Transcription factor ETV1 is essential for rapid conduction in the heart
Akshay Shekhar, … , Glenn I. Fishman, David S. Park
Akshay Shekhar, … , Glenn I. Fishman, David S. Park
Published October 24, 2016
Citation Information: J Clin Invest. 2016;126(12):4444-4459. https://doi.org/10.1172/JCI87968.
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Research Article Cardiology Development

Transcription factor ETV1 is essential for rapid conduction in the heart

Abstract

Rapid impulse propagation in the heart is a defining property of pectinated atrial myocardium (PAM) and the ventricular conduction system (VCS) and is essential for maintaining normal cardiac rhythm and optimal cardiac output. Conduction defects in these tissues produce a disproportionate burden of arrhythmic disease and are major predictors of mortality in heart failure patients. Despite the clinical importance, little is known about the gene regulatory network that dictates the fast conduction phenotype. Here, we have used signal transduction and transcriptional profiling screens to identify a genetic pathway that converges on the NRG1-responsive transcription factor ETV1 as a critical regulator of fast conduction physiology for PAM and VCS cardiomyocytes. Etv1 was highly expressed in murine PAM and VCS cardiomyocytes, where it regulates expression of Nkx2-5, Gja5, and Scn5a, key cardiac genes required for rapid conduction. Mice deficient in Etv1 exhibited marked cardiac conduction defects coupled with developmental abnormalities of the VCS. Loss of Etv1 resulted in a complete disruption of the normal sodium current heterogeneity that exists between atrial, VCS, and ventricular myocytes. Lastly, a phenome-wide association study identified a link between ETV1 and bundle branch block and heart block in humans. Together, these results identify ETV1 as a critical factor in determining fast conduction physiology in the heart.

Authors

Akshay Shekhar, Xianming Lin, Fang-Yu Liu, Jie Zhang, Huan Mo, Lisa Bastarache, Joshua C. Denny, Nancy J. Cox, Mario Delmar, Dan M. Roden, Glenn I. Fishman, David S. Park

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Figure 9

Loss of Etv1 homogenizes sodium channel biophysical properties between ventricular, atrial, and Purkinje myocytes.

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Loss of Etv1 homogenizes sodium channel biophysical properties between v...
Whole-cell patch clamp was performed on dissociated cardiac cells (ventricular, atrial, Purkinje myocytes) from P18 Etv1 WT and KO mice in a Cntn2EGFP/+ background. (A) Comparison of sodium current–voltage (I-V) relationship. (B) Voltage dependence of steady-state activation. (C) Voltage dependence of steady-state inactivation. (D) Time course of recovery from inactivation. (AD) Maximum conductance, voltage at half activation (V0.5, activation), voltage at half inactivation (V0.5, inactivation), and tau of recovery (τrecovery) were used to assess significant differences among experimental groups (right panels), respectively (n = 4 hearts). Diagrams outlining patch clamp protocols are included for each endpoint. Data represent mean ± SEM. *P < 0.05, 1-way ANOVA.