Calcium dependence of acetylcholine induced conductance changes.

The influence of external calcium variation (0.7–28 mM) on acetylcholine (ACh) induced conductance changes was examined under voltage clamp conditions in snail neurons in which ACh elicitis hyperpolarizing responses and in which the main current-carrying ion species is Cl^?. Raising external calcium to 28 mM as well as lowering external calcium to 1.75 mM decreased the ACh-induced condutance change without altering the reversal potential for ACh-induced currents. Lowering external calcium to 0.7 mM increased the ACh-induced conductance change and shifted the reversal potential to less negative values. The results at 28 mM calcium can be best explained on the assumption that excess calcium interferes with the interaction between ACh and the receptor. The results at 1.75 mM calcium can be satisfactorily explained in terms of the concept that fixed membrane charges play a role in regulating Cl^? permeation through transmitter sensitive membranes. Evidence was also obtained that in snail neurons receptor inactivation increases when external calcium is reduced.