Christopher J. Viggiani scite author profile

SUMMARY The replication of eukaryotic chromosomes is organized temporally and spatially within the nucleus through epigenetic regulation of replication origin function. The characteristic initiation timing of specific origins is thought to reflect their chromatin environment or sub-nuclear positioning, however the mechanism remains obscure. Here we show that the yeast Forkhead transcription factors, Fkh1 and Fkh2, are global determinants of replication origin timing. Forkhead regulation of origin timing is independent of local levels or changes of transcription. Instead, we show that Fkh1 and Fkh2 are required for the clustering of early origins and their association with the key initiation factor Cdc45 in G1-phase, suggesting that Fkh1 and Fkh2 selectively recruit origins to emergent replication factories. Fkh1 and Fkh2 bind Fkh-activated origins, and interact physically with ORC, providing a plausible mechanism to cluster origins. These findings add a new dimension to our understanding of the epigenetic basis for differential origin regulation and its connection to chromosomal domain organization.

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Mrc1 Is Required for Normal Progression of Replication Forks throughout Chromatin in S. cerevisiae

Szyjka

2005

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Mrc1 associates with replication forks, where it transmits replication stress signals and is required for normal replisome pausing in response to nucleotide depletion. Mrc1 also plays a poorly understood role in DNA replication, which appears distinct from its role in checkpoint signaling. Here, we demonstrate that Mrc1 functions constitutively to promote normal replication fork progression. In mrc1Delta cells, replication forks proceed slowly throughout chromatin, rather than being specifically defective in pausing and progression through loci that impede fork progression. Analysis of genetic interactions with Rrm3, a DNA helicase required to resolve paused forks, indicates that Mrc1 checkpoint signaling is dispensable for the resolution of stalled replication forks and suggests that replication forks lacking Mrc1 create DNA damage that must be repaired by Rrm3. These findings elucidate a central role for Mrc1 in normal replisome function, which is distinct from its role as a checkpoint mediator, but nevertheless critical to genome stability.

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The Rpd3-Sin3 Histone Deacetylase Regulates Replication Timing and Enables Intra-S Origin Control in Saccharomyces cerevisiae

Aparicio

Viggiani

Gibson

et al. 2004

Molecular and Cellular Biology

153

161

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The replication of eukaryotic genomes follows a temporally staged program, in which late origin firing often occurs within domains of altered chromatin structure(s) and silenced genes. Histone deacetylation functions in gene silencing in some late-replicating regions, prompting an investigation of the role of histone deacetylation in replication timing control in Saccharomyces cerevisiae. Deletion of the histone deacetylase Rpd3 or its interacting partner Sin3 caused early activation of late origins at internal chromosomal loci but did not alter the initiation timing of early origins or a late-firing, telomere-proximal origin. By delaying initiation relative to the earliest origins, Rpd3 enables regulation of late origins by the intra-S replication checkpoint. RPD3 deletion suppresses the slow S phase of clb5⌬ cells by enabling late origins to fire earlier, suggesting that Rpd3 modulates the initiation timing of many origins throughout the genome. Examination of factors such as Ume6 that function together with Rpd3 in transcriptional repression indicates that Rpd3 regulates origin initiation timing independently of its role in transcriptional repression. This supports growing evidence that for much of the S. cerevisiae genome transcription and replication timing are not linked.Duplication of eukaryotic chromosomes is a temporally regulated process that involves accurate replication of DNA sequences coupled with assembly of chromatin. In general, transcriptionally active euchromatin replicates before the structurally condensed and transcriptionally silent heterochromatin. The significance of this epigenetic phenomenon remains to be determined; however, the temporal dynamics of chromosomal replication are thought to be mechanistically linked to the establishment and inheritance of gene expression programs encoded in the chromatin structure. Altered replication timing is associated not only with changes in gene expression, but also with chromosome instabilities and human cancers, suggesting that temporal staging of replication may contribute to the fidelity of genome duplication (reviewed in reference 21).DNA replication initiates at specific sites distributed along each chromosome that are termed origins of replication (reviewed in references 4 and 20). Individual origins exhibit characteristic activities defined by their timing of activation in S phase and their likelihood of activation in each S phase (origin efficiency). The activation characteristics of individual origins, their relative chromosomal locations, and normal impediments to replication fork progression determine the overall dynamics of genome replication. Recent genome-wide studies of origin locations and replication timing have revealed much about the replication dynamics and organization of the Saccharomyces cerevisiae genome (36, 54). Nevertheless, differential origin efficiency and activation timing depends upon a largely undefined relationship between chromatin structure and replication initiation mechanisms.In S. cerevisiae, origin relocation...

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Genome-wide replication profiles indicate an expansive role for Rpd3L in regulating replication initiation timing or efficiency, and reveal genomic loci of Rpd3 function in Saccharomyces cerevisiae

Knott¹,

Viggiani²,

Tavaré³

et al. 2009

Genes Dev.

118

128

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In higher eukaryotes, heritable gene silencing is associated with histone deacetylation and late replication timing. In Saccharomyces cerevisiae, the histone deacetylase Rpd3 regulates gene expression and also modulates replication timing; however, these mechanisms have been suggested to be independent, and no global association has been found between replication timing and gene expression levels. Using 5-Bromo-29-deoxyuridine (BrdU) incorporation to generate genome-wide replication profiles, we identified >100 late-firing replication origins that are regulated by Rpd3L, which is specifically targeted to promoters to silence transcription. Rpd3S, which recompacts chromatin after transcription, plays a primary role at only a handful of origins, but subtly influences initiation timing globally. The ability of these functionally distinct Rpd3 complexes to affect replication initiation timing supports the idea that histone deacetylation directly influences initiation timing. Accordingly, loss of Rpd3 function results in higher levels of histone H3 and H4 acetylation surrounding Rpd3-regulated origins, and these origins show a significant association with Rpd3 chromatin binding and gene regulation, supporting a general link between histone acetylation, replication timing, and control of gene expression in budding yeast. Our results also reveal a novel and complementary genomic map of Rpd3L-and Rpd3S-regulated chromosomal loci.[Keywords: DNA replication timing; replication origin; chromatin; histone deacetylase; 5-Bromo-29-deoxyuridine (BrdU); S-phase checkpoint; microarrays] Supplemental material is available at http://www.genesdev.org.

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Rad53 regulates replication fork restart after DNA damage in Saccharomyces cerevisiae

Szyjka¹,

Aparicio²,

Viggiani³

et al. 2008

Genes Dev.

103

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Replication fork stalling at a DNA lesion generates a damage signal that activates the Rad53 kinase, which plays a vital role in survival by stabilizing stalled replication forks. However, evidence that Rad53 directly modulates the activity of replication forks has been lacking, and the nature of fork stabilization has remained unclear. Recently, cells lacking the Psy2-Pph3 phosphatase were shown to be defective in dephosphorylation of Rad53 as well as replication fork restart after DNA damage, suggesting a mechanistic link between Rad53 deactivation and fork restart. To test this possibility we examined the progression of replication forks in methyl-methanesulfonate (MMS)-damaged cells, under different conditions of Rad53 activity. Hyperactivity of Rad53 in pph3⌬ cells slows fork progression in MMS, whereas deactivation of Rad53, through expression of dominant-negative Rad53-KD, is sufficient to allow fork restart during recovery. Furthermore, combined deletion of PPH3 and PTC2, a second, unrelated Rad53 phosphatase, results in complete replication fork arrest and lethality in MMS, demonstrating that Rad53 deactivation is a key mechanism controlling fork restart. We propose a model for regulation of replication fork progression through damaged DNA involving a cycle of Rad53 activation and deactivation that coordinates replication restart with DNA repair.[Keywords: DNA replication fork; DNA damage; DNA repair; cell cycle checkpoint; BrdU; phosphatase; microarray] Supplemental material is available at http://www.genesdev.org.

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