AUTHOR=Grandi Eleonora , Herren Anthony W.

TITLE=CaMKII-dependent regulation of cardiac Na+ homeostasis

JOURNAL=Frontiers in Pharmacology

VOLUME=Volume 5 - 2014

YEAR=2014

URL=https://www.frontiersin.org/journals/pharmacology/articles/10.3389/fphar.2014.00041

DOI=10.3389/fphar.2014.00041

ISSN=1663-9812

ABSTRACT=Na<sup>+</sup> homeostasis is a key regulator of cardiac excitation and contraction. The cardiac voltage-gated Na<sup>+</sup> channel, Na<sub>V</sub>1.5, critically controls cell excitability, and altered channel gating has been implicated in both inherited and acquired arrhythmias. Ca<sup>2+</sup>/calmodulin-dependent protein kinase II (CaMKII), a serine/threonine kinase important in cardiac physiology and disease, phosphorylates Na<sub>V</sub>1.5 at multiple sites within the first intracellular linker loop to regulate channel gating. Although CaMKII sites on the channel have been identified (S516, T594, S571), the relative role of each of these phospho-sites in channel gating properties remains unclear, whereby both loss-of-function (reduced availability) and gain-of-function (late Na<sup>+</sup> current, I<sub>NaL</sub>) effects have been reported. Our review highlights investigating the complex multi-site phospho-regulation of Na<sub>V</sub>1.5 gating is crucial to understanding the genesis of acquired arrhythmias in heart failure (HF) and CaMKII activated conditions.  In addition, the increased Na<sup>+</sup> influx accompanying I<sub>NaL</sub> may also indirectly contribute to arrhythmia by promoting Ca<sup>2+</sup> overload. While the precise mechanisms of Na<sup>+</sup> loading during HF remain unclear, and quantitative analyses of the contribution of I<sub>NaL</sub> are lacking, disrupted Na<sup>+</sup> homeostasis is a consistent feature of HF. Computational and experimental observations suggest that both increased diastolic Na<sup>+</sup> influx and action potential prolongation due to systolic I<sub>NaL</sub> contribute to disruption of Ca<sup>2+</sup> handling in failing hearts. Furthermore, simulations reveal a synergistic interaction between perturbed Na<sup>+</sup> fluxes and CaMKII, and confirm recent experimental findings of an arrhythmogenic feedback loop, whereby CaMKII activation is at once a cause and a consequence of Na<sup>+</sup> loading.