DNA loop extrusion by condensins and decatenation by DNA topoisomerase II (topo II) are thought to drive mitotic chromosome compaction and individualization. Here, we reveal that the linker histone H1.8 antagonizes condensins and topo II to shape mitotic chromosome organization. In vitro chromatin reconstitution experiments demonstrate that H1.8 inhibits binding of condensins and topo II to nucleosome arrays. Accordingly, H1.8 depletion in Xenopus egg extracts increased condensins and topo II levels on mitotic chromatin. Chromosome morphology and Hi-C analyses suggest that H1.8 depletion makes chromosomes thinner and longer through shortening the average loop size and reducing the DNA amount in each layer of mitotic loops. Furthermore, excess loading of condensins and topo II to chromosomes by H1.8 depletion causes hyper-chromosome individualization and dispersion. We propose that condensins and topo II are essential for chromosome individualization, but their functions are tuned by the linker histone to keep chromosomes together until anaphase.
SummaryDNA loop extrusion by condensins and decatenation by DNA topoisomerase II (topo II) drive mitotic chromosome compaction and individualization. Here, we reveal that the linker histone H1.8 regulates chromatin levels of condensins and topo II. In vitro chromatin reconstitution experiments demonstrate that H1.8 inhibits binding of condensins and topo II to nucleosome arrays. Accordingly, H1.8 depletion in Xenopus egg extracts increased condensins and topo II levels on mitotic chromatin. Chromosome morphology and Hi-C analyses suggest that H1.8 depletion makes chromosomes thinner and longer likely through shortening the average loop size and reducing DNA amount in each layer of mitotic loops. Furthermore, H1.8-mediated suppression of condensins and topo II binding to chromatin limits chromosome individualization by preventing resolution of interchromosomal linkages. While linker histones locally compact DNA by clustering nucleosomes, we propose that H1.8 controls chromosome morphology and topological organization through restricting the loading of condensins and topo II on chromatin.
The human centromere comprises large arrays of repetitive alpha-satellite DNA at the primary constriction of mitotic chromosomes. In addition, centromeres are epigenetically specified by the centromere-specific histone H3 variant CENP-A that supports kinetochore assembly to enable chromosome segregation. Since CENP-A is bound to only a fraction of the alpha-satellite elements within the megabase-sized centromere DNA, correlating the three-dimensional (3D) organization of alpha-satellite DNA and CENP-A remains elusive. To visualize centromere organization within a single chromatid, we used a combination of the Centromere Chromosome Orientation Fluorescent In Situ Hybridization (Cen-CO-FISH) technique together with Structured Illumination Microscopy (SIM). Cen-CO-FISH allows the differential labeling of the sister chromatids without the denaturation step used in conventional FISH that may affect DNA structure. Our data indicate that alpha-satellite DNA is arranged in a ring-like organization within prometaphase chromosomes, in presence or absence of spindle's microtubules. Using expansion microscopy (ExM), we found that CENP-A organization within mitotic chromosomes follows a rounded pattern similar to that of alpha-satellite DNA, often visible as a ring thicker at the outer surface oriented towards the kinetochore-microtubules interface. Collectively, our data provide a 3D reconstruction of alpha-satellite DNA along with CENP-A clusters that outline the overall architecture of the mitotic centromere. [Media: see text] [Media: see text] [Media: see text] [Media: see text]
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