Chemistry of ion coordination and hydration revealed by a K+ channel–Fab complex at 2.0 Å resolution

Abstract

Ion transport proteins must remove an ion's hydration shell to coordinate the ion selectively on the basis of its size and charge. To discover how the K⁺ channel solves this fundamental aspect of ion conduction, we solved the structure of the KcsA K⁺ channel in complex with a monoclonal Fab antibody fragment at 2.0 Å resolution. Here we show how the K⁺ channel displaces water molecules around an ion at its extracellular entryway, and how it holds a K⁺ ion in a square antiprism of water molecules in a cavity near its intracellular entryway. Carbonyl oxygen atoms within the selectivity filter form a very similar square antiprism around each K⁺ binding site, as if to mimic the waters of hydration. The selectivity filter changes its ion coordination structure in low K⁺ solutions. This structural change is crucial to the operation of the selectivity filter in the cellular context, where the K⁺ ion concentration near the selectivity filter varies in response to channel gating.