RECQL5 Controls Transcript Elongation and Suppresses Genome Instability Associated with Transcription Stress

Saponaro, Marco; Kantidakis, Theodoros; Mitter, Richard; Kelly, Gavin; Heron, Mark; Williams, Hannah; Söding, Johannes; Stewart, Aengus; Svejstrup, Jesper Q.

doi:10.1016/j.cell.2014.03.048

Cited by 172 publications

(204 citation statements)

References 47 publications

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“…RECQL5 has a well-established role in maintaining genomic stability (Aygun and Svejstrup 2010;Saponaro et al 2014). While the mechanistic relevance of MLL2-RECQL5 interaction is yet to be investigated, the connection spurred us to investigate the potential role of MLL2 in the maintenance of genome integrity.…”

Section: Mouse Cells Defective For Mll2 Present Genomic Instabilitymentioning

confidence: 99%

“…We recently reported that RECQL5, a member of the RECQ family of helicases, is a general RNA polymerase II (RNAPII) elongation factor that is important for preserving genomic stability during transcription (Saponaro et al 2014). Indeed, depletion of RECQL5 results in increased pausing, stalling, arrest, and/or backtracking (collectively referred to as transcription stress) at sites that overlap with regions of genome instability.…”

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confidence: 99%

“…As it transcribes through nucleosomes, RNAPII interacts with chromatin-modifying enzymes, affecting chromatin structure and nucleosome displacement/reassembly. In the absence of tightly regulated cotranscriptional chromatin rearrangement, transcript elongation can be interrupted, resulting in transcription stress and potential disturbance of the integrity of the transcribed region (Svejstrup 2007;Selth et al 2010;Saponaro et al 2014). In light of these considerations, it is intriguing that mutations in chromatin-regulating enzymes have been identified in several recent cancer genome-sequencing projects (for recent reviews, see Roy et al 2014;Van Rechem and Whetstine 2014).…”

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confidence: 99%

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Mutation of cancer driverMLL2results in transcription stress and genome instability

et al. 2016

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Genome instability is a recurring feature of tumorigenesis. Mutation in MLL2, encoding a histone methyltransferase, is a driver in numerous different cancer types, but the mechanism is unclear. Here, we present evidence that MLL2 mutation results in genome instability. Mouse cells in which MLL2 gene deletion can be induced display elevated levels of sister chromatid exchange, gross chromosomal aberrations, 53BP1 foci, and micronuclei. Human MLL2 knockout cells are characterized by genome instability as well. Interestingly, MLL2 interacts with RNA polymerase II (RNAPII) and RECQL5, and, although MLL2 mutated cells have normal overall H3K4me levels in genes, nucleosomes in the immediate vicinity of RNAPII are hypomethylated. Importantly, MLL2 mutated cells display signs of substantial transcription stress, and the most affected genes overlap with early replicating fragile sites, show elevated levels of γH2AX, and suffer frequent mutation. The requirement for MLL2 in the maintenance of genome stability in genes helps explain its widespread role in cancer and points to transcription stress as a strong driver in tumorigenesis.

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Section: Mouse Cells Defective For Mll2 Present Genomic Instabilitymentioning

confidence: 99%

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confidence: 99%

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Mutation of cancer driverMLL2results in transcription stress and genome instability

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“…RECQ5 prevents transcription-associated DSBs by suppressing RNAPII-dependent transcription initiation 18 , and this may be achieved by the interaction between RNAPII and the RECQ5 KIX domain, which blocks the binding of transcription elongation factor TFIIS to RNAPII 19 . RECQ5 is also known to interact with the active RNAPII (RNAPIIo) elongation complex to maintain the transcription elongation rate and prevent genome instability 15,20,21 . However, the exact mechanism by which RECQ5 maintains genome stability during transcription elongation has also not been determined.…”

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confidence: 99%

RECQ5-dependent SUMOylation of DNA topoisomerase I prevents transcription-associated genome instability

Pokharel

Wang

et al. 2015

Nat Commun

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DNA topoisomerase I (TOP1) has an important role in maintaining DNA topology by relaxing supercoiled DNA. Here we show that the K391 and K436 residues of TOP1 are SUMOylated by the PIAS1-SRSF1 E3 ligase complex in the chromatin fraction containing active RNA polymerase II (RNAPIIo). This modification is necessary for the binding of TOP1 to RNAPIIo and for the recruitment of RNA splicing factors to the actively transcribed chromatin, thereby reducing the formation of R-loops that lead to genome instability. RECQ5 helicase promotes TOP1 SUMOylation by facilitating the interaction between PIAS1, SRSF1 and TOP1. Unexpectedly, the topoisomerase activity is compromised by K391/K436 SUMOylation, and this provides the first in vivo evidence that TOP1 activity is negatively regulated at transcriptionally active chromatin to prevent TOP1-induced DNA damage. Therefore, our data provide mechanistic insight into how TOP1 SUMOylation contributes to genome maintenance during transcription.

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“…A recent paper has shown that RECQL5 slows down RNA polymerase II elongation and increases the robustness of transcription. Depletion of RECQL5 increases polymerase pausing and leads to genomic instability with gains and losses in common fragile sites and long genes, further supporting that stalled forks, regardless of the cause, can ultimately derive into pro-tumoral mutations [58]. These data suggest that RECQL5 may be limiting the generation of R-loops, yet further analyses should address this point.…”

Section: Rs As a Fuel Of Tumorogenesismentioning

confidence: 86%

Replication stress and cancer: It takes two to tango

Lecona

Fernández-Capetillo

2014

Experimental Cell Research

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Problems arising during DNA replication require the activation of the ATR-CHK1 pathway to ensure the stabilization and repair of the forks, and to prevent the entry into mitosis with unreplicated genomes. Whereas the pathway is essential at the cellular level, limiting its activity is particularly detrimental for some cancer cells. Here we review the links between replication stress (RS) and cancer, which provide a rationale for the use of ATR and Chk1 inhibitors in chemotherapy. First, we describe how the activation of oncogene-induced RS promotes genome rearrangements and chromosome instability, both of which could potentially fuel carcinogenesis. Next, we review the various pathways that contribute to the suppression of RS, and how mutations in these components lead to increased cancer incidence and/or accelerated ageing. Finally, we summarize the evidence showing that tumours with high levels of RS are dependent on a proficient RS-response, and therefore vulnerable to ATR or Chk1 inhibitors.

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RECQL5 Controls Transcript Elongation and Suppresses Genome Instability Associated with Transcription Stress

Cited by 172 publications

References 47 publications

Mutation of cancer driverMLL2results in transcription stress and genome instability

Mutation of cancer driverMLL2results in transcription stress and genome instability

RECQ5-dependent SUMOylation of DNA topoisomerase I prevents transcription-associated genome instability

Replication stress and cancer: It takes two to tango

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