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Paradoxes of eukaryotic DNA replication: MCM proteins and the random completion problem
Bioessays 25 (2):116-125 (2003)
Abstract
Eukaryotic DNA replication initiates at multiple origins. In early fly and frog embryos, chromosomal replication is very rapid and initiates without sequence specificity. Despite this apparent randomness, the spacing of these numerous initiation sites must be sufficiently regular for the genome to be completely replicated on time. Studies in various eukaryotes have revealed that there is a strict temporal separation of origin “licensing” prior to S phase and origin activation during S phase. This may suggest that replicon size must be already established at the licensing stage. However, recent experiments suggest that a large excess of potential origins are assembled along chromatin during licensing. Thus, a regular replicon size may result from the selection of origins during S phase. We review single molecule analyses of origin activation and other experiments addressing this issue and their general significance for eukaryotic DNA replication. BioEssays 25:116–125, 2003. © 2003 Wiley Periodicals, Inc.Other Versions
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Citations of this work
How and why multiple MCMs are loaded at origins of DNA replication.Shankar P. Das & Nicholas Rhind - 2016 - Bioessays 38 (7):613-617.
The dynamic replicon: adapting to a changing cellular environment.John Herrick - 2010 - Bioessays 32 (2):153-164.
DNA replication timing: Biochemical mechanisms and biological significance.Nicholas Rhind - 2022 - Bioessays 44 (11):2200097.
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