SYNPO2L Isoforms Regulate the Action Potential Characteristics and Contractility of Atrial Cardiomyocytes via YAP Signaling to Modulate Atrial Fibrillation Risk
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Background
SYNPO2L is a component of the sarcomere Z-disk with two distinct isoforms (SYNPO2L_A and SYNPO2L_B) described to regulate actin bundle size. Common and rare variations in SYNPO2L have been implicated in risk for heart failure and atrial fibrillation (AF); however, little is known about the function or pathophysiological mechanism upon disease risk.
Methods
The role of SYNPO2L was explored with human induced pluripotent stem cell cardiomyocyte (hiPSC-CM) models of a rare splicing mutation rs766868752 differentiated into both atrial and ventricular lineages. Electrophysiology was assessed via multi-electrode arrays (MEAs) and contractility was assessed using engineered heart tissues (EHTs). Genetic survival analyses were performed to explore the potential therapeutic role of the SYNPO2L_A isoform in AF risk after myocardial infarction.
Results
hiPSC-CMs carrying the splice mutation rs766868752 resulted in preferential expression of the SYNPO2L_B isoform and absence of SYNPO2L_A isoform, and atrial hiPSC-CMs displayed significant differences in action potential durations when unpaced, and spontaneous extra-systolic beats when paced. Contractility of atrial hiPSC-CMs carrying the splice mutation was severely compromised. Electrophysiological differences were normalized and contractility was partially restored by overexpression with AAV:SYNPO2L_A. Absence of SYNPO2L_A in the mutant led to an observed decreased phosphorylation of YAP along with significant downstream transcriptional effects. A direct interaction between SYNPO2L_A and LATS2, a known regulator of YAP phosphorylation was found to occur in hiPSC-CMs. Additionally, a common variant time-to-event analysis may suggest a beneficial effect of the SYNPO2L_A isoform to lower the risk of atrial fibrillation after myocardial infarction.
Conclusions
A rare splice mutation conferring isoform predominance of SYNPO2L_B appears to disturb the electrophysiology and contractility of atrial hiPSC-CMs via LATS2 phospho-regulatory effects upon YAP signaling. Supplementation of the SYNPO2L_A isoform can restore many functional deficits and supports a specific gene regulatory role for SYNPO2L in modulating the risk of AF and heart failure.
