Abstract 12947: Development of Molecular Targeted Therapy Against Right Ventricular Failure: Involvement in A Network of Immunocompetent Cells

Abstract

Backgrounds: Right ventricular (RV) failure plays a critical role in right heart failure and left heart failure. However, there is no specific therapy developed for RV failure. To elucidate a novel therapeutic target against RV failure, we focus on differentially expressed genes in RV to develop novel therapeutics for RV failure. Methods: Microarray analysis using several parts of adult murine heart was conducted and differentially expressed genes (DEGs) were applied to pathway analysis by Ingenuity Pathway Analysis R . Molecular mechanism was examined by using neonatal rat ventricular cardiomyocyte (NRVM) in vitro . To understand the function of target molecule in vivo , we induced RV failure by pulmonary artery constriction (PAC) in mice and inhibition experiments were performed using these RV failure model mice. Results: In microarray analysis for RV, left ventricle and ventricular septum, 995 genes were extracted as DEGs in RV. Pathway analysis revealed that alternative complement pathway-related genes were significantly up-regulated in RV. Moreover, complement factor D (Cfd) and C3a was a potential upstream factor attributable to unique feature of RV. Administration of C3a recombinant protein to NRVM phosphorylated several MAP kinases. Moreover, in C3KO PAC mice, RV dysfunction was significantly suppressed, and histological study suggested that RV fibrosis was significantly suppressed by comparing to wild type PAC mice. Furthermore, administration of C3a receptor antagonist to wild type PAC mice dramatically improved RV dysfunction and reduced RV fibrosis. Additionally, in vivo electrophysiological study revealed that the inducibility of ventricular arrhythmia was increased in wild type PAC mice, but ventricular arrhythmia was significantly attenuated in C3KO PAC mice. Conclusion: We revealed that complement C3a was highly produced in RV, and genetic or chemical blockade of C3a ameliorates RV dysfunction and RV fibrosis in RV failure model mice. C3a was to be a potent bioactive protein for immunocompetent cells that played an important role in modulating RV function. Accordingly, we demonstrated that the blockade of C3a had a potential role for novel therapeutic target of RV failure.