Structural Characterization and pH-Induced Conformational Transition of Full-Length KcsA

Abstract

The bacterial K + channel KcsA from Streptomyces lividans was analyzed by neutron and x-ray small-angle solution scattering. The C-terminally truncated version of KcsA, amenable to crystallographic studies, was compared with the full-length channel. Analyzing the scattering data in terms of radius of gyration reveals differences between both KcsA species of up to 13.2 Å. Equally, the real-space distance distribution identifies a 40 to 50 Å extension of full-length KcsA compared to its C-terminally truncated counterpart. We show that the x-ray and neutron scattering data are amenable for molecular shape reconstruction of full-length KcsA. The molecular envelopes calculated display an hourglass-shaped structure within the C-terminal intracellular domain. The C-terminus extends the membrane spanning region of KcsA by 54–70 Å, with a central constriction 10–30 Å wide. Solution scattering techniques were further employed to characterize the KcsA channel under acidic conditions favoring its open conformation. The full-length KcsA at pH 5.0 shows the characteristics of a dumbbell-shaped macromolecular structure, originating from dimerization of the tetrameric K + channel. Since C-terminally truncated KcsA measured under the same low pH conditions remains tetrameric, oligomerization of full-length KcsA seems to proceed via structurally changed C-terminal domains. The determined maximum dimensions of the newly formed complex increase by 50–60%. Shape reconstruction of the pseudooctameric complex indicates the pH-induced conformational reorganization of the intracellular C-terminal domain.