Coordination of cohesin and DNA replication observed with purified proteins
成果类型:
Article
署名作者:
Murayama, Yasuto; Endo, Shizuko; Kurokawa, Yumiko; Kurita, Ayako; Iwasaki, Sanae; Araki, Hiroyuki
署名单位:
Research Organization of Information & Systems (ROIS); National Institute of Genetics (NIG) - Japan; Japan Science & Technology Agency (JST); Research Organization of Information & Systems (ROIS)
刊物名称:
Nature
ISSN/ISSBN:
0028-6876
DOI:
10.1038/s41586-023-07003-6
发表日期:
2024-02-15
页码:
653-+
关键词:
sister-chromatid cohesion
budding yeast
wapl controls
establishment
complex
acetylation
helicase
identification
entry
ctf4
摘要:
Two newly duplicated copies of genomic DNA are held together by the ring-shaped cohesin complex to ensure faithful inheritance of the genome during cell division(1-3). Cohesin mediates sister chromatid cohesion by topologically entrapping two sister DNAs during DNA replication(4,5), but how cohesion is established at the replication fork is poorly understood. Here, we studied the interplay between cohesin and replication by reconstituting a functional replisome using purified proteins. Once DNA is encircled before replication, the cohesin ring accommodates replication in its entirety, from initiation to termination, leading to topological capture of newly synthesized DNA. This suggests that topological cohesin loading is a critical molecular prerequisite to cope with replication. Paradoxically, topological loading per se is highly rate limiting and hardly occurs under the replication-competent physiological salt concentration. This inconsistency is resolved by the replisome-associated cohesion establishment factors Chl1 helicase and Ctf4 (refs. (6,7)), which promote cohesin loading specifically during continuing replication. Accordingly, we found that bubble DNA, which mimics the state of DNA unwinding, induces topological cohesin loading and this is further promoted by Chl1. Thus, we propose that cohesin converts the initial electrostatic DNA-binding mode to a topological embrace when it encounters unwound DNA structures driven by enzymatic activities including replication. Together, our results show how cohesin initially responds to replication, and provide a molecular model for the establishment of sister chromatid cohesion.