Chloride-dependence of the actions of phlorizin on frog skeletal muscle membrane

The effects of phlorizin on the membrane potential changes induced by cevadine were compared in the presence and absence of external chloride anions in frog skeletal muscle. The action of the drug on 24Na-efflux was also studied in chloride-free medium. In accordance with previous results, it was found that phlorizin reduced the frequency of the membrane potential oscillation (1 mmol/l) or fully inhibited the rhythmic activity (2 mmol/l) in the presence of chloride anions. Replacing the total chloride content of bathing fluid with non-penetrating anions (glutamate, isethionate or sulphate) the inhibitory action of phlorizin on the membrane potential oscillation failed to appear while it reappeared rapidly if the chloride ions were partially restored in the incubating medium. The membrane potential changes evoked by changing the chloride concentration of Ringer solution at constant [K]0 were more expressed in the presence of phlorizin. The action of phlorizin on 24Na-transport proved to be a chloride-independent phenomenon. This finding indicates that the inhibitory effect of phlorizin on Na-transport processes may not be the reason of its blocking action on membrane potential oscillation. Furthermore, it suggests that failure of the drug to inhibit the membrane potential oscillation in the absence of chloride anions may not be accounted for the lack of phlorizin-binding under those circumstances. It is therefore assumed that the increase in chloride conductance may play a causal role in the inhibitory effect of phlorizin on membrane potential oscillation.     

Effect of phlorizin on the changes of membrane potential, water, Na and K transport induced by cevadine in frog muscle

The effect of phlorizin on the parameters of cevadine induced membrane potential oscillation and the development of the potential changes were investigated in frog (Rana esculenta) sartorius muscles. The action of phlorizin on Na transport, water and cation contents of cevadine-treated muscles were also studied. On the effect of phlorizin applied at a concentration of 1 mmol/1 the frequency of the membrane potential oscillation evoked by cevadine decreased by about half, parallel with an about four-fold increase in the duration of the resting period and the prepotential. Phlorizin, applied at a concentration of 2 mmol/l on the neural part of the muscle before cevadine treatment, delayed the development of depolarization evoked by cevadine. In the cevadine-pretreated muscles the enhanced 24Na-uptake was not reduced by 2 mmol/l phlorizin. 2 mmol/l phlorizin, applied during the radioactivity washout period, diminished reversibly the rate coefficient for 24Na loss by 49% in 120 min. The 24Na-efflux increasing effect of cevadine, which is characteristic otherwise, was prevented by phlorizin. This action was also reversible. The intracellular water, Na, and K contents of muscles were not altered significantly by 2 mmol/l phlorizin even in 3 hours. Under the effect of cevadine the characteristic gain in intracellular water, Na content and [Na]i developed despite phlorizin treatment, but the changes mentioned above evolved more slowly. In the phlorizin-pretreated muscles the K-content decreasing effect of cevadine failed to come about. In the muscles pretreated with phlorizin the [K]i was reduced by cevadine at a proportional degree to water-uptake.     

Barbiturates Block Sodium and Potassium Conductance Increases in Voltage-Clamped Lobster Axons

Sodium pentobarbital and sodium thiopental decrease both the peak initial (Na) and late steady-state (K) currents and reduce the maximum sodium and potassium conductance increases in voltage-clamped lobster giant axons. These barbiturates also slow the rate at which the sodium conductance turns on, and shift the normalized sodium conductance vs. voltage curves in the direction of depolarization along the voltage axis. Since pentobarbital (pK_a = 8.0) blocks the action potential more effectively at pH 8.5 than at pH 6.7, the anionic form of the drug appears to be active. The data suggest that these drugs affect the axon membrane directly, rather than secondarily through effects on intermediary metabolism. It is suggested that penetration of the lipid layer of the membrane by the nonpolar portion of the barbiturate molecules may cause the decrease in membrane conductances, while electrostatic interactions involving the anionic group on the barbiturate, divalent cations, and "fixed charges" in the membrane could account for the slowing of the rate of sodium conductance turn-on and the shift of the normalized conductance curves along the voltage axis.     

Evidence for active chloride accumulation in normal and denervated rat lumbrical muscle

Intracellular Cl- activity (aiCl) was measured with Cl(-)-sensitive microelectrodes in normal and denervated rat lumbrical muscle. In normal muscle bathed in normal Krebs solution, aiCl lay close to that predicted by the Nernst equation. The addition of 9-anthracene carboxylic acid, which blocks Cl- conductance, caused aiCl to increase far above that predicted by a passive distribution. Furosemide (10 microM) reversibly blocked this accumulation. After muscle denervation, aiCl progressively increased for 1-2 wk. The rise occurred in two stages. The initial stage (1-3 d after denervation) reflected passive Cl- accumulation owing to membrane depolarization. At later times, aiCl continued to increase, with no further change in membrane potential, which suggests an active uptake mechanism. This rise approximately coincided with the natural reduction in membrane conductance to Cl- that occurs several days after denervation. Na+ replacement, K+ replacement, and furosemide each reversibly blocked the active Cl- accumulation in denervated muscle. Quantitative estimates suggested that there was little difference between Cl- flux rates in normal and denervated muscles. The results can be explained by assuming that, in normal muscle, an active accumulation mechanism operates, but that Cl- lies close to equilibrium owing to the high membrane conductance to Cl-. The rise in aiCl after denervation can be accounted for by the membrane depolarization, the reduction in membrane Cl- conductance, and the nearly unaltered action of an inwardly directed Cl- "pump."     

Depolarization increases the single-channel conductance and the open probability of crayfish glutamate channels.

We have studied the voltage sensitivity of glutamate receptors in outside-out patches taken from crayfish muscles. We found that single-channel conductance, measured directly at the single-channel level, increases as depolarization rises. At holding potentials from -90 mV to approximately 20 mV, the conductance is 109 pS. At holding potentials positive to 20 mV, the conductance is 213 pS. This increase in single-channel conductance was also observed in cell-attached patches. In addition, desensitization, rise time, and the dose-response curve were all affected by depolarization. To further clarify these multifaceted effects, we evaluated the kinetic properties of single-channel activity recorded from cell-attached patches in hyperpolarization (membrane potential around -75 mV) and depolarization (membrane potential approximately 105 mV). We found that the glutamate dissociation rate constant (k_) was affected most significantly by membrane potential; it declined 6.5-fold under depolarization. The rate constant of channel closing (k(c)) was also significantly affected; it declined 1.8-fold. The rate constant of channel opening (k(o)) declined only 1.2-fold. The possible physiological significance of the depolarization-mediated changes in the above rate constants is discussed.     

Phloretin-induced changes in ion transport across lipid bilayer membranes

Phloretin, the aglucone derivative of phlorizin, increases cation conductance and decreases anion conductance in lipid bilayer membranes. In this paper we present evidence that phloretin acts almost exclusively by altering the permeability of the membrane interior and not by modifying the partition of the permanent species between the membrane and the bulk aqueous phases. We base our conclusion on an analysis of the current responses to a senylborate, and the cation complex, peptide PV-K+. These results are consistent with the hypothesis that phloretin decreases the intrinsic positive internal membrane potential but does not modify to a great extent the potential energy minima at the membrane interfaces. Phloretin increases the conductance for the nonactin-K+ complex, but above 10(-5) M the steady- state nonactin-K+ voltage-current curve changes from superlinear to sublinear. These results imply that, above 10(-5) M phloretin, the nonactin-5+ transport across the membrane becomes interfacially limited.     

Wheel-running exercise alters rat diaphragm action potentials and their regulation by K+ channels.

Endurance exercise modifies regulatory systems that control skeletal muscle Na+ and K+ fluxes, in particular Na+-K+-ATPase-mediated transport of these ions. Na+ and K+ ion channels also play important roles in the regulation of ionic movements, specifically mediating Na+ influx and K+ efflux that occur during contractions resulting from action potential depolarization and repolarization. Whether exercise alters skeletal muscle electrophysiological properties controlled by these ion channels is unclear. The present study tested the hypothesis that endurance exercise modifies diaphragm action potential properties. Exercised rats spent 8 wk with free access to running wheels, and they were compared with sedentary rats living in conventional rodent housing. Diaphragm muscle was subsequently removed under anesthesia and studied in vitro. Resting membrane potential was not affected by endurance exercise. Muscle from exercised rats had a slower rate of action potential repolarization than that of sedentary animals (P = 0.0098), whereas rate of depolarization was similar in the two groups. The K+ channel blocker 3,4-diaminopyridine slowed action potential repolarization and increased action potential area of both exercised and sedentary muscle. However, these effects were significantly smaller in diaphragm from exercised than sedentary rats. These data indicate that voluntary running slows diaphragm action potential repolarization, most likely by modulating K+ channel number or function.     

The effect of phloretin on single potassium channels in myelinated nerve

The effect of phloretin, a dipolar organic compound, on single potassium channel currents of myelinateed nerve fibres of Xenopus laevis has been investigated, using inside-out patches prepared by the method of Jonas et al. (1989). The I channel, a potential dependent K channel with intermediate deactivation kinetics, was reversibly blocked by 20 µM phloretin applied on the inside; the block was strongest at negative membrane potentials and less pronounced at positive potentials. Phloretin shifted the curve relating open probability to membrane potential towards more positive potentials and reduced its slope and maximum. This confirms previous findings on the effect of phloretin on the voltage dependence of the fast macroscopic K conductance. Single channel conductance and deactivation kinetics were not altered by phloretin. Offprint requests to: Correspondence to: H. Meves     

The interactive effects of fatigue and pH on the ionic conductance of frog sartorius muscle fibers

The effects of fatigue on the membrane conductance of frog sartorius muscle at the resting potential and during an action potential were studied. When muscles were exposed to an extracellular pH of 8.0 the membrane conductance at the resting potential increased during fatigue by about 20% and returned to prefatigue level in about 20 min. The membrane conductance of muscle fibers exposed to pH 6.4 was about three times less than that of pH 8.0 and decreased further during fatigue. Furthermore, the recovery of a normal membrane conductance was slow at pH 6.4. Both the inward, depolarizing and the outward, repolarizing currents during the action potential are reduced in fatigue. In each case the effect is greater at pH 6.4 than at 8.0 and recovery towards normal values is slower at pH 6.4. It is concluded that the ionic conductance of the sarcolemmal membrane at the resting potential and during an action potential are modified by fatigue and that these changes are modulated by pHo.     

Disopyramide phosphate effects on slow and depressed fast responses

We studied the effects of disopyramide phosphate on explanted neonatal rat ventricle cells exhibiting depressed fast responses or naturally occurring slow response action potentials together with automatic activity. Disopyramide suppressed the spontaneous activity at a concentration of 2.5 micrograms/mL with a half-maximal value of 10 micrograms/mL. Before spontaneous activity was lost, there was an increase in beating rate possibly related to membrane depolarization. In depressed fast and slow response action potentials there was an increase in action potential duration (APD) which was consistently found both at the level of the plateau and at 90% repolarization. Comparison of the APD increase observed after disopyramide treatment and that after exposure to 20 mM tetraethylammonium suggested a block of a potassium conductance as a possible cause underlying the change in APD. The Vmax values of the depressed fast response decreased at constant membrane potential and this was attributed to the local anesthetic effect of the drug. In addition, we report two novel findings: (i) a decrease of Vmax of the slow response action potentials which may be secondary to membrane depolarization, and (ii) an increase in the duration of slow action potentials, possibly caused by inhibition of a potassium conductance.     

Effects of tetraethylammonium and 4-aminopyridine on the plateau potential of circular myometrium from the pregnant rat

In the pregnant rat, spontaneous electrical activity of circular muscle (CM) changes from single, plateau-type action potentials at early and mid-term to repetitive spike trains at term. To examine mechanisms underlying the plateau, we studied the effects of potassium channel blockers tetraethylammonium (TEA) and 4-aminopyridine (4-AP) on membrane potentials in CM from rats on gestation Days 14, 15, 16, 21 (term). Apparent membrane conductance was measured at rest and during the plateau in Day 14 muscles with and without TEA. 4-AP depolarized the resting membrane on all gestation days. Therefore, a direct action of 4-AP on plateau configuration could not be separated from an indirect effect of depolarization. TEA did not affect the resting potential but increased action potential size and depolarization rate on all gestation days. On Day 16, TEA reduced plateau amplitude, unmasking small, repetitive depolarizations. D-600 decreased plateau amplitude and duration and attenuated these effects of TEA. Plateau conductance increased initially then decreased before membrane repolarization. Membrane conductance and outward rectification during the plateau were reduced by TEA. The plateau potential may result from an outwardly rectifying TEA-sensitive current combined with a slow inward current, the plateau magnitude being determined by the relative intensity of each current.     

A cleft model for cardiac Purkinje strands.

Conduction of the action potential in cardiac muscle is complicated by its multicellular structure, with narrow intercellular clefts and cell-to-cell coupling. A model is developed from anatomical data to describe cardiac Purkinje strands of variable diameter and different internal arrangements of cells. The admittance of the model is solved analytically and fit to results of cable analysis. Using the extracted specific membrane and cell electrical parameters (Rm = 13 K omega cm2, Cm = 1.5 mu F/cm2, Ri = 100 mu cm, and Re = 50 omega cm), the model correctly predicted conduction velocity and filling of capacitance at the onset of a voltage step. The analysis permits more complete studies of the factors controlling conduction velocity; for instance, the effect on conduction velocity of a capacity in the longitudinal current circuit is discussed. Predictions of the impedance and phase angle were also made. Measurements of the frequency dependence of phase angle may provide a basis for separating cleft membrane properties from those of the surface membrane and may aid the measurement of nonlinear membrane properties in muscle.     

Phlorizin-receptor interactions in fat cell plasma membranes

The rate but not the extent of phlorizin binding to purified fat cell plasma membranes was temperature dependent and this binding was a saturable process. A Scatchard plot revealed a population of sites which exhibited a dissociation constant of about 0.35 mM and a maximum binding capacity of about 8 nmoles/mg membrane protein. Under the conditions of these experiments neither glucose, phloretin, nor cytochalasin B inhibited [³H]phlorizin binding. These data demonstrate the presence in fat cell plasma membrane of specific receptors for phlorizin which may mediate the inhibitory effects of this agent on hexose trasport.     

Permeability Changes Associated with the Action Potential in Procaine-Treated Crayfish Abdominal Muscle Fibers

Permeability changes associated with prolonged action potentials have been analyzed in procaine-treated crayfish abdominal muscle fibers. The effect of external Ca indicates that the increase in membrane conductance observed during the rising phase of the action potential is primarily due to a permeability increase for Ca. A remnant of the permeability increase may cause the succeeding plateau as shown by its high conductance and by the effect of low Mn. A delayed increase in conductance precedes the termination of the plateau phase. This is due to a delayed increase in permeability, probably for K, that is observed when depolarizing electrogenesis is eliminated. High external Ca reduces the action potential duration, the falling phase starting at a higher depolarization. These changes may be related to an earlier onset of the delayed increase in permeability, induced by a larger inside positivity in the presence of higher Ca. No "anomalous rectification" is seen in early or late I-V curves for small depolarizations. Ba may replace Ca in its role in depolarizing electrogenesis, and the first action potential induced in Ba saline has a large overshoot and a long duration. In higher Ba salines, action potentials are greatly prolonged. Long term soaking in Rb-containing or K-free saline also augments and prolongs the action potential. These changes are assumed to be related to depression of the K permeability of the membrane.     

Effects of morphine and meperidine on action potential production in frog's skeletal muscle fibers.

Morphine (3.3 times 10-minus 4 M) and meperidine (8.8 times 10-minus 5 M) inhibited action potential production in frog's skeletal muscle fibers. Over these concentration ranges, neither the resting membrane potentials nor the resting membrane electric properties of the fibers appeared to be modified. Both drugs depressed excitability and the rising phase of the action potential by inhibiting the specific increase in sodium conductance which normally follows an adequate stimulus. Both drugs also seemed to inhibit the secondary rise in potassium conductance which normally occurs during an action potential, causing a prolongation of the action potential duration.     

Activation of the fast calcium input in the denervated smooth muscle of the cat nictitating membrane

The excitation and contraction features of innervated and sympathetically denervated smooth muscle strips from cat's nictitating membrane have been studied by single sucrose gap arrangement. Increasing of smooth muscle cells sensitivity to drugs were accompanied by elevation of membrane response and the ability to generation of action potentials. Action potentials have been induced by agonists or high potassium concentration in external solution and spontaneously. In innervated muscle action potentials have been evoked as a result of depolarization by high potassium concentration of TEA blockade of potassium conductance. Induced and spontaneously generated action potentials were blocked by organic and inorganic antagonists of potential dependent Ca++ channels. In Ca-free solution action potentials were absent but might be supported by Ba++. Decrease of Na+ had no effect on smooth muscle excitability. It is supposed that activation of potential depended Ca++ channels in smooth muscle cells with pharmaco-mechanical coupling are under influence of sympathetic nerves.     

Ionic mechanism of 5-hydroxytryptamine induced hyperpolarization and inhibitory junctional potential in body wall muscle cells of Hirudo medicinalis.

Five-hydroxytryptamine (5-HT) causes a hyperpolarization and increased conductance of the leech body wall muscle cell membrane. If 5-HT is applied in the absence of the Cl minus ion, the response appears as a depolarization, whereas if 5-HT is applied in the absence of the K+ ion, the response is a hyperpolarization. In both cases, the conductance of the muscle cell membrane is increased. Stimulation of the peripheral nerve to the body wall muscle produces a complex junctional potential in muscle cells. Exposing the muscle to d-tubocurarine (d-TC) eliminates the excitatory component (EJP) of the complex potential. The inhibitory potential (IJP) that remains has an equilibrium potential at approximately 65 mV. Furthermore, this IJP appears as a depolarization when the nerve is stimulated in the presence of d-TC and low CL minus, whereas this is not the case if the nerve is stimulated in the presence of d-TC and low K+. The drugs BOL-148 and cyproheptadine block the IJP's in the body wall muscle. These data are interpreted as indicating that 5-HT acts on leech body wall muscle cells by increasing the conductance to the Cl minus ion and that the IJP's caused by nerve stimulation are probably the result of 5-HT release at nerve terminals. As a final point, it has been shown that the inhibition by 5-HT of the spontaneous EJP's that occur on the leech body wall muscle results from an inhibition of central neurons and not from any direct effect on the muscle cell or on peripheral synapses.     

Different actions of calcium channel blocking agents on resting membrane conductance in developing skeletal muscle

The effects of Co2+, Mn2+, and La3+ (2 mM) and verapamil (5 x 10(-6) M) on membrane conductance (Gm) and resting potential (Em) were studied in chick skeletal muscle fibres developing in culture. Cobalt and manganese had no effect on Gm at any time during myogenesis but verapamil caused a decrease in Gm in immature myotubes. This effect diminished with time and was absent by 3 days after myoblast fusion. Lanthanum caused an increase in Gm at all stages of development. All the agents studied caused a significant depolarization of Em. It is concluded that there is no resting calcium conductance in developing skeletal muscle but that there may be a resting sodium conductance which declines with maturation. Lanthanum may increase Gm by displacing membrane-bound calcium and destabilizing membrane structure. All the agents studied were thought to induce depolarization by an inhibitory action on (Na+ + K+)-ATPase.     

Electrophysiology of flounder intestinal mucosa. I. Conductance properties of the cellular and paracellular pathways

We evaluated the conductances for ion flow across the cellular and paracellular pathways of flounder intestine using microelectrode techniques and ion-replacement studies. Apical membrane conductance properties are dominated by the presence of Ba-sensitive K channels. An elevated mucosal solution K concentration, [K]m, depolarized the apical membrane potential (psi a) and, at [K]m less than 40 mM, the K dependence of psi a was abolished by 1-2 mM mucosal Ba. The basolateral membrane displayed Cl conductance behavior, as evidenced by depolarization of the basolateral membrane potential (psi b) with reduced serosal Cl concentrations, [Cl]s. psi b was unaffected by changes in [K]s or [Na]s. From the effect of mucosal Ba on transepithelial K selectivity, we estimated that paracellular conductance (Gp) normally accounts for 96% of transepithelial conductance (Gt). The high Gp attenuates the contribution of the cellular pathway to psi t while permitting the apical K and basolateral Cl conductances to influence the electrical potential differences across both membranes. Thus, psi a and psi b (approximately 60 mV, inside negative) lie between the equilibrium potentials for K (76 mV) and Cl (40 mV), thereby establishing driving forces for K secretion across the apical membrane and Cl absorption across the basolateral membrane. Equivalent circuit analysis suggests that apical conductance (Ga approximately equal to 5 mS/cm2) is sufficient to account for the observed rate of K secretion, but that basolateral conductance (Gb approximately equal to 1.5 mS/cm2) would account for only 50% of net Cl absorption. This, together with our failure to detect a basolateral K conductance, suggests that Cl absorption across this barrier involves KCl co-transport.     

A comparison of phlorizin and phloretin adsorption by the tapeworm Hymenolepis diminuta

Phloretin and phlorizin adsorb to the tegument surface of Hymenolepis diminuta, with KDs of 2.39 mM and 14.7 microM, respectively, and Vmaxs of 1446 and 12.54 nmoles/g tissue per 2 min, respectively. Phloretin adsorption is not inhibited by phlorizin or glucose. Glucose partially inhibits phlorizin adsorption. Phlorizin, but not phloretin, adsorption to isolated tegument brush border membrane preparations is partially inhibited by N-ethylmaleimide. No indications of phlorizin hydrolysis to phloretin during incubation with H. diminuta were obtained. The data are supportive of spacially separate and distinct binding sites for phloretin and phlorizin in the tegument brush border.