hsa-miRNA-548v controls the viscoelastic properties of human cardiomyocytes and improves their relaxation rates

The impairment of left ventricular (LV) diastolic function with inadequate increase in myocardial relaxation velocity directly results in lower LV compliance, increased LV filling pressures and heart failure symptoms. The development of agents facilitating the relaxation of human cardiomyocytes requires a better understanding of the underlying regulatory mechanisms. We performed a high-content microscopy-based screening in human induced pluripotent stem cell-derived cardiomyocytes (hiPSC-CMs) using a library of 2565 human miRNA mimics and measured relaxation kinetics via high-computing analyses of motion movies. We identified hsa-miR-548v, a primate specific miRNA, as the miRNA producing the largest increase in relaxation velocities. This positive lusitropic effect was reproduced in engineered cardiac tissues generated with healthy and BRAF T599R mutant hiPSC-CMs, and was independent of changes in calcium transients. Consistent with improvements in viscoelastic responses to mechanical stretch, RNA-sequencing showed that hsa-miR-548v down-regulated multiple targets, especially components of the mechano-sensing machinery. The exogenous administration of hsa-miR-548v in hiPSC-CMs notably resulted in a significant reduction of ANKRD1/CARP1 expression and localization at the sarcomeric I-band. This study suggests that the sarcomere I-band is a critical control center of the ability of cardiomyocytes to relax and a target for improving relaxation and diastolic dysfunction. Overall design: To investigate the changes in gene expression levels in response to hsa-miR-548v as compared to miR negative control We performed gene expression profiling analysis using data obtained from RNA-seq of hiPSC-CMs transfected with hsa-miR-548v vs.miR negative control, 4 preparations per conditions, one time point