Conformational dynamics of Ca2+-dependent responses in the polycystin-2 C-terminal tail

PC2 (polycystin-2) forms a Ca2+-permeable channel in the cell membrane and its function is regulated by cytosolic Ca2+ levels. Mutations in the C-terminal tail of human PC2 (HPC2 Cterm) lead to autosomal dominant polycystic kidney disease. The HPC2 Cterm protein contains a Ca2+-binding site responsible for channel gating and function. To provide the foundation for understanding how Ca2+ regulates the channel through the HPC2 Cterm, we characterized Ca2+ binding and its conformational and dynamic responses within the HPC2 Cterm. By examining hydrogen–deuterium (H–D) exchange profiles, we show that part of the coiled-coil domain in the HPC2 Cterm forms a stable helix bundle regardless of the presence of Ca2+. The HPC2 L1EF construct contains the Ca2+-binding EF-hand and the N-terminal linker 1 region without the downstream coiled coil. We show that the linker stabilizes the Ca2+-bound conformation of the EF-hand, thus enhancing its Ca2+-binding affinity to the same level as the HPC2 Cterm. In comparison, the coiled coil is not required for the high-affinity binding. By comparing the conformational dynamics of the HPC2 Cterm and HPC2 L1EF with saturating Ca2+, we show that the HPC2 Cterm and HPC2 L1EF share a similar increase in structural stability upon Ca2+ binding. Nevertheless, they have different profiles of H–D exchange under non-saturating Ca2+ conditions, implying their different conformational exchange between the Ca2+-bound and -unbound states. The pr...
Source: Biochemical Journal - Category: Biochemistry Authors: Tags: Energy, Biomolecules Research articles Source Type: research