Interferon-stimulated gene 15 accelerates replication fork progression inducing chromosomal breakage

DNA replication is highly regulated by the ubiquitin system, which plays key roles upon stress. The ubiquitin-like modifier ISG15 (interferon-stimulated gene 15) is induced by interferons, bacterial and viral infection, and DNA damage, but it is also constitutively expressed in many types of cancer, although its role in tumorigenesis is still largely elusive. Here, we show that ISG15 localizes at the replication forks, in complex with PCNA and the nascent DNA, where it regulates DNA synthesis. Indeed, high levels of ISG15, intrinsic or induced by interferon-β, accelerate DNA replication fork progression, resulting in extensive DNA damage and chromosomal aberrations. This effect is largely independent of ISG15 conjugation and relies on ISG15 functional interaction with the DNA helicase RECQ1, which promotes restart of stalled replication forks. Additionally, elevated ISG15 levels sensitize cells to cancer chemotherapeutic treatments. We propose that ISG15 up-regulation exposes cells to replication stress, impacting genome stability and response to genotoxic drugs.

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A ruthenium polypyridyl intercalator stalls DNA replication forks, radiosensitizes human cancer cells and is enhanced by Chk1 inhibition

Scientific Reports ◽

10.1038/srep31973 ◽

2016 ◽

Vol 6 (1) ◽

Cited By ~ 22

Author(s):

Martin R. Gill ◽

Siti Norain Harun ◽

Swagata Halder ◽

Ramon A. Boghozian ◽

Kristijan Ramadan ◽

...

Keyword(s):

Cell Proliferation ◽

Dna Damage ◽

Dna Replication ◽

Cancer Cells ◽

Replication Fork ◽

Human Cancer ◽

Cell Signalling ◽

Ionising Radiation ◽

Replication Forks ◽

Replication Fork Progression

Abstract Ruthenium(II) polypyridyl complexes can intercalate DNA with high affinity and prevent cell proliferation; however, the direct impact of ruthenium-based intercalation on cellular DNA replication remains unknown. Here we show the multi-intercalator [Ru(dppz)2(PIP)]2+ (dppz = dipyridophenazine, PIP = 2-(phenyl)imidazo[4,5-f][1,10]phenanthroline) immediately stalls replication fork progression in HeLa human cervical cancer cells. In response to this replication blockade, the DNA damage response (DDR) cell signalling network is activated, with checkpoint kinase 1 (Chk1) activation indicating prolonged replication-associated DNA damage, and cell proliferation is inhibited by G1-S cell-cycle arrest. Co-incubation with a Chk1 inhibitor achieves synergistic apoptosis in cancer cells, with a significant increase in phospho(Ser139) histone H2AX (γ-H2AX) levels and foci indicating increased conversion of stalled replication forks to double-strand breaks (DSBs). Normal human epithelial cells remain unaffected by this concurrent treatment. Furthermore, pre-treatment of HeLa cells with [Ru(dppz)2(PIP)]2+ before external beam ionising radiation results in a supra-additive decrease in cell survival accompanied by increased γ-H2AX expression, indicating the compound functions as a radiosensitizer. Together, these results indicate ruthenium-based intercalation can block replication fork progression and demonstrate how these DNA-binding agents may be combined with DDR inhibitors or ionising radiation to achieve more efficient cancer cell killing.

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Set1-dependent H3K4 methylation becomes critical for DNA replication fork progression in response to changes in S phase dynamics in Saccharomyces cerevisiae

10.1101/2020.10.26.355008 ◽

2020 ◽

Author(s):

Christophe de La Roche Saint-André ◽

Vincent Géli

Keyword(s):

Saccharomyces Cerevisiae ◽

Dna Damage ◽

Dna Replication ◽

Replication Fork ◽

Genetic Material ◽

S Phase ◽

Replication Forks ◽

H3k4 Methylation ◽

Origin Firing ◽

Phase Dynamics

AbstractDNA replication is a highly regulated process that occurs in the context of chromatin structure and is sensitive to several histone post-translational modifications. In Saccharomyces cerevisiae, the histone methylase Set1 is responsible for the transcription-dependent deposition of H3K4 methylation (H3K4me) throughout the genome. Here we show that a combination of a hypomorphic replication mutation (orc5-1) with the absence of Set1 (set1Δ) compromises the progression through S phase, and this is associated with a large increase in DNA damage. The ensuing DNA damage checkpoint activation, in addition to that of the spindle assembly checkpoint, restricts the growth of orc5-1 set1Δ. Interestingly, orc5-1 set1Δ is sensitive to the lack of RNase H activity while a reduction of histone levels is able to counterbalance the loss of Set1. We propose that the recently described Set1-dependent mitigation of transcription-replication conflicts becomes critical for growth when the replication forks accelerate due to decreased origin firing in the orc5-1 background. Furthermore, we show that an increase of reactive oxygen species (ROS) levels, likely a consequence of the elevated DNA damage, is partly responsible for the lethality in orc5-1 set1Δ.Author summaryDNA replication, that ensures the duplication of the genetic material, starts at discrete sites, termed origins, before proceeding at replication forks whose progression is carefully controlled in order to avoid conflicts with the transcription of genes. In eukaryotes, DNA replication occurs in the context of chromatin, a structure in which DNA is wrapped around proteins, called histones, that are subjected to various chemical modifications. Among them, the methylation of the lysine 4 of histone H3 (H3K4) is carried out by Set1 in Saccharomyces cerevisiae, specifically at transcribed genes. We report that, when the replication fork accelerates in response to a reduction of active origins, the absence of Set1 leads to accumulation of DNA damage. Because H3K4 methylation was recently shown to slow down replication at transcribed genes, we propose that the Set1-dependent becomes crucial to limit the occurrence of conflicts between replication and transcription caused by replication fork acceleration. In agreement with this model, stabilization of transcription-dependent structures or reduction histone levels, to limit replication fork velocity, respectively exacerbates or moderates the effect of Set1 loss. Last, but not least, we show that the oxidative stress associated to DNA damage is partly responsible for cell lethality.

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Single-molecule imaging reveals control of parental histone recycling by free histones during DNA replication

Science Advances ◽

10.1126/sciadv.abc0330 ◽

2020 ◽

Vol 6 (38) ◽

pp. eabc0330 ◽

Cited By ~ 1

Author(s):

D. T. Gruszka ◽

S. Xie ◽

H. Kimura ◽

H. Yardimci

Keyword(s):

Dna Replication ◽

Real Time ◽

Single Molecule ◽

Replication Fork ◽

Epigenetic Inheritance ◽

Replication Forks ◽

Replication Fork Progression ◽

Egg Extracts ◽

Fork Stalling ◽

The Moment

During replication, nucleosomes are disrupted ahead of the replication fork, followed by their reassembly on daughter strands from the pool of recycled parental and new histones. However, because no previous studies have managed to capture the moment that replication forks encounter nucleosomes, the mechanism of recycling has remained unclear. Here, through real-time single-molecule visualization of replication fork progression in Xenopus egg extracts, we determine explicitly the outcome of fork collisions with nucleosomes. Most of the parental histones are evicted from the DNA, with histone recycling, nucleosome sliding, and replication fork stalling also occurring but at lower frequencies. Critically, we find that local histone recycling becomes dominant upon depletion of endogenous histones from extracts, revealing that free histone concentration is a key modulator of parental histone dynamics at the replication fork. The mechanistic details revealed by these studies have major implications for our understanding of epigenetic inheritance.

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Microcephalin 1/BRIT1-TRF2 interaction promotes telomere replication and repair, linking telomere dysfunction to primary microcephaly

Nature Communications ◽

10.1038/s41467-020-19674-0 ◽

2020 ◽

Vol 11 (1) ◽

Author(s):

Alessandro Cicconi ◽

Rekha Rai ◽

Xuexue Xiong ◽

Cayla Broton ◽

Amer Al-Hiyasat ◽

...

Keyword(s):

Dna Damage ◽

Replication Fork ◽

Clinical Feature ◽

Replication Forks ◽

Primary Microcephaly ◽

Dna Damage And Repair ◽

Homology Directed Repair ◽

Replication Fork Progression ◽

Telomere Binding Protein ◽

Telomere Replication

AbstractTelomeres protect chromosome ends from inappropriately activating the DNA damage and repair responses. Primary microcephaly is a key clinical feature of several human telomere disorder syndromes, but how microcephaly is linked to dysfunctional telomeres is not known. Here, we show that the microcephalin 1/BRCT-repeats inhibitor of hTERT (MCPH1/BRIT1) protein, mutated in primary microcephaly, specifically interacts with the TRFH domain of the telomere binding protein TRF2. The crystal structure of the MCPH1–TRF2 complex reveals that this interaction is mediated by the MCPH1 330YRLSP334 motif. TRF2-dependent recruitment of MCPH1 promotes localization of DNA damage factors and homology directed repair of dysfunctional telomeres lacking POT1-TPP1. Additionally, MCPH1 is involved in the replication stress response, promoting telomere replication fork progression and restart of stalled telomere replication forks. Our work uncovers a previously unrecognized role for MCPH1 in promoting telomere replication, providing evidence that telomere replication defects may contribute to the onset of microcephaly.

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The Main Role of Srs2 in DNA Repair Depends on Its Helicase Activity, Rather than on Its Interactions with PCNA or Rad51

mBio ◽

10.1128/mbio.01192-18 ◽

2018 ◽

Vol 9 (4) ◽

Cited By ~ 5

Author(s):

Alex Bronstein ◽

Lihi Gershon ◽

Gilad Grinberg ◽

Elisa Alonso-Perez ◽

Martin Kupiec

Keyword(s):

Dna Damage ◽

Dna Replication ◽

Genome Stability ◽

Dna Helicase ◽

Main Role ◽

Helicase Domain ◽

Helicase Activity ◽

C Terminus ◽

Srs2 Helicase

ABSTRACTHomologous recombination (HR) is a mechanism that repairs a variety of DNA lesions. Under certain circumstances, however, HR can generate intermediates that can interfere with other cellular processes such as DNA transcription or replication. Cells have therefore developed pathways that abolish undesirable HR intermediates. TheSaccharomyces cerevisiaeyeast Srs2 helicase has a major role in one of these pathways. Srs2 also works during DNA replication and interacts with the clamp PCNA. The relative importance of Srs2’s helicase activity, Rad51 removal function, and PCNA interaction in genome stability remains unclear. We created a newSRS2allele [srs2(1-850)] that lacks the whole C terminus, containing the interaction site for Rad51 and PCNA and interactions with many other proteins. Thus, the new allele encodes an Srs2 protein bearing only the activity of the DNA helicase. We find that the interactions of Srs2 with Rad51 and PCNA are dispensable for the main role of Srs2 in the repair of DNA damage in vegetative cells and for proper completion of meiosis. On the other hand, it has been shown that in cells impaired for the DNA damage tolerance (DDT) pathways, Srs2 generates toxic intermediates that lead to DNA damage sensitivity; we show that this negative Srs2 activity requires the C terminus of Srs2. Dissection of the genetic interactions of thesrs2(1-850) allele suggest a role for Srs2’s helicase activity in sister chromatid cohesion. Our results also indicate that Srs2’s function becomes more central in diploid cells.IMPORTANCEHomologous recombination (HR) is a key mechanism that repairs damaged DNA. However, this process has to be tightly regulated; failure to regulate it can lead to genome instability. The Srs2 helicase is considered a regulator of HR; it was shown to be able to evict the recombinase Rad51 from DNA. Cells lacking Srs2 exhibit sensitivity to DNA-damaging agents, and in some cases, they display defects in DNA replication. The relative roles of the helicase and Rad51 removal activities of Srs2 in genome stability remain unclear. To address this question, we created a new Srs2 mutant which has only the DNA helicase domain. Our study shows that only the DNA helicase domain is needed to deal with DNA damage and assist in DNA replication during vegetative growth and in meiosis. Thus, our findings shift the view on the role of Srs2 in the maintenance of genome integrity.

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Mms1 and Mms22 stabilize the replisome during replication stress

Molecular Biology of the Cell ◽

10.1091/mbc.e10-10-0848 ◽

2011 ◽

Vol 22 (13) ◽

pp. 2396-2408 ◽

Cited By ~ 13

Author(s):

Jessica A. Vaisica ◽

Anastasija Baryshnikova ◽

Michael Costanzo ◽

Charles Boone ◽

Grant W. Brown

Keyword(s):

Dna Replication ◽

Ubiquitin Ligase ◽

Replication Fork ◽

E3 Ubiquitin Ligase ◽

Replication Stress ◽

Replication Forks ◽

Replication Fork Progression ◽

Binding Partners ◽

Efficient Recovery ◽

Stalled Replication Forks

Mms1 and Mms22 form a Cul4Ddb1-like E3 ubiquitin ligase with the cullin Rtt101. In this complex, Rtt101 is bound to the substrate-specific adaptor Mms22 through a linker protein, Mms1. Although the Rtt101Mms1/Mms22ubiquitin ligase is important in promoting replication through damaged templates, how it does so has yet to be determined. Here we show that mms1Δ and mms22Δ cells fail to properly regulate DNA replication fork progression when replication stress is present and are defective in recovery from replication fork stress. Consistent with a role in promoting DNA replication, we find that Mms1 is enriched at sites where replication forks have stalled and that this localization requires the known binding partners of Mms1—Rtt101 and Mms22. Mms1 and Mms22 stabilize the replisome during replication stress, as binding of the fork-pausing complex components Mrc1 and Csm3, and DNA polymerase ε, at stalled replication forks is decreased in mms1Δ and mms22Δ. Taken together, these data indicate that Mms1 and Mms22 are important for maintaining the integrity of the replisome when DNA replication forks are slowed by hydroxyurea and thereby promote efficient recovery from replication stress.

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The Human Tim/Tipin Complex Coordinates an Intra-S Checkpoint Response to UV That Slows Replication Fork Displacement

Molecular and Cellular Biology ◽

10.1128/mcb.02190-06 ◽

2007 ◽

Vol 27 (8) ◽

pp. 3131-3142 ◽

Cited By ~ 151

Author(s):

Keziban Ünsal-Kaçmaz ◽

Paul D. Chastain ◽

Ping-Ping Qu ◽

Parviz Minoo ◽

Marila Cordeiro-Stone ◽

...

Keyword(s):

Dna Replication ◽

Replication Fork ◽

Protein A ◽

Chain Elongation ◽

Replication Forks ◽

Interacting Protein ◽

Checkpoint Response ◽

Replication Fork Progression ◽

Dna Chain ◽

Interfering Rna

ABSTRACT UV-induced DNA damage stalls DNA replication forks and activates the intra-S checkpoint to inhibit replicon initiation. In response to stalled replication forks, ATR phosphorylates and activates the transducer kinase Chk1 through interactions with the mediator proteins TopBP1, Claspin, and Timeless (Tim). Murine Tim recently was shown to form a complex with Tim-interacting protein (Tipin), and a similar complex was shown to exist in human cells. Knockdown of Tipin using small interfering RNA reduced the expression of Tim and reversed the intra-S checkpoint response to UVC. Tipin interacted with replication protein A (RPA) and RPA-coated DNA, and RPA promoted the loading of Tipin onto RPA-free DNA. Immunofluorescence analysis of spread DNA fibers showed that treating HeLa cells with 2.5 J/m2 UVC not only inhibited the initiation of new replicons but also reduced the rate of chain elongation at active replication forks. The depletion of Tim and Tipin reversed the UV-induced inhibition of replicon initiation but affected the rate of DNA synthesis at replication forks in different ways. In undamaged cells depleted of Tim, the apparent rate of replication fork progression was 52% of the control. In contrast, Tipin depletion had little or no effect on fork progression in unirradiated cells but significantly attenuated the UV-induced inhibition of DNA chain elongation. Together, these findings indicate that the Tim-Tipin complex mediates the UV-induced intra-S checkpoint, Tim is needed to maintain DNA replication fork movement in the absence of damage, Tipin interacts with RPA on DNA and, in UV-damaged cells, Tipin slows DNA chain elongation in active replicons.

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ATR-like kinase Mec1 facilitates both chromatin accessibility at DNA replication forks and replication fork progression during replication stress

Genes & Development ◽

10.1101/gad.202978.112 ◽

2013 ◽

Vol 27 (1) ◽

pp. 74-86 ◽

Cited By ~ 16

Author(s):

J. Rodriguez ◽

T. Tsukiyama

Keyword(s):

Dna Replication ◽

Replication Fork ◽

Replication Stress ◽

Chromatin Accessibility ◽

Replication Forks ◽

Replication Fork Progression

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Chromatin remodeler Fft3 plays a dual role at blocked DNA replication forks

Life Science Alliance ◽

10.26508/lsa.201900433 ◽

2019 ◽

Vol 2 (5) ◽

pp. e201900433 ◽

Cited By ~ 2

Author(s):

Anissia Ait-Saada ◽

Olga Khorosjutina ◽

Jiang Chen ◽

Karol Kramarz ◽

Vladimir Maksimov ◽

...

Keyword(s):

Dna Damage ◽

Dna Replication ◽

Fission Yeast ◽

Chromatin Remodeling ◽

Replication Fork ◽

Strand Break ◽

Replication Forks ◽

Damage Repair ◽

Single Strand Annealing ◽

Strand Annealing

Here, we investigate the function of fission yeast Fun30/Smarcad1 family of SNF2 ATPase-dependent chromatin remodeling enzymes in DNA damage repair. There are three Fun30 homologues in fission yeast, Fft1, Fft2, and Fft3. We find that only Fft3 has a function in DNA repair and it is needed for single-strand annealing of an induced double-strand break. Furthermore, we use an inducible replication fork barrier system to show that Fft3 has two distinct roles at blocked DNA replication forks. First, Fft3 is needed for the resection of nascent strands, and second, it is required to restart the blocked forks. The latter function is independent of its ATPase activity.

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Replication Fork Slowing and Stalling are Distinct, Checkpoint-Independent Consequences of Replicating Damaged DNA

10.1101/122895 ◽

2017 ◽

Author(s):

Divya Ramalingam Iyer ◽

Nicholas Rhind

Keyword(s):

Dna Damage ◽

Dna Replication ◽

Fission Yeast ◽

Single Molecule ◽

Replication Fork ◽

Replication Forks ◽

Origin Firing ◽

Dna Combing ◽

Fork Stalling

AbstractIn response to DNA damage during S phase, cells slow DNA replication. This slowing is orchestrated by the intra-S checkpoint and involves inhibition of origin firing and reduction of replication fork speed. Slowing of replication allows for tolerance of DNA damage and suppresses genomic instability. Although the mechanisms of origin inhibition by the intra-S checkpoint are understood, major questions remain about how the checkpoint regulates replication forks: Does the checkpoint regulate the rate of fork progression? Does the checkpoint affect all forks, or only those encountering damage? Does the checkpoint facilitate the replication of polymerase-blocking lesions? To address these questions, we have analyzed the checkpoint in the fission yeast Schizosaccharomyces pombe using a single-molecule DNA combing assay, which allows us to unambiguously separate the contribution of origin and fork regulation towards replication slowing, and allows us to investigate the behavior of individual forks. Moreover, we have interrogated the role of forks interacting with individual sites of damage by using three damaging agents—MMS, 4NQO and bleomycin—that cause similar levels of replication slowing with very different frequency of DNA lesions. We find that the checkpoint slows replication by inhibiting origin firing, but not by decreasing fork rates. However, the checkpoint appears to facilitate replication of damaged templates, allowing forks to more quickly pass lesions. Finally, using a novel analytic approach, we rigorously identify fork stalling events in our combing data and show that they play a previously unappreciated role in shaping replication kinetics in response to DNA damage.Author SummaryFaithful duplication of the genome is essential for genetic stability of organisms and species. To ensure faithful duplication, cells must be able to replicate damaged DNA. To do so, they employ checkpoints that regulate replication in response to DNA damage. However, the mechanisms by which checkpoints regulate DNA replication forks, the macromolecular machines that contain the helicases and polymerases required to unwind and copy the parental DNA, is unknown. We have used DNA combing, a single-molecule technique that allows us to monitor the progression of individual replication forks, to characterize the response of fission yeast replication forks to DNA damage that blocks the replicative polymerases. We find that forks pass most lesions with only a brief pause and that this lesion bypass is checkpoint independent. However, at a low frequency, forks stall at lesions, and that the checkpoint is required to prevent these stalls from accumulating single-stranded DNA. Our results suggest that the major role of the checkpoint is not to regulate the interaction of replication forks with DNA damage, per se, but to mitigate the consequences of fork stalling when forks are unable to successfully navigate DNA damage on their own.

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