RADX Promotes Genome Stability and Modulates Chemosensitivity by Regulating RAD51 at Replication Forks

Dungrawala, Huzefa; Bhat, Kamakoti P.; Meur, Rémy Le; Chazin, Walter J.; Ding, Xia; Sharan, Shyam K.; Wessel, Sarah R.; Sathe, Aditya; Zhao, Runxiang; Chen, David

doi:10.1016/j.molcel.2017.06.023

Cited by 167 publications

(243 citation statements)

References 77 publications

(125 reference statements)

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“…Consistent with this idea, SMARCAL1 is required for replication through telomeres; however, silencing HLTF or ZRANB3 did not yield telomere instability (Poole et al , 2015). Furthermore, only silencing SMARCAL1 in unstressed caused spontaneous double-strand breaks (Dungrawala et al , 2017). …”

Section: Discussionmentioning

confidence: 99%

“…Similarly, the checkpoint inhibits fork reversal in S. cerevisiae (Sogo et al , 2002). Furthermore, failure to regulate fork reversal in cells deficient for the recently described RADX protein also yields double-strand breaks (Dungrawala et al , 2017), and fork reversal can facilitate nascent strand degradation (Kolinjivadi et al , 2017). Thus, inappropriate, excessive, or persistent fork reversal can be deleterious.…”

Section: Smarcal1mentioning

confidence: 99%

“…However, SMARCAL1 is also required to address endogenous sources of replication stress. Cells without SMARCAL1 display high levels of DNA damage in the absence of any added drugs (Bansbach et al , 2009, Ciccia et al , 2009, Yuan et al , 2009, Bansbach et al , 2010, Poole et al , 2015) and some SMARCAL1 protein is observed at elongating replication forks in untreated cells (Betous et al , 2012, Dungrawala et al , 2017). Thus, it is important to determine what endogenous sources of replication stress require SMARCAL1 for resolution.…”

Section: Smarcal1mentioning

confidence: 99%

“…These proteins are not functioning redundantly since depleting both further sensitizes cells to replication stress compared to individual depletions (Ciccia et al , 2012). Unlike SMARCAL1, ZRANB3 deficiency does not result in fork breakage in the absence of replication stress, and ZRANB3 has not been linked to telomere replication (Poole et al , 2015, Dungrawala et al , 2017). …”

Section: Zranb3mentioning

confidence: 99%

“…For example, loss of SMARCAL1 increases the frequency of double-strand breaks in replicating cells (Yuan et al , 2009, Bansbach et al , 2010, Dungrawala et al , 2017). Loss of either SMARCAL1 or ZRANB3 reduces the ability of stalled forks to recover from replication stress challenges (Bansbach et al , 2009, Ciccia et al , 2009, Ciccia et al , 2012, Weston et al , 2012, Yuan et al , 2012).…”

Section: Introductionmentioning

confidence: 99%

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Functions of SMARCAL1, ZRANB3, and HLTF in maintaining genome stability

Poole

Chen

2017

Critical Reviews in Biochemistry and Molecular Biology

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A large number of SNF2 family, DNA and ATP-dependent motor proteins are needed during transcription, DNA replication, and DNA repair to manipulate protein-DNA interactions and change DNA structure. SMARCAL1, ZRANB3, and HLTF are three related members of this family with specialized functions that maintain genome stability during DNA replication. These proteins are recruited to replication forks through protein-protein interactions and bind DNA using both their motor and substrate recognition domains (SRD). The SRD provides specificity to DNA structures like forks and junctions and confer DNA remodeling activity to the motor domains. Remodeling reactions include fork reversal and branch migration to promote fork stabilization, template switching, and repair. Regulation ensures these powerful activities remain controlled and restricted to damaged replication forks. Inherited mutations in SMARCAL1 cause a severe developmental disorder and mutations in ZRANB3 and HLTF are linked to cancer illustrating the importance of these enzymes in ensuring complete and accurate DNA replication. In this review, we examine how these proteins function, concentrating on their common and unique attributes and regulatory mechanisms.

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Section: Discussionmentioning

confidence: 99%

Section: Smarcal1mentioning

confidence: 99%

Section: Smarcal1mentioning

confidence: 99%

Section: Zranb3mentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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Functions of SMARCAL1, ZRANB3, and HLTF in maintaining genome stability

Poole

Chen

2017

Critical Reviews in Biochemistry and Molecular Biology

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122

104

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Exploration of poly (ADP‐ribose) polymerase inhibitor resistance in the treatment of BRCA1/2‐mutated cancer

Wu,

Yao,

Sun

et al. 2024

Genes Chromosomes & Cancer

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Breast cancer susceptibility 1/2 (BRCA1/2) genes play a crucial role in DNA damage repair, yet mutations in these genes increase the susceptibility to tumorigenesis. Exploiting the synthetic lethality mechanism between BRCA1/2 mutations and poly(ADP‐ribose) polymerase (PARP) inhibition has led to the development and clinical approval of PARP inhibitor (PARPi), representing a milestone in targeted therapy for BRCA1/2 mutant tumors. This approach has paved the way for leveraging synthetic lethality in tumor treatment strategies. Despite the initial success of PARPis, resistance to these agents diminishes their efficacy in BRCA1/2‐mutant tumors. Investigations into PARPi resistance have identified replication fork stability and homologous recombination repair as key factors sensitive to PARPis. Additionally, studies suggest that replication gaps may also confer sensitivity to PARPis. Moreover, emerging evidence indicates a correlation between PARPi resistance and cisplatin resistance, suggesting a potential overlap in the mechanisms underlying resistance to both agents. Given these findings, it is imperative to explore the interplay between replication gaps and PARPi resistance, particularly in the context of platinum resistance. Understanding the impact of replication gaps on PARPi resistance may offer insights into novel therapeutic strategies to overcome resistance mechanisms and enhance the efficacy of targeted therapies in BRCA1/2‐mutant tumors.

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A CRISPR Path to Finding Vulnerabilities and Solving Drug Resistance: Targeting the Diverse Cancer Landscape and Its Ecosystem

et al. 2022

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Cancer is the second leading cause of death globally, with therapeutic resistance being a major cause of treatment failure in the clinic. The dynamic signaling that occurs between tumor cells and the diverse cells of the surrounding tumor microenvironment actively promotes disease progression and therapeutic resistance. Improving the understanding of how tumors evolve following therapy and the molecular mechanisms underpinning de novo or acquired resistance is thus critical for the identification of new targets and for the subsequent development of more effective combination regimens. Simultaneously targeting multiple hallmark capabilities of cancer to circumvent adaptive or evasive resistance may lead to significantly improved treatment response in the clinic. Here, the latest applications of functional genomics tools, such as clustered regularly interspaced short palindromic repeats (CRISPR) editing, to characterize the dynamic cancer resistance mechanisms, from improving the understanding of resistance to classical chemotherapeutics, to deciphering unique mechanisms that regulate tumor responses to new targeted agents and immunotherapies, are discussed. Potential avenues of future research in combating therapeutic resistance, the contribution of tumor-stroma signaling in this setting, and how advanced functional genomics tools can help streamline the identification of key molecular determinants of drug response are explored.

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RADX Promotes Genome Stability and Modulates Chemosensitivity by Regulating RAD51 at Replication Forks

Cited by 167 publications

References 77 publications

Functions of SMARCAL1, ZRANB3, and HLTF in maintaining genome stability

Functions of SMARCAL1, ZRANB3, and HLTF in maintaining genome stability

Exploration of poly (ADP‐ribose) polymerase inhibitor resistance in the treatment of BRCA1/2‐mutated cancer

A CRISPR Path to Finding Vulnerabilities and Solving Drug Resistance: Targeting the Diverse Cancer Landscape and Its Ecosystem

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