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Viscoelastic extracellular matrix enhances epigenetic remodeling and cellular plasticity

Yifan Wu, Yang Song, Jennifer Soto, Tyler Hoffman, Xiao Lin, Aaron Zhang, Siyu Chen, Ramzi N Massad, Xiao Han, Dongping Qi, Kun-Wei Yeh, Zhiwei Fang, Joon Eoh, Luo Gu, Amy C. Rowat, Zhen Gu, Song Li

2025Nature Communications42 citationsDOIOpen Access PDF

Abstract

Extracellular matrices of living tissues exhibit viscoelastic properties, yet how these properties regulate chromatin and the epigenome remains unclear. Here, we show that viscoelastic substrates induce changes in nuclear architecture and epigenome, with more pronounced effects on softer surfaces. Fibroblasts on viscoelastic substrates display larger nuclei, lower chromatin compaction, and differential expression of distinct sets of genes related to the cytoskeleton and nuclear function, compared to those on elastic surfaces. Slow-relaxing viscoelastic substrates reduce lamin A/C expression and enhance nuclear remodeling. These structural changes are accompanied by a global increase in euchromatin marks and local increase in chromatin accessibility at cis-regulatory elements associated with neuronal and pluripotent genes. Consequently, viscoelastic substrates improve the reprogramming efficiency from fibroblasts into neurons and induced pluripotent stem cells. Collectively, our findings unravel the roles of matrix viscoelasticity in epigenetic regulation and cell reprogramming, with implications for designing smart materials for cell fate engineering.

Topics & Concepts

Extracellular matrixEpigeneticsCell biologyPlasticityBiologyMaterials scienceGeneticsGeneComposite materialTissue Engineering and Regenerative MedicineCellular Mechanics and InteractionsGraphene and Nanomaterials Applications
Viscoelastic extracellular matrix enhances epigenetic remodeling and cellular plasticity | Litcius