Fast Na+ current in circular smooth muscle cells of the large intestine

Whole-cell voltage clamp was carried out on freshly dispersed single smooth muscle cells from adult rat and human colons to investigate the regulation of the Ca²⁺ channels. In this study, we unexpectedly discovered the existence of a fast Na⁺ channel current. With normal physiological salt solution (PSS) plus 4-amino-pyridine (3 mM) in the bath and high-Cs⁺ solution in the pipette to inhibit outward K⁺ currents, an inward current possessing fast and slow components was observed when the cell membrane was depolarized to a value more positive than –20 mV from a holding potential of –100 mV. When Ca²⁺ ions were removed from the PSS, or when nifedipine (10 M) and Ni²⁺ (30 M) were simultaneously applied, the slow component disappeared and the fast component remained. The fast current component became almost completely inactivated within 10 ms. This fast component was dependent on extracellular Na⁺ concentration and was inhibited by tetrodotoxin (TTX) dose dependently (IC₅₀ of 130 nM in rat and 14 nM in human). These results suggest that the slow component of inward current was a Ca²⁺ channel current, whereas the fast component was a TTX-sensitive fast Na⁺ channel current. The threshold voltage, the voltage for peak current, and the reversal potential for the fast Na⁺ current were, respectively, about –50, –20, and + 50 mV in rats, and –40, 0, and + 60 mV in humans. The incidence of cells possessing fast Na⁺ currents depended on the region of the colon. In rat proximal colon, the incidence was 64% (14 out of 22 cells tested); in distal colon, it was 10% (2 out of 21 cells tested). In humans, the incidence in the ascending colon was 73% (16 out of 22 cells tested), and in the descending colon was 22% (7 out of 32 cells tested). The densities of fast Na⁺ and Ca²⁺ currents were 3.2 and 4.5 pA/pF in rats and 1.0 and 1.4 pA/pF in humans, respectively. The ratio of both current densities (Na⁺ vs Ca²⁺) was 0.71, in both rats and humans. We conclude that the major ion channels associated with the generation of inward currents in the circular smooth muscle cells of rat and human colon are voltage-dependent Ca²⁺ channels and TTX-sensitive Na⁺ channels. The fast Na⁺ current may facilitate propagation of excitation.     

Na+ currents in cultured mouse pancreatic B-cells

Pancreatic B-cells, kept in culture for 1–4 days, were studied in the whole-cell, cell-attached and outside-out modes of the patch clamp technique. B-cells were identified by the appearance of electrical activity in the cell-attached mode when the bath glucose was raised from 3 to 20 mM. In whole-cell, 80% of these cells showed a transient inward Na⁺ current, when depolarizing pulses were preceded by holding potentials, or prepulses to potentials more negative than –80 mV. The midpoint (E _h) of the inactivation curve (h ) was at –109 mV in 2.6 mM Ca²⁺, 1.2 mM Mg²⁺ and –120 mV in 0.2 mM Ca²⁺, 3.6 mM Mg²⁺. In 2.6 mM Ca²⁺, inactivation was fully removed atE<–150 mV. Na⁺ currents activated atE>–60 mV and were largest at around –10 mV (120 mM Na⁺). The kinetic parameters of activation (t _p) and inactivation ()_h were similar to those of other mammalian Na⁺ channels. Unitary currents with an amplitude of approximately 1 pA at –30 mV (140 mM Na⁺) with a similar voltage-dependence and time-course of mean current were recorded from outside-out patches. The results show that B-cells have a voltage-dependent Na⁺ current which, owing to the voltage-dependence of inactivation, is unlikely to play a major role in glucose-induced electrical activity.     

Anemonia sulcata toxins modify activation and inactivation of Na+ currents in a crayfish neurone

1. The effects of three toxins (ATX I, II, III) isolated from the sea anemoneAnemonia sulcata were studied in the soma membrane of a crustacean neurone under voltage-clamp conditions. 2. All three toxins affected the action potentials and the Na⁺ currents in a similar manner. The lowest concentrations tested (10 nM, 20 nM and 50 nM for AtX I, II and III, respectively) had pronounced selective effects on the Na⁺ current. No effect on K⁺ or Ca²⁺ currents was observed with concentrations up to 5 M. 3. In the presence of ATX the Na⁺ inactivation was incomplete even with pulses of 700 ms length or strong depolarizing prepulses. 4. Besides the effects on the inactivation process ATX affected also the activation of the Na⁺ current. 5. In cells treated with ATX the negative resistance branch of the peak Na⁺ current voltage relation was shifted by –5 mV to –20 mV. 6. The time to peak was increased for small depolarizations (up to –30 mV) and the rate of rise (I/t) was enlarged by ATX. A slow activating current component was also observed after depolarizing prepulses or if the Na⁺ current was outward. 7. The decay of the Na⁺ tail currents was considerably prolonged after the application of ATX if the membrane was repolarized to potentials more positive than about –60 mV. 8. Repetitive stimulation led to a shortening of the action potential in ATX II treated neurones. A simultaneous and parallel decrement of the peak and plateau current was observed with depolarizing voltage steps.     

Electrophysiological properties of membrane currents in single myometrial cells isolated from pregnant rats

The whole-cell voltage-clamp method was applied to single smooth muscle cells prepared from the longitudinal layer of the pregnant rat myometrium (17–20 days of gestation). It was found that the transient inward current mainly consists of Ca²⁺ current, because the removal of Ca²⁺ ions from the external medium and 10 M nifedipine eliminated this inward current. Its steady-state inactivation curve was obtained by the standard method, in which the membrane potential of half inactivation and the slope factor were estimated to be –58.0±4.9 mV (n=11) and 8.9±1.4 mV (n=11), respectively. In a small number of preparations (in 2 out of 30 preparations), there remained a very fast inward current in Ca²⁺-free medium containing Mg²⁺. Tetrodotoxin (TTX, 10 M) can abolish this current, suggesting that the channel for this current is equivalent to the Na⁺ channel in nerve cells. Two major phases of outward currents were identified by voltage jumps from negative holding levels to more positive levels. The first phase was a fast transient outward current. This current remained intact after external tetraethylammonium (TEA, 20 mM) was added. Following the transient current, a large delayed rectified outward current reached its peak over a period of 50 ms and then decayed. The reversal potential for this outward current was determined by observing the change of polarity of the tail currents with the change in extracellular K⁺ concentration ([K⁺]₀). The slope for the change of reversal potential per ten-fold change in [K⁺]₀ is 57.7 mV at more than 23.2 mM [K⁺]_o, indicating that this current is mostly carried by K⁺ ions. Voltage-dependent inactivation of the delayed rectified outward current was determined by the standard method. The membrane potential for half inactivation and the slope factor were estimated to be –42.8±3.9 mV (n=3) and 10.1±1.5 mV (n=3), respectively. External TEA (20 mM) effectively eliminated the delayed rectified outward currents. Nifedipine (10 M) suppressed not only Ca²⁺ current but also outward K⁺ currents.     

Voltage-dependent Na+ and Ca2+ currents in human pancreatic islet β-cells: evidence for roles in the generation of action potentials and insulin secretion

We describe three voltage-dependent inward currents in human pancreatic -cells. First, a rapidly inactivating Na⁺ current, blocked by tetrodotoxin (TTX) is seen upon brief depolarization to or beyond –40 mV. Second, a transient, low-voltage-activated (LVA), amiloride-blockable Ca²⁺ current is seen upon depolarization to or beyond –55 mV; it inactivates within less than 1s of sustained depolarization to –40 mV. Third, a more sustained, high-voltage-activated (HVA) Ca²⁺ current, which shows variable sensitivity to dihydropyridines is seen upon depolarization to or beyond –40 mV, and thereafter slowly inactivates over a time course of many seconds. Our pharmacological evidence suggests that all three currents contribute to action potential initiation and upstroke when the background membrane potential (V _m) is equal or negative to –45 to –40 mV, a situation often induced by glucose concentrations (5–6 mM) in the range of those seen post-prandially. Consistent with this, TTX drastically reduces both transient and sustained insulin secretion in the presence of 5–6 mM glucose, but has little effect in 10 mM glucose, at which concentration cells rapidly depolarize to –35 mV, a V _m sufficient to rapidly inactivate Na⁺ and LVA Ca²⁺ currents.     

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.     

Electrophysiological study of transport systems in isolated perfused pancreatic ducts: properties of the basolateral membrane

In order to study the mechanism of pancreatic HCO ₃ ^– transport, a perfused preparation of isolated intra-and interlobular ducts (i.d. 20–40 m) of rat pancreas was developed. Responses of the epithelium to changes in the bath ionic concentration and to addition of transport inhibitors was monitored by electrophysiological techniques. In this report some properties of the basolateral membrane of pancreatic duct cells are described. The transepithelial potential difference (PD_te) in ducts bathed in HCO ₃ ^– -free and HCO ₃ ^– -containing solution was –0.8 and –2.6 mV, respectively. The equivalent short circuit current (I_sc) under similar conditions was 26 and 50 A·cm^–2. The specific transepithelial resistance (R_te) was 88 cm². In control solutions the PD across the basolateral membrane (PD_bl) was –63±1 mV (n=314). Ouabain (3 mmol/l) depolarized PD_bl by 4.8±1.1 mV (n=6) within less than 10 s. When the bath K⁺ concentration was increased from 5 to 20 mmol/l, PD_bl depolarized by 15.9±0.9 mV (n=50). The same K⁺ concentration step had no effect on PD_bl if the ducts were exposed to Ba²⁺, a K⁺ channel blocker. Application of Ba²⁺ (1 mmol/l) alone depolarized PD_bl by 26.4±1.4 mV (n=19), while another K⁺ channel blocker TEA⁺ (50 mmol/l) depolarized PD_bl only by 7.7±2.0 mV (n=9). Addition of amiloride (1 mmol/l) to the bath caused 3–4 mV depolarization of PD_bl. Furosemide (0.1 mmol/l) and SITS (0.1 mmol/l) had no effect on PD_bl. An increase in the bath HCO ₃ ^– concentration from 0 to 25 mmol/l produced fast and sustained depolarization of PD_bl by 8.5±1.0 mV (n=149). It was investigated whether the effect of HCO ₃ ^– was due to a Na⁺⁺-dependent transport mechanism on the basolateral membrane, where the ion complex transferred into the cell would be positively charged, or whether it was due to decreased K⁺ conductance caused by lowered intracellular pH. Experiments showed that the HCO ₃ ^– effect was present even when the bath Na⁺ concentration was reduced to a nominal value of 0 mmol/l. Similarly, the HCO ₃ ^– effect remained unchanged after Ba²⁺ (5 mmol/l) was added to the bath. The results indicate that on the basolateral membrane of duct cells there is a ouabain sensitive (Na⁺+K⁺)-ATPase, a Ba²⁺ sensitive K⁺ conductance and an amiloride sensitive Na⁺/H⁺ antiport. The HCO ₃ ^– effect on PD_bl is most likely due to rheogenic anion exit across the luminal membrane.     

Electrogenic Na+/K+-transport in human endothelial cells

Na⁺/K⁺ pump currents were measured in endothelial cells from human umbilical cord vein using the whole-cell or nystatin-perforated-patch-clamp technique combined with intracellular calcium concentration ([Ca²⁺]_i) measurements with Fura-2/AM. Loading endothelial cells through the patch pipette with 40 mmol/l [Na⁺] did not induce significant changes of [Ca²⁺]_i. Superfusing the cells with K⁺-free solutions also did not significantly affect [Ca²⁺]_i. Reapplication of K⁺ after superfusion of the cells with K⁺-free solution induced an outward current at a holding potential of 0 mV. This current was nearly completely blocked by 100 mol/l dihydroouabain (DHO) and was therefore identified as a Na⁺/K⁺ pump current. During block and reactivation of the Na⁺/K⁺ pump no changes in [Ca²⁺]_i could be observed. Pump currents were blocked concentration dependently by DHO. The concentration for half-maximal inhibition was 21 mol/l. This value is larger than that reported for other tissues and the block was practically irreversible. Insulin (10–1000 U/l) did not affect the pump currents. An increase of the intracellular Na⁺ concentration ([Na⁺]_i) enhanced the amplitude of the pump current. Half-maximal activation of the pump current by [Na⁺]_i occurred at about 60 mmol/l. The concentration for half-maximal activation by extracellular K⁺ was 2.4±1.2 mmol/l, and 0.4±0.1 and 8.7±0.7 mmol/l for Tl⁺ and NH₄ ⁺ respectively. The voltage dependence of the DHO-sensitive current was obtained by applying linear voltage ramps. Its reversal potential was more negative than –150 mV. Pump currents measured with the conventional whole-cell technique were about four times smaller than pump currents recorded with the nystatin-perforated-patch method. If however 100 mol/l guanosine 5-O-(3-thiotriphosphate) (GTPS) were added to the pipette solution, the currents measured in the ruptured-whole-cell-mode were not significantly different from the currents measured with the perforated-patch technique. We suppose that the use of the perforated-patch technique prevents wash out of a guanine nucleotide-binding protein (G-protein)-connected intracellular regulator that is necessary for pump activation.     

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.     

Potassium conductance of smooth muscle cells from rabbit aorta in primary culture

Vascular smooth muscle cells were obtained from rabbit aorta and were studied in primary culture on days 1–7 after seeding with electrophysiological techniques. In impalement experiments a mean membrane potential difference (PD) of –50±0.3 mV (n=387) was obtained with Ringer-type solution in the bath. PD was depolarized by 6±0.3 mV (n=45) and 16±2 mV (n= 5) when the bath K⁺ concentration was increased from the control value of 3.6 mmol/l to 13.6 and 23.6 mmol/l, respectively. Ba²⁺ (0.1–1 mmol/l) depolarized PD. Tetraethylammonium (TEA, 10 mmol/l) depolarized PD only slightly but significantly. Verapamil (0.1 mmol/l) and charybdotoxin (10 nmol/l) had no effect on PD. The conductance properties of these cells were further examined with the patch-clamp technique. K⁺ channels were spontaneously present in cell-attached patches. When the pipette was filled with 145 mmol/l KCl, a mean conductance (g _K) of 209.6±4.6 mV (n=17) was read from the current/voltage curves at a clamp voltage (V _c) of 0 mV. After excision K⁺ channels were found in 129 patches with inside-out and in 50 with outside-out configuration. With KCl on one and NaCl on the other side the mean g _K at a V _c of 0 mV was 134.6±3.9 pS (n=179). The mean permeability was 0.89±0.03×10^–12 cm³/s. With symmetrical KCl solution the mean g _K was 227±6 pS (n=17). The conductance sequence was g _K g _Rb= g _Cs=g _Na=0. TEA blocked dose-dependently only from the outside.(1–10 mmol/l). Lidocaine (5 mmol/l) quinidine (0.01–1 mmol/l) and quinine (0.01–1 mmol/l) blocked from both sides. Charybdotoxin (0.5–5 nmol/l) blocked only from the extracellular side. Ba²⁺ blocked from the cytosolic side and the inhibition was increased by depolarization and reduced by hyperpolarization. At a V _c of 0 mV a half-maximal inhibition (IC₅₀) of 2 mol/l was obtained. Verapamil and diltiazem blocked from both sides, verapamil with an IC₅₀ of 2 mol/l and diltiazem with an IC₅₀ of 10 mol/l. The open probability of this channel was increased by Ca²⁺ on the cytosolic side at activities > 0.1 mol/l. Half-maximal activation occurred at Ca²⁺ activities exceeding 1 mol/l. The present data indicate that the vascular smooth muscle cells of rabbit aorta in primary culture possess a K⁺ conductance. In excised patches only a maxi K⁺ channel was detected. This channel has properties different from the macroscopic K⁺ conductance. Hence, it is likely that the K⁺ conductance of the intact cell is dominated by yet another and thus far not detected K⁺ channel.Supported by DFG Gr 480/10     

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.     

Ba2+ and amiloride uncover or induce a pH-sensitive and a Na+ or non-selective cation conductance in transitional cells of the inner ear

The membrane potential V _m the cytosolic pH (pH_i), the transference numbers (t) for K⁺, Cl^– and Na⁺/ non-selective cation (NSC) and the pH-sensitivity of V _m were investigated in transitional cells from the vestibular labyrinth of the gerbil. V _m, pH_i, , and the pH_i sensitivity of V _m were under control conditions were –92±1 mV (n=89 cells), pH_i 7.13±0.07 (n=11 epithelia), 0.87±0.02 (n=22), 0.02±0.01 (n=19), 0.01±0.01 (n=24) and –5 mV/pH unit (n=13 cells/n=11 epithelia), respectively. In the presence of 100 mol/l Ba²⁺ the corresponding values were: –70±1 mV (n=32), pH_i 7.16±0.08 (n=6), 0.31±0.05 (n=4), 0.06±0.01 (n=6), 0.20±0.03 (n=10) and -16 mV/pH-unit (n=15/n=6). In the presence of 500 mol/l amiloride the corresponding values were: –72±2mV (n=34), pH_i 7.00±0.07 (n=5), 0.50±0.04 (n=6), 0.04±0.01 (n=11), 0.28±0.04 (n=9) and –26 mV/pH-unit (n=20/n=5). In the presence of 20 mmol/l propionate plus amiloride the corresponding values were: –61±2 mV (n=27), pH_i 6.72±0.06 (n=5), 0.30±0.02 (n=6), 0.06±0.01 (n=5) and 0.40±0.02 (n=8), respectively. V _m was depolarized and and pH_i decreased due to (a) addition of 1 mmol/l amiloride in 150 mmol/l Na⁺ by 38±1 mV (n=8), from 0.82±0.02 to 0.17±0.02 (n=8) and by 0.13±0.01 pH unit (n=6), respectively; (b) reduction of [Na⁺] from 150 to 1.5 mmol/l by 3.3±0.5 mV (n=30), from 0.83±0.02 to 0.75±0.04 (n=9) and by 0.33±0.07 pH unit (n=4), respectively and (c) addition of 1 mmol/l amiloride in 1.5 mmol/l Na⁺ by 20±1 mV (n=11) and from 0.83±0.03 to 0.53±0.02 (n=5), respectively. These data suggest that the K⁺ conductance is directly inhibited by amiloride and Ba²⁺ and that Ba²⁺ and amiloride uncover or induce a pH-sensitive and a Na⁺/NSC conductance which may or may not be the same entity.Some of the data have been presented at various meetings and appear in abstract form in [31, 35, 37]     

Actions of growth-hormone-releasing hormone on rat pituitary cells: intracellular calcium and ionic currents

Actions of growth-hormone-releasing hormone (GHRH) on single rat anterior pituitary cells were studied using indo-1 fluorescence to monitor changes in intracellular calcium, [Ca²⁺]_i, and perforated-patch recording to measure changes in membrane potential and ionic currents. GHRH elevated [Ca²⁺]_i in non-voltage-clamped cells by a mechanism that was dependent upon extracellular Na⁺ and Ca²⁺ and was blocked by the dihydropyridine Ca²⁺-channel blocker, nitrendipine. Resting cells had a fluctuating membrane potential whose a mean value depolarized by 9 mV in response to GHRH. The membrane-permeant cAMP analogue, 8-(4-chlorophenylthio)cAMP, mimicked the action of GHRH on membrane potential. Under voltage clamping, GHRH activated a small inward current (1–5 pA). Two types of response could be distinguished. The type I response had an inward current that was largest at more negative potentials (–90 mV), and the type II response had inward current that was larger at more positive potentials (–40 to –70 mV). Both types of response were reversible and blocked by removal of extracellular Na⁺. These results suggest that the rise in [Ca²⁺]_i produced by GHRH in non-voltage-clamped cells results from the activation via cAMP of a Na⁺-dependent conductance, which depolarizes the cell and increases the Ca²⁺ influx through voltage-gated Ca²⁺ channels.Dedicated in memory of the late Alexander P. Naumov.     

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.     

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.     

Role of Na+/Ca2+ exchange in transcellular Ca2+ transport across primary cultures of rabbit kidney collecting system

Cells from connecting tubule and cortical collecting duct of rabbit kidney were isolated by immunodissection with mAb R2G9 and cultured on permeable filters. Confluent monolayers developed an amiloride-sensitive transepithelial potential difference of –50±1 mV (lumen negative) and a transepithelial resistance of 507±18 cm². Transepithelial Ca²⁺ transport increased dose-dependently with apical [Ca²⁺] and, in solutions containing 1 mM Ca²⁺, the active transcellular Ca²⁺ transport rate was 92±2 nmol h^–1 cm^–2. Transcellular Ca²⁺ transport was dependent on basolateral Na⁺ (Na _b ⁺ ). Isoosmotic substitution of Na _b ⁺ for N-methylglucamine resulted in a concentration-dependent decrease in Ca²⁺ absorption, with maximal inhibition of 67±5%. A Hill plot of the Na⁺-dependence yielded a coefficient of 1.9±0.4, indicating more than one Na⁺ site on a Na⁺-dependent Ca²⁺ transport system. In addition, the absence of Ca _b ²⁺ resulted in a significant increase in Ca²⁺ transport both in the presence and absence of Na _b ⁺ . Added basolaterally, ouabain (0.1 mM) inhibited Ca²⁺ transport to the same extent as did Na⁺-free solutions, while bepridil (0.1 mM), an inhibitor of Na⁺/Ca²⁺ exchange, reduced Ca²⁺ transport by 32±6%. Methoxyverapamil, felodipine, flunarizine and diltiazem (10 M) were without effect. Depolarisation of the basolateral membrane, by raising [K⁺]_b to 60 mM, significantly decreased transcellular Ca²⁺ transport, which is indicative of electrogenic Na⁺/Ca²⁺ exchange. In conclusion, active Ca²⁺ transport in the collecting system of rabbit kidney is largely driven by basolateral Na⁺/Ca²⁺ exchange. However, a residual Ca²⁺ absorption of about 30% was always observed, suggesting that other Ca²⁺ transport mechanisms, presumably a Ca²⁺-ATPase, participate as well.     

Single channel Ca2+ currents inHelix pomatia neurons

Unitary Ca²⁺ currents of TEA injected Helix neurons were recorded in the Giga seal situation (6, 7) from microscopic membrane patches exposed to 50 mM [Ca²⁺]_o, O [Na⁺]_o, 20 mM [TEA⁺]_o and 2.5 M [TTX]_o. Constant field assumptions yield a channel permeability of 2.9±1.0×10^–14 cm³s^–1 corresponding to slope conductances of 5 to 15 pS between 0 and –30 mV. Frequency of occurrence of the units strongly increased with depolarization. Mean open time of the Ca²⁺ channels was about 3 ms without obvious dependence on voltage. A similar open time was seen with [Ba²⁺]_o, yielding about double the current strength when compared with [Ca²⁺]_o.     

Sodium-dependent recovery of ionised magnesium concentration following magnesium load in rat heart myocytes

Our objectives were to investigate regulation of intracellular ionised Mg²⁺ concentration ([fMg²⁺]_i) in cardiac muscle and cardiac Na⁺/Mg²⁺ antiport stoichiometry. [fMg²⁺]_i was measured at 37°C in isolated rat ventricular myocytes with mag-fura-2. Superfusion of myocytes with Na⁺ and Ca²⁺ free solutions containing 30 mM Mg²⁺ for 15 min more than doubled [fMg²⁺]_i from its basal level (0.75 mM). Re-addition of Na⁺ caused [fMg²⁺]_i to fall exponentially with time to basal level, the rate increasing linearly with [Na⁺]. Log(recovery rate) increased linearly with log([Na⁺]), the slope of 1.06 (95% confidence limits, 0.94–1.17) suggesting one Na⁺ ion is exchanged for each Mg²⁺. [fMg²⁺]_i recovery was complete even if the membrane potential was depolarised to 0 mV or if superfusate [Mg²⁺] was increased to 3 mM. Recovery was rapid in normal Tyrode (0.3 min^–1) with a Q₁₀ of 2.2. It was completely inhibited by 200 M imipramine but was unaffected by 20 M KB-R7943 or 1 M SEA0400, suggesting the Na⁺ /Ca²⁺ antiporter is not involved. Membrane depolarisation by increasing superfusate [K⁺] to 70 mM, or voltage clamp to 0 mV, increased recovery rate in Na⁺ containing solutions more than threefold. We conclude [fMg²⁺]_i recovery is by Mg²⁺ efflux on a 1 Na⁺:1 Mg²⁺ antiport.     

Abnormal erythrocyte sodium leak in a subset of essential hypertensive patients

Summary We measured the ouabain- and bumetanide-resistant Na⁺ efflux in Mg²⁺-sucrose medium (passive Na⁺ leak) in erythrocytes from 30 normotensive controls and 72 essential hypertensive patients. The mean values (±SEM) of the rate constant of Na⁺ leak (k_pNa) were not significantly different between normotensives and hypertensives. Nevertheless, using the 95% confidence limits of the k_pNa (in 10^–3.h^–1) in the normotensive group as a cut-off point, 7 (9.7%) essential hypertensives exhibited increased values (58.96±10.12) when compared with the other 65 patients (23.86±0.74). revealing increased passive Na⁺ permeability in the former (leak + hypertensives). Na⁺ fluxes depending on the Na⁺-K⁺ pump, outward Na⁺-K⁺ cotransport, and Na⁺-Li⁺ countertransport were also measured in fresh erythrocytes from the same 72 patients. Three of them (4.2%) exhibited decreased values of ouabain-sensitive Na⁺ efflux and 6 (8.3%) of bumetanide-sensitive Na⁺ efflux, while 8 patients (11.1%) showed increased values of Li⁺-stimulated Na⁺ efflux and, finally, 48 patients (59.7%) did not present any evident abnormality in these Na⁺ transport systems. No differences were observed between leak + hypertensives and the remaining 65 patients when both basal erythrocyte Na⁺ content and clinical parameters of hypertension were compared. However, Na⁺ efflux depending on the outward Na⁺-K⁺ cotransport was significantly higher in the leak + hypertensive subset (299.43±43.18 vs 181.52±10.76 µmol.(l cells.h)^–1;P=0.0078), suggesting a compensatory phenomenon. Enhancement of Na⁺ permeability detected in 3% to 16% of essential hypertensives may be implicated in the pathogenesis of primary hypertension.Abbreviations ATPase adenosine triphosphatase - Dcat difference between the external Na⁺ concentration after incubation at 37° C and at zero time - k_pNa rate constant of passive Na⁺ leak - Leak + hypertensive essential hypertensive patient with abnormally high erythrocyte Na⁺ leak - MOPS 4-morpholinopropanesulfonic acid - OBR ouabain- and bumetanide-resistant - PRA plasma renin activity - sPRA plasma renin activity stimulated after furosemide infusion - SEM standard error of the mean Supported in part by Grant 87/1078 of the Fondo de Investigaciones Sanitarias de la Seguridad Social and Grant PA85/0168 of the Comisión Asesora de Investigación Científica y Técnica