. Treatment with bafilomycin A1, a specific inhibitor ofthe vacuolar H⁺-ATPase, induced a small alkalinization of thevacuole, and a significant acidification of the cytoplasm, theseeffects being greater in chl1 than in wt. The greater responseof the mutant to bafilomycin Al suggests that, in the absenceof the inhibitor, the activity of the tonoplast H⁺-ATPase inchl1 is higher than in wt, this diversity being a possible reasonfor the differences in intracellular pH detected between thetwo strains. A possible role for the vacuolar H⁺-ATPase in regulatingthe cytoplasmic pH is discussed. (Received August 2, 1995; Accepted February 1, 1996)     

Inhibition of Malate Synthesis by Vanadate: Implications for the Cytosolic Alkalinization Induced by Vanadate Concentrations Partially Inhibiting the Plasmalemma H+ Pump

The effects of Na-orthovanadate, at concentrations only partiallyinhibiting net H⁺ extrusion, were determined on vacuolar andcytosolic pH by the weak base and weak acid distribution atequilibrium. Treatment with vanadate induces in Elodea densaleaves and in Arabidopsis thaliana seedlings a moderate acidificationof both cell sap and vacuole. Conversely, it induces an alkalinizationof cytosol, this effect being in apparent contrast with a conditionof reduced activity of the H⁺-transporting plasmalemma ATPase,which should be associated with a cytosolic acidification. InArabidopsis seedlings treated with vanadate, the increase inpH of both cytosol and external medium is associated with adecrease in cell sap buffer capacity, more evident for highervanadate concentrations, and particularly marked in the pH rangebetween 3·5 and 5·5. In these conditions, themalate content is strongly reduced, its decrease almost completelyaccounting for the decrease in cell sap buffer capacity. Anin vitro analysis of the vanadate effect on phosphoenolpyruvatecarboxylase indicates that the decrease in malate content seemssubstantially due to an inhibiting effect of vanadate on thisenzyme. These results stress that the in vivo use of vanadateas an inhibitor of the plasmalemma H⁺-ATPase must be taken withcaution; in particular, for studying the correlations betweenchanges in net H⁺ extrusion and changes in cytosolic pH andrelated processes. Key words: Vanadate, malate, cytosolic pH, Elodea densa, Arabidopsis thaliana     

Effects of Two Plasmalemma ATPase Inhibitors on H+ Extrusion and Intracellular pH in Elodea densa Leaves

Beffagna, N. and Romani, G. 1988. Effects of two plasmalemmaATPase inhibitors on H⁺ extrusion and intracellular pH in Elodeadensa leaves.—J. exp. Bot. 39: 1033–1043. Elodea leaves in the dark show very little exchange of H⁺ withthe medium in the external pH range between 5.0 and 6.0. Thepresence of fusicoccin and potassium in the medium markedlystimulates H⁺ extrusion. Fusicoccin- and K⁺ -induced H⁺ extrusionis inhibited by either erythrosin B (EB) or Na-orthovanadate,two inhibitors of H⁺ transporting plasma membrane ATPase. EBcompletely inhibits it from the first 30 min of treatment, whensupplied at pH 5.5 at a concentration of 30 mmol m^–3.Vanadate also inhibits H⁺ extrusion, this effect becoming evidentonly after 45 min of treatment. After this time inhibition iscomplete with 250 mmol m^–3 vanadate but only partial forlower concentrations. In the presence of either inhibitor the intracellular pH, measuredas cell sap pH, is significantly lowered. When the intracellularpH changes are determined on vacuole and, separately, on cytoplasmby the weak acid and base distribution method, acidificationof both compartments is found to accompany the blocking of H⁺extrusion by either of the inhibitors. Key words: Intracellular pH, vanadate, erythrosin B, H⁺pumping     

Intracellular pH Regulation in an Acidophilic Unicellular Alga, Cyanidium caldarium: 31P-NMR Determination of Intracellular pH

The intracellular pH of an acidophilic unicellular alga, Cyanidiumcaldarium, was determined as a function of external pH by ³¹Pnuclear magnetic resonance. The algal cells incubated underaerobic conditions or under anaerobic and illuminated conditionsmaintained the intracellular pH in the range from 6.8 to 7.0even when the external pH was changed from 1.2 to 8.4. Underanaerobic and dark conditions, however, the intracellular pHacidified at the acidic pH region of the external medium. Theacidified intracellular pH reversibly returned to neutral eitheron aeration or illumination. The results indicate that, in Cyanidiumcells growing in extremely acidic environments, an active H⁺efflux (H⁺ pump) which depends on metabolic activity (respirationor photosynthesis) is essential to maintain the intracellularpH at a constant physiological level against the passive H⁺leakage due to the steep pH gradient across the cell membrane. (Received March 19, 1986; Accepted July 17, 1986)     

Salinity-induced Malate Accumulation in Chara

Ion absorption by Chara corallina from solutions containingpredominantly KC1 or RbCl at up to 100 mol m^–3 resultedin accumulation of salts and turgor regulation. Turgor regulationdid not occur in solutions containing Na⁺ or Li⁺salts. Duringion absorption from various salts of K⁺ and Rb⁺ vacuolar cationconcentration exceeded Cl^– concentration. This differencewas shown to be balanced by the synthesis and accumulation ofmalate. Vacuolar malate concentration reached 48 mol m₃^–,with accumulation occurring at rates of up to 0.45 mol m^–3h^–1. Malate accumulation was inhibited by low externalpH and was dependent upon external HCO₃^– concentration.The synthesis of malic acid and its subsequent dissociationimposed a severe acid load on the cell. Biophysical regulationof cellular pH was achieved by a H⁺efflux at a rate of about40 nmol m^–2 s^–1from the cell. The results presentedargue against cytoplasmic Cl^–, HCO₃^– or pH regulatingmalate accumulation in Chara and it is suggested that malatetransport across the tonoplast may regulate malate accumulation. Key words: Malate, Chara corallina, pH regulation, salinity     

Effects of Abscisic Acid and Cytoplasmic pH on Potassium and Chloride Efflux in Arabidopsis thaliana Seedlings

The effects of ABA, isobutyric acid (IBA) and nicotine on K⁺and Cl⁺ efflux were studied in Arabidopsis thaliana seedlings,and the role of pH_cyt, and E_m in the regulation of the effluxof these ions was discussed. The data show that treatments withIBA and nicotine influenced in opposite directions the effluxof either K⁺ or Cl^–: K⁺ efflux was increased by nicotineand reduced in the presence of IBA, whereas Cl^– effluxwas stimulated by IBA and decreased by nicotine treatment. Underall the conditions tested ABA induced cytoplasmic acidificationand inhibition of K⁺ and Cl^– net efflux. Experiments aimedto estimate the individual contribution of pH_cyt and E_m in modulatingK^– efflux indicated that, within the range of acidic pH_cytvalues, a regulation of K⁺ efflux was imposed by pH_cyt on thecontrol exerted by E_m, the efflux being inhibited by lower pH_cytvalues. Conversely, in the alkaline side of pH_cyt K⁺ effluxseemed linked only to the E_m values. These results are consistentwith the hypothesis that the decrease in K⁺ efflux observedin non-stomatal tissues in the presence of ABA may be mediatedby the cytoplasmic acidification induced by the hormone. (Received August 6, 1996; Accepted January 19, 1997)     

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).     

Potassium Transport and Regulation of Intracellular pH in Elodea densa Leaves

The effects of extracellular K⁺ concentration ([K⁺]_o) on the pH of cell sap, “bulk cytoplasm” and vacuole have been investigated in Elodea densa leaves under conditions of either low or high activity of the plasmalemma electrogenic H⁺ pump. Cell sap pH was evaluated directly in the cell sap expressed after freezing and thawing. Cytoplasmic and vacuolar pH were calculated by the weak base and weak acid distribution method, DMO and benzylamine appearing to be a suitable acid and base, respectively, for this purpose in this material. When added to the basal medium (no rapidly permeating ions present), 5 mM K⁺ induced an increase in intracellular pH, larger for the cell sap and the vacuole (about 0.2 units), and smaller but still significant for the cytoplasm (0.07 units). This alkalinizing effect of K⁺ was thus associated with a significant decrease in the pH difference across the tonoplast. The alkalinizing effect of K⁺ was markedly and synergistically enhanced by the presence of fusicoccin, a condition inducing a marked activation of H⁺ extrusion and of K⁺ uptake. The correlation between these effects of [K⁺]_o on intracellular pH and those on H⁺ extrusion indicates that changes in extracellular K⁺ concentration, and thus in K⁺ influx, can influence cytoplasmic and vacuolar pH by modulating the rate of H⁺ extrusion by the plasmalemma H⁺ pump.     

Effects of Cations on the Cytoplasmic pH of Chara corallina

Smith, F. A. and Gibson, J.–L. 1985. Effects of cationson the cytoplasmic pH of Chara corallina.—J.exp. Bot.36: 1331–1340 Removal of external Ca²⁺ from cells of Chara corallina lowersthe cytoplasmic pH, as determined by the intracellular distributionof the weak acid 5,5–dimethyloxazolidine2–,4–dione(DM0), when the external pH is below about 60. This effect isreversed, at least partially, by addition of the following cationsto Ca²⁺-free solutions: tetraethylammonium (TEA⁺) and Na⁺ at5 or 10 mol m^-3, Li⁺ and Cs⁺ (10 mol m^-3), or Mg²⁺, Mn²⁺ andLa³⁺ (02 or 05 mol m^-3). Under the same conditions, increasesin pH sometimes, but not always, occur in the presence of 10mol m^-3 K⁺ or Rb⁺ The results are discussed in relation to the major transportprocesses that determine pH and the electric potential differenceacross the plasma membrane, namely fluxes of H⁺ and of K⁺. Thesimplest explanation of the effects of the various cations testedin this study is that they primarily affect pHi_c via changesin influx of H⁺ but direct effects on the H⁺ pump or on K⁺ fluxesmay also be involved Key words: Chara corallina, cytoplasmic pH, cations, H⁺transport     

Effect of Intracellular ATP Levels on the Light-Induced H+ Efflux from Intact Cells of Cyanidium caldarium

The light-induced H⁺ efflux observed at acidic pH in Cyanidiumcells was shown to be an active H⁺ transport depending on theintracellular ATP produced by cyclic photo-phosphorylation.Triton X-100 was found to act as an effective uncoupler in intactCyanidium cells without collapsing the pH gradient across theplasma membrane. Triton X-100 at 0.015% significantly reducedthe intracellular ATP levels, stimulated the p-BQ, Hill reactionand completely inhibited the light-induced H⁺ efflux. Inhibitionof the H⁺ efflux by Triton X-100 correlated well with the depressionof the apparent rale of light-induced ATP synthesis as wellas the decrease in the intracellular ATP level in light. The light-induced H⁺ efflux was completely inhibited by diethylstilbestrol,a specific inhibitor of plasma membrane ATPase, without anychanges in the intracellular ATP level, thereby suggesting theparticipation of the plasma membrane ATPase in the light-inducedH⁺ efflux. ¹The data in this paper are included in the Ph. D. dissertationsubmitted by M. Kura-Hotta to Tokyo Metropolitan University. (Received February 3, 1984; Accepted June 14, 1984)     

Biophysical and Biochemical Regulation of Cytoplasmic pH in Chara corallina during Acid Loads

The contribution of membrane transport to regulation of cytoplasmicpH in Chara corallina has been measured during proton-loadingby uptake of butyric acid. In the short-term (i.e. up to 20min) uptake of butyric acid is not affected by removal of externalK⁺, Na⁺ or Cl^– but over longer periods uptake is decreased(by 20–50% in different experiments) in the absence ofexternal Na⁺ or, sometimes, K⁺. Influxes of both Na⁺ and K⁺increase temporarily after addition of butyrate, Na⁺ immediatelyand K⁺ after a lag. Effects on Cl^– influx are small butCl^– efflux increases enormously after a short lag. Anapproximate comparison of internal butyrate with changes inthe concentration of K⁺, Na⁺, and Cl^– suggests that initially(i.e. for a few min) cytoplasmic pH is determined by bufferingand possibly by some decarboxylation of organic acids (biochemicalpH regulation), and that biophysical pH regulation involvingefflux of H⁺ balanced by influxes of K⁺, Na⁺ and especiallyefflux of Cl^– progressively becomes dominant. When butyric acid is washed out of the cells, cytoplasmic pHis restored completely or partially (depending on the butyrateconcentration used) and this is independent of the presenceor absence of external Cl^–. Where Cl^– is present,its influx is relatively small. It is suggested that cytoplasmicpH is then controlled biochemically, involving the synthesisof an (unidentified) organic acid and the accumulation of acidicanions in place of butyurate lost from the cell. During thesecond application of butyrate, net Cl^– efflux is small:it is suggested that control of cytoplasmic pH then involvesdecarboxylation of the organic acid anions. The questions of the source of Cl^– lost from the cell(cytoplasm or vacuole) and of possible cytoplasmic swellingassociated with the accumulation of butyrate are discussed. Key words: Chara corallina, butyric acid, cytoplasmic pH, membrane transport     

31P NMR Measurements of Cytoplasmic pH Changes in Maize Root Tips

³¹P nuclear magnetic resonance (NMR) spectroscopy has been usedto measure the changes caused by sodium azide and anaerobiosisin the cytoplasmic pH of maize (Zea mays L.) root tips. Measurementsof H⁺ influx, lactate accumulation and ATP hydrolysis, togetherwith estimates of the cytoplasmic volume and the cytoplasmicbuffering capacity, were used to calculate the expected pH changesunder the same conditions. In the case of azide inhibition,where there was a large H⁺ influx, there was good agreementbetween the calculated and measured pH changes. In contrastduring anoxia, where the accumulation of lactate was the mostimportant source of protons, the predicted cytoplasmic pH changewas greater than the observed change. It was concluded thatin the absence of a compensating H⁺ efflux, the excess H⁺ productionwas offset by the production of H⁺-consuming metabolites suchas -aminobutyrate. Key words: Cytoplasmic pH, ³¹P NMR, Membrane H⁺ fluxes.     

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     

Bafilomycin A1 is a non-competitive inhibitor of the tonoplast H+-ATPase of maize coleoptiles

When microsomal membranes from maize (Zea mays L. cv. Clipper)coleoptiles were separated by isopyc-nic centrifugation on acontinuous 10–45% sucrose gradient, bafilomycin A1-inhibitedATPase activity co-localized with the activities of the tonoplastmarker-enzymes, nitrate-Inhibited ATPase and K⁺-dependent pyrophosphatase.Thus, bafilomycin A1 is a specific inhibitor of the vacuolarH⁺-ATPase of maize coleoptiles. Inhibition of the vacuolar H⁺-ATPaseby bafilomycin A1 was strictly dependent upon the concentrationof the enzyme present in the assay medium, suggesting a stoichiometricassociation between bafilomycin A1 and the vacuolar H⁺-ATPase.In tonoplast-enriched preparations, half-maximal inhibitionwas obtained at 43 pmol bafilomycin A1 mg^–1 protein. BafilomycinA1 inhibited the vacuolar H⁺-ATPase in a simple non-competitivemanner: increasing bafilomycin A1 concentrations reduced theV_max, of the H+ -ATPase, but had no effect on its K_m towardsATP. Key words: Bafilomycin A1, coleoptile, H⁺-ATPase (vacuolar), maize, Zea mays L     

Shoot-Dependent Regulation of Sodium and Potassium Fluxes in Roots of Whole Barley Seedlings

Unidirectional fluxes and the cytoplasmic and vacuolar contentsof potassium and sodium in root cells of intact barley seedlings(Hordeum vulgare L., cv. Villa) were determined by use of compartmentalanalysis. In addition, the net vacuolar accumulation J_cv andthe xylem transport ø_cx of K⁺ and Na⁺ were measured.Both of these data were needed for the evaluation of the effluxdata. Fluxes and compartmental contents of K⁺ and Na⁺ were comparableto data obtained with excised roots. The effect of the shoot-to-rootratio—as varied by partial excision of the seedlings seminalroots—on the fluxes and contents was investigated. Highershoot-to-root ratios induced an increase in xylem transport,in plasmalemma influx, and also in the cytoplasmic content ofK⁺ and Na⁺. With potassium the plasmalemma efflux was almostunaltered while the tonoplast fluxes and vacuolar content weredecreased (in presence of Na⁺). With sodium, on the other hand,the plasmalemma efflux and the tonoplast fluxes were also increasedin the plants having one root and a high shoot-to-root ratio.These changes occurred even under conditions of low humidity,when transpiration was low and guttation occurred. The latterwas also increased at the high shoot-to-root ratio. The observedchanges could be due to a relieved feedback control of ion fluxesby the shoot and mediated in part by a relatively higher supplyof photosynthates in the plants having one root In addition,hormonal signals were suggested to participate. In particulara possibly decreased level of cytokinins in the plants havingonly one root could contribute to the signal. The observed changesappear to be responses of the plant to an alteration that canoccur under natural conditions when the root system is damaged.     

Efficiency of Potassium Utilization by Barley Varieties: The Role of Subcellular Compartmentation

Memon, A. R., Saccomani, M. and Glass, A. D. M. 1985. Efficiencyof potassium utilization by barley varieties: The role of subcellularcompartmentation.?J. exp. Bot. 36: 1860–1876. The subcellulardistributions of K⁺ in roots of three barley (Hordeum vulgareL.) varieties, grown at 10 and 100 mmol m^–3 external K⁺([K⁺]_o) were estimated by compartmental analyses. In general,increased [K⁺]_o caused a 2–3 fold increase in vacuolar[K⁺], but cytoplasmic [K⁺] increased only slightly. Nevertheless,the three varieties, which had been selected for study on thebasis of their different rates of K⁺ utilization, showed distinctdifferences in the allocation of K⁺ between cytoplasm and vacuole.At 10 mmol m^–3 [K⁺]_o var. Betzes exhibited typical K⁺deficiency symptoms while var. Fergus and var. Compana did not,even though Betzes had higher [K⁺] in shoots and roots. Theinefficient utilization of K⁺ in this variety appears to beassociated with a failure to mobilize vacuolar K⁺ into the cytoplasmiccompartment (the ratio of vacuolar: cytoplasmic K⁺ contentsfor Betzes was 4.1 compared to 2.7 and 2.5, respectively, forFergus and Compana). Fergus and Betzes, which demonstrate pronouncedgrowth responses to increased [K⁺]₀ between 10 and 100 mmolm^–3, showed significant increases of cytoplasmic [K⁺]in this range of [K⁺]_o. By contrast, cytoplasmic [K⁺] in Compana,a variety whose growth is not stimulated by increased [K⁺]₀(from 10 to 100 mmol m^–3) showed virtually no increase.It is suggested that the efficiency of K⁺ utilization and thegrowth response to [K⁺]₀ in these varieties are functions ofthe subcellular distribution of this ion between cytoplasm andvacuole. Key words: Barley varieties, K⁺ subcellular compartmentation, utilization efficiency     

Proton Transport and pH Control in Sinapis alba Root Hairs: A Study carried out with Double-Barrelled pH Micro-electrodes

Continuous measurements of cytoplasmic pH (pH_c) in Sinapis roothairs have been carried out with double-barrelled pH-micro-electrodesin order to gain information on translocation of protons acrossthe plasmalemma and cytoplasmic pH control. (i) The cytoplasmicpH of Sinapis (7–33 ? 0–12, standard conditions)changes no more than 0.1 pH_c, per pH_o-unit, regardless of whethercyanide is present or not. (ii) Weak acids rapidly acidify pH_cand hyperpolarize, while weak bases alkalize pH_c and depolarizethe cells, (iii) 1.0 mol M,³ NaCN acidifies the cytoplasm by0.4 to 0.7 pH-units, but alkalizes the vacuole. (iv) 20 mmolm^–3 CCCP has no significant effect on pH_c, if added atpH 9.6 or 7.2, but acidifies pH_c by 1.3 units at pH 4.3. Inthe presence of CCCP, cyanide acidifies the cytoplasm, (v) Chloridetransiently acidifies pH_c, while K⁺, Na⁺, and have no significant effects, (vi) Cytoplasmic buffer capacityforms a bell-shaped curve versus pH_c with an optimum of about50 mol m^–3 H⁺pH_c-unit. The modes of proton re-entry and the effects of active and passiveproton transport on cellular pH control are critically discussed.It is suggested that the proton leak, consisting of H⁺-cotransport(e.g. H⁺/Cl^–) rather than H⁺-uniport, is no threat topH_c. The proton export pump, although itself reacting to changesin pH_c, influences pH_c only to a minor extent. It is concludedthat buffer capacity and membrane transport play moderate rolesin pH_c control in Sinapis, while the interlocked H⁺-producingand -consuming reactions of cellular metabolism are the mainregulating factors. This makes pH control in Sinapis quite differentfrom bacterial and animal cells. Key words: Cytoplasmic pH, double-barrelled pH micro-electrode, pH control, proton transport, Sinapis