The potassium and chloride conductance of frog muscle membrane

Elevation of extracellular osmolarity improves signs of myotonia congenita in vitro: a preclinical animal study

KEY POINTS

During myotonia congenita, reduced chloride (Cl- ) conductance results in impaired muscle relaxation and increased muscle stiffness after forceful voluntary contraction. Repetitive contraction of myotonic muscle decreases or even abolishes myotonic muscle stiffness, a phenomenon called 'warm up'. Pharmacological inhibition of low Cl- channels by anthracene-9-carboxylic acid in muscle from mice and ADR ('arrested development of righting response') muscle from mice showed a relaxation deficit under physiological conditions compared to wild-type muscle. At increased osmolarity up to 400 mosmol L-1 , the relaxation deficit of myotonic muscle almost reached that of control muscle. These effects were mediated by the cation and anion cotransporter, NKCC1, and anti-myotonic effects of hypertonicity were at least partly antagonized by the application of bumetanide.

ABSTRACT

Low chloride-conductance myotonia is caused by mutations in the skeletal muscle chloride (Cl- ) channel gene type 1 (CLCN1). Reduced Cl- conductance of the mutated channels results in impaired muscle relaxation and increased muscle stiffness after forceful voluntary contraction. Exercise decreases muscle stiffness, a phenomena called 'warm up'. To gain further insight into the patho-mechanism of impaired muscle stiffness and the warm-up phenomenon, we characterized the effects of increased osmolarity on myotonic function. Functional force and membrane potential measurements were performed on muscle specimens of ADR ('arrested development of righting response') mice (an animal model for low gCl- conductance myotonia) and pharmacologically-induced myotonia. Specimens were exposed to solutions of increasing osmolarity at the same time as force and membrane potentials were monitored. In the second set of experiments, ADR muscle and pharmacologically-induced myotonic muscle were exposed to an antagonist of NKCC1. Upon osmotic stress, ADR muscle was depolarized to a lesser extent than control wild-type muscle. High osmolarity diminished myotonia and facilitated the warm-up phenomenon as depicted by a faster muscle relaxation time (T90/10 ). Osmotic stress primarily resulted in the activation of the NKCC1. The inhibition of NKCC1 with bumetanide prevented the depolarization and reversed the anti-myotonic effect of high osmolarity. Increased osmolarity decreased signs of myotonia and facilitated the warm-up phenomenon in different in vitro models of myotonia. Activation of NKCC1 activity promotes warm-up and reduces the number of contractions required to achieve normal relaxation kinetics.

CLC Chloride Channels and Transporters: Structure, Function, Physiology, and Disease

CLC anion transporters are found in all phyla and form a gene family of eight members in mammals. Two CLC proteins, each of which completely contains an ion translocation parthway, assemble to homo- or heteromeric dimers that sometimes require accessory β-subunits for function. CLC proteins come in two flavors: anion channels and anion/proton exchangers. Structures of these two CLC protein classes are surprisingly similar. Extensive structure-function analysis identified residues involved in ion permeation, anion-proton coupling and gating and led to attractive biophysical models. In mammals, ClC-1, -2, -Ka/-Kb are plasma membrane Cl−channels, whereas ClC-3 through ClC-7 are 2Cl−/H+-exchangers in endolysosomal membranes. Biological roles of CLCs were mostly studied in mammals, but also in plants and model organisms like yeast and Caenorhabditis elegans. CLC Cl−channels have roles in the control of electrical excitability, extra- and intracellular ion homeostasis, and transepithelial transport, whereas anion/proton exchangers influence vesicular ion composition and impinge on endocytosis and lysosomal function. The surprisingly diverse roles of CLCs are highlighted by human and mouse disorders elicited by mutations in their genes. These pathologies include neurodegeneration, leukodystrophy, mental retardation, deafness, blindness, myotonia, hyperaldosteronism, renal salt loss, proteinuria, kidney stones, male infertility, and osteopetrosis. In this review, emphasis is laid on biophysical structure-function analysis and on the cell biological and organismal roles of mammalian CLCs and their role in disease.

Analysis of Spike Electrogenesis and Depolarizing K Inactivation in Electroplaques of Electrophorus electricus, L

Voltage clamp analyses, combined with pharmacological tools demonstrate the independence of reactive Na and K channels in electrically excitable membrane of eel electroplaques. Spike electrogenesis is due to Na activation and is eliminated by tetrodotoxin or mussel poison, or by substituting choline, K, Cs, or Rb for Na in the medium. The K channels remain reactive, but K activation is always absent, the electroplaques responding only with K inactivation. This is indicated by an increased resistance when the membrane is depolarized by more than about 30 mv. The resting resistance (1 to 5 ohm cm²) is dependent upon the ionic conditions, but when K inactivation occurs the resistance becomes about 10 ohm cm² in all conditions. K inactivation does not change the EMF significantly. The transition from low to high resistance may give rise to a negative-slope voltage current characteristic, and to regenerative inactivation responses under current clamp. The further demonstration that pharmacological K inactivation (by Cs or Rb) leaves Na activation and spike electrogenesis unaffected emphasizes the independence of the reactive processes and suggests different chemical compositions for the membrane structures through which they operate.

A difference in inward rectification and polyamine block and permeation between the Kir2.1 and Kir3.1/Kir3.4 K+ channels

Inward rectification is caused by voltage-dependent block of the channel pore by intracellular Mg2+ and polyamines such as spermine. In the present study, we compared inward rectification in the Kir3.1/Kir3.4 channel, which underlies the cardiac current I(K,ACh), and the Kir2.1 channel, which underlies the cardiac current I(K,1). Sustained outward current at potentials positive to the K+ reversal potential was observed through Kir3.1/Kir3.4, but not Kir2.1, demonstrating that Kir3.1/Kir3.4 exhibits weaker inward rectification than Kir2.1. We show that Kir3.1/Kir3.4 is more sensitive to extracellular spermine block than Kir2.1, and that intracellular and extracellular polyamines can permeate Kir3.1/Kir3.4, but not Kir2.1, to a limited extent. We describe a simple kinetic model in which polyamines act as permeant blockers of Kir3.1/Kir3.4, but as relatively impermeant blockers of Kir2.1. The model shows the difference in sensitivity to extracellular spermine block, as well as the difference in the extent of inward rectification between the two channels. This suggests that Kir3.1/Kir3.4 exhibits weaker inward rectification than Kir2.1 because of the difference in the balance of polyamine block and permeation of the two channels.

Mechanism of Rectification in Inward-Rectifier K+ Channels

Inward rectifiers are a class of K+ channels that can conduct much larger inward currents at membrane voltages negative to the K+ equilibrium potential than outward currents at voltages positive to it, even when K+ concentrations on both sides of the membrane are made equal. This conduction property, called inward rectification, enables inward rectifiers to perform many important physiological tasks. Rectification is not an inherent property of the channel protein itself, but reflects strong voltage dependence of channel block by intracellular cations such as Mg2+ and polyamines. This voltage dependence results primarily from the movement of K+ ions across the transmembrane electric field along the pore, which is energetically coupled to the blocker binding and unbinding. This mutual displacement mechanism between several K+ ions and a blocker explains the signature feature of inward rectifier K+ channels, namely, that at a given concentration of intracellular K+, their macroscopic conductance depends on the difference between membrane voltage and the K+ equilibrium potential rather than on membrane voltage itself.

Denervation-activated inward rectifier in frog slow skeletal muscle fibers

We tested whether the absence of an inward rectifier channel in slow skeletal muscle fibers of the frog is regulated by innervation. Normal and denervated slow fibers were identified according to their passive electrical properties. In current-clamp experiments, anomalous rectification was quantified as the ratio of effective resistances for hyperpolarizing and depolarizing pulses. In isotonic potassium solution, this ratio was 0.45 +/- 0.1 (n = 14) for twitch fibers, whereas slow fibers displayed linear behavior [ratio = 1.0 +/- 0.05 (n = 15)]. However, denervated slow fibers showed anomalous rectification (ratio, 0.48 +/- 0.07; n = 5). This finding was supported by voltage-clamp experiments in which denervated slow fibers displayed (1) an inward rectifier current during hyperpolarizing pulses, (2) an increase in this current when [K(+)](o) was increased, and (3) a current inhibition after application of Ba(2+). These results suggest that frog slow fibers, which normally do not possess inward rectifier channels, can express them after denervation.

Mechanisms for the time-dependent decay of inward currents through cloned Kir2.1 channels expressed in Xenopus oocytes

1. The decay of inward currents was characterized using the giant patch-clamp technique in the cloned inward rectifier K+ channels Kir2.1 expressed in Xenopus laevis oocytes. 2. The degree of decay was increased by strong hyperpolarization and reduced by increases in external [K+]. This voltage (membrane potential, Vm)- and K+-dependent decay is referred to as inactivation. The dissociation constant for the protective effects of external K+ ions against inactivation was about 5 mM and was not Vm dependent. 3. Internal K+ ions also showed mildly protective effects against inactivation when external K+ sites were not saturated. Results from variations in [K+] suggest that the hyperpolarization-induced inactivation of the Kir2.1 channels is not dependent on the driving force for K+ ions. 4. In the mutant which demonstrates higher external K+ affinity, the degree of inactivation was reduced. These results suggest that binding of K+ ions in the external channel pore mouth stabilizes channel opening. 5. Internal Mg2+ and polyamines induced time-dependent decay of inward currents in a dose-dependent but Vm-independent manner between -150 and -60 mV. The order of potency for Mg2+- and polyamine-induced decay was different from that for inward rectification. Furthermore, mutations with reduced inward rectification did not show parallel reduction of Mg2+- and polyamine-induced decay. These results suggest that the effects of internal Mg2+ and polyamines on Kir2.1 channels involve different binding sites. 6. This study provides evidence for Vm-dependent processes controlling the inactivation of the Kir2.1 channels.

Opposite effect of intracellular Ca2+ and protein kinase C on the expression of inwardly rectifying K+ channel 1 in mouse skeletal muscle

The level of inwardly rectifying K+ channel 1 (IRK1) mRNA decreased upon denervation and increased during muscle differentiation in mouse skeletal muscle. To identify the mechanism(s) underlying the regulation of IRK1 mRNA expression, we examined its expression using the well differentiated C2C12 mouse skeletal muscle cell line as a model system. Since nerve-induced muscle activity results in contraction, it was questioned whether the changes in IRK1 expression might be relevant to the increased intracellular calcium that functions as a cytoplasmic messenger in excitation-contraction coupling. Indeed, activation of either L-type calcium channels or ryanodine receptors increased the level of IRK1 mRNA. More directly, ionomycin activated the IRK1 expression in time- and dose-dependent manners, which was abolished by treatment with EGTA. Genistein, a tyrosine kinase inhibitor, also abolished the stimulating effect of ionomycin. Meanwhile, activation of protein kinase C by 12-O-tetradecanoylphorbol acetate (TPA) markedly decreased the level of IRK1 mRNA, which required ongoing protein synthesis. Actinomycin D experiments revealed that ionomycin increased the half-life of IRK1 mRNA from 0.86 to 1.97 h, but TPA decreased it to 0.38 h. However, neither ionomycin nor TPA appreciably altered the rate of IRK1 gene transcription. Based on these observations, we conclude that intracellular calcium and protein kinase C are oppositely involved in the muscle activity-dependent regulation of IRK1 gene expression and that both act at the level of mRNA stability.

THE INFLUENCE OF SODIUM-FREE SOLUTIONS ON THE MEMBRANE POTENTIAL OF FROG MUSCLE FIBERS

The membrane potential of frog sartorius muscle fibers in a Cl- and Na-free Ringer's solution when sucrose replaces NaCl is about the same as that in normal Ringer's solution. The K⁺ efflux is also about the same in the two solutions but muscles lose K and PO₄ in sucrose Ringer's solutions. The membrane potential in sucrose Ringer's solution is equal to that given by the Nernst equation for a K⁺ electrode, when corrections are made for the activity coefficients for K⁺ inside and outside the fiber. For a muscle in normal Ringer's solution, the measured membrane potential is within a few millivolts of E_K. This finding is incompatible with a 1:1 coupled Na-K pump. It is consistent with either no coupling of Na efflux to K influx, or a coupling ratio of 3 or greater.

EFFECTS OF EXTERNAL POTASSIUM AND STROPHANTHIDIN ON SODIUM FLUXES IN FROG STRIATED MUSCLE

Unidirectional Na fluxes in isolated fibers from the frog's semitendinosus muscle were measured in the presence of strophanthidin and increased external potassium ion concentrations. Strophanthidin at a concentration of 10^-5M inhibited about 80 per cent of the resting Na efflux without having any detectable effect on the resting Na influx. From this it is concluded that the major portion of the resting Na efflux is caused by active transport processes. External potassium concentrations from 2.5 to 7.5 mM had little effect on resting Na efflux. Above 7.5 mM and up to 15 mM external K, the Na efflux was markedly stimulated; with 15 mM K the Na influx was 250 to 300 per cent greater than normal. On the other hand, Na influx was unchanged with 15 mM K. The stimulated Na efflux with the higher concentrations was not appreciably reduced when choline or Li was substituted for external Na, but was completely inhibited by 10^-5M strophanthidin. From these findings it is concluded that the active transport of Na is stimulated by the higher concentrations of K. It is postulated that this effect on the Na "pump" is produced as a result of the depolarization of the muscle membranes and is related to the increased metabolism and heat production found under conditions of high external K.

TRACER AND NON-TRACER POTASSIUM FLUXES IN FROG SARTORIUS MUSCLE AND THE KINETICS OF NET POTASSIUM MOVEMENT

Experiments were performed to test the applicability of permeability kinetics to whole frog sartorius muscle using K⁴² ions as tracers of potassium flux. The whole muscle was found to obey closely the kinetic laws expected to hold for single cellular units in which the potassium fluxes are membrane-limited and intracellular mixing is rapid enough not to introduce serious error. In a 5 mM K Ringer's solution, potassium efflux was very nearly equal to influx when the rate constant for K⁴² loss was applied to the whole of the muscle potassium. Over a fairly wide range of external potassium concentration, the assumed unidirectional fluxes measured with tracer K⁴² showed good agreement with net potassium changes determined analytically. The specific activity of potassium lost from labeled muscles to an initially K-free Ringer's solution was measured as a test of the adequacy of intracellular mixing. The results were those expected for a population of cells with uniformly distributed intracellular K⁴². A small deviation was encountered which can be attributed either to a dispersion of fiber sizes in the sartorius or to a possible small additional cellular compartment in each individual fiber. The additional cellular compartment, should it exist, contains from 0.5 to 1 per cent of the muscle potassium. This is evidently not large enough to interfere seriously with the applicability of permeability kinetics to the whole muscle.

CAT HEART MUSCLE IN VITRO. 8. ACTIVE TRANSPORT OF SODIUM IN PAPILLARY MUSCLES

The cells of cat right ventricular papillary muscles were depleted of K and caused to accumulate Na and water by preincubation at 2-3 degrees C. The time courses of changes in cellular ion content and volume and of the resting membrane potential (V(m)) were then followed after abrupt rewarming to 27-28 degrees C. At physiological external K concentration ([K](o) = 5.32 mM) recovery of cellular ion and water contents was complete within 30 minutes, the maximal observable rates of K uptake and Na extrusion (Deltammol cell ion/(kg dry weight) (min.)) being 3.4 and 3.6, respectively. The recovery rate was markedly slowed at [K](o) = 1.0 mM. Rewarming caused V(m) measured in cells at the muscle surface to recover within from <1 to 9 minutes, but only slight restoration of cellular ion contents (measured in whole muscles) had occurred after 10 minutes. Studies of recovery in NaCl-free sucrose Ringer's solution made it possible to separate the ouabain-insensitive outward diffusion of Na as a salt from a simultaneous ouabain-sensitive Na extrusion which is associated with a net cellular K uptake. A hypothesis consistent with these observations is that rewarming may activate a ouabain-sensitive "electrogenic" mechanism, most probably the net active transport of Na out of the cell, from which net K uptake may then follow passively.

EVIDENCE FOR ANION-PERMSELECTIVE MEMBRANE IN CRAYFISH MUSCLE FIBERS AND ITS POSSIBLE ROLE IN EXCITATION-CONTRACTION COUPLING

Under certain conditions only, isolated crayfish skeletal muscle fibers change in appearance, becoming grainy, darkening, and seemingly losing their striations. These changes result from development of large vesicles on both sides of the Z-line. The longitudinal sarcoplasmic reticulum remains unaffected. The vesicles are due to swelling of a transverse tubular system (TTS) which is presumably homologous with the T-system tubules of other muscle fibers. The vesiculations occur during efflux of water or on reducing external K or Cl, but only when KCl can leave the fiber. They never result from osmotic, ionic, or electrical changes when KCl cannot leave. Inward currents, applied through a KCl-filled intracellular cathode, also cause the vesiculations. These are not produced when the cathode is filled with K-propionate, nor by outward or longitudinal currents. Thus the transverse tubules swell only when Cl leaves the cell. Accordingly, their membrane is largely or exclusively anion-permselective. These findings also indicate that the TTS forms part of a current loop, connecting with the exterior of the fiber probably through radial tubules (RT) possessing membrane of low conductivity. Thus, part of the current flowing inward across the sarcolemma during activity can return to the exterior through the membrane of the TTS. The structure and properties of the latter offer the possibility for an efficient electrical mechanism to initiate excitation-contraction coupling.

A gap isolation method to investigate electrical and mechanical properties of fully contracting skeletal muscle fibers

We describe here a single-gap isolation method that allows the simultaneous measurement of electrical activity and tension output from fully contracting segments of frog skeletal muscle fibers. By using single pulses and pulse trains of varying frequency (5-100 Hz), records obtained for both electrical and mechanical fiber response demonstrate that the physiological properties of the fiber segments have been preserved. Action potentials could be recorded free of movement artifacts, even while segments were in fused tetani and developing maximum tensions of more than 600 kN/m2. Single current pulses evoked action potentials that averaged 144 +/- 16 mV (mean +/- SD, n = 8) in amplitude and twitches that averaged 285 +/- 66 kN/m2 and 55 +/- 5 ms (mean +/- SD, n = 20) in magnitude and time to peak, respectively. Trains of action potentials elicited patterns of tension development that exhibited summation, unfused tetani, and fused tetani in a frequency-dependent manner. The AC and DC electrical properties of the single grease gap were modeled with a simple Thévenin equivalent circuit, which satisfactorily predicted the experimental results. Our methodology is easily implemented and potentially applicable to any muscle preparation in which fiber segments with an intact end attached to a piece of tendon can be dissected.

The effects of chloride ions in excitation-contraction coupling and sarcoplasmic reticulum calcium release in twitch muscle fibre

Using the sucrose vaseline gap technique, experiments were carried out on isolated frog twitch muscle fibre to investigate the role of chloride ions in excitation-contraction coupling. In current clamp conditions, replacement of chloride ions by impermeant anions led to an increase of the amplitude of the early after potential and of the amplitude of the twitch. Addition of a chloride channel blocker, anthracene-9-carboxylic acid gave similar results. In voltage clamp conditions, replacement of chloride ions by impermeant anions induced a decrease of the outward current and an increase of both the amplitude of the contraction and of the resting tension. Addition of anthracene-9-carboxylic acid gave similar results except that resting tension was not modified. Replacement of chloride ions by impermeant anions resulted in a shift of the tension-voltage relationship toward negative potentials and in an increase of the amplitude of the contraction at all potentials. Outward currents were also reduced at all potentials but no shift of the current-voltage relationship was observed. Similar results were obtained upon addition of anthracene-9-carboxylic acid. Rapid filtration experiments were performed on isolated sarcoplasmic reticulum vesicles to study the role of chloride ions in Ca2+ release. Under conditions where KCl was present in the intra- and extravesicular media, removal of chloride ions from the release solution produced a 2-fold increase in the rate of Ca(2+)-induced Ca2+ release. Together, these results suggest that, besides their involvement in the action potential time course, chloride ions could exert a negative control on the sarcoplasmic reticulum Ca2+ release.(ABSTRACT TRUNCATED AT 250 WORDS)

Frog striated muscle is permeable to hydroxide and buffer anions

Hydroxide, bicarbonate and buffer anion permeabilities in semitendinosus muscle fibers of Rana pipiens were measured. In all experiments, the fibers were initially equilibrated in isotonic, high K2SO4 solutions at pHo = 7.2 buffered with phosphate. Two different methods were used to estimate permeabilities: (i) membrane potential changes were recorded in response to changes in external ion concentrations, and (ii) intracellular pH changes were recorded in response to changes in external concentrations of ions that alter intracellular pH. Constant field equations were used to calculate relative or absolute permeabilities. In the first method, to increase the size of the membrane potential change produced by a sudden change in anion entry, external K+ was replaced by Cs+ prior to changes of the anion under study. At constant external Cs+ activity, a hyperpolarization results from increasing external pH from 7.2 to 10.0 or higher, using either CAPS (3-[cyclohexylamino]-1-propanesulfonic acid) or CHES (2-[N-cyclohexylamino]-ethanesulfonic acid) as buffer. For each buffer, the protonated form is a zwitterion of zero net charge and the nonprotonated form is an anion. Using reported values of H+ permeability, calculations show that the reduction in [H+]o cannot account for the hyperpolarizations produced by alkaline solutions. Membrane hyperpolarization increases with increasing total external buffer concentration at constant external pH, and with increasing external pH at constant external buffer anion concentration. Taken together, these observations indicate that both OH- and buffer anions permeate the surface membrane. The following relative permeabilities were obtained at pHo = 10.0 +/- 0.3: (POH/PK) = 890 +/- 150, (PCAPS/PK) = 12 +/- 2, (PCHES/PK) = 5.3 +/- 0.9, and (PNO3/PK) = 4.7 +/- 0.5. PNO3/PK was independent of pHo up to 10.75. At pHo = 9.6, (PHCO3/PK) = 0.49 +/- 0.03; at pHo = 8.9, (PCl/PK) = 18 +/- 2 and at pHo = 7.1, (PHEPES/PK) = 20 +/- 2. In the second method, on increasing external pH from 7.2 to 10.0, using 2.5 mM CAPS (total buffer concentration), the internal pH increases linearly with time over the next 10 min. This alkalinization is due to the entry of OH- and the absorption of internal H+ by entering CAPS- anion. The rate of CAPS- entry was determined in experiments in which the external CAPS concentration was increased at constant external pH. Such increases invariably produced an increase in the rate of internal alkalinization, which was reversed when the CAPS concentration was reduced to its initial value.(ABSTRACT TRUNCATED AT 400 WORDS)

Conductances contributing to the action potential of Sternopygus electrocytes

In Sternopygus macrurus, electrocyte action potential duration determines the electric organ discharge pulse duration. Since the electric organ discharge is a sexually-dimorphic behavior under the control of steroid hormones, and because electrocyte action potential durations can range from 3-14 ms, the electrocytes provide a unique opportunity to study how sex steroids regulate membrane excitability. In this study, the voltage-sensitive ionic currents of electrocytes were identified under current- and voltage-clamp as a prelude to further studies on their regulation by sex steroid hormones. Bath application of TTX completely abolished the spike and eliminated an inward current under voltage clamp, indicating that the action potential is due primarily to a sodium current. Calcium-free saline had no effect on spike waveform or voltage-clamp currents, indicating that neither calcium nor calcium-dependent currents contribute to the action potential. Application of potassium channel blocking agents, such as tetraethylammonium and cesium ions, caused changes in the spike which, together with voltage-clamp results, indicate the presence of two potassium currents: an inward rectifier and a classical delayed rectifier. In addition, these cells have a large, presumably voltage-insensitive, chloride current. Differences in one or more of these currents could be responsible for the range of action potential durations found in these cells and for the steroid-mediated changes in spike duration.

Respiratory muscles in endocrinopathies

The aim of this review was to demonstrate that RM function is altered in various endocrinopathies and that RM weakness is a common finding. RM function has been well-studied in diseases such as thyroid dysfunction, and steroid induced RM myopathies. Less well documented reports on RM function were found in parathyroid dysfunctions, disorders of mineralocorticoids and pituitary disturbances. Controversial reports were found in diabetes mellitus. No report was found connecting RM function with androgens, pheochromocytoma or adrenaline deficiency in humans. These diseases could potentially cause RM impairment leading to severe respiratory failure (pump failure) putting life in great danger. Therefore, it is obvious that further studies are needed to investigate the performance of RMs in endocrinopathies. Such studies are extremely urgent in Cushing's and Addison's disease, acromegaly, disorders of the adrenal medulla, and in diabetes insipidus.

Voltage-dependent K+ currents in guinea pig Müller (glia) cells show different sensitivities to blockade by Ba2+

The effect of externally applied Ba2+ and Na+ on K+ currents was investigated by means of whole-cell patch-clamp in isolated and in situ Müller cells from guinea pig retina. Müller cells express a typical set of K+ currents, i.e. an ohmic current, an inactivating inward current (IK(IR)), a delayed rectifier (IK(DR)) and an inactivating outward current (IK(A)). Inactivation of the inward current did not occur when extracellular Na+ was replaced by choline. When administered in increasing concentrations, Ba2+ blocked these K+ currents in a typical sequence: the ohmic current and IK(A) were most sensitive, followed by IK(IR), whereas IK(DR) was not completely blocked even in 1 mM Ba2+. The differential sensitivity of Müller cell K+ currents to external Ba2+ may be a tool which can be used to improve our understanding of the Müller cell response to physiological stimulation of the retina.

Developmental sequence of expression of voltage-dependent currents in embryonic Xenopus laevis myocytes

Although the development of several of the voltage-dependent currents in embryonic amphibian myocytes has been described, the overall muscle electrical development, particularly the relative times of expression of different voltage-dependent currents, has not been addressed in a single study under one set of conditions. We have found that, in mesoderm isolated and cultured from neurula stage embryos, myocytes are identifiable before they express voltage-gated currents. These ionic currents are absent from all Xenopus mesodermal cells during the late gastrula/early neurula stages of embryonic development. At about the time of first somite segregation an inward rectifier K+ current is expressed in some myocytes, followed within 2 hr by a delayed rectifier K+ current. The density of both currents increases fourfold over the next 24 hr in culture. A Na+ current is not expressed in large numbers of myocytes until late in this culture period, at about the time that a slow Ca2+ current appears. Under our culture conditions the myocytes have a very low chloride conductance. A fast inactivating component to the outward K+ current is expressed in all myocytes by 24 hr in culture. In some experiments we dissociated embryos at later times and made recordings when all previously isolated myocytes expressed currents. In the late dissociations, most myocytes did not express currents, but developed them after a short period in culture. Because we have evidence that in vivo development is more closely approximated by the early dissociations, these results suggest that dissociation causes some degree of dedifferentiation.

REPETITIVE ELECTRICAL ACTIVITY OF THE MUSCLE MEMBRANE INDUCED IN CHLORIDE-FREE MEDIUM

1. Superficial fibres of frog skeletal muscle were electrically stimulated in Ringer solution where the chloride content had been replaced by various weakly permeant anions. Changes of the membrane potential were recorded at three different time scales. The complex response was initiated by a volley of fast repetitive action potentials (10-20 ms cycle length) superimposed on the ascending phase of a transient depolarization to -35 mV. The transient depolarization was followed by a membrane potential oscillation (0.3-0.6 s cycle length). The parameters of the volley and membrane potential oscillation were not greatly affected by the substituent anion. 2. The transient depolarization was fully abolished by tetrodotoxin (3 mumol/L), but left unaffected by nifedipine (5 mumol/L), or by the replacement of extracellular Ca for Ni or Co. Tetraethylammonium (20-40 mmol/L) increased the duration and amplitude of the transient depolarization. The shape of transient depolarization was uniform in a given fibre, in spite of its marked variability under different experimental conditions. 3. Single outward current pulses applied in chloride-free solution containing tetraethylammonium (20-40 mmol/L) evoked prolonged depolarizations to positive membrane potentials accompanied by increases in the specific membrane conductance. This slow response, which was also frequently observed in the absence of TEA, was mediated by Ca ions, as it was insensitive to tetrodotoxin (3 mumol/L) but abolished by nifedipine (10 mumol/L). 4. Two populations of the muscle fibres were observed during the slow response. Some fibres repolarized completely, while others failed to produce complete repolarization but formed a plateau between -20 and -30 mV, lasting for several minutes. When the external K concentration was abruptly increased to 5 or 10 mmol/L during the plateau of the slow response, repolarization and increase in membrane conductance were observed. 5. In muscle fibres, having osmotically disrupted T-system, the duration of transient depolarization was in the range of minutes, in contrast to the range of seconds observed in intact fibres. The volley was preserved in glycerol treated fibres, however, the baseline of discharges was close to the resting potential and the rate of depolarization of the baseline was significantly less in glycerol treated than in intact fibres. 6. These results are consistent with the existence of a second stable membrane potential level in skeletal muscle between -40 and -30 mV. The depolarization and repolarization during the membrane potential oscillation and transient depolarization can be regarded as a partial or full transition, respectively, between these two stable membrane potential levels, possibly due to the conductance changes of the inward rectifier K channels.(ABSTRACT TRUNCATED AT 400 WORDS)

Voltage-dependent K+ channels in the sarcolemma of mouse skeletal muscle

The voltage-dependent K+ channels of the mammalian sarcolemma were studied with the patch-clamp technique in intact, enzymatically dissociated fibres from the toe muscle of the mouse. With a physiological solution (containing 2.5 mM K+) in the pipette, depolarizing pulses imposed on a cell-attached membrane patch activated K+ channels with a conductance of about 17 pS. No channel activity was observed when the pipette solution contained 2 mM tetraethylammonium (TEA), or 2 mM 4-aminopyridine (4-AP). Whole cell recordings from these very small muscle fibres showed the well-known delayed rectifier K+ outward current with a threshold of about -40 mV. The whole-cell current was completely blocked by 2 mM TEA in the bath, suggesting that the TEA-sensitive channels in the patch were also delayed rectifier channels. The inactivation properties of the channels were studied in the cell-attached mode. Averaged single-channel traces showed at least two types of channels discernible by their inactivation time course at a test potential of 60 mV. The fast type inactivated with a time constant of about 150 ms, the slow type with a time constant of about 400 ms. A little channel activity always remained during pulses lasting several minutes, indicating either the presence of a very slowly inactivating third type of K+ channel, or the tendency of the fast inactivating channels to re-open at constant voltage. No difference was seen in the single-channel amplitudes of the different types of K+ channels. The well characterized adenosine-5'-triphosphate-(ATP)-sensitive and Ca(2+)-dependent K+ channels, although present, were not active under the conditions used.(ABSTRACT TRUNCATED AT 250 WORDS)

Postnatal induction and neural regulation of inward rectifiers in mouse skeletal muscle

The whole-cell voltage-clamp technique was used to examine developmental changes of inward rectifier currents in fibres of the flexor digitorum brevis muscle acutely isolated from mice on postnatal day 0 (P0) to P36. Neither a steady-state component (Is-s) nor a slowly activated component (Irise) of inward rectifier currents were observed in fibres of P0 and P4 mice. Both Is-s and Irise became apparent between days P8 and P16. The specific amplitudes of Is-s and Irise measured at a test-pulse potential of -100 mV at 20 mM extracellular K+ [( K+]o) increased to their respective platcau values of -68 +/- 10 and -15 +/- 7 microA/cm2 at P20. In fibres denervated on day P4 the developmental increase of Is-s was suppressed, its specific amplitude at P20 being one-tenth of that in the corresponding normal fibres. Irise did not appear in P4-denervated fibres throughout the development. In muscle fibres denervated at P16 or P20, the specific amplitudes of Is-s and Irise decreased, reaching the levels of P4-denervated fibres in 2-4 days after denervation. We conclude that Is-s and Irise develop within 3 weeks after birth, and suggest that innervation plays a key role in their induction.

Characterization of ion channels on the surface membrane of adult rat skeletal muscle

The channels present on the surface membrane of isolated rat flexor digitorum brevis muscle fibers were surveyed using the patch clamp technique. 85 out of 139 fibers had a novel channel which excluded the anions chloride, sulfate, and isethionate with a permeability ratio of chloride to sodium of less than 0.05. The selectivity sequence for cations was Na+ = K+ = Cs+ greater than Ca++ = Mg++ greater than N-Methyl-D-Glucamine. The channel remained closed for long periods, and had a large conductance of approximately 320 pS with several subconductance states at approximately 34 pS levels. Channel activity was not voltage dependent and the reversal potential for cations in muscle fibers of approximately 0 mV results in the channel's behaving as a physiological leakage conductance. Voltage activated potassium channels were present in 65 of the cell attached patches and had conductances of mostly 6, 12, and 25 pS. The voltage sensitivity of the potassium channels was consistent with that of the delayed rectifier current. Only three patches contained chloride channels. The scarcity of chloride channels despite the known high chloride conductance of skeletal muscle suggests that most of the chloride channels must be located in the transverse tubular system.

Characterization of ion channels seen in subconfluent human dermal fibroblasts

1. Ion channels expressed in human dermal fibroblasts are characterized using the patch-clamp technique. 2. A number of different ion channels were found but their expression occurred at various frequencies. The most commonly found phenotype was the expression of voltage-gated K+ current. This 'typical' K+ current was seen in about 60% of the cells recorded. 3. Subtypes of voltage-gated K+ channels could be discerned by differences in gating kinetics. One has fast inactivation and resembles the 'A' K+ current. Additional subtypes were sometimes discerned based on activation kinetics. 4. The large-conductance Ca(2+)-activated K+ channel (maxi-K+) could be found in nearly every cell but required large depolarizations to activate using the standard Ca(2+)-buffered pipette solution (10(-8) M [Ca2+]i). 5. Inward rectifier K+ channels were seen in a low percentage of cells. The inward rectifier K+ current was sensitive to 'wash-out' if guanosine 5'-O-(3-thiotriphosphate) (GTP gamma S) was included in the pipette solution dialysing the cell. 6. Tetrodotoxin (TTX)-sensitive voltage-gated Na+ channels were seen but in a lower number of cells recorded, about 20%. Evidence for subtypes of Na+ channels were sometimes seen based on differences in gating kinetics. 7. An ATP-dependent osmotically activated Cl- current was also found. This current showed some outward rectification but was otherwise voltage independent. 8. In addition, a cell-to-cell contact-associated K+ current was described. This current was linear over the voltage ranges used and whose gating correlated with the existence of gap junctions. 9. These currents were characterized to determine the baseline behaviour of unstimulated cells and to compare to bradykinin-stimulated cells described in the following paper. As unexcitable cells, human dermal fibroblasts are capable of expressing a surprising diversity of ion channel phenotypes and of ion channel modulations.

Modulation of inwardly rectifying channels by substance P in cholinergic neurones from rat brain in culture

1. Whole-cell recording was used to investigate the effects of substance P on cultured neurones from the rat nucleus basalis. 2. Brief applications of substance P produced a reduction, about 1 min in duration, of resting membrane conductance. The concentration producing a half-maximal effect was approximately 40 nM, with the continuous presence of substance P resulting in desensitization of the response. 3. The control current-voltage relation exhibited inward rectification over the voltage range -70 to -150 mV, and hyperpolarization produced a time-dependent decrease of current (inactivation). 4. The substance P-sensitive current, obtained by subtracting the current during the presence of the tachykinin from the control current, showed no time-dependent inactivation, though its current-voltage relation also revealed inward rectification, with the reversal potential being approximately equal to the potassium equilibrium potential, Vk. 5. The relation between the substance P-sensitive chord conductance and voltage could be fitted by a Boltzmann equation, with changes in [K+]o shifting this relation along the voltage axis roughly in parallel with the shift in Vk. The maximum conductance was proportional to [( K+]o). 6. Cs+ (0.1 mM) blocked the substance P-sensitive current in a voltage-dependent manner, with an equivalent valency for Cs+ of 1.9. Barium blockage of the substance P-sensitive current was less voltage dependent. 7. Replacement of external Na+ by tetramethylammonium (TMA+) ions reduced the substance P-sensitive current by only 18%. 8. These results indicate that substance P inhibits potassium channels with inward rectifier properties very similar to those of skeletal muscle. 9. Application of sodium nitroprusside did not alter the effect of substance P, suggesting that cyclic GMP plays no role in the channel modulation.

Optical evidence for a chloride conductance in the T-system of frog skeletal muscle

T-system action potentials were recorded optically from intact frog skeletal muscle fibers stained with the non-penetrating potentiometric dye NK-2367. The effect of chloride removal on the falling phase of the radially propagating tubular action potential was studied to determine whether a chloride conductance located in the T-system membranes contributes to tubular repolarization during activity. Our results show that, in chloride-free Ringer, repolarization of the tubular action potential is significantly slowed. Moreover, the late phase of tubular repolarization is characterized by a large after-potential, which is highly temperature-dependent and appears as a secondary peak above 10 degrees C. The optical data were compared with predicted T-system action potentials generated from a radial cable equivalent circuit model of the T-system, in which the effects of a distributed tubular leak conductance were tested. Results of this analysis are consistent with the proposal that some of the outward repolarization current during the T-system action potential is drawn across a chloride conductance located in the T-system membranes.

Nitrate and chloride ions have different permeation pathways in skeletal muscle fibers of Rana pipiens

The effects of pH on the permeability and conductance of the membranes to nitrate and to chloride of semitendinosus and lumbricalis muscle fibers were examined. Membrane potential responses to quick solution changes were recorded in semitendinosus fibers initially equilibrated in isotonic, high K2SO4 solutions. External solutions were first changed to ones in which either Rb+ or Cs+ replaced K+ and then to solutions containing either NO3- or Cl- to replace SO4(2-). The hyperpolarizations produced by Cl- depend on external pH, being smaller in acid than in alkaline solutions. By contrast, hyperpolarizations produced by NO3- were independent of external pH over a pH range from 5.5 to 9.0. In addition, voltage-clamp measurements were made on short lumbricalis muscle fibers. Initially they were equilibrated in isotonic solutions containing mainly K2SO4 plus Na2SO4. KCl or KNO3 were added to the sulfate solutions and the fibers were equilibrated in these new solutions. When finally equilibrated the fibers had the same volume they had in the sulfate solutions before the additions. Constant hyperpolarizing voltage pulses of 0.6-sec duration were applied when all external K+ was replaced by TEA+. For these conditions, inward currents flowing during the voltage pulses were largely carried by Cl- or NO3- depending on the final equilibrating solution. Cl- currents during voltage pulses were both external pH and time dependent. By contrast, NO3- currents were independent of both external pH and time. The voltage dependence of NO3- currents could be fit by constant field equations with a PNO3 of 3.7.10(-6) cm/sec. The voltage dependence of the initial or "instantaneous" Cl- currents at pH 7.5 and 9.0 could also be fit by constant field equations with PCl of 5.8 x 10(-6) and 7.9 x 10(-6) cm/sec, respectively. At pH 5.0, no measurable "instantaneous" Cl- currents were found. From these results we conclude that NO3- does not pass through the pH, time-dependent Cl- channels but rather passes through a distinct set of channels. Furthermore, Cl- ions do not appear to pass through the channels which allow NO3- through. Consequently, the measured ratio of PCl/PNO3 based on membrane potential changes to ionic changes made on intact skeletal muscle fibres is not a measure of the selectivity of a single anion channel but rather is a measure of the relative amounts of different channel types.(ABSTRACT TRUNCATED AT 400 WORDS)

Studies on cadmium-induced myotonia in the mouse diaphragm

The purpose of this investigation was to study the possible mechanism of the potentiation of the contractile response and myotonia caused by Cd2+ in the mouse diaphragm. Cd2+ increased both amplitude and duration of the contractile response to direct stimulation in either 0.25 mM Ca2+ Krebs or 2.5 mM Ca2+ Krebs containing the K+-channel blockers, 4-aminopyridine, uranyl nitrate or tetraethylammonium ion. High K+ and tetrodotoxin inhibited these effects of Cd2+. Electrophysiological studies revealed that only one or two action potentials were triggered by passing a short depolarizing current across the muscle fibre membrane in 0.25 mM Ca2+ Krebs, but in the presence of Cd2+, a train of action potentials (153 +/- 21 Hz) which lasted for 0.7 +/- 0.2 s was induced. Furthermore, Cd2+ triggered a train of action potentials evoked by a single extracellular direct stimulation on the muscle fibre in 2.5 mM Ca2+ Krebs solution containing either 4-aminopyridine or uranyl nitrate. The membrane depolarized during the repetitive firing and then repolarized immediately after the cessation of repetitive firing. Cd2+ (0.1 mM) increased the input resistance of the muscle fibre by 53 +/- 7% and this effect was inhibited in low [Cl-]o. These findings suggest that the contractile potentiation and myotonia induced by Cd2+ in the mouse diaphragm are mediated by lowering the Cl- conductance of the membrane.

Single inwardly rectifying potassium channels in cultured muscle cells from rat and mouse

1. Inward unitary currents through inwardly rectifying K+ channels of myotubes derived from newborn rats or from a murine, clonal myoblast cell line were studied in the cell-attached configuration. Open-closed transitions of the channel were observed in the absence of blocking ions. 2. The single-channel conductance was 26.3 +/- 2.9 pS (mean + S.D., n = 14) with 150 mM-K+ pipette solution at room temperature (19-22 degrees C). The channel showed substates of conductance in addition to the main conductance state. A channel with a smaller conductance (8.9 +/- 2.6 pS, n = 4) was also but less frequently observed. 3. The probability of the channel being open is weakly voltage dependent: it decreased from 0.94 to 0.84 as the membrane was hyperpolarized from the resting potential (RP) + 20 mV to RP - 50 mV. 4. The lifetimes of the openings were distributed according to a single exponential. At least three exponentials were required to fit the frequency histogram of the lifetimes of all closed states. The mean open time showed a weak voltage dependence, while the mean closed times had little voltage dependence. 5. In the presence of external Na+, the open probability decreased from 0.89 to 0.43 and the mean open time decreased from 203 to 28 ms (40 mM-K+, 200 mM-Na+ pipette solution) when the patch membrane was hyperpolarized from RP - 40 mV to RP - 110 mV. The mean closed times were not different from those with 150 mM-K+, Na+-free pipette solution and showed little voltage dependence. 6. It is suggested that inactivation of the macroscopic inward currents during hyperpolarization results mainly from a voltage-dependent block by Na+ with relatively slow kinetics.

Inward rectifier produced by Xenopus oocytes injected with mRNA extracted from carp olfactory epithelium

Ionic channels encoded by mRNA extracted from carp olfactory epithelium were investigated by injection into Xenopus laevis oocytes. The oocytes expressed an inward rectifier K+ -channel, as detected under two-electrode voltage clamp conditions. The results were as follows. An inactivating inward current appeared on hyperpolarization and increased with increasing extracellular K+ concentrations. The 0 current potentials plotted as a function of log [K+]0 in the range between 2 to 20 mMK+ fell on a straight line, with a slope of 58 mV per tenfold change in K+ concentration, indicating that the current carrier is K+. Chord conductances reached saturation levels on extreme hyperpolarization. The chord conductances at the saturation levels were 35.7, 22.5, and 13.4 muSec in 20, 10, and 5 mM extracellular K+, respectively. Extracellular application of 0.1 mM Cs+ or 0.1 mM Ba2+ blocked the inward current in 2 mM K+, whereas 1 microM TTX or 0.3 mM Cd2+ did not affect the inward current. Inactivation of the inward currents, which became clear on extreme hyperpolarization, was suppressed with decreasing extracellular Na+ concentration. The present results suggest that carp olfactory epithelium is rich in the inward rectifier and is an excellent source of mRNA for cloning cDNA coding the inward rectifier.

Inward rectifier K+-channel kinetics from analysis of the complex conductance of Aplysia neuronal membrane

Conduction in inward rectifier, K+-channels in Aplysia neuron and Ba++ blockade of these channels were studied by rapid measurement of the membrane complex admittance in the frequency range 0.05 to 200 Hz during voltage clamps to membrane potentials in the range -90 to -40 mV. Complex ionic conductances of K+ and Cl- rectifiers were extracted from complex admittances of other membrane conduction processes and capacitance by vector subtraction of the membrane complex admittance during suppressed inward K+ current (near zero-mean current and in zero [K+]0) from complex admittances determined at other [K+]0 and membrane potentials. The contribution of the K+ rectifier to the admittance is distinguishable in the frequency domain above 1 Hz from the contribution of the Cl- rectifier, which is only apparent at frequencies less than 0.1 Hz. The voltage dependence (-90 to -40 mV) of the chord conductance (0.2 to 0.05 microS) and the relaxation time (4-8 ms) of K+ rectifier channels at [K+]0 = 40 mM were determined by curve fits of admittance data by a membrane admittance model based on the linearized Hodgkin-Huxley equations. The conductance of inward rectifier, K+ channels at a membrane potential of -80 mV had a square-root dependence on external K+ concentration, and the relaxation time increased from 2 to 7.5 ms for [K+]0 = 20 and 100 mM, respectively. The complex conductance of the inward K+ rectifier, affected by Ba++, was obtained by complex vector subtraction of the membrane admittance during blockage of inward rectifier, K+ channels (at -35 mV and [Ba++]0 = 5 mM) from admittances determined at -80 mV and at other Ba++ concentrations. The relaxation time of the blockade process decreased with increases in Ba++ concentration. An open-closed channel state model produces the inductive-like kinetic behavior in the complex conductance of inward rectifier, K+ channels and the addition of a blocked channel state accounts for the capacitive-like kinetic behavior of the Ba++ blockade process.

The effects of space charge on the ionic currents through biological membranes

In this paper, the ions moving through an ion-selective membrane are regarded as a space charge. The repulsive action among the ions attenuates the ion current through the membrane. For a quantitative description of this effect on the relation between the ion current, the ion concentrations and the membrane voltage, the usual assumption of a constant electric field within the membrane is replaced by that of an inconstant field influenced by the moving ions. This can be done either by inserting the Poisson equation into the Nernst-Planck equation or by directly calculating the Coulomb forces, e.g. between two ions moving through a narrow channel. An attenuation factor is defined and its dependence on membrane thickness, dielectric number, membrane voltage, and ion concentrations is exactly calculated; its dependence on the cross section of an assumed channel is necessary for the current through the channel to be appreciably attenuated by saturation effects. The saturation effect described differs from the Michaelis-Menten kinetics in that no absolute maximum effect is attained.

An electrophysiological study of skeletal muscle fibres in the 'muscular dysgenesis' mutation of the mouse

Experiments were performed on muscles of 18-19 day mice fetuses affected with muscular dysgenesis (mdg). Action potentials generated by electrical stimulation or potassium depolarization failed to trigger muscle contraction in mdg muscle fibres. By contrast, muscle contraction could be obtained by caffeine (15 mM) and, to a lesser degree, by nerve stimulation. We conclude that a defect in excitation-contraction (E-C) coupling is the cause of muscle paralysis. An early after potential (EAP) was present in the decay phase of the action potential and a potential 'creep' occurred in response to hyperpolarizing current pulses which can be taken as evidence for the presence of T-tubules in mdg muscle fibres. Data obtained from square pulse analysis and EAP measurements indicate larger input impedance and membrane time constant in mdg as compared to controls, which contrasts with similar surface membrane time constant (as estimated from the foot of the action potential) in both types of muscle. The excitability of the T-tubule system was tested by recording action potentials at early stages of TTX (5 X 10(-7) M) perfusion or washout in mdg and control muscles. In both cases, the action potentials decreased in amplitude and rate of rise and displayed two peaks, the second of which was suppressed by detubulation using the formamide treatment. This indicates action potential generation in the T-tubule membrane of mdg muscles. In all the impaled muscle fibers, nerve stimulation evoked epps which were accompanied by a weak local contraction in relation with Ca2+ influx through postsynaptic channels.(ABSTRACT TRUNCATED AT 250 WORDS)

Influence of chloride concentration and pH on the 36Cl efflux from depolarized skeletal muscle of Rana temporaria

1. 36Cl- efflux rates were measured in depolarized fibre bundles (predominantly fast fibres) from m. semitendinosus of Rana temporaria in order to investigate the influence of chloride concentration (20-400 mM) and external pH (pHo, 5.5-11.6) on chloride self-exchange. Usually, the bundles were depolarized to a membrane potential of virtually zero ([Cl-]i = [Cl-]o = [Cl-]) in 140 mM-K+ and 20 mM-Cl- combined with either 60 mM-SO4(2-) (+52 mM-sucrose) or 120 mM-methyl sulphate, gluconate or glucuronate. Various values of [Cl-] were obtained by adding KCl to the medium, keeping constant the concentration of relatively impermeant solutes and thus the fibre volume. 2. The chloride permeability, PCl, at pH 7.5 decreased with increasing [Cl-] above 50 mM. At [Cl-] less than 50 mM, PCl was about 4 X 10(-6) cm s-1. 3. PCl at pHo 7.5 and 5.6 was a hyperbolic function of [Cl-1] (greater than or equal to 50 mM), consistent with saturation kinetics of chloride self-exchange. 4. Methyl sulphate inhibited chloride self-exchange and may enter depolarized fibre membranes slowly. Comparison of PCl estimates in SO4(2-), gluconate, and glucuronate suggested that SO4(2-) and gluconate may interfere with chloride self-exchange at low [Cl-], and that glucuronate interferes the least. 5. A change from chloride equilibrium to an inward KCl gradient increased the 36Cl- efflux rate in acid media (pH less than 6.5) and decreased the efflux rate at pHo greater than or equal to 7. The effects were not due to changes of membrane potential and demonstrate a change of transport mode consistent with single-filing at high pH and dominant exchange diffusion at low pH. This result makes interpretation of the saturation kinetics difficult. 6. At constant [Cl-], PCl showed a bell-shaped dependence on pHo with a maximum around pH 8.5. The decrease of chloride permeability as the pH is decreased below 8.5 showed an apparent pK of about 7. PCl fell at very alkaline pH with an apparent pK of about 10. 7. The results are in agreement with previous observations of an external pH-sensitive control of PCl (pK approximately 7) and suggest that, in conditions close to chloride equilibrium, this control includes a transition between a dominant conductive channel conformation at high pH and a dominant non-conductive conformation at low pH.(ABSTRACT TRUNCATED AT 400 WORDS)

Extracellular hydrogen ions influence channel-mediated and carrier-mediated K+ fluxes in cultured mouse astrocytes

Physiological (pH 7.2 and 7.0) and pathological (pH 6.8 and 6.6) changes of external pH, as they are measured in vivo, were imposed on mouse astrocytes in primary cultures and the effect on components of K+ transport pathways across the cell membrane was measured. Physiological pH changes had no effect at all. Pathological pH changes in inhibited K+ fluxes through channels by 40%. This effect occurred 3-6 min after a pH change and was not additive to a similar change induced by amiloride. This could be seen as an indication that the observed effects are mediated by subsequent changes in intracellular pH; however, direct intracellular pH measurements were not undertaken. A low pH of 6.6 inhibited the activity of the Na+, K+-ATPase by 65% and reduced the carrier-mediated K+ net accumulation into the cells by 60%. This suggests that measured extracellular pH changes in the brain may be functionally important, as they interfere with the K+ homeostasis of the nervous tissue.

Ionic channels: II. Voltage- and agonist-gated and agonist-modified channel properties and structure

This article reviews the different forms of ionic channels: voltage-gated, agonist-gated, and agonist- and second messenger-modified channels. The recent advances in our knowledge of the amino acid sequence of the sodium channel and the nicotinic acetylcholine receptor and the relationship of the primary structure to the channels' quarternary structure and function are discussed.

Quantitative description of three modes of activity of fast chloride channels from rat skeletal muscle

The steady-state kinetic properties of single Cl- channels with fast kinetics active at resting membrane potentials in cultured rat skeletal muscle were studied using the patch-clamp technique. Membrane patches containing single active Cl- channels were often observed, and binomial analysis of the percentage open time in membrane patches containing several Cl- channels indicated that the channels did not occur as obligatory dimers and that they gated independently of one another. Channel activity could be divided into three categories: normal, which included about 99% of the openings and closings; buzz mode, which included about 1% and consisted of bursts of about 50 brief open and shut intervals; and inactivated shut states which included about 0.01% of the shut intervals and lasted for seconds, and occasionally minutes. The method of maximum likelihood was used to determine the number of significant exponential components required to fit the distributions of open and shut intervals during normal activity. Open interval distributions required at least two components, with time constants of 0.52 and 1.5 ms at -40 mV and 7.6 degrees C. Shut interval distributions required at least five exponential components, with time constants of 0.064, 0.72, 1.9, 12.3 and 350 ms. Kinetic reaction schemes were developed for the normal and buzz mode using maximum likelihood techniques to determine the most likely models and rate constants. In developing these models the effects of limited time resolution and missed events were taken into account. Each model tested typically had two or more sets of equally likely rate constants. Incorrect sets of rate constants resulting from the effect of missed events could be eliminated by analysis of the data with different time resolutions. Normal activity could be accounted for by several different seven-state models with two open and five shut states. As different models could be found that gave identical descriptions of the data, the distributions of open and shut intervals were not sufficient to define a unique model. It was established that no other seven-state models would be found that describe the distributions of open and shut intervals during normal activity better than the most likely presented models.(ABSTRACT TRUNCATED AT 400 WORDS)

Reversal of the static component of spindle potential by imposed depolarizing current in the frog muscle spindle

The static component of the spindle potential provoked during stretch of isolated muscle spindles of the frog was reversed during the application of depolarizing currents ranging from 0.2 to 5 nA in normal Ringer solution and also in Na+-free Ringer solution. In the same range of current intensities, spontaneous rhythmic hyperpolarizations due to [Ca2+]i-activated GK, an attenuation of membrane impedance, and an anomalous decrease in amplitude of the afferent spikes were observed. All 4 phenomena were abolished by K+ channel blockers (10 mM CsCl, 1-2 mM 4-aminopyridine (4-AP), or 20 mM tetraethylammonium chloride (TEA], Ca2+ channel blockers (5-10 mM CoCl2, MnCl2, 1-2 mM CdCl2 or 0.5 mM verapamil) or 0.1 mM quinine. The amplitude of the static component of the spindle potential was markedly increased at threshold concentration of the K+ channel blockers (5 mM CsCl, 0.1-0.5 mM 4-AP or 5-10 mM TEA), but the component disappeared at that of the Ca2+ channel blockers. The rhythmic hyperpolarizations are associated with the spindle potential, except for its dynamic component, which often triggers a hyperpolarizing deflection. We suggest that both the static component of the spindle potential and rhythmic hyperpolarizations are due to GK(Ca) in the intracapsular axon, either along the terminal or at the branching nodes, or both; and that the receptor potential contributes to, but is not the same as, the spindle potential.