Tetraethylammonium ion sensitivity of a 35-pS Ca2+-activated K+ channel in GH3 cells that is activated by thyrotropin-releasing hormone

Single Ca²⁺-activated K⁺ channels were studied in membrane patches from the GH₃ anterior pituitary cell line. We have previously demonstrated the coexistence of large-conductance and small-conductance (280 pS and 11 pS in symmetrical 150 mM K⁺, respectively) Ca²⁺-activated K⁺ channels in this cell line (Lang and Ritchie 1987). Here we report the existence of a third type of Ca²⁺-activated K⁺ channel that has a conductance of about 35 pS under similar conditions. In excised inside-out patches, this channel can be activated by elevations of the internal free Ca²⁺ concentration, and the open probability increases as the membrane potential is made more positive. In excised patches, the sensitivity of this 35-pS channel to internal Ca²⁺ is low; at positive membrane potentials, this channel requires Ca²⁺ concentrations greater than 10 M for activation. However, 35-pS channels have a much higher sensitivity to Ca²⁺ in the first minute after excision (activated by 1 M Ca²⁺ at –50 mV). Therefore, it is possible that the Ca²⁺ sensitivity of this channel is stabilized by intracellular factors. In cell-attached patches, this intermediate conductance channel can be activated (at negative membrane potentials) by thyrotropin-releasing hormone-induced elevations of the intracellular Ca²⁺ concentration and by Ca²⁺ influx during action potentials. The intermediate conductance channel is inhibited by high concentrations of external tetraethylammonium ions (K _d=17 mM) and is relatively resistant to inhibition by apamin.     

A potassium current activated by lemakalim and metabolic inhibition in rabbit mesenteric artery

K⁺ channels which are inhibited by intracellular ATP (ATP_i) (K_ATP channels) are thought to be the physiological target site of the K⁺ channel opening drugs (2) and to underlie a variety of physiological phenomena including hypoxia induced vasodilation (3). However, electrophysiological evidence for ATP_i-regulated K⁺ currents in smooth muscle is scarce. We, therefore, investigated the effects of one K⁺ channel opener, lemakalim, and metabolic inhibition on the membrane conductance of freshly dissociated rabbit mesenteric artery smooth muscle cells, using the perforated-patch whole cell recording technique (6). The cells were metabolically inhibited with 1 mM iodoacetic acid and 50 M dinitrophenol. Both lemakalim (0.1–3 M) and metabolic inhibition activated a time-independent and glyburide sensitive K⁺ current at physiological membrane potentials. The similarities between the lemakalim and metabolic inhibition activated currents suggest that a single class of channels underlies both currents. These results are the first whole-cell current recordings to demonstrate the activation of a smooth muscle membrane conductance by metabolic inhibition, lending support to the view that hypoxia induced vasodilation arises from the activation of K_ATP channels.     

Small-conductance Ca2+-activated K+ channels in bovine chromaffin cells

Simultaneous whole-cell patch-clamp and fura-2 fluorescence [Ca²⁺]_i measurements were used to characterize Ca²⁺-activated K⁺ currents in cultured bovine chromaffin cells. Extracellular application of histamine (10 M) induced a rise of [Ca²⁺]_i concomitantly with an outward current at holding potentials positive to –80 mV. The activation of the current reflected an increase in conductance, which did not depend on membrane potential in the range –80 mV to –40 mV. Increasing the extracellular K⁺ concentration to 20 mM at the holding potential of –78 mV was associated with inwardly directed currents during the [Ca²⁺]_i elevations induced either by histamine (10 M) or short voltage-clamp depolarizations. The current reversal potential was close to the K⁺ equilibrium potential, being a function of external K⁺ concentration. Current fluctuation analysis suggested a unit conductance of 3–5 pS for the channel that underlies this K⁺ current. The current could be blocked by apamin (1 M). Whole-cell current-clamp recordings snowed that histamine (10 M) application caused a transient hyperpolarization, which evolved in parallel with the [Ca²⁺]_i changes. It is proposed that a small-conductance Ca²⁺-activated K⁺ channel is present in the membrane of bovine chromaffin cells and may be involved in regulating catecholamine secretion by the adrenal glands of various species.     

Demonstration of a novel apamin-insensitive calcium-activated K+ channel in mouse pancreatic B cells

The whole-cell configuration of the patchclamp technique was used to characterize the biophysical and pharmacological properties of an oscillating K⁺-current that can be induced by intracellular application of GTP[S] in mouse pancreatic B cells (Ämmälä et al. 1991). These K⁺ conductance changes are evoked by periodic increases in the cytoplasmic Ca²⁺ concentration ([Ca²⁺]_i) and transiently repolarize the B cell, thus inhibiting action-potential firing and giving rise to a bursting pattern. GTP[S]-evoked oscillations in K⁺ conductance were reversibly suppressed by a high (300 M) concentration of carbamylcholine. By contrast, ₂-adrenoreceptor stimulation by 20 M clonidine did not interfere with the oscillatory behaviour but evoked a small sustained outward current. At 0 mV membrane potential, the oscillating K⁺-current elicited by GTP[S] was highly sensitive to extracellular tetraethylammonium (TEA; 70% block by 1 mM). The TEA-resistant component, which carried approximately 80% of the current at –40 mV, was affected neither by apamin (1 M) nor by tolbutamide (500 M). The current evoked by internal GTP[S] was highly selective for K⁺, as demonstrated by a 51-mV change in the reversal potential for a sevenfold change in [K⁺]_o. Stationary fluctuation analysis indicated a unitary conductance of 0.5 pS when measured with symmetric ( 140mM) KCl solutions. The estimated singlechannel conductance with physiological ionic gradients is 0.1 pS. The results indicate the existence of a novel Ca²⁺-gated K⁺ conductance in pancreatic B cells. Activation of this K⁺ current may contribute to the generation of the oscillatory electrical activity characterizing the B cell at intermediate glucose concentrations.     

Determination of intracellular K+ activity in rat kidney proximal tubular cells

The intracellular K⁺ activity of rat kidney proximal tubular cells was determined in vivo, using intracellular microelectrodes. In order to minimize damage from the impaling electrodes, separate measurements on separate cells, were performed with single-barrelled KCl-filled non-selective electrodes and single-barrelled, K⁺-sensitive microelectrodes, which were filled with a liquid K⁺-exchanger resin that has also a small sensitivity to Na⁺. Both electrodes had tip diameters of 0.2 m or below. The proper intracellular localization of the electrodes was ascertained by recording the cell potential response to intermittent luminal perfusions with glucose. The membrane potential measured with the non-selective microelectrodes was –76.3±8.1 mV (n=81) and the potential difference measured with the K⁺-sensitive microelectrode was –7.2±5.8 mV (n=32). Based on the activity of K⁺ in the extracellular fluid of 3 mmol/l the intracellular K⁺ activity was estimated to be 82 mmol/l. Assuming equal K⁺-activity coefficients to prevail inside and outside the cell, this figure suggests that the intracellular K⁺ concentration is 113 mmol/l which must be considered as a lower estimate, however. The data indicate that the K⁺-ion distribution between cytoplasm and extracellular fluid is not in equilibrium with the membrane potential, but that K⁺ is actively accumulated inside the cell. This result provides direct evidence for the presence of an active K⁺ pump in the tubular cell membranes, which in view of other observations, must be envisaged as a (not necessarily electroneutral) Na⁺/K⁺-exchange pump which operates in the peritubular cell membrane and is eventually responsible for the major part of the tubular solute and water absorption.     

Properties of single K+ channels in the basolateral membrane of rabbit proximal straight tubules

The basolateral membrane of rabbit straight proximal tubules, which were cannulated and perfused on one side, was investigated with the patch clamp technique. Properties of inward and outward directed single K⁺ channel currents were studied in cell-attached and insideout oriented cell-excised membrane patches. In cell-attached patches with NaCl Ringer solution both in pipette and bath, outward K⁺ currents could be detected after depolarization of the membrane patch by about 20–30 mV. The current-voltage (i/V) relationship could be fitted by the Goldman-Hodgkin-Katz (GHK) current equation, with the assumption that these channels were mainly permeable for K⁺ ions. A permeability coefficientP _K of (0.17±0.04) · 10^–12 cm³/s was obtained, the single channel slope conductance at infinite positive potentialg(V ) was 50±12 pS and the single channel conductance at the membrane resting potentialg(V _bl) was 12±3 pS (n=4). In cell-excised patches, with NaCl in the pipette and KCl in the bath, the data could also be fitted to the GHK equation and yieldedP _K = (0.1 ±0.01) ·10^–12 cm³/s,g(V ) = 40 ± 4 pS andg(V _bl) = 7 ± 1 pS (n=8). In cell-attached patches with KCl in the pipette and NaCl in the bath, inward K⁺ channels occurred at clamp potentials 60 mV, whereas outward K⁺ channel current was detected at more positive voltages. The current-voltage curves showed slight inward rectification. The single channel conductance, obtained from the linear part of the i/V curve by linear regression, was 46±3 pS and the reversal potential was 59±6 mV (n=9). In cell-excised patches with KCl in the pipette and NaCl in the bath, inward directed K⁺ channel currents could again be described by the GHK equation. The single channel parameters were similar to those recorded for outward K⁺ currents (see above). In inside-out oriented cell-excised patches with NaCl in the pipette and KCl in the bath, reducing bath (i.e. cytosolic) Ca²⁺ concentration from 10^–6 mol/l to less than 10^–9 mol/l did not affect the open state probability of single channel currents. These results demonstrate that the observed channels are permeable for K⁺ ions in both directions and that these basolateral K⁺ channels in rabbit proximal straight tubule are not directly dependent on Ca²⁺ ions.     

Single Ca2+-activated K+ channels in excised membrane patches of hamster oocytes

The properties of the Ca²⁺-activated K⁺ channel in unfertilized hamster oocytes were investigated at the single-channel level using inside-out excised membrane patches. The results indicate a new type of Ca²⁺-activated K⁺ channel which has the following characteristics: (1) single-channel conductance of 40–85 pS for outward currents in symmetrical K⁺ (150 mM) solutions, (2) inward currents of smaller conductance (10–50 pS) than outward currents, i.e. the channel is outwardly rectified in symmetrical K⁺ solutions, (3) channel activity dependent on the internal concentration of free Ca⁺ and the membrane potential, (4) modification of the channel activity by internal adenosine 5 diphosphate (0.1 mM) producing a high open probability regardless of membrane potential.     

Differential distribution of two Ca2+-dependent and -independent K+ channels throughout receptive and basolateral membranes of bullfrog taste cells

We could identify two types of K⁺ channels, of 80 and 40 pS conductance, respectively, in the bullfrog taste cell membrane using excised and cell-attached configurations of the patch-clamp technique. The taste cell membrane could be divided into four membrane parts — receptive area, apical process, cell body and proximal process. The 80-pS K⁺ channels were dependent on voltage and Ca²⁺ and were located exclusively on the receptive membrane and the apical process membrane. The 40-pS K⁺ channels were independent of voltage and Ca²⁺. The open probability of 40-pS K⁺ channels was decreased by the simultaneous presence of cyclic adenosine monophosphate (cAMP) and adenosine triphosphate (ATP), and the suppressive effect was antagonized by protein kinase inhibitor (PKI). Although 40-pS K⁺ channels were found in a high density on the receptive and apical process membranes, the channels also were present in the other two parts of the taste cell membrane. These results suggest that the two different types of K⁺ channel in the bullfrog taste cells may play different roles in gustatory transduction.     

Identification of an ATP-sensitive K+ channel in rat cultured cortical neurons

To determine whether membranes of mammalian central neurons contain an ATP-sensitive K⁺ (K_ATP) channel similar to that present in pancreatic cells, the patch-clamp technique was applied to cultured neurons prepared from the neonatal rat cerebral cortex and hippocampus. In whole-cell experiments with hippocampal neurons, extracellular application of 0.5 mM diazoxide (a K_ATP channel activator) elicited a hyperpolarization concomitant with an increase in membrane conductance, whereas application of 0.5 mM tolbutamide (a K_ATP channel blocker) induced a depolarization with a decrease in conductance. Similar results were obtained with cortical neurons. In outside-out patch experiments with cortical neurons, a K⁺ channel sensitive to these drugs was found. The channel was completely blocked by 0.5 mM tolbutamide and activated by 0.5 mM diazoxide. The single-channel conductance was 65 pS under symmetrical 145 mM K⁺ conditions and 24 pS in a physiological K⁺ gradient. In inside-out patch experiments, this channel was demonstrated to be inhibited by an application of 0.2–1 mM ATP to the cytoplasmic surface of the patch membrane. These results indicate that the membranes of rat cortical neurons contain a K_ATP channel that is quite similar to that found in pancreatic cells. It is also suggested that the same or a similar K⁺ channel may exist in membranes of hippocampal neurons.     

Microelectrode study of voltage-dependent Ba2+ and Cs+ block of apical K+ channels in the skin of Rana temporaria

The blockage of the apical K⁺ channels in frog species Rana temporaria by Ba²⁺ and Cs⁺ is strongly voltage-dependent. The interaction of both blockers with the K⁺ channels was studied by recording relations between the K⁺ currents (I _K) and the transepithelial and intracellular potential. Mucosal Ba²⁺ and Cs⁺ depress I _K, hyperpolarize the cell and induce pronounced nonlinearities in the current/voltage (I/V) relations. The nonlinearities are caused by the voltage-dependent interaction of Ba²⁺ and Cs⁺ with the binding site. Consequently, the apical membrane resistance not only depends on the blocker concentration but also on the apical membrane potential. Also the fractional resistance, fR _a, and the voltage divider ratio, fV _a, will change with blocker concentration and voltage. Owing to this non-ohmic behaviour, measurements of fV _a in the presence of Ba²⁺ deviate markedly from the expected fR _a values. The inhibitory effect of Ba²⁺ and Cs⁺ was analysed at different transepithelial and apical membrane voltages. The relation between the Michaelis-Menten constants and the voltage could be fitted with equations based on Eyring rate theory with the assumption of a single binding site. With this model we calculated the relative electrical position of the binding site for the blocker (), referred to the extracellular side of the channel. We obtained for Ba²⁺, =0.34±0.05 and for Cs⁺, =0.81±0.01. Comparison of the results from apical and transepithelial I/V relations demonstrates that the analysis of the transepithelial data provides overestimated values of the Hill coefficient and results in an underestimation of .     

Effect of NH4 +/NH3 on cytosolic pH and the K+ channels of freshly isolated cells from the thick ascending limb of Henle's loop

The conductance properties of the luminal membrane of cells from the thick ascending limb of Henle's loop of rat kidney (TAL) are dominated by K⁺. In excised membrane patches the luminal K⁺ channel is regulated by pH changes on the cytosolic side. To examine this pH regulation in intact cells of freshly isolated TAL segments we measured the membrane voltage (V _m) in slow-whole-cell (SWC) recordings and the open probability (P _o) of K⁺ channels in the cell-attached nystatin (CAN) configuration, where channel activity and part of V _m can be recorded. The pipette solution contained K⁺ 125 mmol/l and Cl^– 32 mmol/l. Intracellular pH was determined by 2,7 bis(2-carboxyethyl)-5,(6)-carboxyfluorescein (BCECF) fluorescence. pH changes were induced by the addition of 10 mmol/l NH₄ ⁺/NH₃ to the bath. In the presence of NH₄ ⁺/NH₃ intracellular pH acidified by 0.53±0.11 units (n=7). Inhibition of the Na⁺2Cl^– K⁺ cotransporter by furosemide (0.1 mmol/l) reversed this effect and led to a transient alkalinisation by 0.62±0.14 units (n=7). In SWC experiments V _m of TAL cells was -72±1 mV (n=70). NH₄ ⁺/NH₃ depolarised V _m by 22±2 mV (n=25). In 11 SWC experiments furosemide (0.1 mmol/l) attenuated the depolarising effect of NH₄ ⁺ from 24±3 mV to 7±3 mV. Under control conditions the single-channel conductance of TAL K⁺ channels in CAN experiments was 66±5 pS and the reversal voltage for K⁺ currents was 70±2 mV (n=35). The P _o of K⁺ channels in CAN patches was reduced by NH₄ ⁺/NH₃ from 0.45±0.15 to 0.09±0.07 (n=7). NH₄ ⁺/NH₃ exposure depolarised the zero current voltage of the permeabilised patches by-9.7±3.6 mV (n=5). The results show that TAL K⁺ channels are regulated by cytosolic pH in the intact cell. The cytosolic pH is acidified by NH₄ ⁺/NH₃ exposure at concentrations which are physiologically relevant because Na⁺2Cl^–K⁺(NH₄ ⁺) cotransporter-mediated import of NH₄ ⁺ exceeds the rate of NH₃ diffusion into the TAL. K⁺ channels are inhibited by this acidification and the cells depolarise. In the presence of furosemide TAL cells alkalinise proving that NH₄ ⁺ uptake occurs by the Na⁺2Cl^–K⁺ cotransporter. The findings that, in the presence of NH₄ ⁺/NH₃ and furosemide, V _m is not completely repolarised and that K⁺ channels are not activated suggest that the respective K⁺ channels may in addition to their pH regulation be inhibited directly by NH₄ ⁺/NH₃.     

Characterisation of Ca2+-dependent inwardly rectifying K+ currents in HeLa cells

The whole-cell configuration of the patch-clamp technique was used to examine K⁺ currents in HeLa cells. Under quasi-physiological ionic gradients, using an intracellular solution containing 10^–7 mol/l free Ca²⁺, mainly outward currents were observed. Large inwardly rectifying currents were elicited in symmetrical 145 mmol/l KCl. Replacement of all extracellular K⁺ by isomolar Na⁺, greatly decreased inward currents and shifted the reversal potential as expected for K⁺ selectivity. The inwardly rectifying K⁺ currents exhibited little or no apparent voltage dependence within the range of from –120 mV to 120 mV. A square-root relationship between chord conductance and [K⁺]₀ at negative potentials could be established. The inwardly rectifying nature of the currents was unaltered after removal of intracellular Mg²⁺ and chelation with ATP and ethylenediaminetetraacetic acid (EDTA). Permeability ratios for other monovalent cations relative to K⁺ were: K⁺ (1.0)>Rb⁺ (0.86)>Cs⁺ (0.12)>Li⁺ (0.08)>Na⁺ (0.03). Slope conductance ratios measured at –100 mV were: Rb⁺ (1.66)>K⁺ (1.0)>Na⁺ (0.09)>Li⁺ (0.08)>Cs⁺ (0.06). K⁺ conductance was highly sensitive to intracellular free Ca²⁺ concentration. The relationship between conductance at 0 mV and Ca²⁺ concentration was well described by a Hill expression with a dissociation constant, K _D, of 70 nmol/l and a Hill coefficient, n, of 1.81. Extracellular Ba²⁺ blocked the currents in a concentration- and voltage-dependent manner. The dependence of the K _D for the blockade was analysed using a Woodhull-type treatment, locating the ion interaction site at 19 % of the distance across the electrical field of the membrane and a K _D (0 mV) of 7 mmol/l. Tetraethylammonium and 4-aminopyridine were without effect whilst quinine and quinidine blocked the currents with concentrations for half-maximum effects equal to 7 mol/l and 3.5 mol/l, respectively. The unfractionated venom of the scorpion Leiurus quinquestriatus (LQV) blocked the K⁺ currents of HeLa cells. The toxins apamin and scyllatoxin had no detectable effect whilst charybdotoxin, a component of LQV, blocked in a voltage-dependent manner with half-maximal concentrations of 40 nmol/l at –120 mV and 189 nmol/l at 60 mV; blockade by charybdotoxin accounts for the effect of LQV. Application of ionomycin (5–10 mol/l), histamine (1 mmol/l) or bradykinin (1–10 mol/l) to cells dialysed with low-buffered intracellular solutions induced K⁺ currents showing inward rectification and a lack of voltage dependence.     

Ca2+ dependence of small Ca2+-activated K+ channels in cultured N1E-115 mouse neuroblastoma cells

Single-channel properties of Ca²⁺-activated K⁺ channels have been investigated in excised membrane patches of N1E-115 mouse neuroblastoma cells under asymmetric K⁺ concentrations at 0 mV. The SK channels are blocked by 3 nM external apamin, are unaffected by 20 mM external tetraethylammonium (TEA) and have a single-channel conductance of 5.4 pS. The half-maximum open probability and opening frequency of SK channels are observed at 1 M internal Ca²⁺. Concentration/effect curves of these parameters are very steep with exponential slope factors between 7 and 13. Opentime distributions demonstrate the existence of at least two open states. The mean short open time increases with [Ca²⁺]_i, whereas the mean long open time is independent of [Ca²⁺]_i. At low [Ca²⁺]_i the short-lived open state predominates. At saturating [Ca²⁺]_i the number of longlived openings is more enhanced than the number of short-lived openings and both open states occur equally frequently. The opening frequency as well as the open times of SK channels are independent of the membrane potential in the range of –16 to +40 mV. The results indicate that activation of K⁺ current through SK channels is mainly determined by the Ca²⁺-dependent single-channel opening frequency. BK channels in N1E-115 cells are insensitive to 100 nM external apamin, are sensitive to external TEA in the millimolar range and have a single-channel conductance of 98 pS. Half-maximum open probability and opening frequency of the BK channel are observed at 7.5–21 M internal Ca²⁺. The slope factors of concentration/effect curves range between 1.7 and 2.9. As the BK channel open time is markedly enhanced at raised [Ca²⁺]_i, the Ca²⁺ dependence of the current through BK channels is determined by the single-channel opening frequency as well as the open time. SK as well as BK channels appear to be clustered and interact in a negative cooperative manner in multiple channel patches. The differences in Ca²⁺ dependence suggest that BK channels are activated by a local high [Ca²⁺]_i associated with Ca²⁺ influx, whereas SK channels may be activated by Ca²⁺ released from internal stores as well.     

Basolateral K+ efflux is largely independent of maxi-K+ channels in rat submandibular glands during secretion

The involvement of large-conductance, voltage- and Ca²⁺-activated K⁺ channels (maxi-K⁺ channels) in basolateral Ca²⁺-dependent K⁺-efflux pathways and fluid secretion by the rat submandibular gland was investigated. Basolateral K⁺ efflux was monitored by measuring the change in K⁺ concentration in the perfusate collected from the vein of the isolated, perfused rat submandibular gland every 30 s. Under conditions in which the Na⁺/K⁺-ATPase and Na⁺-K⁺-2Cl^– cotransporter were inhibited by ouabain (1 mmol/l) and bumeta-nide (50 mol/l) respectively, continuous stimulation with acetylcholine (ACh) (1 mol/l) caused a transient large net K⁺ efflux, followed by a smaller K⁺ efflux, which gradually returned to the basal level within 10 min. These two components of the K⁺ efflux appear to be dependent on an increase in cytosolic Ca²⁺ concentration. The initial transient K⁺ efflux was not affected by charybdotoxin (100 nmol/l) or tetraethylammonium (TEA) (5 mmol/l) but the smaller second component was strongly and reversibly inhibited by charybdotoxin (100 nmol/l) and TEA (0.1 and 5 mmol/l). The initial K⁺ efflux transient induced by ACh was inhibited by quinine (0.1–3 mmol/l), quinidine (1–3 mmol/l) and Ba²⁺ (5 mmol/l), but not by verapamil (0.1 mmol/l), lidocaine (1 mmol/l), 4-aminopyridine (1 mmol/l) or apamin (1 mol/l). Ca²⁺-dependent transient large K⁺ effluxes induced by substance P (0.01 mol/l) and A23187 (3 mol/l) were not inhibited by TEA (5 mmol/l or 10 mmol/l). A23187 (3 mol/l) evoked a biphasic fluid-secretory response, which was not inhibited by TEA (5 mmol/l). Patch-clamp studies confirmed that the whole-cell outward K⁺ current attributable to maxi-K⁺ channels obtained from rat submandibular endpiece cells was strongly inhibited by the addition of TEA (1–10 mmol/l) to the bath. It is concluded that maxi-K⁺ channels are not responsible for the major part of the Ca²⁺-dependent basolateral K⁺ efflux and fluid secretion by the rat submandibular gland.     

Intracellular Ca2+ inactivates an outwardly rectifying K+ current in human adenomatous parathyroid cells

We have used whole-cell patch-clamp techniques to study the conductances in the plasma membranes of human parathyroid cells. With a KCl-rich pipette solution containing Ca²⁺ buffered to a concentration of 0.1 mol/l, the zero current potential was –71.1±0.5 mV (n=19) and the whole-cell current/ voltage (I/V) relation had an inwardly rectifying and an outwardly rectifying component. The inwardly rectifying current activated instantaneously on hyperpolarization of the plasma membrane to potentials more negative than –80 mV, and a semi-logarithmic plot of the reversal potential of the inward current (estimated by extrapolation from the range in which it was linear) as a function of extracellular K⁺ concentration ([K⁺]_o) revealed a linear relation with a slope of 64 mV per decade change in [K⁺]_o, which is not significantly different from the Nernstian slope, demonstrating that the current was carried by K⁺ ions. The conductance exhibited a square root dependence on [K⁺]_o as has been observed for inward rectifiers in other tissues. The current was blocked by the presence of Ba²⁺ (1 mmol/l) or Cs⁺ (1.5 mmol/l) in the bath. The outwardly rectifying current was activated by depolarization of the membrane potential to potentials more positive than –20 mV. It was inhibited by replacement of pipette K⁺ with Cs⁺, indicating that it also was a K⁺ current: it was partially (42%) blocked when tetraethylammonium (TEA⁺, 10 mmol/l) was added to the bath. The outwardly rectifying, but not the inwardly rectifying K⁺ current, was regulated by intracellular free Ca²⁺ concentration ([Ca²⁺]_i) such that increasing [Ca²⁺]_i above 10 nmol/l inhibited the outwardly rectifying current, the half-maximum effect being seen at 1 mol/l. Since it is known that increases in [Ca²⁺]_o produce increases in [Ca²⁺]_i, and that they depolarize parathyroid cells by reducing the membrane K⁺ conductance, we suggest that it is the reduction of the outwardly rectifying K⁺ conductance by increases in [Ca²⁺]_i which is responsible for the reduction in K⁺ conductance seen when [Ca²⁺]_o is increased.     

Cation specificity and pharmacological properties of the Ca2+-dependent K+ channel of rat cortical collecting ducts

The luminal membrane of principal cells of rat cortical collecting duct (CCD) is dominated by a K⁺ conductance. Two different K⁺ channels are described for this membrane. K⁺ secretion probably occurs via a small-conductance Ca²⁺-independent channel. The function of the second, large-conductance Ca²⁺-dependent channel is unclear. This study examines properties of this channel to allow a comparison of this K⁺ channel with the macroscopic K⁺ conductance of the CCD and with similar K⁺ channels from other preparations. The channel is poorly active on the cell. It has a conductance of 263±11 pS (n=36, symmetrical K⁺ concentrations) and of 139±3 pS (n=91) with 145 mmol/l K⁺ on one side and 3.6 mmol/l K⁺ on the other side of the membrane. Its open probability is high after excision (0.71±0.03, n=85). The channel flickers rapidly between open and closed states. Its permeability in the cell-free configuration was 7.0±0.2×10^–13 cm³/s (n=85). It is inhibited by several typical blockers of K⁺ channels such as Ba²⁺, tetraethylammonium, quinine, and quinidine and high concentrations of Mg²⁺. The Ca²⁺ antagonists verapamil and diltiazem also inhibit this K⁺ channel. As is typical for the maxi K⁺ channel, it is inhibited by charybdotoxin but not by apamin. The selectivity of this large-conductance K⁺ channel demonstrates significant differences between the permeability sequence (P _K > P _Rb > P _NH4 > P _Cs=P _Li=P _Na=P _choline=0) and the conductance sequence (g _K > g _NH4 > g _Rb > g _Li=g _choline > g _Cs=g _Na=0). The only other cations that are significantly conducted by this channel besides K⁺ (g _K at V _c = is 279±8 pS, n=88) are NH ₄ ⁺ (g _NH4=127±22 pS, n=10) and Rb⁺ (g _Rb=36±5 pS, n=6). The K⁺ currents through this channel are reduced by high concentrations of choline⁺, Cs⁺, Rb⁺, and NH ₄ ⁺ . These properties and the dependence of this channel on Ca²⁺ and voltage classify it as a maxi K⁺ channel. A possible physiological function of this channel is discussed in the accompanying paper.Supported by DFG Gr 480/10, by Schl 277/2-3 and by GIF 88/II     

Taurocholate depolarizes rat hepatocytes in primary culture by increasing cell membrane Na+ conductance

Rat hepatocytes in primary culture were impaled with conventional microelectrodes. Addition of 5–100 mol/l taurocholate led to a slowly developing depolarization that was maximal at 50 mol/l (10.5±1.5 mV, n=15) and not reversible. The effect was Na⁺ dependent and decreased in cells preincubated with 1 mol/l taurocholate. Increasing external K⁺ tenfold depolarized the cells by 12.3±2.3 mV under control conditions and by 6.3±1.2 mV with 50 mol/l taurocholate present (n=7). Depolarization by 1 mmol/l Ba²⁺ was 7.6±0.8 mV and 6.0±0.7 mV (n=9) before and after addition of taurocholate, respectively. Cable analysis and Na⁺ substitution experiments reveal that this apparent decrease in K⁺ conductance reflects an actual increase in Na⁺ conductance: in the presence of taurocholate, specific cell membrane resistance decreased from 2.8 to 2.3 k · cm² · Na⁺ substitution by 95% depolarized cell membranes by 8.9±2.9 mV (n=9), probably due to indirect effects on K⁺ conductance via changes in cell pH. With taurocholate present, the same manoeuvre changed membrane voltages by –0.8±2.6 mV. When Na⁺ concentration was restored to 100% from solutions containing 5% Na⁺, cells hyperpolarized by 3.5±3.6 mV (n=7) under control conditions and depolarized by 4.4±2.9 mV in the presence of taurocholate, respectively. In Cl^– substitution experiments, there was no evidence for changes in Cl^– conductance by taurocholate. These results show that taurocholate-induced membrane depolarization is due to an increase in Na⁺ conductance probably via uptake of the bile acid.     

Anion and cation channels in the basolateral membrane of rabbit parietal cells

Ion channels in the basolateral membrane of rabbit parietal cells in isolated gastric glands were studied by the patch clamp technique. Whole-cell current-clamp recordings showed that the membrane potential (E _m ) changed systematically as a function of the chloride concentrations of the basolateral bathing solution ([Cl^–]₀), and of the pipette (intracellular) solution. The relationship betweenE _m and [Cl^–]₀ was not affected by additions of histamine, dibutyryl-cAMP, 4-acetoamido-4-isothiocyanostilbene-2,2-disulfonic acid and diphenylamine-2-carboxylate. The whole-cell Cl^– conductance was insensitive to voltage. In cell-attached and cell-free patch membranes, however, single Cl^– channel opening events could not be observed. The value ofE _m depended little on the basolateral K⁺ concentration, but inward-rectifier K⁺ currents were observed in the whole-cell configuration, activated by hyperpolarizing pulses and inhibited by extracellular Ba²⁺. In cell-attached and cell-free patches, openings of single inward-rectifier K⁺ channels and non-selective cation channels were infrequently recorded. Neither cAMP nor Ca²⁺ activated these cation channels. The single K⁺ channel conductance was about 230 pS under the symmetrical high K⁺ conditions and was inhibited by intracellular tetraethylammonium ions (TEA). The non-selective cation channel had a voltage-independent single conductance of 22 pS and was not inhibited by TEA.     

ATP-sensitive K+ channels regulated by intracellular Ca2+ and phosphorylation in normal (T84) and cystic fibrosis (CFPAC-1) epithelial cells

The elementary K⁺ conductance activated by the cAMP or the Ca²⁺ second messenger pathways was investigated in the model salt-secreting epithelium, the human T84 cell line. Under Cl^–-free conditions, an inwardly rectifying whole-cell K⁺ current was evoked by either forskolin 10 (mol/l) or acetylcholine 1 (mol/l) and blocked by extracellular charybdotoxin 10 (nmol/l). In the cell-attached mode, both secretory agonists induced the opening of a channel showing inward rectification with a unitary chord conductance of 36.8±2.5 pS (n=26) for inward currents. In inside-out patches, a 35-pS inwardly rectifying K⁺ channel that corresponded to the channel recorded in the cell-attached configuration was recorded in the presence of 0.3 mol/l free Ca²⁺ at the inner side of the membrane. This channel was blocked by Ba²⁺ (5 mol/l) and by charybdotoxin (50 nmol/l). Its open probability was enhanced by intracellular Ca²⁺ with and EC₅₀ of 0.25 mol/l and strongly reduced by intracellular MgATP with an IC₅₀ of 600 mol/l. In the continuous presence of ATP, the channel activity was consistently increased by 125 kU/l catalytic subunit of cAMP-dependent protein kinase. In the cystic fibrosis pancreatic duct cell line CFPAC-1, a K⁺ channel was also recorded, with similar characterictics and regulation as the 35-pS channel in T84 cells. We conclude that an ATP-sensitive K⁺ channel regulated by intracellular Ca²⁺ and phosphorylation supports the main K⁺ current activated by secretory agonists in normal cystic fibrosis cell lines. This conductance possibly represents the major pathway for K⁺ recycling at the basolateral membrane during transepithelial fluid secretion.     

Evidence that the depolarization of glial cells by inhibitory amino acids is caused by an efflux of K+ from neurones

Summary The action of inhibitory amino acid transmitters GABA, glycine, -alanine and taurine has been studied on the membrane potential of cultured astrocytes and on the extracellular K⁺-concentration ([K⁺]₀) using K⁺-sensitive microelectrodes. All four amino acids caused a depolarization of glial cells and an increase of [K⁺]₀. The effects produced by GABA were usually more pronounced than those caused by the other amino acids. Simultaneous recordings of the action of GABA and glycine on the glial membrane potential and on [K⁺]₀ usually revealed a good correlation in time course, but often there were differences between the amplitudes of glial depolarizations and the values calculated from the [K⁺]₀ increase. 4-Aminopyridine, which blocks K⁺-conductance of excitable membranes, reversibly abolished both the glial depolarization and the [K⁺]₀ increase produced by GABA and glycine. From these results it is concluded that unlike neurones, glial cells do not have receptors for these amino acid transmitters and that their action on glial cells is caused by the efflux of K⁺ from activated neurones.