Ion conductances of isolated cortical collecting duct cells

The study of ion conductances in the intact cortical collecting duct (CCD) with the patch-clamp method is rather difficult. An optimized method to isolate CCD cells from rat kidneys using an in vivo followed by an in vitro enzyme digestion is described. Individual CCD segments were collected after this digestion and incubated in EGTA-buffered medium. This procedure resulted in single cells or cell clusters. These freshly isolated CCD cells were studied with different modifications of the patch-clamp method. Membrane voltages measured in the cell-attached-nystatin configuration were –74 ±1mV (n=13) and –68±3 mV (n=22) in cells isolated from normal and mineralocorticoid-treated rats respectively. These values and those measured with the nystatin-perforated slow-whole-cell configuration (–79 ±1mV, n=23) are comparable to those measured in principal cells of isolated CCD segments. The cells hyperpolarized after the addition of amiloride and depolarized with the addition of adiuretin to the bath. The amiloride effect was enhanced when cells were isolated from deoxycorticosterone-acetate-treated rats. The cells were strongly depolarized upon elevation of the extracellular K⁺-concentration and did not demonstrate a measurable Cl^– conductance. A large-conductance K⁺ channel (174 pS, n=5, cell-attached, 145 mmol/l K⁺ in the pipette; 140 pS, n=12, cell-free, 3.6 mmol/l K⁺ in the bath) was seen. It had a very low activity on the cell, but a high open probability when excised into a solution with 1 mmol/l Ca²⁺ on the cytosolic side. More often a small-conductance K⁺ channel (36–52 pS, n=19, cell-attached; 30 pS, n=5, cell-free) with a high open probability was found on the cell. These freshly isolated cells seem to be a powerful preparation to study the properties and regulation of ion conductances of rat CCD with several electrophysiological methods. These freshly isolated CCD cells maintain the conductance properties known from principal cells of the intact CCD.     

K+ channels in the basolateral membrane of rat cortical collecting duct

Impalement studies in isolated perfused cortical collecting ducts (CCD) of rats have shown that the basolateral membrane possesses a K⁺ conductive pathway. In the present study this pathway was investigated at the single-channel level using the patch-clamp technique. Patch-clamp recordings were obtained from enzymatically isolated CCD segments and freshly isolated CCD cells with the conventional cell-free, cell-attached and the cell-attached nystatin method. Two K⁺ channels were found which were highly active on the cell with a conductance of 67±5 pS (n=18) and 148±4 pS (n=21) with 145 mmol/l K⁺ in the pipette. In excised patches the first channel had a conductance of 28±2 pS (n=15), whereas the second one had a conductance of 85±1 pS (n=53) at 0 mV clamp voltage with 145 mmol/l K⁺ on one side and 3.6 mmol/l K⁺ on the other side of the membrane. So far it has not been possible to characterize the smaller channel further. Excised, and with symmetrical K⁺ concentrations of 145 mmol/l, the intermediate channel had a linear conductance of 198±19 pS (n=5). After excision in the inside-out configuration the open probability (P _o) of this channel was low (0.18±0.05, n=13) whereas in the outside-out configuration this channel had a threefold higher P _o (0.57±0.04, n=12). Several inhibitors were tested in excised membranes. Ba²⁺ (1 mmol/l), tetraethylammonium (TEA⁺, 10 mmol/l) and verapamil (0.1 mmol/l) all blocked this channel reversibly. Furthermore P _o was reversibly reduced by 10 nmol/l charybdotoxin (outside-out). This K⁺ channel of the basolateral membrane was regulated by cellular pH. P _o was reduced to 26±3% at pH 6.5 (n=6) and increased to 216±18% at pH 8.5 (n=7) compared to pH 7.4. Half-maximal inhibition was reached at pH 7.0. The channel had its highest P _o at a Ca²⁺ activity of less than 10^–8 mol/l (n=13). Increasing the Ca²⁺ activity to 1 mmol/l on the cytosolic side of the membrane resulted in a reduction of P _o to 13±3% (n=11). Half-maximal inhibition was reached at a Ca²⁺ activity of 10^–5 mol/l. The high activity of both K⁺ channels of the basolateral membrane on the cell indicates that they may serve for K⁺ recirculation across the basolateral membrane.     

Regulation of inwardly rectifying K+ channels by intracellular pH in opossum kidney cells

The effects of intracellular pH on an inwardly rectifying K⁺ channel (K_in channel) in opossum kidney (OK) cells were examined using the patch-clamp technique. Experiments with inside-out patches were first carried out in Mg²⁺-and adenosine triphosphate (ATP)-free conditions, where Mg²⁺-induced inactivation and ATP-induced reactivation of K_in channels were suppressed. When the bath (cytoplasmic side) pH was decreased from 7.3 to either 6.8 or 6.3, K_in channels were markedly inhibited. The effect of acid pH was not fully reversible. When the bath pH was increased from 7.3 to 7.8, 8.3 or 8.8, the channels were activated reversibly. The channel activity exhibited a sigmoidal pH dependence with a maximum sensitivity at pH 7.5. Inside-out experiments were also carried out with a solution containing 3 mM Mg-ATP and a similar pH sensitivity was observed. However, in contrast with the results obtained in the absence of Mg²⁺ and ATP, the effect of acid pH was fully reversible. Experiments with cell-attached patches demonstrated that changes in intracellular pH, which were induced by changing extracellular pH in the presence of an H⁺ ionophore, could influence the channel activity reversibly. It is concluded that the activity of K_in channels can be controlled by the intracellular pH under physiological conditions.     

High-conductance K+ channel in apical membranes of principal cells cultured from rabbit renal cortical collecting duct anlagen

Using the patch clamp technique, one type of K⁺ channel was identified in the apical cell membrane of cultured principal cells of rabbit renal collecting ducts in the cell-attached or excised-patch configuration. The channel was highly selective for K⁺ over Na⁺ (typically 30-70-fold) and had a conductance of 180, SD±39 pS (n=6), referred to a situation of 140 mmolar K⁺-Ringer solution present on either surface of the patch membrane. Channel activity was completely blocked by Ba²⁺ (5 mmol/l) and partially inhibited by Na⁺. The latter was evidenced by a deviation from Goldman rectification at high cytoplasm-positive membrane potentials, which was observed when Na⁺ competed with K⁺ for channel entrace from the cytoplasmic surface. Channel open probability depended strongly on membrane voltage and cytoplasmic Ca²⁺ concentration. Open-close kinetics exhibited double exponential behaviour, with a strong voltage dependence of the slow open time constant. Infrequently also a substate conductance level was identified. The voltage and calcium dependence suggest that the channel plays a role in adjusting K⁺ secretion to Na⁺ absorption in the fine regulation of cation excretion in renal collecting ducts.     

Properties of the potassium conductances of principal cells of rat cortical collecting ducts

In this study we examined by impalement techniques properties of the macroscopic K⁺ conductances in the luminal and basolateral membrane of principal cells from isolated perfused cortical collecting ducts (CCD) of the rat. Both membranes possess a dominating K⁺ conductance. Compared to their behaviour with K⁺, both membranes appear much less permeable to NH ₄ ⁺ and Rb⁺, and the K⁺ conductances of both membranes are inhibited by these cations. In light of these findings, it is very unlikely that significant amounts of NH ₄ ⁺ , which is secreted in the CCD, cross the principal cells as NH ₄ ⁺ . Several inhibitors with known effects on K⁺ channels in patch-clamp studies have been examined. Tetraethylammonium, which inhibits the excised K⁺ channels of these cells, has no effect on the macroscopic K⁺ conductances of either membrane. Verapamil, which inhibits the K⁺ channels in the luminal membrane, acts predominantly on the basolateral membrane K⁺ conductance in the intact tubule. Therefore, some of the macroscopic properties of the K⁺ conductances are distinct from those of single channels thus far observed in patchclamp studies.Supported by DFG Schl 277/2-1 and Gr 480/10     

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     

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.     

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.     

Maxi K+ channels in the basolateral membrane of the exocrine frog skin gland regulated by intracellular calcium and pH

With the single-channel patch-clamp technique we have identified Ca²⁺-sensitive, high-conductance (maxi) K⁺ channels in the basolateral membrane (BLM) of exocrine gland cells in frog skin. Under resting conditions, maxi K⁺ channels were normally quiescent, but they were activated by muscarinic agonists or by high serosal K⁺. In excised inside-out patches and with symmetrical 140 mmol/l K⁺, single-channel conductance was 200 pS and the channel exhibited a high selectivity for K⁺ over Na⁺. Depolarization of the BLM increased maxi K⁺ channel activity. Increasing cytosolic free Ca²⁺ (by addition of 100 nmol/l thapsigargin to the bathing solution of cell-attached patches also increased channel activity, whereas thapsigargin had no effect when added to excised inside-out patches. An increase in cytosolic free Ca²⁺ directly activated channel activity in a voltage-dependent manner. Maxi K⁺ channel activity was sensitive to changes in intracellular pH, with maximal activity at pH 7.4 and decreasing activities following acidification and alkalinization. Maxi K⁺ channel outward current was reversibly blocked by micromolar concentrations of Ba²⁺ from the cytosolic and extracellular site, and was irreversibly blocked by micromolar concentrations of charybdotoxin and kaliotoxin from the extracellular site in outside-out patches.     

Regulation and possible physiological role of the Ca2-dependent K+ channel of cortical collecting ducts of the rat

In the luminal membrane of rat cortical collecting duct (CCD) a big Ca²⁺-dependent and a small Ca²⁺-independent K⁺ channel have been described. Whereas the latter most likely is responsible for the K⁺ secretion in this nephron segment, the function of the large-conductance K⁺ channel is unknown. The regulation of this channel and its possible physiological role were examined with the conventional cell-free and the cell-attached nystatin patch-clamp techniques. Patch-clamp recordings were obtained from the luminal membrane of isolated perfused CCD segments and from freshly isolated CCD cells. Intracellular calcium was measured using the calcium-sensitive dye fura-2. The large-conductance K⁺ channel was strongly voltage- and calcium-dependent. At 3 mol/l cytosolic Ca²⁺ activity it was half-maximally activated. At 1 mmol/l it was neither regulated by cytosolic pH nor by ATP. At 1 mol/l Ca²⁺ activity the open probability (P _o) of this channel was pH-dependent. At pH 7.0 P _o was decreased to 4±2% (n=9) and at pH 8.5 it was increased to 425±52% (n=9) of the control. At this low Ca²⁺ activity the P _o of the channel was reduced by 1 mmol/l ATP to 8±4% (n=6). Cell swelling activated the large-conductance K⁺ channel (n=14) and hyperpolarized the membrane potential of the cells by 9±1 mV (n=23). Intracellular Ca²⁺ activity increased after hypotonic stress. This increase depended on the extracellular Ca²⁺ activity. A possible physiological function of the large-conductance K⁺ channel in rat CCD cells may be the reduction of the intracellular K⁺ concentration after cell swelling. Once this channel is activated by increases in the cytosolic Ca²⁺ activity it can be regulated by changes in cellular pH and ATP.Supported by DFG Schl 277/2-3     

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.     

Characterization of Ca2+-activated K+ channels in excised patches of human T lymphocytes

Ca²⁺-activated K⁺ [K(Ca)] channels were studied in excised patches of resting and activated human peripheral blood T lymphocytes. The K(Ca) channel had a single-channel conductance of 50±6 pS in symmetrical high-K⁺ solutions in the potential range of –100 to –10 mV and was inwardly rectifying at more depolarized potentials. The channel was sensitive to block by charybdotoxin (10 nM) and insensitive to apamin (3 nM). Half-maximum activation occurred at an internal free Ca²⁺ concentration of 360±110 nM. The concentration-effect curve had a slope factor of 0.83±0.12, suggesting a 11 interaction of Ca²⁺ ions with the channel. Ca²⁺ affects the open time probability of the K(Ca) channels, mainly by modulating the frequency of channel opening. The open probability did not show voltage dependence. The kinetics of the channel could be described assuming one open state and two closed states. The time constant of the exponential describing the open time distribution amounted to 2.8±1.2 ms, whereas the closed time distribution could be described with two exponentials with time constants of 0.2±0.05 ms and 8.0±2.1 ms, respectively. Resting T lymphocytes expressed a low number of channels but the density of channels increased dramatically during chronic phytohaemagglutinin stimulation.     

Single-channel properties and regulation of pinacidil/glibenclamide-sensitive K+ channels in follicular cells from Xenopus oocyte

Follicular oocytes from Xenopus laevis contain K⁺ channels that are activated by members of the recently recognized class of vasorelaxants that includes the pinacidil derivative P1060. These channels are blocked by antidiabetic sulphonylureas such as glibenclamide. Opening of the glibenclamide-sensitive K⁺ channels with P1060 promotes follicular oocyte maturation. Whole-cell and single-channel patch-clamp configurations were used to monitor K⁺ channel activity in isolated follicular cells. In the presence of micromolar concentrations of intracellular Mg²⁺ ATP, P1060 activated a whole-cell K⁺ current that was blocked by glibenclamide. The P1060 response was depressed by millimolar concentrations of intracellular ATP and ATP[S]. Single-channel recordings identified two different types of K⁺ channel. These channels differed in their unitary conductances (19 pS and 150 pS), in their sensitivities to internal Ca²⁺, to charybdotoxin and to pinacidil and glibenclamide. Only the Ca²⁺-independent K⁺ channel (19 pS) was activated by the pinacidil derivative and blocked by glibenclamide. Opening of the 19-pS glibenclamide-sensitive K⁺ channel by P1060 critically required the presence of a low concentration of Mg²⁺ATP in the intracellular medium. The 19-pS K⁺ channel was opened by increasing intracellular cAMP. Similar effects were obtained by intracellular application of the catalytic subunit of protein kinase A in the presence of micromolar concentrations of Mg²⁺ATP. Both acetylcholine and the phorbol ester phorbol 12-myristate 13-acetate blocked the 19-pS K⁺ channel after it was activated by P1060.This work was supported by the Centre National de la Recherche Scientifique (CNRS) and the Fondation pour la Recherche Médicale (FRM)     

Mechanisms of intracellular pH regulation in the hamster inner medullary collecting duct perfused in vitro

To examine the mechanisms of H⁺ transport in the mid-inner medullary collecting duct of hamsters, we measured the intracellular pH (pH_i) in the in vitro perfused tubules by microscopic fluorometry using 2,7-bis(carboxyethyl)-carboxyfluorescein (BCECF) as a fluorescent probe. In the basal condition, pH_i was 6.74±0.04 (n=45) in HCO ₃ ^– -free modified Ringer solution. Either elimination of Na⁺ from the bath or addition of amiloride (1 mM) to the bath produced a reversible fall in pH_i After acid loading with 25 mM NH₄Cl, pH_i spontaneously recovered with an initial recovery rate of 0.096±0.012 (n=23) pH unit/min. In the absence of ambient Na⁺, after removal of NH ₄ ⁺ , the pH_i remained low (5.95±0.10, n=8) and showed no signs of recovery. Subsequent restoration of Na⁺ only in the lumen had no effect on pH_i. However, when Na⁺ in the bath was returned to the control level, pH_i recovered completely. Amiloride (1 mM) in the bath completely inhibited the Na⁺-dependent pH_i recovery. Furthermore, elimination of Na⁺ from the bath, but not from the lumen, decreased pH_i from 6.97±0.07 to 6.44±0.05 (n=12) in the HCO ₃ ^– /Ringer solution or 6.70±0.03 to 6.02±0.05 (n=8) in the HCO ₃ ^– free solution. pH_i spontaneously returned to 6.76±0.08 with a recovery rate of 0.017±0.5 pH unit/min in the presence of CO₂/HCO ₃ ^– , whereas it did not recover in the absence of CO₂/HCO ₃ ^– . Although elimination of ambient Na⁺ depolarized the basolateral membrane voltage (V _B) from –78±1.2 to –72 ±0.6 mV (n=5, P<0.01), the level of V _B was not sufficient to explain the pH_i recovery solely by HCO ₃ ^– entry driven by the voltage. These results indicate that (a) pH_i of the inner medullary collecting duct is regulated mainly by a Na⁺/H⁺ exchanger in the basolateral membranes, (b) no apparent Na⁺-dependent H⁺ transport system exists in the luminal membranes and (c) Na⁺-independent H⁺ transport may also operate in the presence of CO₂/HCO ₃ ^– Preliminary data were reported at the Conference on Bicarbonate, Chloride, and Proton Transport Systems, New York, USA, in January 1989     

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.     

Reciprocal effects of Ca2+ and Mg-ATP on the ‘run-down’ of the K+ channels in opossum kidney cells

Using the patch clamp technique, we identified an inwardly rectifying K⁺ channel in the membrane of opossum kidney cells. The single channel conductance was about 90 pS for inward currents and 30 pS for outward currents under a symmetrical high-K⁺ condition. The activity of the channel was found to decrease with time during recording from inside-out patches. In the solution with submicromolar Ca²⁺, the activity disappeared within 4–20 min. Intracellular Ca²⁺ promoted the run-down of the channel activity at 0.1–1 mM, whereas millimolar Mg-ATP restored the activity after run-down. The run-down channels could never be reactivated by ATP in the absence of Mg²⁺, or by a nonhydrolyzable ATP analog, AMPPNP, even in the presence of Mg²⁺.     

Intracellular Na+ modulates large conductance Ca2+-activated K+ currents in human umbilical vein endothelial cells

We studied the effects of Na⁺ influx on large-conductance Ca²⁺-activated K⁺ (BK_Ca) channels in cultured human umbilical vein endothelial cells (HUVECs) by means of patch clamp and SBFI microfluorescence measurements. In current-clamped HUVECs, extracellular Na⁺ replacement by NMDG⁺ or mannitol hyperpolarized cells. In voltage-clamped HUVECs, changing membrane potential from 0 mV to negative potentials increased intracellular Na⁺ concentration ([Na⁺]_i) and vice versa. In addition, extracellular Na⁺ depletion decreased [Na⁺]_i. In voltage-clamped cells, BK_Ca currents were markedly increased by extracellular Na⁺ depletion. In inside-out patches, increasing [Na⁺]_i from 0 to 20 or 40 mM reduced single channel conductance but not open probability (NPo) of BK_Ca channels and decreasing intracellular K⁺ concentration ([K⁺]_i) gradually from 140 to 70 mM reduced both single channel conductance and NPo. Furthermore, increasing [Na⁺]_i gradually from 0 to 70 mM, by replacing K⁺, markedly reduced single channel conductance and NPo. The Na⁺–Ca²⁺ exchange blocker Ni²⁺ or KB-R7943 decreased [Na⁺]_i and increased BK_Ca currents simultaneously, and the Na⁺ ionophore monensin completely inhibited BK_Ca currents. BK_Ca currents were significantly augmented by increasing extracellular K⁺ concentration ([K⁺]_o) from 6 to 12 mM and significantly reduced by decreasing [K⁺]_o from 12 or 6 to 0 mM or applying the Na⁺–K⁺ pump inhibitor ouabain. These results suggest that intracellular Na⁺ inhibit single channel conductance of BK_Ca channels and that intracellular K⁺ increases single channel conductance and NPo. GH Liang and MY Kim contributed equally to this publication and therefore share the first authorship.     

Characterization of an outward K+ current in freshly dispersed cerebral arterial muscle cells

This study was carried out to define some of the cellular ionic mechanisms controlling cerebral arterial muscle. Muscle cells were enzymatically dispersed from cat cerebral arteries. Cells were dialyzed and voltage-clamped using patch pipettes and whole-cell currents measured. Using pipette solutions allowing us to record K⁺ currents we identified an outward current elicited by depolarizing voltage steps beyond –20 mV. This outward current exhibited properties of delayed outward rectification having a peak macroscopic current at +90 mV of 504±236 pA. The current was sensitive to 4-aminopyridine, but was sensitive to tetraethylammonium only at very high doses. When CsCl was in the recording pipette, macroscopic outward currents could not be recorded. Variations in the extracellular Ca²⁺ concentration from 0.5 to 5.0 mM had no effect on current amplitude or voltage dependence; similarly the Ca²⁺ channel blockers nifedipine and Mn²⁺ were without effect on this outward current. The current inactivated slowly with no decay seen even with 3-s command pulses. Repetitive voltage pulses from –60 to +90 mV at a frequency of 1 Hz resulted in cumulative reduction, depressing peak current by 60% after ten pulses. Upon reduction of pH from 7.43 to 7.20 we observed a 350% increase in peak outward current in 7 of 12 cells studied in this regard. Thus, the cellular mechanism responsible for cerebral vascular dilation to acidosis and/or hypercapnia may involve an increase in outward K⁺ current.     

Regulation of membrane excitability by intracellular pH (pHi) changers through Ca2+-activated K+ current (BK channel) in single smooth muscle cells from rabbit basilar artery

Employing microfluorometric system and patch clamp technique in rabbit basilar arterial myocytes, regulation mechanisms of vascular excitability were investigated by applying intracellular pH (pH_i) changers such as sodium acetate (SA) and NH₄Cl. Applications of caffeine produced transient phasic contractions in a reversible manner. These caffeine-induced contractions were significantly enhanced by SA and suppressed by NH₄Cl. Intracellular Ca²⁺ concentration ([Ca²⁺]_i) was monitored in a single isolated myocyte and based the ratio of fluorescence using Fura-2 AM (R _340/380). SA (20 mM) increased and NH₄Cl (20 mM) decreased R _340/380 by 0.2 ± 0.03 and 0.1 ± 0.02, respectively, in a reversible manner. Caffeine (10 mM) transiently increased R _340/380 by 0.9 ± 0.07, and the ratio increment was significantly enhanced by SA and suppressed by NH₄Cl, implying that SA and NH₄Cl may affect [Ca²⁺]_i (p < 0.05). Accordingly, we studied the effects of SA and NH₄Cl on Ca²⁺-activated K⁺ current (IK_Ca) under patch clamp technique. Caffeine produced transient outward current at holding potential (V _h) of 0 mV, caffeine induced transient outward K⁺ current, and the spontaneous transient outward currents were significantly enhanced by SA and suppressed by NH₄Cl. In addition, IK_Ca was significantly increased by acidotic condition when pH_i was lowered by altering the NH₄Cl gradient across the cell membrane. Finally, the effects of SA and NH₄Cl on the membrane excitability and basal tension were studied: Under current clamp mode, resting membrane potential (RMP) was −28 ± 2.3 mV in a single cell level and was depolarized by 13 ± 2.4 mV with 2 mM tetraethylammonium (TEA). SA hyperpolarized and NH₄Cl depolarized RMP by 10 ± 1.9 and 16 ± 4.7 mV, respectively. SA-induced hyperpolarization and relaxation of basal tension was significantly inhibited by TEA. These results suggest that SA and NH₄Cl might regulate vascular tone by altering membrane excitability through modulation of [Ca²⁺]_i and Ca²⁺-activated K channels in rabbit basilar artery.     

The luminal K+ channel of the thick ascending limb of Henle's loop

In vitro perfused rat thick ascending limbs of Henle's loop (TAL) were used (n=260) to analyse the conductance properties of the luminal membrane applying the patch-clamp technique. Medullary (mTAL) and cortical (cTAL) tubule segments were dissected and perfused in vitro. The free end of the tubule was held and immobilized at one edge by a holding pipette kept under continuous suction. A micropositioner was used to insert a patch pipette into the lumen, and a gigaohm seal with the luminal membrane was achieved in 455 instances out of considerably more trials. In approximately 20% of all gigaohm seals recordings of single ionic channels were obtained. We have identified only one single type of K⁺ channel in these cell-attached and cell-excised recordings. In the cell-attached configuration with KCl or NaCl in the pipette, the channel had a conductance of 60±6 pS (n=24) and 31±7 pS (n=4) respectively. In cell-free patches with KCl either in the patch pipette or in the bath and with a Ringer-type solution (NaCl) on the opposite side the conductance was 72±4 pS (n=37) at a clamp voltage of 0 mV. The permeability was 0.33±0.02 · 10^±12 cm³/s. The selectivity sequence für this channel was: K⁺=Rb⁺=NH ₄ ⁺ =Cs⁺>Li⁺Na⁺=0; the conductance sequence was K⁺Li⁺Rb⁺=Cs⁺= NH ₄ ⁺ =Na⁺=0. In excised patches Rb⁺, Cs⁺ and NH ₄ ⁺ when present in the bath at 145 mmol/l all inhibited K⁺ currents out of the pipette. The channel kinetics were described by one open (9.5±1.5 ms, n=18) and by two closed (1.4±0.1 and 14±2 ms) time constants. The open probability of this channel was increased by depolarization. The channel open probability was reduced voltage dependently by Ba²⁺ (half maximal inhibition at 0 mV: 0.07 mmol/l) from the cytosolic side. Verapamil, diltiazem, quinine and quinidine inhibited at approximately 1 mol/l ±0.1 mmol/l from either side. Similarly, the amino cations lidocaine, tetraethylammonium and choline inhibited at 10–100 mmol/l. The channel was downregulated in its open probability by cytosolic Ca²⁺ activities > 10^±7 mol/l and by adenosine triphosphate 10^±4 mol/l. The open probability was downregulated by decreasing cytosolic pH (2-fold by a decrease in pH by 0.2 units). The described channel differs in several properties from the K⁺ channels of other epithelia and of renal cells and TAL cells in culture. It appears to be responsible for K⁺ recycling in the TAL segment.Preliminary reports of the present study have been given at the following conferences: Tagung der Deutschen Physiologischen Gesellschaft, Würzburg, October 1988; Membranforum, Frankfurt, April 1989; 3rd Int. Conf. Diur., Mexico City, April 1989; 3rd Nephrology Forefront Symposium, Arrola, July, 1989; IUPS meeting, Helsinki, July 1989. This study has been supported by Deutsche Forschungsgemeinschaft Grant No. Gr 480/9