Abstract
DNA unwinding in eukaryotic replication is performed by the Cdc45–MCM–GINS (CMG) helicase. Although the CMG architecture has been elucidated, its mechanism of DNA unwinding and replisome interactions remain poorly understood. Here we report the cryoEM structure at 3.3 Å of human CMG bound to fork DNA and the ATP-analogue ATPγS. Eleven nucleotides of single-stranded (ss) DNA are bound within the C-tier of MCM2–7 AAA+ ATPase domains. All MCM subunits contact DNA, from MCM2 at the 5′-end to MCM5 at the 3′-end of the DNA spiral, but only MCM6, 4, 7 and 3 make a full set of interactions. DNA binding correlates with nucleotide occupancy: five MCM subunits are bound to either ATPγS or ADP, whereas the apo MCM2-5 interface remains open. We further report the cryoEM structure of human CMG bound to the replisome hub AND-1 (CMGA). The AND-1 trimer uses one β-propeller domain of its trimerisation region to dock onto the side of the helicase assembly formed by Cdc45 and GINS. In the resulting CMGA architecture, the AND-1 trimer is closely positioned to the fork DNA while its CIP (Ctf4-interacting peptide)-binding helical domains remain available to recruit partner proteins.
Highlights
DNA unwinding in eukaryotic replication is performed by the Cdc45-MCM-GINS (CMG) helicase
After co-expression of MCM2-7, Cdc45 and GINS, human CMG was purified by Ni2+- and Streptactin-affinity chromatography (Supplementary figure 1A)
We have used cryoEM to capture a high-resolution view of the human CMG bound to a fork DNA substrate in the presence of ATPgS
Summary
DNA unwinding in eukaryotic replication is performed by the Cdc45-MCM-GINS (CMG) helicase. Processive strand separation results from the allosteric coupling of ATP hydrolysis to concerted movements of the DNA-binding elements that line the ring pore in each subunit, as first shown for the replicative viral E1 DNA helicase (Enemark & Joshua-Tor, 2006) and the hexameric Rho RNA helicase (Thomsen & Berger, 2009). Based on structural analysis of bacteriophage, viral and bacterial systems (Enemark & Joshua-Tor, 2006; Gao et al, 2019; Itsathitphaisarn, Wing, Eliason, Wang, & Steitz, 2012; Singleton, Sawaya, Ellenberger, & Wigley, 2000) a consensus has emerged for a sequential rotary mechanism of DNA unwinding by replicative DNA helicases In this mechanism, ATP is sequentially hydrolysed by successive ring subunits so that each ring position cycles through ATP, ADP and apo states. The sequential hydrolysis of ATP around the ring causes the coordinated motion of the DNA-binding loops, resulting in translocation of the DNA substrate through the ring
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