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Multiscale structure of chromatin condensates explains phase separation and material properties

Huabin Zhou, Jan Huertas, Maria Julia Maristany, Kieran Russell, June Ho Hwang, Run-Wen Yao, Nirnay Samanta, Joshua Hutchings, Ramya Billur, Momoko Shiozaki, Xiaowei Zhao, Lynda K. Doolittle, Bryan A. Gibson, Andrea Soranno, Margot Riggi, Jorge R. Espinosa, Zhiheng Yu, Elizabeth Villa, Rosana Collepardo‐Guevara, Michael K. Rosen

2025Science23 citationsDOIOpen Access PDF

Abstract

The structure and interaction networks of molecules within biomolecular condensates are poorly understood. Using cryo-electron tomography and molecular dynamics simulations, we elucidated the structure of phase-separated chromatin condensates across scales, from individual amino acids to network architecture. We found that internucleosomal DNA linker length controls nucleosome arrangement and histone tail interactions, shaping the structure of individual chromatin molecules within and outside condensates. This structural modulation determines the balance between intra- and intermolecular interactions, which governs the molecular network, thermodynamic stability, and material properties of chromatin condensates. Mammalian nuclei contain dense clusters of nucleosomes whose nonrandom organization is mirrored by the reconstituted condensates. Our work explains how the structure of individual chromatin molecules determines physical properties of chromatin condensates and cellular chromatin organization.

Topics & Concepts

ChromatinNucleosomeLinker DNAHistoneBiophysicsDNAMoleculeIntermolecular forceChemical physicsChemistryHistone H1Protein structureLinkerChIA-PETSolenoidChromatin remodelingBivalent chromatinMolecular dynamicsPhase (matter)BiologyPhysicsCrystallographyHistone codeGenomics and Chromatin DynamicsDNA Repair MechanismsAdvanced Electron Microscopy Techniques and Applications
Multiscale structure of chromatin condensates explains phase separation and material properties | Litcius