posted on 2021-02-17, 09:45authored byJe-Kyung Ryu, Céline Bouchoux, Hon Wing Liu, Eugene Kim, Masashi Minamino, Ralph de Groot, Allard J Katan, Andrea Bonato, Davide Marenduzzo, Davide Michieletto, Frank Uhlmann, Cees Dekker
Structural maintenance of chromosome (SMC) protein complexes are able to extrude DNA loops. While loop extrusion constitutes a fundamental building block of chromosomes, other factors may be equally important. Here, we show that yeast cohesin exhibits pronounced clustering on DNA, with all the hallmarks of biomolecular condensation. DNA-cohesin clusters exhibit liquid-like behavior, showing fusion of clusters, rapid fluorescence recovery after photobleaching and exchange of cohesin with the environment. Strikingly, the in vitro clustering is DNA length dependent, as cohesin forms clusters only on DNA exceeding 3 kilo-base pairs. We discuss how bridging-induced phase separation, a previously unobserved type of biological condensation, can explain the DNA-cohesin clustering through DNA-cohesin-DNA bridges. We confirm that, in yeast cells in vivo, a fraction of cohesin associates with chromatin in a manner consistent with bridging-induced phase separation. Biomolecular condensation by SMC proteins constitutes a new basic principle by which SMC complexes direct genome organization.
Funding
Crick (Grant ID: 10198, Grant title: Uhlmann FC001198)
European Research Council (Grant ID: 670412 - ChromatidCohesion, Grant title: ERC 670412 - ChromatidCohesion)