2006
DOI: 10.1038/ncb1206-1313
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DNA replication timing: random thoughts about origin firing

Abstract: Regions of metazoan genomes replicate at defined times within S phase. This observation suggests that replication origins fire with a defined timing pattern that remains the same from cycle to cycle. However, an alterative model based on the stochastic firing of origins may also explain replication timing. This model assumes varying origin efficiency instead of a strict origin-timing programme. Here, we discuss the evidence for both models.Models for the organization of eukaryotic DNA replication have to accou… Show more

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Cited by 124 publications
(151 citation statements)
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“…Additionally, the firing propensity of each origin along the genome has been determined based on the experimentally defined observed efficiencies in the presence of the drug hydroxyurea, which inhibits fork progression, thereby eliminating passive replication (24). In fission yeast, only a small number of origins genome-wide appear intrinsically late and do not fire during a long hydroxyurea block (24,27), while for the vast majority of origins, the timing of firing appears correlated to their firing propensities (24), suggesting that stochastic determination of firing times is the prevailing mechanism in the fission yeast (18). Fission yeast offers therefore a good opportunity to capture full genome replication based on experimental data coupled to an understanding of the underlining biology.…”
Section: Resultsmentioning
confidence: 99%
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“…Additionally, the firing propensity of each origin along the genome has been determined based on the experimentally defined observed efficiencies in the presence of the drug hydroxyurea, which inhibits fork progression, thereby eliminating passive replication (24). In fission yeast, only a small number of origins genome-wide appear intrinsically late and do not fire during a long hydroxyurea block (24,27), while for the vast majority of origins, the timing of firing appears correlated to their firing propensities (24), suggesting that stochastic determination of firing times is the prevailing mechanism in the fission yeast (18). Fission yeast offers therefore a good opportunity to capture full genome replication based on experimental data coupled to an understanding of the underlining biology.…”
Section: Resultsmentioning
confidence: 99%
“…The model was modified to accommodate a specific biological hypothesis for the reason behind the probabilistic nature of the firing of origins: the presence of a limiting initiation factor, which is released following origin firing and binds again to origins still at the prereplicative state (18). Since the number of origins in the prereplicative state decreases as S-phase progresses, the probability of the limiting factor binding to a particular prereplicative origin (and therefore the firing probability of this origin) increases along S-phase (18). The firing propensity redistribution model was developed to code this hypothesis, assuming that the pool of available factor remains roughly constant during S-phase.…”
Section: Discussionmentioning
confidence: 99%
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