Mechanisms of MCM2-7 helicase activation and initial DNA melting at near base-pair resolution
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ABSTRACT: During eukaryotic DNA replication initiation, inactive MCM2-7 double-hexamers assembled at replication origins must be converted into two active CMG helicases, yet how this transition is coupled to origin DNA unwinding in vivo remains unclear. Here, we identify a DNA-bound intermediate with an extended genomic footprint that forms during helicase activation. Genome-wide mapping of initial strand separation reveals that DNA unwinding initiates near the N-terminal interface of opposing MCM2-7 hexamers. At these sites, the origin DNA exhibits a conserved AT-rich/GC-rich/AT-rich sequence architecture centred under the helicase complex, which is associated with an elevated DNA melting probability. We further show that restricting hexamer splitting delays release of the Cdc45-loading factor Sld3, demonstrating that mechanical transitions during helicase activation are tightly coupled to complex disassembly. Finally, we provide in vivo evidence that single-stranded DNA is ejected through a specialised DNA exit gate at the Mcm2/5 interface during helicase activation, which is dispensable for ongoing DNA synthesis. Together, these findings establish a mechanistic framework for how replication origins are remodelled to initiate DNA replication and reveal key intermediates and DNA transactions during helicase activation.
INSTRUMENT(S):
ORGANISM(S): Saccharomyces Cerevisiae (baker's Yeast)
SUBMITTER:
Alex Montoya
LAB HEAD: Professor Christian Speck
PROVIDER: PXD080178 | Pride | 2026-06-26
REPOSITORIES: Pride
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