Calcium-activated transient outward current in calf cardiac Purkinje fibres

Excitation-contraction coupling in the myocardium of hibernating chipmunks

In the myocardium of nonhibernating chipmunks, replacing external Ca by Sr markedly prolongs the action potential plateau with an increase in contraction, while in preparations from hibernating animals this procedure inhibits both responses. Pretreatment with 4-aminopyridine causes a prolongation of the action potential plateau by Sr in hibernating animals.

Two distinct calcium-activated potassium currents in larval muscle fibres of Drosophila melanogaster

The non-synaptic membrane currents of muscle fibres have been studied in late embryogenesis of Drosophila melanogaster using the voltage-clamp technique in wild-type and Shaker mutant third instar larvae. Five currents were found in the wild type muscle membrane at this embryonic stage: one fast inward Ca current (ICa), two fast outward K currents (IA and IAcd) and two slow outward K currents (IK and IC). IAcd and IC are Ca-dependent. Several procedures were used to separate IAcd from IA: IAcd is present in Shaker mutants which are characterized by the absence of IA (Salkoff and Wyman 1981); IAcd, but not IA, is suppressed by Co2+ (10 mM) or La3+ (1 mM); IAcd shows steady-state inactivation at more positive potentials than IA; IAcd, unlike IA, is 3,4-diaminopyridine (3,4-DAP) resistant. Furthermore, tetraethylammonium (TEA, 20 mM) which is known to be uneffective on IA, blocks IAcd. IAcd could not be triggered by using strontium or barium as calcium substitutes. By partial substitution of Ca by Ba or Sr ions, it was found that Ba, but not Sr, blocks the IAcd channel. A non-inactivating, TEA sensitive, Ca-dependent K current (IC), which gave N-shaped I-V plots, could be separated from IK by using Ca-channel blockers. IC and IK activate at membrane potentials of about -25 mV and -10 mV, respectively. The participation of IAcd and IC to membrane electrophysiology is discussed.

Electrophysiological analysis of the sensitivity to calcium in ventricular muscle from alloxan diabetic rats

The effects of acute and chronic alloxan diabetes on the transmembrane electrical activity of rat heart papillary muscle were investigated. The action potential duration (APD) appeared markedly prolonged in all diabetic papillary muscles, as compared to normal. This prolongation of ADP, with no difference in the resting potential (RP), resulted from both a lengthening of the complex time course plateau and a slower rate of repolarisation. APD0 (at 0 mV) and APD10 (+10 mV from RP) increased, respectively, an average of 50% and 24% in the acute, and 72% and 98% in the chronic diabetics as compared to control, whereas Vmax and overshoot (OS) were unchanged. Varying [Ca]o between 0.5 and 3.5 mM did not induce any change in the RP of either control or diabetic papillary muscles. Conversely, there were differences, within and between groups, in the amplitude of the OS and in Vmax, depending on the [Ca]o concentration. In particular, OS and Vmax of acute diabetics were markedly reduced at 1.5 mM. This reduction was maintained at concentrations of [Ca]o lower than 1.5, attesting to the greater sensitivity of both acutely and chronically diabetic muscles to a decrease in external calcium. Cd, a Ca-channel blocker, reduced in diabetics the duration of both the complex plateau and the repolarisation phase, suggesting that a Ca inward current was maintained throughout these two phases. Direct evidence for elucidating the mechanism(s) of the observed APD change in diabetics will be obtained only by transmembrane current analysis.

Calcium activated potassium channels in cultured astrocytes

The patch clamp technique was used to analyze single channel currents in intact and excised patches of glial cell membranes grown in primary cultures from newborn rat brain. Glial cells were morphologically identified by immunohistochemical staining for glial fibrillary acidic protein. Outward currents due to single channels were observed in recordings from both intact and excised patches obtained from the cell body region. The channel responsible for these currents was preferentially permeable to K+ because the reversal potential for this current was correlated with changes in the potassium equilibrium potential, when experimentally altered. The single channel conductance was 25 pS when measured between -20 and +20 mV in solutions with physiological K+ concentrations (10 degrees C). Channel gating was dependent on both the internal Ca2+ concentration and the membrane potential. Either depolarization of the membrane patch, or the addition of increasing Ca2+ concentrations to the internal surface, increased the probability of channel opening. Tetraethylammonium reversibly blocked the channel whereas 4-aminopyridine had no effect. The characteristics exhibited by this channel indicate that a Ca2+-activated K+ channel is present in the membrane of astrocytes grown in culture. These results, combined with previous evidence for a voltage dependent Ca2+ channel, suggest a dynamic role for glial cells in controlling excitability in the central nervous system. Influx of Ca2+ upon depolarization would increase the membrane permeability to K+ and could increase the "buffering" capacity of glial cells for extracellular K+.

Properties of "creep currents" in single frog atrial cells

Changes in membrane current in response to an elevation of [Na]i were studied in enzymatically dispersed frog atrial cells. Na loading by either intracellular dialysis or exposure to the Na ionophore monensin produces changes in membrane current that resemble the "creep currents" originally observed in cardiac Purkinje fibers during exposure to low-K solutions. Na loading induces a transient outward current during depolarizing voltage-clamp pulses, followed by an inward current in response to repolarization back to the holding potential. In contrast to cardiac Purkinje fibers, Na loading of frog atrial cells induces creep currents without accompanying transient inward currents. Creep currents induced by Na loading are insensitive to K channel antagonists like Cs and 4-aminopyridine; they are not influenced by doses of Ca channel antagonists that abolish iCa, but are sensitive to changes in [Ca]o or [Na]o. A comparison of the time course of development of inward creep currents are not tail currents associated with iCa. Inward creep currents can also be induced by experimental interventions that increase the iCa amplitude. Exposure to isoproterenol enhances the iCa amplitude and induces inward creep currents; both can be attenuated by Ca channel antagonists. Both inward and outward creep currents are blocked by low doses of La, independently of La's ability to block iCa. It is concluded that (a) creep currents are not mediated by voltage-gated Na, Ca, or K channels or by an electrogenic Na,K pump; (b) inward creep currents induced either by Na loading or in response to an increase in the amplitude of iCa are triggered by an elevation of [Ca]i; and (c) creep currents may be generated by either an electrogenic Na/Ca exchange mechanism or by a nonselective cation channel activated by [Ca]i.

Voltage-dependent properties of macroscopic and elementary calcium channel currents in guinea pig ventricular myocytes

Whole-cell Ca channel currents were recorded from guinea pig ventricular myocytes that were internally perfused with Cs solution and bathed in solutions containing 3.6 mM Ca, 3.6 mM Ba or 90 mM Ba (34 degrees C). Single Ca channel currents were recorded from cell-attached membrane patches of similar myocytes; the patch pipettes contained a 90 mM Ba solution. 1. Although the shape of the whole-cell I-V relation was independent of the bathing solution, this was not the case with the location of the inward current maximum (Vpeak); Vpeak in 90 mM Ba was about 30 mV positive to Vpeak in 3.6 mM Ba. 2. The activation and inactivation of whole-cell currents were voltage dependent. Compared to the voltage dependencies in 3.6 mM Ba, those in 90 mM Ba were shifted by about 30 mV to the right, suggesting a neutralization of surface charges. 3. Observations compatible with the ion permeation model proposed by Hess and Tsien (1984) included (a) a depression of current during Ca/Ba solution exchange, (b) a high divalent to monovalent ion permeability, and (c) rectification of the outward limb of the I-V relation. 4. Estimated current densities at Vpeak were similar for myocytes in 3.6 mM Ca and 3.6 mM Ba, and about 10 times larger in 90 mM Ba. 5. Average currents (I) calculated from ensembles of records of single Ca channel current had voltage-dependent time courses resembling those of whole-cell IBa (90 mM). 6. Single-channel I-V relations were superimposable on whole-cell I-V curves suggesting that voltage-dependent single-channel parameters (probability of opening, elementary current amplitude) can be related to the voltage-dependent macroscopic current parameters (activation, instantaneous I-V relation) when scaled by channel number. 7. The density of Ca channels in myocytes was calculated from whole-cell IBa (90 mM) and average current through single channels. The outcome, 3-5 channels/micron 2, agrees with two other recent estimates (Tsien et al. 1983; Lux and Brown 1984). However, it is difficult to reconcile with the much lower density that one would forecast from the frequency of functional channel observation in myocyte membrane patches (Pelzer et al. 1985c).

Inhibition of calcium currents in cultured rat dorsal root ganglion neurones by (-)-baclofen

Voltage-dependent inward calcium currents (ICa) activated in cultured rat dorsal root ganglion neurones were reversibly reduced in a dose-dependent manner by (-)-baclofen (10 microM to 100 microM). Baclofen (100 microM) reduced the calcium-dependent slow outward potassium current (IK(Ca)). This current was abolished in calcium-free medium and by 300 microM cadmium chloride. The action of baclofen on IK(Ca) was reduced when the calcium concentration in the medium was increased from 5 mM to 30 mM. The calcium independent fast transient voltage-dependent outward current (IK(Vt] was also reduced by baclofen; this effect remained present when Ca2+-free medium was used to prevent contamination by IK(Ca). 4-Aminopyridine (500 microM) reduced IK(Vt) and induced a small increase in ICa. The action of baclofen on ICa was partially antagonized by 4-aminopyridine. GABAB receptor-mediated inhibition of ICa in cultured rat dorsal root ganglion neurones involves a direct mechanism rather than resulting indirectly from an increase in the residual outward potassium currents activated by depolarization. The reduction in ICa by baclofen was variable and dependent on the amplitude of control ICa, larger currents being more resistant to the baclofen-induced inhibition.

Extracellular calcium transients at single excitations in rabbit atrium measured with tetramethylmurexide

Extracellular calcium transients were resolved within the time course of single contraction cycles in rabbit left atrium using tetramethylmurexide (2 mM) as the calcium-sensitive dye (150-250 microM total calcium, 80-150 microM free calcium). Net extracellular calcium depletion began within 2-4 ms upon excitation; over the following 5-20 ms, depletion continued steeply and amounted to 0.2 mumol/kg wet weight X 10 ms (135 microM free extracellular calcium). In regularly excited muscles (0.5-2 Hz), net depletion slowed rapidly and stopped early during the rise of contractile motion monitored by transmitted light. Maximum depletions amounted to 0.2-0.5% of total extracellular calcium (0.2-0.5 mumol/kg wet weight with 135 microM free calcium). Replenishment of extracellular calcium began at the latest midway to the peak of the motion signal. Calcium replenishment could be complete for the most part by an early phase of relaxation or could take place continuously through relaxation. The maximal net depletion per beat decreased manyfold with a decrease of frequency from 1 to 0.05 Hz. During paired pulse stimulation (200-300-ms twin pulse separation at basal rates of 0.3-1 Hz), extracellular calcium accumulation was enhanced at the initial potentiated contraction; extracellular calcium depletion was prolonged at the low-level premature contraction. With quadruple stimulation (three premature excitations), the apparent rate of net extracellular calcium accumulation at potentiated contractions approached or exceeded the apparent rate of early net calcium depletion. Under the special circumstance of a strongly potentiated post-stimulatory contraction after greater than 5 s rest, repolarization beyond -40 mV occurred within 10 ms, net extracellular calcium accumulation began with the onset of muscle motion, and net extracellular calcium accumulation (1-3 microM/kg wet weight) coincided with a more positive late action potential in comparison with subsequent action potentials. Consistent changes of the apparent rate of early net calcium depletion were not found with any of the simulation patterns examined. In ryanodine-pretreated atria, the duration of depletion was clearly limited by action potential duration at post-rest stimulations; in the presence of 4-aminopyridine (2 mM), depletion continued essentially undiminished for up to 200 ms. The resulting net depletion magnitudes were greater than 10 times larger than the transient depletions found during steady stimulation.

Existence of a calcium-dependent potassium channel in the membrane of cow cardiac Purkinje cells

Single-channel currents were recorded in the membrane of cow cardiac Purkinje cells using the patch-clamp technique. Recordings from cell-attached and cell-free patches demonstrated large outward single-channel currents associated with depolarizing voltage-clamp pulses. The time course of the reconstructed mean current showed a rapid activation phase followed by a slower inactivation following a single exponential time course with a time-constant in the range 30 ms to 100 ms. The current-voltage relation of the channel was linear in the voltage range between +10 mV and +110 mV with a slope conductance of 120 pS in 10.8 mM external K. The results indicated that the channel is selective for K ions. In inside-out patches, when the internal Ca activity was raised from 0.01 microM to 1 microM, the frequency of opening of the K channel during a depolarizing pulse was markedly increased, indicating Ca-dependence of these channels. The relation between this ion channel and the previously described transient outward current in cow Purkinje fibres is discussed. In sheep Purkinje cells a channel, carrying a transient outward current, with different properties was found.

A calcium-activated potassium current in motor nerve terminals of the mouse

Local circuit currents involving presynaptic terminals were recorded by micro-electrodes inserted into the perineurium of nerves from the triangularis sterni muscle of the mouse. A transient outward current component was isolated by blocking the voltage-activated (delayed rectifier) K current by 3,4-diaminopyridine (3,4-DAP). The amplitude of this component depended on external K concentration and fell to zero at [K]o = 15 mM. Since it also depended on [Ca]o, it was identified as a Ca-activated K current (IK(Ca)). Tetraethylammonium (TEA) (2 mM), Ba (2 mM), Co (10 mM) and Mn (2.5 mM) blocked IK(Ca). IK(Ca) decayed to zero in approximately 12 ms and recovered from inactivation in about 100 ms. Ca current was enhanced in inverse proportion to the degree of IK(Ca) depression. The possible role of IK(Ca) in the process of neuromuscular facilitation is briefly discussed.

A transient outward current in isolated cells from the crista terminalis of rabbit heart

Voltage-clamp experiments were carried out with the objective of identifying and characterizing the time- and voltage-dependent properties of a transient outward current recorded in single myocytes from the crista terminalis region of the rabbit heart. A collagenase enzymic dispersion procedure similar to that described by Desilets & Horackova (1982) was used to obtain these viable individual myocytes. Transmembrane ionic currents were recorded using a single micro-electrode voltage-clamp technique. In experiments aimed at studying a tetrodotoxin-resistant transient inward current, (ICa); a transient outward current was consistently recorded following blockade of ICa with Cd2+ (5 X 10(-4) M). The time and voltage dependence of the activation and inactivation of this current were measured. Its steady-state inactivation curve spans the voltage range -70 to -10 mV, and it is activated between -20 and +10 mV. The reversal potential of this transient outward current is approximately -75 mV in [K+]O 5 mM, suggesting that it is carried mainly by K+. This transient outward current can be inhibited completely by external application of 4-aminopyridine (4-AP, 3 mM). The time- and voltage-dependent properties, the reversal potential, and the sensitivity to 4-AP of this transient outward current are all very similar to those of a transient outward current first identified in molluscan neurones. Hence, we have labelled it, IA. Selective inhibition of IA and knowledge of its voltage- and time-dependent properties yield specific predictions concerning its role in the action potential of isolated crista terminalis cells. Consistent with these predictions, a decrease in stimulus rate is found to decrease the duration of the action potential and vice versa; and application of effective doses of 4-AP results in a substantial lengthening of the action potential. These results are discussed in terms of the possible physiological role of IA in subsidiary or follower pace-maker tissue, and the anatomical and physiological heterogeneity of the sino-atrial node region of the rabbit heart.

Ionic basis of the different action potential configurations of single guinea-pig atrial and ventricular myocytes

Single myocardial cells were enzymatically dispersed from guinea-pig atria and ventricles. At 25 degrees C, atrial cell action potentials differed significantly from ventricular cell action potentials in duration (atrial = 141 ms, ventricular = 497 ms) and over-shoot (atrial = +36 mV, ventricular = +42 mV). Action potentials of atrial and ventricular cells responded differently to changes in external K+ concentration ([K+]o). Elevation of [K+]o from 6 to 11 mM depolarized atrial cells but produced no significant change in action potential duration; similar changes in [K+]o depolarized ventricular cells and produced a significant shortening of the action potential duration. Voltage-clamp experiments were performed to investigate the ionic basis underlying the different action potential configurations of single atrial and ventricular myocytes. A single-micropipette voltage-clamp technique was used, employing either extremely small-tip diameter pipettes, without internal cell dialysis (Hume & Giles, 1983), or larger tip diameter pipettes, with internal dialysis (Hamill, Marty, Neher, Sakmann & Sigworth, 1981). Two significant differences in background K+ conductance in single atrial and ventricular myocytes were observed: (i) the isochronal (5 s) current-voltage relationship of single ventricular myocytes exhibited a region of prominent negative slope conductance and elevation of [K+]o produced cross-over; a negative slope conductance region was absent in atrial cells and elevation of [K+]o produced very little cross-over of isochronal current-voltage relationships, and (ii) hyperpolarizing voltage pulses applied from holding potentials of -50 mV elicited inward current in ventricular cells which decayed with time; similar voltage-clamp pulses in atrial cells elicited inward currents which fail to decay. Single K+ channel current measurements confirmed the existence of different resting K+ channel properties in single atrial and ventricular myocytes. Resting K+ channels in both cell types had similar single channel conductances (30-32 pS with [K+]o = 145 mM) but ventricular K+ channels had significantly slower gating kinetics compared to atrial K+ channels (ventricular K+ channel mean open time = 223 ms; atrial K+ channel mean open time = 1 ms at Vr (resting membrane potential) -20 mV). The plateau and duration of the guinea-pig ventricular action potential was insensitive to high concentrations of tetrodotoxin (3 X 10(-5) M) but extremely sensitive to external Ca2+ concentration ([Ca2+]o). The second inward Ca2+ current (iCa) density was estimated in small atrial and ventricular myocytes of similar diameter and length.(ABSTRACT TRUNCATED AT 400 WORDS)

The effects of caffeine and ryanodine on the electrical activity of the canine coronary sinus

Cells of the coronary sinus of the canine heart can exhibit triggered activity which each action potential arises from a depolarizing after-potential that follows the previous action potential; an early after-hyperpolarization commonly precedes the delayed after-depolarization and both are increased in amplitude by the addition of noradrenaline. The delayed after-depolarization is thought to be caused by an inward current activated by a rise in intracellular Ca2+ that is, in turn, caused by Ca2+-induced release of Ca2+ from the sarcoplasmic reticulum (s.r.). The effects of caffeine and of ryanodine on the electrical activity of the coronary sinus were investigated because each of those agents is thought to affect the handling of intracellular Ca2+ by the s.r. The steady-state effect of exposure to 5 mM-caffeine is to cause the delayed after-depolarization to move much earlier in the cycle, and become too small to give rise to an action potential so that preparations cannot show triggered activity; moreover, if a burst of activity is in progress it is terminated by exposure to 5 mM-caffeine. Exposure to 0.5 mM-caffeine causes the delayed after-depolarization to move earlier in the cycle but to become larger so that triggered activity is more easily induced and longer lasting than in the absence of caffeine. Shortly after the addition (or wash-out) of 5 mM-caffeine the after-depolarization transiently resembles that seen in the presence of 0.5 mM-caffeine so that bursts of triggered activity may occur just after the addition or removal of 5 mM-caffeine. Exposure to 5 mM-caffeine abolishes early rapid repolarization (phase 1), shifts the plateau to a more positive level and retards the completion of repolarization. The effect on phase 1 is mimicked by exposure to solutions low in Cl-; the effect on the plateau is mimicked by exposure to 20 mM-tetraethylammonium (TEA); fibres exposed to solutions containing 20 mM-TEA and 21 mM-Cl- show action potentials very like those of fibres exposed to 5 mM-caffeine. If a fibre already exposed to a low Cl-, TEA-containing solution is then exposed to 5 mM-caffeine, no further change occurs in the action potential but the characteristic effects of caffeine on the after-depolarization appear. Exposure to ryanodine prevents the appearance of the delayed after-depolarization but leads to the appearance of an exceptionally long depolarizing after-potential that begins very early in diastole and, though waning, persists almost throughout diastole.(ABSTRACT TRUNCATED AT 400 WORDS)

Delayed rectification in the calf cardiac Purkinje fiber. Evidence for multiple state kinetics

We have investigated the delayed rectifier current (Ix) in the calf cardiac Purkinje fiber using a conventional two-microelectrode voltage clamp arrangement. The deactivation of Ix was monitored by studying decaying current tails after the application of depolarizing voltage prepulses. The reversal potential (Vrev) of these Ix tails was measured as a function of prepulse magnitude and duration to test for possible permeant ion accumulation- or depletion-induced changes in Vrev. We found that prepulse-induced changes in Vrev were less than 5 mV, provided that prepulse durations were less than or equal to 3.5 s and magnitudes were less than or equal to +35 mV. We kept voltage pulse structures within these limits for the remainder of the experiments in this study. We studied the sensitivity of Vrev to variation in extracellular K+. The reversal potential for Ix is well described by a Goldman-Hodgkin-Katz relation for a channel permeable to Na+ and K+ with PNa/PK = 0.02. The deactivation of Ix was always found to be biexponential and the two components shared a common reversal potential. These results suggest that it is not necessary to postulate the existence of two populations of channels to account for the time course of the Ix tails. Rather, our results can quantitatively be reproduced by a model in which the Ix channel can exist in three (two closed, one open) conformational states connected by voltage dependent rate constants.

Transient outward current carried by potassium and sodium in quiescent atrioventricular node cells of rabbits

Single atrioventricular node cells were dispersed by treating the rabbit heart with collagenase. In Tyrode's solution, the cells became rounded, and about 20% of them showed spontaneous activity, whereas the rest remained quiescent. When those quiescent cells were whole-cell clamped, depolarizing clamp pulses from the holding potential of -83 mV induced an outward current which decayed quickly, with a time course similar to that of the transient outward current in the Purkinje fiber. The amplitude of the current became larger when progressively more positive clamp pulses were given from a very negative holding potential. The inactivation time course of this current consisted of two exponential components. Single-channel current recordings from those cells revealed a class of channels that activated more frequently during the initial part of depolarizing pulses. Summation of those unitary currents reproduced activation and inactivation time courses of the macroscopic current well, suggesting that this channel corresponds to the transient outward current. The current-voltage relationship of the channel was linear with the slope conductance of 19.9 +/- 1.8 pS (n = 7), and the reversal potential was near the resting potential of the atrioventricular node cell with 5.4 mM potassium chloride and 134.6 mM sodium chloride in the pipette. The channel was passing mainly potassium ions, but sodium ions also seemed to carry a fraction of the current. The possible role of the transient outward current in the quiescent node cell is discussed.

The calcium channel blocker nitrendipine blocks sodium channels in neonatal rat cardiac myocytes

The dihydropyridine calcium channel blocker, nitrendipine, was studied for its effects on the sodium current of single cultured ventricular cells from neonatal rats. The patch-clamp method of recording whole cell currents was used, and sodium currents were isolated by suppressing potassium and calcium currents. Potassium currents were blocked by replacing potassium with cesium in the internal and external solutions and by adding tetraethylammonium chloride and 4-aminopyridine in the external solution; calcium current was blocked by replacing calcium with cobalt in the external solution. At low frequencies (0.1 Hz), nitrendipine reduced sodium currents without any significant change in the current-voltage relation. The block was dose dependent, and assuming a single occupancy model with complete block, had a half-maximum value of 3 X 10(-6) M at a holding potential of -80 mV where half the sodium channels are activatable. This value is within the range of the Kd's that have been reported for low-affinity dihydropyridine-binding sites found in cardiac sarcolemmal vesicles. In the presence of nitrendipine, the inactivation curve was shifted to hyperpolarized potentials. The block was greater with pulse intervals shorter than 1000 msec, and repriming was prolonged in the presence of the drug. These effects are similar to those of local anesthetics of the tertiary amine class, such as lidocaine. The block was relieved by the dihydropyridine agonist Bay K8644. The results are interpreted as indicating that dihydropyridines react with sodium channels.

Modulation of slow response excitability by calcium in rabbit atrial trabeculae

Slow responses were induced in rabbit isolated left atrial trabeculae in a modified Tyrode solution containing 15 mM-KCl and 1 mM-BaCl2. Conventional electrophysiological techniques were employed for stimulating and recording membrane potentials. Under these conditions, the excitability of the slow response depends on the past excitatory history of the preparation. As the stimulation frequency increases (range: 0.08-1 Hz) for a conditioning period of stimulation, the excitability of the slow response increases. This can be demonstrated by a decrease in stimulus requirement necessary to maintain slow response excitation following the conditioning period of stimulation. It is shown that when extracellular Ca2+ concentration is reduced to 0.5 mM, that phenomenon of frequency-dependent slow response excitability disappears but slow responses can still be elicited. Also, the addition of D-600 to 2.7 mM-Ca2+ solutions depresses both the slow response and its frequency-dependent excitability. The absence of frequency-dependent slow response excitability is not related to the depression of the slow response upstroke caused by low-Ca2+ solutions. Increasing intracellular Ca2+ concentration by exposing the preparation to low-Na+ solutions or to ouabain did not revert the observed effects in low-Ca2+ solutions. The addition of substances (5 mM-caffeine or 0.35 microM-adrenaline) that potentiate the influx of Ca2+ in low-Ca2+ solutions was found to be effective in restoring the dependence of slow response excitability on the frequency of stimulation. The increase in extracellular Ca2+ above 4 mM depressed the excitation of the slow response. Above 5.4 mM-Ca2+, the excitation of the slow response was completely inhibited while the preparation displayed continuous oscillations in transmembrane potential. The presence of a subthreshold response (subliminal response) that precedes and triggers slow response excitation is accompanied by tension development. Since the subliminal response is responsible for the changes in slow response excitability it is proposed that the Ca2+ inflow during slow response electrogenesis modulates the excitability of the slow response. Two possible physiological implications for this finding are discussed.

Removal of Ca current inactivation in dialysed guinea-pig atrial cardioballs by Ca chelators

Ca currents flowing during voltage clamp depolarizations were studied in cultured guinea-pig atrial cardioballs by means of single low resistance patch clamp pipettes. The pipettes were filled with solutions containing Cs+ as major cation in order to block K+ currents and high concentrations of various Ca chelating agents (EGTA, nitrilotriacetic acid, citrate, dipicolinic acid) to prevent rises of the intracellular Ca-activity by Ca-entry. Ca currents of myocytes loaded with 20 mM of either EGTA [(ethylenedioxy)-diethylenedinitrilo)tetra-acetic acid] or NTA (nitrilotriacetic acid) display a biphasic time course of inactivation at membrane potentials between -25 and +45 mV. The fast phase is reduced with increasingly positive membrane potentials. In cells loaded with either citrate or DPA (dipicolinic acid, pyridine-2,6-dicarboxylic acid) inactivation is negligible or absent for small depolarizations. In the range of membrane potentials where maximum current flows (0-+10 mV) a monophasic slow time course of inactivation is observed. At more positive membrane potentials inactivation is slowed. The amount of inactivation under this condition is related to the current density of the cell. Conditions, which for a given membrane potential reduce the amplitude of ICa such as extracellular application of blocking ions (Co2+, Cd2+), a conditioning depolarization, or 'rundown' of Ca-channels lead to a slowing or a complete removal of inactivation in cells dialysed with citrate or DPA respectively. Cells loaded with these Ca chelators did not show any symptom of voltage dependent inactivation of ICa. Under the conditions described action potentials were recorded in the current clamp mode. Upon dialysis with EGTA the typical 'triangular shaped' atrial action potential develops a plateau of 500 to 800 ms in duration. With citrate-containing pipette solutions the action potential duration usually is several seconds. The results for the first time demonstrate that inactivation of cardiac ICa can be considerably slowed or even removed. They provide further strong support for the hypothesis that inactivation of this current depends on Ca entry rather than membrane potential. The fast phase of inactivation observed with EGTA (NTA) possibly reflects the slow kinetics of the binding reaction of this type of Ca chelators.

A fast transient outward current in the rat sympathetic neurone studied under voltage-clamp conditions

Post-ganglionic neurones of the isolated rat superior cervical ganglion were voltage clamped at 37 degrees C using separate intracellular voltage and current micro-electrodes. Control experiments in current clamp suggested that the neurone is electrotonically compact, the soma and the proximal dendritic membranes being under good spatial voltage uniformity. Depolarizing voltage steps from membrane potentials near -50 mV evoked: (i) a voltage-dependent inward Na+ current, (ii) an inward Ca2+ current, (iii) a voltage-dependent outward K+ current, (iv) a Ca2+-activated K+ outward current. Depolarizations from holding potentials more negative than -60 mV elicited, besides the currents mentioned above, a fast transient outward current IA which peaked in 1-2.5 ms and then decayed to zero following an exponential time course. The IA current was shown to be primarily, if not exclusively, carried by K+. It was unaffected by removal of external Ca2+ or addition of Cd2+ and was weakly blocked by tetraethylammonium ions and partially by 4-aminopyridine. The IA current showed a linear instantaneous current-voltage relationship. Its activation ranged from -60 to 0 mV with a mid-point at -30 mV. The A conductance could be described in terms of a simple Boltzmann distribution for a single gating particle with a valency of +3. Both the development and removal of inactivation followed a single exponential time course with a voltage-dependent time constant which was large near the resting potential (42 ms at -70 mV) and small (11 ms) near -100 and -40 mV. Steady-state inactivation h infinity ranged from -100 to -50 mV, with a mid-point at -78 mV, suggesting that approximately 50% of the IA channels are available at the physiological resting potential. Action potentials elicited from various holding potentials showed maximal repolarization rates dependent on the holding potential itself. This voltage dependence was found to be in reasonably good agreement with that of h infinity curve. These data are consistent with the view that in the rat sympathetic neurone, under physiological conditions, it is the IA current rather than the delayed outward current that is responsible for the fast action potential repolarization.

A dihydropyridine (Bay k 8644) that enhances calcium currents in guinea pig and calf myocardial cells. A new type of positive inotropic agent

Bay k 8644 is a structural analog of nifedipine with positive inotropic activity. The mechanism of drug action was evaluated by measuring the effects of Bay k 8644 on twitch tension, action potential configuration, and calcium channel currents in myocardial cells. Bay k 8644 increases twitch tension in guinea pig atria without changing the time course of tension development. The drug does not occlude the effect of isoproterenol on twitch tension. The effects of Bay k 8644 on atrial twitch tension are highly dependent on the frequency of stimulation. Maximal inotropic effects are observed at approximately 0.5 Hz, but no inotropic effect occurs at 0.003 Hz (a rested-state contraction). Since positive inotropic effects only occur with frequent electrical stimulation, they are not due to an intracellular action or to mechanisms that elevate cell calcium in quiescent muscle, such as inhibition of the Na,K-ATPase. Bay k 8644 increases the action potential duration of calf ventricular muscle and Purkinje fibers. Effects on action potential duration are occluded by 1 microM nisoldipine, which specifically blocks calcium channels. The interaction of Bay k 8644 with calcium channels in calf Purkinje fibers was studied using the two-microelectrode voltage clamp technique. Strontium was used as a charge carrier to minimize current through calcium-activated channels and to avoid changes in calcium conductance due to changes in intracellular calcium. Bay k 8644 increases strontium currents and alters the time- and voltage-dependence of channel opening. The greatest percent increase in strontium current occurs for weak depolarizations. For strong depolarizations, strontium current is increased most at the beginning of a test pulse. The drug-induced changes in calcium channel gating are inconsistent with a calcium- or cyclic adenosine monophosphate-mediated effect, and indicate a novel mechanism of action on calcium channels. Thus, Bay k 8644 is the first positive inotropic agent shown to act specifically and directly on calcium channels.

Ryanodine as a tool to determine the contributions of calcium entry and calcium release to the calcium transient and contraction of cardiac Purkinje fibers

Our object was to assess the relative roles of transsarcolemmal calcium entry and intracellular calcium release in the contraction of cardiac Purkinje fibers. We observed intracellular calcium transients, membrane potential, and contraction in aequorin-injected canine cardiac Purkinje fibers exposed to highly selective pharmacological modifiers of excitation-contraction coupling. To influence selectively the release of calcium from the sarcoplasmic reticulum, we used the plant alkaloid, ryanodine. To influence calcium entry, selectively, we used either the calcium channel antagonist, nitrendipine, or the calcium channel agonist, Bay k 8644. Ryanodine alone (1 microM) reduced both components of the intracellular aequorin luminescence signal (L1 and L2). In three muscles, the luminescence signals were 3% of control in amplitude (standard error of the mean, 2%) without two distinct components and the twitch tension was 2% of control (standard error of the mean, 3%), whereas the action potential was prolonged. The aequorin signal and twitch remaining in ryanodine were abolished by the calcium antagonist nitrendipine (10 microM), which also lowered the action potential plateau, consistent with the block of functional calcium channels. In two experiments, the calcium-channel agonist, Bay k 8644, in the presence of ryanodine, increased the aequorin luminescence and the contraction, but only to a very small fraction of their control values. Sodium withdrawal in potassium-free, ryanodine-containing solution produced large slow increases in calcium and tension, showing that tension could still be produced, that aequorin remained functional, and that sodium/calcium exchange was not inhibited by ryanodine. Caffeine increased intracellular calcium, showing that calcium stores were not depleted.(ABSTRACT TRUNCATED AT 250 WORDS)

A transient outward current related to calcium release and development of tension in elephant seal atrial fibres

Membrane currents and development of tension in atrial trabeculae from elephant seal hearts were studied using a single sucrose-gap voltage-clamp technique. A transient outward current (Ito) was observed with kinetics, voltage and beat dependence, similar to those of tension. Ito had a bell-shaped voltage dependence similar to that of tension and the slow inward current (Isi). Ito, unlike Isi, showed beat dependence quite similar to developed tension. Increases in [Ca]o, frequency of stimulation, and addition of adrenaline enhanced Ito and developed tension. Ito was suppressed by addition of Mn2+, tetracaine, or by depolarizing pre-pulses (to -40 mV for 250 ms). Caffeine at low concentrations (1 mM) blocked beat dependence of Ito. At higher concentrations (greater than 5 mM) caffeine suppressed the activation of Ito, phasic tension, and the second component of the birefringence signal (related to Ca2+-releasing activity of the sarcoplasmic reticulum (s.r.]. Similar to Isi phasic tension and Ito, the voltage dependence of the second component of the birefringence signal was bell-shaped. Our studies suggest that activation of Ito is related to triggered release of Ca2+ from the s.r. which generates the phasic tension. An excitation-contraction coupling scheme is presented which incorporates these findings and suggests that Ito may be responsible for shorter action potentials found in atrial fibres.

A model of sino-atrial node electrical activity based on a modification of the DiFrancesco-Noble (1984) equations

DiFrancesco & Noble's (1984) equations (Phil. Trans. R. Soc. Lond. B (in the press.] have been modified to apply to the mammalian sino-atrial node. The modifications are based on recent experimental work. The modified equations successfully reproduce action potential and pacemaker activity in the node. Slightly different versions have been developed for peripheral regions that show a maximum diastolic potential near --75 mV and for central regions that do not hyperpolarize beyond --60 to --65 mV. Variations in extracellular potassium influence the frequency of pacemaker activity in the s.a. node model very much less than they do in the Purkinje fibre model. This corresponds well to the experimental observation that the node is less sensitive to external [K] than are Purkinje fibres. Activation of the Na-K exchange pump in the model by increasing intracellular sodium can suppress pacemaker activity. This phenomenon may contribute to the mechanism of overdrive suppression.

The surprising heart: a review of recent progress in cardiac electrophysiology

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Ca2+-dependent K+ permeability of heart sarcolemmal vesicles. Modulation by cAMP-dependent protein kinase activity and by calmodulin

The Ca2+-dependent K+ permeability of heart sarcolemma vesicles was measured by following the transmembrane movement of the charge compensating tetraphenylborate anion. The increase in vesicles permeability induced by Ca2+ is lost when membrane proteins are dephosphorylated by an endogenous protein phosphatase and is restored by a phosphorylation process catalysed by a cAMP-dependent protein kinase. The calmodulin antagonist R 24571 lowers the Ca2+-dependent K+ permeability by decreasing the Ca2+ affinity of the K+ transporting system.

Cat ventricular muscle treated with D600: effects on calcium and potassium currents

In single sucrose-gap experiments on cat ventricular muscle strands stimulated with 300 ms pulses at 0.33 Hz, 2 microM-D600 reduced the Ca-dependent slow inward current (ICa) by 50% within 5 min and more than 90% in 90-120 min. The late outward current was reduced by up to 30%. During the exposure to D600, Ca channels could be unblocked by hyperpolarizing pulses and blocked again by stimulation with depolarizing pulses. Since the degree of unblocking depended on voltage, and the degree of blocking depended on stimulation pattern, ICa amplitude could be rapidly manipulated to probe the dependence of K conductance on ICa. Under control conditions, an increase in stimulation rate from 0.02 to 1 Hz reduced ICa by 15% and increased the late outward current by a smaller amount. During exposure to D600, a similar intervention provoked a 60% reduction in ICa, but a control-like increase in the late outward current. Two other series of experiments failed to disclose a link between ICa and K conductance: when a block of Ca channels was reimposed following their unblocking, the outward currents were independent of ICa amplitude. Unblock-block experiments also provided information on the extent of steady-state ICa at 0 mV. The fraction of Ca channels not undergoing inactivation appears to be very small. During full D600 block, the inward peak of the current wave form is broad and very much delayed in comparison with pre-drug currents or currents on the first pulse following unblocking. A similar wave form was recorded in D600-treated ventricular myocytes from cat but not guinea-pig. The likely explanation is that D600 unmasks a small transient outward current in cat ventricle.

Adenosine-5'-triphosphate-sensitive single potassium channel in the atrioventricular node cell of the rabbit heart

The patch-clamp method was applied to single atrioventricular (a.v.) node cells of the rabbit heart to study the characteristics of the K+ channel. When the electrode contained 5.4 mM-K+, depolarizations of the cell-attached patch membrane induced outward single channel currents characterized by burst-like openings; the open-state probability increased from 0.005-0.01 at -40 mV to 0.07-0.1 at +20 mV of membrane potential. The reversal potentials of the current at K+ concentrations of 5.4, 20 and 130 mM in the electrode agreed with those given by the Nernst equation, indicating that this channel is selective for K+ ions. The slope conductance of the channel decreased beyond 60-90 mV positive to the reversal potential (inward-going rectification). The conductance near the reversal potential increased with increasing K+ concentrations on either side of the membrane: from 31-32 pS at 5.4 mM-K+ to 41-42 pS at 20 mM-K+ on the outside, and from 19 pS at 90 mM-K+ to 29.3 pS at 130 mM-K+ on the inside. Superfusion of the cell with 5.4 mM-CN-, glucose-free Tyrode markedly increased the number of channel openings in the cell-attached patch. In the inside-out patch, application of 1 mM-adenosine-5'-triphosphate (ATP) at the inner surface of the patch membrane blocked reversibly the channel activity, while 1 mM-adenosine-5'-diphosphate (ADP) failed to block it. The conductance and kinetics of the channel were not modified by increasing the Ca2+ concentration from 10(-8) M to 5 X 10(-6) M on the inner side of the membrane, while a further increase in Ca2+ to 10(-4) M decreased the open-state probability. The probability density for the open time fitted well with an exponential distribution (time constant of 5.4 ms at 60 mV positive to the resting potential), while that for the closed time was separated into a fast and a slow component (time constants of 4.0 and 132.0 ms, respectively). The time constant of the slow component decreased significantly with depolarization in some preparations. However, neither the time constant of the fast component of the closed-time histogram nor that of the open-time histogram was voltage-dependent.

Damped oscillation in the ampullary electroreceptors of Plotosus involves Ca-activated transient K conductance in the basal membrane of receptor cells

K-blockers suppressed damped oscillation of Plotosus electroreceptors in situ. Ca-blockers abolished V-dependent non-linear responses, as well, and shifted the DC level in the ampulla by ca. -1 mV. Thus, the in situ receptor is held depolarized with maintained Ca current in the basal membrane of receptor cells. The oscillation involves Ca-activated transient K current in the same membrane, which contributes to the initial sensory adaptation, and presumably also to stabilizing the sensitive receptors.

Photoalteration of calcium channel blockade in the cardiac Purkinje fiber

Organic compounds that block calcium channel current (calcium antagonists) are important tools for the characterization of this channel. However, the practically irreversible nature of this block restricts the usefulness of this group of drugs. In this paper, we investigate the influence of light on calcium channel blockade by several organic compounds. Our results show that inhibition of calcium channel current by two dihydropyridine derivatives that contain an o-nitro moiety (nisoldipine and nifedipine) can be rapidly reversed by illumination. The energy range important to this reaction is for light wavelengths between 320 and 450 nm. Calcium channel inhibition by two other dihydropyridine derivatives (nicardipine and nitrendipine) as well as by D600, is not modulated by illumination. These results indicate that the photosensitivity of certain dihydropyridine calcium channel blockers make these compounds useful as reversible blockers of this channel.

Insulin-specific receptor-mediated slowing of beat rate in embryonic heart cells

Spheroidal aggregates of embryonic heart cells showed their spontaneous beat rate when exposed to insulin. The concentration that produced a half-maximal response (1.7 nM) corresponded to the dissociation constant of binding to a specific high-affinity insulin receptor. The pace-maker phase of action potentials recorded during insulin perfusion was preceded by a prolonged or flattened after hyperpolarization, and its slope was less steep than controls. The action potential duration was also prolonged. These results indicate that physiological concentrations of insulin can regulate the embryonic heart rate.

Strontium, nifedipine and 4-aminopyridine modify the time course of the action potential in cells from rat ventricular muscle

Action potentials, initiated by brief depolarizing pulses, were recorded from single cells isolated from rat ventricular muscle. These action potentials showed a rapid upstroke to about +30 mV, followed by two phases of repolarization referred to as the early and late phases of the action potential. Nifedipine (1 microM), which blocks the second inward current (Isi) carried by Ca in these cells, shortened the early phase. Substitution of strontium for calcium in the solution bathing the cells, a procedure which prolongs Isi, prolonged the early phase. 4-Aminopyridine (1 mM), which inhibits transient outward current, prolonged the early phase with either calcium or strontium in the external solution. It is concluded that both Isi and transient outward current contribute to the early phase of the action potential in rat ventricular muscle. It is also suggested that Isi does not directly contribute to the late phase, since the characteristics of the late phase are not compatible with such a role, and the possibility of additional inward current is investigated in the accompanying paper (Mitchell et al., 1984).

Excitation-contraction coupling in cardiac Purkinje fibers. Effects of caffeine on the intracellular [Ca2+] transient, membrane currents, and contraction

The effects of caffeine on tension, membrane potential, membrane currents, and intracellular [Ca2+], measured as the light emitted by the Ca2+-activated photoprotein aequorin, were studied in canine cardiac Purkinje fibers. An initial, transient, positive inotropic effect of caffeine was accompanied by a transient increase in the second component of the aequorin signal (L2) but not the first (L1). In the steady state, 4 or 10 mM caffeine always decreased twitch tension and greatly reduced both L1 and L2. At a concentration of 2 mM, caffeine usually reduced but occasionally increased the steady state twitch tension. However, 2 mM caffeine always reduced both L1 and L2. Caffeine eliminated the diastolic oscillations of intracellular [Ca2+] induced by high extracellular [Ca2+]. In voltage-clamp experiments, 10 mM caffeine reduced the transient outward current and the peak tension elicited by step depolarization from a holding potential of -45 mV. In the presence of 20 mM Cs+, 10 mM caffeine reduced slow inward current. However, the time course of this reduction was far slower than that in tension and light observed in separate experiments. The simplest explanation of the results is that caffeine inhibits the sequestration of Ca2+ by the sarcoplasmic reticulum. The results also suggest that in Purkinje fibers caffeine increases the sensitivity of the myofilaments to Ca2+.

Calcium and the mechanism of action of digitalis

A critical review is made of the mechanism by which digitalis increases the force of contraction of heart muscle. First, it is concluded that the initial step is always an inhibition of the sodium pump, and that the postulated stimulation of the pump by low digitalis concentrations is, possibly, not a real phenomenon. Secondly, the major theories that try to explain the inotropic effect of digitalis are analyzed, and it is tentatively concluded that the effect occurs because Na increases close to the inner side of the plasma membrane, and this decreases Ca efflux through the Na-Ca "exchange" mechanism. An internal Ca store, probably the sarcoplasmic reticulum, that competes with the plasma membrane for Ca, is then able to capture and, subsequently release, a larger fraction of the Ca mobilized during each transient. It is also concluded that the digitalis-induced larger Ca transients can be entirely explained because of a greater Ca "injection" into the cytoplasm during each beat, and not because of changes in resting pCa. A comprehensive model is presented that seems to explain in some detail both the inotropic and the toxic effect of digitalis.

Do calcium-activated potassium channels exist in the heart?

Changes of intracellular Ca concentration in cardiac muscle have significant effects on transmembrane currents and many of these effects can be accounted for by postulating the existence of Ca-activated K channels in the heart. However, the evidence that such channels exist is equivocal. This is partly because of technical problems, for example the difficulty of identifying an individual ionic current amongst the many currents that exist in the heart. An additional problem, however, is posed by the fact that other currents may also be modulated by Ca ions. It is important therefore to distinguish between these currents and those caused by Ca-activated, K-specific channels. In this review we consider the evidence for Ca activated currents in the heart and, in particular, we discuss whether or not these currents are carried exclusively by K ions.

Characteristics of the second inward current in cells isolated from rat ventricular muscle

The second inward current (Isi) in single cells isolated from ventricular muscle of adult rat hearts was measured in response to step depolarizations under voltage-clamp conditions. The major ion carrying this current was Ca, and Isi was reduced or abolished by Mn, Ni, Cd, nifedipine, nimodipine and D600. Sr and B could substitute for Ca as charge carriers, and reduced the rate of apparent inactivation of Isi. These effects of Sr and Ba, together with the relation between the steady level of apparent inactivation and membrane potential in Ca containing solution, were taken as evidence that inactivation was at least in part dependent on internal Ca. The reduction of external Na to 11% of normal caused a reduction in peak Isi when Ca was present in the external solution, but did not reduce Isi when Ca was replaced by Sr. It therefore seems unlikely that Na is a major charge carrier for Isi under the conditions of our experiments. The time-to-peak and rate of apparent inactivation of Isi were faster than in previous studies that used multicellular preparations. Both the kinetics and peak amplitude of Isi were markedly dependent on temperature (Q10 close to 3). Contraction of the cells, which was monitored optically, was initiated within 3 ms of the peak Isi, reached a maximum level after approximately 40-50 ms, and was about 100 ms in duration.

Transient outward current and rate dependence of action potential duration in rabbit cardiac ventricular muscle

A conventional (single sucrose gap) voltage clamp technique was employed to investigate the rate dependence of ionic currents activated in the plateau range of potential in the rabbit ventricular muscle. A transient outward current of increasing amplitude was observed when the period of rest preceding the test voltage clamp pulse was increased from 0.7-60 s. The action potential duration was short when the transient outward current peak (100-150 ms after the voltage clamp pulse beginning) was high under the studied conditions of stimulation (interbeat intervals 0.7-60 s). The rate dependent transient outward current was small at low levels of depolarization above the resting potential (40 mV), had a maximum at some 90-100 mV and decreased at more positive potentials. This current was sensitive to the simultaneous application of 4-aminopyridine and calcium substitution with strontium in the Tyrode solution. It is suggested that the transient outward current is probably responsible for the changes of the action potential duration in rabbit papillary muscles when the interbeat interval varies from some 0.7-60 s.

Simulation of potassium accumulation in clefts of Purkinje fibers: effect on membrane electrical activity

Purkinje fiber action potentials and concomitant intercellular cleft [K] variations were reconstructed by using modified McAllister, Noble & Tsien (1975) equations including the pump current, ip, and the pacemaker current, if. Three different mean cleft widths were chosen: 40, 200 and 1000 nm. Assuming a cylindrical arrangement of the cells in the bundle, the cleft [K] gradient across the bundle was calculated by using the radial cylindrical diffusion equation. The effects of varying several parameters (cleft width, tortuosity, ip and if) were studied in conditions corresponding to two different values of [K] in the bulk solution, namely 2.7 and 5.4 mM. The shortening influence on the action potential of the systolic increase in cleft [K] was detectable only in the case of the smallest cleft width. Reduction in electrogenic pump activity led to alterations of the electrical activity which depended on the cleft width. The evolution of the intercellular [K] during each action potential and the following diastolic period was normally biphasic; a small reaccumulation during the late part of the diastole was induced by the K component of the if current. Experimentally determined intercellular [K] variations described in the literature exhibit a monophasic evolution. Such a monophasic evolution could be reproduced after reduction of both if and the transient outward K current and suppression of the negative slope of the ik1-Em relationship. In this case the amplitude of the cyclic change in intercellular [K] was approximately equal to 0.2 mM (for a 200 nm cleft width), a value much lower than that experimentally recorded. Possible reasons for this discrepancy are discussed. A simplified three compartment model for K diffusion was also used. Results obtained with the two models demonstrated that the simplified model can be used as a reasonable approximation of the more complex radial diffusion model, with a reduction in computation time reaching 80% or more.

A transient calcium-dependent chloride current in the immature Xenopus oocyte

Ionic currents were studied in immature full-grown Xenopus oocytes using the two-micro-electrode voltage-clamp technique. Recordings of total membrane current showed a transient outward peak during depolarizations from the approximate resting voltage (-70 or -80 mV) to voltages more positive than -20 mV. The current-voltage relation for peak outward current was U-shaped, with a maximum at about 0 mV. Replacement of external Cl with methanesulphonate reversed this transient outward current to a transient inward current. Current relaxations recorded after the membrane potential was stepped to different voltages at the time of the peak showed a component that inverted at about -25 to -30 mV. This value was close to ECl as determined by measurement of the intracellular Cl ion concentration. The reversal potential for these current relaxations changed with the external Cl concentration as predicted by the Nernst relation. Replacement of external Ca with Mg, Sr or Ba, or addition of low concentrations of Ni in the presence of Ca, eliminated the transient outward current. Increasing the external Ca concentration increased the amplitude of the transient outward current without affecting the amplitude of the steady-state current. It was concluded that the outward peak in records of total membrane current represented the contribution of a transient outward current carried by Cl ions which was dependent on the entry of external Ca. It will be noted as ICl(Ca). Decay of ICl(Ca) could be described at the normal Ca concentration by a single exponential function whose time constant showed a shallow U-shaped voltage dependence. ICl(Ca) was maximally activatable by depolarizations from a holding potential of about -100 mV, but could not be activated by depolarizations from -40 mV. The amplitude of ICl(Ca) showed a large temperature dependence as compared to the steady-state current, suggesting complex control of its activation.

Voltage- and frequency-dependent block of diltiazem on the slow inward current and generation of tension in frog ventricular muscle

The effects of a new "Ca2+ -antagonist", diltiazem, were studied in frog ventricular myocardium. The single sucrose gap voltage clamp technique was used to control membrane potential and measure membrane current and tension. Diltiazem had no effect on the resting potential, but reduced the slow inward current (Isi) and increased the net outward current. Membrane conductance measurements suggest that the increase in the total membrane current may be due to the suppression of a maintained inward current. The blocking action of diltiazem is frequency-dependent such that at higher frequencies of stimulation, the steady-state amplitude of twitch is reduced. The diltiazem-induced suppression of tension and Isi could be partially reversed by hyperpolarizing the surface membrane for brief intervals. These results suggest that diltiazem blocks Isi in a voltage- and time-dependent manner. These effects of diltiazem on Isi seem to be, in part, responsible for the tension-suppressant effect of the drug.

A voltage-clamp analysis of inward (anomalous) rectification in mouse spinal sensory ganglion neurones

Mouse embryo dorsal root ganglion neurones were grown in tissue culture and voltage-clamped with two micro-electrodes. Hyperpolarizing voltage commands from holding potentials of -50 to -60 mV evoked slow inward current relaxations which were followed by inward tail currents on repolarization to the holding potential. These relaxations are due to the presence of a time- and voltage-dependent conductance provisionally termed Gh. Gh activates over the membrane potential range -60 to -120 mV. The presence of Gh causes time-dependent rectification in the current-voltage relationship measured between -60 and -120 mV. Gh does not inactivate within this range and thus generates a steady inward current at hyperpolarized membrane potentials. The current carried by Gh increases when the extracellular K+ concentration is raised, and is greatly reduced in Na+-free solutions. Current-voltage plots show considerably less inward rectification in Na+-free solution; conversely inward rectification is markedly enhanced when the extracellular K+ concentration is raised. The reversal potential of Ih is close to -30 mV in media of physiological composition. Tail-current measurement suggests that Ih is a mixed Na+-K+ current. Low concentrations of Cs+ reversibly block Ih and produce outward rectification in the steady-state current-voltage relationship recorded between membrane potentials of -60 and -120 mV. Cs+ also reversibly abolishes the sag and depolarizing overshoot that distort hyperpolarizing electrotonic potentials recorded in current-clamp experiments. Impermeant anion substitutes reversibly block Ih; this block is different from that produced by Cs+ or Na+-free solutions: Cs+ produces outward rectification in the steady-state current-voltage relationship recorded over the Ih activation range; in Na+-free solutions inward rectification, of reduced amplitude, can still be recorded since Ih is a mixed Na+-K+ current; in anion-substituted solutions the current-voltage relationship becomes approximately linear. It is concluded that in dorsal root ganglion neurones anomalous rectification is generated by the time-and voltage-dependent current Ih. The possible function of Ih in sensory neurones is discussed.

Phenytoin reduces calcium current in the cardiac Purkinje fiber

We have investigated the effects of phenytoin on the electrical and mechanical activity of isolated calf and dog cardiac Purkinje fibers. Phenytoin (5-100 microM) lowers and shortens the plateau phase of the Purkinje fiber action potential and reduces twitch tension. We studied the ionic basis of these effects by combining a conventional two-microelectrode voltage clamp procedure with pharmacological techniques that allow separation of time-dependent plateau membrane currents. We find that phenytoin reduces voltage-dependent calcium current in the Purkinje fiber. In addition, this drug slightly reduces two time-dependent outward currents. These effects of phenytoin on membrane current account, at least in part, for its influence on the action potential and twitch tension.

Calcium buffering and slow recovery kinetics of calcium-dependent outward current in molluscan neurones

Calcium entry into molluscan neurones during depolarizing voltage-clamp steps activates an outward current which on repolarization decays over periods of more than 30 sec. This slowly decaying tail current was used to study the relation between calcium buffering in cytoplasm and the decline of a calcium-activated membrane process. Calcium-dependent outward current was also studied after injection of calcium into the cytoplasm. The time course of the fall of outward tail current was much less sensitive than tail current amplitude to the amount of calcium entry. Increasing bath temperature from 5 to 15 degrees C decreased the rate of fall of outward tail current activated by calcium entry. In contrast, outward current activated by calcium injection declined more rapidly at higher temperatures. Injection of sufficient EGTA to give maximum depression of outward current during depolarizations reduced the amplitude of outward tail current by at most 50%. After EGTA injection outward tail current declined more rapidly immediately following repolarization, but returned to base line at about the same time as the control. After injection of EGTA, outward current activated by calcium injection was reduced or completely blocked, and returned to base line more rapidly. Application of the mitochondrial uncoupler carbonyl cyanide m-chlorophenyl hydrazone (CCCP) did not alter the decay time course of outward tail current, but markedly prolonged the decline of outward current activated by calcium injection. The slow kinetics of outward tail current were compared to predictions of the concentration of calcium ions at the outermost surface of a spherical model cell following calcium influx. We conclude that after depolarization and calcium entry, the diffusion and binding of free calcium to cytoplasmic buffers plays a key role in determining the rate of fall of outward tail current. Further, different mechanisms influence the decline of calcium-dependent outward current following injection of calcium into the cytosol.

Drosophila mutants reveal two components of fast outward current

The gating of potassium ion channels has been shown to be dependent on voltage or Ca2+ ions or both 4,5. A fast transient potassium current (sometimes denoted IA) is found in a wide variety of animals. The Ca2+-sensitivity of this early outward current has been a matter of dispute as reports from different systems have indicated complete insensitivity, marked sensitivity or only partial sensitivity. It is possible that there are two distinct early outward current systems, one Ca2+-sensitive and the other not. Thus, the reports of partial Ca2+-sensitivity would indicate the presence of both systems in the membrane. I now report that in the adult Drosophila flight muscles, the transient outward current is also partially Ca2+-sensitive. The hypothesis that two separate currents are present is strengthened by the discovery that in several mutants of the X-linked Shaker locus (ShKS133, Sh102 and ShK0120): the Ca2+-independent component (IAci) is absent with only the Ca2+-dependent component (IAcd) remaining. Hence, the mutations seem to delete one of two separate current systems. An alternative hypothesis is that only one channel type is present that can be modified by mutation to be totally Ca2+-dependent.

Voltage-clamp studies on the canine Purkinje strand

Purkinje strands were excised from the left and right ventricles of adult mongrel dogs and cut to lengths of less than 2.0 mm in order to apply the two-microelectrodes voltage-clamp technique. A sizeable fraction of these preparations fully recover following dissection, with resting potentials more negative than--80 mV and upstroke velocities faster than 290 V s-1. Analysis of the voltage response to small current pulses shows that the short Purkinje strands can be treated as simple finite one-dimensional cables with ends of infinite resistance. The average length constant is 2.5 mm. In keeping with the relatively long length constant, insertion of a third microelectrode along the strand demonstrates a high degree of longitudinal homogeneity of the voltage clamp. Analysis of the capacity transient gives an estimate of the total capacity, normalized to cylindrical surface area, of 11.5 muF cm-2. The final decay of the capacity transient is a single exponential with an average time constant of 1 ms. A second slower component to the final decay of the capacity transient is absent in solutions of normal conductivity as well as in solutions of reduced (13%) conductivity. This suggests that the extracellular series resistance may be relatively small. The magnitude of the K+ depletion current was estimated by measuring the ratio of depletion current to instantaneous current. This ratio averaged 10%. These two results are consistent with the morphometric data described in the accompanying paper, which show that the canine preparation has wider extracellular clefts than the ungulate preparation. The existence of the full complement of inward and outward currents, including the pacemaker current, is demonstrated. The presence of wide clefts does not affect the potential at which the pacemaker current reverses (about--107 mV in 4 mM [K+] Tyrode solution), since the pacemaker current reverses at approximately the same potential in the canine Purkinje preparation as it does in the ungulate.

The ultrastructure of the cardiac Purkinje strand in the dog: a morphometric analysis

Purkinje strands from both ventricles of adult mongrel dogs were excised, and electrical properties were studied by the voltage-clamp technique. The strands were then examined with light and electron microscopy and structural properties were analysed by morphometric techniques. The canine Purkinje strand contains (by volume) about 28% myocyte and 55% dense outer connective tissue. The remainder of the volume is taken up by the inner shell of loosely packed connective tissue within 10 microns of a myocyte membrane. These volume fractions vary considerably from one strand to another. Clefts less than 10 microns wide occupy 18% of the myocyte volume and clefts less than 1 micron wide occupy 1%. The membrane surface area of the myocytes can be divided into three categories by reference to the size of the adjacent cleft. About 47.8% of the membrane surface area faces clefts wider than 1 micron, another 22.2% faces clefts between 0.1 and 1 micron wide, and the final 30% faces clefts less than 0.1 micron wide. The surface area facing the narrowest clefts (less than 0.1 micron wide) is divided between nexuses 3%, desmosomes 10%, and unspecialized membrane 17% (each figure is expressed as a percentage of the total surface area of myocyte membrane). The canine Purkinje strand has a more favourable anatomy than the sheep Purkinje strand for most physiological experiments. We expect that the complicating effects of series resistance and change in the concentration of extracellular ions will be much smaller than in sheep strands, but still not negligible.

Action potential repolarization may involve a transient, Ca2+-sensitive outward current in a vertebrate neurone

Repolarization of the action potential in squid axon1 and several types of neurones2-4 involves a voltage-activated potassium (K+) current. Voltage clamp analysis has demonstrated that this current has rapid activation kinetics1,3-5. In several neuronal types, the same technique has also revealed a slowly activated K+ current that is calcium (Ca2+)-sensitive3,5-10. This slow Ca2+-activated K+ current is the major current underlying the late, slower portion of the after-hyperpolarization following an action potential11-14. In several muscle types, fast, transient Ca2+-dependent K+ currents have been described15-17 which may contribute to repolarization of the action potential. Rapidly activating, Ca2+-dependent K+ currents have been observed in sympathetic neurones of the bullfrog and it has been suggested that they contribute to action potential repolarization of those neurones8,9,18. We have studied the membrane currents in bullfrog sympathetic neurones using voltage clamp methods and report here a transient outward current that appears to be composed of two separate currents. One of those currents is a transient, Ca2+-sensitive outward current as indicated by a significant reduction of the current by treatments that reduce or block Ca2+ entry (Mn2+, Cd2+, Co2+, Mg2+ or Ca2+-free Ringer). Such treatments also decreased the rate of action potential repolarization. The results suggest that this current is involved in repolarization of the action potential and consequently may regulate Ca2+ entry into the neurone during spike activity.