Fibroblast growth factor homologous factors tune arrhythmogenic late NaV1.5 current in calmodulin binding–deficient channels
Jeffrey Abrams, Daniel Roybal, Nourdine Chakouri, Alexander N. Katchman, Richard Weinberg, Lin Yang, Bi-xing Chen, Sergey I. Zakharov, Jessica A. Hennessey, Uma Mahesh R. Avula, Johanna Diaz, Chaojian Wang, Elaine Y. Wan, Geoffrey S. Pitt, Manu Ben-Johny, Steven O. Marx
Jeffrey Abrams, Daniel Roybal, Nourdine Chakouri, Alexander N. Katchman, Richard Weinberg, Lin Yang, Bi-xing Chen, Sergey I. Zakharov, Jessica A. Hennessey, Uma Mahesh R. Avula, Johanna Diaz, Chaojian Wang, Elaine Y. Wan, Geoffrey S. Pitt, Manu Ben-Johny, Steven O. Marx
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Research Article Cardiology

Fibroblast growth factor homologous factors tune arrhythmogenic late NaV1.5 current in calmodulin binding–deficient channels

Abstract

The Ca2+-binding protein calmodulin has emerged as a pivotal player in tuning Na+ channel function, although its impact in vivo remains to be resolved. Here, we identify the role of calmodulin and the NaV1.5 interactome in regulating late Na+ current in cardiomyocytes. We created transgenic mice with cardiac-specific expression of human NaV1.5 channels with alanine substitutions for the IQ motif (IQ/AA). The mutations rendered the channels incapable of binding calmodulin to the C-terminus. The IQ/AA transgenic mice exhibited normal ventricular repolarization without arrhythmias and an absence of increased late Na+ current. In comparison, transgenic mice expressing a lidocaine-resistant (F1759A) human NaV1.5 demonstrated increased late Na+ current and prolonged repolarization in cardiomyocytes, with spontaneous arrhythmias. To determine regulatory factors that prevent late Na+ current for the IQ/AA mutant channel, we considered fibroblast growth factor homologous factors (FHFs), which are within the NaV1.5 proteomic subdomain shown by proximity labeling in transgenic mice expressing NaV1.5 conjugated to ascorbate peroxidase. We found that FGF13 diminished late current of the IQ/AA but not F1759A mutant cardiomyocytes, suggesting that endogenous FHFs may serve to prevent late Na+ current in mouse cardiomyocytes. Leveraging endogenous mechanisms may furnish an alternative avenue for developing novel pharmacology that selectively blunts late Na+ current.

Authors

Jeffrey Abrams, Daniel Roybal, Nourdine Chakouri, Alexander N. Katchman, Richard Weinberg, Lin Yang, Bi-xing Chen, Sergey I. Zakharov, Jessica A. Hennessey, Uma Mahesh R. Avula, Johanna Diaz, Chaojian Wang, Elaine Y. Wan, Geoffrey S. Pitt, Manu Ben-Johny, Steven O. Marx

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Figure 3

QT interval and ventricular repolarization is not prolonged in IQ/AA transgenic mice.

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QT interval and ventricular repolarization is not prolonged in IQ/AA tra...
(A) Representative limb-lead surface electrocardiograms of isoflurane-anesthetized littermate nontransgenic, pWT, IQ/AA, and F1759A transgenic mice. (B–D) Bar graphs of RR, PR, and QT intervals from isoflurane-anesthetized mice. Mean ± SEM. For RR interval, P= 0.12; for PR interval, P = 0.0004; for QT interval, P < 0.001 by 1-way ANOVA. **P < 0.01, ***P < 0.001 by Dunnett’s multiple comparison test. NTG, n = 5; pWT, n = 17; IQ/AA, n = 13; F1759A, n = 5. (E–G) Representative optical APD maps (E and G) and optical action potential tracings (F) from F1759A and IQ/AA mice. APD maps for F1759A-dTG were obtained after hyperkalemia-induced conversion to sinus rhythm. The circles in panels E and G mark the regions for which optical action potential tracings are displayed in F. Scale bar: 1 mm. Representative of 3 similar recordings. (H) Snapshot from phase movie of Langendorff-perfused F1759A-dTG hearts demonstrating rotor in the ventricle after burst pacing–induced ventricular arrhythmia. Representative of 3 similar experiments.