Chl1 DNA helicase and Scc2 function in chromosome condensation through cohesin deposition.

Donglai Shen,Robert V Skibbens,Hong-Guo Yu

doi:10.1371/journal.pone.0188739

Donglai Shen, Robert V Skibbens + Show 1 more

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https://doi.org/10.1371/journal.pone.0188739

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Journal: PloS one	Publication Date: Nov 29, 2017
Citations: 9	License type: CC BY 4.0

Affiliation: Lehigh University

Abstract

Chl1 DNA helicase promotes sister chromatid cohesion and associates with both the cohesion establishment acetyltransferase Eco1/Ctf7 and the DNA polymerase processivity factor PCNA that supports Eco1/Ctf7 function. Mutation in CHL1 results in precocious sister chromatid separation and cell aneuploidy, defects that arise through reduced levels of chromatin-bound cohesins which normally tether together sister chromatids (trans tethering). Mutation of Chl1 family members (BACH1/BRIP/FANCJ and DDX11/ChlR1) also exhibit genotoxic sensitivities, consistent with a role for Chl1 in trans tethering which is required for efficient DNA repair. Chl1 promotes the recruitment of Scc2 to DNA which is required for cohesin deposition onto DNA. There is limited evidence, however, that Scc2 also directs the deposition onto DNA of condensins which promote tethering in cis (intramolecular DNA links). Here, we test the ability of Chl1 to promote cis tethering and the role of both Chl1 and Scc2 to promote condensin recruitment to DNA. The results reveal that chl1 mutant cells exhibit significant condensation defects both within the rDNA locus and genome-wide. Importantly, chl1 mutant cell condensation defects do not result from reduced chromatin binding of condensin, but instead through reduced chromatin binding of cohesin. We tested scc2-4 mutant cells and similarly found no evidence of reduced condensin recruitment to chromatin. Consistent with a role for Scc2 specifically in cohesin deposition, scc2-4 mutant cell condensation defects are irreversible. We thus term Chl1 a novel regulator of both chromatin condensation and sister chromatid cohesion through cohesin-based mechanisms. These results reveal an exciting interface between DNA structure and the highly conserved cohesin complex.

Highlights

Structural changes to the genome that occur over the cell cycle are fundamental yet mysterious features that underlie many cellular events
To assess the impact of Chl1 helicase on rDNA structure, wildtype and chl1 deletion cells were synchronized in G1 using medium supplemented with alpha factor, washed and released into fresh medium supplemented with nocodazole for 3 hours
Mutations in CHL1 human homologs BACH1/BRIP/FANCJ and ChlR1/DDX11 helicases collectively result in Warsaw Breakage Syndrome, Fanconi anemia, breast and ovarian cancers [27], [35,36,37], [40], [59,60,61]

Summary

Introduction

Structural changes to the genome that occur over the cell cycle are fundamental yet mysterious features that underlie many cellular events. During G1 phase of the cell cycle, chromatin compaction and higher order DNA assemblies termed TADS (topological associated domains) are largely regional [1], [2]. These cis-based (intramolecular) and trans-based (intermolecular) tetherings of DNA segments must remain dynamic to allow for plasticity and appropriate. Cis tethers established during prophase are stable—maintaining fully condensed and disentangled chromosomes through mitosis. These cis tethers are required for high fidelity chromosome segregation and the positioning of chromosomes away from the cytokinetic furrow. In an impressive coopting of function through evolution, each of these tethering activities in combination are mediated by SMC (stability of minichromosomes or structural maintenance of chromosomes) complexes that include cohesins (Smc, Smc, Mcd1/Scc1/RAD21, Pds, Scc3/Irr1/SA1,2 and Sororin in vertebrate cells) and condensins (Smc2/Cut, Smc4/Cut, Ycs4/Cnd1/DPY-28, Ycg1/ Cdn3/CAP-G1, Brn1/Cdn2/DPY-26) [1], [2], [6], [7]

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