Jack of all trades? The versatility of RNA in DNA double-strand break repair

Abstract The mechanisms by which RNA acts in the DNA damage response (DDR), specifically in the repair of DNA double-strand breaks (DSBs), are emerging as multifaceted and complex. Different RNA species, including but not limited to; microRNA (miRNA), long non-coding RNA (lncRNA), RNA:DNA hybrid structures, the recently identified damage-induced lncRNA (dilncRNA), damage-responsive transcripts (DARTs), and DNA damage-dependent small RNAs (DDRNAs), have been shown to play integral roles in the DSB response. The diverse properties of these RNAs, such as sequence, structure, and binding partners, enable them to fulfil a variety of functions in different cellular contexts. Additionally, RNA can be modified post-transcriptionally, a process which is regulated in response to cellular stressors such as DNA damage. Many of these mechanisms are not yet understood and the literature contradictory, reflecting the complexity and expansive nature of the roles of RNA in the DDR. However, it is clear that RNA is pivotal in ensuring the maintenance of genome integrity. In this review, we will discuss and summarise recent evidence which highlights the roles of these various RNAs in preserving genomic integrity, with a particular focus on the emerging role of RNA in the DSB repair response.

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Repair Kinetics of Genomic Interstrand DNA Cross-Links: Evidence for DNA Double-Strand Break-Dependent Activation of the Fanconi Anemia/BRCA Pathway

Molecular and Cellular Biology ◽

10.1128/mcb.24.1.123-134.2004 ◽

2004 ◽

Vol 24 (1) ◽

pp. 123-134 ◽

Cited By ~ 170

Author(s):

Andreas Rothfuss ◽

Markus Grompe

Keyword(s):

Fanconi Anemia ◽

Strand Break ◽

S Phase ◽

Dna Double Strand Breaks ◽

Subsequent Formation ◽

Strand Breaks ◽

Dna Double Strand Break ◽

Cross Links ◽

Kinetics Of

ABSTRACT The detailed mechanisms of DNA interstrand cross-link (ICL) repair and the involvement of the Fanconi anemia (FA)/BRCA pathway in this process are not known. Present models suggest that recognition and repair of ICL in human cells occur primarily during the S phase. Here we provide evidence for a refined model in which ICLs are recognized and are rapidly incised by ERCC1/XPF independent of DNA replication. However, the incised ICLs are then processed further and DNA double-strand breaks (DSB) form exclusively in the S phase. FA cells are fully proficient in the sensing and incision of ICL as well as in the subsequent formation of DSB, suggesting a role of the FA/BRCA pathway downstream in ICL repair. In fact, activation of FANCD2 occurs slowly after ICL treatment and correlates with the appearance of DSB in the S phase. In contrast, activation is rapid after ionizing radiation, indicating that the FA/BRCA pathway is specifically activated upon DSB formation. Furthermore, the formation of FANCD2 foci is restricted to a subpopulation of cells, which can be labeled by bromodeoxyuridine incorporation. We therefore conclude that the FA/BRCA pathway, while being dispensable for the early events in ICL repair, is activated in S-phase cells after DSB have formed.

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The ubiquitin landscape at DNA double-strand breaks

The Journal of Cell Biology ◽

10.1083/jcb.200908074 ◽

2009 ◽

Vol 187 (3) ◽

pp. 319-326 ◽

Cited By ~ 90

Author(s):

Troy E. Messick ◽

Roger A. Greenberg

Keyword(s):

Dna Damage ◽

Cancer Susceptibility ◽

Strand Break ◽

Dna Double Strand Breaks ◽

Dsb Repair ◽

Checkpoint Signaling ◽

Strand Breaks ◽

Parallel Processes ◽

Dna Double Strand Break ◽

Cellular Dna

The intimate relationship between DNA double-strand break (DSB) repair and cancer susceptibility has sparked profound interest in how transactions on DNA and chromatin surrounding DNA damage influence genome integrity. Recent evidence implicates a substantial commitment of the cellular DNA damage response machinery to the synthesis, recognition, and hydrolysis of ubiquitin chains at DNA damage sites. In this review, we propose that, in order to accommodate parallel processes involved in DSB repair and checkpoint signaling, DSB-associated ubiquitin structures must be nonuniform, using different linkages for distinct functional outputs. We highlight recent advances in the study of nondegradative ubiquitin signaling at DSBs, and discuss how recognition of different ubiquitin structures may influence DNA damage responses.

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HP1β Chromo Shadow Domain facilitates H2A ubiquitination for BRCA1 recruitment at DNA double-strand breaks

10.1101/2022.01.11.475809 ◽

2022 ◽

Author(s):

Tej Pandita ◽

Vijay Kumari Charaka ◽

Sharmistha Chakraborty ◽

Chi-Lin Tsai ◽

Xiaoyan Wang ◽

...

Keyword(s):

Dna Damage ◽

Genome Stability ◽

Strand Break ◽

Dna Double Strand Breaks ◽

Dsb Repair ◽

Strand Breaks ◽

Damage Repair ◽

Dna Double Strand Break ◽

Assembly Factor ◽

Chromo Shadow Domain

Efficient DNA double strand break (DSB) repair by homologous recombination (HR), as orchestrated by histone and non-histone proteins, is critical to genome stability, replication, transcription, and cancer avoidance. Here we report that Heterochromatin Protein1 beta (HP1β) acts as a key component of the HR DNA resection step by regulating BRCA1 enrichment at DNA damage sites, a function largely dependent on the HP1β chromo shadow domain (CSD). HP1β itself is enriched at DSBs within gene-rich regions through a CSD interaction with Chromatin Assembly Factor 1 (CAF1) and HP1β depletion impairs subsequent BRCA1 enrichment. An added interaction of the HP1β CSD with the Polycomb Repressor Complex 1 ubiquitinase component RING1A facilitates BRCA1 recruitment by increasing H2A lysine 118-119 ubiquitination, a marker for BRCA1 recruitment. Our findings reveal that HP1β interactions, mediated through its CSD with RING1A, promote H2A ubiquitination and facilitate BRCA1 recruitment at DNA damage sites, a critical step in DSB repair by the HR pathway. These collective results unveil how HP1β is recruited to DSBs in gene-rich regions and how HP1β subsequently promotes BRCA1 recruitment to further HR DNA damage repair by stimulating CtIP-dependent resection.

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SETD2 is required for DNA double-strand break repair and activation of the p53-mediated checkpoint

eLife ◽

10.7554/elife.02482 ◽

2014 ◽

Vol 3 ◽

Cited By ~ 121

Author(s):

Sílvia Carvalho ◽

Alexandra C Vítor ◽

Sreerama C Sridhara ◽

Filipa B Martins ◽

Ana C Raposo ◽

...

Keyword(s):

Dna Damage ◽

Strand Break ◽

Dna Lesions ◽

Alternative Mechanism ◽

Dna Double Strand Breaks ◽

Cell Renal Cell Carcinoma ◽

Strand Breaks ◽

Dna Damage Signaling ◽

Dna Double Strand Break ◽

Recombination Repair

Histone modifications establish the chromatin states that coordinate the DNA damage response. In this study, we show that SETD2, the enzyme that trimethylates histone H3 lysine 36 (H3K36me3), is required for ATM activation upon DNA double-strand breaks (DSBs). Moreover, we find that SETD2 is necessary for homologous recombination repair of DSBs by promoting the formation of RAD51 presynaptic filaments. In agreement, SETD2-mutant clear cell renal cell carcinoma (ccRCC) cells displayed impaired DNA damage signaling. However, despite the persistence of DNA lesions, SETD2-deficient cells failed to activate p53, a master guardian of the genome rarely mutated in ccRCC and showed decreased cell survival after DNA damage. We propose that this novel SETD2-dependent role provides a chromatin bookmarking instrument that facilitates signaling and repair of DSBs. In ccRCC, loss of SETD2 may afford an alternative mechanism for the inactivation of the p53-mediated checkpoint without the need for additional genetic mutations in TP53.

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Positive regulation of meiotic DNA double-strand break formation by activation of the DNA damage checkpoint kinase Mec1(ATR)

Open Biology ◽

10.1098/rsob.130019 ◽

2013 ◽

Vol 3 (7) ◽

pp. 130019 ◽

Cited By ~ 46

Author(s):

Stephen Gray ◽

Rachal M. Allison ◽

Valerie Garcia ◽

Alastair S. H. Goldman ◽

Matthew J. Neale

Keyword(s):

Dna Damage ◽

Chromosome Segregation ◽

Meiotic Chromosome ◽

Strand Break ◽

Genetic Exchange ◽

Dna Double Strand Breaks ◽

Strand Breaks ◽

Complex Process ◽

Dna Double Strand Break ◽

Dna Damage Signalling

During meiosis, formation and repair of programmed DNA double-strand breaks (DSBs) create genetic exchange between homologous chromosomes—a process that is critical for reductional meiotic chromosome segregation and the production of genetically diverse sexually reproducing populations. Meiotic DSB formation is a complex process, requiring numerous proteins, of which Spo11 is the evolutionarily conserved catalytic subunit. Precisely how Spo11 and its accessory proteins function or are regulated is unclear. Here, we use Saccharomyces cerevisiae to reveal that meiotic DSB formation is modulated by the Mec1(ATR) branch of the DNA damage signalling cascade, promoting DSB formation when Spo11-mediated catalysis is compromised. Activation of the positive feedback pathway correlates with the formation of single-stranded DNA (ssDNA) recombination intermediates and activation of the downstream kinase, Mek1. We show that the requirement for checkpoint activation can be rescued by prolonging meiotic prophase by deleting the NDT80 transcription factor, and that even transient prophase arrest caused by Ndt80 depletion is sufficient to restore meiotic spore viability in checkpoint mutants. Our observations are unexpected given recent reports that the complementary kinase pathway Tel1(ATM) acts to inhibit DSB formation. We propose that such antagonistic regulation of DSB formation by Mec1 and Tel1 creates a regulatory mechanism, where the absolute frequency of DSBs is maintained at a level optimal for genetic exchange and efficient chromosome segregation.

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Kinesin Kif2C in regulation of DNA double strand break dynamics and repair

eLife ◽

10.7554/elife.53402 ◽

2020 ◽

Vol 9 ◽

Cited By ~ 3

Author(s):

Songli Zhu ◽

Mohammadjavad Paydar ◽

Feifei Wang ◽

Yanqiu Li ◽

Ling Wang ◽

...

Keyword(s):

Dna Damage ◽

Mammalian Cells ◽

Strand Break ◽

Dna Double Strand Breaks ◽

Dsb Repair ◽

Strand Breaks ◽

Dna Double Strand Break ◽

Egg Extracts ◽

Xenopus Egg ◽

Xenopus Egg Extracts

DNA double strand breaks (DSBs) have detrimental effects on cell survival and genomic stability, and are related to cancer and other human diseases. In this study, we identified microtubule-depolymerizing kinesin Kif2C as a protein associated with DSB-mimicking DNA templates and known DSB repair proteins in Xenopus egg extracts and mammalian cells. The recruitment of Kif2C to DNA damage sites was dependent on both PARP and ATM activities. Kif2C knockdown or knockout led to accumulation of endogenous DNA damage, DNA damage hypersensitivity, and reduced DSB repair via both NHEJ and HR. Interestingly, Kif2C depletion, or inhibition of its microtubule depolymerase activity, reduced the mobility of DSBs, impaired the formation of DNA damage foci, and decreased the occurrence of foci fusion and resolution. Taken together, our study established Kif2C as a new player of the DNA damage response, and presented a new mechanism that governs DSB dynamics and repair.

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Poly(ADP-ribosyl)ation temporally confines SUMO-dependent ataxin-3 recruitment to control DNA double-strand break repair

Journal of Cell Science ◽

10.1242/jcs.247809 ◽

2021 ◽

pp. jcs.247809

Author(s):

Annika Pfeiffer ◽

Laura K. Herzog ◽

Martijn S. Luijsterburg ◽

Rashmi G. Shah ◽

Magdalena B. Rother ◽

...

Keyword(s):

Dna Damage ◽

Dna Repair ◽

Time Window ◽

Strand Break ◽

Dna Double Strand Breaks ◽

Strand Breaks ◽

Dna Double Strand Break ◽

Dna Repair Proteins ◽

Short Time Window ◽

Short Time

DNA damage-induced SUMOylation serves as a signal for two antagonizing proteins that both stimulate repair of DNA double strand breaks (DSBs). Here, we demonstrate that the SUMO-dependent recruitment of the deubiquitylating enzyme ataxin-3 to DSBs, unlike recruitment of the ubiquitin ligase RNF4, additionally depends on PARP1-mediated poly(ADP-ribosyl)ation (PARylation). The co-dependence of ataxin-3 recruitment on PARylation and SUMOylation temporally confines its presence at DSBs to a short time window directly following detection of the DNA damage. We propose that this mechanism ensures that ataxin-3 prevents the premature removal of DNA repair proteins only during the early phase of the DSB response and does not interfere with the subsequent timely displacement of DNA repair proteins by RNF4. Thus, our data show that PARylation differentially regulates SUMO-dependent recruitment of ataxin-3 and RNF4 to DSBs, explaining how both proteins can play a stimulatory role at DSBs despite their opposing activities.

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Physiological Roles of DNA Double-Strand Breaks

Journal of Nucleic Acids ◽

10.1155/2017/6439169 ◽

2017 ◽

Vol 2017 ◽

pp. 1-20 ◽

Cited By ~ 7

Author(s):

Farhaan A. Khan ◽

Syed O. Ali

Keyword(s):

Double Helix ◽

Strand Break ◽

Double Strand Breaks ◽

Genomic Integrity ◽

Dna Double Strand Breaks ◽

Dna Breaks ◽

Strand Breaks ◽

Spatiotemporal Regulation ◽

Dna Double Strand Break

Genomic integrity is constantly threatened by sources of DNA damage, internal and external alike. Among the most cytotoxic lesions is the DNA double-strand break (DSB) which arises from the cleavage of both strands of the double helix. Cells boast a considerable set of defences to both prevent and repair these breaks and drugs which derail these processes represent an important category of anticancer therapeutics. And yet, bizarrely, cells deploy this very machinery for the intentional and calculated disruption of genomic integrity, harnessing potentially destructive DSBs in delicate genetic transactions. Under tight spatiotemporal regulation, DSBs serve as a tool for genetic modification, widely used across cellular biology to generate diverse functionalities, ranging from the fundamental upkeep of DNA replication, transcription, and the chromatin landscape to the diversification of immunity and the germline. Growing evidence points to a role of aberrant DSB physiology in human disease and an understanding of these processes may both inform the design of new therapeutic strategies and reduce off-target effects of existing drugs. Here, we review the wide-ranging roles of physiological DSBs and the emerging network of their multilateral regulation to consider how the cell is able to harness DNA breaks as a critical biochemical tool.

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i-BLESS is an ultra-sensitive method for detection of DNA double-strand breaks

Communications Biology ◽

10.1038/s42003-018-0165-9 ◽

2018 ◽

Vol 1 (1) ◽

Cited By ~ 22

Author(s):

Anna Biernacka ◽

Yingjie Zhu ◽

Magdalena Skrzypczak ◽

Romain Forey ◽

Benjamin Pardo ◽

...

Keyword(s):

Cell Fate ◽

Genome Stability ◽

Strand Break ◽

Double Strand Breaks ◽

Universal Method ◽

Dna Double Strand Breaks ◽

Strand Breaks ◽

Agarose Beads ◽

Genome Wide ◽

Dna Double Strand Break

AbstractMaintenance of genome stability is a key issue for cell fate that could be compromised by chromosome deletions and translocations caused by DNA double-strand breaks (DSBs). Thus development of precise and sensitive tools for DSBs labeling is of great importance for understanding mechanisms of DSB formation, their sensing and repair. Until now there has been no high resolution and specific DSB detection technique that would be applicable to any cells regardless of their size. Here, we present i-BLESS, a universal method for direct genome-wide DNA double-strand break labeling in cells immobilized in agarose beads. i-BLESS has three key advantages: it is the only unbiased method applicable to yeast, achieves a sensitivity of one break at a given position in 100,000 cells, and eliminates background noise while still allowing for fixation of samples. The method allows detection of ultra-rare breaks such as those forming spontaneously at G-quadruplexes.

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ATM-dependent pathways of chromatin remodelling and oxidative DNA damage responses

Philosophical Transactions of the Royal Society B Biological Sciences ◽

10.1098/rstb.2016.0283 ◽

2017 ◽

Vol 372 (1731) ◽

pp. 20160283 ◽

Cited By ~ 25

Author(s):

N. Daniel Berger ◽

Fintan K. T. Stanley ◽

Shaun Moore ◽

Aaron A. Goodarzi

Keyword(s):

Dna Damage ◽

Oxidative Dna Damage ◽

Strand Break ◽

Chromatin Remodelling ◽

Double Strand Breaks ◽

Biochemical Network ◽

Regulatory Function ◽

Dna Double Strand Breaks ◽

Strand Breaks ◽

The Impact

Ataxia-telangiectasia mutated (ATM) is a serine/threonine protein kinase with a master regulatory function in the DNA damage response. In this role, ATM commands a complex biochemical network that signals the presence of oxidative DNA damage, including the dangerous DNA double-strand break, and facilitates subsequent repair. Here, we review the current state of knowledge regarding ATM-dependent chromatin remodelling and epigenomic alterations that are required to maintain genomic integrity in the presence of DNA double-strand breaks and/or oxidative stress. We will focus particularly on the roles of ATM in adjusting nucleosome spacing at sites of unresolved DNA double-strand breaks within complex chromatin environments, and the impact of ATM on preserving the health of cells within the mammalian central nervous system. This article is part of the themed issue ‘Chromatin modifiers and remodellers in DNA repair and signalling’.

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