Patrick Wright scite author profile

Ion channel function is fundamental to the existence of life. In metazoans, the coordinate activities of voltagegated Na + channels underlie cellular excitability and control neuronal communication, cardiac excitationcontraction coupling, and skeletal muscle function. However, despite decades of research and linkage of Na + channel dysfunction with arrhythmia, epilepsy, and myotonia, little progress has been made toward understanding the fundamental processes that regulate this family of proteins. Here, we have identified β IV -spectrin as a multifunctional regulatory platform for Na + channels in mice. We found that β IV -spectrin targeted critical structural and regulatory proteins to excitable membranes in the heart and brain. Animal models harboring mutant β IV -spectrin alleles displayed aberrant cellular excitability and whole animal physiology. Moreover, we identified a regulatory mechanism for Na + channels, via direct phosphorylation by β IV -spectrin-targeted calcium/calmodulin-dependent kinase II (CaMKII). Collectively, our data define an unexpected but indispensable molecular platform that determines membrane excitability in the mouse heart and brain.

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Voltage-Gated Sodium Channel Phosphorylation at Ser571 Regulates Late Current, Arrhythmia, and Cardiac Function In Vivo

Glynn

et al. 2015

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Background Voltage-gated Na+ channels (Nav) are essential for myocyte membrane excitability and cardiac function. Nav current (INa) is a large amplitude, short duration “spike” generated by rapid channel activation followed immediately by inactivation. However, even under normal conditions, a small “late” component of INa (INa,L) persists due to incomplete/failed inactivation of a subpopulation of channels. Notably, INa,L is directly linked with both congenital and acquired disease states. The multifunctional Ca2+/calmodulin-dependent kinase II (CaMKII) has been identified as an important activator of INa,L in disease. Several potential CaMKII phosphorylation sites have been discovered, including Ser571 in the Nav1.5 DI-DII linker, but the molecular mechanism underlying CaMKII-dependent regulation of INa,L in vivo remains unknown. Methods and Results To determine the in vivo role of Ser571, two Scn5a knock-in mouse models were generated expressing either: 1) Nav1.5 with a phosphomimetic mutation at Ser571 (S571E), or 2) Nav1.5 with the phosphorylation site ablated (S571A). Electrophysiology studies revealed that Ser571 regulates INa,L but not other channel properties previously linked to CaMKII. Ser571-mediated increases in INa,L promote abnormal repolarization and intracellular Ca2+ handling, and increase susceptibility to arrhythmia at the cellular and animal level. Importantly, Ser571 is required for maladaptive remodeling and arrhythmias in response to pressure overload. Conclusions Our data provide the first in vivo evidence for the molecular mechanism underlying CaMKII activation of the pathogenic INa,L. Relevant for improved rational design of potential therapies, our findings demonstrate that Ser571-dependent regulation of Nav1.5 specifically tunes INa,L without altering critical physiological components of the current.

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Ca ²⁺ /Calmodulin-Dependent Protein Kinase II–Based Regulation of Voltage-Gated Na ⁺ Channel in Cardiac Disease

et al. 2012

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Background Human gene variants affecting ion channel biophysical activity and/or membrane localization are linked with potentially fatal cardiac arrhythmias. However, the mechanism for many human arrhythmia variants remains undefined despite over a decade of investigation. Post-translational modulation of membrane proteins is essential for normal cardiac function. Importantly, aberrant myocyte signaling has been linked to defects in cardiac ion channel post-translational modifications and disease. We recently identified a novel pathway for post-translational regulation of the primary cardiac voltage-gated Na+ channel (Nav1.5) by CaMKII. However, a role for this pathway in cardiac disease has not been evaluated. Methods and Results We evaluated the role of CaMKII-dependent phosphorylation in human genetic and acquired disease. We report an unexpected link between a short motif in the Nav1.5 DI-DII loop, recently shown to be critical for CaMKII-dependent phosphorylation, and Nav1.5 function in monogenic arrhythmia and common heart disease. Experiments in heterologous cells and primary ventricular cardiomyocytes demonstrate that human arrhythmia susceptibility variants (A572D and Q573E) alter CaMKII-dependent regulation of Nav1.5 resulting in abnormal channel activity and cell excitability. In silico analysis reveals that these variants functionally mimic the phosphorylated channel resulting in increased susceptibility to arrhythmia-triggering afterdepolarizations. Finally, we report that this same motif is aberrantly regulated in a large animal model of acquired heart disease and in failing human myocardium. Conclusions We identify the mechanism for two human arrhythmia variants that affect Nav1.5 channel activity through direct effects on channel post-translational modification. We propose that the CaMKII phosphorylation motif in the Nav1.5 DI-DII cytoplasmic loop is a critical nodal point for pro-arrhythmic changes to Nav1.5 in congenital and acquired cardiac disease.

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Ankyrin-G Coordinates Intercalated Disc Signaling Platform to Regulate Cardiac Excitability In Vivo

Makara

Curran

Little

et al. 2014

Circulation Research

111

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Rationale Nav1.5 (SCN5A) is the primary cardiac voltage-gated Nav channel. Nav1.5 is critical for cardiac excitability and conduction, and human SCN5A mutations cause sinus node dysfunction, atrial fibrillation, conductional abnormalities, and ventricular arrhythmias. Further, defects in Nav1.5 regulation are linked with malignant arrhythmias associated with human heart failure. Consequently, therapies to target select Nav1.5 properties have remained at the forefront of cardiovascular medicine. However, despite years of investigation, the fundamental pathways governing Nav1.5 membrane targeting, assembly, and regulation are still largely undefined. Objective Define the in vivo mechanisms underlying Nav1.5 membrane regulation. Methods and Results Here, we define the molecular basis of a Nav channel regulatory platform in heart. Using new cardiac-selective ankyrin-G−/− mice (cKO), we report that ankyrin-G targets Nav1.5, and its regulatory protein, calcium/calmodulin-dependent kinase II (CaMKII) to the intercalated disc. Mechanistically, βIV-spectrin is requisite for ankyrin-dependent targeting of CaMKIIδ, however βIV-spectrin is not essential for ankyrin-G expression. Ankyrin-G cKO myocytes display decreased Nav1.5 expression/membrane localization, and reduced INa associated with pronounced bradycardia, conduction abnormalities, and ventricular arrhythmia in response to Nav channel antagonists. Moreover, we report that ankyrin-G links Nav channels with broader intercalated disc signaling/structural nodes, as ankyrin-G loss results in reorganization of plakophilin-2 and lethal arrhythmias in response to beta-adrenergic stimulation. Conclusions Our findings provide the first in vivo data for the molecular pathway required for intercalated disc Nav1.5 targeting/regulation in heart. Further, these new data identify the basis of an in vivo cellular platform critical for membrane recruitment and regulation of Nav1.5.

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Patrick Wright

A βIV-spectrin/CaMKII signaling complex is essential for membrane excitability in mice

Voltage-Gated Sodium Channel Phosphorylation at Ser571 Regulates Late Current, Arrhythmia, and Cardiac Function In Vivo

Ca ²⁺ /Calmodulin-Dependent Protein Kinase II–Based Regulation of Voltage-Gated Na ⁺ Channel in Cardiac Disease

Ankyrin-G Coordinates Intercalated Disc Signaling Platform to Regulate Cardiac Excitability In Vivo

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Patrick Wright

A βIV-spectrin/CaMKII signaling complex is essential for membrane excitability in mice

Voltage-Gated Sodium Channel Phosphorylation at Ser571 Regulates Late Current, Arrhythmia, and Cardiac Function In Vivo

Ca 2+ /Calmodulin-Dependent Protein Kinase II–Based Regulation of Voltage-Gated Na + Channel in Cardiac Disease

Ankyrin-G Coordinates Intercalated Disc Signaling Platform to Regulate Cardiac Excitability In Vivo

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Ca ²⁺ /Calmodulin-Dependent Protein Kinase II–Based Regulation of Voltage-Gated Na ⁺ Channel in Cardiac Disease