Abstract
Diastolic dysfunction is increasingly prevalent in our ageing society and an important contributor to heart failure. The giant protein titin could serve as a therapeutic target, as its elastic properties are a main determinant of cardiac filling in diastole. This study aimed to develop a high throughput pharmacological screen to identify small molecules that affect titin isoform expression through differential inclusion of exons encoding the elastic PEVK domains. We used a dual luciferase splice reporter assay that builds on the titin splice factor RBM20 to screen ~34,000 small molecules and identified several compounds that inhibit the exclusion of PEVK exons. These compounds belong to the class of cardenolides and affect RBM20 dependent titin exon exclusion but did not affect RBFOX1 mediated splicing of FMNL3. We provide evidence that cardenolides do not bind to the RNA interacting domain of RBM20, but reduce RBM20 protein levels and alter transcription of select splicing factors that interact with RBM20.Cardenolides affect titin isoform expression. Understanding their mode of action and harnessing the splice effects through chemical modifications that suppress the effects on ion homeostasis and more selectively affect cardiac splicing has the potential to improve cardiac filling and thus help patients with diastolic heart failure, for which currently no targeted therapy exists.
Highlights
In developed countries heart failure (HF) keeps the top spot in mortality statistics and prevention and therapy have continuously been improved over the past 30 years, the prevalence of heart failure remains high [1]
A dual luciferase splicing reporter assay for high-throughput compound library screen
To facilitate high-throughput screen with a sensitive reporter that is not affected by background fluorescence of the compounds or cell system, we developed dual luciferase splicing reporter (DLR) based on the established minigenes: We integrated firefly luciferase (FLuc) into PEVK exon 8 or I97 and renilla luciferase (RLuc) at the 3’-end of the PEVK exon 13 or Iband exon I98 maintaining the open reading frame (Fig 1D and S1F Fig)
Summary
In developed countries heart failure (HF) keeps the top spot in mortality statistics and prevention and therapy have continuously been improved over the past 30 years, the prevalence of heart failure remains high [1]. Multiple environmental and genetic factors contribute to the development of heart failure. This includes age, sex, diabetes, kidney disease, inflammation, and mutations in sarcomeric proteins such as titin and splice factors such as RBM20, a regulator of titin based stiffness [2]. Small molecule screen with RBM 20 splice reporter assay
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