Rat magnocellular neurones with cell bodies in the supraoptic and paraventricular nuclei of the hypothalamus send their axonal nerve endings into the neurohypophysis, where they release oxytocin or vasopressin into the bloodstream during highly specific firing patterns. Peptide release from the neurohypophysis is closely controlled by an interplay between the duration and frequency of the action potential burst, and the silence that separates the bursts generated by these neurones (Cazalis et al. 1985). Thus, understanding of peptide release from the hypothalamicneurohypophysial system requires characterization of the conductances that shape action potentials in both the cell bodies and their axonal endings. The physical separation of cell bodies and nerve endings in this system allows a unique opportunity to elucidate the differences in neuronal excitability, and underlying conductances in different cellular domains. Large conductance Ca¥-activated K¤ (BK) channels are ubiquitous in neurones. They typically exhibit high permeability and selectivity for K¤, and activation upon 1. Large conductance, Ca¥-activated K¤ (BK) channels were identified in freshly dissociated rat supraoptic neurones using patch clamp techniques. 2. The single channel conductance of cell body BK channels, recorded from inside-out patches in symmetric 145 mÒ K¤, was 246·1 pS, compared with 213 pS in nerve ending BK channels (P < 0·01). 3. At low open probability (Pï), the reciprocal of the slope in the ln(NPï)-voltage relationship (N, number of available channels in the patch) for cell body and nerve ending channels were similar: 11 vs. 14 mVper e-fold change in NPï, respectively. 4. At 40 mV, the [Ca¥]é producing half-maximal activation was 273 nÒ, as opposed to > 1·53 ìÒ for the neurohypophysial channel, indicating the higher Ca¥ sensitivity of the cell body isochannel. 5. Cell body BK channels showed fast kinetics (open time constant, 8·5 ms; fast closed time constant, 1·6 and slow closed time constant, 12·7 ms), identifying them as 'type I' isochannels, as opposed to the slow gating (type II) of neurohypophysial BK channels. 6. Cell body BK activity was reduced by 10 nÒ charybdotoxin (NPï, 37% of control), or 10 nÒ iberiotoxin (NPï, 5% of control), whereas neurohypophysial BK channels are insensitive to charybdotoxin at concentrations as high as 360 nÒ. 7. Whilst blockade of nerve ending BK channels markedly slowed the repolarization of evoked single spikes, blockade of cell body channels was without effect on repolarization of evoked single spikes. 8. Ethanol reversibly increased neurohypophysial BK channel activity (EC50, 22 mÒ; maximal effect, 100 mÒ). In contrast, ethanol (up to 100 mÒ) failed to increase cell body BK channel activity. 9. In conclusion, we have characterized BK channels in supraoptic neuronal cell bodies, and demonstrated that they display different electrophysiological and pharmacological properties from their counterparts in the nerve endings. Keywords:
