Studies on Electrogenesis under High K+ Concentrations in Internodal Cells of Chara corallina

+ concentration ([K⁺]_o) on the membrane potential (E_m) of Chara corallina was studied. E_m more negative than -100 mV was maintained even at 100 mM [K⁺]_o. Addition of Ca²⁺ to the external medium further increased this tendency. However, E_m responded sensitively to the increase in [K⁺]_o, when the electrogenic proton pump of the plasma membrane was inhibited by treating cells with dicyclohexylcarbodiimide, an inhibitor of proton pump. Analysis using equivalent circuit model of the plasma membrane suggested that the electrogenic proton pump was activated by the increase in [K⁺]_o. In the presence of 100 mM K⁺, action potentials were generated by electric stimuli. The ionic mechanism of generation of action potentials in the presence of K⁺ at high concentration was discussed. Received 3 October 2000/ Accepted in revised form 6 January 2001     

A study of the current-voltage relationships of electrogenetic active and passive membrane elements in riccia fluitans

Potassium- and proton-dependent membrane potential, conductance, and current-voltage characteristics (I–V curves) have been measured on rhizoid cells of the liverwort Riccia fluitans. The potential difference (E_m) measured with microelectrodes across plasmalemma and tonoplast is depolarized to the potassium-sensitive diffusion potential (E_D) in the presence of 1 mM NaCN, 1 mM NaN₃, or at temperatures below 6°C. Whereas the temperature change from 25°C to 5°C decreases the membrane conductance (g_m) from 0.71 to 0.43 S ? m^?2, 1 mM NaCN increases g_m by about 25%. The membrane displays potassium-controlled rectification which gradually disappears at temperatures below 5°C. The potassium pathway can be described by an equivalent circuit of a diode and an ohmic resistor in parallel. In the potential interval of E_D ± 100 mV the measured I-V curves roughly fit the theoretical curves obtained from a modified diode equation. ⁸⁶Rb⁺(K⁺)-influx is voltage sensitive: In the presence of 1 mM NaCN, ⁸⁶Rb⁺-influx follows a hyperbolic function corresponding to a low conductance at low [K⁺]_o and high conductance at high [K⁺]_o. On the contrary ⁸⁶Rb⁺-influx is linear with [K⁺]_o when pump activity is normal. It is believed that there are two K⁺-transport pathways in the Riccia membrane, one of which is assigned to the low conductance (0.2 S · m^?2), the other to a temperature-dependent facilitated diffusion system with a higher conductance (7.7 S · m^?2). The electrogenic pump essentially acts as a current source and consumes about 39% of the cellular ATP-turnover. In the presence of 30 μM CCCP the saturation current of 0.1 A · m^?2 is doubled to about 0.2 A · m^?2, and the electromotive force of ?360 mV switches to ?250 mV. It is suggested that this may be due to a change in stoichiometry from one to two transported charges per ATP hydrolyzed.     

Simultaneous Measurements of Cytoplasmic K Concentration and the Plasma Membrane Electrical Parameters in Single Membrane Samples of Chara corallina

The electrophysiological properties of cytoplasm-rich fragments (single membrane samples) prepared from internodal cells of Chara corallina were explored in conjunction with K⁺-sensitive microelectrode and current-voltage (I-V) measurements. This system eliminated the problem of the inaccessible cytoplasmic layer, while preserving many of the electrical characteristics of the intact cells. In 0.1 millimolar external K concentration (K_o⁺), the resting conductance (membrane conductance G_m, 0.85 ± 0.25 Siemens per square meter (±standard error)) of the single membrane samples, was dominated by the proton pump, as suggested by the response of the near-linear I-V characteristic to changes in external pH. Initial cytoplasmic K⁺ activities (a_K+), judged most reliable, gave values of 117 ± 67 millimolar; stable a_K+ values were 77 ± 31 millimolar. Equilibrium potentials for K⁺ (Nernst equilibrium potential) (E_K) calculated, using either of these data sets, were near the mean membrane potential (V_m). On a cell-to-cell basis, however, E_K was generally negative of the V_m, despite an electrogenic contribution from the Chara proton pump. When K_o⁺ was increased to 1.0 millimolar or above, G_m rose (by 8- to 10-fold in 10 millimolar K_o⁺), the steady state I-V characteristics showed a region of negative slope conductance, and V_m followed E_K. These results confirm previous studies which implicated a K_o⁺-induced and voltage-dependent permeability to K⁺ at the Chara plasma membrane. They provide an explanation for transitions between apparent K_o⁺-insensitive and K_o⁺-sensitive (`K⁺ electrode') behavior displayed by the membrane potential, as recorded in many algae and higher plant cells.     

Dependence of membrane potential on Ca2+ transport in cultured cytotrophoblasts of human immature placentas

The electrical membrane properties of cultured human cytotrophoblast were examined by means of a standard electrophysiological technique. The mean values of the membrane potential (E_m) and the membrane resistance in a physiological medium were around ?49 mV and 12 MΩ, respectively. The membrane potential was dependent, to a large extent, on the external Ca²⁺ concentration ([Ca²⁺]₀). Deprivation of external Ca²⁺ reduced membrane potential to about ?20 mV, and an increase in [Ca²⁺]₀ caused a hyperpolarization in a saturable manner. The Ca²⁺-dependency of membrane potential was affected remarkably by [K⁺]₀, but not by [Na⁺]₀ or [Cl^?]₀. The intracellular Ca²⁺ injection hyperpolarized the membrane in a Ca²⁺-free medium. A Ca²⁺ channel blocker, verapamil, completely abolished the Ca²⁺-dependent E_m. The Ca²⁺-dependent E_m was also suppressed by cooling or by the application of metabolic inhibitors. It is suggested that the Ca²⁺-dependent E_m in cultured human cytotrophoblast is caused by a Ca²⁺ influx which, in turn, increases the K⁺ conductance of the cell membrane, presumably due to stimulation of Ca²⁺-activated K⁺ channel.     

Effects of potassium on the anion and cation contents of primary cultures of mouse astrocytes and neurons

Inastrocytes, as [K⁺]_o was increased from 1.2 to 10 mM, [K⁺]_i and [Cl^–]_i were increased, whereas [Na⁺]_i was decreased. As [K⁺]_o was increased from 10 to 60 mM, intracellular concentration of these three ions showed no significant change. When [K⁺]_o was increased from 60 to 122 mM, an increase in [K⁺]_i and [Cl^–]_i and a decrease in [Na⁺]_i were observed.Inneurons, as [K⁺]_o was increased from 1.2 to 2.8 mM, [Na⁺]_i and [Cl^–]_i were decreased, whereas [K⁺]_i was increased. As [K⁺]_o was increased from 2.8 to 30 mM, [K⁺]_i, [Na⁺]_i and [Cl^–]_i showed no significant change. When [K⁺]_o was increased from 30 to 122 mM, [K⁺]_i and [Cl^–]_i were increased, whereas [Na⁺]_i was decreased. Inastrocytes, pH_i increased when [K⁺]_o was increased. Inneurons, there was a biphasic change in pH_i. In lower [K⁺]_o (1.2–2.8 mM) pH_i decreased as [K⁺]_o increased, whereas in higher [K⁺]_o (2.8–122 mM) pH_i was directly related to [K⁺]_o. In bothastrocytes andneurons, changes in [K⁺]_o did not affect the extracellular water content, whereas the intracellular water content increased as the [K⁺]_o increased. Transmembrane potential (E_m) as measured with Tl-204 was inversely related to [K⁺]_o between 1.2 and 90 mM, a ten-fold increase in [K⁺]_o depolarized the astrocytes by about 56 mV and the neurons about 52 mV. The E_m values measured with Tl-204 were close to the potassium equilibrium potential (E_k) except those in neurons at lower [K⁺]_o. However, they were not equal to the chloride equilibrium potential (E_Cl) at [K⁺]_o lower than 30 mM in both astrocytes and neurons. Results of this study demonstrate that alteration of [K⁺]_o produced different changes in [K⁺]_i, [Na⁺]_i, [Cl^–]_i, and pH_i in astrocytes and neurons. The data show that astrocytes can adapt to alterations in [K⁺]_o, in such a way to maintain a more suitable environment for neurons.     

Salt tolerance inNitellopsis obtusa

Summary The mechanism of salt tolerance was studied using isolated internodal cells of the charophyteNitellopsis obtusa grown in fresh water. When 100 mM NaCl was added to artificial pond water (0.1 mM each of NaCl, KC1, CaCl₂), no cell survived for more than one day. Within the first 30 minutes, membrane potential (E_m) depolarized and membrane resistance (R_m) decreased markedly. Simultaneously, cytoplasmic Na⁺ increased and K⁺ decreased greatly. At steady state the increase in Na⁺ content was roughly equal to the decrease in K⁺ content. The Cl^– content of the cytoplasm did not change. These results suggest that Na⁺ enters the cytoplasm by exchange with cytoplasmic K⁺. Both the entry of Na⁺ and the exit of K⁺ are assumed to be passive and the latter being caused by membrane depolarization. Vacuolar K⁺, Na⁺, and Cl^– remained virtually constant, suggesting that rapid influx of Na⁺ from the cytoplasm did not occur.In 100 mM NaCl containing 10 mM CaCl₂, membrane depolarization, membrane resistance decrease and changes in cytoplasmic [Na⁺] and [K⁺] did not occur, and cells survived for many days. When cells treated with 100 mM NaCl were transferred within 1 hour to 100 mM NaCl containing 10 mM CaCl₂, Em decreased, Rm increased, cytoplasmic Na⁺ and K⁺ returned to their initial levels, and cells survived. Two possible mechanisms for the role of Ca²⁺ in salt tolerance inNitellopsis are discussed; one a reduction in plasmalemma permeability to Na⁺ and the other a stimulation of active Na⁺-extrusion.     

Ultrastructural and biochemical studies of the isolated fibrillar component of nucleoli from Novikoff hepatoma ascites cells

Previously we have presented evidence for a direct relationship between post-mitotic new membrane formation and changes in the electrical membrane characteristics during cytokinesis of Xenopus eggs [1, 2]. In the present study the phenomena underlying the hyperpolarization of the electrical membrane potential during cytokinesis were investigated. Total Na⁺ and K⁺ contents at the onset of the first and second cleavage were measured independently by flame spectophotometry and by means of ion-selective electrodes. Total Cl^? content was measured by the latter method only. The water content was determined from the difference between wet weight and dry weight. ³H₂O-influx experiments yielded an independent estimate of the water content (0.737 μl/egg), a rate constant for the influx of 1.412 × 10^?3 sec,^?1 and a low water permeability of 1.87 × 10^?5 cm sec^?1. They furthermore revealed the absence of intracellular water compartmentation. The Na⁺, K⁺ and Cl^? concentrations remained constant during first cleavage at 58.6, 87.3 and 62.6 mM/l cell water, respectively. The membrane potential (E_m), the membrane resistance (R_m), and the intracellular ion activities of Na⁺, K⁺ and Cl^? (a_Naⁱ, a_Kⁱ and a_Clⁱ) were measured simultaneously and continuously during cleavage, using conventional glass microelectrodes and ion-selective microelectrodes. a_Naⁱ showed an increase from 19.4 to 22.4 mM concomitant with the hyperpolarization of E_m and the decline of R_m. a_Kⁱ and a_Clⁱ remained constant at 51.4 and 53.1 mM, respectively. From the calculated activity coefficients it was concluded that all Cl^? ions were free, whereas 30% of the K⁺ ions and 60% of the Na⁺ ions were bound. The influence of changes in the ionic composition of the medium on E_m was analysed in the uncleaved egg, in normally cleaving eggs, and in eggs cleaving outside the vitelline membrane. The latter conditions leads to exposure of the whole area of newly formed membrane to the medium. The cell membrane of the uncleaved egg exhibits no permselectivity. In normally cleaving eggs the relative permeability $\text{P}{}_{\mathrm{Na}}\text{P}{}_{\mathrm{K}}$ was 0.73, while in eggs cleaving outside the vitelline membrane it was 0.19. It was concluded that the changes of E_m during cytokinesis are due to the insertion of a part of the newly formed membrane into the cell surface. The K⁺ permeability of this new membrane is at least five times greater that that of the pre-existing membrane. The possible role of the hyperpolarization of E_m in the regulation of the cell cycle is briefly discussed.     

Fractional contribution of major ions to the membrane potential of Drosophila melanogaster oocytes

In ovarian follicles of Drosophila melanogaster, ion substitution experiments revealed that K⁺ is the greatest contributor (68%) in setting oocyte steady‐state potential (E_m), while Mg²⁺ and a metabolic component account for the rest. Because of the intense use made of Drosophila ovarian follicles in many lines of research, it is important to know how changes in the surrounding medium, particularly in major diffusible ions, may affect the physiology of the cells. The contributions made to the Drosophila oocyte membrane potential (E_m) by [Na⁺]_o, [K⁺]_o, [Mg²⁺]_o, [Ca²⁺]_o, [Cl^?]_o, and pH (protons) were determined by substitutions made to the composition of the incubation medium. Only K⁺ and Mg²⁺ were found to participate in setting the level of E_m. In follicles subjected to changes in external pH from the normal 7.3 to either pH 6 or pH 8, E_m changed rapidly by about 6 mV, but within 8 min had returned to the original E_m. Approximately half of all follicles exposed to reduced [Cl^?]_o showed no change in E_m, and these all had input resistances of 330 kΩ or greater. The remaining follicles had smaller input resistances, and these first depolarized by about 5 mV. Over several minutes, their input resistances increased and they repolarized to a value more electronegative than their value prior to reduction in [Cl^?]_o. Together, K⁺ and Mg²⁺ accounted for up to 87% of measured steady‐state potential. Treatment with sodium azide, ammonium vanadate, or chilling revealed a metabolically driven component that could account for the remaining 13%. © 2009 Wiley Periodicals, Inc.     

Energization of potassium uptake in Arabidopsis thaliana

Plant roots accumulate K⁺ from micromolar external concentrations. However, the absence of a firm determination of the trans-plasma-membrane electrochemical gradient for K⁺ in these conditions has precluded an assessment of whether K⁺-accumulation requires energization in addition to the driving force provided by the inside-negative membrane electrical potential (E_m). To address this question unequivocally, we measured E_m, and the cytosolic and external K⁺-activities in root cells of Arabidopsis thaliana (L.) Heynh. cv. Columbia in conditions in which net K⁺-accumulation occurs at low external K⁺ (10 M). In these conditions, net K⁺-uptake was about 0.1 mol · (g FW)^-1 · h^-1, E_m varied between-153 and -129 mV and the cytosolic K⁺-activity, determined with K⁺-selective electrodes, was 83 ± 4 mM. These values yield an outwardly-directed driving force on K⁺ of at least 6.5 kJ · mol^-1. Only if external potassium is raised to the region of 1 mM does E_m become sufficient to drive net K⁺-accumulation. It is therefore concluded that at micromolar external K⁺-activities which prevail in most soils, K⁺-uptake cannot be solely energized by E_m — as exemplified by a channel-mediated mechanism. The nature of the energization mechanism is discussed in relation to processes operating in fungal and algal cells.Abbreviations and Symbols AAS atomic absorption spectrometry - E_m membrane potential - electrochemical potassium gradient - F Faraday constant (96500 C · mol^-1) We thank Peter Barraclough, Roger Leigh, David Walker and Tony Miller (Rothamsted Experimental Station, Harpenden, UK) for helpful discussions. Financial support was provided by the Agricultural and Food Research Council (Grant PG87/529).     

Transmembrane potential-mediated coupling between H+ pump operation and K+ fluxes in Elodea densa leaves hyperpolarized by fusicoccin, light or acid load

In isolated Elodea densa leaves, the relationships between H⁺ extrusion (-ΔH⁺), K⁺ fluxes and membrane potential (E_m) were investigated for two different conditions of activation of the ATP-dependent H⁺ pump. The ‘basal condition’ (darkness, no pump activator present) was characterized by low values of-ΔH⁺ and K⁺ uptake (ΔK⁺), wide variability of the ?ΔH⁺/ΔK⁺ ratio, relatively low membrane polarization and E_m values more positive than EK for external K⁺ concentrations (|K⁺]_o of up to 2mol m^?3. A net K⁺ uptake was seen already at [K⁺]_o below 1 mol m^?3, suggesting that K⁺ influx in this condition was a thermodynamically uphill process involving an active mechanism. When the H⁺ pump was stimulated by fusicoccin (FC), by cytosol acidification, or by light (the ‘high polarization condition’), K⁺ influx largely dominated K⁺ and C^? efflux, and the ?ΔH⁺/ΔK⁺ ratio approached unity. In the range 50 mmol m^?3?5 mol m^?3 [K⁺]₀, E_m was consistently more negative than E_K. The curve of K⁺ influx at [K⁺]₀ ranging from 50 to 5000mmol m^?3 fitted a monophasic, hyperbolic curve, with an apparent half saturation value = 0–2 mol m^?3. Increasing |K⁺]₀ progressively depolarized E_m, counteracting the strong hyperpolarizing effect of FC. The effects of K⁺ in depolarizing E_m were well correlated with the effects on both K⁺ influx and ?ΔH⁺, suggesting a cause-effect chain: K⁺₀ influx → depolarization → activation of H⁺ extrusion. Cs⁺ competitively inhibited K⁺ influx much more strongly in the ‘high polarization’ than in the ‘basal’ condition (50% inhibition at [Cs⁺]/[K⁺]₀ ratios of 1:14 and 1:2, respectively) thus confirming the involvement of different K⁺ uptake systems in the two conditions. These results suggest that in E. densa leaves two distinct modes of interactions rule the relationships between H⁺ pump, membrane polarization and K⁺ transport. At low membrane polarization, corresponding to a low state of activation of the PM H⁺-ATP^ase and to E_m values more positive than E_K, K⁺ influx would mainly     

Characterization of glutamate transport system in hydrophobic protein (H protein) of Bacillus subtilis

Hydrophobic protein (H protein) was isolated from membrane fractions of Bacillus subtilis and constituted into artificial membrane vesicles with lipid of B. substilis. Glutamate was accumulated into the vesicle when a Na⁺ gradient across the membrane was imposed. The maximum effect of Na⁺ on the transport was achieved at a concentration of about 40 mM, while the apparent K_m for Na⁺ was approximately 8 mM. On the other hand, K_m for glutamate in the presence of 50 mM Na⁺ was about 8 μM. Increasing the concentration of Na⁺ resulted in a decrease in K_m for glutamate, maximum velocity was not affected. The transport was sensitive to monensin (Na⁺ ionophore).Glutamate was also accumulated when pH gradient (interior alkaline) across the membrane was imposed or a membrane potential was induced with K⁺-diffusion potential. The pH gradient-driven glutamate transport was sensitive to carbonylcyanide m-chlorophenylhydrazone and the apparent K_m for glutamate was approximately 25 μM.These results indicate that two kinds of glutamate transport system were present in H protein: one is Na⁺ dependent and the other is H⁺ dependent.     

Extracellular charge adsorption influences intracellular electrochemical homeostasis in amphibian skeletal muscle

The membrane potential measured by intracellular electrodes, E_m, is the sum of the transmembrane potential difference (E₁) between inner and outer cell membrane surfaces and a smaller potential difference (E₂) between a volume containing fixed charges on or near the outer membrane surface and the bulk extracellular space. This study investigates the influence of E₂ upon transmembrane ion fluxes, and hence cellular electrochemical homeostasis, using an integrative approach that combines computational and experimental methods. First, analytic equations were developed to calculate the influence of charges constrained within a three-dimensional glycocalyceal matrix enveloping the cell membrane outer surface upon local electrical potentials and ion concentrations. Electron microscopy confirmed predictions of these equations that extracellular charge adsorption influences glycocalyceal volume. Second, the novel analytic glycocalyx formulation was incorporated into the charge-difference cellular model of Fraser and Huang to simulate the influence of extracellular fixed charges upon intracellular ionic homeostasis. Experimental measurements of E_m supported the resulting predictions that an increased magnitude of extracellular fixed charge increases net transmembrane ionic leak currents, resulting in either a compensatory increase in Na⁺/K⁺-ATPase activity, or, in cells with reduced Na⁺/K⁺-ATPase activity, a partial dissipation of transmembrane ionic gradients and depolarization of E_m.     

Voltage dependent potassium fluxes and the significance of action potentials in Acetabularia

Membrane potential, V_m, and K⁺(⁸⁶Rb⁺) fluxes have been measured simultaneously on individual cells of Acetabularia mediterranea. During resting state (resting potential approx. ?170 mV) the K⁺ influx amounts to 0.24–0.6 pmol · cm^?2 · s^?1 and the K⁺ efflux to 0.2–1.5 pmol · cm^?2 s^?1. According to the K⁺ concentrations inside and outside the cell (40 : 1) the voltage dependent K⁺ flux (zero at V_m = E_K = ?90 mV) is stimulated approx. 40-fold for V_m more positive than E_K.It is calculated that during one action potential (temporary depolarization to V_m more positive than E_K) a cell looses the same amount of K⁺, which leaks in during 10–20 min in the resting state (V_m = ?170 mV). Since action potentials occur spontaneously in Acetabularia, they are therefore suggested to have a significant function for the K⁺ balance of this alga.     

Electrophysiology of phagocytic membranes: intracellular K+ activity and K+ equilibrium potential in macrophage polykaryons

The role of K⁺ as current carrier during the slow membrane hyperpolarizations (SH) elicited by iontophoretic Ca²⁺ injections into macrophage polykaryons is studied. The intracellular K⁺ activity (a_K) and the K⁺ equilibrium potential (E_K) are measured using ion-sensitive microelectrodes. The mean value of a_K is 84 ± 5 mM in a culture medium containing 5.3 mM K⁺, but increases to 100 ± 8 mM when the extracellular K⁺ concentration is raised to 30.3 mM. Under the same conditions the values of E_K obtained from the Nernst equation are −81 ± 2 mV and −40 ± 2 mV, respectively. The reversal potentials (E_R) of the SH are calculated from changes observed in transmembrane potential and input resistance, according to an equivalent model based only on passive ionic fluxes. The mean E_R values obtained are −74 ± 8 mV in the presence of low K⁺ concentration and −37 ± 3 mV for the high K⁺ medium. These values are significantly smaller than the estimated E_K for the corresponding situations. Evidence for the existence of an electrogenic (Na⁺ + K⁺)-ATPase activity is also presented. The evidence indicates that an increase in the membrane potassium permeability can account for about 90% of the total permeability change occurring during the SH.     

Potassium activation of Na+-dependent leucine transport in brush-border membrane vesicles from rat jejunum

Na⁺-dependent leucine uptake was greater in potassium loaded brush-border membrane vesicles compared with controls. This effect was not mediated by an electrical potential difference, since it was still present in voltage-clamped conditions. Inhibition experiments indicate the same Na⁺-dependent leucine transport activity in the presence or in the absence of potassium. The affinity of sodium for the cotransporter was identical at 10 or 100 mM potassium. Leucine kinetics at different potassium concentrations showed a maximum 2.4-fold increase in V_max, while K_m was unaffected. The secondary plots of the kinetic results were not linear. This kinetic behaviour suggests that K⁺ acts as a non-essential activator of Na⁺-dependent leucine cotransport. A charge compensation of sodium-leucine influx is most probably a component of the potassium effect in the presence of valinomycin.     

Resting potential of the mouse neuroblastoma cells: I. The presence of K+ channels activated at high K+ concentration but closed at low K+ concentration including the physiological concentration

The effects of changes in extracellular K⁺ concentration ([K⁺]_o) on the resting membrane potential, the input resistance and ⁸⁶Rb efflux (as a marker of K⁺ efflux) were examined with use of the cultured mouse neuroblastoma cells (N-18 clone). The results obtained are as follows. (1) The membrane potential was depolarized, with an increase in [K⁺]_o at concentrations above 10–20 mM at a rate of 55–58 mV per 10-fold change in [K⁺]_o, but practically unchanged with varying [K⁺]_o below this concentration. (2) Above the critical [K⁺]_o of 10–20 mM, the input membrane resistance decreased sharply by a factor of $\text{1}\text{4}\text{?}\text{1}\text{5}$ with an increase in [K⁺]_o. A similar decrease in the resistance occurred even under the conditions that the membrane potential was held at control level (about ?55 mV) by a steady-state current passage. (3) Elimination of Na⁺ and Cl^? from the external solution brought about practically no change in the membrane potential. (4) A fractional escape rate of ⁸⁶Rb from N-18 cells remained constant at relatively low level (0.125%/min on average) in the low [K⁺]_o range, but increased sharply with increasing [K⁺]_o above 15 mM (e.g., approx. 3.4- and 4.5-fold at 30 and 100 mM [K⁺]_o, respectively). (5) The high K⁺-induced ⁸⁶Rb efflux was not practically inhibited by 1 mM tetraethylammonium or 0.1 mM 4-aminopyridine, indicating that the K⁺ channels activated by an elevation of [K⁺]_o are not the delayed (voltage-dependent) K⁺ channels. The present results favoured the conclusion that N-18 cells carry K⁺ channels which open at high [K⁺]_o but are closed at low [K⁺]_o including the physiological range for the mouse neuroblastoma cells (around 5.4 mM). This conclusion leads to the notion that in the mouse neuroblastoma N-18 cells the K⁺ permeability does not mainly contribute to determining the resting membrane potential under physiological conditions.     

Boron induces hyperpolarization of sunflower root cell membranes and increases membrane permeability to k

Although many studies have alluded to a role for boron (B) in membrane function, there is little evidence for a direct effect of B on the plasmalemma of higher plant cells. These studies were conducted to demonstrate, by electrophysiological techniques, a direct effect of B on the membrane potential (E_m) of sunflower (Helianthus annuus [L.], cv Mammoth Grey Stripe) root tip cells and to determine if the response to B occurs rapidly enough to account for the previously observed effects of B on ion uptake. By inserting a glass microelectrode into an individual cell in the root tip, the E_m of the cell was determined in basal salt medium (BSM), pH 6.0. The perfusion solution surrounding the root tissue was then changed to BSM + 50 micromolar H₃BO₃, pH 6.0. The exposure to B induced a significant plasmalemma hyperpolarization in sunflower root cells within 20 minutes. After just 3 minutes of exposure to B, the change in E_m was already significantly different from the negligible change in E_m observed over time in root cells never exposed to B. Membrane hyperpolarization could be caused by a stimulation of the proton pump or by a change in the conductance of one or more permeable ions. Since B has been shown to affect K⁺ uptake by plants, the electrophysiological techniques described above were used to determine if B has an effect on membrane permeability to K⁺, and could thereby lead to an increased diffusion potential. When sunflower root tips were pretreated in 50 micromolar B for 2 hours, cell membranes exhibited a significantly greater depolarization with each 10-fold increase in external [K⁺] than minus-B cells. Subsequent studies demonstrated that the depolarization due to increased external [K⁺] was also significantly greater when tissue was exposed to B at the same time as the 10-fold increase in [K⁺], indicating that the effect of B on K⁺ permeability was immediate. Analysis of sunflower root tips demonstrated that treatment in 50 micromolar B caused a significantly greater accumulation of K⁺ after 48 hours. The B-induced increase in K⁺ uptake may cause a subsequent stimulation of the H⁺-ATPase (proton pump) and lead to the observed hyperpolarization of root cell membranes. Alternatively, B may stimulate the proton pump, with the subsequent hyperpolarization resulting in an increased driving force for K⁺ influx.     

Intracellular ionic compartmentation, electrical membrane properties, and cell membrane permeability before and during first cleavage in the Ambystoma egg.

The intracellular ionic distribution in uncleaved and cleaving Ambystoma eggs was investigated by analysing the influx of ³H₂O, by determining the total content of Na⁺, K⁺ and Cl^? in extracts of eggs at different stages by both flame spectrophotometry and ion-selective microelectrodes, and by the continuous measurement of the Na⁺, K⁺ and Cl^? activities (a_Naⁱ, a_Kⁱ and a_Clⁱ) using intracellular ion-selective microelectrodes. The electrical membrane potential (E_m) and membrane resistance (R_m) were measured continuously in uncleaved and normally cleaving eggs as well as in eggs cleaving after removal of the vitelline membrane. The latter eggs expose their newly formed cleavage membrane to the external medium. Ionic permeability of the cell membrane before and during cleavage was analysed by a statistical comparison of the experimentally determined relationship between E_m and the ionic gradients across the cell membrane with those predicted theoretically from a constant field equation in dependence on the relative permeability, through insertion of the measured intracellular ion activities.³H₂O influx revealed the existence of a single intracellular water compartment (3.06 μl/egg) and a low water permeability (5.35 × 10^?5 cm sec^?1). Na⁺, K⁺ and Cl^? concentrations were constant at 54.1, 72.1 and 73.1 mM respectively, while a_Naⁱ, a_Kⁱ and a_Clⁱ were constant at 5.8, 51.8 and 59.7 mM respectively. It was concluded that all Cl^? ions are in solution, while 12.5% of all K⁺ and 86% of all Na⁺ is bound. The uncleaved egg showed a positive E_m of ca 40 mV and a specific membrane resistance of 39 kOhm cm². E_m could be described by a constant field equation with a permeability ratio $\text{P}{}_{\mathrm{<mtext>K</mtext>}}\text{P}{}_{\mathrm{<mtext>Na</mtext>}}\text{= 0.073}$. Shortly after the onset of first cleavage, E_m rapidly decreased concomitant with a rise in R_m (68.5 kOhm cm²). This was interpreted as a drop in Na⁺ permeability. During the cleavage process E_m progressively hyperpolarized and R_m decreased due to the insertion of a small fraction (3.3%) of the newly formed intercellular membrane into the cleavage furrow. This new membrane had a low specific resistance (0.69 kOhm cm²). Both in normally cleaving eggs and in eggs cleaving in the absence of the vitelline membrane E_m behaved according to the constant field equation, $\text{P}{}_{\mathrm{<mtext>Na</mtext>}}\text{P}{}_{\mathrm{<mtext>K</mtext>}}$ being 0.69 and 0.39, respectively. The differences with other amphibian eggs were discussed.     

Changes in membrane properties of chick embryonic hearts during development

The electrophysiological properties of embryonic chick hearts (ventricles) change during development; the largest changes occur between days 2 and 8. Resting potential (E_m) and peak overshoot potential (+E _max) increase, respectively, from -35 mv and +11 mv at day 2 to -70 mv and +28 mv at days 12–21. Action potential duration does not change significantly. Maximum rate of rise of the action potential (+V _max) increases from about 20 v/sec at days 2–3 to 150 v/sec at days 18–21; + V _max of young cells is not greatly increased by applied hyperpolarizing current pulses. In resting E_m vs. log [K⁺]_o curves, the slope at high K⁺ is lower in young hearts (e.g. 30 mv/decade) than the 50–60 mv/decade obtained in old hearts, but the extrapolated [K⁺]_i values (125–140 mM) are almost as high. Input resistance is much higher in young hearts (13 MΩ at day 2 vs. 4.5 MΩ at days 8–21), suggesting that the membrane resistivity (R_m) is higher. The ratio of permeabilities, P _Na/P _K, is high (about 0.2) in young hearts, due to a low P _K, and decreases during ontogeny (to about 0.05). The low K⁺ conductance (g _K) in young hearts accounts for the greater incidence of hyperpolarizing afterpotentials and pacemaker potentials, the lower sensitivity (with respect to loss of excitability) to elevation of [K⁺]_o, and the higher chronaxie. Acetylcholine does not increase g _K of young or old ventricular cells. The increase in (Na⁺, K⁺)-adenosine triphosphatase (ATPase) activity during development tends to compensate for the increase in g _K. +E _max and + V _max are dependent on [Na⁺]_o in both young and old hearts. However, the Na⁺ channels in young hearts (2–4 days) are slow, tetrodotoxin (TTX)-insensitive, and activated-inactivated at lower E_m. In contrast, the Na⁺ channels of cells in older hearts (> 8 days) are fast and TTX-sensitive, but they revert back to slow channels when placed in culture.     

Contrasting roles in ion transport of two K+-channel types in root cells of Arabidopsis thaliana

Plant roots accumulate K⁺ over a range of external concentrations. Root cells have evolved at least two parallel plasma-membrane K⁺ transporters which operate at millimolar and micromolar external [K⁺]: high-affinity K⁺ uptake is energised by symport with H⁺, while low-affinity uptake is assumed to occur via ion channels. To determine the role of ion channels in low-affinity K⁺ uptake, a characterisation of the principal K⁺-selective ion channels in the plasma membrane of Arabidopsis thaliana (L.) Heynh. cv. Columbia roots was undertaken. Two classes of K⁺-selective channels were frequently observed: one inward (IRC) and one outward (ORC) rectifying with unitary conductances of 5 pS, 20 pS (IRCs) and 15 pS (ORC), measured in symmetrical 10 mM KCl. The dominant IRC (5 pS) and ORC (15 pS) were highly cation-selective (P_Cl P_K < 0.025) but less selective amongst monovalent cations (P_NaP_K0.17–0.3). Both the IRC and the ORC were blocked by Ba²⁺, Cs⁺ and tetra-ethyl-ammonium, whereas 4-aminopyridine and quinidine selectively inhibited the ORC. The ORC open probability was steeply voltage-dependent and ORC activation potentials were close to the potassium equilibrium potential (E_K+), enabling ORCs to conduct mainly outward, but occasionally inward, K⁺ current. By contrast, gating of the 5-pS IRC was weakly voltageependent and IRC gating was invariably restricted to membrane potentials more negative than E_K+, ensuring K⁺ transport was always inwardly directed. Studies on channel activity were conducted for a large number of root cells grown at two levels of external [K⁺], one where K⁺ uptake is likely to be principally through channels (6 mM K⁺) and one where it must be energised (100 M K⁺). Shifting growth conditions from high to low K⁺ did not affect single-channel properties such as conductance and selectivity, nor the manifestation of the ORC and 20-pS IRC, but led to enhanced activity of the 5-pS IRC. The enhanced activity of the 5-pS IRC was mirrored by a parallel increase in unidirectional ⁸⁶Rb⁺ influx after low-K⁺ growth, clearly indicating a dominant role of this particular channel in K⁺ uptake at supra millimolar external [K⁺].Abbreviations E_K+ potassium equilibrium potential - E_m membrane potential - HK high [K⁺] - IRC inward rectifying channel - LK low [K⁺] - ORC outward rectifying channel - TEA tetra-ethyl-ammonium Financial support was provided by the Biotechnology and Biological Sciences Research Council (Grant PG87/529) and by the European Union (Framework III, Biotechnology Programme).