Extrusive and cohesive cohesin cooperate to repair double-strand breaks in DNA.
Learn more in a new #SciencePerspective: https://scim.ag/3XKbhb6
13.12.2025 21:15
π 39
π 10
π¬ 1
π 2
Extrusive and cohesive cohesin cooperate to repair double-strand breaks in DNA.
Learn more in a new #SciencePerspective: https://scim.ag/3XKbhb6
Thank you, Federico! And congratulations to you too! The studies complement each other quite nicely, indeed.
Thank you, Prof. Ramsden!
Thanks, Jan! Congratulations to you too. Really amazing work!
Last but not least, I am incredibly grateful to my mentor, Taekjip Ha, for giving me the freedom to take risks and for guiding me throughout the project. And co-mentor, Ralph Scully, for all his support and mentorship. 11/n
Big thanks to our amazing team β especially co-first authors Adam and @namratan.bsky.social who put so much work into this project. Itβs been a huge privilege to work with you. 10/n
Also, check out the related work by @fedeteloni.bsky.social et al, from @gerlichlab.bsky.social who looked at the role of cohesive cohesin as well.
www.science.org/doi/10.1126/...
And the insightful perspective by Jiazhi Hu! 9/n
www.science.org/doi/10.1126/...
Link to the publication below! 8/n
www.science.org/doi/10.1126/...
Thus, chromatin loops donβt just organize the genome to control gene expression β they also protect its integrity by helping a broken DNA find its matching sequence for repair! 7/n
We discovered that instead of searching randomly, cells use an active 1D scanning process: the repair machinery leverages a looping protein called cohesin to βslideβ the break along the DNA and find the matching sequence. 6/n
Simply relying on random 3D diffusion β letting the broken DNA wander through the nucleus β would be inefficient. Even for a 1 Mb region, the broken DNA would take far too long to find its matching sequence by chance alone. 5/n
Now, after DNA replicates, sister chromatids are held together approximately every 1 Mb so the search is confined to ~1 M nucleotides. But finding the right match is still a huge challenge β especially if the sisters arenβt perfectly aligned. 4/n
Homologous recombination is key for protecting the genome, but itβs also challenging because the broken DNA must find its matching copy within billions of nucleotides. How can a cell achieve this? This is known as the βhomology searchβ problem. 3/n
When DNA breaks, cells often repair it through a process called homologous recombination, in which a matching (replicated) copy of the broken sequence is used as a repair template. 2/n
Thrilled to share that my postdoc research is published today in @science.org! We found that DNA repair uses cohesin complexes to build new chromatin loops that guide the homology search and boost accurate repair! 1/n
www.science.org/doi/10.1126/...
And the insightful perspective by Jiazhi Hu! 10/n
www.science.org/doi/10.1126/...
Also, check out the related study by @fedeteloni.bsky.social from @gerlichlab.bsky.social where they also looked at the role of cohesive cohesin! 9/n
www.science.org/doi/10.1126/...
Link to the publication below! 8/n
www.science.org/doi/10.1126/...
Thus, chromatin loops donβt just organize the genome to control gene expression β they also protect its integrity by helping a broken DNA find its matching sequence for repair! 7/n
We discovered that instead of searching randomly, cells use an active 1D scanning process: the repair machinery leverages a looping protein called cohesin to βslideβ the break along the DNA and find the matching sequence. 6/n
Simply relying on random 3D diffusion β letting the broken DNA wander through the nucleus β would be inefficient. Even for a 1 Mb region, the broken DNA would take far too long to find its matching sequence by chance alone. 5/n
Now, after DNA replicates, sister chromatids are held together approximately every 1 Mb so the search is confined to ~1 M nucleotides. But finding the right match is still a huge challenge β especially if the sisters arenβt perfectly aligned. 4/n
Homologous recombination is key for protecting the genome, but itβs also challenging because the broken DNA must find its matching copy within billions of nucleotides. How can a cell achieve this? This is know as the βhomology searchβ problem. 3/n
When DNA breaks, cells often repair it through a process called homologous recombination, in which a matching (replicated) copy of the broken sequence is used as a repair template. 2/n
15/n
Also, check out the pre-prints by @fedeteloni.bsky.social from @gerlichlab.bsky.social and by @charlesyeh.bsky.social from @jcornlab.bsky.social with other cool insights about the homology search!
www.biorxiv.org/content/10.1...
www.biorxiv.org/content/10.1...
14/n
I also want to thank all the other authors: Daniel Nguyen, Violetta Karwacki-Neisius, Andrew G. Li, Roger Zou, Franklin Aviles-Vazquez and Masato Kanemaki.
And huge thanks to Yang Liu who made vfCRISPR and to
@nucleosomezky.bsky.social and @rezakalhor.bsky.social for discussions!
13/n
Incredibly thankful to my mentor, Taekjip Ha, who supervised and mentored me on this project,
to my co-mentor, Ralph Scully, who designed the mESC exps and mentored me on HR,
and to co-first authors Adam Rybczynski and Namrata Nilavar, who helped make this possible!
12/n
Our model, in a nutshell: cohesin drives homology search via 1D scanning.
During HR, a RAD51 filament locally scans the sister chromatid, but this search could be unproductive (e.g., because the donor is far).
Cohesin loops would then facilitate long-range scanning to help find a donor!
