Kinetics of the work of the ion channels controlled by nicotinic cholinoreceptors in the membrane of mollusk neurons

Currents entering through single channels with conductivity 10 pS were produced on the membrane of an isolated neuron of the fresh-water molluskPlanorbarius corneus in the presence of suberyldicholine (5 µM) by the patch-clamp technique (cell-attached configuration). The times of stay of the channels in the open and closed states, as well as the durations of pulse bursts and clusters, were measured. The distributions of the time intervals obtained experimentally were approximated for open states by one exponential function: to=27±3 msec (n=21), and for closed states by a sum of three exponentials: tc1=9.5±1.0 msec (n=21); tc2=171±33 msec (n=19); tc3=5.2±1.0 sec (n=21). The burst durations are characterized by the presence of two exponential functions in the distribution: tb2=20±14 msec (n=10), tb2=203±23 msec (n=10), and the clusters by three exponential functions: tk1=33±11 msec (n=8), tk2=274±84 msec (n=8), and tk3=1.5±0.5 sec (n=9). Thus, for work of a chemoactivated channel associated with nicotinic-type cholinoreceptors in a mollusk neuron we can suggest a kinetic scheme with one open and three nonconducting states: C ⇄ O ⇄ D1A2 ⇄ D2A2. The two "long-lived" closed states of the channel may be associated with desensitization of the integral response of the neurons to the application of suberyldicholine. Values were obtained for the rate constants of these proposed reactions. It is suggested that this model may be useful in analyzing the action of cholinomimetics and blockers on the molluskan neuronal membrane.