Searching for the Interaction Sites of the Beta1 Subunit with the Voltage-Sensing Domains of Sodium Channels Using LRET

Abstract

Mammalian voltage-gated sodium channels (Nav) are composed of two subunits: a monomeric pore-forming subunit (α-subunit), that contains four domains (DI-DIV), each composed of a voltage-sensing domain (VSD, S1-S4) and a pore domain (S5-S6) and auxiliary subunits (β-subunits) that are transmembrane proteins with type I topology: containing an extracellular amino-terminus, a single transmembrane segment and an intracellular carboxyl terminus. A large body of literature has shown that interaction between α- and β-subunits results in Nav with altered gating kinetics suggesting that β-subunits may directly interact with VSD. However, aspects of the stoichiometry, arrangement and molecular interaction between α and β subunits remain unclear. In this study, we explored the location of β1 in relation to the rat skeletal muscle sodium channel α-subunit (Nav1.4) using lanthanide-based resonance energy transfer (LRET) via two strategies. 1) Four Nav1.4 constructs were designed to encode a Tb3+ binding-tag (Nav1.4-LBT) on top of the S4 of each domain (DI-LBT, DII-LBT, DIII-LBT and DIV-LBT) as energy donor. A hexa-histidine-tag was inserted in β1 (6His-β1), which binds a Cu2+ ion to act as acceptor. 2) β1 constructs were designed to encode at an extracellular site an LBT that binds Tb3+ as energy donor while the acceptor was Alexa488 conjugated to Ts1, a β scorpion toxin which binds to DII-VSD in Nav1.4. For both experiments, we used Xenopus laevis oocytes co-expressing Nav1.4 and β1 constructs injected with the cRNA at 1:1 molar ratio. In preliminary results, DIV-LBT + 6His-β1 oocytes displayed robust energy transfer between Tb3+ and Cu2+, indicating that at least one β1-subunit is located at ∼28 A of S4-DIV. Support: 13POST14800031 (AHA), MOP-10053 (CIHR), GM68044-07, U54GM087519 and GM030376.