Uncoupling sodium channel dimers restores the phenotype of a pain-linked Nav1.7 channel mutation

Background and Purpose The voltage-gated sodium channel Na(v)1.7 is essential for adequate perception of painful stimuli. Mutations in the encoding gene,SCN9A, cause various pain syndromes in humans. The hNa(v)1.7/A1632E channel mutant causes symptoms of erythromelalgia and paroxysmal extreme pain disorder (PEPD), and its main gating change is a strongly enhanced persistent current. On the basis of recently published 3D structures of voltage-gated sodium channels, we investigated how the inactivation particle binds to the channel, how this mechanism is altered by the hNa(v)1.7/A1632E mutation, and how dimerization modifies function of the pain-linked mutation. Experimental Approach We applied atomistic molecular simulations to demonstrate the effect of the mutation on channel fast inactivation. Native PAGE was used to demonstrate channel dimerization, and electrophysiological measurements in HEK cells andXenopus laevisoocytes were used to analyze the links between functional channel dimerization and impairment of fast inactivation by the hNa(v)1.7/A1632E mutation. Key Results Enhanced persistent current through hNa(v)1.7/A1632E channels was caused by impaired binding of the inactivation particle, which inhibits proper functioning of the recently proposed allosteric fast inactivation mechanism. hNa(v)1.7 channels form dimers and the disease-associated persistent current through hNa(v)1.7/A1632E channels depends on their functional dimerization status: Expression of the synthetic peptide difopein, a 14-3-3 inhibitor known to functionally uncouple dimers, decreased hNa(v)1.7/A1632E channel-induced persistent currents. Conclusion and Implications Functional uncoupling of mutant hNa(v)1.7/A1632E channel dimers restored their defective allosteric fast inactivation mechanism. Our findings support the concept of sodium channel dimerization and reveal its potential relevance for human pain syndromes.