Movement of Lucifer Yellow CH in potato tuber storage tissues: A comparison of symplastic and apoplastic transport

The fluorescent dye Lucifer Yellow CH (LYCH) was introduced directly into the symplast of potato (Solanum tuberosum L.) tuber storage parenchyma by microinjection and also into the apoplast through cuts made in the stolon cortex. Microinjected LYCH moved away rapidly from a single storage cell and spread radially via the symplast. When the microinjected tissue was subsequently fixed in glutaraldehyde and sectioned the dye was seen clearly to be localised in the cytoplasm but not in the vacuole. In comparison, when LYCH was introduced into cuts made in the stolon cortex the dye entered the tuber by the xylem and subsequently spread apoplastically. No movement of dye was observed in the phloem. In glutaraldehyde-fixed tissues, in which LYCH was introduced to the apoplast, the dye was found within xylem vessels, in the cell walls and in intercellular spaces. Wall regions, possibly associated with plasmodesmata, became stained by the dye as it moved through the apoplast. Three hours after introduction of the dye to the stolon, intense deposits of LYCH were found in the vacuoles of all cells in the tuber, many aligned along the tonoplast. Differentiating vascular parenchyma elements contained large amounts of dye within enlarging vacuoles. However, with the exception of plasmolysed and-or damaged cells, LYCH was absent from the cytoplasm following its introduction to the plasmalemma it is suggested that the most likely pathway from the cell wall to the vacuole was by endocytosis, the dye being transported across the cytoplasm in membrane-bound vesicles. Clathrin-coated vesicles were abundant in the storage cells, providing a possible endocytotic pathway for dye movement. The significance of these observations is discussed in relation to the movement of LYCH in plant tissues and to the movement of solutes within and between storage cells of the tuber.Abbreviation LYCH Lucifer Yellow CH     

Uptake of Lucifer Yellow CH into intact barley roots: Evidence for fluid-phase endocytosis

Intact barley (Hordeum vulgare L.) roots have been shown to take up the highly fluorescent dye Lucifer Yellow CH (LYCH) into their cell vacuoles. In the apical 1 cm of root tip, differentiating and dividing cells showed a prolific uptake of LYCH into their provacuoles. The LYCH was retained during fixation, apparently becoming bound to electron-dense material in the vacuoles. The dye freely entered the apoplast of roots in which the Casparian band was not developed, being taken up into the vacuoles of cells in both the cortex and stele. However, when LYCH was applied to a 1-cm zone approx. 6 cm behind the root tip the Casparian band on the radial walls of the endodermis completely prevented the dye from entering the cells of the stele, only the cell walls and vacuoles of the cortical cells taking up the dye. The inability of LYCH to cross the plasmalemma of the endodermal cells and enter the stele via the symplast substantiates previous claims that the dye is unable to cross the plasmalemma of plant cells. The results are discussed in the light of recent demonstrations that LYCH is a particularly effective marker for fluid-phase endocytosis in animal and yeast cells. A calculation of the energetic requirements for LYCH uptake into barley roots supports the contention that LYCH is taken up into the vacuoles of plant cells by fluid-phase endocytosis.Abbreviation LYCH Lucifer Yellow CH     

The Permeability of the Guard Cell Plasma Membrane and Tonoplast

Uptake experiments and efflux compartmental analysis of planthormones, osmotica and toxins using ‘isolated’ guardcells of Valerianella locusta and guard cell protoplasts (GCP)of Vicia faba were performed in order to study the permeabilityproperties of guard cell plasma membrane and tonoplast. Theplasma membrane of guard cells exhibits a higher permeabilitythan plasma membranes of mesophyll cells for most solutes investigated.The permeability coefficients (P_s calculated for the guard cellplasma membranes are also significantly higher than the P_s valuesfor the guard cell tonoplast. This applies also for protonatedABA. We suppose that the high permeability for ABAH could bepart of the target cell properties. A Collander analysis demonstratesa linear correlation between P_s, values and the ratio K_r/M_r^1,5for both plasma membrane (r = 0.87) and for the tonoplast (r=0.93). Because of deviations from the observed correlations,the permeation of some solutes (ABA, GA, IAA through the tonoplast;methylamine through the plasma membrane) seems to be facilitatedby an additional transport mechanism. The Collander analysisof the plasma membrane of GCP shows very similar results tothe analysis of the plasma membrane of ‘isolated’guard cells, indicating that isolation of protoplasts does notalter the permeability of the guard cell plasma membrane. Key words: Permeability coefficient, guard cells, plasma membrane, tonoplast     

Effect of Ca2+ on Tonoplast Potential of Permeabilized Characeae Cells

Using permeabilized characean cells in which the ionic conditionsat the cytoplasmic side of the tonoplast are easily controlled,effects of Ca²⁺ ion on tonoplast potential were examined. Whenthe cell was treated with 1 µM Ca²⁺, the tonoplast potential(E_M became positive in a complicated manner in Chara corallinawhile it simply became negative in Nitella axilliformis. Whenthe cell was treated with 9-antracenecarboxylic acid, a Cl^–-channelinhibitor, E_m became more negative and the response of E_m toCa²⁺ was significantly suppressed. It is suggested that Ca²⁺activates Cl^–-channel at a low concentration and inactivatesat a higher one in C. corallina while it simply inactivate Cl^–-channelin N. axilliformis. ¹Present address: Biological Laboratory, The University of theAir, Wakaba 2-11, Wakaba, 260 Japan. (Received August 22, 1988; Accepted December 26, 1988)     

FRET-based voltage probes for confocal imaging: membrane potential oscillations throughout pancreatic islets

Insulin secretion is dependent on coordinated pancreatic islet physiology. In the present study, we found a way to overcome the limitations of cellular electrophysiology to optically determine cell membrane potential (V_m) throughout an islet by using a fast voltage optical dye pair. Using laser scanning confocal microscopy (LSCM), we observed fluorescence (Förster) resonance energy transfer (FRET) with the fluorescent donor N-(6-chloro-7-hydroxycoumarin-3-carbonyl)-dimyristoylphosphatidyl-ethanolamine and the acceptor bis-(1,3-diethylthiobarbiturate) trimethine oxonol in the plasma membrane of essentially every cell within an islet. The FRET signal was approximately linear from V_m –70 to +50 mV with a 2.5-fold change in amplitude. We evaluated the responses of islet cells to glucose and tetraethylammonium. Essentially, every responding cell in a mouse islet displayed similar time-dependent changes in V_m. When V_m was measured simultaneously with intracellular Ca²⁺, all active cells showed tight coupling of V_m to islet cell Ca²⁺ changes. Our findings indicate that FRET-based, voltage-sensitive dyes used in conjunction with LSCM imaging could be extremely useful in studies of excitation-secretion coupling in intact islets of Langerhans. pancreatic -cell; optical electrophysiology; islet electrical coupling     

Characterization of Two Proton Transport Systems in the Tonoplast of Plasmalemma-Permeabilized Nitella Cells

ATP-dependent and PP_i-dependent H⁺-transport systems of thetonoplast were characterized in plasmalemma-permeabilized Nitellacells, where direct access to the protoplasmic surface of thetonoplast was possible. Since H⁺ transport across the tonoplastcan be measured in situ, the identity of the membrane responsiblefor H⁺ pumping is unequivocal. H⁺ transport was evaluated bythe accumulation of neutral red. While both transport systemswere obligately dependent on Mg²⁺, the two transport systemsshowed completely different sensitivity to NO₃^– and K⁺,suggesting the presence of two types of H⁺-pumps in Nitellatonoplast. NO₃^– applied to the protoplasmic surface, completelyand reversibly inhibited ATP-dependent transport but had noeffect on PP_i-dependent transport. By contrast, NO₃^– appliedinto the vacuole by the vacuolar perfusion technique did notinhibit ATP-dependent or PP_i-dependent H⁺ transport. Replacementof K⁺ with the organic cation, BTP, inhibited PP_i-dependenttransport but not the ATP-dependent one, indicating that PP_i-dependenttransport is K⁺ dependent. The sensitivities of the H⁺ transportsystems found in the tonoplast of Nitella are quite similarto those of higher plant tonoplasts. ¹ Present address: Department of Botany, Faculty of Science,University of Tokyo, Hongo, Tokyo 113, Japan. (Received February 21, 1987; Accepted May 27, 1987)     

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     

The Conductance of the Plasmalemma for CO2

Permeability coefficients (P_S values) for CO₂ of the plasmamembrane (PM) of the unicellular green algae Eremosphaera viridis,Dunaliella parva, and Dunaliella acidophila, and of mesophyllprotoplasts isolated from Valerianella locusta were determinedfrom ¹⁴CO₂ uptake experiments using the rapid separation ofcells by the silicone oil layer centrifugation technique. Theexperimental P_S values were compared with calculated numbersobtained by interpolation of Collander plots, which are basedon lipid solubility and molecular size, for D. parva cells,mesophyll protoplasts isolated from Spinacia oleracea, mesophyllcells and guard cells of Valerianella, and guard cell protoplastsisolated from Vicia faba. The conductivity of algal plasma membranes for CO₂ varies between0.1 and 9 ? 10^–6 m s^–1, whereas for the plasmalemmaof cells and protoplasts isolated from leaves of higher plantsvalues between 0.3 and 11 ? 10^–6 m s^–1 were measured.By assuming that these measurements are representative for plantsand algae in general, it is concluded that the CO₂ conductivityof algal PM is of the same order of magnitude as that of thehigher plant cell PM. P_s values of plasma membranes for CO₂are lower than those for SO₂, but are in the same order of magnitudeas those measured for H₂O. On the basis of these results itis concluded that theoretical values of about 3000 ? 10^–6m s^–1 believed to be representative for higher plant cells(Nobel, 1983) and which are frequently used for computer-basedmodels of photosynthesis, lack experimental confirmation andrepresent considerable overestimations. However, with severalsystems, including higher plant cells, the conductance of thePM for CO₂ was significantly higher in light than in darkness.This suggests that in light, additional mechanisms for CO₂ uptakesuch as facilitated diffusion or active uptake may operate inparallel with diffusional uptake. Key words: Conductivity, CO₂, permeability coefficient, photosynthesis, plasmalemma     

Sodium Stimulates Regeneration of Phosphoenolpyruvate in Mesophyll Chloroplasts of Amaranthus tricolor

Mesophyll chloroplasts were isolated from leaves of a Na⁺-requiringNAD-malic enzyme type, dicotyledonous C₄ plant, Amaranthus tricolorL. The chloroplasts converted pyruvate to phosphoenolpyruvateunder illumination, and the conversion was stimulated by Na⁺.This observation may explain the requirement for Na⁺ of someC₄ plants. ² Present address: Institute for Life Science Research, NihonNohyaku Co., Ltd., Kawachi-Nagano, Osaka, 586 Japan     

An electrophysiological study of the membrane in aplanospore-like cell of Boergesenia forbesii

Membrane potential and resistance, each of which was the sumof those of the plasmalemma and tonoplast, measured in the coenocyticthallus of Boergesenia forbesii were 6.7 mv inside positiveand 2.8 k.cm², respectively. Protoplasm squeezed from the thallus into artificial sea water(ASW) formed numerous spherical bodies, which are termed aplanospore-likecells (simply "spores"). The following electrical propertiesof the "spores" 20–40 hr after squeezing were obtained:potential difference (p.d.) across plasmalemma (E_co) was –66mv (– means inside negative), plasmalemma resistance 665cm², p.d. across the tonoplast (E_vc) +73 mv, and tonoplast resistance2.6 k.cm². Tenfold increase in external [K⁺] caused +45 mv changein E_co and +17 mv in E_vc. The plasmalemma was entirely depolarizedin Ca⁺⁺-free ASW or ASW containing Triton X-100. When the "spore" was immersed in potassium-rich (277 mil) ASW,E_co was almost zero and the tonoplast showed two states (I andII, E_ve about +70 mv and +20 mv, respectively). E_vc went backand forth between the two states spontaneously or when a smallcurrent was applied. In most cases oscillatory changes in E^vcoccurred after the lapse of a long time in the K+-rich sea water.Membrane resistances in states I and II were 5 and 9 k.cm²,respectively. (Received July 11, 1977; )     

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.     

Characterization of the vacuolar-type H+-ATPase from guard cell protoplasts of Commelina

Characteristics of the vacuolar-type (V-type) H⁺-ATPase fromguard cell protoplasts of Commelina communis L. were investigatedusing a linked enzyme assay and nitrate inhibition as a diagnosticindicator of the enzyme activity. ATPase activity was completelyinhibited by about 50 mol m^–3 nitrate and activity wasoptimal near pH 8.0. The temperature optimum for activity wasabout 37 C and an Arrhenius plot indicated changes in activationenergy for the ATPase at 15C and possibly at about 30 C. Theenzyme was stimulated by Cl^– while Ca²⁺ inhibited activity(l₅₀ = 1.5 mol m^–3). The apparent K_m (MgATP) was 0.62mol m^–3. Incubation of guard cell protoplasts for up to 5 h in 50 µMabscisic acid (ABA) or 25µM fusicoccin (FC) did not affectsubsequent ATPase activity. In vitro assays with FC or ABA alsodid not affect enzyme activity. Activity was not affected bylight or potassium ferricyanide, two factors which are knownto influence stomatal activity. Beticoline was a potent inhibitorof activity (l₅₀ = 50 µM) while DCCD was less effective(l₅₀ = 90µM). On chlorophyll, protein and protoplast bases, V-type ATPaseactivity was greater in guard cell protoplasts than mesophyllcell protoplasts by 66, 13.9 and 1.9, respectively. On atonoplast surface area basis the enzyme activity was 5.6 timeshigher in guard cell protoplasts than in mesophyll cell protoplasts Thus, although the characteristics of the V-type, H ⁺-ATPaseof GCP are very similar to those found in other cell types,rates of activity and probably tonoplast enzyme density aremuch greater in guard cell protoplasts than mesophyll cell protoplastsof C. communis which corresponds with the large and rapid ionfluxes across the tonoplast associated with stomatal movements Key words: Guard cell protoplasts, stomata, V-type H ⁺-ATPase     

Presence of the distinct systems responsible for superoxide anion and hydrogen peroxide generation in red tide phytoplankton Chattonella marina and Chattonella ovata

Raphidophycean flagellates, Chattonella marina and C. ovata,are harmful red tide phytoplankters; blooms of these phytoplanktersoften cause severe damage to fish farming. Previous studieshave demonstrated that C. marina and C. ovata continuously producereactive oxygen species (ROS) such as superoxide anion (O₂^–)hydrogen peroxide (H₂O₂) under normal growth conditions, andan ROS-mediated toxic mechanism against fish and other marineorganisms has been proposed. Although the exact mechanism ofROS generation in these phytoplankters still remains to be clarified,our previous study suggested that NADPH oxidase-like enzymelocated on the cell surface of C. marina may be involved inO₂^– generation. To investigate the localization of O₂^–and H₂O₂ generation in C. marina and C. ovata, we employed 2-methyl-6(p-methoxyphenyl)-3,7-dihydroimidazo[1,2-a]pyrazin-3-oneand 5-(and-6)-carboxy-2',7'-dichlorodihydrodihydrofluoresceindictate, acetyl ester, which are specific fluorescent probefor detecting O₂^– and H₂O₂, respectively. Observationby fluorescence microscopy of live phytoplankters incubatedwith each probe revealed that O₂^– is mainly generatedon the cell surface, whereas H₂O₂ is generated in the intracellularcompartment in these phytoplankters. When the cells were rupturedby ultrasonic treatment, O₂^– levels of C. marina and C.ovata decreased significantly, whereas a few times higher levelsof H₂O₂ were detected in the ruptured cell suspensions whencompared with the levels of the live cell suspension. In immunoblottinganalysis, the protein recognized by anti-human gp91 phox wasdetected in both species. These results suggest that, in bothphytoplankters, the underlying mechanisms of O₂^– and H₂O₂generation may be distinct and such systems are independentlyoperating in the cells.     

DNA damage-induced [Zn(2+)](i) transients: correlation with cell cycle arrest and apoptosis in lymphoma cells

Reactive changes in free intracellularzinc cation concentration ([Zn²⁺]_i) weremonitored, using the fluorescent probe Zinquin, in human lymphoma cells exposed to the DNA-damaging agent VP-16. Two-photon excitation microscopy showed that Zinquin-Zn²⁺ formscomplexes in cytoplasmic vesicles. [Zn²⁺]_iincreased in both p53^wt (wild type) and p53^mut(mutant) cells after exposure to low drug doses. In p53^mutcells noncompetent for DNA damage-induced apoptosis, elevated [Zn²⁺]_i was maintained at higher drug doses,unlike competent p53^wt cells that showed a collapse of thetransient before apoptosis. In p53^wt cells, the[Zn²⁺]_i rise paralleled an increase in p53and bax-to-bcl-2 ratio but preceded an increase in p21^WAF1,active cell cycle arrest in G₂, or nuclear fragmentation.Reducing [Zn²⁺]_i, usingN,N,N',N'-tetrakis(2-pyridylmethyl)ethylenediamine, caused rapid apoptosis in both p53^wt andp53^mut cells, although cotreatment with VP-16 exacerbatedapoptosis only in p53^wt cells. This may reflectchanged thresholds for proapoptotic caspase-3 activation incompetent cells. We conclude that the DNA damage-induced transient isp53-independent up to a damage threshold, beyond which competent cellsreduce [Zn²⁺]_i before apoptosis.Early stress responses in p53^wt cells take place in anenvironment of enhanced Zn²⁺ availability.

     

Interactions of Ca2+ and NaCI stress on the ion relations and intracellular pH of Sorghum bicolor root tips: An in vivo 31P-NMR study

In vivo ³¹P-NMR measurements showed that supplemental Ca²⁺ (5.0mM CaSO₄) decreased the magnitude of the NaCl-induced reductionof the pH gradient across the tonoplast (     

Endothelial response to stress from exogenous Zn2+ resembles that of NO-mediated nitrosative stress, and is protected by MT-1 overexpression

While nitric oxide (NO)-mediated biological interactions have been intensively studied, the underlying mechanisms of nitrosative stress with resulting pathology remain unclear. Previous studies have demonstrated that NO exposure increases free zinc ions (Zn²⁺) within cells. However, the resulting effects on endothelial cell survival have not been adequately resolved. Thus the purpose of this study was to investigate the role of altered zinc homeostasis on endothelial cell survival. Initially, we confirmed the previously observed significant increase in free Zn²⁺ with a subsequent induction of apoptosis in our pulmonary artery endothelial cells (PAECs) exposed to the NO donor N-[2-aminoethyl]-N-[2-hydroxy-2-nitrosohydrazino]-1,2-ethylenediamine. However, NO has many effects upon cell function and we wanted to specifically evaluate the effects mediated by zinc. To accomplish this we utilized the direct addition of zinc chloride (ZnCl₂) to PAEC. We observed that Zn²⁺-exposed PAECs exhibited a dose-dependent increase in superoxide (O₂^–·) generation that was localized to the mitochondria. Furthermore, we found Zn²⁺-exposed PAECs exhibited a significant reduction in mitochondrial membrane potential, loss of cardiolipin from the inner leaflet, caspase activation, and significant increases in TdT-mediated dUTP nick end labeling-positive cells. Furthermore, using an adenoviral construct for the overexpression of the Zn²⁺-binding protein, metallothionein-1 (MT-1), we found either MT-1 overexpression or coincubation with a Zn²⁺-selective chelator, N,N,N',N'-tetrakis(2-pyridylmethyl)ethylene-diamide, in PAECs significantly protected the mitochondria from both NO and Zn²⁺-mediated disruption and induction of apoptosis and cell death. In summary, our results indicate that a loss of Zn²⁺ homeostasis produces mitochondrial dysfunction, increased oxidative stress, and apoptotic cell death. We propose that regulation of Zn²⁺ levels may represent a potential therapeutic target for disease associated with both nitrosative and oxidative stress. reactive nitrogen species; apoptosis mitochondrial dysfunction     

Demonstration of light-induced potential change in Chara cells lacking tonoplast

Chara cells without tonoplasts, prepared by replacing the cellsap with EGTA-containing media, showed essentially the samepattern of light-induced changes in membrane potential and membraneresistance as normal cells although the concentrations of ionsand ATP in the cytoplasm decreased considerably (1/3–1/10)after loss of the tonoplast. Removal of the tonoplast reducedthe rate of photosynthetic O₂ evolution to about 50% of thatof normal cells but did not affect the magnitude of light-inducedpotential change. Not a full but a certain level of electronflow seems necessary to activate the putative electrogenic H⁺-pump. ¹ Present address: Department of Botany, Faculty of Science,University of Tokyo, Japan. ² Present address: Niigata College of Pharmacy, Niigata 950-21,Japan. (Received September 4, 1978; )     

ATP-Dependent Ca2+ Transport in Tonoplast Vesicles from Apple Fruit

Protoplasts and vacuoles were isolated from immature apple fruit(Malus pumila Mill. cv. Golden Delicious). ATP-stimulated Ca²⁺uptake was identified in both protoplast vesicles and tonoplastvesicles. The apparent K_m for Ca²⁺ of the tonoplast transportsystem was 43.4 µM. The pH optima were 7.2 and 6.7 forCa²⁺ transport by protoplast and tonoplast vesicles, respectively.Ca²⁺ transport in tonoplast vesicles was strongly inhibitedby the calmodulin antagonists fluphenazine and N-(6-aminohexyl)-5-chloro-l-naphthalensulfonamidehydrochloride (W-7), while N-aminohexyl)-l-naphthalensulfonamidehydrochloride (W-5) was relatively ineffective. Addition ofexogenous calmodulin stimulated transport by 35%. Ca²⁺ uptakewas inhibited by vanadate, but not by the ionophores carbonylcyanidem-chlorophenyl hydrazone (CCCP) or valinomycin. The resultsindicate that apple tonoplasts have a Ca²⁺ transport systemthat is driven by the direct hydrolysis of ATP, and may be calmodulindependent. ¹Present address: Morioka Branch, Fruit Tree Research Station,Ministry of Agriculture, Forestry and Fisheries, Shimokuriyagawa,Morioka 020-01, Japan. To whom reprint requests should be addressed. (Received October 18, 1985; Accepted January 29, 1986)     

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.     

Role of K(+) channel expression in polyamine-dependent intestinal epithelial cell migration

Polyamines are essential for cell migrationduring early mucosal restitution after wounding in the gastrointestinaltract. Activity of voltage-gated K⁺ channels (Kv) controlsmembrane potential (E_m) that regulates cytoplasmicfree Ca²⁺ concentration([Ca²⁺]_cyt) by governing thedriving force for Ca²⁺ influx. This study determinedwhether polyamines are required for the stimulation of cell migrationby altering K⁺ channel gene expression,E_m, and[Ca²⁺]_cyt in intestinal epithelialcells (IEC-6). The specific inhibitor of polyamine synthesis,-difluoromethylornithine (DFMO, 5 mM), depleted cellularpolyamines (putrescine, spermidine, and spermine), selectivelyinhibited Kv1.1 channel (a delayed-rectifier Kv channel) expression,and resulted in membrane depolarization. Because IEC-6 cells did notexpress voltage-gated Ca²⁺ channels, the depolarizedE_m in DFMO-treated cells decreased [Ca²⁺]_cyt as a result of reduceddriving force for Ca²⁺ influx through capacitativeCa²⁺ entry. Migration was reduced by 80% in thepolyamine-deficient cells. Exogenous spermidine not only reversed theeffects of DFMO on Kv1.1 channel expression, E_m,and [Ca²⁺]_cyt but also restoredcell migration to normal. Removal of extracellular Ca²⁺ orblockade of Kv channels (by 4-aminopyridine, 1-5 mM) significantly inhibited normal cell migration and prevented the restoration of cellmigration by exogenous spermidine in polyamine-deficient cells. Theseresults suggest that polyamine-dependent intestinal epithelial cellmigration may be due partially to an increase of Kv1.1 channelexpression. The subsequent membrane hyperpolarization raises[Ca²⁺]_cyt by increasing the drivingforce (the electrochemical gradient) for Ca²⁺ influx andthus stimulates cell migration.