BK channels with beta3a subunits generate use-dependent slow afterhyperpolarizing currents by an inactivation-coupled mechanism.

Large-conductance, Ca2+- and voltage-activated K+ (BK) channels are broadly expressed proteins that respond to both cellular depolarization and elevations in cytosolic Ca2+. The characteristic functional properties of BK channels among different cells are determined, in part, by tissue-specific expression of auxiliary beta subunits. One important functional property conferred on BK channels by beta subunits is inactivation. Yet, the physiological role of BK channel inactivation remains poorly understood. Here we report that as a consequence of a specific mechanism of inactivation, BK channels containing the beta3a auxiliary subunit exhibit an anomalous slowing of channel closing. This produces a net repolarizing current flux that markedly exceeds that expected if all open channels had simply closed. Because of the time dependence of inactivation, this behavior results in a Ca2+-independent but time-dependent increase in a slow tail current, providing an unexpected mechanism by which use-dependent changes in slow afterhyperpolarizations might regulate electrical firing. The physiological significance of inactivation in BK channels mediated by different beta subunits may therefore arise not from inactivation itself, but from the differences in the amplitude and duration of repolarizing currents arising from the beta-subunit-specific energetics of recovery from inactivation.

Direct observation of a preinactivated, open state in BK channels with beta2 subunits.

Proteins arising from the Slo family assemble into homotetramers to form functional large-conductance, Ca2+- and voltage-activated K+ channels, or BK channels. These channels are also found in association with accessory beta subunits, which modulate several aspects of channel gating and expression. Coexpression with either of two such subunits, beta2 or beta3b, confers time-dependent inactivation onto BK currents. mSlo1+beta3b channels display inactivation that is very rapid but incomplete. Previous studies involving macroscopic recordings from these channels have argued for the existence of a second, short-lived conducting state in rapid equilibrium with the nonconducting, inactivated conformation. This state has been termed "pre-inactivated," or O*. beta2-mediated inactivation, in contrast, occurs more slowly but is virtually complete at steady state. Here we demonstrate, using both macroscopic and single channel current recordings, that a preinactivated state is also a property of mSlo1+beta2 channels. Detection of this state is enhanced by a mutation (W4E) within the initial beta2 NH2-terminal segment critical for inactivation. This mutation increases the rate of recovery to the preinactivated open state, yielding macroscopic inactivation properties qualitatively more similar to those of beta3b. Furthermore, short-lived openings corresponding to entry into the preinactivated state can be observed directly with single-channel recording. By examining the initial openings after depolarization of a channel containing beta2-W4E, we show that channels can arrive directly at the preinactivated state without passing through the usual long-lived open conformation. This final result suggests that channel opening and inactivation are at least partly separable in this channel. Mechanistically, the preinactivated and inactivated conformations may correspond to binding of the beta subunit NH2 terminus in the vicinity of the cytoplasmic pore mouth, followed by definitive movement of the NH2 terminus into a position of occlusion within the ion-conducting pathway.