Kalium-Fluxe und Membranpotential am Froschvorhof in Abh�ngigkeit von der Kalium-Au�enkonzentration

Electrical activity and metabolism in cardiac tissue: An experimental and theoretical study

(1) Effects of the metabolic inhibitor 2,4-dinitrophenol (DNP) on electrical activity in frog atria were studied by means of the sucrose-gap technique and in tracer experiments. (2) Voltage-clamp studies of ionic membrane currents showed a suppression by DNP of peak Na inward current without marked changes in the kinetics of the Na-carrying system and an increase of steady state outward current to three to five times its normal value. In(42)K tracer experiments, DNP increased K resting efflux by about 10% and decreased K influx by 25 to 30%. (3) The depression of Na inward current is regarded as being caused by a partial block of Na channels and an increase of internal Na concentration after inhibition of active Na extrusion. (4) The strong rise in outward current is probably not caused by a K current since K efflux fails to show a correspondingly large change. As a possible explanation for current and flux changes, an electrogenic K pump is discussed. (5) A mathematical model of a carrier system transporting a single ion species is described. The system is designed as a direct "potential" pump. Uphill transport requires an asymmetry of the rate constants governing the cyclic formation and breakdown of carrier-ion complex. The asymmetry is brought about by an input of metabolic energy. Reduction of energy input decreases the asymmetry and induces a carrier-mediated downhill ion movement, with corresponding changes in membrane current and ion fluxes. (6) A model of electrogenic K inward transport is calculated that approximately accounts for the steady state current and the K flux changes experimentally observed after inhibition.

Embryonic induction and cation concentrations in amphibian embryos

Explanted ectoderm from early gastrulae of Triturus alpestris was treated with the Na-K ionophore gramicidin (10(-9) to 10(-5) M) and the Ca-ionophore A 23187 (10(-7) to 10(-5) M). The ectoderm developed almost exclusively to atypical epidermis as in the control explants. When the ectoderm was treated with ouabain (10(-4) M), intracellular Na+ increased about 4.4-fold and K+ was reduced by half. Mesenchyme cells in small number differentiated in about 40% of the ouabain-treated explants. The time course of total Na+ and K+ ion concentrations was measured over a period of 72 h in ectoderm of T. alpestris after induction with vegetalizing factor and in control explants. In the first 15 h after explantation, no significant differences between control and induced explants were found. Thereafter, the steady state concentration of K+ decreased in the induced explants, whereas the steady-state concentration of Na+ slightly increased. The membrane resting potential recorded intracellularly of ectoderm sandwiches from early gastrula stages was found to be -41.3 mV in control and -59.3 mV in induced explants. From the specific conductances and permeabilities of non-induced and induced cells it is concluded that the induction process leads to a differentiation of the cell membrane, which acquires the characteristics of ionic selectivity. Ectoderm from Ambystoma mexicanum forms neural or neuroid tissue, mesenchyme and melanophores after explantation in salt solution in up to 50% of the explants without any additions. Isolated Ambystoma ectoderm is therefore not suitable for test experiments.

Local regulation of blood flow

H+ and K+ ions participate decisively in the local regulation of blood flow. Variation of their extracellular concentration changes the membrane potential of vascular smooth muscle cells and tension via electromechanical coupling. The effect of K+ ions can be primarily attributed to a change of K+ equilibrium potential and electrogenic pump rate, the effect of H+ ions to a change of Na+ and K+ permeability of the cell membrane. Shifts of external proton and/or cation concentrations cause changes of the binding properties of the polyanionic macromolecules in vascular connective tissue. Thus, the extracellular concentration of various cation species can very fast and drastically in the tight mesh-work of connective tissue fibres close to the membrane of vascular smooth muscle cells. Especially, the K+ adsorption with extracellular acidification as well as the cooperative K+ binding as consequence of a conformational change induced by Mg++ ions are of great importance for membrane hyperpolarization and vasodilatation.

Intra- and extracellular potassium activities, acetylcholine and resting potential in guinea pig atria

Intracellular potassium activity in guinea pig left atria was measured using potassium ion-selective microelectrodes and conventional microelectrodes. The effects of extracellular potassium concentration and acetylcholine on both intracellular potassium activity and the relationship between the resting membrane potential and the potassium equilibrium potential were investigated. Intracellular potassium activity was 102.1 mM in bathing media with a potassium concentration of 5 mM. Neither increasing extracellular potassium concentration to 10 mM nor exposure to acetylcholine (2 x 10(-6) to 10(-3) M) significantly altered intracellular potassium activity. In contrast, intracellular potassium activity decreased to 92.9 mM in 2.5 mM potassium concentration solutions. Resting membrane potential was 18.6, 9.6, and 7.3 mV positive to the potassium equilibrium potential in 2.5, 5, and 10 mM potassium, respectively. Acetylcholine caused a significant hyperpolarization at each extracellular potassium activity, confirming that resting membrane potential was positive to the potassium equilibrium potential. Even after exposure to 10(-3) M acetylcholine, the resting membrane potential apparently remained positive to the potassium equilibrium potential. If potassium accumulates in extracellular clefts during acetylcholine exposure, the calculated potassium equilibrium potentials are too negative, and the resting membrane potential might closely approximate the potassium equilibrium potential under these conditions. Fading of the acetylcholine-induced hyperpolarization and overshoot of the resting membrane potential on washout of acetylcholine were observed and are consistent with an accumulation of potassium during exposure to acetylcholine. In 5.0 mM potassium bathing solution, preparation-to-preparation variability of resting membrane potential can largely be explained by variability of intracellular potassium activity.(ABSTRACT TRUNCATED AT 250 WORDS)

Properties of an inward rectifying K channel in the membrane of guinea-pig atrial cardioballs

Single channel outward current fluctuations are recorded in excised (outside-out) membrane patches of isolated atrial cells in culture (cardioballs) from hearts of adult guinea-pigs. The ionic channel displays a high selectivity to K ions. Accordingly the reversal potential of the single channel current is close to the K equilibrium potential. The open channel conductance is unaffected by the membrane potential but depends on the K concentration of the outside solution (19.7pS at 2 mM Ko to 30.7pS at 20 mM Ko). The open state probability (Po) of the channel shows a marked voltage dependence. Po amounts to c.0.9 at -40 mV and decreases to c.0.1 at +40 mV. Under the assumption of no channel interaction a macroscopic steady state current voltage relationship is reconstructed from the single channel data. The relationship displays inward-going rectification. The rectification is due to the voltage dependence of Po. The I-V curve displays a negative slope at membrane potentials positive to -15 mV. In bathing solutions containing Ba ions (0.2 mM) Po is reduced by rapid closures which interrupt the open state events. The unit channel conductance is unaffected by Ba ions. The channel block exerted by Ba ions is augmented with increasing membrane hyperpolarization. The results suggest that the channel studied may represent a background K conductance.

K efflux through inward rectifying K channels in voltage clamped Purkinje fibers

The 42K efflux was measured in voltage clamped sheep Purkinje fibers. The voltage dependence of the K efflux can be described as N-shaped, showing a negative slope region. At potentials negative to -30mV, the K efflux is largely due to K flowing through a channel which rectifies in the inward direction and which is blocked by external application of 20mM Cs+. At potentials positive to -30mV an outward rectifier dominates the shape of the K efflux-voltage relationship. This component is insensitive to short external application of Cs+. Both components were also found when Na+ was replaced by tetramethylammonium. When the steady-state current-voltage relationship is compared with the K efflux one can conclude that the outward rectifying K flux largely determines the shape of this curve at positive membrane potentials, while the negative slope region of the K efflux correlates with the negative slope of the steady-state current-voltage relation. The K efflux is only slightly enhanced by stimulation of the preparation, corroborating the finding of inward-going rectification of the K channel. A clamp program repetitively activating the positive dynamic current e.g. by alternating the membrane potential between -70 and +10mV, increases the K efflux by about 50% as compared to the efflux measured in steady-state at this positive membrane potential. 4-Aminopyridine suppresses both this extra K efflux and the positive dynamic current. It is concluded that K ions contribute to the positive dynamic current.

Calcium-dependent slow action potentials in potassium-depolarized guinea-pig ventricular myocardium enhanced by barium ions

Experiments were performed to investigated the mechanism by which Ba ions facilitate slow response in the myocardium. In partially depolarized guinea-pig papillary muscles, adding 0.2 mmol/l Ba to K-rich solution drastically lowered the stimulus threshold and converted the graded response to an all-or-none activity. This change was accompanied by an increase in the membrane resistance, as determined by cable analysis. When [Ca]0 was altered (0.9--7.2 mmol/l) in the presence of 0.2 mmol/l Ba, the action potentials varied almost in a manner expected for a Ca-electrode, and there were concomitant increases in the twitch tension. The electrical and mechanical activities of muscles treated with 1 mmol/l Ba were also strongly Ca-dependent. At normal [Ca]0, increasing [Ba]0 from 0.2--1 mmol/l only slightly enhanced the action potentials without any appreciable change in the peak twitch tension. When [Ca]0 was lowered to 0.2 mmol/l, elevation of [Ba]0 to over 0.5 mmol/l restored the action potentials, and the resting tension increased. These results suggest that the facilitatory action of the low concentration of Ba on the Ca-dependent slow action potentials is due to a reduction in the membrane shunting conductance and not to a development of any sizeable inward Ba current. However, Ba-dependent action potentials may be generated under conditions of Ca-deficiency. Isoprenaline (0.5--5 x 10(-7) mol/l) induced an automatic activity in the Ba-treated muscles and this phenomenon is probably related to both the drug-induced increase in Ca-permeability and the Ba-induced decrease in shunting conductance. Thus Ba ions appear to be a feasible tool for studies on the myocardial slow channel.

Voltage clamp and tracer flux data: effects of a restricted extra-cellular space

In the original Hodgkin & Huxley analysis of the membrane currents in squid giant axon, the time dependence of the currents was attributed to voltage-dependent changes in the permeability of the membrane to the ions involved. According to this theoretical framework, the time constants for the rate of change of current should be unique functions of the membrane potential, and should be independent of the previous history of the voltage and current flowing. In recent years, however, there has been increasing awareness of the fact that, for many physiological preparations, the space just outside the cell membrane is not in good diffusive contact with thebulkextra-cellular fluid perfusing the preparation. Consequently, when current flows across the cell membrane, there are changes in the ion concentrations in this so-called ‘restricted extra-cellular space’ (RECS).

Compartmental analysis of potassium efflux from growth-oriented heart cells

Radioisotopic flux studies were initiated with a new preparation of growth-oriented heart cells to determine the contribution of heterogeneous cell types and the limitations of extracellular diffusion in quantitating the passive movement of potassium ions. The efflux of potassium-42 from contractile preparations, which contain two populations of cells, cardiac muscle and fibroblastlike, could be resolved into two components similar to that described for naturally occurring preparations of cardiac muscle. Compartmental analysis of the efflux data, using analog and digital computational methods, resolved the tracer kinetics into a slow compartment (k=0.015 min-1) associated with fibroblastlike cells and a fast compartment (k=0.067 min-1) associated with the cardiac muscle cells. The rate constants derived from compartmental analysis were independent of tracer equilibration and preparation dry weight. Analytical measurements of the preparations provided a quantitative basis for determing the transmembrane potassium fluxes from the tracer kinetics. Cardiac muscle cells stimulated at a rate of 150 min-1 in the presence of 5.4 mM external potassium were found to have a potassium efflux of 15.7 pmoles cm-2sec-1 whereas the value obtained for the fibroblastlike cells was 1.88 pmoles cm-2sec-1. Diffusional limitations of 42K efflux were analyzed for several important variables which can affect isotopic reflux, namely, transmembrane flux, cell volume-to-surface area and cell packing fraction.

Increase of potassium flux by valinomycin in embryonic chick heart

The effect of different concentrations of the antibiotic valinomycin, was determined on 42K efflux and Na, K content of embryonic chick hearts. Valinomycin produces an increase of K efflux which is progressive in time and markedly dependent on the concentration of external K (0-5 mM) and valinomycin (10(-8) to 10(-5) M). The changes in K efflux is not due to a reversal of the Na-K pump mechanism, secondary to ATP depletion: i) the increase of K efflux by valinomycin persists in the absence of external Na ions. ii) analysis of Na and K content and 42K influx measurements with and without valinomycin indicate that active K influx is not inhibited in a solution containing 0.5 mM K and only slightly decreased in a solution containing 5 mM K. Valinomycin, acting as a K carrier, presumably increases K conductance of the cell membrane resulting in a rise in K efflux.