ATP-sensitive inward rectifier and voltage- and calcium-activated K+ channels in cultured pancreatic islet cells

Summary K⁺ channels in cultured rat pancreatic islet cells have been studied using patch-clamp single-channel recording techniques in cell-attached and excised inside-out and outside-out membrane patches. Three different K⁺-selective channels have been found. Two inward rectifier K⁺ channels with slope conductances of about 4 and 17 pS recorded under quasi-physiological cation gradients (Na⁺ outside, K⁺ inside) and maximal conductances recorded in symmetrical K⁺-rich solutions of about 30 and 75 pS, respectively. A voltage- and calcium-activated K^– channel was recorded with a slope conductance of about 90 pS under the same conditions and a maximal conductance recorded in symmetrical K⁺-rich solutions of about 250 pS. Single-channel current recording in the cell-attached conformation revealed a continuous low level of activity in an apparently small number of both the inward rectifier K⁺ channels. But when membrane patches were excised from the intact cell a much larger number of inward rectifier K⁺ channels became transiently activated before showing an irreversible decline. In excised patches opening and closing of both the inward rectifier K⁺ channels were unaffected by voltage, internal Ca²⁺ or externally applied tetraethyl-ammonium (TEA) but the probability of opening of both inward rectifier K⁺ channels was reduced by internally applied 1–5mm adenosine-5-triphosphate (ATP). The large K⁺ channel was not operational in cell-attached membrane patches, but in excised patches it could be activated at negative membrane potentials by 10^–7 to 10^–6 m internal Ca²⁺ and blocked by 5–10mm external TEA.     

The efficiency of (Na + K)-ATPase in tumorigenic cells

The efficiency of (Na⁺ + K⁺)-ATPase (i.e. the amount of K⁺ pumped per ATP hydrolyzed) in intact tumorigenic cells was estimated in this study. This was accomplished by simultaneously measuring the rate of ouabain-sensitive K⁺ uptake and oxygen consumption in tumorigenic cell suspensions during the reintroduction of K⁺ to K⁺-depleted cells. The ATP turnover was then estimated by assuming 5.6–6 ATP/O₂ as the stoichiometry of NADH-linked respiration in these cells. In the three cell lines tested (hamster and chick embryo cells transformed with Rous sarcoma virus and Ehrlich ascites cells), the K⁺/ATP ratio was approximately 2, the same value as that found in normal tissues. Furthermore, only 20% of the total ATP production of these cells was used by (Na⁺ + K⁺)-ATPase.     

Whole-cell K+ current activation in response to voltages and carbachol in gastric parietal cells isolated from guinea pig

Summary Patch-clamp studies of whole-cell ionic currents were carried out in parietal cells obtained by collagenase digestion of the gastric fundus of the guinea pig stomach. Applications of positive command pulses induced outward currents. The conductance became progressively augmented with increasing command voltages, exhibiting an outwardly rectifying current-voltage relation. The current displayed a slow time course for activation. In contrast, inward currents were activated upon hyperpolarizing voltage applications at more negative potentials than the equilibrium potential to K⁺ (E _K). The inward currents showed time-dependent inactivation and an inwardly rectifying current-voltage relation. Tail currents elicited by voltage steps which had activated either outward or inward currents reversed at nearE _K, indicating that both time-dependent and voltagegated currents were due to K⁺ conductances. Both outward and inward K⁺ currents were suppressed by extracellular application of Ba²⁺, but little affected by quinine. Tetraethylammonium inhibited the outward current without impairing the inward current, whereas Cs⁺ blocked the inward current but not the outward current. The conductance of inward K⁺ currents, but not outward K⁺ currents, became larger with increasing extracellular K⁺ concentration. A Ca²⁺-mobilizing acid secretagogue, carbachol, and a Ca²⁺ ionophore, ionomycin, brought about activation of another type of outward K⁺ currents and voltage-independent cation currents. Both currents were abolished by cytosolic Ca²⁺ chelation. Quinine preferentially inhibited this K⁺ current. It is concluded that resting parietal cells of the guinea pig have two distinct types of voltage-dependent K⁺ channels, inward rectifier and outward rectifier, and that the cells have Ca²⁺-activated K⁺ channels which might be involved in acid secretion under stimulation by Ca²⁺-mobilizing secretagogues.     

Blockade of potassium channels in the plasmalemma ofChara corallina by tetraethylammonium,Ba2+, Na+ and Cs+

Summary The outer membranes of plant cells contain channels which are highly selective for K⁺. In the giant-celled green algaChara corallina, K⁺ currents in the plasmalemma were measured during the action potential and when the cell was depolarized to the K⁺ equilibrium potential in high external K⁺ concentrations. Currents in both conditions were reduced by externally added tetraethylammonium (TEA⁺), Ba²⁺, Na⁺ and Cs⁺. In contrast to inhibition by TEA⁺, the latter three ions inhibited inward K⁺ current in a voltage-dependent manner, and reduced inward current more than outward. Ba²⁺ and Na⁺ also appeared to inhibit outward current in a strongly voltage-dependent manner. The blockade by Cs⁺ is studied in more detail in the following paper. TEA⁺ inhibited both inward and outward currents in a largely voltage-independent manner, with an apparentK _D of about 0.7 to 1.1mm, increasing with increasing external K⁺. All inhibitors reduced current towards a similar linear leak, suggesting an insensitivity of the background leak inChara to these various K⁺ channel inhibitors. The selectivity of the channel to various monovalent cations varied depending on the method of measurement, suggesting that ion movement through the K⁺-selective channel may not be independent.     

Properties of the K+ inward rectifier in the plasma membrane of xylem parenchyma cells from barley roots: Effects of TEA+, Ca2+, Ba2+ and La3+

Xylem parenchyma cells are situated around the (apoplastic) xylem vessels and are involved in the control of the composition of the xylem sap by exporting and resorbing solutes. We investigated properties of the K⁺ inward rectifier in the plasma membrane of these cells by performing patch clamp experiments on protoplasts in the whole-cell configuration. Inward currents were sensitive to the K⁺ channel blocker TEA⁺ at a high concentration (20 mm). Barium, another classical K⁺ channel blocker, inhibited K⁺ currents with a K _i of about 1.3 mm. In contrast to guard cells, the cytosolic Ca²⁺ level proved to be ineffective in regulating the K⁺ conductance at hyperpolarization. External Ca²⁺ blocked currents weakly in a voltage-dependent manner. From instantaneous current-voltage curves, we identified a binding site in the channel pore with an electrical distance of about 0.2 to 0.5. Lanthanum ions reduced the inward current in a voltage-dependent manner and simultaneously displaced the voltage at which half of the channels are in the open state to more positive values. This finding was interpreted as resulting from a sum of two molecular effects, an interaction with the mouth of the channel that causes a reduction of current, and a binding to the voltage sensor, leading to a shielding of surface charges and, subsequently, a modulation of channel gating.A comparison between the K⁺ inward rectifier in xylem parenchyma cells, guard cells and KAT1 from Arabidopsis leads to the conclusion that these rectifiers form subtypes within one class of ion channels. The ineffectiveness of Ca²⁺ to control K⁺ influx in xylem parenchyma cells is interpreted in physiological terms.     

The voltage-dependent potassium-uptake channel of corn coleoptiles has permeation properties different from other K+ channels

The initial response of coleoptile cells to growth hormones and light is a rapid change in plasma-membrane polarization. We have isolated protoplasts from the cortex of maize (Zea mays L.) coleoptiles to study the electrical properties of their plasma membrane by the patch-clamp techniqueUsing the whole-cell configuration and cell-free membrane patches we could identify an H⁺-ATPase, hyperpolarizing the membrane potential often more negative than -150 mV, and a voltage-dependent, inward-rectifying K⁺ channel (unit conductance 5–7 pS) as the major membrane conductan-ces Potassium currents through this channel named CKC1_in (for Coleoptile K ⁺ Channel inward rectifier) were elicited upon voltage steps negative to -80 mV, characterized by a half-activation potential of -112 mV. The kinetics of activation, well described by a double-exponential process, were strongly dependent on the degree of hyperpolarization and the cytoplasmic Ca²⁺ level. Whereas at nanomolar Ca²⁺ concentrations K⁺ currents increased with a t_1/2=16 ms (at -180 mV), higher calcium levels slowed the activation process about fourto fivefoldUpon changes in the extracellular K⁺ concentration the reversal potential of the K⁺ channel followed the Nernst potential for potassium with a 56-mV shift for a tenfold increaseThe absence of a measurable conductance for Na⁺, Rb⁺, Cs⁺ and a permeability ratio P_{NH 4} ⁺ /P_K+ around 0.25 underlines the high selectivity of CKC1_in for K⁺In contrast to Cs⁺, which at submillimolar concentration blocks the channel in a voltage-dependent manner, Rb⁺, often used as a tracer for K+, does not permeate this type of K⁺ channelThe lack of Rb⁺ permeability is unique with respect to other K⁺ transporters. Therefore, future molecular analysis of CKC1_in, considered as a unique variation of plant inward rectifiers, might help to understand the permeation properties of K⁺ channels in general.Abbreviations CKC1_in Coleoptile K ⁺ Channel inward rectifier - U membrane voltage - I_ss steady-state currents - I_tail tail currents Experiments were conducted in the laboratory of F.G. during the stay of RHas a guest professor sponsored by Special Project RAISA, subproject N2.1, paper N2155.     

L-type Ca<Superscript>2+</Superscript> channel and Ca<Superscript>2+</Superscript>-permeable nonselective cation channel as a Ca<Superscript>2+</Superscript> conducting pathway in myocytes isolated from the cricket lateral oviduct

The Ca²⁺-conducting pathway of myocytes isolated from the cricket lateral oviduct was investigated by means of the whole-cell patch clamp technique. In voltage-clamp configuration, two types of whole cell inward currents were identified. One was voltage-dependent, initially activated at –40 mV and reaching a maximum at 10 mV with the use of 140 mM Cs²⁺-aspartate in the patch pipette and normal saline in the bath solution. Replacement of the external Ca²⁺ with Ba²⁺ slowed the current decay. Increasing the external Ca²⁺ or Ba²⁺ concentration increased the amplitude of the inward current and the current–voltage (I–V) relationship was shifted as expected from a screening effect on negative surface charges. The inward current could be carried by Na⁺ in the absence of extracellular Ca²⁺. Current carried by Na⁺ (I _Na) was almost completely blocked by the dihydropyridine Ca²⁺ channel antagonist, nifedipine, suggesting that the I _Na is through voltage-dependent L-type Ca²⁺ channels. The other inward current is voltage-independent and its I–V relationship was linear between –100 mV to 0 mV with a slight inward rectification at more hyperpolarizing membrane potentials when 140 mM Cs⁺-aspartate and 140 mM Na⁺-gluconate were used in the patch pipette and in the bath solution, respectively. A similar current was observed even when the external Na⁺ was replaced with an equimolar amount of K⁺ or Cs⁺, or 50 mM Ca²⁺ or Ba²⁺. When the osmolarity of the bath solution was reduced by removing mannitol from the bath solution, the inward current became larger at negative potentials. The I–V relationship for the current evoked by the hypotonic solution also showed a linear relationship between –100 mV to 0 mV. Bath application of Gd³⁺ (10 M) decreased the inward current activated by membrane hyperpolarization. These results clearly indicate that the majority of current activated by a membrane hyperpolarization is through a stretch-activated Ca²⁺-permeable nonselective cation channel (NSCC). Here, for the first time, we have identified voltage-dependent L-type Ca²⁺ channel and stretch-activated Ca²⁺-permeable NSCCs from enzymatically isolated muscle cells of the cricket using the whole-cell patch clamp recording technique.Abbreviations I _Ca Ca²⁺ current - I _Na Na⁺ current - I–V current–voltage - NSCC nonselective cation channel Communicated by G. Heldmaier     

Modification of voltage-sensitive inactivation of Na+ current by external Ca2+ in the marine dinoflagellateNoctiluca miliaris

Effects of the external Ca²⁺ concentration on the depolarization-induced transient inward Na⁺ current responsible for the Na⁺ spike in the dinoflagellate Noctiluca miliaris were examined. The peak value and the duration of the Na⁺ current increased when lowering the external Ca²⁺ concentration. The threshold potential level for activation and the reversal potential level of the current were not affected by the external Ca²⁺ concentration. The inactivation took place even in a solution containing EGTA with very low (<10^–9 M) Ca²⁺ concentration. Voltage dependency of the inactivation was scarcely affected by the external Ca²⁺ concentration. It is concluded that inactivation of Na⁺ channels responsible for the current is dependent on membrane depolarization and that the external Ca²⁺ modulates the inactivation kinetics. Appearance of a Na⁺ spike in a solution with reduced Ca²⁺ concentration is caused by a lowered rate of inactivation of the Na⁺ channels.     

Ca2+-activated K+ conductance of the human red cell membrane: Voltage-dependent Na+ block of outward-going currents

Summary Human red cells were prepared with various cellular Na⁺ and K⁺ concentrations at a constant sum of 156mm. At maximal activation of the K⁺ conductance,g _K(Ca), the net efflux of K⁺ was determined as a function of the cellular Na⁺ and K⁺ concentrations and the membrane potential,V _m , at a fixed [K⁺]_ex of 3.5mm.V _m was only varied from (V _m –E _K)25 mV and upwards, that is, outside the range of potentials with a steep inward rectifying voltage dependence (Stampe & Vestergaard-Bogind, 1988).g _K(Ca) as a function of cellular Na⁺ and K⁺ concentrations atV _m =–40, 0 and 40 mV indicated a competitive, voltage-dependent block of the outward current conductance by cellular Na⁺. Since the present Ca²⁺-activated K⁺ channels have been shown to be of the multi-ion type, the experimental data from each set of Na⁺ and K⁺ concentrations were fitted separately to a Boltzmann-type equation, assuming that the outward current conductance in the absence of cellular Na⁺ is independent of voltage. The equivalent valence determined in this way was a function of the cellular Na⁺ concentration increasing from 0.5 to 1.5 as this concentration increased from 11 to 101mm. Data from a previous study of voltage dependence as a function of the degree of Ca²⁺ activation of the channel could be accounted for in this way as well. It is therefore suggested that the voltage dependence ofg _K(Ca) for outward currents at (V _m –E _K)>25 25 mV reflects a voltage-dependent Na⁺ block of the Ca²⁺-activated K⁺ channels.     

Genetic Na channelopathies and sinus node dysfunction

Voltage-gated Na⁺ channels are transmembrane proteins that produce the fast inward Na⁺ current responsible for the depolarization phase of the cardiac action potential. They play fundamental roles in the initiation, propagation, and maintenance of normal cardiac rhythm. Inherited mutations in SCN5A, the gene encoding the pore-forming α-subunit of the cardiac-type Na⁺ channel, result in a spectrum of disease entities termed Na⁺ channelopathies. These include multiple arrhythmic syndromes, such as the long QT syndrome type 3 (LQT3), Brugada syndrome (BrS), an inherited cardiac conduction defect (CCD), sudden infant death syndrome (SIDS) and sick sinus syndrome (SSS). To date, mutational analyses have revealed more than 200 distinct mutations in SCN5A, of which at least 20 mutations are associated with sinus node dysfunction including SSS. This review summarizes recent findings bearing upon: (i) the functional role of distinct voltage-gated Na⁺ currents in sino-atrial node pacemaker function; (ii) genetic Na⁺ channelopathy and its relationship to sinus node dysfunction.     

Voltage-dependent Conductance Changes in a Nonvoltage-activated Sodium Current from a Mast Cell Line

Nonexcitable cells do not express voltage-activated Na⁺ channels. Instead, selective Na⁺ influx is accomplished through GTP-activated Na⁺ channels, the best characterized of which are found in renal epithelia. We have described recently a GTP-dependent Na⁺ current in rat basophilic leukemia (RBL) cells that differs from previous reported Na⁺ channels in several ways including selectivity, pharmacology and mechanism of activation. In this report, we have investigated the biophysical properties of the RBL cell Na⁺ current using the whole cell patch-clamp technique. Following activation by 250–500 μm GTPγS, hyperpolarizing steps to a fixed potential (−100 mV) from a holding potential of 0 mV evoked transient inward Na⁺ currents that declined during the pulse. If the holding potential was made more positive (range 0 to +100 mV), then the amplitude of the transient inward current evoked by the hyperpolarization increased steeply, demonstrating that the conductance of the channels was voltage-dependent. Using a paired pulse protocol (500 msec pulses to −100 mV from a holding potential of 0 mV), it was found that the peak amplitude of the current during the second pulse became larger as the interpulse potential became more positive. In addition, increasing the time at which the cells were held at positive potentials also resulted in larger currents, indicating a time-dependent conductance change. With symmetrical Na⁺ solutions, outward currents were recorded at positive potentials and these demonstrated both a time- and voltage-dependent increase in conductance. The results show that a nonvoltage activated Na⁺ channel in an electrically nonexcitable cell undergoes prominent voltage-dependent transitions. Possible mechanisms underlying this voltage dependency are discussed. Received: 12 March 1998/Revised: 5 June 1998     

Analysis and use of the perforated patch technique for recording ionic currents in pancreaticβ-cells

Summary To investigate the voltage dependence of the Na^–/K^– pump, current-voltage relations were determined in prophasearrested oocytes ofXenopus laevis. All solutions contained 5mm Ba^2– and 20mm tetraethylammonium (TEA) to block K^– channels. If. in addition, the Na⁺/K⁺ pump is blocked by ouabain, K⁺-sensitive currents no larger than 50 nA/cm² remain. Reductions in steady-state current (on the order of 700 nA/cm²) produced by 50 m ouabain or dihydro-ouabain or by K⁺ removal, therefore, primarily represent current generated by the Na^–/K^– pump. In Na^–-free solution containing 5mm K⁺, Na⁺/K⁺ pump current is relatively voltage independent over the potential range from –160 to +40 mV. If external [K⁺] is reduced below 0.5mm, negative slopes are observed over this entire voltage range. Similar results are seen in Na⁺- and Ca²⁺-free solutions in the presence of 2mm Ni²⁺, an experimental condition designed to prevent Na⁺/Ca²⁺ exchange. The occurrence of a negative slope can be explained by the voltage dependence of the apparent affinity for activation of the Na⁺/K⁺ pump by external K⁺, consistent with the existence of an external ion well for K^– binding. In 90mm Na⁺, 5mm K⁺ solution, Na⁺/K⁺ pump current-voltage curves at negative membrane potentials have a positive slope and can be described by a monotonically increasing sigmoidal function. At an extracellular [K⁺] of 1.3mm, a negative slope was observed at positive potentials. These findings suggest that in addition to a voltage-dependent step associated with Na⁺ translocation, a second voltage-dependent step that is dependent on external [K⁺], possibly external K⁺ binding, participates in the overall reaction mechanism of the Na⁺/K⁺ pump.     

K outward rectifying channels as targets of phosphatase inhibitor deltamethrin inVicia faba guard cells

The dominant outward rectifier K⁺ currents were examined in protoplasts from Vicia faba guard cells. In whole-cell patch-clamp recordings, we generally observed that the conductance of the K⁺ inward and the outward rectifier gradually decreases with a half time in the order of 2.3 ± 0.7 min. As a consequence of this rundown, a new steady state was achieved which was 90 ± 5 percnt; lower than that obtained at the beginning of the recording. The rundown of the outward rectifier could be greatly reduced by pre-treating protoplasts either with the membrane permeable drug deltamethrin or by perfusing protoplasts with a pipette solution containing 5 μmol/L cyclosporine A. Furthermore, after the rundown, the conductance of the outward rectifier could be partially restored upon addition of 5 μmol/L deltamethrin to the bath medium. Since deltamethrin and cyclosporine A are established inhibitors of the calcium sensitive phosphatase calcineurin, the data argue for a participation of this type of phosphatase in the control of the activity of K⁺ outward rectifier channels in guard cells.     

Fast Na+ channels and slow Ca2+ current in smooth muscle from pregnant rat uterus

Summary Smooth muscle cells normally do not possess fast Na²⁺ channels, but inward current is carried through two types of Ca²⁺ channels: slow (L-type) Ca²⁺ channels and fast (T-type) Ca²⁺ channels. Using whole-cell voltage clamp of single smooth muscle cells isolated from the longitudinal layer of 18-day pregnant rat uterus, depolarizing pusles, applied from a holding potential of –90 mV, evoked two types of inward current, fast and slow [8]. The fast inward current decayed within 30 ms, depended on [Na]₀, and was inhibited by TTX (K_0.5 = 27 nM). The slow inward current decayed slowly, was dependent on [Ca]₀, and was inhibited by nifedipine. These results suggest that the fast inward current is a fast Na²⁺ channel current, and that the slow inward current is a Ca²⁺ channel current was not evident. Thus, the ion channels which generate inward currents in pregnant rat uterine cells are TTX-sensitive fast Na⁺ channels and dihudropuridine-sensitive slow Ca²⁺ channels. The number of fast Na⁺ channels increased during gestation [9]. The averaged current density increased from 0 on day 5, to 0.19 on day 9, to 0.56 on day 14, to 0.90 on day 18, and to 0.86 pA/pF on day 21. This almost linear increase occurs because of an increase in the fraction of cells which possess fast Na²⁺ channels, and it suggested that the fast Na⁺ current may be involved in spread of excitation. The Ca²⁺ channel current density also was higher during the latter half of gestation. These results indicate that the fast Na⁺ channels and Ca²⁺ slow channels in myometrium become more numerous as term approaches, and may facilitate parturition. Isoproterenol (beta-agonist) did not affect either I_Ca(s) or I_Na(f), whereas Mg²⁺ (K_0.5 of 12 mM) and nifedipine (K_0.5 of 3.3 nM) depressed I_Ca(s). Oxytocin had no effect on I_Na(f) and actually depressed I_Ca(s) to a small extect. Therefore, the tocolytic action of beta-agonists cannot be explained by an inhibition of I_Ca(s), whereas that of Mg²⁺ can be so explained. The stimulating action of oxytocin on uterine contractions is not due to stimulation of I_Ca(s).     

In vivo tumorigenicity and in vitro sensitivity to tumor-necrosis-factorα mediated killing of c-Ha-ras-transformed cells

Summary Cellular subclones of high and low tumorigenicity obtained from a mouse c-Ha-ras-transformed clone, were examined for their sensitivity to tumornecrosis-factor (TNF)-mediated cytotoxicity. Cells of the highly tumorigenic subclones showed a significantly enhanced resistance to the cytotoxic effect of TNF plus cyclohexamide (CHI) as compared to cells of the lowtumorigenic subclones. The enhanced resistance to TNF+CHI was not due to a lower expression of TNF receptors on the cells. The c-Ha-ras-transfected cells were transformed and maintained in culture only (C cells). In vivo passage of cells of the initially low-tumorigenic c-Ha-ras subclones through the mouse significantly enhanced the tumorigenic potential of these CTC cells (culture/tumor/culture). In correlation with their enhanced tumorigenicity, the CTC cells were highly resistant to TNF-mediated cytotoxicity as compared to C cells of the same subclone. Furthermore, the involvement of TNF in determining the tumorigenic phenotype of the c-Ha-ras-transformed cells was demonstrated in a more direct manner. Cells of a c-Ha-ras-transformed low-tumorigenic, highly TNF-sensitive subclone were selected by repeated cycles of in vitro exposure to TNF. As a result, a stable, highly TNF-resistant population of cells emerged. These TNF-resistant cells caused more tumors in mice as compared to their original TNF-sensitive cells. These results show that the resistance to the cytotoxic effect of TNF plus cyclohexamide may be involved, at least partially, in the tumorigenic potential of c-Ha-ras-transformed cells and suggest a possible role for TNF in the enhancement of the tumorigenic potential of these cells in mice.     

Evidence for coupling between Na+ pump activity and TEA-sensitive K+ currents in Xenopus laevis oocytes

Using the two-microelectrode voltage clamp technique in Xenopus laevis oocytes, we estimated Na⁺-K⁺-ATPase activity from the dihydroouabain-sensitive current (I _DHO) in the presence of increasing concentrations of tetraethylammonium (TEA⁺; 0, 5, 10, 20, 40 mm), a well-known blocker of K⁺ channels. The effects of TEA⁺ on the total oocyte currents could be separated into two distinct parts: generation of a nonsaturating inward current increasing with negative membrane potentials (V _M) and a saturable inhibitory component affecting an outward current easily detectable at positive V _M. The nonsaturating component appears to be a barium-sensitive electrodiffusion of TEA⁺ which can be described by the Goldman-Hodgkin-Katz equation, while the saturating component is consistent with the expected blocking effect of TEA⁺ on K⁺ channels. Interestingly, this latter component disappears when the Na⁺-K⁺-ATPase is inhibited by 10 m DHO. Conversely, TEA⁺ inhibits a component of I _DHO with a k _d of 25±4 mm at +50 mV. As the TEA⁺-sensitive current present in I _DHO reversed at –75 mV, we hypothesized that it could come from an inhibition of K⁺ channels whose activity varies in parallel with the Na⁺-K⁺-ATPase activity. Supporting this hypothesis, the inward portion of this TEA⁺-sensitive current can be completely abolished by the addition of 1 mm Ba²⁺ to the bath. This study suggests that, in X. laevis oocytes, a close link exists between the Na-K-ATPase activity and TEA⁺-sensitive K⁺ currents and indicates that, in the absence of effective K⁺ channel inhibitors, I _DHO does not exclusively represent the Na⁺-K⁺-ATPase-generated current.     

In vivo modification of Na,K-ATPase activity in Drosophila

We have constructed and characterized transgenic Drosophila lines with modified Na⁺,K⁺-ATPase activity. Using a temperature dependent promoter from the hsp70 gene to drive expression of wild-type α subunit cDNA, we can conditionally rescue bang-sensitive paralysis and ouabain sensitivity of a Drosophila Na⁺,K⁺-ATPase α subunit hypomorphic mutant, 2206. In contrast, a mutant α subunit (α^D369N) leads to increased bang-sensitive paralysis and ouabain sensitivity. We can also generate temperature dependent phenotypes in wild-type Drosophila using the same hsp70 controlled α transgenes. Ouabain sensitivity was as expected, however, both bang sensitive paralysis or locomotor phenotypes became more severe regardless of the type of α subunit transgene. Using the Gal4-UAS system we have limited expression of α transgenes to cell types that normally express a particular Drosophila Na⁺,K⁺-ATPase β (Nervana) subunit isoform (Nrv1 or 2). The Nrv1-Gal4 driver results in lethality while the Nrv2-Gal4 driver shows reduced viability, locomotor function and uncontrolled wing beating. These transgenic lines will be useful for disrupting function in a broad range of cell types.     

Role of calcium in the modulation of Vicia guard cell potassium channels by abscisic acid: A patch-clamp study

There is evidence for a role of increased cytoplasmic Ca²⁺ in the stomatal closure induced by abscisic acid (ABA), but two points of controversy remain the subject of vigorous debate—the universality of Ca²⁺ as a component of the signaling chain, and the source of the increased Ca²⁺, whether influx across the plasmalemma, or release from internal stores. We have addressed these questions by patch-clamp studies on guard cell protoplasts of Vicia faba, assessing the effects of ABA in the presence and absence of external Ca²⁺, and of internal Ca²⁺ buffers to control levels of cytoplasmic Ca²⁺. We show that ABA-induced reduction of the K⁺ inward rectifier can occur in the absence of external Ca²⁺, but is abolished when Ca²⁺ buffers are present inside the cell. Thus, some minimum level of cytoplasmic Ca²⁺ is a necessary component of the signaling chain by which ABA decreases the K⁺ inward rectifier in stomatal guard cells, thus preventing stomatal opening. Release of Ca²⁺ from internal stores is capable of mediating the response, in the absence of any Ca²⁺ influx from the extracellular medium. The work also shows that enhancement of the K⁺ outward rectifier by ABA is Ca²⁺ independent, and that other signaling mechanisms must be involved. A role for internal pH, as suggested by H.R. Irving, C.A. Gehring and R.W. Parish (Proc. Natl. Acad. Sci. USA 89:1790–1794, 1990) and M.R. Blatt (J. Gen. Physiol. 99:615–644, 1992), is an attractive working hypothesis.     

Regulating role of acetylcholine and its antagonists in inward rectified K+ channels from guard cell protoplasts ofVicia faba

The inward rectified potassium current ofVicia faba guard cell protoplasts treated with acetylcholine (ACh) or the antagonists of its receptors were recorded by employing the patch clamp technique. The results show that ACh at lower concentrations increases the inward K⁺ current, in contrast, ACh at higher concentrations inhibits it. Treated with d-Tubocurarine (d-Tub), an antagonist of the nicotine ACh receptor (nAChR) inhibits the inward K⁺ current by 30%. Treated with atropine (Atr), an antagonist of the muscarine (Mus) ACh receptor (mAChR) also inhibits it by 36%. However, if guard cell protoplasts are treated with d-Tub and Atr together, the inward K⁺ current is inhibited by 60% –75%. Tetraethylammonium chloride (TEA), a strong inhibitor of K⁺ channels has no effect on the inward K⁺ current regulated by ACh, suggesting that there are inward K⁺ channels modulated by AChRs on the membrane of the guard cell protoplasts. These data demonstrate an ACh-regulated mechanism for stomatal movement.     

Functional analysis of amino acids of the Na+/H+ exchanger that are important for proton translocation

The Na⁺/H⁺ exchanger is an integral membrane protein found in the plasma membrane of eukaryotic and prokaryotic cells. In eukaryotes it functions to exchange one proton for a sodium ion. In mammals it removes intracellular protons while in plants and fungal cells the plasma membrane form removes intracellular sodium in exchange for extracellular protons. In this study we used the Na⁺/H⁺ exchanger of Schizosaccharomyces pombe (Sod2) as a model system to study amino acids critical for activity of the protein. Twelve mutant forms of the Na⁺/H⁺ exchanger were examined for their ability to translocate protons as assessed by a cytosensor microphysiometer. Mutation of the amino acid Histidine 367 resulted in defective proton translocation. The acidic residues Asp145, Asp178, Asp266 and Asp267 were important in the proton translocation activity of the Na⁺/H⁺ exchanger. Mutation of amino acids His98, His233 and Asp241 did not significantly impair proton translocation by the Na⁺/H⁺ exchanger. These results confirm that polar amino acids are important in proton flux activity of Na⁺/H⁺ exchangers.