Cell Reports (Sep 2018)
A Splicing-Independent Function of RBM10 Controls Specific 3′ UTR Processing to Regulate Cardiac Hypertrophy
Abstract
Summary: RNA binding motif protein 10 (RBM10) is a regulator of alternative splicing in apoptosis and inflammation. We discovered a splicing-independent function of RBM10 critical for the regulation of heart failure (HF). RBM10 is enriched in the heart and associates with Star-PAP (TUT1) to control the expression and 3′ end processing of cardiac mRNAs. The RBM10 RRM2 domain binds the Star-PAP catalytic domain, which directs Star-PAP activity toward polyadenylation. RBM10 binds the pre-mRNA UTR, assembles the Star-PAP complex, and guides this complex specifically to mRNAs encoding anti-hypertrophy regulators. Accordingly, we tested cellular hypertrophy in rat cardiomyoblasts and cardiac hypertrophy (CH) and the subsequent progression to HF in Wistar rat hearts. We demonstrated downregulation of RBM10 during CH and HF. Ectopic re-expression of RBM10 rescued cardiomyocyte hypertrophy. RBM10 depletion evoked a hypertrophic response in H9c2 cells. Our results establish an anti-hypertrophy mechanism mediated by RBM10 in the heart that is directly linked to HF. : Regulation at the mRNA 3′ UTR is a critical mechanism in the heart, but how it is accomplished during hypertrophy or heart failure is poorly understood. Mohan et al. report an anti-hypertrophy mechanism mediated by RBM10 through 3′ UTR processing of key hypertrophy factors that regulates heart failure. Keywords: 3′ end processing, Star-PAP, RBM10, gene expression, 3′ UTR, cardiac mRNA, heart failure, cardiac hypertrophy
