Clindamycin-induced alteration of ganglionic function. II. Effect of nicotinic receptor-channel function

Abstract

The postsynaptic effects of clindamycin have been analyzed in bullfrog sympathetic ganglion B cells using single electrode current and voltage clamp recording and two electrode voltage clamp measurements. Clindamycin added to the bathing solution in the concentration decreased range, 2.5 × 10 −4 to 5 × 10 −4M, inhibited fast ganglionic transmission. In addition, local application of clindamycin depolarizations produced by direct application of acetylcholine and decreased the amplitude of miniature excitatory postsynaptic potentials (MEPSPs) evoked by tetanic stimulation of the preganglionic trunk. In contrast, clindamycin did not change the amplitude or time course of the slow EPSP elicited by preganglionic stimulation (30 Hz for 10s) or muscarinic depolarizations produced by local acetylcholine application to preparations pretreated with 25–50 μM (+)-tubocurarine. In voltage-clamped ganglion cells, excitatory postsynaptic current (EPSC) amplitude initially was increased and then decreased with increasing concentrations of clindamycin (0.5 × 10 −5 to 2.5 × 10 −4). The EPSC time course in control cells was exponential. After exposure to clindamycin, the EPSC decay was composed of two exponential components. The time constant of the fast component decreased and the time constant of the slow component increased with increasing concentrations of clindamycin. The two time constants of EPSCs obtained in clindamycin were independent of membrane voltage between −50 and −100 mV. We concluded that the block of fast ganglionic transmission is primarily due to a postsynaptic site of action, at least part of which is due to a concentration-dependent, but voltage-independent blockade of open nicotinic receptor channel complexes.