Chloride action potentials and currents in embryonic skeletal muscle of the chick

Abstract Chloride‐dependent action potentials were elicited from embryonic skeletal muscle fibers of the chick during the last week of in ovo development. The duration of the action potentials was extremely long (>8 sec). The action potentials were reversibly blocked by the stilbene derivative, SITS, a specific blocker of chloride permeability. Using patch clamp pipettes, in which the intracellular chloride concentration was controlled and with other types of ion channels blocked, the membrane potential at the peak of the action potential closely coincided with the chloride equilibrium potential calculated from the Nernst equation. These data indicate that activation of a chloride‐selective conductance underlies the long duration action potential. The occurrence of the chloride‐dependent action potential was found to increase during embryonic development. The percentage of fibers that displayed the action potential increased from ∼20% at embryonic day 13 to ∼ 70% at hatching. Chloride‐dependent action potentials were not found in adult fibers. The voltage and time‐dependent currents underlying the action potential were recorded under voltage clamp using the whole‐cell version of the patch pipette technique. The reversal potential of the currents was found to shift with the chloride concentration gradient in a manner predicted by the Nernst equation, and the currents were blocked by SITS. These data indicate that chloride ions were the charge carriers. The conductance was activated by depolarization and exhibited very slow activation and deactivation kinetics.