Replication-dependent histone (Repli-Histo) labeling dissects the physical properties of euchromatin/heterochromatin in living human cells

A string of nucleosomes, where genomic DNA is wrapped around histones, is organized in the cell as chromatin. Chromatin in the cell varies greatly, from euchromatin to heterochromatin, in its genome functions. It is important to understand how heterochromatin is physically different from euchromatin. However, their specific labeling methods in living cells are limited. To address this, we have developed replication-dependent histone labeling (Repli-Histo labeling) to label nucleosomes in euchromatin and heterochromatin based on DNA replication timing. We investigated local nucleosome motion in the four chromatin classes from euchromatin to heterochromatin of living human and mouse cells. We found that more euchromatic regions (earlier replicated regions) show greater nucleosome motion. Notably, the motion profile in each chromatin class persists throughout interphase. Genome chromatin is essentially replicated from regions with greater nucleosome motions, even though the replication timing program is perturbed. Our findings, combined with computational modeling, suggest that earlier replicated regions have more accessibility and local chromatin motion can be a major determinant of genome-wide replication timing.