Bottom-up design of calcium channels from defined selectivity filter geometry

Native ion channels play key roles in biological systems, and engineered versions are widely used as chemogenetic tools and in sensing devices ^1,2 . Protein design has been harnessed to generate pore-containing transmembrane proteins, but the capability to design ion selectivity based on the interactions between ions and selectivity filter residues, a crucial feature of native ion channels ³ , has been constrained by the lack of methods to place the metal-coordinating residues with atomic-level precision. Here we describe a bottom-up RFdiffusion-based approach to construct Ca ²⁺ channels from defined selectivity filter residue geometries, and use this approach to design symmetric oligomeric channels with Ca ²⁺ selectivity filters having different coordination numbers and different geometries at the entrance of a wide pore buttressed by multiple transmembrane helices. The designed channel proteins assemble into homogenous pore-containing particles, and for both tetrameric and hexameric ion-coordinating configurations, patch-clamp experiments show that the designed channels have higher conductances for Ca ²⁺ than for Na ⁺ and other divalent ions (Sr ²⁺ and Mg ²⁺ ). Cryo-electron microscopy indicates that the design method has high accuracy: the structure of the hexameric Ca ²⁺ channel is nearly identical to the design model. Our bottom-up design approach now enables the testing of hypotheses relating filter geometry to ion selectivity by direct construction, and provides a roadmap for creating selective ion channels for a wide range of applications.