Targeting Pannexin 1 as a Novel Mechanism for Arrhythmia and Fibrosis in Duchenne Cardiomyopathy

PROJECT SUMMARY Cardiovascular disease is the primary cause of death for patients with Duchenne muscular dystrophy (DMD). Arrhythmia and cardiac fibrosis leading to dilated cardiomyopathy are the primary mechanisms of cardiac mortality. Pannexins (Pxs), which are large conductance ion and small molecule channels, have been

implicated in other fibroproliferative diseases and are thought to be arrhythmogenic in other model of cardiac disease. Loss of dystrophin, the primary defect in DMD, leads to elevated intracellular calcium (Ca2+) which is also a primary effector of Pxs. The goal of this project is to investigate the mechanisms by which Px1

modulates the development of cardiac fibrosis and arrhythmogenesis in models of DMD cardiomyopathy. Our preliminary data demonstrate a novel role for Px1 in the development of cardiac fibrosis and inducible arrhythmia seen in the D2-mdx model of DMD. Genetic ablation of Px1 in the D2-mdx model (mdxPx1-/-)

rescues the cardiac phenotype, including normalization of cardiac fibrosis.as assessed by histopathology and significant reduction in isoproterenol-induced ventricular ectopy. Based on these data, we hypothesize that pathologically elevated intracellular Ca2+, a hallmark of this disease, leads to Px1 activation and results in

signaling cascades that activate apoptotic, oxidative, and inflammatory pathways that ultimately lead to fibroblast activation and the development of cardiac fibrosis. We also hypothesize that Px1 channels represent an independent mechanism for ventricular arrhythmia via generation of delayed after-depolarizations (DADs).

We with test these hypotheses using the 3 specific aims outlined in this proposal. In Aim 1, we will use transgenic mice with global Px1 deletion in addition to pharmacological Px inhibition to determine if Px1 activation results in triggered arrhythmia. In Aim 2, we will identify the mechanism by which Px1 contributes to

cardiac fibrosis in DMD cardiomyopathy using pharmacological and genetic strategies. As Pxs are expressed in both cardiomyocytes and cardiac fibroblasts, Aim 3 will test if fibroblast migration is dependent on Px1 activation in cardiomyocytes and/or fibroblasts using co-culture techniques for human induced pluripotent stem

cell cardiomyocytes (hiPSC-CMs) and cardiac fibroblasts. The completion of these studies will help to improve our understanding of the mechanisms of cardiovascular disease in DMD and will provide the basis for further investigation of a novel therapeutic target that has the potential to delay or prevent cardiac mortality in DMD

patients. Additionally, this proposal will allow a promising young physician scientist to gain important skill in basic and translational studies in cardiac electrophysiology, cell signaling, and inflammation/fibrosis biology under the expert guidance of a highly accomplished and dedicated mentorship committee. These new skills will

provide the foundation for a successful transition from junior investigator to an independently-funded academic physician scientist.