Characterization of the Ca2+-Dependent Cl- Efflux in Perfused Chara Cells

The mechanism of the Ca²⁺-dependent Cl^– efflux was studiedin tonoplast-free cells, in which the intracellular chemicalcomposition can be freely controlled. Tonoplast-free cells wereprepared by perfusing the cell interior of internodal cellsof Chara corallina with a medium that contained EGTA. The Ca²⁺-inducedCl^– efflux was measured together with the membrane potentialduring continuous intracellular perfusion. The dependenciesof Cl^– efflux and the membrane potential on the intracellularCa²⁺ or Cl^– concentrations were analyzed. When perfusionwas started with medium that contained Ca²⁺ ions, Cl^–efflux and membrane depolarization were induced. The amountof Cl^– efflux varied considerably among individual cells.The rate of efflux decreased exponentially but a residual effluxremained detectable. The Cl^– efflux was induced at concentrationsof Ca²⁺ ions above 1 µM and reached a maximum at 1 mM.By contrast, the membrane depolarization reached a maximum atabout 10 µM Ca²⁺. The rate of Cl^– efflux increasedlinearly with logarithmic increases in the intracellular Cl^–concentrations. These findings suggest that more than two kindsof Ca²⁺-dependent Cl^– channel might be present in theplasma membrane. Addition of ATP or its removal from the perfusion medium didnot affect the Ca²⁺-dependent Cl^– efflux. Calmodulin antagonistsslightly inhibited the Ca²⁺-dependent Cl^– efflux. ¹Present address: Biological Laboratory, Hitotsubashi University,Naka 2-1, Kunitachi, Tokyo, 186 Japan.     

Membrane Potentials and Resistances of Excitable Cells in the Petiole and Main Pulvinus of Mimosa pudica

Resting potentials of excitable cells in the petiole and mainpulvinus of Mimosa pudica depended on the external concentrationsof potassium ([K^$]) and sodium ([Na^$]), and peaks of the actionpotentials depended on the external concentration of chloride([Cl^–]) in the excitable protoxylem cells of the petioleand the upper-half cells of the main pulvinus, which suggeststhat the action potential in these cells is a Cl^– spike.In the lower-half cells of the main pulvinus, the peak of theaction potential did not show a clear dependence on [K^$], [Na^$]or [Cl^–]. This implies that there is a decrease in theion selectivity of the membrane toward the peak of the actionpotential. Effective membrane resistances of the excitable protoxylemand phloem cells of the petiole, and the lower-half cells ofthe main pulvinus were 3.9?3.1 M (mean?SD, n=7), 9.4?8.2 M (n=5)and 5.0?2.9 M (n=15), respectively. The membrane resistanceof the lower-half cells of the main pulvinus decreased on itssudden bending, but not always. ¹ Present address: 1st Department of Physiology, Hamamatsu UniversitySchool of Medicine, Handa-cho 3600, Hamamatsu 431-31, Japan. (Received November 17, 1981; Accepted January 29, 1982)     

Ionic Fluxes from Pulvinar Cells during the Rapid Movement of Mimosa pudica L.

K^$ and Cl^- contents and the ratio of the fresh weight to dryweight of the abaxial halves of the main pulvini of Mimosa decreasedafter movement, but changes in the adaxial halves were not clear.Another experimental result showed that the solution ejectedfrom the pulvinar cells flowed both toward the stem and thepetiole. These transferred ions and water may flow back to thepulvinar cells during recovery. (Received January 30, 1984; Accepted June 12, 1984)     

The Effects of 2,4-Dichlorophenoxyacetic Acid on Ion Uptake by Maize Roots

The effects of the synthetic auxin and herbicide 2,4-dichlorophenoxyaceticacid (2,4-D) on K^$ and Cl^– uptake and H^$ release by youngexcised maize roots has been studied. Brief exposure to 2,4-D(0.01 mmol dm^–3) at pH 3.5 causes a large depolarizationof the electrical potential across the root plasma membranesand converts K^$ uptake to K^$ leakage into the bathing solution.These results can be explained by the increased H^$ permeabilityof the membranes induced by the weak acid 2,4-D. The depolarizationresults in a less favourable electrochemical potential gradientfor K^$ uptake across these membranes. These effects are notrelated to the auxin properties of 2,4-D as the nonauxin 3,5-dichlorophenoxyaceticacid (3,5-D) gives rise to similar effects. The relative depolarizationsinduced by a range of weak acids appear to be unrelated to theiroil/water partition coefficients. In contrast, on bathing the roots for longer periods in solutions(pH > 5) containing 2,4-D (0.01 mmol dm^–3) K^$ and Cl^–uptake and H^$ release are inhibited. These effects are not shownwith 3,5-D suggesting an auxin-linked action for 2,4-D. Alsothe electrical potential across the plasma membranes is onlyslightly depolarized so that a change in the electrochemicalpotential gradient cannot be invoked to explain the loweredion fluxes. The evidence is consistent with the removal of anenergy supply to a metabolically linked K^–/H^– exchangemechanism in the plasma membranes. It is likely that both modes of action would operate to lowerion uptake under soil-grown conditions, the former becomingmore manifest in acidic soils.     

The Role of Transmembrane Electrical Potential in Determining the Absorption Isotherm for Chloride in Potato

Measurements have been made of the electrical potential differencebetween the vacuoles of single potato tuber cells and externalCl^- solutions over the range 1–40 mM. With K⁺ as the counter-ion,the relationship between this transmembrane electrical potentialand external Cl^- concentration, for fresh cells at 20° C,was found to be one of decreasing negative polarity with increasingCl^- concentration (E at 1 mM Cl^- external = – 81 m V;change in E for a 10-fold change in external concentration,E₁₀ = 46 m V). The linearity of this relationship, apparenton a semi-logarithmic plot, was virtually unaltered by low temperature(0.5–2.5° C) or by previous ageing of the cells forperiods up to four days (indicating that metabolic ion absorptionis not an electrogenic process). When the counter-ion was maintainedat a constant high concentration (40 mM K⁺), the change in potentialover the Cl^- concentration range was only 4 m V, polarity becomingmore negative with increasing Cl^- concentration. With Ca⁺⁺ asthe counter-ion, the potential to external Cl^- concentrationrelationship was similar to that found in KCl solutions, exceptthat E₁₀ was only about 20 m V. Curves for the influx of C1^- to be expected on the basis ofthese electrochemical data alone have been shown to run closelyparallel to Cl^– absorption isotherms previously determinedexperimentally. This confirms the opinion, already formed onthe basis of theoretically derived values for passive Cl^- influx,that Cl^- uptake by both fresh and one-day-aged potato tissue,from KCl solutions and Cl^- solutions with a fixed high K⁺ concentration,is rate-determined at o° C by passive movement across theplasmalemma. Uptake of Cl^- by fresh tissue at 20° C appearsto be similarly regulated. No such parallelism was found between observed and expectedpatterns of Cl^- uptake from CaCl₂ solutions, or from KCl bytwo-day-aged tissue, and here factors in addition to the electrochemicalones must determine low temperature Cl^-uptake.     

Ca2+-dependent Cl− efflux in tonoplast-free cells ofNitellopsis obtusa

Summary In order to demonstrate the presence of a Ca²⁺-activated Cl^–-channel in theNitellopsis plasmalemma, tonoplast-free cells were prepared and their intracellular Ca²⁺ concentration was modified by internal perfusion. An increase in the Ca²⁺ concentration caused a large Cl^– efflux with a concomitant depolarization of the membrane potential. These changes were for the most part reversible. The critical Ca²⁺ concentration was about 4.0 m. Neither the Cl^– efflux nor the membrane depolarization showed a time-dependent inactivation. A Cl^–-channel blocker, A-9-C (9-anthracenecarboxylic acid) reduced both the Cl^– efflux and the magnitude of the membrane potential depolarization. A small increase in the intracellular Ca²⁺ concentration, which is caused by membrane excitation of tonoplast-free cells is not sufficient to activate this Ca²⁺-dependent Cl^–-channel.     

Chloride in Soils and its Uptake and Movement within the Plant: A Review

Natural inputs of chlorine (Cl) to soils come mainly from rainwater,sea spray, dust and air pollution. In addition, human practices,such as irrigation and fertilization, contribute significantlyto Cl deposition. In the soil solution, Cl occurs predominantlyas the chloride anion (Cl^-). The Cl^-anion does not form complexesreadily, and shows little affinity (or specificity) in its adsorptionto soil components. Thus, Cl^-movement within the soil is largelydetermined by water flows. Chlorine is an essential micronutrientfor higher plants. It is present mainly as Cl^-. Chloride isa major osmotically active solute in the vacuole and is involvedin both turgor- and osmoregulation. In the cytoplasm it mayregulate the activities of key enzymes. In addition, Cl^-alsoacts as a counter anion, and Cl^-fluxes are implicated in thestabilization of membrane potential, regulation of intracellularpH gradients and electrical excitability. Chloride enters plantsthrough the roots, and there is some concern over the uptakeof the long-lived radionuclide³⁶Cl, which enters into the foodchain through plants. Chloride is thought to traverse the rootby a symplastic pathway, and Cl^-fluxes across the plasma membraneand tonoplast of root cells have been estimated. These fluxesare regulated by the Cl^-content of the root. Chloride is mobilewithin the plant. The Cl^-concentrations of xylem and phloemsaps have been determined and Cl^-fluxes through the xylem andphloem have been modelled. Measurements of transmembrane voltagesand Cl^-activities in cellular compartments suggest (1) thatactive Cl^-transport across the plasma membrane dominates Cl^-influxto root cells at low Cl^-concentrations in the soil solutionand that passive Cl^-influx to root cells occurs under more salineconditions, and (2) that both active and passive Cl^-transportoccurs at the tonoplast. Electrophysiological studies have demonstratedthe presence of an electrogenic Cl^-/2H⁺symporter in the plasmamembrane of root-hair cells and Cl^-channels mediating eitherCl^-influx or Cl^-efflux across the plasma membrane. Similarly,there is both biochemical and electrophysiological evidencethat Cl^-channels mediate Cl^-fluxes in either direction acrossthe tonoplast and that a Cl^-/nH⁺antiport mediates Cl^-influxto the vacuole. This article reviews the availability of Cl^-inthe soil, the roles and distribution of Cl^-within the plant,the magnitude of Cl^-fluxes across membranes and between tissues,the mechanisms of Cl^-transport across membranes and the electricalcharacteristics and molecular biology of Cl^-channels. Copyright2001 Annals of Botany Company Review, Arabidopsis thaliana, channel, chloride (Cl^-), influx, phloem, plasma membrane, radiochlorine (³⁶Cl), soil, tonoplast, transport, uptake, xylem     

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)     

Comparative Studies of Leaf Tissue and Isolated Mesophyll Protoplasts: II. ION RELATIONS

Freshly isolated tobacco mesophyll protoplasts had contentsof K^$, Cl^– and Na^$ slightly higher (on a cell basis) thanthe original leaf tissue, and had a high K^$/Na^$ ratio similarto that of the leaf tissue. Influxes of these ions into theprotoplasts were of similar magnitudes to the correspondingfluxes in leaf tissue when compared on the basis of the respectiveplasmalemma surface areas. In both systems the K^$ influx wasstrongly inhibited by CN^– and by DNP. These results suggestthat the ion relations of the freshly isolated mesophyll protoplastswere similar to those of the original leaf tissue and that isolatedmesophyll protoplasts should be a useful system for the studyof ion transport processes in leaf cells.     

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     

Movements of K+ during Shutting and Opening of the Trap-Lobes in Aldrovanda vesiculosa

K⁺ movements during the shutting and subsequent opening of trap-lobesin Aldrovanda vesiculosa were measured using ⁸⁶Rb as a tracerfor K⁺. Immediately after the shutting, a large amount of ⁸⁶Rbpre-loaded in the trap-lobes was detected in the hollow spaceinside the shut trap. This may indicate that much of the K⁺in the active motor cells leaks out during the shutting, resultingin turgor loss in the cells. ⁸⁶Rb(K⁺) uptake in the trap wasactive. During the opening process, enhanced ⁸⁶Rb uptake wasobserved. The time course of this uptake was similar to thatof the opening of the trap-lobes, and both courses were acceleratedby IAA. Enhanced K⁺ uptake may restore the turgor in activemotor cells. The quantity of K⁺ that moved during the shuttingor opening was estimated as 20% of that in the active motorcells in the open state of the trap-lobes. The K⁺ efflux acrossthe membranes of the active motor cells may be caused by a largeincrease in bulk flow triggered by an action potential, andwas estimated as 6,200 pmol.cm^–2. ¹ This paper is dedicated to the memory of Professor Joji Ashidawho established the physiology of rapid movement in Aldrovandavesiculosa. (Received July 22, 1982; Accepted November 11, 1982)     

Effect of Ferricyanide on Potassium Uptake by Intact Epidermal Tissue and Guard Cell Protoplasts

The effect of ferricyanide on K^$ fluxes in epidermis and inguard cells of Commelina communis L. were studied. Ferricyanideenhanced guard cell protoplasts swelling, which results fromenhanced K^$ uptake. In intact epidermis ferricyanide inhibitedK^$ uptake and consequently, stomatal opening. This was foundin floated and submerged epidermal tissues, indicating thatthe degree of contact with the solution does not affect theresponse to ferricyanide. Investigation of the rate of plasmolysisand de-plasmolysis of guard cells in epidermal tissue revealedthat ferricyanide enhances deplasmolysis, caused by K^$ uptake,only in completely plasmolysed cells, which resemble protoplastsin situ. (Received January 21, 1988; Accepted March 24, 1988)     

Nitrate Inhibition of Chloride Influx in Barley: Implications for a Proposed Chloride Homeostat

Net accumulation of Cl^– by intact barley plants was virtuallyeliminated in roots and reduced by 40% in shoots when externalmedia (0.5 mol m^–3 CaSO₄ plus 0–5 mol m^–3KCI) were supplemented with 0.25 mol m^– Ca(NO₃)₂. Plasmalemma³⁶Cl^– influx (_oc) was shown to be insensitive to externalNO₃^- in plants which had previously been grown in solutionslacking ^–3, but _oc became sensitive to NO₃^-after a lagperiod of 3–6 h. Kinetic analyses revealed that the inhibitionof 36C1^– influx by external NO₃^- was complex. At 0.25mol m^–3 NO₃^- the V_max for Cl^– influx was reducedby greater than 50%, with insignificant effects upon K_m. At0.5 mol m^–3 NO₃^- there was no further effect upon V_maxbut K_m for influx increased from 38±5 mmol m^–3to 116±26 mmol m^–3. By contrast, Cl^– effluxwas found to be insensitive to external NO₃^-. A model for theregulation of Cl^– influx is proposed which involves bothnegative feedback effects from vacuolar NO₃^- +Cl^–) concentrationand (external) NO₃^- inhibition of Cl^– influx at the plasmalemma.These combined effects serve to discriminate against Cl^–accumulation, favouring NO₃^- accumulation, when the latter ionis available. Such observations are inconsistent with recentproposals for the existence of bona fide homeostats for chlorideaccumulation in higher plants. Key words: Nitrate inhibition, Chloride influx, Barley     

Cl- Fluxes and Cl- Content of Dunaliella acidophila--An Alga with a Positive Membrane Potential

The Cl^– fluxes across the plasma membrane and the Cl^–content of the acid–resistant alga Dunaliella acidophila(optimal growthat pH 1.0, positive membrane potential) werestudied in the presence of 0.01–300 mM Cl^–. Up to40 mM Cl^– in the medium, theinternal Cl^– concentrationis higher than that predicted by the electrochemical equilibrium,whereas at higher external Cl^– concentrations internalCl^– levels are lower than expected for the electrochemicalequilibrium. Growth in the absence of Cl^– is significantlylower than in the standard growth medium (2.2 mM Cl^–)and this reduction cannot be overcome by the addition ofothermonovalent anions such as Br^– or NO^–₃ The latterimplies a specific Cl^– requirement in addition to therole of Cl^– as apermeant anion during ion translocations.Growth and photosynthesis tolerate an excess of Cl^– upto 300 mM (without stepwiseadaptation to increasing salinity).The uptake of Cl^– (measured by tracer techniques) exhibitsMichaelis–Menten kinetics (K_M = 0.75 mM Cl^–) andis stimulated by light and high H⁺ concentrations. Internalacidification by acetic acid causes an inhibition of Cl^–uptake. The uptake of Cl^– is inhibited by the monovalentanions Br^–, I^–, and NO^–₃ with K¹, values notvery much different from the K_M. value for Cl^–. The aniontransport inhibitors SITS and DIDS do not affect photosynthesis,but strongly suppressthe uptake of Cl^–. The Cl^–channel blockers A–9–C and NPPB cause inhibitionsof Cl^– uptake as well as of photosynthesis andthe ATPpool. FCCP strongly depresses the internal ATP–pool withouta marked effect on Cl^– uptake. Cl^– efflux was inhibitedbyDIDS and SITS, but stimulated or inhibited by FCCP, dependingon the external Cl^– concentration. Results are in agreementwiththe hypothesis that Cl^– uptake into D. acidophila is dueto catalysed diffusion and is primarily independent of the hydrolysisofATP. Cl^– efflux is assumed to be coupled to an activepump. Data suggest tight co–operativity between the systemsresponsiblefor Cl^– uptake and Cl^– efflux, with thecytoplasmic pH and the membrane potential being important mediators. Key words: Acid resistance, chloride carrier, chloride channels, Dunaliella acidophila, membrane potential, plasma membrane     

Intracellular chloride and potassium ions in relation to excitability ofChara membrane

Summary Internodal cells ofChara australis were made tonoplast-free by replacing the cell sap with EGTA-containing media; then the involvement of internal Cl^– and K⁺ in the excitation of the plasmalemma was studied.[Cl^–] _i was drastically decreased by perfusing the cell interior twice with a medium lacking Cl^–. The lowered [Cl^–] _i was about 0.01mm. Cells with this low [Cl^–] _i generated action potential and showed anN-shapedV–I curve under voltage clamped depolarization like Cl^–-rich cells containing 13 or 29mm Cl^–.E _m at the peak of the action potential was constant at [Cl^–] _i between 0.01 and 29mm. The possibility that the plasmalemma becomes as permeable to other anions as to Cl^– during excitation is discussed.At [Cl^–] _i higher than 48mm, cells were inexcitable. When anions were added to the perfusion medium to bring the K⁺ concentration to 100mm, NO ₃ ^– , F^–, SO ₄ ^2– , acetate, and propionate inhibited the generation of action potentials like Cl^–, while methane sulfonate, PIPES, and phosphate did not inhibit excitability.The duration of the action potential depended strongly on the intracellular K⁺ concentration. It decreased as [K⁺] _i (K-methane sulfonate) increased. Increase in [Na⁺] _i (Na-methane sulfonate) also caused its decrease, although this effect was weaker than that of K⁺. The action of these monovalent cations on the duration of the action potential is the opposite of their action on the membrane from the outside (cf. Shimmen, Kikuyama & Tazawa, 1976,J. Membrane Biol. 30:249).     

KATP channels depress force by reducing action potential amplitude in mouse EDL and soleus muscle

Although ATP-sensitive K⁺ (K_ATP) channel openers depress force, channel blockers have no effect. Furthermore, the effects of channel openers on single action potentials are quite small. These facts raise questions as to whether 1) channel openers reduce force via an activation of K_ATP channels or via some nonspecific effects and 2) the reduction in force by K_ATP channels operates by changes in amplitude and duration of the action potential. To answer the first question we tested the hypothesis that pinacidil, a channel opener, does not affect force during fatigue in muscles of Kir6.2^-/- mice that have no cell membrane K_ATP channel activity. When wild-type extensor digitorum longus (EDL) and soleus muscles were stimulated to fatigue with one tetanus per second, pinacidil increased the rate at which force decreased, prevented a rise in resting tension, and improved force recovery. Pinacidil had none of these effects in Kir6.2^-/- muscles. To answer the second question, we tested the hypothesis that the effects of K_ATP channels on membrane excitability are greater during action potential trains than on single action potentials, especially during metabolic stress such as fatigue. During fatigue, M wave areas of control soleus remained constant for 90 s, suggesting no change in action potential amplitude for half of the fatigue period. In the presence of pinacidil, the decrease in M wave areas became significant within 30 s, during which time the rate of fatigue also became significantly faster compared with control muscles. It is therefore concluded that, once activated, K_ATP channels depress force and that this depression involves a reduction in action potential amplitude. Kir6.2^-/- mice; pinacidil; action potential train; M wave     

Characteristics of Action Potentials in Willow (Salix viminalis L.)

After application of electric stimuli (square DC pulses) extra-andintracellular potentials were recorded on willow shoots. Theall-or-nothing law, strength-duration relation, and generalcharacteristics of the action potential were investigated. Byusing inhibitors of ionic channels (tetraethylammonium, MnCl₂,LaCl₃), the excitability of willow could be completely blocked.Treatment with the phosphorylation uncoupler dinitrophenol induceda depolarization and disappearance of excitability, indicatingthe participation of a metabolic component of the membrane potential.By using energy-dispersive X-ray microanalysis, the distributionof chloride, potassium and calcium was measured in differenttissues of non-stimulated and stimulated willow shoots. It was shown that stimulation of the plant was followed by ionshifts which were most striking in the phloem cells. While theircontent of potassium and chloride was diminished after stimulation,the amount of cytoplasmic calcium increased slightly. Thesedisplacements lead to the conclusion that Ca²⁺ influx as wellas K⁺ and Cl^– efflux are involved in the propagation ofaction potentials. Key words: Action potential, electrical stimuli, energy-dispersive X-ray microanalysis, ion shifts, Salix viminalis     

Inhibition of Cl- Channel Activation in Chara corallina Membrane by Lanthanum Ion

We examined a role of Ca²⁺ in the activation of the two majorion channels, i.e., Cl^– and K⁺ channels at the excitationof the characean plasmalemma. The current-voltage relation (I-Vcurve) of the Chara membrane was compared under the ramp voltageclamp condition before and after external application of 20µMof La³⁺ (a Ca²⁺ channel blocker). The transient inward currentcomponent, which is carried mainly by the efflux of Cl^–,disappeared almost completely in about 30 min with La³⁺ treatment.On the other hand, no effect was observed on the late largeoutward current, which is mainly carried by the efflux of K⁺in a large depolarization region (less negative than –50mV). These results suggest that the Cl^– channel in theChara plasmalemma is activated by Ca²⁺ influx, while the K⁺channel is simply activated by depolarization. (Received April 7, 1986; Accepted June 6, 1986)     

STUDIES ON NITELLA HAVING ARTIFICIAL CELL SAP II. RATE OF CYCLOSIS AND ELECTRIC POTENTIAL

The rate of cyclosis, the value of resting potential and theexcitability were studied on the Nitella internode whose cellsap was replaced with artificial solutions. K⁺ to Ca⁺⁺ ratioin the cell sap should be within 2 to 50 in order to maintainthe normal rate of cyclosis and the resting and action potentialsat least for several days. Replacement of the cell sap witha solution containing Li⁺, Na⁺ or Rb⁺ in place of K⁺ had noappreciable effect on the activity of the internode for severaldays, while gradual but marked decrease in the rate of cyclosisand the resting potential was observed with Cs⁺. There was noappreciable difference between the effects of Cl^– andNO₃^– on cyclosis, resting and action potentials, whileSO₄^–– decreased them to some extent. The rate ofcyclosis was not affected appreciably by changes in osmoticconcentration between 0.17 and 0.30 M. (Received September 6, 1963; )     

Volume changes and whole cell membrane currents activated during gradual osmolarity decrease in C6 glioma cells: contribution of two types of K+ channels

Volume changes and whole cell ionic currents activated by gradual osmolarity reductions (GOR) of 1.8 mosM/min were characterized in C6 glioma cells. Cells swell less in GOR than after sudden osmolarity reductions (SOR), the extent of swelling being partly Ca²⁺ dependent. In nominally Ca²⁺-free conditions, GOR activated predominantly whole cell outward currents. Cells depolarized from the initial –79 mV to a steady state of –54 mV reached at 18% osmolarity reduction [hyposmolarity of –18% (H-18%)]. Recordings of Cl^– and K⁺ currents showed activation at H-3% of an outwardly rectifying Cl^– current, with conductance of 1.6 nS, sensitive to niflumic acid and 5-nitro-2-(3-phenylpropylamino)benzoic acid, followed at H-18% by an outwardly rectifying K⁺ current with conductance of 4.1 nS, inhibited by clofilium but insensitive to the typical K⁺ channel blockers. With 200 nM Ca²⁺ in the patch pipette, whole cell currents activated at H-3% and at H-13% cells depolarized from –77 to –63 mV. A K⁺ current activated at H-1%, showing a rapid increase in conductance, suppressed by charybdotoxin and insensitive to clofilium. These results show the operation of two different K⁺ channels in response to GOR in the same cell type, activated by Ca²⁺ and osmolarity and with different osmolarity activation thresholds. Taurine and glutamate efflux, monitored by labeled tracers, showed delayed osmolarity thresholds of H-39 and H-33%, respectively. This observation clearly separates the Cl^– and amino acid osmosensitive pathways. The delayed amino acid efflux may contribute to counteract swelling at more stringent osmolarity reductions. volume regulation; taurine; hyposmolarity; isovolumetric regulation; regulatory volume decrease