Regulatory γ1 subunits defy symmetry in functional modulation of BK channels

Structural symmetry is a hallmark of homomeric ion channels. Nonobligatory regulatory proteins can also critically define the precise functional role of such channels. For instance, the pore-forming subunit of the large conductance voltage and calcium-activated potassium (BK, Slot or KCa1.1) channels encoded by a single KCa1.1 gene assembles in a fourfold symmetric fashion. Functional diversity arises from two families of regulatory subunits, R and gamma, which help define the range of voltages over which BK channels in a given cell are activated, thereby defining physiological roles. A BK channel can contain zero to four R subunits per channel, with each R subunit incrementally influencing channel gating behavior, consistent with symmetry expectations. In contrast, a gamma 1 subunit (or single type of gamma 1 subunit complex) produces a functionally all-or-none effect, but the underlying stoichiometry of gamma 1 assembly and function remains unknown. Here we utilize two distinct and independent methods, a Forster resonance energy transfer-based optical approach and a functional reporter in single-channel recordings, to reveal that a BK channel can contain up to four gamma 1 subunits, but a single gamma 1 subunit suffices to induce the full gating shift. This requires that the asymmetric association of a single regulatory protein can act in a highly concerted fashion to allosterically influence conformational equilibria in an otherwise symmetric K+ channel.