Reversal of lidocaine effects on sodium currents by isoproterenol in rabbit hearts and heart cells.

We demonstrated recently that isoproterenol enhanced the cardiac voltage-dependent sodium currents (INa) in rabbit ventricular myocytes through dual G-protein regulatory pathways. In this study, we tested the hypothesis that isoproterenol reverses the sodium channel blocking effects of class I antiarrhythmic drugs through modulation of INa. The experiments were performed in rabbit ventricular myocytes using whole-cell patch-clamp techniques. Reversal of lidocaine suppression of INa by isoproterenol (1 microM) was significant at various concentrations of lidocaine (20, 65, and 100 microM, P < 0.05). The effects of isoproterenol were voltage dependent, showing reversal of INa suppression by lidocaine at normal and hyperpolarized potentials (negative to -80 mV) but not at depolarized potentials. Isoproterenol enhanced sodium channel availability but did not alter the steady state activation or inactivation of INa nor did it improve sodium channel recovery in the presence of lidocaine. The physiological significance of the single cell INa findings were corroborated by measurements of conduction velocities using an epicardial mapping system in isolated rabbit hearts. Lidocaine (10 microM) significantly suppressed epicardial impulse conduction in both longitudinal (theta L, 0.430 +/- 0.024 vs. 0.585 +/- 0.001 m/s at baseline, n = 7, P < 0.001) and transverse (theta T, 0.206 +/- 0.012 vs. 0.257 +/- 0.014 m/s at baseline, n = 8, P < 0.001) directions. Isoproterenol (0.05 microM) significantly reversed the lidocaine effects with theta L of 0.503 +/- 0.027 m/s and theta T of 0.234 +/- 0.015 m/s (P = 0.014 and 0.004 compared with the respective lidocaine measurements). These results suggest that enhancement of INa is an important mechanism by which isoproterenol reverses the effects of class I antiarrhythmic drugs.

Evidence that the FSH receptor itself is not a calcium channel.

FSH has been shown to stimulate the uptake of calcium in cultured rat Sertoli cells, resulting in an increase in cytosolic calcium concentrations. One possibility which has been put forth is that the FSH receptor per se may act as a calcium channel. This is all the more tantalizing given the proposed structure of this receptor which, like all other G protein-coupled receptors, is thought to have the putative transmembrane helices forming a bundle-like structure in the plasma membrane. To test whether the FSH receptor could function as a calcium channel, we performed whole-cell voltage clamp experiments on 293 and 293F(wt1) cells, which are a clonal line of 293 cells expressing high levels of rat FSH receptors. The 293 cells, which do not express FSH receptors, were found to lack any detectable inward calcium currents, and therefore, serve as an excellent model for transfecting with potential calcium conducting FSH receptors. When the 293F(wt1) cells were then tested, no inward calcium currents could be detected in either control or FSH-stimulated cells. These results suggest that the FSH receptor itself is not a calcium channel and, therefore, FSH must be stimulating endogenous calcium channels in rat Sertoli cell plasma membranes.

Structural and mechanical adaptation of immature bone to strenuous exercise.

To investigate the adaptive responses of immature bone to increased loads, young (3-wk-old) White Leghorn roosters were subjected to moderately intense treadmill running for 5 or 9 wk. The training program induced significant increases in maximal O2 consumption and muscle fumarase activity in the 12-wk-old birds, demonstrating that growing chickens have the ability to enhance their aerobic capacity. The structural and mechanical properties of the runners' tarsometatarsus bones were compared with sedentary age-matched controls at 8 and 12 wk of age. Suppression of circumferential growth occurred with exercise at both ages, whereas exercise enhanced middiaphysial cortical thickening, especially on the bones' concave surfaces. Although cross-sectional area moments of inertia did not change with exercise, significant decreases in bending stiffness, energy to yield, and energy to fracture were observed. It was concluded that strenuous exercise may retard long-bone maturation, resulting in more compliant bones.

A voltage-dependent potassium current in rabbit coronary artery smooth muscle cells.

1. Voltage- and time-dependent outward currents were recorded from relaxed enzymatically isolated smooth muscle cells from the rabbit left descending coronary artery using a single pipette voltage clamp technique. The calcium-activated potassium current was blocked by inclusion of EGTA in the pipette solution and CdCl2 in the extracellular bath. 2. Outward currents were elicited with depolarizing voltage steps to potentials positive to -20 mV. Long (5 s) voltage steps revealed slow inactivation of the current with a time constant of nearly 3 s at +60 mV. Potassium was identified as the predominant charge carrier by reversal potential measurements in potassium substitution experiments. 3. The results of kinetic analyses compared favourably with the Hodgkin-Huxley model for a delayed rectifier with some deviations. The sigmoid current onset was best fitted by raising the activation variable (n) to the second power. Deactivation tail currents were consistently found to be comprised of two exponential components. The kinetics of activation and deactivation were strongly voltage-dependent from -80 to +60 mV. 4. Envelope of tails experiments showed that the scaled tail current amplitudes followed the kinetic behaviour of current activation. The contribution of each of the two exponential tail components was also measured in these experiments. They did not reveal kinetically separable currents, nor were they differentially altered by 4-aminopyridine (4-AP), tetraethylammonium (TEA), or elevated [K+]o. 5. The steady-state voltage-dependence curves for both activation and inactivation were well fitted by a Boltzmann distribution with V1/2 = -5.60 mV and k = -8.66 mV for n infinity act and V1/2 = -24.20 mV and k = 5.16 mV for n infinity act. Super-imposition of the two curves revealed a 'window' of voltage where channels are available for activation without completely inactivating. 6. Neither of the commonly used potassium channel blockers, TEA or 4-AP, were particularly effective blockers of IK, reducing current by only 50-70% at an extracellular concentration of 10 mM. TEA block was mildly voltage-dependent and was more effective in reducing current towards the end of a 500 ms depolarization. 4-AP, on the other hand, demonstrated considerable voltage-dependence and preferentially reduced early currents. 7. Outward currents recorded from guinea-pig and human coronary artery myocytes under the same conditions as in the rabbit cell experiments displayed similar characteristics.(ABSTRACT TRUNCATED AT 400 WORDS)

Acetylcholine reversal of isoproterenol-stimulated sodium currents in rabbit ventricular myocytes.

We have recently shown that beta-adrenergic agonists enhance the cardiac sodium current (INa) in rabbits through dual G-protein regulatory pathways. To determine if muscarinic cholinergic receptor stimulation can also modulate INa, we studied the effects of acetylcholine (ACh) and carbachol on INa in enzymatically dispersed rabbit ventricular myocytes. Whole-cell patch-clamp experiments done at room temperature using 20 mM [Na+]o showed that 100 nM isoproterenol increased INa and accelerated current decay as previously described. ACh (1 microM) or carbachol (1 microM) significantly reversed the stimulatory isoproterenol effects at test potentials throughout the INa activation range and at holding potentials negative to -80 mV. This effect was completely inhibited by atropine (1 microM) and was confirmed by studying single-channel INa from cell-attached patches. When INa was stimulated by forskolin (1 microM), carbachol (1 microM) significantly reversed the effect. The muscarinic-mediated inhibition of INa was inhibited by pertussis toxin (0.1 or 1.0 microgram/ml) incubation (12-15 hours), suggesting that the effect was inhibitory G-protein dependent. Further investigation of the ACh inhibitory mechanism revealed that ACh alone had no effect on INa and that when cells were dialyzed with cAMP (5 microM), ACh failed to inhibit INa. Furthermore, cGMP failed to inhibit the effect of isoproterenol on INa. These data suggest that ACh acts at or proximal to adenylate cyclase stimulation. Thus, rabbit cardiac Na+ channels are regulated by muscarinic agonists in a fashion similar to cardiac Ca2+ channels.

Enhancement of rabbit cardiac sodium channels by beta-adrenergic stimulation.

Voltage-dependent sodium channels from a variety of tissues are known to be phosphorylated by the cAMP-dependent protein kinase, protein kinase A. However, the functional significance of sodium channel phosphorylation is not clearly understood. Using whole-cell voltage-clamp techniques, we show that sodium currents (INas) in rabbit cardiac myocytes are enhanced by isoproterenol (ISO). This enhancement of INa by ISO 1) is holding potential dependent, 2) can be mimicked by forskolin and dibutyryl cAMP, and 3) is accompanied by an increase in the rate of Na+ channel inactivation. In single-channel, inside-out patch experiments, the catalytic subunit of protein kinase A also enhances INa and increases the rate of inactivation, suggesting that cardiac Na+ channel phosphorylation may be physiologically important. Addition of the protein kinase A inhibitor to the pipette solution in whole-cell experiments blocks the stimulatory effect of forskolin without blocking the effect of ISO, suggesting that ISO also enhances INa through a cAMP-independent pathway. To determine if ISO may stimulate INa through a direct G protein pathway, single channels were recorded in the presence of the Gs-activating GTP analogue, GTP gamma S, and the stimulatory G protein subunit, Gs alpha. Both of these agents enhanced INa without affecting the rate of Na+ channel inactivation. These results suggest that ISO enhances rabbit cardiac INa through a dual (direct and indirect) G protein regulatory pathway.

Calcium currents in isolated rabbit coronary arterial smooth muscle myocytes.

1. Calcium inward currents were recorded from relaxed enzymatically isolated smooth muscle cells from the rabbit epicardial left descending coronary artery using a single-pipette voltage-clamp technique. Outward K+ currents were blocked with CsCl-tetraethylammonium-filled pipette solutions. 2. Relaxed coronary smooth muscle cells had a maximum diameter of 8.6 +/- 0.6 microns and a cell length of 96.7 +/- 3.3 microns when bathed in 2.5 mM [Ca2+]o. The average resting membrane potential at room temperature was -32 +/- 10 mV. The mean cell capacitance was 18.5 +/- 1.7 pF and the input resistance was 3.79 +/- 0.58 G omega. 3. Depolarizing voltage-clamp steps from a holding potential of -80 mV elicited a single time- and voltage-dependent inward current which was dependent upon extracellular [Ca2+]. In 2.5 mM [Ca2+]o, the inward current was activated at a potential of -40 mV and peaked at +10 mV. This current was inhibited by 0.5 mM-CdCl2 and 1 microM-nifedipine and was enhanced with 1 microM-Bay K 8644. No detectable low-threshold, rapidly inactivating T-type calcium current was observed. 4. The apparent reversal potential of this inward current in 2.5 mM [Ca2+]o was +70 mV and shifted by 33.0 mV per tenfold increase in [Ca2+]o. This channel was also more permeable to barium and strontium ions than to calcium ions. 5. Single calcium channel recordings with 110 mM-Ba2+ as the charge carrier revealed a mean slope conductance of 20.7 +/- 0.8 pS. 6. This calcium current (ICa) exhibited a strong voltage-dependent inactivation process. However, the steady-state inactivation curve (f infinity) displayed a slight nonmonotonic, U-shaped dependence upon membrane potential. The potential at which half of the channels were inactivated was -27.9 mV with a slope factor of 6.9 mV. The steady-state activation curve (d infinity) was also well-described by a Boltzmann distribution with a half-activation potential at -4.4 mV and a slope factor of -63 mV. ICa was fully activated at approximately +20 mV. 7. The rate of inactivation was dependent upon the species of ion carrying the current. Both Sr2+ and Ba2+ decreased the rate as well as the degree of inactivation. The tau f (fitted time constant of inactivation) curve displayed a U-shaped relationship in 2.5 mM [Ca2+]o. The reactivation process was voltage dependent and could be described by a single exponential. 8. The current amplitude and the inactivation kinetics were temperature dependent.(ABSTRACT TRUNCATED AT 400 WORDS)