A Checkpoint-Related Function of the MCM Replicative Helicase Is Required to Avert Accumulation of RNA:DNA Hybrids during S-phase and Ensuing DSBs during G2/M

Vijayraghavan, Sriram; Tsai, Feng-Ling; Schwacha, Anthony

doi:10.1371/journal.pgen.1006277

Cited by 31 publications

(35 citation statements)

References 87 publications

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“…We propose that transcription of the (GAA) 10 repeat generates an R-loop (Fig 7). During replication, the approaching replicative helicase traverses the transcription complex by displacing the RNA polymerase (Pomerantz & O'Donnell, 2010) or by reorganising the helicase itself Vijayraghavan et al, 2016). Biophysical calculations show that DNA:RNA hybrids are sufficiently thermodynamically stable to survive the accumulation of positive supercoiling generated ahead of the replicative helicase (Belotserkovskii et al, 2013).…”

Section: Discussionmentioning

confidence: 99%

R‐loop formation during S phase is restricted by PrimPol‐mediated repriming

Šviković

Crisp

Tan-Wong³

et al. 2018

The EMBO Journal

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During DNA replication, conflicts with ongoing transcription are frequent and require careful management to avoid genetic instability. R‐loops, three‐stranded nucleic acid structures comprising a DNA:RNA hybrid and displaced single‐stranded DNA, are important drivers of damage arising from such conflicts. How R‐loops stall replication and the mechanisms that restrain their formation during S phase are incompletely understood. Here, we show in vivo how R‐loop formation drives a short purine‐rich repeat, (GAA)10, to become a replication impediment that engages the repriming activity of the primase‐polymerase PrimPol. Further, the absence of PrimPol leads to significantly increased R‐loop formation around this repeat during S phase. We extend this observation by showing that PrimPol suppresses R‐loop formation in genes harbouring secondary structure‐forming sequences, exemplified by G quadruplex and H‐DNA motifs, across the genome in both avian and human cells. Thus, R‐loops promote the creation of replication blocks at susceptible structure‐forming sequences, while PrimPol‐dependent repriming limits the extent of unscheduled R‐loop formation at these sequences, mitigating their impact on replication.

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Section: Discussionmentioning

confidence: 99%

R‐loop formation during S phase is restricted by PrimPol‐mediated repriming

Šviković

Crisp

Tan-Wong³

et al. 2018

The EMBO Journal

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“…R-loop-accumulating yeast mutants activate the S-phase checkpoint (Gómez-González et al 2009) and head-on T-R conflicts induce ATR checkpoint activation in human cells (Hamperl et al 2017). Furthermore, R-loop-accumulating mutants require a functional S-phase checkpoint to survive (Gómez-González et al 2009), and an MCM-specific mutant impairing its checkpoint activation function was found to lead to R-loop-driven T-R conflicts (Vijayraghavan et al 2016). These results suggest that the replication checkpoint protects against the harmful effect of T-R collisions.…”

Section: Repriming or Arrestmentioning

confidence: 99%

Transcription-mediated replication hindrance: a major driver of genome instability

2019

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Genome replication involves dealing with obstacles that can result from DNA damage but also from chromatin alterations, topological stress, tightly bound proteins or non-B DNA structures such as R loops. Experimental evidence reveals that an engaged transcription machinery at the DNA can either enhance such obstacles or be an obstacle itself. Thus, transcription can become a potentially hazardous process promoting localized replication fork hindrance and stress, which would ultimately cause genome instability, a hallmark of cancer cells. Understanding the causes behind transcription–replication conflicts as well as how the cell resolves them to sustain genome integrity is the aim of this review.

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“…DNA–RNA hybrids have been shown to be a replication obstacle (Wellinger et al , ; Gan et al , ; Madireddy et al , ). In the last years, it has been reported that DNA replication‐associated activities, such as those of topoisomerases, MCM2‐7 replicative helicase, and Fanconi anemia proteins, are necessary to prevent transcription–replication conflicts and R‐loop accumulation (Tuduri et al , ; Garcia‐Rubio et al , ; Schwab et al , ; Madireddy et al , ; Vijayraghavan et al , ). Since R‐loops may constitute a major source of replication stress and genome instability (Garcia‐Muse & Aguilera, ), a hallmark of tumor cells (Halazonetis et al , ), deciphering how cells prevent R‐loop accumulation is crucial to understand the origin of genome instability.…”

Section: Introductionmentioning

confidence: 99%

Human THO –Sin3A interaction reveals new mechanisms to prevent R‐loops that cause genome instability

et al. 2017

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R-loops, formed by co-transcriptional DNA-RNA hybrids and a displaced DNA single strand (ssDNA), fulfill certain positive regulatory roles but are also a source of genomic instability. One key cellular mechanism to prevent R-loop accumulation centers on the conserved THO/TREX complex, an RNA-binding factor involved in transcription elongation and RNA export that contributes to messenger ribonucleoprotein (mRNP) assembly, but whose precise function is still unclear. To understand how THO restrains harmful R-loops, we searched for new THO-interacting factors. We found that human THO interacts with the Sin3A histone deacetylase complex to suppress co-transcriptional R-loops, DNA damage, and replication impairment. Functional analyses show that histone hypo-acetylation prevents accumulation of harmful R-loops and RNA-mediated genomic instability. Diminished histone deacetylase activity in THO- and Sin3A-depleted cell lines correlates with increased R-loop formation, genomic instability, and replication fork stalling. Our study thus uncovers physical and functional crosstalk between RNA-binding factors and chromatin modifiers with a major role in preventing R-loop formation and RNA-mediated genome instability.

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A Checkpoint-Related Function of the MCM Replicative Helicase Is Required to Avert Accumulation of RNA:DNA Hybrids during S-phase and Ensuing DSBs during G2/M

Cited by 31 publications

References 87 publications

R‐loop formation during S phase is restricted by PrimPol‐mediated repriming

R‐loop formation during S phase is restricted by PrimPol‐mediated repriming

Transcription-mediated replication hindrance: a major driver of genome instability

Human THO –Sin3A interaction reveals new mechanisms to prevent R‐loops that cause genome instability

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