Spontaneous electrical activity and indo 1 fluorescence ratios were recorded simultaneously in cultured pacemaker cells isolated from the rabbit sinoatrial node. Ryanodine (10 μM) reduced the amplitude of action potential-induced intracellular Ca2+([Formula: see text]) transients by 19 ± 3%, increased the time constant for their decay by 51 ± 5%, and slowed spontaneous firing by 32 ± 3%. 1,2-Bis(2-aminophenoxy)ethane- N, N, N′, N′-tetraacetic acid (BAPTA)-acetoxymethyl ester (AM; 25 μM) inhibited the [Formula: see text] transients and slowed spontaneous firing by 28 ± 4%. Ryanodine did not alter hyperpolarization-activated or time-independent inward current, but it reduced the sum of L- and T-type Ca2+ currents ( I Ca,L and I Ca,T) in both the presence and absence of BAPTA-AM. In contrast, I Ca,L was unchanged by ryanodine. Slow inward current tails, presumed to be Na/Ca exchange current ( I Na/Ca), were abolished by BAPTA or ryanodine. The results suggest that a decrement of I Ca,T, due to reduction of the intracellular Ca2+ concentration or a direct effect of ryanodine on T-type Ca2+channels, contributes to the negative chronotropic effect. Another possibility, based primarily on theory and results in other preparations, is that a reduction of I Na/Ca, as a consequence of the smaller action potential-induced[Formula: see text] transients, contributes to the effect of ryanodine.
A tetrodotoxin (TTX)-sensitive Na+ current (iNa) was investigated in single pacemaker cells after 1-4 days in culture. Ruptured-patch and perforated-patch whole cell recording techniques were used to record iNa and spontaneous electrical activity, respectively. For seven cells exposed to 20 mM Na+ (22-24 degrees C) and held at -98 mV (25% of the channels inactivated), the uncorrected maximum iNa was -39 +/- 10 pA/pF at -29.1 +/- 2.4 (SE) mV, maximum conductance was 0.9 +/- 0.2 nS/pF (1.6 +/- 0.2 mS/cm2). Half-activation and inactivation potentials were -41.4 +/- 2.0 and -90.6 +/- 2.5 mV, and the corresponding slope factors were 6.0 +/- 0.4 and 6.4 +/- 0.6 mV. Inactivation and recovery from inactivation were best fit by sums of two exponentials. During action potential clamp, a TTX-sensitive compensation current accounted for 55% of the upstroke velocity. The results suggest that iNa contributes significantly to the action potential in some nodal pacemaker cells, and the characteristics of iNa are similar to those of atrial and ventricular myocytes.
A B S T R A C T The double-microelectrode voltage clamp technique was applied tosmall spheroidal aggregates of heart cells from 7-d chick embryos. A third intracellular electrode was sometimes used to monitor spatial homogeneity. On average, aggregates were found to deviate from isopotentiality by 12% during the first 3-5 ms of large depolarizing voltage steps, when inward current was maximal, and by <3% thereafter. Two components of inward current were recorded: (a) a fast, transient current associated with the rapid upstroke of the action potential, which was abolished by tetrodotoxin (TTX); and (b) a slower inward current related to the plateau, which was not affected by TTX but was blocked by D600. The magnitudes, kinetics, and voltage dependence of these two inward currents and a delayed outward current were similar to those reported for adult cardiac preparations. From a holding potential of -60 mV, the peak fast component at the point of maximal activation (-20 mV) was -185 gA/cm ~. This value was about seven times greater than the maximal slow component which peaked at 0 mV. The ratio of rate constants for the decay of the two currents was between 10:1 and 30:1.
Individual myocytes were isolated from bullfrog atrium by enzymatic and mechanical dispersion, and a one-microelectrode voltage clamp was used to record the slow outward K + currents . In normal [K'']o (2 .5 mM), the slow outward current tails reverse between -95 and -100 mV . This finding, and the observed 51-mV shift of E, /10-fold change in [K'']o, strongly suggest that the "delayed rectifier" in bullfrog atrial cells is a K+ current . This current, IK, plays an important role in initiating repolarization, and it is distinct from the quasi-instantaneous, inwardly rectifying background current, IK,. In atrial cells, IK does not exhibit inactivation, and very long depolarizing clamp steps (20 s) can be applied without producing extracellular K+ accumulation . The possibility of [K''] . accumulation contributing to these slow outward current changes was assessed by (a) comparing reversal potentials measured after short sponding envelope of tails demonstrate that the activation variable, n, must be raised to the second power to fit the sigmoid onset accurately . The voltage dependence of the kinetics of IK was studied by recording and curve-fitting activating and deactivating (tail) currents . The resulting I/7" curve is U-shaped and somewhat asymmetric ; IK exhibits strong voltage dependence in the diastolic 88 . 1986 range of potentials . Changes in the [Ca"], in the superfusing Ringer's, and/or addition of La" to block the transmembrane Ca" current, show that the time course and magnitude of IK are not significantly modulated by transmembrane Ca 2+ movements, i.e., by Imo. These experimentally measured voltage-and timedependent descriptors of IK strongly suggest an important functional role for IK in atrial tissue : it initiates repolarization and can be an important determinant of rate-induced changes in action potential duration .
The whole cell configuration of the patch-clamp technique was used to test the hypothesis that the presence of sialic acid residues influences both T- and L-type Ca2+ currents (ICa,T and ICa,L) in cultured pacemaker cells isolated from the rabbit sinoatrial node. Removal of these anionic sugar moieties by neuraminidase (1.0 U/ml for 5-20 min) increased ICa,T in five of nine cells (by a factor of 2.2-5.1) and ICa,L in three of six cells (by a factor of 1.2-1.6). In cells that did not exhibit such an increase, the enzyme reduced ICa,T but had no significant effect on ICa,L. In cells that exhibited an increase in ICa,T, exposure to neuraminidase also shifted the activation curve to more negative potentials and increased the slope of the inactivation curve. The enzyme did not influence the gating of ICa,L or the rates of inactivation of either ICa,T or ICa,L. The enhancement of ICa,T and ICa,L could not be mimicked by including neuraminidase in the patch pipette or by adding a contaminant of the enzyme preparation, phospholipase C, to the bath. When external Ca2+ was replaced by Ba2+, neither ICa,T nor ICa,L was increased significantly by neuraminidase. It is proposed that by removing sialic acid residues neuraminidase might directly alter the gating of T-type Ca2+ channels. On the other hand, the increased amplitudes of ICa,T and ICa,L might be due to a rise in intracellular Ca2+.
Previous investigations employing multicellular nodal preparations (i.e., mixtures of dominant and subsidiary pacemaker cells) have suggested that the fast transient inward sodium current (iNa) either is not present in dominant pacemaker cells or is present but inactivated at the depolarized take-off potentials that these cells exhibit. In the present study, this question was resolved by voltage clamp analysis of single pacemaker cells isolated from the sinoatrial node and maintained in vitro for 1-3 days. Two types of cells, each with a different morphology, exhibited two modes of electrophysiological behavior. Type I cells (presumably dominant pacemakers) displayed only a tetrodotoxin (TTX)-resistant (but cadmium-sensitive) slow inward current, whereas type II cells (presumably subsidiary pacemakers) exhibited two components of inward current, a TTX-sensitive, fast transient inward current and a TTX-resistant (but cadmium-sensitive) slow inward current. Three other voltage-gated currents, 1) a slowly developing inward current activated by hyperpolarization (if, ih, delta ip), 2) a transient outward current activated by strong depolarization (ito, iA), and 3) a delayed outward current, were recorded in both types of pacemaker cells.
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