Effects of electrogenic sodium pumping on the membrane potential of longitudinal smooth muscle from terminal ileum of guinea-pig

Inward rectifier potassium conductance regulates membrane potential of canine colonic smooth muscle

1. The membrane potential of gastrointestinal smooth muscles determines the open probability of ion channels involved in rhythmic electrical activity. The role of Ba2+-sensitive K+ conductances in the maintenance of membrane potential was examined in canine proximal colon circular muscle. 2. Application of Ba2+ (1-100 microM) to strips of tunica muscularis produced depolarization of cells along the submucosal surface of the circular muscle layer. Significantly higher concentrations of Ba2+ were needed to depolarize preparations from which the submucosal and myenteric pacemaker regions were removed. 3. Elevation of extracellular [K+]o (from 5.9 to 12 mM) brought membrane potentials closer to EK (the Nernst potential for K+ ions), suggesting activation of a K+ conductance. This occurred at potentials much more negative than the activation range for delayed rectifier channels (Kv). 4. Forskolin (1 microM) caused hyperpolarization and a leftward shift in the dose-response relationship for Ba2+, suggesting that forskolin may activate a Ba2+-sensitive conductance. 5. Patch-clamp recordings from interstitial cells of Cajal (ICC) revealed the presence of a Ba2+-sensitive inward rectifier potassium conductance. Far less of this conductance was present in smooth muscle cells. 6. Kir2.1 was expressed in the circular muscle layer of the canine proximal colon, duodenum, jejunum and ileum. Kir2.1 mRNA was expressed in greater abundance along the submucosal surface of the circular muscle layer in the colon. 7. These results demonstrate that ICC express a Ba2+-sensitive conductance (possibly encoded by Kir2.1). This conductance contributes to the generation and maintenance of negative membrane potentials between slow waves.

AlF4- induces Ca2+ oscillations in guinea-pig ileal smooth muscle

The effects of different compounds that inhibit the isolated plasma-membrane Ca2+/Mg2(+)-ATPase on the cytosolic free Ca2+ concentration ([Ca2+]i) and on the corresponding force development have been examined in smooth muscle of the longitudinal layer of the guinea-pig ileum. F-, in the presence of Al3+, induced an increase of the resting force and of the amplitude of the superimposed phasic contractions. The increase of resting force was associated with an increased level of basal [Ca2+]i while the phasic contractions were accompanied by concomitant oscillations in [Ca2+]i. Comparable contractions could be induced by vanadate and the calmodulin antagonist calmidazolium. The oscillations of [Ca2+]i and of force elicited by AlF4- were not modified by adrenergic or cholinergic blocking agents but were inhibited by verapamil. These phasic contractions were not affected by depleting the intracellular Ca2+ stores with ryanodine. This finding excludes a cytosolic origin of these oscillations. However, hyperpolarization and complete depolarization of the cells inhibited the oscillations. It is concluded that AlF4-, vanadate and calmidazolium induce cytoplasmic Ca2+ oscillations possibly by acting at the plasma membrane. Indeed all these substances affect by different mechanisms the isolated plasma-membrane Ca2+/Mg2(+)-ATPase. The generation of membrane-linked Ca2+ oscillations could therefore be related to an inhibition of the plasma-membrane Ca2+ pump resulting in an increase of [Ca2+]i. This change in [Ca2+]i could be responsible for the pronounced changes of the electrical and mechanical activity of this tissue.

Effects of ouabain on background and voltage-dependent currents in canine colonic myocytes

Previous studies have suggested that the membrane potential gradient across the circular muscle layer of the canine proximal colon is due to a gradient in the contribution of the Na(+)-K(+)-ATPase. Cells at the submucosal border generate approximately 35 mV of pump potential, whereas at the myenteric border the pump contributes very little to resting potential. Results from experiments in intact muscles in which the pump is blocked are somewhat difficult to interpret because of possible effects of pump inhibitors on membrane conductances. Therefore, we studied isolated colonic myocytes to test the effects of ouabain on passive membrane properties and voltage-dependent currents. Ouabain (10(-5) M) depolarized cells and decreased input resistance from 0.487 +/- 0.060 to 0.292 +/- 0.040 G omega. The decrease in resistance was attributed to an increase in K+ conductance. Studies were also performed to measure the ouabain-dependent current. At 37 degrees C, in cells dialyzed with 19 mM intracellular Na+ concentration [( Na+]i), ouabain caused an inward current averaging 71.06 +/- 7.49 pA, which was attributed to blockade of pump current. At 24 degrees C or in cells dialyzed with low [Na+]i (11 mM), ouabain caused little change in holding current. With the input resistance of colonic cells, pump current appears capable of generating at least 35 mV. Thus an electrogenic Na+ pump could contribute significantly to membrane potential.

Phorbol esters inhibit smooth muscle contractions through activation of Na(+)-K(+)-ATPase

1. The role of protein kinase C (PKC) in agonist-induced contractions of guinea-pig ileum longitudinal smooth muscle has been investigated. 2. The phorbol esters, phorbol 12,13-dibutyrate (PDBu), phorbol 12,13-diacetate (PDA) and phorbol 12-myristate 13-acetate (PMA), relaxed tissues precontracted by submaximal concentrations of carbachol, histamine or substance P. 3. This inhibitory action of the phorbol esters was reversed following the application of ouabain, a specific inhibitor of Na(+)-K(+)-ATPase. Similarly, pretreatment with ouabain inhibited the ability of phorbol esters to relax tissues precontracted by the above agonists. 4. The slow relaxation of the tonic component of contraction induced by submaximal concentrations of carbachol and histamine, and all concentrations of substance P, was abolished in the presence of ouabain. 5. In Na(+)-loaded tissues, PDBu and carbachol caused a concentration-dependent increase of Na(+)-K(+)-ATPase activity, assessed by ouabain-sensitive 86Rb(+)-uptake. Extrusion of Na+, assessed by the cellular content of the ion, was also stimulated by PDBu (the effect of carbachol was not investigated). 6. We conclude that phorbol esters inhibit the tonic component of contractions induced by submaximal concentrations of these agonists through activation of Na(+)-K(+)-ATPase. We suggest that PKC may exert feedback control over the tonic component of agonist contractions through stimulation of the pump.

Role of sodium pump in membrane potential gradient of canine proximal colon

A large gradient in membrane potential exists through the thickness of the circular layer in canine colonic muscles. This study tested the effects of several experimental manipulations known to block electrogenic sodium pumping on the resting potentials of colonic muscles. Membrane potentials were recorded with microelectrodes from cells through the circular muscle layer. In cells adjacent to the submucosal surface of the circular layer, application of ouabain (10(-6) to 10(-5) M) caused an average membrane depolarization of 36 mV. Removal of the external K+ resulted in depolarizations similar to the effect of ouabain. Readmission of K+ (5.9 mM) produced repolarization and an additional hyperpolarization that averaged 13 mV beyond the resting potential. When exposed to 15 mM K+, cells hyperpolarized well beyond the estimated potassium equilibrium potential (EK). Ouabain blocked the repolarization in response to reintroduction of external K+. Lowering the bath temperature to 20 degrees C rapidly depolarized membrane potential; rewarming repolarized cells. Ouabain and K+-free solutions blocked the repolarization response to rewarming. Cells also depolarized when exposed to solutions in which the NaCl was replaced with LiCl. Membrane potentials of cells within the bulk of the circular layer decreased as a function of distance from the submucosal border. Cells at the myenteric border of the circular muscle were not significantly affected by ouabain and K+-free solution, but these treatments abolished the gradient in membrane potential across the circular layer.(ABSTRACT TRUNCATED AT 250 WORDS)

The effect of known K+-channel blockers on the electrical activity of bovine lymphatic smooth muscle

The effects of known K+-channel blockers on the electrical properties of bovine lymphatic smooth muscle were investigated using the double sucrose-gap technique. Constant current anodal pulses elicited hyperpolarizing electrotonic potentials (EP's) which were characterised by a "sag" in the potential record. Current/voltage relationship (I/V), which were examined by measuring EP amplitude at the end of 5 s anodal pulses (less than 30 microA), showed an apparent increase in conductance with increasing hyperpolarization. In the presence of caesium (10 mM), 4-aminopyridine (10 mM) or in the absence of external K+ the sag in the EP was lost and the inward rectification characteristic of the control I/V relationship was abolished. Barium (2.5 mM) also abolished in sag in the EP although TEA (10 mM) had no effect on either EP shape or I/V relationship. Thus it would appear that lymphatic smooth muscle shows inward rectification which is slowly activating and is blocked by some of the known K+-channel blockers or by the removal of external K+.

Depolarisation of guinea-pig visceral smooth muscle causes hydrolysis of inositol phospholipids

Increasing concentrations of KCl caused a progressive stimulation of contractile activity in guinea-pig jejunal longitudinal smooth muscle strips, accompanied by increased production of [3H]inositol phosphates in smooth muscle fragments pre-labelled with myo-[3H]inositol. The concentration-response curve for contractility lay to the left of that for [3H]inositol phosphate production. Both responses showed a dependency on the presence of Ca2+ in the incubation medium. K+-induced contractility was abolished by D600 or by Mn2+, whereas stimulated [3H]inositol phosphate formation persisted in the presence of these Ca2+ channel blockers. The simultaneous addition of high KCl concentrations together with a maximal concentration of neurotransmitter (carbamylcholine of substance P) produced additive stimulation of [3H]inositol phosphate production. Enhanced production of [3H]inositol phosphates was also observed under a variety of conditions known to cause smooth muscle depolarisation, including omission from the incubation medium of Na+ or K+, and in response to ouabain or veratridine. The results suggest that inositol lipid hydrolysis in visceral longitudinal smooth muscle may be triggered by depolarisation, an event which causes the entry of Ca2+ into the cell but which is not generally believed to cause the release of stored Ca2+ within the cell. However, calcium entry seems not to be essential for the effect on inositol lipid hydrolysis.

Spectrum of altered reactivity of isolated cerebral arteries following subarachnoid haemorrhage--response to potassium, pH, noradrenaline, 5-hydroxytryptamine, and sodium loading

The circular contractile responses to various stimuli have been measured in segments of cerebral arteries (both middle cerebral and basilar) taken from dogs either 3 or 7 days following the cisternal injection of autologous blood under anaesthesia. The maximum contractile response to 5-hydroxytryptamine was increased significantly 7 days following subarachnoid haemorrhage; the response to noradrenaline also increased but not significantly at 7 days. The contractile response to a raised extracellular potassium concentration (25 and 100 mM) was slightly depressed by 7 days, and the response to a fall in extracellular pH was depressed by 43% both 3 and 7 days following subarachnoid haemorrhage. The ability of these arteries to handle a sodium load was also assessed. The arteries were sodium loaded for various periods of time in mock cerebrospinal fluid with a zero potassium concentration. On transfer to 25 mM potassium solution, the duration but not the magnitude of the initial relaxation phase prior to a final contraction was greater with increasing time spent in the zero potassium solution. Both the magnitude and the duration of this relaxation phase, which reflect in part the ability of the vascular smooth muscle to extrude the sodium load, were increased in arteries following subarachnoid haemorrhage when compared with control arteries. These results demonstrate that the altered reactivity of cerebrovascular smooth muscle following subarachnoid haemorrhage persists in vitro and is more than simply an enhanced response to biogenic amines.

Towards an estimate of chloride permeability in the smooth muscle of guinea-pig vas deferens

Cl movements across the cell membranes of smooth muscle from the guinea-pig vas deferens were measured using Cl-sensitive micro-electrodes and 36Cl fluxes. The rate constants for the loss of Cl ions measured by both methods under a variety of conditions were used to calculate the apparent Cl permeability (PCl). If it is assumed that the initial rate of decline of the intracellular Cl activity (aiCl) on removal of extracellular Cl (Clo) represents net transmembrane Cl movement, the apparent PCl was 3-6 X 10(-8) cm s-1. This value is in good agreement with those calculated from the rate constant of 36Cl efflux into both normal Krebs solution (steady-state) and Cl-free solution. Such a value for PCl predicts a large depolarization on removal of Clo, but only a minimal change was recorded. It also predicts that changes in membrane potential (Em) would affect aiCl; furthermore that removal of Clo would increase membrane resistance and thus the hyperpolarization observed on reactivation of the electrogenic Na pump. Neither of these was observed. The PCl/PK ratio obtained from changes in Em on rapid changes in Clo and Ko gives a value for PCl which is an order of magnitude lower: 4 X 10(-9) cm s-1, using Casteels' (1969 b) value for PK. These observations can be reconciled by a substantial proportion of the measured Cl movements being carrier-mediated. The presence of the stilbene derivative DIDS greatly slowed both the steady-state efflux and uptake of 36Cl, as has previously been shown for the loss and reaccumulation of Cl ions on removal and replacement of Clo. PCl calculated in the presence of DIDS was about 5 X 10(-9) cm s-1. The nominal absence of CO2 and HCO3, which slows the reaccumulation and loss of Cl, had no effect on the steady-state fluxes. This indicates that the carrier operates in the self-exchange mode in the steady state.

Effects of monensin on the response to low potassium in a molluscan muscle, the radular protractor of Busycon canaliculatum

1. A sucrose gap technique was used to study the effect of a sodium ionophore on the potential changes which occur during superfusion with potassium-free solution. Crucial values were checked with a microelectrode technique. 2. Potassium-free solution induces a complex response consisting of a hyperpolarizing phase (HP) and then a depolarization phase (DP) during exposure to zero K+, followed by a transient extra hyperpolarizing phase (EHP) on readmission of K+. 3. The sodium ionophore, monensin, has the effect of increasing the amplitude of the DP, in perfusion medium of normal Na+ content. This is similar to the effect of treatment with neurohumors and to the after-effect of direct electrical stimulation. The effects of ACh and monensin are additive. 5. These effects are consistent with an action of monensin in increasing Na+ flux in the direction of the concentration gradient and support the hypothesis that neurohumors stimulate the sodium pump by increasing Na+ influx.

Ionic basis of the resting potential of submucosal arterioles in the ileum of the guinea-pig

1. The changes in the resting membrane potential of arterioles produced by rapid and brief changes in external ionic concentrations were measured. 2. The resting membrane potential was insensitive to changes in the external concentrations of both sodium and chloride ions but sensitive to changes in the external concentration of potassium ions. 3. Increasing the external concentrations of potassium ions produced depolarizations that were well described by the Nernst equation. 4. Decreased external concentrations of potassium ions produced membrane depolarizations which appeared to result not from inhibition of an electrogenic sodium pump but rather from a change in the resting conductance of the arteriolar membrane to potassium ions. 5. Ouabain caused both membrane depolarization and an increase in membrane resistance. 6. It is suggested that at rest, arteriolar smooth muscle is permeant predominantly to potassium ions, with only small contributions from chloride and sodium ions. No evidence was obtained which would support the idea that an appreciable proportion of the resting membrane potential depended upon current flow from an electrogenic sodium pump.

Termination of transmitter release by stimulation of sodium-potassium activated ATPase

1. The release of acetylcholine (ACh) from Auerbach's plexus of guinea-pig ileum has been measured in eserinized Krebs solution using longitudinal muscle strip preparations. 2. Removal of the external K ions enhanced both the resting and stimulated release of ACh from the plexus. This effect was not affected by tetrodotoxin. 3. On readmission of K+ to tissues which had been suspended in K-free Krebs solution the release of ACh was promptly reduced in both stimulated and unstimulated tissues. The extent of the reduction of ACh release depended on the exposure time to K-free solution, the recovery being delayed by longer exposure. 4. The ACh releasing effect of (1,1-dimethyl-4-phenyl-piperazinium iodide (DMPP) was completely inhibited by the readmission of K ions to tissue which had been kept in K-free Krebs solution. 5. Rb+ substitution for K+ produced no change in ACh release and addition of 5-9 mM-Rb after K removal reduced the release of ACh as K did readmission. When the K ions were substituted by Cs+, both the resting and stimulated release were enhanced. The amount of ACh released by a stimulus was enhanced both at low and high frequency of sustained stimulation. 6. Removal of the external K ions increased the release of tritiated noradrenaline (NA), from isolated rat iris; however, when K+ (5-9 mM) was readmitted the release was reduced even below the control value. 7. It is concluded that the stimulation of (Na+-K+)-activated ATP-ase in the membrane inhibits the release of transmitter, and under physiological condition Ca-fluxes and the subsequent inhibition of membrane ATP-ase may be involved in triggering the release of transmitter.

Ouabain-sensitive ion fluxes in the smooth muscle of the guinea-pig's taenia coli

1. Tissues with raised intracellular Na levels, produced by incubation in K-free media, were used throughout. The uptake of 42K by these Na-loaded tissues was followed for 10 min in the presence and absence of 1-37 X 10(-4) M ouabain, this being sufficient to inhibit Na pumping maximally. Subtraction of the uptake seen in the presence from that seen in the absence of ouabain gave estimates of the pumped ouabain-sensitive K uptake. 2. In Na-free (MgCl2) medium this depended on the [K]0 in a sigmoidal fashion with a half maximal [K]0 for activation of some 4mM. The maximal uptake of K was 3 m-mole/kg.min corresponding to a transmembrane flux of some 12-5 p-mole. cm-2.sec-1. 3. In the presence of Na the K activation curve became more obviously sigmoid and higher concentrations of K were needed to achieve a given active K influx. The results were well fitted by assuming that Na and K competed for two identical, non-interacting sites on the external pump face. 4. Addition of K during the efflux of 24Na into a Na-free (MgCl2) medium led to an increased rate of tracer loss. The magnitude of this increase depended on the [K] used in a hyperbolic fashion and it was abolished by addition of ouabain. The [K] causing half-maximal activation of ouabain-sensitive Na efflux was in the order of 1-2 mM. 5. When the [K] in the uptake media was 1-5 mM; Na, Li, Rb and Cs all inhibited ouabain-sensitive K uptake, the order of effectiveness being Rb greater than Cs greater than Na greater than Li. With a E1TKA10 OF 0-15 MM low concentrations of Cs and Rb were shown to stimulate K uptake. Such an effect is predicted by assuming two ion binding sites on the pump's outer face, and that the pump can translocate mixtures of K and either Rb or Cs...

The effect of sodium-free and potassium-free solutions, ionic current inhibitors and ouabain on electrophysiological properties of smooth muscle of guinea-pig ureter

1. The effects of Na-free and K-free solutions, tetraethyl ammonium (TEA), Mn2+, verapamil and ouabain on the electrophysiological properties of the smooth muscle cells of guinea-pig ureter have been studied, using the double sucrose-gap method. 2. TEA (5 mM) increased the amplitude and duration of both the initial spike component and the subsequent plateau of the action potential. The repetitive spike discharge on the plateau was abolished. The amplitude and duration of the phasic contraction was increased. The threshold for excitation was lowered while the resting potential and membrane resistance were unaffected. 3. In Na-free solution the duration of the action potential decreased mainly due to the suppression of the plateau. A similar effect was produced by exposure to K-free solution and also by ouabain. 4. Mn2+ (2 mM) suppressed the spike component and raised the threshold for excitation. The amplitude of the remaining part of the action potential was markedly increased but the contraction was rapidly abolished. The resting potential and membrane resistance were unchanged. When Mn2+ was added to Na-free solution it produced an increase in the amplitude and duration of the remaining part of the action potential but the phasic contraction was abolished. 5. Verapamil did not specifically block the fast component of the action potential but initially increased the amplitude of the spike and shortened the plateau. Subsequently, both the action potential and the phasic contraction became smaller. 6. The observations indicate that the phasic contractions are triggered by the initial spike component of the action potential, whereas the plateau is associated with the amplitude and particularly the duration of the contraction.

Studies on potassium induced coronary dilation in the isolated guinea pig heart

Changes of coronary flow in the isolated perfused spontaneously beating guinea pig heart were induced by elevation of potassium concentration in the perfusion medium (4-16 meq/l). Potassium caused a dose-dependent transient increase of diastolic coronary inflow. The response was inhibited by ouabain (1.4 X 10(-7) M) or reduced temperature. Rubidium ions elicited almost identical vasodilator effects which were also inhibited by ouabain. Autoregulation of coronary flow, reactive hyperemia, and hypoxic coronary dilation were not significantly altered in the presence of ouabain. The results support the hypothesis that potassium as well as rubidium cause vasodilation by activating a Na+, K+-ATPase. On the other hand, they do not favour the view of an essential involvement of potassium ions in local regulation of coronary flow under the conditions studied.

Interaction of mono- and divalent metallic cations and of indomethacin on the membrane potential of vascular endothelial cells in vitro

1 Endothelial cells depolarized progressively when heated for 5 h at 45 degrees C in the presence of calcium (1 mM), cupric (0.08 mM) or ferrous (0.04mM) ions. In the absence of these ions, heating caused only slight depolarization. Higher concentrations of these ions caused depolarization even at normal body temperature (37 degrees C). 2 Cuprous and potassium ions, although producing depolarization at 37 degrees C, failed to augment the depolarization due to heating to 45 degrees C. 3 Hydrogen peroxide caused depolarization which was potentiated by the presence of calcium, cupric or ferrous ions, but not by the presence of cuprous or potassium ions. 4 Indomethacin (0.25 mM) reduced the depolarization caused by calcium, cupric or ferrous ions at 37 degrees C and also reduced the potentiation of heat-induced and hydrogen peroxide-induced depolarization which these divalent metallic cations produced. However, indomethacin failed to modify the depolarization caused by cuprous or potassium ions.

A study of pace-maker activity in intestinal smooth muscle

1. Electrical activity of longitudinal muscle from cat intestine was recorded in the double sucrose gap.2. Approximately 20% of the preparations demonstrated slow, spontaneous fluctuations of membrane voltage, slow waves. This activity, although quite uniform in a given preparation, showed considerable inter-preparation variation with respect to amplitude, frequency and wave form.3. Application of steady hyperpolarizing current decreased slow-wave frequency and increased slow-wave amplitude while depolarizing currents increased frequency and decreased amplitude.4. Some preparations with no spontaneous slow-wave activity developed slow waves when the membrane was hyperpolarized into a given range which, depending on the preparation, varied in size from 10 to 40 mV. Step or ramp depolarization of the membrane from hyperpolarized levels triggered slow waves in some preparations.5. When the membrane potential of a slow-wave generating preparation was clamped at the resting potential, spontaneous inward-directed current transients were observed.6. No changes in membrane conductance were observed during the course of a slow wave.7. The slow-wave pattern was simulated for individual preparations by applying the membrane current measured under voltage clamp to the passive membrane resistance and capacitance measured independently under current clamp.8. In addition to the defined slow-wave activity, voltage-dependent oscillations in membrane potential were sometimes observed.9. Application of 10(-5)M ouabain irreversibly blocked slow waves and produced a membrane depolarization equal to or slightly greater than the slow wave crest. Repolarization of the membrane to the resting potential, or hyperpolarization, failed to restore slow-wave activity.10. Removal of external potassium produced a reversible sequence of events almost identical to those following ouabain application.11. Replacement of 50% of the external sodium chloride with sucrose produced no changes in slow-wave activity with respect to rates of rise or fall, maximum amplitude or frequency. Sucrose replacement of all external sodium chloride eliminated slow waves after 5 min; however, activity could be restored by a slight hyperpolarization. Longer exposures to the modified bath abolished activity.12. Following a conditioning exposure to potassium-free Krebs solution, readmission of potassium at normal concentration produced a mean hyperpolarization of 20.5 mV and in spontaneous preparations an arrest of activity.13. Pump current in sodium-loaded, non-spontaneously active preparations was measured by voltage clamp and was observed to be voltage-dependent.14. The results of this study indicate that an electrogenic pump is present in longitudinal muscle of cat duodenum, and that oscillations in the level of pump current produce slow waves.

An estimate of sodium-potassium pump activity and the number of pump sites in the smooth muscle of the guinea-pig taenia coli, using (3H)ouabain

1. Binding of tritiated ouabain to the smooth muscle of the guinea-pig taenia coli showed two components, one saturable at lower glycoside concentrations and the other linear with increasing concentrations.2. The saturable component alone was affected by extracellular potassium concentrations. This component seems to be bound to sodium pumping sites, and when completely saturated binds 1.1 x 10(11) molecules per mg fresh wt. of tissue, or 250-300 molecules per square micron of membrane, assuming a volume:surface area ratio of 1.5 mum.3. Only a fraction of (42)K uptake by the cells can be blocked by ouabain at maximal concentrations. In normal Krebs solution two thirds can be blocked. The remaining one third is presumably passive uptake. The fraction blocked is reduced as the extracellular potassium concentration, and thus passive uptake, is increased.4. The amount of potassium pumped into the cells at various concentrations of extracellular potassium has been calculated. In normal Krebs solution the amount pumped in 45 min was 20.0 m-mole/kg fresh wt., and this was increased at higher potassium concentrations.5. On the assumption of a stoichiometry of 3Na: 2K, the pump sites in normal Krebs solution have a turnover rate of 1320 min(-1).6. Indirect calculations of sodium movements suggest that the sodium permeability may be about 0.9 x 10(-8) cm sec(-1) and the pump may generate a current of 0.9 x 10(-7) A cm(-2). This crossing an Ohmic membrane resistance of 30-60 kOmega cm(2) would be equivalent to a potential difference of 3-5 mV.

Membrane potential measurement in parotid acinar cells

1. Intracellular recording of membrane potential was made from acinar cells of the isolated mouse parotid gland superfused with physiological salt solutions.2. The mean acinar resting membrane potential was - 68.5 mV during superfusion with Krebs-Henseleit solution. Shift of the superfusion solution to one containing ACh or adrenaline (10(-5)M) always caused a transient hyperpolarization (about 10-15 mV).3. The membrane potential was mainly dependent on the extracellular K concentration ([K](o)). Increasing [K](o) tenfold decreased the membrane potential by 50 mV. This depolarization was not mediated by ACh release from depolarized nerve endings, since it was seen in the presence of atropine (1.4 x 10(-6)M) and not caused by the accompanying reduction in [Na](o) to 40 mM caused only a small depolarization (less than 10 mV).4. When the superfusion solution was shifted, during intracellular recording, from a normal Krebs-Henseleit solution ([K] = 4.7 mM) to a K-free solution, a hyperpolarization of about 8 mV was measured. Reintroduction of the normal K-containing solution after a longer period of K deprivation (30-70 min) resulted in a short-lasting pronounced hyperpolarization (about 20 mV) which could be blocked by Strophanthin-G (10(-3)M).5. In contrast to previous reports, the present findings indicate that the membrane potential of salivary acinar cells is similar, with respect to magnitude and K-dependence, to that of cells of more thoroughly investigated tissues, such as muscle and nerve, and that the membrane Na-K pump is electrogenic, at least when the cells have been loaded with Na.

The role of electrogenic sodium pumping in the response of smooth muscle to acetylcholine

1. Intracellular recording of membrane potential was made from the separated longitudinal muscle of the guinea-pig terminal ileum in physiological salt solution.2. When acetylcholine was washed from the tissue following a brief application the membrane repolarized and then hyperpolarized (;after-hyperpolarization') beyond the level existing before the application of acetylcholine.3. No after-hyperpolarization was observed following acetylcholine in potassium-free solution, in sodium-deficient (17 mM) solution, or in the presence of ouabain (1.7 x 10(-6)M). Repolarization under these conditions was delayed, especially after the membrane potential reached -20 to -30 mV, and was generally incomplete.4. The after-hyperpolarization was significantly (P < 0.01) greater when acetylcholine was applied in chloride-deficient (13 mM) solution.5. It was incidentally observed that the membrane potential in the presence of acetylcholine was more positive in potassium-free solution (significance P < 0.025), unchanged in chloride-deficient solution (P > 0.4), and much more negative in sodium-deficient (17 mM) solution (P << 0.001), confirming previous results using carbachol.6. When a 2 min application of 1.4 x 10(-6)M carbachol was made, the membrane potential 15-20 sec after beginning its application was not affected by ouabain (10(-5)M), but showed a significantly (P < 0.005) greater positive shift subsequently, so that the potential after 120 sec in carbachol was significantly (P < 0.025) more positive in the presence of ouabain. After 45 sec in 5.5 x 10(-5)M carbachol the membrane potential was also significantly (P < 0.005) more positive in the presence of ouabain (10(-5)M).7. Calculations based on hypotheses concerning the movements of sodium and potassium showed that the positive shift of the membrane potential in the presence of carbachol when sodium pumping was arrested, could be quantitatively explained by a decline in the sodium and potassium gradients across the membrane. It appeared that the electrogenic fraction of the sodium pumped was small in the presence of carbachol.8. It was concluded that the application of acetylcholine or carbachol (> 10(-6)M) to this smooth muscle disturbs the sodium and potassium gradients across the membrane. These disturbances are in a direction which stimulates electrogenic sodium pumping. Some limitation of depolarization results, and the increased electrogenic extrusion of sodium is responsible for the after-hyperpolarization which follows the application of acetylcholine.