Litcius/Paper detail

Reduction of A-to-I RNA editing in the failing human heart regulates formation of circular RNAs

Karoline Elizabeth Kokot, Jasmin M. Kneuer, David John, Sabine Rebs, Maximilian N. Möbius-Winkler, Stephan Erbe, Marion Müller, Michael Andritschke, Susanne Gaul, Bilal N. Sheikh, Jan Haas, Hölger Thiele, Oliver J. Müller, Susanne Hille, Florian Leuschner, Stefanie Dimmeler, Katrin Streckfuß‐Bömeke, Benjamin Meder, Ulrich Laufs, Jes‐Niels Boeckel

2022Basic Research in Cardiology50 citationsDOIOpen Access PDF

Abstract

Alterations of RNA editing that affect the secondary structure of RNAs can cause human diseases. We therefore studied RNA editing in failing human hearts. Transcriptome sequencing showed that adenosine-to-inosine (A-to-I) RNA editing was responsible for 80% of the editing events in the myocardium. Failing human hearts were characterized by reduced RNA editing. This was primarily attributable to Alu elements in introns of protein-coding genes. In the failing left ventricle, 166 circRNAs were upregulated and 7 circRNAs were downregulated compared to non-failing controls. Most of the upregulated circRNAs were associated with reduced RNA editing in the host gene. ADAR2, which binds to RNA regions that are edited from A-to-I, was decreased in failing human hearts. In vitro, reduction of ADAR2 increased circRNA levels suggesting a causal effect of reduced ADAR2 levels on increased circRNAs in the failing human heart. To gain mechanistic insight, one of the identified upregulated circRNAs with a high reduction of editing in heart failure, AKAP13, was further characterized. ADAR2 reduced the formation of double-stranded structures in AKAP13 pre-mRNA, thereby reducing the stability of Alu elements and the circularization of the resulting circRNA. Overexpression of circAKAP13 impaired the sarcomere regularity of human induced pluripotent stem cell-derived cardiomyocytes. These data show that ADAR2 mediates A-to-I RNA editing in the human heart. A-to-I RNA editing represses the formation of dsRNA structures of Alu elements favoring canonical linear mRNA splicing and inhibiting the formation of circRNAs. The findings are relevant to diseases with reduced RNA editing and increased circRNA levels and provide insights into the human-specific regulation of circRNA formation.

Topics & Concepts

RNA editingRNAADARBiologyIntronRNA splicingAlu elementRNA silencingRNA-binding proteinCell biologyDownregulation and upregulationTranscriptomeMolecular biologyGeneticsGeneGene expressionRNA interferenceHuman genomeGenomeRNA regulation and diseaseRNA Research and SplicingViral Infections and Immunology Research