PIP 2 stabilizes Na V 1.5 gating and links receptor signaling to cardiac late sodium current

Read the full article See related articles

Discuss this preprint

Start a discussion What are Sciety discussions?

Listed in

This article is not in any list yet, why not save it to one of your lists.
Log in to save this article

Abstract

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.

Article activity feed