Abstract
The extracellular matrix protein fibronectin (FN) is alternatively spliced in a variety of inflammatory conditions, resulting in increased inclusion of alternative exons EIIIA and EIIIB. Inclusion of these exons affects fibril formation, fibrosis, and inflammation. To define upstream regulators of alternative splicing in FN, we have developed an in vitro flow-cytometry based assay, using RNA-binding probes to determine alternative exon inclusion level in aortic endothelial cells. This approach allows us to detect exon inclusion in the primary transcripts themselves, rather than in surrogate splicing reporters. We validated this assay in cells with and without FN-EIIIA and -EIIIB expression. In a small-scale CRISPR KO screen of candidate regulatory splice factors, we successfully detected known regulators of EIIIA and EIIIB splicing, and detected several novel regulators. Finally, we show the potential in this approach to broadly interrogate upstream signaling pathways in aortic endothelial cells with a genome-wide CRISPR-KO screen, implicating the TNFalpha and RIG-I-like signaling pathways and genes involved in the regulation of fibrotic responses. Thus, we provide a novel means to screen the regulation of splicing of endogenous transcripts, and predict novel pathways in the regulation of FN-EIIIA inclusion.
Highlights
Alternative splicing of the essential extracellular matrix protein fibronectin (FN) is tightly regulated during development and in d isease[1]
We found increased staining with both the EIIIA and EIIIB probes in FnAB-het cells, compared to FnABnull cells (Fig. 1B and data not shown), indicating that our probes are specific to these domains
As we were most interested in the ratio of splice isoform to total FN, or the percent spliced in (Psi), we normalized EIIIA and EIIIB inclusion to total FN
Summary
Alternative splicing of the essential extracellular matrix protein fibronectin (FN) is tightly regulated during development and in d isease[1]. We describe an approach to assess RNA splicing in native transcripts with single cell resolution, and show how this approach allows for the screening of upstream mediators of EIIIA and EIIIB inclusion in cultured aortic endothelial cells. We validate that this approach identifies known regulators of EIIIA and EIIIB splicing in a targeted screen, and use the approach in a genome-wide screen to identify novel genetic dependencies
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