RNA-binding protein RBM20 represses splicing to orchestrate cardiac pre-mRNA processing
Henrike Maatz, … , Markus Landthaler, Norbert Hubner
Henrike Maatz, … , Markus Landthaler, Norbert Hubner
Published June 24, 2014
Citation Information: J Clin Invest. 2014;124(8):3419-3430. https://doi.org/10.1172/JCI74523.
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Research Article Cardiology

RNA-binding protein RBM20 represses splicing to orchestrate cardiac pre-mRNA processing

Abstract

Mutations in the gene encoding the RNA-binding protein RBM20 have been implicated in dilated cardiomyopathy (DCM), a major cause of chronic heart failure, presumably through altering cardiac RNA splicing. Here, we combined transcriptome-wide crosslinking immunoprecipitation (CLIP-seq), RNA-seq, and quantitative proteomics in cell culture and rat and human hearts to examine how RBM20 regulates alternative splicing in the heart. Our analyses revealed the presence of a distinct RBM20 RNA-recognition element that is predominantly found within intronic binding sites and linked to repression of exon splicing with RBM20 binding near 3′ and 5′ splice sites. Proteomic analysis determined that RBM20 interacts with both U1 and U2 small nuclear ribonucleic particles (snRNPs) and suggested that RBM20-dependent splicing repression occurs through spliceosome stalling at complex A. Direct RBM20 targets included several genes previously shown to be involved in DCM as well as genes not typically associated with this disease. In failing human hearts, reduced expression of RBM20 affected alternative splicing of several direct targets, indicating that differences in RBM20 expression may affect cardiac function. Together, these findings identify RBM20-regulated targets and provide insight into the pathogenesis of human heart failure.

Authors

Henrike Maatz, Marvin Jens, Martin Liss, Sebastian Schafer, Matthias Heinig, Marieluise Kirchner, Eleonora Adami, Carola Rintisch, Vita Dauksaite, Michael H. Radke, Matthias Selbach, Paul J.R. Barton, Stuart A. Cook, Nikolaus Rajewsky, Michael Gotthardt, Markus Landthaler, Norbert Hubner

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Figure 6

Alignment of orthologous rat and human exons for Ryr2, Lmo7, Rtn4, and Pdlim3 to compare RBM20-regulated exon usage.

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Alignment of orthologous rat and human exons for Ryr2, Lmo7, Rtn4, and P...
PSI scores for the RBM20-deficient individual (S635A) are indicated in red and the average of 5 control subjects from the human heart failure cohort (CP) in blue. The average PSI of 3 rats per genotype is shown below (WT in blue and Rbm20–/– in red). Resulting ΔPSIs are shown in black (S635A compared with CP) and in gray (WT compared with Rbm20–/– rats). Deflections in ΔPSI values in differentially spliced regions are highly conserved across species. (A) Ryr2 shows RBM20-dependent splicing of a 24-bp exon included in RBM20-deficient hearts. The magnified view shows RBM20 cluster flanking the differentially spliced rat Ryr2 exon. (B) In Lmo7, RBM20 deficiency causes retention of exons 9 and 10. The zoom-in shows RBM20 cluster flanking exon 10 immediately upstream of its 3′ splice site. (C) Rtn4 exons 3 and 4 are differentially spliced. The magnification shows the intronic RBM20 cluster flanking rat exons 3 and 4. (D) Pdlim3 exons 4–6 are mutually exclusive and differentially regulated by RBM20. The zoom-in shows the locations of RBM20 cluster upstream of exon 4.