Control of endothelial cell function and arteriogenesis by MEG3:EZH2 epigenetic regulation of integrin expression

Hywel Dunn-Davies, Tatiana Dudnakova, Antonella Nogara, Julie Rodor, Anita C. Thomas, Elisa Parish, Philippe Gautier, Alison Meynert, Igor Ulitsky, Paolo Madeddu, Andrea Caporali, Andrew Baker, David Tollervey, Tijana Mitić*

*Corresponding author for this work

Research output: Contribution to journalArticlepeer-review

1 Citation (Scopus)

Abstract

Epigenetic processes involving long non-coding RNAs regulate endothelial gene expression. However, the underlying regulatory mechanisms causing endothelial dysfunction remain to be elucidated. Enhancer of zeste homolog 2 (EZH2) is an important rheostat of histone H3K27 trimethylation (H3K27me3) that represses endothelial targets, but EZH2 RNA binding capacity and EZH2:RNA functional interactions have not been explored in post-ischemic angiogenesis. We used formaldehyde/UV-assisted crosslinking ligation and sequencing of hybrids and identified a new role for maternally expressed gene 3 (MEG3). MEG3 formed the predominant RNA:RNA hybrid structures in endothelial cells. Moreover, MEG3:EZH2 assists recruitment onto chromatin. By EZH2-chromatin immunoprecipitation, following MEG3 depletion, we demonstrated that MEG3 controls recruitment of EZH2/H3K27me3 onto integrin subunit alpha4 (ITGA4) promoter. Both MEG3 knockdown or EZH2 inhibition (A-395) promoted ITGA4 expression and improved endothelial cell migration and adhesion to fibronectin in vitro. The A-395 inhibitor re-directed MEG3-assisted chromatin remodeling, offering a direct therapeutic benefit by increasing endothelial function and resilience. This approach subsequently increased the expression of ITGA4 in arterioles following ischemic injury in mice, thus promoting arteriogenesis. Our findings show a context-specific role for MEG3 in guiding EZH2 to repress ITGA4. Novel therapeutic strategies could antagonize MEG3:EZH2 interaction for pre-clinical studies.

Original languageEnglish
Article number102173
JournalMolecular Therapy Nucleic Acids
Volume35
Issue number2
Early online date17 Mar 2024
DOIs
Publication statusPublished - 11 Jun 2024

Bibliographical note

This work was supported by the British Hearth Foundation (BHF) Career Re-entry Fellowship (FS/16/38/32351), Wellcome Trust Institutional Strategic Funding Award (IS3-R1.12 19/20), and the BHF REA3 Institutional Award (RE/18/5/34216) (to T.M.). We are grateful for the support by BHF project grant (RG/20/5/34796) (to J.R.) and Cardioregenix grant (825670) (to T.D.). H.D.-D. was supported by the Core grant (092076) to the Wellcome Centre for Cell Biology at the University of Edinburgh. A.M. and P.G. are funded by the UK Medical Research Council (MRC core funding of the MRC Human Genetics Unit). D.T. was supported by the Wellcome Trust (109916, 222516). A.B. is supported by the BHF personal Chair (CH/11/2/28733). Furthermore, we thank the IGMM Mass Spectrometry Facility and Wellcome Trust Clinical Research Fascility in Edinburgh for processing the samples, and Alex von Kriegsheim for support with designing proteomics experiments, Richard Clark for help with sonicating samples, rispectively; Pam Holland for technical support. Finally, we are grateful to Dr. Mark Miller, Prof. Dave Newby, Dr. Rob Illingworth, and Prof. Alejandra San Martin for their fruitful discussions and valuable feedback on the project and for critically reading the manuscript. The graphical abstract and Figure 1B were created using Biorender.com.

Publisher Copyright:
© 2024

All Science Journal Classification (ASJC) codes

  • Molecular Medicine
  • Drug Discovery

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