DNA catenation is essential for Sister Chromatid Cohesion
DNA catenation is essential for Sister Chromatid Cohesion
Kaushik, A.; Fraile, A. A.; Viera, V.; Martin, A. M.; Maduro, A. H.; Collier, J.; Sakata, T.; Fukute, J.; Shirahige, K.; Jeppsson, K.; Oliveira, R. A.; Roca, J.; Srinivasan, M.
AbstractFrom S phase until anaphase, sister chromatids remain physically linked to ensure accurate chromosome segregation. This linkage, called sister chromatid cohesion, must withstand the pulling forces generated by the mitotic spindle and is thought to require entrapment of sister DNAs inside the ring-shaped cohesin complex. DNA catenations that arise naturally during replication could also tether sister chromatids, but whether they contribute to cohesion has remained unresolved. Here, using budding yeast, we show that cohesin-mediated sister DNA entrapment alone cannot withstand spindle-generated pulling forces and that robust sister chromatid cohesion requires DNA catenation. Selective removal of DNA catenations causes catastrophic cohesion loss, delays chromosome biorientation and increases chromosome mis-segregation, even when cohesin rings remain intact. Importantly, DNA catenation similarly underpins force-resistant cohesion in metazoan chromosomes. Our findings fundamentally redefine the physical basis of sister chromatid cohesion by establishing DNA catenation as an evolutionarily conserved component of the force-resistant linkage between sister chromatids that enables accurate chromosome segregation.