Abstract P1134: RNA Elongation Mediates Rapid Induction Of Gene Expression During Endothelial-to-mesenchymal Transition

Abstract

Endothelial-to-mesenchymal transition (EndMT) is triggered by stress stimuli and characterized by the conversion of endothelial cells (EC) into mesenchymal cells. Stress stimuli such as hypoxia or inflammation depend on rapid gene expression mediated by RNA elongation. RNA elongation is controlled by the super elongation complex (SEC) through transient pausing of RNA Polymerase II (RNAPII). We aimed to analyze the regulatory role of RNA elongation on rapid gene expression during the onset of EndMT. In an in vitro EndMT model, SEC scaffolds AFF1 and AFF4 were upregulated compared to controls. SEC inhibition using chemical compounds reduced the protein levels of AFF1 and AFF4. EndMT was reduced by SEC inhibition, whereas overexpression of AFF4 increased EndMT as measured by mesenchymal marker gene expression. Rapid gene expression depends on the release of paused RNAPII at promoter sites. ChIP-sequencing revealed a reduction of RNAPII occupancy at promoter sites in EndMT compared to controls, suggesting the release of RNAPII during EndMT. Transcriptome-wide RNA elongation rates were increased as early as 10 min after induction of EndMT, as determined by analysis of nascent 4sU-labeled RNA. SEC inhibition reduced global RNA elongation rates, suggesting a regulatory contribution of RNA elongation in EndMT. Among the genes that were immediately upregulated after the induction of EndMT was the SPARC mRNA. RNA initiation and elongation of SPARC mRNA were increased 10 min after EndMT induction, which was reduced by SEC inhibition. At 72 h after EndMT induction, inhibition of SEC decreased SPARC mRNA, protein concentration and SPARC delivery to the supernatant. Silencing of SPARC reduced the angiogenic potential of EC and enhanced EndMT induction, which was attenuated by treatment with recombinant SPARC. Treatment with recombinant SPARC also improved endothelial impedance under EndMT conditions. Spatial transcriptomics revealed increased SPARC expression in brachiocephalic artery plaques from LDLR-/- mice. In conclusion, we observed increased RNA elongation rates associated with reduced RNAPII pausing during EndMT that mediate rapid gene expression of target genes such as SPARC. Our results suggest that RNA elongation plays a regulatory role in EndMT.