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.

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.

A specific interaction between the cardiac sodium channel and site-3 toxin anthopleurin B.

The polypeptide neurotoxin anthopleurin B (ApB) isolated from the venom of the sea anemone Anthopleura xanthogrammica is one of a family of toxins that bind to the extracellular face of voltage-dependent sodium channels and retard channel inactivation. Because most regions of the sodium channel known to contribute to inactivation are located intracellularly or within the membrane bilayer, identification of the toxin/channel binding site is of obvious interest. Recently, mutation of a glutamic acid residue on the extracellular face of the fourth domain of the rat neuronal sodium channel (rBr2a) was shown to disrupt toxin/channel binding (Rogers, J.

Differences in the binding sites of two site-3 sodium channel toxins.

Site-3 toxins from scorpion and sea anemone bind to Na channels and selectively inhibit current decay. Anthopleurins A and B (ApA and ApB, respectively), toxins found in the venom of the sea anemone Anthopleura xanthogrammica, bind to closed states of mammalian skeletal and cardiac Na channels with differing affinities which arise from differences in first-order toxin/channel dissociation rate constants, koff. Using chimera comprising domain interchanges between channel isoforms, we examined the structural basis of this differential affinity.