Abstract 17334: Association of BIN1 Deletion With Electrical and Structural Remodeling in a Transgenic BIN1 KO Mouse Model of Heart Failure-Novel Option for Effective Therapy Using VK-II-86

Abstract

Introduction: Cardiac deletion of Bridging Integrator 1 (BIN1) membrane protein produces an age-related cardiomyopathy in mice. Our hypothesis was to determine whether electrical accompanies this structural remodeling and examine the utility of VK-II-86, a structural analog of carvedilol with minimum β-blocking activity, as a potential antiarrhythmic therapeutic strategy. Methods: A cardiac-specific transgenic BIN1 KO mouse was employed. Structural and electrical cardiac changes were assessed using echocardiography and EKG (Visual Sonics-Vevo Heart Image). Murine ventricular cardiomyocytes were studied using patch-clamp techniques to examine changes in ion channel function and to study the effects of VK-II-86 on the action potential (AP). Results: Loss of BIN1 (KO) significantly reduced Left Ventricular Ejection Fraction (LVEF) and Cardiac Output (CO) when compared to WT mice, with a relative reduction of nearly 20% and 35% in EF and CO, respectively. Heterozygotic mice (HET) also exhibited significant reduction in EF and CO compared to WT mice. Loss of BIN1 (KO and HET) significantly prolonged the QT interval on surface ECG by approximately 15%. This finding correlates with the increase in AP duration (APD) demonstrated in ventricular cardiomyocytes using current clamp. BIN1 deficient hearts displayed significant reduction in expression of I to , I K1 and peak I Na (80%, 40% and 20% respectively) as well as augmented expression of late I Na (50%). This electrical remodeling is likely responsible for the increased expression of early (EAD) and late (DAD) afterdepolarization observed in APs. In BIN1 deficient ventricular cardiomyocytes, the addition of 1 μM VK-II-86 prevented the development of APD prolongation and suppressed EAD and DAD development. Conclusions: Our study adds to the understanding the role of BIN1. We demonstrate the first-time electrical remodeling in the form of QT and APD prolongation associated with BIN1 deficiency, due to reduced I to and I K1 and increase in late I Na , an increase in EAD and DAD events. Additionally, VK-II-86 is shown to normalize APD in isolated cardiomyocytes and suppress afterdepolarization events, making it a potentially novel and effective therapeutic strategy in HF associated with BIN1 deficiency.