DNA Replication Origins Fire Stochastically in Fission Yeast

Patel, P. K.; Arcangioli, Benoı̂t; Baker, Stephen P.; Bensimon, Aaron; Rhind, Nick

doi:10.1091/mbc.e05-07-0657

Cited by 178 publications

(245 citation statements)

References 59 publications

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“…In the 'time-course experiment', DNA samples were taken every 5-10 min until S-phase was complete. In the 'HU experiment', HU was added to slow down replication fork progression and confine DNA synthesis to the vicinity of origins (Patel et al, 2006). DNA samples were taken from cells that had been blocked for 90 min in HU, which is around 30 min after the onset of S-phase when bulk DNA replication was almost completed in a cdc25-22 block/release experiment ( Figure 1A, right panel).…”

Section: Resultsmentioning

confidence: 99%

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Genome-wide characterization of fission yeast DNA replication origins

Heichinger

Penkett

Bähler

et al. 2006

EMBO J

197

358

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Eukaryotic DNA replication is initiated from multiple origins of replication, but little is known about the global regulation of origins throughout the genome or in different types of cell cycles. Here, we identify 401 strong origins and 503 putative weaker origins spaced in total every 14 kb throughout the genome of the fission yeast Schizosaccharomyces pombe. The same origins are used during premeiotic and mitotic S-phases. We found that few origins fire late in mitotic S-phase and that activating the Rad3 dependent S-phase checkpoint by inhibiting DNA replication had little effect on which origins were fired. A genome-wide analysis of eukaryotic origin efficiencies showed that efficiency was variable, with large chromosomal domains enriched for efficient or inefficient origins. Average efficiency is twice as high during mitosis compared with meiosis, which can account for their different S-phase lengths. We conclude that there is a continuum of origin efficiency and that there is differential origin activity in the mitotic and meiotic cell cycles.

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Section: Resultsmentioning

confidence: 99%

“…An example of the timecourse experiment for a 300 kb region is given in Figure 2A. The HU experiment allowed origins to be mapped more precisely because fork migration away from the origin was reduced (Patel et al, 2006). A moving average across three microarray probes was applied (B3.9 kb) and signal ratios were plotted along the chromosomes.…”

Section: Resultsmentioning

confidence: 99%

Genome-wide characterization of fission yeast DNA replication origins

Heichinger

Penkett

Bähler

et al. 2006

EMBO J

197

358

View full text Add to dashboard Cite

show abstract

“…To avoid the random gap problem, it has been argued that there must be some mechanism to coordinate origin firing so as to avoid large random gaps 22 . Surprisingly, in two cases in which the distribution of origin firing has been carefully examined -frog embryo extracts and fission yeast -the distribution was in fact random and large random gaps were observed 8,9,23,24 .…”

Section: Introductionmentioning

confidence: 99%

“…The fact that budding yeast more closely fits the replicon model has made it much easier to understand replication in budding yeast, and has supported application of the replicon paradigm to eukaryotes in general. However, the observation that budding yeast's strategy of well-spaced, efficient origins is not conserved in its distant cousin, fission yeast, let alone in metazoans, suggests that it does not serve as a general model for the global regulation of eukaryotic origins 8,13,14 . Thus, budding yeast seems to be the exception, rather than the rule, in the organization of eukaryotic replication.…”

mentioning

confidence: 99%

DNA replication timing: random thoughts about origin firing

2006

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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 account for two diametrically opposed conceptions of replication. On one side of the spectrum is the replicon paradigm, exemplified by the mechanism of bacterial replication, in which origins are welldefined sites that fire once in each cell cycle, leading to uniform replication that is identical in every cell 1 . At the opposite end of the spectrum is the mechanism of replication in frog and fly embryos, in which replication initiates asynchronously throughout S phase at indiscriminate sites, presumably leading to a different, random pattern of replication in each cell 2,3 . It is clear that neither of these extreme mechanisms reflect the reality of replication in most eukaryotic somatic cells, but it is also clear that both models contain a kernel of truth. So how do we reconcile these apparently competing views of replication? Recent work suggests a way to bridge the gap and to reconcile stochastic origin firing with defined patterns of genome replication.It is useful to first establish which parts of each model generally apply to eukaryotic replication. The replicon paradigm, which serves as the foundation for most textbook models of eukaryotic replication, describes eukaryotic replication reasonably well, with two major exceptions: first, most eukaryotes do not seem to have well-defined, sequence-specific origins4 , 5. Consequently, it has been difficult to identify metazoan replication origins, and in the few cases in which they have been identified, they seem to have no particular sequence specificity. However, too few metazoan origins have been defined to exclude the possibility of origin specific sequences. The question of what constitutes a eukaryotic replication origin remains an active field of research, and as knowledge of the exact location of origins is not necessary for the ideas presented here, we will not pursue it further. Second, eukaryotic origins are inefficient and fire in only a subset of S phases 6 -only a fraction of the origins established in G1 are fired in S phase and it is a different set in each cell. In fission yeast, most origins fire about 30% of the time, whereas in mammals, the well-studied dihydrofolate reductase (DHFR) origins fire approximately 20% of the time 7, 8.In terms of these two exceptions to the replicon paradigm, eukaryotic replication looks more like the example of frog and fly embryos. Frog embryos go to the extreme of establishing origins randomly across the genome, without regard to DNA sequence 2,9 . This is not the case for eukaryotes in general, whi...

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“…But even in this system, analysis of DNA from single cells shows that initiation can be intrinsically disordered in time (Czajkowsky et al 2008), implying that origin selection has a significant stochastic component (Patel et al 2006). In mammalian cells, origin selection is also known to be highly stochastic (see Maya-Mendoza et al 2009 for review).…”

Section: S-phase Progressionmentioning

confidence: 99%

Spatio-Temporal Organization of Replication in Bacteria and Eukaryotes (Nucleoids and Nuclei)

Jackson

Wang²,

Rudner³

2012

Cold Spring Harbor Perspectives in Biology

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Here we discuss the spatio-temporal organization of replication in eubacteria and eukaryotes. Although there are significant differences in how replication is organized in cells that contain nuclei from those that do not, you will see that organization of replication in all organisms is principally dictated by the structured arrangement of the chromosome. We will begin with how replication is organized in eubacteria with particular emphasis on three well studied model organisms. We will then discuss spatial and temporal organization of replication in eukaryotes highlighting the similarities and differences between these two domains of life.

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DNA Replication Origins Fire Stochastically in Fission Yeast

Cited by 178 publications

References 59 publications

Genome-wide characterization of fission yeast DNA replication origins

Genome-wide characterization of fission yeast DNA replication origins

DNA replication timing: random thoughts about origin firing

Spatio-Temporal Organization of Replication in Bacteria and Eukaryotes (Nucleoids and Nuclei)

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