(Na + K)-ATPase activity of crude homogenates of rat skeletal muscle as estimated from their K-dependent 3-O-methylfluorescein phosphatase activity

A highly sensitive fluorimetric assay using 3-O-methylfluorescein phosphate as substrate was used in the determination of K⁺-dependent phosphatase activity in preparations of rat skeletal muscle. The gastrocnemius muscle was chosen because of mixed fibre composition. Crude, detergent treated homogenate was used so as to avoid loss of activity during purification. K⁺-dependent phosphatase activities in the range 0.19–0.37 μmol · (g wet weight)⁻¹ · min⁻¹ were obtained, the value decreasing with age and K⁺-deficiency. Complete inhibition of the K⁺-dependent phosphatase was obtained with 10⁻³ M ouabain. Using a KSCN-extracted muscle enzyme the intimate relation between K⁺-dependent phosphatase activity and (Na⁺ + K⁺)-activated ATP hydrolysis could be demonstrated. A molecular activity of 620 min⁻¹ was estimated from simultaneous determination of K⁺-dependent phosphatase activity and [³H]ouabain binding capacity using the partially purified enzyme preparation. The corresponding enzyme concentration in the crude homogenates was calculated and corresponded well with the number of [³H]ouabain binding sites measured in intact muscles or biopsies hereof.     

Gill (Na+,K+)-ATPase from the blue crab Callinectes danae: modulation of K+-phosphatase activity by potassium and ammonium ions

The kinetic properties of a microsomal gill (Na⁺,K⁺)-ATPase from the blue crab Callinectes danae were analyzed using the substrate p-nitrophenylphosphate. The (Na⁺,K⁺)-ATPase hydrolyzed PNPP obeying cooperative kinetics (n=1.5) at a rate of V=125.4±7.5 U mg⁻¹ with K_0.5=1.2±0.1 mmol l⁻¹; stimulation by potassium (V=121.0±6.1 U mg⁻¹; K_0.5=2.1±0.1 mmol l⁻¹) and magnesium ions (V=125.3±6.3 U mg⁻¹; K_0.5=1.0±0.1 mmol l⁻¹) was cooperative. Ammonium ions also stimulated the enzyme through site–site interactions (n_H=2.7) to a rate of V=126.1±4.8 U mg⁻¹ with K_0.5=13.7±0.5 mmol l⁻¹. However, K⁺-phosphatase activity was not stimulated further by K⁺ plus NH₄⁺ ions. Sodium ions (K_I=36.7±1.7 mmol l⁻¹), ouabain (K_I=830.3±42.5 μmol l⁻¹) and orthovanadate (K_I=34.0±1.4 nmol l⁻¹) completely inhibited K⁺-phosphatase activity. The competitive inhibition by ATP (K_I=57.2±2.6 μmol l⁻¹) of PNPPase activity suggests that both substrates are hydrolyzed at the same site on the enzyme. These data reveal that the K⁺-phosphatase activity corresponds strictly to a (Na⁺,K⁺)-ATPase in C. danae gill tissue. This is the first known kinetic characterization of K⁺-phosphatase activity in the portunid crab C. danae and should provide a useful tool for comparative studies.     

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.     

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.     

Pump and K+ inward rectifiers in the plasmalemma of wheat root protoplasts

An electrogenic pump, a slowly activating K⁺ inward rectifier and an intermittent, spiky, K⁺ inward rectifier, have been identified in the plasmalemma of whole protoplasts from root cortical cells of wheat (Triticum) by the use of patch clamping techniques. Even with high external concentrations of K⁺ of 100 m m, the pump can maintain the membrane potential difference (PD) down to –180 mV, more negative than the electrochemical equilibrium potentials of the various ions in the system. The slowly activating K⁺ inward rectifier, apparent in about 23% of protoplasts, allows inward current flow when the membrane PD becomes more negative than the electrochemical equilibrium potential for K⁺ by about 50 mV. The current usually consists of two exponentially rising components, the time constant of one about 10 times greater than the other. The longer time constant is voltage dependent, while the smaller time constant shows little voltage dependence. The rectifier deactivates, on return of the PD to less negative levels, with a single exponential time course, whose time constant is strongly voltage dependent. The spiky K⁺ inward rectifier, present in about 68% of protoplasts, allows intermittent current, of considerable magnitude, through the plasmalemma at PDs usually more negative than about –140 mV. Patch clamp experiments on detached outside-out patches show that a possibly multi-state K⁺ channel, with maximum conductance greater than 400 pS, may constitute this rectifier. The paper also considers the role of the pump and the K⁺ inward rectifiers in physiological processes in the cell.We thank Don Mackenzie and Kay Morris for their valuable technical assistance, particularly in the preparation of protoplasts. The project is funded by the Australian Research Council.     

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.     

The k/na selectivity of a cation channel in the plasma membrane of root cells does not differ in salt-tolerant and salt-sensitive wheat species

The characteristics of cation outward rectifier channels were studied in protoplasts from wheat root (Triticum aestivum L. and Triticum turgidum L.) cells using the patch clamp technique. The cation outward rectifier channels were voltage-dependent with a single channel conductance of 32 ± 1 picosiemens in 100 millimolar KCl. Whole-cell currents were dominated by the activity of the cation outward rectifiers. The time- and voltage-dependence of these currents was accounted for by the summed behavior of individual channels recorded from outside-out detached patches. The K⁺/Na⁺ permeability ratio of these channels was measured in a salt-sensitive and salt-tolerant genotype of wheat that differ in rates of Na⁺ accumulation, using a voltage ramp protocol on protoplasts in the whole-cell configuration. Permeability ratios were calculated from shifts in reversal potentials following ion substitutions. There were no significant differences in the K⁺/Na⁺ permeability ratios of these channels in root cells from either of the two genotypes tested. The permeability ratio for K⁺/Cl⁻ was greater than 50:1. The K⁺/Na⁺ permeability ratio averaged 30:1, which is two to four times more selective than the same type of channel in guard cells and suspension culture cells. Lowering the Ca²⁺ concentration in the bath solution to 0.1 millimolar in the presence of 100 millimolar Na⁺ had no significant effect on the K⁺/Na⁺ permeability ratios of the channel. It seems unlikely that the mechanism of salt tolerance in wheat is based on differences in the K⁺/Na⁺ selectivity of these channels.     

Calcium-sensitivity of the plasmalemmal delayed rectifier potassium current suggests that calcium influx in pulvinar protoplasts from Mimosa pudica L. can be revealed by hyperpolarization

Isolated protoplasts from pulvinar motor cells of Mimosa pudica were studied using conventional whole-cell patch clamp techniques. With internal solutions weakly buffered for Ca²⁺ (0.2 mm EGTA), a run-down of the outward delayed rectifier K⁺ current was induced by hyperpolarizing the holding potential, and this effect was strongly promoted by high external Ca²⁺ concentrations. This rundown could be reversed by coming back to less hyperpolarized holding potentials or by lowering the external [Ca²⁺]. Such rundown was absent when pipette internal solutions strongly buffered (10 mm EGTA) for Ca²⁺ were used. Ionomycin induced run-down of the K⁺ current with internal solutions containing 0.2 mm but not 10 mm EGTA. The hyperpolarization-associated rundown was reversibly blocked by Gd³⁺ and La³⁺.We thank Christophe Untereiner and Denis Wagner for expert technical assistance in facilitating the experiments and data acquisition and analysis.     

Long-term exposure of the freshwater shrimp Macrobrachium olfersii to elevated salinity: Effects on gill (Na,K)-ATPase α-subunit expression and K-phosphatase activity

The kinetic properties of a microsomal gill (Na⁺,K⁺)-ATPase from the freshwater shrimp, Macrobrachium olfersii, acclimated to 21‰ salinity for 10 days were investigated using the substrate p-nitrophenylphosphate. The enzyme hydrolyzed this substrate obeying cooperative kinetics at a rate of 123.6 ± 4.9 U mg^− 1 and K_0.5 = 1.31 ± 0.05 mmol L^− 1. Stimulation of K⁺-phosphatase activity by magnesium (V_max = 125.3 ± 7.5 U mg^− 1; K_0.5 = 2.09 ± 0.06 mmol L^− 1), potassium (V_max = 134.2 ± 6.7 U mg^− 1; K_0.5 = 1.33 ± 0.06 mmol L^− 1) and ammonium ions (V_max = 130.1 ± 5.9 U mg^− 1; K_0.5 = 11.4 ± 0.5 mmol L^− 1) was also cooperative. While orthovanadate abolished p-nitrophenylphosphatase activity, ouabain inhibition reached 80% (K_I = 304.9 ± 18.3 μmol L^− 1). The kinetic parameters estimated differ significantly from those for freshwater-acclimated shrimps, suggesting expression of different isoenzymes during salinity adaptation. Despite the ≈2-fold reduction in K⁺-phosphatase specific activity, Western blotting analysis revealed similar α-subunit expression in gill tissue from shrimps acclimated to 21‰ salinity or fresh water, although expression of phosphate-hydrolyzing enzymes other than (Na⁺,K⁺)-ATPase was stimulated by high salinity acclimation.     

Phosphorylation Regulates an Inwardly Rectifying ATP-sensitive K<Superscript><Emphasis Type="Bold">+</Emphasis></Superscript>- Conductance in Proximal Tubule Cells of Frog Kidney

K⁺ channels in the renal proximal tubule play an important role in salt reabsorption. Cells of the frog proximal tubule demonstrate an inwardly rectifying, ATP-sensitive K⁺ conductance that is inhibited by Ba²⁺, G_Ba. In this paper we have investigated the importance of phosphorylation state on the activity of G_Ba in whole-cell patches. In the absence of ATP, G_Ba decreased over time; this fall in G_Ba involved phosphorylation, as rundown was inhibited by alkaline phosphatase and was accelerated by the phosphatase inhibitor F⁻(10 mM). Activation of PKC using the phorbol ester PMA accelerated rundown via a mechanism that was dependent on phosphorylation. In contrast, the inactive phorbol ester PDC slowed rundown. Inclusion of the PKC inhibitor PKC-ps in the pipette inhibited rundown. These data indicate that PKC-mediated phosphorylation promotes channel rundown. Rundown was prevented by the inclusion of PIP-2 in the pipette. PIP-2 also abrogated the PMA-mediated increase in rundown, suggesting that regulation of G_Ba by PIP-2 occurred downstream of PKC-mediated phosphorylation. G-protein activation inhibited G_Ba, with initial currents markedly reduced in the presence of GTPγs. These properties are consistent with G_Ba being a member of the ATP-sensitive K⁺ channel family.     

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.     

Channel-mediated K+ flux in barley aleurone protoplasts

Gibberellic acid (GA₃) stimulates K⁺ efflux from the barley (Hordeum vulgare L. cv. Himalaya) aleurone. We investigated the mechanism of K⁺ flux across the plasma membrane of aleurone protoplasts using patch-clamp techniques. Potassium-ion currents, measured over the entire surface of the protoplast plasma membrane, were induced when the electrochemical gradient for K⁺ was inward (into the cytoplasm). The magnitude and voltage-dependence of this inward current were the same in protoplasts treated with GA₃ and in control protoplasts (no GA₃). Inward currents activated by negative shifts in the membrane potential (E_M) from the Nernst potential for K⁺ (E_K) showed membrane conductance to be a function of the electrochemical gradient (i.e. E_M-E_K). Single-channel influx currents of K⁺ were recorded in small patches of the plasma membrane. These channels had a single-channel conductance of 5–10 pS with 100 mM K⁺ on the inside and 10 mM K⁺ on the outside of the plasma membrane. Single-channel currents, like whole-cell currents, were the same in protoplasts treated with GA₃ and control protoplasts. Voltage-gated efflux currents were found only in protoplasts tha thad been incubated without GA₃. We conclude that K⁺ influx in the aleurone is mediated by channels and these membrane proteins are not greatly effected by GA₃.Abbreviations and symbols F_K Nernst potential for K⁺ - E_M membrane potential - E_rev reversal potential - GA₃ gibberellic acid - K_i concentration of K⁺ inside the cell - K_o concentration of K⁺ outside the cell - R gas constant - S conductance (siemens) - T temperature (^oK) - _i ionic activity coefficient for internal (cytoplasmic) solution - _o ionic activity coefficient for external medium     

Voltage-dependent K channels in protoplasts of trap-lobe cells ofDionaea muscipula

Summary The outward rectification of the K⁺ current in mesophyll cell protoplasts from trap-lobes ofDionaea muscipula was studied with the patch-clamp technique. The rectification had instantaneous and time-dependent components. Changes in [K⁺] _i strongly affected the conductance voltage relation of the plasma membrane while changes in [K⁺] _o had little effect on the relation. Thus, the outward rectification depends on the membrane voltage and the concentration of intracellular K⁺. Corresponding single-channel activities were observed both in the intact membrane (cell-attached recording) and in excised patches. The single-channel conductance was about 3.3 pS with symmetrical solutions containing 30mm K⁺.     

Electrophysiological Characterization of the Rat Epithelial Na+ Channel (rENaC) Expressed in MDCK Cells : Effects of Na+ and Ca2+

The epithelial Na⁺ channel (ENaC), composed of three subunits (α, β, and γ), is expressed in several epithelia and plays a critical role in salt and water balance and in the regulation of blood pressure. Little is known, however, about the electrophysiological properties of this cloned channel when expressed in epithelial cells. Using whole-cell and single channel current recording techniques, we have now characterized the rat αβγENaC (rENaC) stably transfected and expressed in Madin-Darby canine kidney (MDCK) cells. Under whole-cell patch-clamp configuration, the αβγrENaC-expressing MDCK cells exhibited greater whole cell Na⁺ current at −143 mV (−1,466.2 ± 297.5 pA) than did untransfected cells (−47.6 ± 10.7 pA). This conductance was completely and reversibly inhibited by 10 μM amiloride, with a Ki of 20 nM at a membrane potential of −103 mV; the amiloride inhibition was slightly voltage dependent. Amiloride-sensitive whole-cell current of MDCK cells expressing αβ or αγ subunits alone was −115.2 ± 41.4 pA and −52.1 ± 24.5 pA at −143 mV, respectively, similar to the whole-cell Na⁺ current of untransfected cells. Relaxation analysis of the amiloride-sensitive current after voltage steps suggested that the channels were activated by membrane hyperpolarization. Ion selectivity sequence of the Na⁺ conductance was Li⁺ > Na⁺ >> K⁺ = N-methyl-d-glucamine⁺ (NMDG⁺). Using excised outside-out patches, amiloride-sensitive single channel conductance, likely responsible for the macroscopic Na⁺ channel current, was found to be ∼5 and 8 pS when Na⁺ and Li⁺ were used as a charge carrier, respectively. K⁺ conductance through the channel was undetectable. The channel activity, defined as a product of the number of active channel (n) and open probability (P _o), was increased by membrane hyperpolarization. Both whole-cell Na⁺ current and conductance were saturated with increased extracellular Na⁺ concentrations, which likely resulted from saturation of the single channel conductance. The channel activity (nP _o) was significantly decreased when cytosolic Na⁺ concentration was increased from 0 to 50 mM in inside-out patches. Whole-cell Na⁺ conductance (with Li⁺ as a charge carrier) was inhibited by the addition of ionomycin (1 μM) and Ca²⁺ (1 mM) to the bath. Dialysis of the cells with a pipette solution containing 1 μM Ca²⁺ caused a biphasic inhibition, with time constants of 1.7 ± 0.3 min (n = 3) and 128.4 ± 33.4 min (n = 3). An increase in cytosolic Ca²⁺ concentration from <1 nM to 1 μM was accompanied by a decrease in channel activity. Increasing cytosolic Ca²⁺ to 10 μM exhibited a pronounced inhibitory effect. Single channel conductance, however, was unchanged by increasing free Ca²⁺ concentrations from <1 nM to 10 μM. Collectively, these results provide the first characterization of rENaC heterologously expressed in a mammalian epithelial cell line, and provide evidence for channel regulation by cytosolic Na⁺ and Ca²⁺.     

Time-dependent Outward Currents through the Inward Rectifier Potassium Channel IRK1 : The Role of Weak Blocking Molecules

Outward currents through the inward rectifier K⁺ channel contribute to repolarization of the cardiac action potential. The properties of the IRK1 channel expressed in murine fibroblast (L) cells closely resemble those of the native cardiac inward rectifier. In this study, we added Mg²⁺ (0.44–1.1 mM) or putrescine (∼0.4 mM) to the intracellular milieu where endogenous polyamines remained, and then examined outward IRK1 currents using the whole-cell patch-clamp method at 5.4 mM external K⁺. Without internal Mg²⁺, small outward currents flowed only at potentials between −80 (the reversal potential) and ∼−40 mV during voltage steps applied from −110 mV. The strong inward rectification was mainly caused by the closed state of the activation gating, which was recently reinterpreted as the endogenous-spermine blocked state. With internal Mg²⁺, small outward currents flowed over a wider range of potentials during the voltage steps. The outward currents at potentials between −40 and 0 mV were concurrent with the contribution of Mg²⁺ to blocking channels at these potentials, judging from instantaneous inward currents in the following hyperpolarization. Furthermore, when the membrane was repolarized to −50 mV after short depolarizing steps (>0 mV), a transient increase appeared in outward currents at −50 mV. Since the peak amplitude depended on the fraction of Mg²⁺-blocked channels in the preceding depolarization, the transient increase was attributed to the relief of Mg²⁺ block, followed by a re-block of channels by spermine. Shift in the holding potential (−110 to −80 mV), or prolongation of depolarization, increased the number of spermine-blocked channels and decreased that of Mg²⁺-blocked channels in depolarization, which in turn decreased outward currents in the subsequent repolarization. Putrescine caused the same effects as Mg²⁺. When both spermine (1 μM, an estimated free spermine level during whole-cell recordings) and putrescine (300 μM) were applied to the inside-out patch membrane, the findings in whole-cell IRK1 were reproduced. Our study indicates that blockage of IRK1 by molecules with distinct affinities, spermine and Mg²⁺ (putrescine), elicits a transient increase in the outward IRK1, which may contribute to repolarization of the cardiac action potential.     

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.     

The effects of transmitters on the affinity of the insoluble fraction of Ox brain for Na+ and K+

The insoluble fraction of ox-brain, which had previously been shown to have a non-linear affinity for Na⁺ and K⁺, was prepared. Acetylcholine (1×10^–8 mol/l and 1×10^–7 mol/l) reduced the affinity of the fraction for Na⁺ and K⁺ to zero, while at 1×10^–6 mol/l, the affinity for the cations was almost as high as in the absence of the transmitter; the affinities for Na⁺ and K⁺ were particularly high, when the supernatant concentrations of these ions exceeded 80–100 mM. Addition of eserine (3×10^–5 mol/l) considerably modified the response of the fraction to acetylcholine (1×10^–5 mol/l). Atropine (1×10^–8 mol/l) in the absence or presence of acetylcholine (1×10^–5, or 1×10^–4 mol/l) reduced the affinity of the fraction for Na⁺ and K⁺ to zero. Epinephrine (3×10^–10 mol/l) lowered the affinity for Na⁺ and K⁺, while ergotamine itself (1×10^–5 mol/l) reduced it to zero. The addition of both epinephrine and ergotamine at the latter concentrations restored the affinity of the fractions for Na⁺ and K⁺ to what it had been in the absence of the transmitter or antagonist, previously reported. Norepinephrine (3×10^–10 mol/l), or ouabain (1×10^–7 mol/l) reduced the affinity of the fraction for Na⁺ and K⁺ to zero. Thus, the transmitters and antagonists altered the affinity of the insoluble fraction for Na⁺ and K⁺ nonlinearity, dependent upon their concentrations, the concentrations of the cations, and the interaction of transmitter and antagonist.     

Effects of antidiuretic hormone on cellular conductive pathways in mouse medullary thick ascending limbs of Henle: I. ADH increases transcellular conductance pathways

Summary This paper reports experiments designed to assess the relations between net salt absorption and transcellular routes for ion conductance in single mouse medullary thick ascending limbs of Henle microperfusedin vitro. The experimental data indicate that ADH significantly increased the transepithelial electrical conductance, and that this conductance increase could be rationalized in terms of transcellular conductance changes. A minimal estimate (G _c ^min ) of the transcellular conductance, estimated from Ba⁺⁺ blockade of apical membrane K⁺ channels, indicated thatG _c ^min was approximately 30–40% of the measured transepithelial conductance. In apical membranes, K⁺ was the major conductive species; and ADH increased the magnitude of a Ba⁺⁺-sensitive K⁺ conductance under conditions where net Cl^– absorption was nearly abolished. In basolateral membranes, ADH increased the magnitude of a Cl^– conductance; this ADH-dependent increase in basal Cl^– conductance depended on a simultaneous hormone-dependent increase in the rate of net Cl^– absorption. Cl^– removal from luminal solutions had no detectable effect onG _e , and net Cl^– absorption was reduced at luminal K⁺ concentrations less than 5mm; thus apical Cl^– entry may have been a Na⁺,K⁺,2Cl^– cotransport process having a negligible conductance. The net rate of K⁺ secretion was approximately 10% of the net rate of Cl^– absorption, while the chemical rate of net Cl^– absorption was virtually equal to the equivalent short-circuit current. Thus net Cl^– absorption was rheogenic; and approximately half of net Na⁺ absorption could be rationalized in terms of dissipative flux through the paracellular pathway. These findings, coupled with the observation that K⁺ was the principal conductive species in apical plasma membranes, support the view that the majority of K⁺ efflux from cell to lumen through the Ba⁺⁺-sensitive apical K⁺ conductance pathway was recycled into cells by Na⁺,K⁺,2Cl^– cotransport.     

Whole-cell and single-channel currents across the plasmalemma of corn shoot suspension cells

Summary Whole-cell sealed-on pipettes have been used to measure electrical properties of the plasmalemma surrounding protoplasts isolated from Black Mexican sweet corn shoot cells from suspension culture. In these protoplasts the membrane resting potential (V _m ) was found to be –59±23 mV (n=23) in 1mm K _o ^– . The meanV _m became more negative as [K^–] _o decreased, but was more positive than the K⁺ equilibrium potential. There was no evidence of electrogenic pump activity. We describe four features of the current-voltage characteristic of the plasmalemma of these protoplasts which show voltagegated channel activity. Depolarization of the whole-cell membrane from the resting potential activates time- and voltage-dependent outward current through K⁺-selective channels. A local minimum in the outward current-voltage curve nearV _m =150 mV suggests that these currents are mediated by two populations of K⁺-selective channels. The absence of this minimum in the presence of verapamil suggests that the activation of one channel population depends on the influx of Ca²⁺ into the cytoplasm. We identify unitary currents from two K⁺-selective channel populations (40 and 125 pS) which open when the membrane is depolarized; it is possible that these mediate the outward whole-cell current. Hyperpolarization of the membrane from the resting potential produces time- and voltage-dependent inward whole-cell current. Current activation is fast and follows an exponential time course. The current saturates and in some cases decreases at membrane potentials more negative than –175 mV. This current is conducted by poorly selective K⁺ channels, whereP _Cl/P _K=0.43±0.15. We describe a low conductance (20 pS) channel population of unknown selectivity which opens when the membrane is hyperpolarized. It is possible that these channels mediate inward whole-cell current. When the membrane is hyperpolarized to potentials more negative than –250 mV large, irregular inward current is activated. A third type of inward whole-cell current is briefly described. This activates slowly and with a U-shaped current-voltage curve over the range of membrane potentials –90<V _m <0 mV.