Modes of operation of the BKCa channel beta2 subunit.

The beta(2) subunit of the large conductance Ca(2+)- and voltage-activated K(+) channel (BK(Ca)) modulates a number of channel functions, such as the apparent Ca(2+)/voltage sensitivity, pharmacological and kinetic properties of the channel. In addition, the N terminus of the beta(2) subunit acts as an inactivating particle that produces a relatively fast inactivation of the ionic conductance. Applying voltage clamp fluorometry to fluorescently labeled human BK(Ca) channels (hSlo), we have investigated the mechanisms of operation of the beta(2) subunit. We found that the leftward shift on the voltage axis of channel activation curves (G(V)) produced by coexpression with beta(2) subunits is associated with a shift in the same direction of the fluorescence vs. voltage curves (F(V)), which are reporting the voltage dependence of the main voltage-sensing region of hSlo (S4-transmembrane domain). In addition, we investigated the inactivating mechanism of the beta(2) subunits by comparing its properties with the ones of the typical N-type inactivation process of Shaker channel. While fluorescence recordings from the inactivated Shaker channels revealed the immobilization of the S4 segments in the active conformation, we did not observe a similar feature in BK(Ca) channels coexpressed with the beta(2) subunit. The experimental observations are consistent with the view that the beta(2) subunit of BK(Ca) channels facilitates channel activation by changing the voltage sensor equilibrium and that the beta(2)-induced inactivation process does not follow a typical N-type mechanism.

Post-afterdischarge depolarization does not stimulate prolonged neurohormone secretion but is required for activity-dependent stimulation of neurohormone biosynthesis from peptidergic neurons.

Membrane depolarization plays a critical role in stimulating secretion of neuropeptides and can also be important in regulating transcriptional and translational events that control peptide biosynthesis. The purpose of this study was to test the hypothesis that persistent membrane depolarization after the end of an electrical afterdischarge plays an important role in stimulating both prolonged secretion of egg-laying hormone (ELH) and ELH synthesis from peptidergic bag cell neurons of Aplysia. Experimental preparations were treated with a low Na(+) solution to rapidly repolarize membrane potential (Vm). Compared with control preparations, the low Na(+) solution caused rapid membrane repolarization to resting levels, significant shortening of the duration of the afterdischarge, and significant decrease in the decay time constant of cytosolic Ca(2+) ([Ca(2+)](i)) concentrations, but no effect on peak [Ca(2+)](i), total [Ca(2+)](i) above baseline, or duration of elevated [Ca(2+)](i). Contrary to both theoretical expectations and findings in other cell types, low Na(+) treatment and the resulting premature repolarization of Vm did not inhibit ELH secretion. On the other hand, low Na(+) treatment that blocked prolonged depolarization, as well as inhibition of Ca(2+) influx, prevented the afterdischarge-induced stimulation of ELH synthesis. These findings provide support for membrane depolarization acting as a trigger mechanism, rather than a sustained driving force, for cellular events that control ELH secretion. It also demonstrates, for the first time, a critical role for postdischarge Vm in regulating an important aspect of neuroendocrine cell function-that of hormone synthesis.