Maeda, Y. K.; Kojima, K.; Nakamura, T. Y.; Nakatsu, T.; Irie, K.

Voltage-gated sodium channels (Navs) selectively permeate Na+ to generate action potentials. The efficiency of Na+ permeation is known to be significantly higher than that of many other cations, but Li+ can permeate Navs as much as Na+. However, the molecular basis of the Li+ permeation has been unclear. The ion selectivity of Navs is carried by the selectivity filter (SF) inside the ion pore. In this study, we performed mutagenesis of the SF and created prokaryotic Nav mutants with enhanced Li+ selectivity. Electrophysiological and crystallographic analyses revealed the critical determinants for the enhanced Li+ selectivity: the widened entrance of the SF allowing Li+ to invade deeper into the SF without dehydration, the attraction of hydrated Li+ by negative charges on the strong ion recognition site, and the smaller number of hydration water exchanges inside the SF. Additionally, the extensive interactions around the SF were shown to support ion permeation by stabilizing the ion pore. New drug directions based upon molecular basis for Li+ permeation may target various neurological disorders and clarify the broader biological effects of lithium.