Chromosomal Mcm2-7 distribution is the primary driver of the genome replication program in species from yeast to humans

Foss, Eric J.; Sripathy, Smitha; Gatbonton-Schwager, Tonbelle; Kwak, Hyunchang; Thiesen, Adam H.; Lao, Uyen; Bedalov, Antonio

doi:10.1101/737742

Cited by 6 publications

(10 citation statements)

References 66 publications

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“…Our combination of MCM ChIP-seq and replication timing data also allow us to directly confirm in a single experiment previous conclusions, drawn from comparing data collected in different studies, that replication timing correlates with levels of MCM loading (Das et al, 2015;Foss et al, 2020). Although the correlation between MCM levels and replication timing is robust (Figure 4c, p > 10 -5 ), it is clearly not the only determining factor (r = 0.29-0.52).…”

Section: Discussionsupporting

confidence: 78%

“…Alternatively, in a multiple-MCM scenario, more than one MCM double-hexamer complex can be loaded at a single origin, so MCM occupancy can range from 0 to many. Both single-and multiple-MCM scenarios have been proposed (Das et al, 2015;Foss et al, 2020;de Moura et al, 2010;Das and Rhind, 2016;Yang et al, 2010).…”

Section: Discussionmentioning

confidence: 99%

“…Although excess loading of MCM is important for a successful S phase in response to replication stress, it has also been implicated in contributing to the replication timing program under optimal conditions. Genome-wide ChIP experiments in budding yeast have shown that MCM is loaded at origins in different amounts, and that the level of MCM loading correlates with the time in S phases at which an origin fires (Das et al, 2015;Foss et al, 2020). In addition, mutation of the B2 element in ARS1, which that has been shown to be important for MCM loading at that origin, causes reduced MCM loading and a delay in replication timing (Zou and Stillman, 2000;Das et al, 2015).…”

Section: Introductionmentioning

confidence: 99%

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Competition for MCM Loading at Origins Establishes Replication Timing Patterns

Dukaj

Rhind

2020

Preprint

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Loading of the MCM replicative helicase onto origins of replication is a highly regulated process that precedes DNA replication in all eukaryotes. The number of MCM loaded on origins has been proposed to be a key determinant of when those origins initiate replication during S phase. Nevertheless, the genome-wide characteristics of MCM loading and their direct effect on replication timing remain unclear. In order to probe MCM loading dynamics and its effect on replication timing, we perturbed MCM levels in budding yeast cells and, for the first time, directly measured MCM levels and replication timing in the same experiment. Reduction of MCM levels through degradation of Mcm4, one of the six obligate components of the MCM complex, slowed progression through S phase and increased sensitivity to replication stress. Reduction of MCM levels also led to differential loading at origins during G1, revealing origins that are sensitive to reductions in MCM and others that are not. Sensitive origins loaded less MCM under normal conditions and correlated with a weak ability to recruit the origin recognition complex (ORC). Moreover, reduction of MCM loading at specific origins of replication led to a delay in their initiation during S phase. In contrast, overexpression of MCM had no effects on cell cycle progression, relative MCM levels at origins, or replication timing, suggesting that, under optimal growth conditions, cellular MCM levels not limiting for MCM loading. Our results support a model in which the loading activity of origins, controlled by their ability to recruit ORC and compete for MCM, determines the number of helicases loaded, which in turn affects replication timing.

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Section: Discussionsupporting

confidence: 78%

Section: Discussionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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Competition for MCM Loading at Origins Establishes Replication Timing Patterns

Dukaj

Rhind

2020

Preprint

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“…This data points to a model where the more MCMs that are available for activation at an origin in S phase, the higher the likelihood that the specific origin will initiate early. Indeed, this MCM-stoichiometry model fits well with kinetic modeling of replication, which predicts that stochastic firing arising from differences in the availability of MCM in the presence of limiting initiation factors can give rise to the observed replication kinetics seen in budding yeast cells [ 21 , 22 , 26 ]. It is important to note that the MCM-stoichiometry models are equally valid whether MCM stoichiometry varies from 0 to 1 or 0 to many.…”

Section: Discussionmentioning

confidence: 58%

“…Although excess loading of MCM is important for a successful S phase under conditions of replication stress, it has also been implicated in contributing to the replication timing program under normal conditions. Genome-wide MCM mapping experiments in budding yeast have shown that MCM is loaded at origins in different amounts, and that the level of MCM loading correlates with the time in S phases at which an origin fires [ 20 , 21 ]. In addition, mutation of the B2 element in ARS1, which has been shown to be important for MCM loading at that origin, causes reduced MCM loading and a delay in replication timing [ 20 , 54 ].…”

Section: Discussionmentioning

confidence: 99%

The capacity of origins to load MCM establishes replication timing patterns

Dukaj

Rhind

2021

PLoS Genet

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Loading of the MCM replicative helicase at origins of replication is a highly regulated process that precedes DNA replication in all eukaryotes. The stoichiometry of MCM loaded at origins has been proposed to be a key determinant of when those origins initiate replication during S phase. Nevertheless, the genome-wide regulation of MCM loading stoichiometry and its direct effect on replication timing remain unclear. In order to investigate why some origins load more MCM than others, we perturbed MCM levels in budding yeast cells and, for the first time, directly measured MCM levels and replication timing in the same experiment. Reduction of MCM levels through degradation of Mcm4, one of the six obligate components of the MCM complex, slowed progression through S phase and increased sensitivity to replication stress. Reduction of MCM levels also led to differential loading at origins during G1, revealing origins that are sensitive to reductions in MCM and others that are not. Sensitive origins loaded less MCM under normal conditions and correlated with a weak ability to recruit the origin recognition complex (ORC). Moreover, reduction of MCM loading at specific origins of replication led to a delay in their replication during S phase. In contrast, overexpression of MCM had no effects on cell cycle progression, relative MCM levels at origins, or replication timing, suggesting that, under optimal growth conditions, cellular MCM levels are not limiting for MCM loading. Our results support a model in which the loading capacity of origins is the primary determinant of MCM stoichiometry in wild-type cells, but that stoichiometry is controlled by origins’ ability to recruit ORC and compete for MCM when MCM becomes limiting.

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Transcription as source of genetic heterogeneity in budding yeast

Piguet,

Houseley

2024

Yeast

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Transcription presents challenges to genome stability both directly, by altering genome topology and exposing single‐stranded DNA to chemical insults and nucleases, and indirectly by introducing obstacles to the DNA replication machinery. Such obstacles include the RNA polymerase holoenzyme itself, DNA‐bound regulatory factors, G‐quadruplexes and RNA‐DNA hybrid structures known as R‐loops. Here, we review the detrimental impacts of transcription on genome stability in budding yeast, as well as the mitigating effects of transcription‐coupled nucleotide excision repair and of systems that maintain DNA replication fork processivity and integrity. Interactions between DNA replication and transcription have particular potential to induce mutation and structural variation, but we conclude that such interactions must have only minor effects on DNA replication by the replisome with little if any direct mutagenic outcome. However, transcription can significantly impair the fidelity of replication fork rescue mechanisms, particularly Break Induced Replication, which is used to restart collapsed replication forks when other means fail. This leads to de novo mutations, structural variation and extrachromosomal circular DNA formation that contribute to genetic heterogeneity, but only under particular conditions and in particular genetic contexts, ensuring that the bulk of the genome remains extremely stable despite the seemingly frequent interactions between transcription and DNA replication.

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Chromosomal Mcm2-7 distribution is the primary driver of the genome replication program in species from yeast to humans

Cited by 6 publications

References 66 publications

Competition for MCM Loading at Origins Establishes Replication Timing Patterns

Competition for MCM Loading at Origins Establishes Replication Timing Patterns

The capacity of origins to load MCM establishes replication timing patterns

Transcription as source of genetic heterogeneity in budding yeast

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