Abstract 190: A Mechanotransduction Study In Embryonic Zebrafish Heart

Abstract

Background: While proper heart contraction requires an intact sarcomere structure, contraction reciprocally regulates sarcomere assembly and cardiomyocyte shape during heart morphogenesis and heart remodeling. However, how contraction modulates heart morphogenesis and the underlying molecular mechanism remains unclear. Here we address this question by manipulating cardiac contractility in a developing zebrafish embryo. Results: Cessation of heart contraction was achieved by treating zebrafish embryos with blebbistatin, a myosin II specific inhibitor, or Niferdipine, a Ca 2+ channel inhibitor. Loss of cardiac contractility reduces ventricular chamber size in 1 dpf embryo, but significantly increases ventricular chamber size in 2 dpf and 3 dpf embryos. In both circumstances, cessation of contraction consistently prevents or disrupts the lateral fusion of myofibril. Cessation of contraction-induced heart enlargement is reversible and also dependent on the time of drug treatment. This heart-remodeling event in 2dpf embryo, which manifests as increased cardiomyocyte surface area accompanied by reduced thickness, can be attenuated by reducing the transmural pressure towards the ventricle wall. This mechanotransductive process occurs in the myocardium without need of endocardium. At the molecular level, by screening several compounds, we found that PI3K signaling confers this contraction-regulated cardiomyocyte shape remodeling process without affecting the lateral fusion of sarcomere. Conclusion: Our data in an in vivo animal model distinguish two different and relatively independent functions of contraction in regulating lateral fusion of sarcomere and cardiomyocytes shape remodeling. The contraction-regulated heart shape remodeling is conveyed by PI3k signaling mediated mechanotransduction independent of endocardium.