Abstract
An increase in intracellular Ca2+ opens KCa2.2 Ca2+-activated K+-channels (SK) to conduct K+ down its electrochemical gradient. SK activation requires bound calmodulin proteins to decode dynamic Ca2+ fluctuations in a cell. Bilobal calmodulin has four Ca2+ binding sites. A common model proposes that just the N-terminal domain (N-lobe) of calmodulin binds Ca2+ to open SK, while an immobile C-terminal domain (C-lobe) has constitutive, Ca2+-independent binding. Such a mechanism is compatible with x-ray and EM structures of intact SK channels and fragments. While molecular structures provide snapshots of the channels in different conformations with and without calcium, gating is a dynamic process involving several different conformations, calcium binding to calmodulin, interactions between calmodulin and the channel and channel opening. We measured SK activity using inside-out patch recordings from “calmodulin-disrupted” SK channels where calcium-dependent activation can be restored by exogenously applied full-length calmodulin. Isolated N and C lobes have little ability to activate SK. We measured calmodulin binding to a C-terminal SK2 peptide (SKp) using both composition-gradient multi-angle light scattering and tryptophan emission spectra. While they do not rescue activation, isolated lobes do bind to a SK cytoplasmic domain with high affinity. Consistent with earlier models, N-lobe binding to SKp is stronger in Ca2+, and C-lobe binding affinity is strong regardless of Ca2+. However, a native tryptophan in SKp is sensitive to Ca2+ binding to either the N- or C-lobe of calmodulin at Ca2+ concentrations that activate SK. Our results show that the calmodulin C-lobe bound to SK is Ca2+ sensitive and that both lobes of calmodulin bind SK in Ca2+-dependent states governed by the different properties of each lobe.
Published Version
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