Activation and cooperative multi‐ion block of single nicotinic‐acetylcholine channel currents of Ascaris muscle by the tetrahydropyrimidine anthelmintic, morantel

1 We have investigated activation and block, by the tetrahydropyrimidine anthelmintic, morantel, of nicotinic‐acetylcholine receptor (AChR) currents in membrane vesicles isolated from somatic muscle cells of the nematode parasite Ascaris suum. Standard single‐channel recording techniques were employed. Morantel in the pipette (6 nM to 600 μm), activated single nicotinic AChR currents. 2 Kinetic properties of the main‐conductance state of morantel‐activated currents were investigated in detail throughout the concentration range, 0.6 μm to 600 μm. Open‐time distributions were best fitted by a single exponential. Mean open‐times were slightly voltage‐dependent, increasing from 0.9 ms at + 75 mV to 1.74 ms at —75 mV in the presence of 0.6 μm morantel. At low concentrations, closed‐time distributions were best fitted by the sum of two or three exponential components. 3 As the concentration of morantel was increased (100–600 μm), fast‐flickering open channel‐block was observed at positive potentials, even though morantel, a cation, was only present at the extracellular surface of the membrane. The block rate was dependent on morantel concentration and both block rate and duration of block increased as the potential became less positive. A simple channel‐block mechanism did not explain properties of this block. 4 At negative potentials, as the morantel concentration increased, a complex block was observed. With increases in morantel concentration two additional gap components appeared in closed‐time distributions: one was short with a duration (∼13 ms) independent of morantel concentration; the other was long with a duration that increased with morantel concentration (up to many minutes). In combination, these two components produced a marked reduction in probability of channel opening (Po) with increasing morantel concentration. The relationship between the degrees of block and morantel concentration had a Hill coefficient of 1.6, suggesting the involvement of at least two blocking molecules. The data were analysed by use of a simple sequential double block kinetic model.

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