Intrinsic Gating Behavior of Voltage-Gated Sodium Channels Predetermines Regulation by Auxiliary β-subunits

Voltage-gated sodium (Nav) channels mediate rapid millisecond electrical signaling in excitable cells. Auxiliary subunits, {beta}1-{beta}4, are thought to regulate Nav channel function through covalent and/or polar interactions with the channel s voltage-sensing domains. How these interactions translate into the diverse and variable regulatory effects of {beta}-subunits remains unclear. Here, we find that the intrinsic movement order of the voltage-sensing domains during channel gating is unexpectedly variable across Nav channel isoforms. This movement order dictates the channel s propensity for closed-state inactivation, which in turn modulates the actions of {beta}1 and {beta}3. We show that the differential regulation of skeletal muscle, cardiac, and neuronal Nav channels is explained by their variable levels of closed-state inactivation. Together, this study provides a unified mechanism for the regulation of all Nav channel isoforms by {beta}1 and {beta}3, which explains how the fixed structural interactions of auxiliary subunits can paradoxically exert variable effects on channel function.