Histone marks are drivers of the splicing changes necessary for an epithelial-to-mesenchymal transition

Abstract

Cell differentiation and reprogramming depend on coordinated changes in specific alternative splicing events. How these cell type-specific splicing patterns are dynamically modified in response to a stimulus remains elusive. Taking advantage of the epithelial-to-mesenchymal transition (EMT), a reversible cell reprogramming intimately involved in cancer cell invasiveness and metastasis, we found a strong correlation between changes in the alternative splicing of key exons for EMT, such as at the Fgfr2 and Cnntd1 loci, and changes in the enrichment levels of specific histone modifications, namely H3K27ac and H3K27me3. Localised CRISPR epigenome editing of these exon-specific histone marks was sufficient to induce changes in splicing capable of recapitulating important aspects of EMT, such as a motile and invasive cell phenotype. Whereas, impairment of the changes in H3K27 marks observed during EMT, using histone deacetylase inhibitors, repressed inclusion of the mesenchymal isoform despite an EMT induction, supporting a driving effect for H3K27 modifications in establishing the new cell type-specific splicing patterns necessary for EMT cell reprogramming. Finally, H3K27 marks were shown to impact splicing by modulating recruitment of the splicing factor PTB to its RNA binding sites, suggesting a direct link between chromatin modifications and the splicing machinery. Taken together, these results prove the causal role of H3K27 marks in driving the dynamic splicing changes necessary for induction of important aspects of EMT. They also prove that chromatin-mediated splicing changes are sufficient to impact the cell’s phenotype, which expands the cell’s toolkit to adapt and respond to diverse stimuli, such as EMT induction.