ID3 regulates the MDC1-mediated DNA damage response in order to maintain genome stability

Cellular function is highly dependent on genomic stability, which is mainly ensured by two cellular mechanisms: the DNA damage response (DDR) and the Spindle Assembly Checkpoint (SAC). The former provides the repair of damaged DNA, and the latter ensures correct chromosome segregation. This review focuses on recently emerging data indicating that the SAC and the DDR proteins function together throughout the cell cycle, suggesting crosstalk between both checkpoints to maintain genome stability.

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Identification of S-phase DNA damage-response targets in fission yeast reveals conservation of damage-response networks

Proceedings of the National Academy of Sciences ◽

10.1073/pnas.1525620113 ◽

2016 ◽

Vol 113 (26) ◽

pp. E3676-E3685 ◽

Cited By ~ 8

Author(s):

Nicholas A. Willis ◽

Chunshui Zhou ◽

Andrew E. H. Elia ◽

Johanne M. Murray ◽

Antony M. Carr ◽

...

Keyword(s):

Gene Expression ◽

Dna Damage ◽

Dna Replication ◽

Fission Yeast ◽

Dna Damage Response ◽

Cellular Response ◽

Genome Stability ◽

Biological Significance ◽

S Phase ◽

Damage Response

The cellular response to DNA damage during S-phase regulates a complicated network of processes, including cell-cycle progression, gene expression, DNA replication kinetics, and DNA repair. In fission yeast, this S-phase DNA damage response (DDR) is coordinated by two protein kinases: Rad3, the ortholog of mammalian ATR, and Cds1, the ortholog of mammalian Chk2. Although several critical downstream targets of Rad3 and Cds1 have been identified, most of their presumed targets are unknown, including the targets responsible for regulating replication kinetics and coordinating replication and repair. To characterize targets of the S-phase DDR, we identified proteins phosphorylated in response to methyl methanesulfonate (MMS)-induced S-phase DNA damage in wild-type, rad3∆, and cds1∆ cells by proteome-wide mass spectrometry. We found a broad range of S-phase–specific DDR targets involved in gene expression, stress response, regulation of mitosis and cytokinesis, and DNA replication and repair. These targets are highly enriched for proteins required for viability in response to MMS, indicating their biological significance. Furthermore, the regulation of these proteins is similar in fission and budding yeast, across 300 My of evolution, demonstrating a deep conservation of S-phase DDR targets and suggesting that these targets may be critical for maintaining genome stability in response to S-phase DNA damage across eukaryotes.

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PML Colocalizes with and Stabilizes the DNA Damage Response Protein TopBP1

Molecular and Cellular Biology ◽

10.1128/mcb.23.12.4247-4256.2003 ◽

2003 ◽

Vol 23 (12) ◽

pp. 4247-4256 ◽

Cited By ~ 74

Author(s):

Zhi-Xiang Xu ◽

Anna Timanova-Atanasova ◽

Rui-Xun Zhao ◽

Kun-Sang Chang

Keyword(s):

Dna Damage ◽

Dna Damage Response ◽

Genome Stability ◽

Growth Regulation ◽

Suppressor Gene ◽

Nuclear Body ◽

Promyelocytic Leukemia ◽

Multifunctional Protein ◽

Damage Response

ABSTRACT The PML tumor suppressor gene is consistently disrupted by t(15;17) in patients with acute promyelocytic leukemia. Promyelocytic leukemia protein (PML) is a multifunctional protein that plays essential roles in cell growth regulation, apoptosis, transcriptional regulation, and genome stability. Our study here shows that PML colocalizes and associates in vivo with the DNA damage response protein TopBP1 in response to ionizing radiation (IR). Both PML and TopBP1 colocalized with the IR-induced bromodeoxyuridine single-stranded DNA foci. PML and TopBP1 also colocalized with Rad50, Brca1, ATM, Rad9, and BLM. IR and interferon (IFN) coinduce the expression levels of both TopBP1 and PML. In PML-deficient NB4 cells, TopBP1 was unable to form IR-induced foci. All-trans-retinoic acid induced reorganization of the PML nuclear body (NB) and reappearance of the IR-induced TopBP1 foci. Inhibition of PML expression by siRNA is associated with a significant decreased in TopBP1 expression. Furthermore, PML-deficient cells express a low level of TopBP1, and its expression cannot be induced by IR or IFN. Adenovirus-mediated overexpression of PML in PML−/− mouse embryo fibroblasts substantially increased TopBP1 expression, which colocalized with the PML NBs. These studies demonstrated a mechanism of PML-dependent expression of TopBP1. PML overexpression induced TopBP1 protein but not the mRNA expression. Pulse-chase labeling analysis demonstrated that PML overexpression stabilized the TopBP1 protein, suggesting that PML plays a role in regulating the stability of TopBP1 in response to IR. Together, our findings demonstrate that PML regulates TopBP1 functions by association and stabilization of the protein in response to IR-induced DNA damage.

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Multifunctional Role of ATM/Tel1 Kinase in Genome Stability: From the DNA Damage Response to Telomere Maintenance

BioMed Research International ◽

10.1155/2014/787404 ◽

2014 ◽

Vol 2014 ◽

pp. 1-17 ◽

Cited By ~ 16

Author(s):

Enea Gino Di Domenico ◽

Elena Romano ◽

Paola Del Porto ◽

Fiorentina Ascenzioni

Keyword(s):

Dna Damage ◽

Dna Damage Response ◽

Ataxia Telangiectasia ◽

Genome Stability ◽

Genetic Disorder ◽

Cell Cycle Control ◽

Premature Aging ◽

Telomere Maintenance ◽

Damage Response

The mammalian protein kinase ataxia telangiectasia mutated (ATM) is a key regulator of the DNA double-strand-break response and belongs to the evolutionary conserved phosphatidylinositol-3-kinase-related protein kinases. ATM deficiency causes ataxia telangiectasia (AT), a genetic disorder that is characterized by premature aging, cerebellar neuropathy, immunodeficiency, and predisposition to cancer. AT cells show defects in the DNA damage-response pathway, cell-cycle control, and telomere maintenance and length regulation. Likewise, inSaccharomyces cerevisiae, haploid strains defective in theTEL1gene, the ATM ortholog, show chromosomal aberrations and short telomeres. In this review, we outline the complex role of ATM/Tel1 in maintaining genomic stability through its control of numerous aspects of cellular survival. In particular, we describe how ATM/Tel1 participates in the signal transduction pathways elicited by DNA damage and in telomere homeostasis and its importance as a barrier to cancer development.

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POGZ modulates the DNA damage response in a HP1-dependent manner

10.1101/2021.06.28.447216 ◽

2021 ◽

Author(s):

John Heath ◽

Estelle Simo Cheyou ◽

Steven Findlay ◽

Vincent Luo ◽

Edgar Pinedo Carpio ◽

...

Keyword(s):

Dna Damage ◽

Dna Repair ◽

Dna Damage Response ◽

Genome Stability ◽

Dependent Manner ◽

Dna Double Strand Breaks ◽

Humoral Immune ◽

Damage Response

The heterochromatin protein HP1 plays a central role in the maintenance of genome stability, in particular by promoting homologous recombination (HR)-mediated DNA repair. However, little is still known about how HP1 is controlled during this process. Here, we describe a novel function of the POGO transposable element derived with ZNF domain protein (POGZ) in the regulation of HP1 during the DNA damage response in vitro. POGZ depletion delays the resolution of DNA double-strand breaks (DSBs) and correlates with an increased sensitivity to different DNA damaging agents, including the clinically-relevant Cisplatin and Talazoparib. Mechanistically, POGZ promotes homology-directed DNA repair pathways by retaining the BRCA1/BARD1 complex at DSBs, in a HP1-dependent manner. In vivo CRISPR inactivation of Pogz is embryonic lethal and Pogz haplo-insufficiency (Pogz+/Δ) results in a developmental delay, a deficit in intellectual abilities, a hyperactive behaviour as well as a compromised humoral immune response in mice, recapitulating the main clinical features of the White Sutton syndrome (WHSUS). Importantly, Pogz+/Δ mice are radiosensitive and accumulate DSBs in diverse tissues, including the spleen and the brain. Altogether, our findings identify POGZ as an important player in homology-directed DNA repair both in vitro and in vivo, with clinical implications for the WHSUS.

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POT1a depletion in the developing brain leads to p53-dependent neuronal cell death and ataxia

10.1101/335059 ◽

2018 ◽

Author(s):

Robert She ◽

Charlie Clapp ◽

Eros Lazzerini Denchi

Keyword(s):

Dna Damage ◽

Dna Damage Response ◽

Genome Stability ◽

Neuronal Cell Death ◽

Neuronal Cell ◽

Neuronal Progenitor ◽

Damage Response ◽

The Central Nervous System ◽

P53 Inactivation ◽

Dna Damage Response Pathway

AbstractThe processes that control genome stability are essential for the development of the Central Nervous System (CNS) and the prevention of neurological disease. Here we investigated whether activation of a DNA damage response by dysfunctional telomeres affects neurogenesis. More specifically, we analyzed ATR-dependent DNA damage response by depletion of POT1a in neural progenitors. These experiments revealed that POT1a inactivation leads to a partially penetrant lethality, and surviving mice displayed ataxia due to loss of neuronal progenitor cells, and died by 3 weeks of age. Inactivation of p53 was sufficient to completely suppress the lethality associated with POT1a depletion and rescued the neuronal defects characterizing POT1a depleted animals. In contrast, activation of ATM by the depletion of the shelterin protein TRF2 resulted in a fully penetrant lethality that could not be rescued by p53 inactivation (Lobanova et al.). This data reveals that activation of distinct types of DNA damage response pathway give rise to different types of neuropathology. Moreover, our data provides an explanation for the heterogeneity of the neurological defects observed in patients affected by telomere biological disorders.

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DNA damage response proteins regulating mitotic cell division: double agents preserving genome stability

FEBS Journal ◽

10.1111/febs.15240 ◽

2020 ◽

Vol 287 (9) ◽

pp. 1700-1721 ◽

Cited By ~ 5

Author(s):

Eleni Petsalaki ◽

George Zachos

Keyword(s):

Dna Damage ◽

Cell Division ◽

Dna Damage Response ◽

Genome Stability ◽

Mitotic Cell ◽

Mitotic Cell Division ◽

Damage Response

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Interplay between DNA replication stress, chromatin dynamics and DNA-damage response for the maintenance of genome stability

Mutation Research/Reviews in Mutation Research ◽

10.1016/j.mrrev.2020.108346 ◽

2021 ◽

Vol 787 ◽

pp. 108346

Author(s):

Maddalena Mognato ◽

Susanne Burdak-Rothkamm ◽

Kai Rothkamm

Keyword(s):

Dna Damage ◽

Dna Replication ◽

Dna Damage Response ◽

Genome Stability ◽

Replication Stress ◽

Chromatin Dynamics ◽

Damage Response ◽

Dna Replication Stress

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The Roles of SPOP in DNA Damage Response and DNA Replication

International Journal of Molecular Sciences ◽

10.3390/ijms21197293 ◽

2020 ◽

Vol 21 (19) ◽

pp. 7293

Author(s):

Masashi Maekawa ◽

Shigeki Higashiyama

Keyword(s):

Dna Damage ◽

Dna Replication ◽

Dna Damage Response ◽

Genome Stability ◽

Substrate Binding ◽

Critical Role ◽

Tumor Formation ◽

Missense Mutations ◽

Cellular Functions ◽

Damage Response

Speckle-type BTB/POZ protein (SPOP) is a substrate recognition receptor of the cullin-3 (CUL3)/RING type ubiquitin E3 complex. To date, approximately 30 proteins have been identified as ubiquitinated substrates of the CUL3/SPOP complex. Pathologically, missense mutations in the substrate-binding domain of SPOP have been found in prostate and endometrial cancers. Prostate and endometrial cancer-associated SPOP mutations lose and increase substrate-binding ability, respectively. Expression of these SPOP mutants, thus, causes aberrant turnovers of the substrate proteins, leading to tumor formation. Although the molecular properties of SPOP and its cancer-associated mutants have been intensively elucidated, their cellular functions remain unclear. Recently, a number of studies have uncovered the critical role of SPOP and its mutants in DNA damage response and DNA replication. In this review article, we summarize the physiological functions of SPOP as a “gatekeeper” of genome stability.

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