1. DNA Entry into and Exit out of the Cohesin Ring by an Interlocking Gate Mechanism
- Author
-
Frank Uhlmann and Yasuto Murayama
- Subjects
Chromosomal Proteins, Non-Histone ,Protein subunit ,Saccharomyces cerevisiae ,Cell Cycle Proteins ,Biology ,Article ,General Biochemistry, Genetics and Molecular Biology ,03 medical and health sciences ,chemistry.chemical_compound ,Adenosine Triphosphate ,0302 clinical medicine ,ATP hydrolysis ,Schizosaccharomyces ,Escherichia coli ,Humans ,030304 developmental biology ,0303 health sciences ,Cohesin ,Biochemistry, Genetics and Molecular Biology(all) ,DNA transport ,Hydrolysis ,DNA ,biology.organism_classification ,Molecular biology ,6. Clean water ,Cell biology ,Establishment of sister chromatid cohesion ,chemistry ,biological phenomena, cell phenomena, and immunity ,Adenosine triphosphate ,030217 neurology & neurosurgery - Abstract
Summary Structural maintenance of chromosome (SMC) complexes are proteinaceous rings that embrace DNA to enable vital chromosomal functions. The ring is formed by two SMC subunits, closed at a pair of ATPase heads, whose interaction is reinforced by a kleisin subunit. Using biochemical analysis of fission-yeast cohesin, we find that a similar series of events facilitates both topological entrapment and release of DNA. DNA-sensing lysines trigger ATP hydrolysis to open the SMC head interface, whereas the Wapl subunit disengages kleisin, but only after ATP rebinds. This suggests an interlocking gate mechanism for DNA transport both into and out of the cohesin ring. The entry direction is facilitated by a cohesin loader that appears to fold cohesin to expose the DNA sensor. Our results provide a model for dynamic DNA binding by all members of the SMC family and explain how lysine acetylation of cohesin establishes enduring sister chromatid cohesion., Graphical Abstract, Highlights • Biochemical reconstitution of DNA entry into and exit out of the cohesin ring • DNA-sensing lysines on the Psm3/Smc3 subunit’s ATPase trigger main ring opening • The Wapl subunit disengages an interlocking kleisin subunit “outer gate” • A unified model for DNA entry and exit with implications for all SMC complexes, The biochemical reconstitution of the topological entrapment and release of DNA by the fission-yeast cohesin complex indicates that DNA sensing by lysine residues triggers entry into and exit from nested gates comprised of the cohesin complex proteins in a manner that can be regulated by acetylation.
- Published
- 2015