Crystallographic basis for calcium regulation of sodium channels

Abstract

Voltage-gated sodium channels underlie the rapid regenerative upstroke of action potentials and are modulated by cytoplasmic calcium ions through a poorly understood mechanism. We describe the 1.35 Å crystal structure of Ca 2+-bound calmodulin (Ca 2+/CaM) in complex with the inactivation gate (DIII-IV linker) of the cardiac sodium channel (Na V1.5). The complex harbors the positions of five disease mutations involved with long Q-T type 3 and Brugada syndromes. In conjunction with isothermal titration calorimetry, we identify unique inactivation-gatemutations that enhance or diminish Ca 2+/CaM binding,which, in turn, sensitize or abolish Ca 2+ regulation of full-length channels in electrophysiological experiments. Additional biochemical experiments support a model whereby a single Ca 2+/CaM bridges the C-terminal IQ motif to the DIII-IV linker via individual N and C lobes, respectively. The data suggest that Ca 2+/CaM destabilizes binding of the inactivation gate to its receptor, thus biasing inactivation toward more depolarized potentials.