Reconstituted TAD-size chromatin fibers feature heterogeneous nucleosome clusters

Reconstituted TAD-size chromatin fibers feature heterogeneous nucleosome clusters

Large topologically associated domains (TADs) contain irregularly spaced nucleosome clutches, and interactions between such clutches are thought to aid the compaction of these domains. Here, we reconstituted TAD-sized chromatin fibers containing hundreds of nucleosomes on native source human and lam...

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Bibliographic Details
Main Authors: Korolev, Nikolay, Zinchenko, Anatoly, Soman, Aghil, Chen, Qinming, Wong, Sook Yi, Berezhnoy, Nikolay V., Basak, Rajib, van der Maarel, Johan R. C., van Noort, John, Nordenskiöld, Lars
Other Authors: School of Biological Sciences
Format: Article
Language:English
Published: 2023
Subjects:
Science::Biological sciences
Histone
Chromatin
Online Access:https://hdl.handle.net/10356/165451
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Institution: Nanyang Technological University
Language: English
Description
Summary:Large topologically associated domains (TADs) contain irregularly spaced nucleosome clutches, and interactions between such clutches are thought to aid the compaction of these domains. Here, we reconstituted TAD-sized chromatin fibers containing hundreds of nucleosomes on native source human and lambda-phage DNA and compared their mechanical properties at the single-molecule level with shorter '601' arrays with various nucleosome repeat lengths. Fluorescent imaging showed increased compaction upon saturation of the DNA with histones and increasing magnesium concentration. Nucleosome clusters and their structural fluctuations were visualized in confined nanochannels. Force spectroscopy revealed not only similar mechanical properties of the TAD-sized fibers as shorter fibers but also large rupture events, consistent with breaking the interactions between distant clutches of nucleosomes. Though the arrays of native human DNA, lambda-phage and '601' DNA featured minor differences in reconstitution yield and nucleosome stability, the fibers' global structural and mechanical properties were similar, including the interactions between nucleosome clutches. These single-molecule experiments quantify the mechanical forces that stabilize large TAD-sized chromatin domains consisting of disordered, dynamically interacting nucleosome clutches and their effect on the condensation of large chromatin domains.

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