PIP 2 stabilizes Na V 1.5 gating and links receptor signaling to cardiac late sodium current
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The cardiac sodium channel Na V 1.5 initiates each heartbeat by generating the rapid depolarizing upstroke of the action potential. Dysregulation of Na V 1.5 gating can produce cardiac arrhythmias by slowing inactivation, increasing late sodium current (I Na,L ), and impairing electrical stability. Here, we show that phosphatidylinositol-4,5-bisphosphate (PIP 2 ) is a critical membrane cofactor that stabilizes Na V 1.5 gating. Acute PIP 2 depletion in human iPSC-derived cardiomyocytes, produced by activation of endogenous AT1 receptors, activation of an engineered M3q-DREADD, or optogenetic recruitment of CRY2-pseudojanin, shifted voltage dependence, slowed fast inactivation, and increased I Na,L . These effects were prevented by augmenting intracellular PIP 2 , required PLC activity when driven by Gq-coupled receptors, and were independent of downstream Ca² or PKC signaling. Unlike the skeletal-muscle isoform Na V 1.4, Na V 1.5 displayed PIP 2 -dependent shifts in both activation and steady-state inactivation, indicating isoform-specific lipid coupling. Induced-fit docking and molecular dynamics simulations identified a PIP 2 -interaction interface between the domain IV voltage sensor and pore that contains disease-linked residues. The disease-reported variant R1644C weakened and redistributed the predicted PIP 2 -contact network, produced elevated basal I Na,L , showed enhanced sensitivity to PIP 2 depletion, and caused an approximately 30-fold reduction in apparent functional PIP 2 sensitivity in excised patches. These findings define a lipid-dependent mechanism that stabilizes Na V 1.5 gating and reveal how physiological Gq signaling and inherited channel variants can converge on the channel-PIP 2 axis to promote proarrhythmic late sodium current.