Separation of ionic currents in the somatic membrane of frog sensory neurons

Summary Electrical properties of isolated frog primary afferent neurons were examined by suction pipette technique, which combines internal perfusion with current or voltage clamp using a switching circuit with a single electrode. When K⁺ in the external and internal solutions was totally replaced with Cs⁺, extremely prolonged Ca spikes, lasting for 5 to 10 sec, and Na spikes, having a short plateau phase of 10 to 15 msec, were observed in Na⁺-free and Ca²⁺-free solutions, respectively. Under voltage clamp, Ca²⁺ current (I _Ca) appeared at around –30 mV and maximum peak current was elicited at about 0 mV. With increasing test pulses to the positive side,I _Ca became smaller and flattened but did not reverse. Increases of [Ca] _o induced a hyperbolic increase ofI _Ca and also shifted itsI-V curve along the voltage axis to the more positive direction. Internal perfusion of F^– blockedI _Ca time-dependently. The Ca channel was permeable to foreign divalent cations in the sequence ofI _Ca>I _Ba>I _SrI _Mn>I _Zn. Organic Ca-blockers equally depressed the divalent cation currents dose- and time-dependently without shifting theI-V relationships, while inorganic blockers suppressed these currents dose-dependently and the inhibition appeared much stronger in the order ofI _Ba=I _Sr>I _Ca>I _Mn=I _Zn.     

Effects of conditioning polarization on the membrane ionic currents in rat myometrium

Summary Membrane ionic currents were measured in pregnant rat uterine smooth muscle under voltage clamp conditions by utilizing the double sucrose gap method, and the effects of conditioning pre-pulses on these currents were investigated. With depolarizing pulses, the early inward current was followed by a late outward current. Cobalt (1mm) abolished the inward current and did not affect the late outward currentper se, but produced changes in the current pattern, suggesting that the inward current overlaps with the initial part of the late outward current. After correction for this overlap, the inward current reached its maximum at about +10 mV and its reversal potential was estimated to be +62 mV. Tetraethylammonium (TEA) suppressed the outward currents and increased the apparent inward current. The increase in the inward current by TEA thus could be due to a suppression of the outward current. The reversal potential for the outward current was estimated to be –87 mV. Conditioning depolarization and hyperpolarization both produced a decrease in the inward current. Complete depolarization block occurred at a membrane potential of –20 mV. Conditioning hyperpolarization experiments in the presence of cobalt and/or TEA revealed that the decrease in the inward current caused by conditioning hyperpolarization was a result of an increase in the outward current overlapping with the inward current. It appears that a part of the potassium channel population is inactivated at the resting membrane potential and that this inactivation is removed by hyperpolarization.     

Effects of sulfhydryl inhibitors on nonlinear membrane currents in frog skeletal muscle fibers

The effect of sulhydryl reagents on nonlinear membrane currents of frog skeletal muscle fibers has been studied using the triple Vaseline gap voltage-clamp technique. These compounds, which are known to interfere with depolarization contraction coupling, also appear to diminish intramembranous charge movement recorded with fibers polarized to -100 mV (charge 1). This effect, however, is accompanied by changes in the fiber membrane conductance and in most cases by the appearance of an inwardly directed current in the potential range between -60 and +20 mV. This current is reduced by both cadmium and nifedipine and does not occur in Ca-free solution, suggesting that it is carried by calcium ions flowing through regular calcium channels that are more easily activated in the presence of SH reagent. These changes in the membrane electrical active and passive properties decrease the quality and reliability of the P/n pulse subtracting procedure normally used for charge movement measurements. These effects can be substantially reduced by cadmium ions (0.1 mM), which has no effect on charge movement. When SH reagents are applied in the presence of cadmium, no effects are observed, indicating that this cation may protect the membrane from the reagent effects. The effects of -SH reagents can be observed by applying them in the absence of cadmium, followed by addition of the cation. Under these conditions the conductance changes are reversed and the effects of the SH reagents on charge movement can be measured with a higher degree of confidence. Maximum charge is reduced by 32% in the presence of 1.5 mM PCMB and by 31% in the presence of 2 mM PHMPS. These effects do not occur in the presence of DTT and in some cases they may be reversed by this agent. Charge 2, recorded in depolarized muscle fibers, is also reduced by these agents.     

Effect of nonachlazine on transmembrane ionic currents in the frog atrial trabeculae

The effect of the antianginal drug nonachlazine displaying antiarrhythmic properties on transmembrane ionic currents in the frog atrial fibers was studied in experiments on isolated trabeculae of the frog atria. The transmembrane ionic currents were measured by a voltage clamp technique based on a double sucrose gap arrangement. Nonachlazine (1.03 X 10(-5) mol/l) decreased the amplitude of the fast inward current whatever the magnitude of membrane potential. The drug inhibited the slow inward current and prevented the adrenaline-increased permeability of the slow sodium-calcium channel if external sodium ions were replaced by choline chloride. Nonachlazine (1.03 X 10(-5) mol/l) diminished the amplitude of the inward ionic current in a calcium-free medium as well. The stimulatory effect of prostacycline (2 X 10(-7) mol/l) on the fast inward ionic current was inhibited by nonachlazine. The data obtained suggest that the antiarrhythmic effect of nonachlazine might be linked with the inhibition of the fast sodium inward current and the slow calcium inward current.     

Voltage-dependent membrane ionic currents in lamprey striated muscle

Membrane ionic currents in striated muscle bundles of lamprey suction apparatus were recorded using a double sucrose gap technique. Transmembrane currents in a single muscle fiber and a fiber bundle in the frog were compared so as to check the validity of current measurement in multicell preparations. It was found that fast inward sodium currents arise in the lamprey muscle membrane in response to depolarization together with a delayed outward potassium current, with steady-state characteristics resembling those of membrane currents in frog muscle. The only difference consisted of a flatter curve for steady-state inactivation of potassium current, probably indicative of greater density of potassium channels. Both the changes in reversal potential and the speed of potassium current deactivation occurring during protracted stimuli point to the presence of two fractions in this current. No functioning voltage-dependent calcium channels are found in the lamprey muscle membrane.I. M. Sechenov Institute of Evolutionary Physiology and Biochemistry, Academy of Sciences of the USSR, Leningrad. Translated from Neirofiziologiya, Vol. 18, No. 5, pp. 629–636, September–October, 1986.     

Properties of membrane ionic currents in pituitary clone cells

Membrane ionic currents of the GH3 pituitary cell line have been studied using voltage clamp techniques. The inward current is completely blocked by cobalt (Co2+) ions and appeared to be carried by calcium ions. Three outward currents can be differentiated on the ground of kinetics and pharmacological studies: a transient current blocked by 4-aminopyridine (4 AP) and two delayed outward current which are voltage dependent. One is blocked by tetraethylammonium (TEA); the second is blocked by Co2+ and represents a calcium-activated potassium conductance.     

Calcium currents of frog and insect skeletal muscle fibres measured during voltage clamp

Both vertebrate and invertebrate skeletal muscle fibres have Ca2+ permeability mechanisms which are turned on by depolarization of the surface membrane. In frog muscle, Ca currents are extremely slow and will be scarcely activated during the action potential that normally elicits a twitch. This Ca permeability cannot therefore play any substantial, direct role in excitation--contraction coupling. In insect (Carausius morosus) muscle, Ca currents activate within milliseconds of depolarization, even at low temperature, and may well play at least a triggering role in excitation--contraction coupling. These Ca currents show saturation with increasing [Ca]0, while the instantaneous current--voltage relation rectifies inwards, as expected from a very low [Ca]i. The Ca channel is permeable to Sr2+ and Ba2+. Inactivation of Ca currents under a maintained depolarization depends on Ca2+ carrying inward current, however, rather than on the depolarization itself.     

Effects on anthracycline antibiotics on ionic currents and contraction of frog atrial fibrils associated with Na+/Ca2+ exchange

The action of the anthracycline antibiotics rubomycin and its nitroxyl analogue ehoxyl(ruboxyl) at the concentration 100 mg/l was studied in the experiments, have been carried out with the isolated bundles of frog atrium using simultaneous registration of the ionic currents (or the active potentials) and the contraction. It has been shown, that rubomycin caused an action of potential shortening, membrane depolarization, increasing of the background outward current IKI, slowing of the muscle relaxation and the growth of the ionic contraction, associated with the Na/Ca exchange. Nitroxyl derivative of the rubomycin ruboxyl, exhibited small toxicity, did not change the ionic currents and the parameters of the mechanical activity. It is assumed, that cardiotoxicity of anthracyclines is in the great degree due to their ability to block the elimination of the Ca++ from the cell via the Na/Ca exchange, that results in the disturbance of the Ca-homeostasis of the cardiomyocyte and its calcium overload.     

Spontaneous mechanical activity in depolarized frog ventricle

Spontaneous mechanical activity can be produced in depolarized frog ventricle by bathing the tissue in a solution with low Na, Iow Ca, and high K+. The contractions can be inhibited by depleting the tissue of Ca first, but they are relatively insensitive to changes in either extracellular [Ca++] or [Ca++]/[Na+]2. They are terminated very rapidly by raising [Na+] to 40 mM. Local anesthetics enhance the spontaneous activity in proportion to the concentration of their free base form. These contractions occur relatively rhythmically for several hours. Since the preparation is multicellular, this suggests a mechanism for intercellular communication without change in membrane potential.     

Effects of potassium,sodium, and azide on the ionic movements that accompany activity in frog nerves

Stimulation of intact or desheathed frog sciatic nerves produced an increase in the sodium content and a decrease in the potassium content of this tissue. In desheathed preparations the magnitudes of the changes in ionic contents decreased as the concentration of the potassium in the bathing solution was increased, while changing the external sodium concentration produced small effects on the ionic shifts. During tetanization, the rate of decline of the compound action potential also decreased as the external potassium concentration increased. Eliminating the activity respiration with 0.2 mM azide did not greatly modify the changes in sodium and potassium distribution that accompanied activity in either intact or desheathed nerves.     

Ultra-slow inactivation of the ionic currents through the membrane of myelinated nerve.

(1) Voltage-clamp experiments were performed with myelinated fibres isolated from the sciatic nerve of the frog to study slow changes of the specific sodium and potassium currents as a function of membrane (holding) potential and time. (2) The level of the peak sodium current depends on holding potential VH. This dependence can be described by a sigmoidal function uinfinity(VH). The underlying process is called "ultra-slow sodium inactivation" and is different and separable from the short time steady-state inactivation, hinfinity(V), and from the slow inactivation depending on the extracellular potassium concentration (Adelman, Jr., W. J. and Palti, Y. (1969), J Gen. Physiol. 54, 589-606; Peganov, E. M., Khodorov, B.I. and Shishkova, L. D. (1973), Bull. Exp. Biol. Med. 25, 15-19; Khodorov, B. I. Shishkova, L. D. and Peganov, E. M. (1974), Bull. Exp. Biol. Med. 3, 10-14). (3) After a sudden change of the holding potential the sodium current reaches a new steady-state level (due to the transition of uinfinity(VH) to the corresponding value) within approx. 4 min. The kinetics of the transition cannot be described by a single exponential function. (4) A corresponding voltage- and time-dependent process of ultra-slow inactivation exists for the potassium current in the node of Ranvier. The kinetics are faster than those of the sodium system.     

Electrical and mechanical activity of isoproterenol-damaged frog heart

The electrical and mechanical activities of myocardial strips from Rana pipiens were studied in the steady state at various stimulation frequencies and after a period of rest. The temperature of the bath was varied between + 12 and 35 degrees C. Normal myocardium was compared with that damaged by isoproterenol (ISO). The percentage change of action potential durations (APD50) and isometric force (P) was similar in ISO-damaged and control hearts at various bath temperatures with steady state stimulation rates between 20 and 100/min. At low stimulation rates (3-6/min) the prolongation of the action potential (AP) was more pronounced and the P-decrease was less in ISO-damaged myocardium compared to controls. These differences became more apparent at low bath temperatures. After 10 min of rest, APD50-90 was significantly prolonged in ISO-damaged heart and P was increased by a factor of 2 compared to controls (stimulation rate 20/min). Steady state values, on the other hand, were nearly the same in both groups. These findings are interpreted as indicating a temperature or ISO-dependent increase of electrogenic trans-sarcolemmal Ca2+-uptake during low frequency, or post-rest stimulation, either directly by an increase of the slow inward current (Isi), or indirectly by decreased K+-permeabilities.     

Effects of Na-octanoate on potassium contractures in normal and denervated frog tonic fibres

In frog twitch muscle fibres, Na-octanoate (NaC8) shifted the relation between potassium induced tension and membrane potential to the right. The present study has been carried out to investigate the effect of this fatty acid on frog tonic fibres. Potassium contractures measured on bundles of 30-40 fibres of ileofibularis muscles were less decreased by NaC8 (2.5-10 mmol/l) than those of twitch fibre bundles. In denervated muscles the sensitivity to NaC8 was increased, probably due to the development of sodium channels in the membranes. Experiments with mixed fibre bundles also showed a lower influence of NaC8 on potassium contracture of tonic fibres. On the other hand, tonic fibres showed a lower threshold of the potassium induced tension as well as a lower K+ concentration for maximal activation. This lower threshold was further lowered by NaC8, corresponding to a shift of the relation between potassium concentration and tension to the left. The membrane resting potentials were -58 +/- 9 mV in tonic fibres and -83 +/- 5 mV in twitch fibres. Five mmol/l NaC8 only induced depolarization of the membrane of tonic fibres. This depolarization (by about 20 mV) may be responsible for the threshold shift to lower K+ concentration in NaC8-exposed tonic fibres. In addition to the effects of NaC8 on sodium channels, interactions with Ca2+ binding sites are discussed.     

Study of ionic currents across a model membrane channel using Brownian dynamics.

Brownian dynamics simulations have been carried out to study ionic currents flowing across a model membrane channel under various conditions. The model channel we use has a cylindrical transmembrane segment that is joined to a catenary vestibule at each side. Two cylindrical reservoirs connected to the channel contain a fixed number of sodium and chloride ions. Under a driving force of 100 mV, the channel is virtually impermeable to sodium ions, owing to the repulsive dielectric force presented to ions by the vestibular wall. When two rings of dipoles, with their negative poles facing the pore lumen, are placed just above and below the constricted channel segment, sodium ions cross the channel. The conductance increases with increasing dipole strength and reaches its maximum rapidly; a further increase in dipole strength does not increase the channel conductance further. When only those ions that acquire a kinetic energy large enough to surmount a barrier are allowed to enter the narrow transmembrane segment, the channel conductance decreases monotonically with the barrier height. This barrier represents those interactions between an ion, water molecules, and the protein wall in the transmembrane segment that are not treated explicitly in the simulation. The conductance obtained from simulations closely matches that obtained from ACh channels when a step potential barrier of 2-3 kTr is placed at the channel neck. The current-voltage relationship obtained with symmetrical solutions is ohmic in the absence of a barrier. The current-voltage curve becomes nonlinear when the 3 kTr barrier is in place. With asymmetrical solutions, the relationship approximates the Goldman equation, with the reversal potential close to that predicted by the Nernst equation. The conductance first increases linearly with concentration and then begins to rise at a slower rate with higher ionic concentration. We discuss the implications of these findings for the transport of ions across the membrane and the structure of ion channels.     

Effects of isoprenaline on tonic tension and Na-Ca exchange in frog atrial fibres

The action of isoprenaline, a purely beta-agonist, was investigated on frog atrial fibres under voltage clamp conditions; tonic tension was induced by long depolarizing pulses and the outward delayed current simultaneously developed. The cumulative dose-response curves showed that isoprenaline increased the peak of tonic tension in the concentration range 10(-8) to 3. 10(-6) mol.l-1, with a maximum effect for 10(-6) mol.l-1. The positive inotropic action of isoprenaline was associated with an increase in the rates of tension rise and of relaxation. Isoprenaline also increased the amplitude of the outward delayed current in a dose-dependent manner. The effects of isoprenaline (10(-6) mol.l-1) on tonic tension and outward delayed current were not observed in the presence of propranolol (10(-7) mol.l-1). Experiments carried out in low-sodium solution demonstrated that the action of isoprenaline on tonic tension can be explained by activation of Na-Ca exchange; the enhanced relaxation might result from the same process. These results suggested that the positive inotropic action of isoprenaline is mediated not only by the well-known increase in the slow inward current but also by activation of the Na-Ca exchange mechanism.     

Effects of manganese chloride on the outward currents in frog atrial trabeculae

The effects of MnCl2 on outward currents in frog atrial muscle were investigated under voltage-clamp conditions. MnCl2 (3 mmol/L), which completely abolished the slow inward current, produced a decrease in the outward background current (Ib) at potentials positive to -50 mV. The delayed outward current (Ix, time dependent) was not altered by Mn. "Isochronic activation curves" for Ix and decay of current tails at -40 mV remained unaffected after Mn. Effects on Ib probably reflect a decrease in IK1 related to the decrease in Ca influx as well as a reduction in the Na-Ca exchange current.