Measuring the Influence of the BKCa β1 Subunit on Ca2+ Binding to the BKCa Channel

Abstract

The large-conductance Ca2+-activated potassium (BKCa) channel of smooth muscle is unusually sensitive to Ca2+ as compared with the BKCa channels of brain and skeletal muscle. This is due to the tissue-specific expression of the BKCa auxiliary subunit β1, whose presence dramatically increases both the potency and efficacy of Ca2+ in promoting channel opening. β1 contains no Ca2+ binding sites of its own, and thus the mechanism by which it increases the BKCa channel's Ca2+ sensitivity has been of some interest. Previously, we demonstrated that β1 stabilizes voltage sensor activation, such that activation occurs at more negative voltages with β1 present. This decreases the work that Ca2+ must do to open the channel and thereby increases the channel's apparent Ca2+ affinity without altering the real affinities of the channel's Ca2+ binding sites. To explain the full effect of β1 on the channel's Ca2+ sensitivity, however, we also proposed that there must be effects of β1 on Ca2+ binding. Here, to test this hypothesis, we have used high-resolution Ca2+ dose–response curves together with binding site–specific mutations to measure the effects of β1 on Ca2+ binding. We find that coexpression of β1 alters Ca2+ binding at both of the BKCa channel's two types of high-affinity Ca2+ binding sites, primarily increasing the affinity of the RCK1 sites when the channel is open and decreasing the affinity of the Ca2+ bowl sites when the channel is closed. Both of these modifications increase the difference in affinity between open and closed, such that Ca2+ binding at either site has a larger effect on channel opening when β1 is present.