Sensor Of DNA Double-strand Breaks Research Articles

Impact of Optimized Ku-DNA Binding Inhibitors on the Cellular and In Vivo DNA Damage Response.

Background: DNA-dependent protein kinase (DNA-PK) is a validated cancer therapeutic target involved in DNA damage response (DDR) and non-homologous end-joining (NHEJ) repair of DNA double-strand breaks (DSBs). Ku serves as a sensor of DSBs by binding to DNA ends and activating DNA-PK. Inhibition of DNA-PK is a common strategy to block DSB repair and improve efficacy of ionizing radiation (IR) therapy and radiomimetic drug therapies. We have previously developed Ku-DNA binding inhibitors (Ku-DBis) that block in vitro and cellular NHEJ activity, abrogate DNA-PK autophosphorylation, and potentiate cellular sensitivity to IR. Results and Conclusions: Here we report the discovery of oxindole Ku-DBis with improved cellular uptake and retained potent Ku-inhibitory activity. Variable monotherapy activity was observed in a panel of non-small cell lung cancer (NSCLC) cell lines, with ATM-null cells being the most sensitive and showing synergy with IR. BRCA1-deficient cells were resistant to single-agent treatment and antagonistic when combined with DSB-generating therapies. In vivo studies in an NSCLC xenograft model demonstrated that the Ku-DBi treatment blocked IR-dependent DNA-PKcs autophosphorylation, modulated DDR, and reduced tumor cell proliferation. This represents the first in vivo demonstration of a Ku-targeted DNA-binding inhibitor impacting IR response and highlights the potential therapeutic utility of Ku-DBis for cancer treatment.

Resection of DNA double-strand breaks activates Mre11-Rad50-Nbs1- and Rad9-Hus1-Rad1-dependent mechanisms that redundantly promote ATR checkpoint activation and end processing in Xenopus egg extracts.

Sensing and processing of DNA double-strand breaks (DSBs) are vital to genome stability. DSBs are primarily detected by the ATM checkpoint pathway, where the Mre11-Rad50-Nbs1 (MRN) complex serves as the DSB sensor. Subsequent DSB end resection activates the ATR checkpoint pathway, where replication protein A, MRN, and the Rad9-Hus1-Rad1 (9-1-1) clamp serve as the DNA structure sensors. ATR activation depends also on Topbp1, which is loaded onto DNA through multiple mechanisms. While different DNA structures elicit specific ATR-activation subpathways, the regulation and mechanisms of the ATR-activation subpathways are not fully understood. Using DNA substrates that mimic extensively resected DSBs, we show here that MRN and 9-1-1 redundantly stimulate Dna2-dependent long-range end resection and ATR activation in Xenopus egg extracts. MRN serves as the loading platform for ATM, which, in turn, stimulates Dna2- and Topbp1-loading. Nevertheless, MRN promotes Dna2-mediated end processing largely independently of ATM. 9-1-1 is dispensable for bulk Dna2 loading, and Topbp1 loading is interdependent with 9-1-1. ATR facilitates Mre11 phosphorylation and ATM dissociation. These data uncover that long-range end resection activates two redundant pathways that facilitate ATR checkpoint signaling and DNA processing in a vertebrate system.

PARP1-DNA co-condensation drives DNA repair site assembly to prevent disjunction of broken DNA ends

DNA double-strand breaks (DSBs) are repaired at DSB sites. How DSB sites assemble and how broken DNA is prevented from separating is not understood. Here we uncover that the synapsis of broken DNA is mediated by the DSB sensor protein poly(ADP-ribose) (PAR) polymerase 1 (PARP1). Using bottom-up biochemistry, we reconstitute functional DSB sites and show that DSB sites form through co-condensation of PARP1 multimers with DNA. The co-condensates exert mechanical forces to keep DNA ends together and become enzymatically active for PAR synthesis. PARylation promotes release of PARP1 from DNA ends and the recruitment of effectors, such as Fused in Sarcoma, which stabilizes broken DNA ends against separation, revealing a finely orchestrated order of events that primes broken DNA for repair. We provide a comprehensive model for the hierarchical assembly of DSB condensates to explain DNA end synapsis and the recruitment of effector proteins for DNA damage repair.

Free cGAS.

The DNA double-strand break sensor MRE11 is necessary to liberate cGAS and enable its activation by dsDNA.

MRE11 liberates cGAS from nucleosome sequestration during tumorigenesis

Oncogene-induced replication stress generates endogenous DNA damage that activates cGAS–STING-mediated signalling and tumour suppression1–3. However, the precise mechanism of cGAS activation by endogenous DNA damage remains enigmatic, particularly given that high-affinity histone acidic patch (AP) binding constitutively inhibits cGAS by sterically hindering its activation by double-stranded DNA (dsDNA)4–10. Here we report that the DNA double-strand break sensor MRE11 suppresses mammary tumorigenesis through a pivotal role in regulating cGAS activation. We demonstrate that binding of the MRE11–RAD50–NBN complex to nucleosome fragments is necessary to displace cGAS from acidic-patch-mediated sequestration, which enables its mobilization and activation by dsDNA. MRE11 is therefore essential for cGAS activation in response to oncogenic stress, cytosolic dsDNA and ionizing radiation. Furthermore, MRE11-dependent cGAS activation promotes ZBP1–RIPK3–MLKL-mediated necroptosis, which is essential to suppress oncogenic proliferation and breast tumorigenesis. Notably, downregulation of ZBP1 in human triple-negative breast cancer is associated with increased genome instability, immune suppression and poor patient prognosis. These findings establish MRE11 as a crucial mediator that links DNA damage and cGAS activation, resulting in tumour suppression through ZBP1-dependent necroptosis.

Abstract A027: Development of small molecule inhibitors of the Ku-DNA interaction: Impacts on NHEJ, DDR signaling, optimizing genome editing technologies, and therapeutic intervention for the treatment of cancer

Abstract DNA-PK, the DNA-dependent protein kinase is a validated target for cancer therapeutics that drives the DNA damage response (DDR) and plays a critical role in the non-homologous end joining (NHEJ) DNA repair pathway. NHEJ is responsible for the repair of DNA double strand breaks (DSB), particularly those induced by ionizing radiation (IR). The generation of DNA DSBs drives clinical efficacy of radiation therapy and numerous DNA damaging chemotherapeutic drugs used to treat cancer. Modulating the DSB repair pathways is an effective mechanism to increase clinical efficacy of IR and certain chemotherapeutic regimens. We have taken the novel approach to inhibit target the DDR and NHEJ by developing small molecule inhibitors of the DSB sensor Ku, and its interaction with DNA. The Ku heterodimer serves as initiator of the NHEJ pathway following DSB induction and is the key DNA-binding component of the DNA-PK. We have created an extensive library of Ku DNA binding inhibitors (Ku-DBis) and demonstrate a direct interaction with the Ku heterodimer and potent inhibition of Ku-DNA binding and DNA-PK catalytic activity. In vitro analysis of a series of Ku truncation mutants defines the necessary domains for Ku-DBi activity. Ku-DBi’s show potent inhibition of in vitro and cellular NHEJ and, as a result, potentiate cellular sensitivity to DSB-inducing agents. Enhancement of sensitivity is a function of inhibiting DNA-PKcs autophosphorylation and dysregulation of signaling to the DDR. Recent chemical optimization has identified independent pharmacophores that drive off-target cytotoxicity, direct Ku inhibitory potency, and enhance cellular uptake activity. These data served as the basis for creation of a novel series of Ku-DBi’s towards interrogating NHEJ and DDR signaling in vivo, optimizing genome editing technologies, and therapeutic intervention for the treatment of cancer. Citation Format: John J. Turchi, Pamela L. Mendoza-Munoz, Pamela S. VanderVere-Carozza, Navnath S. Gavande, Joseph R. Dynlacht, Joy E. Garrett, Dineshsinha Chauhan, Katherine S. Pawelczak. Development of small molecule inhibitors of the Ku-DNA interaction: Impacts on NHEJ, DDR signaling, optimizing genome editing technologies, and therapeutic intervention for the treatment of cancer [abstract]. In: Proceedings of the AACR Special Conference in Cancer Research: DNA Damage Repair: From Basic Science to Future Clinical Application; 2024 Jan 9-11; Washington, DC. Philadelphia (PA): AACR; Cancer Res 2024;84(1 Suppl):Abstract nr A027.

Abstract A012: Mre11 mediates cGAS activation and tumor suppression through ZBP1-dependent necroptosis in breast cancer

Abstract Oncogene-induced replication stress leads to endogenous DNA damage, activating the cGAS/STING signaling pathway, a critical player in tumor suppression. The exact mechanism underlying cGAS activation, however, remains unclear due to the continual inhibition of cGAS by its high-affinity interaction with the histone acidic patch (AP), which sterically prevents its activation by double-stranded DNA (dsDNA). In this investigation, we elucidate the significant role of the DNA double-strand break sensor, Mre11, in regulating cGAS activation and thereby inhibiting mammary tumorigenesis. Our data reveal that the binding of the Mre11-Rad50-Nbn (MRN) complex to nucleosome fragments is crucial to liberate cGAS from AP-mediated sequestration, facilitating its subsequent activation by dsDNA. Consequently, Mre11 emerges as a vital component in the cGAS activation process, responding to oncogenic stress, cytosolic dsDNA, and ionizing radiation. Moreover, we highlight the ramifications of Mre11-dependent cGAS activation which fosters ZBP1/RIPK3/MLKL-mediated necroptosis, a vital process in curtailing oncogenic proliferation and breast tumorigenesis. Significantly, our study identifies a strong correlation between the downregulation of ZBP1 in human triple-negative breast cancer and increased genomic instability, suppressed immune response, and adverse patient prognosis. Our findings firmly establish Mre11 as a pivotal mediator connecting DNA damage to cGAS activation, thereby facilitating tumor suppression through ZBP1-dependent necroptosis, offering a promising avenue for targeted breast cancer therapies. Citation Format: Minguk Jo, Rashmi J. Kumar, Chien-Chu Lin, Joshua A. Boyer, Jamshaid A. Shahir, Katerina Fagan-Solis, Dennis A. Simpson, Cheng Fan, Christine E. Foster, Anna M. Goddard, Lynn M. Lerner, Simon W. Ellington, Qinhong Wang, Ying Wang, Alice Y. Ho, Pengda Liu, Charles M. Perou, Qi Zhang, Robert K. McGinty, Jeremy E. Purvis, Gaorav P. Gupta. Mre11 mediates cGAS activation and tumor suppression through ZBP1-dependent necroptosis in breast cancer [abstract]. In: Proceedings of the AACR Special Conference in Cancer Research: DNA Damage Repair: From Basic Science to Future Clinical Application; 2024 Jan 9-11; Washington, DC. Philadelphia (PA): AACR; Cancer Res 2024;84(1 Suppl):Abstract nr A012.

Translocating RNA polymerase generates R-loops at DNA double-strand breaks without any additional factors.

The R-loops forming around DNA double-strand breaks (DSBs) within actively transcribed genes play a critical role in the DSB repair process. However, the mechanisms underlying R-loop formation at DSBs remain poorly understood, with diverse proposed models involving protein factors associated with RNA polymerase (RNAP) loading, pausing/backtracking or preexisting transcript RNA invasion. In this single-molecule study using Escherichia coli RNAP, we discovered that transcribing RNAP alone acts as a highly effective DSB sensor, responsible for generation of R-loops upon encountering downstream DSBs, without requiring any additional factors. The R-loop formation efficiency is greatly influenced by DNA end structures, ranging here from 2.8% to 73%, and notably higher on sticky ends with 3' or 5' single-stranded overhangs compared to blunt ends without any overhangs. The R-loops extend unidirectionally upstream from the DSB sites and can reach the transcription start site, interfering with ongoing-round transcription. Furthermore, the extended R-loops can persist and maintain their structures, effectively preventing the efficient initiation of subsequent transcription rounds. Our results are consistent with the bubble extension model rather than the 5'-end invasion model or the middle insertion model. These discoveries provide valuable insights into the initiation of DSB repair on transcription templates across bacteria, archaea and eukaryotes.

DNA End Joining: G0-ing to the Core.

Humans have evolved a series of DNA double-strand break (DSB) repair pathways to efficiently and accurately rejoin nascently formed pairs of double-stranded DNA ends (DSEs). In G0/G1-phase cells, non-homologous end joining (NHEJ) and alternative end joining (A-EJ) operate to support covalent rejoining of DSEs. While NHEJ is predominantly utilized and collaborates extensively with the DNA damage response (DDR) to support pairing of DSEs, much less is known about A-EJ collaboration with DDR factors when NHEJ is absent. Non-cycling lymphocyte progenitor cells use NHEJ to complete V(D)J recombination of antigen receptor genes, initiated by the RAG1/2 endonuclease which holds its pair of targeted DSBs in a synapse until each specified pair of DSEs is handed off to the NHEJ DSB sensor complex, Ku. Similar to designer endonuclease DSBs, the absence of Ku allows for A-EJ to access RAG1/2 DSEs but with random pairing to complete their repair. Here, we describe recent insights into the major phases of DSB end joining, with an emphasis on synapsis and tethering mechanisms, and bring together new and old concepts of NHEJ vs. A-EJ and on RAG2-mediated repair pathway choice.

ATM controls meiotic DNA double-strand break formation and recombination and affects synaptonemal complex organization in plants.

Meiosis is a specialized cell division that gives rise to genetically distinct gametic cells. Meiosis relies on the tightly controlled formation of DNA double-strand breaks (DSBs) and their repair via homologous recombination for correct chromosome segregation. Like all forms of DNA damage, meiotic DSBs are potentially harmful and their formation activates an elaborate response to inhibit excessive DNA break formation and ensure successful repair. Previous studies established the protein kinase ATM as a DSB sensor and meiotic regulator in several organisms. Here we show that Arabidopsis ATM acts at multiple steps during DSB formation and processing, as well as crossover (CO) formation and synaptonemal complex (SC) organization, all vital for the successful completion of meiosis. We developed a single-molecule approach to quantify meiotic breaks and determined that ATM is essential to limit the number of meiotic DSBs. Local and genome-wide recombination screens showed that ATM restricts the number of interference-insensitive COs, while super-resolution STED nanoscopy of meiotic chromosomes revealed that the kinase affects chromatin loop size and SC length and width. Our study extends our understanding of how ATM functions during plant meiosis and establishes it as an integral factor of the meiotic program.

Mutation Spectra of the MRN (MRE11, RAD50, NBS1/NBN) Break Sensor in Cancer Cells.

Simple SummaryA DNA double strand break cuts a chromosome in two and is one of the most dangerous forms of DNA damage. Improper repair can lead to various chromosomal re-arrangements that have been detected in almost all cancer cells. A complex of three proteins (MRE11, RAD50, NBS1 or NBN) detects chromosome breaks and orchestrates repair processes. Mutations in these “break sensor” genes have been described in a multitude of cancers. Here, we provide a comprehensive analysis of reported mutations from data deposited on the Catalogue of Somatic Mutations in Cancer (COSMIC) archive. We also undertake an evolutionary analysis of these genes with the aim to understand whether these mutations preferentially accumulate in conserved residues. Interestingly, we find that mutations are overrepresented in evolutionarily conserved residues of RAD50 and NBS1/NBN but not MRE11.The MRN complex (MRE11, RAD50, NBS1/NBN) is a DNA double strand break sensor in eukaryotes. The complex directly participates in, or coordinates, several activities at the break such as DNA resection, activation of the DNA damage checkpoint, chromatin remodeling and recruitment of the repair machinery. Mutations in components of the MRN complex have been described in cancer cells for several decades. Using the Catalogue of Somatic Mutations in Cancer (COSMIC) database, we characterized all the reported MRN mutations. This analysis revealed several hotspot frameshift mutations in all three genes that introduce premature stop codons and truncate large regions of the C-termini. We also found through evolutionary analyses that COSMIC mutations are enriched in conserved residues of NBS1/NBN and RAD50 but not in MRE11. Given that all three genes are important to carcinogenesis, we propose these differential enrichment patterns may reflect a more severe pleiotropic role for MRE11.

RECQL5 KIX domain splicing isoforms have distinct functions in transcription repression and DNA damage response

RecQL5, a mammalian RecQ family protein, is involved in the regulation of transcription elongation, DNA damage response, and DNA replication. Here, we identified and characterized an alternative splicing isoform of RECQL5 (RECQL5β1), which contains 17 additional amino acid residues within the RECQL5 KIX domain when compared with the canonical isoform (RECQL5β). RECQL5β1 had a markedly decreased binding affinity to RNA polymerase II (Pol II) and poorly competed with the transcription elongation factor TFIIS for binding to Pol II. As a result, this isoform has a weaker activity for repression of transcription elongation. In contrast, we discovered that RECQL5β1 could bind stronger to MRE11, which is a primary sensor of DNA double-strand breaks (DSBs). Furthermore, we found that RECQL5β1 promoted DNA repair in the RECQL5β1 rescue cells. These results suggest that RECQL5β mainly functions as a transcription repressor, while the newly discovered RECQL5β1 has a specialized role in DNA damage response. Taken together, our data suggest a cellular-functional specialization for each KIX splicing isoform in the cell.

ATM-Dependent Recruitment of BRD7 is required for Transcriptional Repression and DNA Repair at DNA Breaks Flanking Transcriptional Active Regions.

Repair of DNA double‐strand breaks (DSBs) is essential for genome integrity, and is accompanied by transcriptional repression at the DSB regions. However, the mechanisms how DNA repair induces transcriptional inhibition remain elusive. Here, it is identified that BRD7 participates in DNA damage response (DDR) and is recruited to the damaged chromatin via ATM signaling. Mechanistically, BRD7 joins the polycomb repressive complex 2 (PRC2), the nucleosome remodeling and histone deacetylation (NuRD) complex at the damaged DNA and recruits E3 ubiquitin ligase RNF168 to the DSBs. Furthermore, ATM‐mediated BRD7 phosphorylation is required for recruitment of the PRC2 complex, NuRD complex, DSB sensor complex MRE11‐RAD50‐NBS1 (MRN), and RNF168 to the active transcription sites at DSBs, resulting in transcriptional repression and DNA repair. Moreover, BRD7 deficiency sensitizes cancer cells to PARP inhibition. Collectively, BRD7 is crucial for DNA repair and DDR‐mediated transcription repression, which may serve as a therapeutic target. The findings identify the missing link between DNA repair and transcription regulation that maintains genome integrity.

Abstract CT248: AZD7648: A Phase I/IIa first-in-human trial of a novel, potent and selective DNA-PK inhibitor in patients with advanced malignancies

Abstract Background: DNA-dependent protein kinase (DNA-PK) is a critical sensor of DNA double-strand breaks (DSBs) and orchestrates their repair through non-homologous end joining (NHEJ). AZD7648 is a novel, potent and highly selective inhibitor of DNA-PK being evaluated as monotherapy or in combination with doxorubicin or olaparib in a Phase I/II first-in-human study. The objectives of this trial are to assess safety and tolerability, establish a Recommended Phase 2 Dose (RP2D) and evaluate early clinical activity. Pre-clinically, AZD7648 monotherapy leads to tumour growth inhibition in ATM deficient models in vivo, demonstrating potential to enhance the effects of endogenous tumour damage clinically. AZD7648 is also an efficient sensitizer of doxorubicin-induced DNA damage and demonstrates enhanced efficacy in combination with olaparib. Both combinations induce sustained regressions in vivo across a range of tumour xenografts with differing genetic alterations, accompanied by robust pharmacodynamic biomarker modulation. These data provide the rationale to explore AZD7648 as monotherapy and in combination with either doxorubicin or olaparib. Methods: This is a Phase I/IIa study comprising 3 modules: Core Module (AZD7648 monotherapy - dose escalation), combination module 1 (AZD7648 + pegylated liposomal doxorubicin [PLD]), and combination module 2 (AZD7648 + olaparib). Each combination evaluates AZD7648 in a Phase I escalation (Part A) and a Phase IIa expansion (Part B). Patients are assigned to a single study Part, but intra-patient dose escalation is permitted in Part A. The study incorporates a Bayesian adaptive dose escalation trial design which combines prior expectations about the dose toxicity relationship and applies the data at the end of each cohort to recommend a dose for the next cohort. The study will investigate pharmacodynamic (PD) and exploratory biomarker (DNA, RNA, proteins or metabolites) profiles in exclusive cohorts, and study their relationship to drug effect. Eligible patients are aged ≥18 years with advanced solid tumours, who have failed standard therapies. In Part A, patients are assessed for dose-limiting toxicities during the evaluable period. Blood samples are collected for pharmacokinetic (PK) analysis following a single dose of AZD7648 and at steady state. Single patient cohorts may occur for the first four cohorts (or until drug-related ≥ Grade 2 toxicity). From cohort 5 onwards, a minimum of 3 patients will be enrolled into each dose cohort until the Maximum Tolerated Dose, Maximum Feasible Dose or RP2D is identified. Enrolment into the study commenced in Oct 2019 and is currently enrolling cohort 3 in the monotherapy dose escalation. To date, no DLTs have been reported in prior cohorts. [clinicaltrials.gov identifier: NCT03907969] Citation Format: Timothy A. Yap, Yingxue Chen, Lisa H. Butler, Si-houy Lao-Sirieix, Elaine Cadogan, Lenka Oplustil O'Connor, Karthick Vishwanathan, Younghwa Kim, Dónal Landers, Emma Dean. AZD7648: A Phase I/IIa first-in-human trial of a novel, potent and selective DNA-PK inhibitor in patients with advanced malignancies [abstract]. In: Proceedings of the Annual Meeting of the American Association for Cancer Research 2020; 2020 Apr 27-28 and Jun 22-24. Philadelphia (PA): AACR; Cancer Res 2020;80(16 Suppl):Abstract nr CT248.

A P53-Independent DNA Damage Response Suppresses Oncogenic Proliferation and Genome Instability

The Mre11-Rad50-Nbs1 complex is a DNA double-strand break sensor that mediates a tumor-suppressive DNA damage response (DDR) in cells undergoing oncogenic stress, yet the mechanisms underlying this effect are poorly understood. Using a genetically inducible primary mammary epithelial cell model, we demonstrate that Mre11 suppresses proliferation and DNA damage induced by diverse oncogenic drivers through a p53-independent mechanism. Breast tumorigenesis models engineered to express a hypomorphic Mre11 allele exhibit increased levels of oncogene-induced DNA damage, R-loop accumulation, and chromosomal instability with a characteristic copy number loss phenotype. Mre11 complex dysfunction is identified in a subset of human triple-negative breast cancers and is associated with increased sensitivity to DNA-damaging therapy and inhibitors of ataxia telangiectasia and Rad3 related (ATR) and poly (ADP-ribose) polymerase (PARP). Thus, deficiencies in the Mre11-dependent DDR drive proliferation and genome instability patterns in p53-deficient breast cancers and represent an opportunity for therapeutic exploitation.

SIRT6 is a DNA double-strand break sensor.

DNA double-strand breaks (DSB) are the most deleterious type of DNA damage. In this work, we show that SIRT6 directly recognizes DNA damage through a tunnel-like structure that has high affinity for DSB. SIRT6 relocates to sites of damage independently of signaling and known sensors. It activates downstream signaling for DSB repair by triggering ATM recruitment, H2AX phosphorylation and the recruitment of proteins of the homologous recombination and non-homologous end joining pathways. Our findings indicate that SIRT6 plays a previously uncharacterized role as a DNA damage sensor, a critical factor in initiating the DNA damage response (DDR). Moreover, other Sirtuins share some DSB-binding capacity and DDR activation. SIRT6 activates the DDR before the repair pathway is chosen, and prevents genomic instability. Our findings place SIRT6 as a sensor of DSB, and pave the road to dissecting the contributions of distinct DSB sensors in downstream signaling.

Poly-glycine\u2013alanine exacerbates C9orf72 repeat expansion-mediated DNA damage via sequestration of phosphorylated ATM and loss of nuclear hnRNPA3

Repeat expansion in C9orf72 causes amyotrophic lateral sclerosis and frontotemporal lobar degeneration. Expanded sense and antisense repeat RNA transcripts in C9orf72 are translated into five dipeptide-repeat proteins (DPRs) in an AUG-independent manner. We previously identified the heterogeneous ribonucleoprotein (hnRNP) A3 as an interactor of the sense repeat RNA that reduces its translation into DPRs. Furthermore, we found that hnRNPA3 is depleted from the nucleus and partially mislocalized to cytoplasmic poly-GA inclusions in C9orf72 patients, suggesting that poly-GA sequesters hnRNPA3 within the cytoplasm. We now demonstrate that hnRNPA3 also binds to the antisense repeat RNA. Both DPR production and deposition from sense and antisense RNA repeats are increased upon hnRNPA3 reduction. All DPRs induced DNA double strand breaks (DSB), which was further enhanced upon reduction of hnRNPA3. Poly-glycine–arginine and poly-proline-arginine increased foci formed by phosphorylated Ataxia Telangiectasia Mutated (pATM), a major sensor of DSBs, whereas poly-glycine–alanine (poly-GA) evoked a reduction of pATM foci. In dentate gyri of C9orf72 patients, lower nuclear hnRNPA3 levels were associated with increased DNA damage. Moreover, enhanced poly-GA deposition correlated with reduced pATM foci. Since cytoplasmic pATM deposits partially colocalized with poly-GA deposits, these results suggest that poly-GA, the most frequent DPR observed in C9orf72 patients, differentially causes DNA damage and that poly-GA selectively sequesters pATM in the cytoplasm inhibiting its recruitment to sites of DNA damage. Thus, mislocalization of nuclear hnRNPA3 caused by poly-GA leads to increased poly-GA production, which partially depletes pATM, and consequently enhances DSB.

Genetic interaction between DNA repair factors PAXX, XLF, XRCC4 and DNA-PKcs in human cells.

DNA double‐strand breaks (DSBs) are highly cytotoxic lesions, and unrepaired or misrepaired DSBs can lead to various human diseases, including immunodeficiency, neurological abnormalities, growth retardation, and cancer. Nonhomologous end joining (NHEJ) is the major DSB repair pathway in mammals. Ku70 and Ku80 are DSB sensors that facilitate the recruitment of downstream factors, including protein kinase DNA‐dependent protein kinase, catalytic subunit (DNA‐PKcs), structural components [X‐ray repair cross‐complementing protein 4 (XRCC4), XRCC4‐like factor (XLF), and paralogue of XRCC4 and XLF (PAXX)], and DNA ligase IV (LIG4), which complete DNA repair. DSBs also trigger the activation of the DNA damage response pathway, in which protein kinase ataxia‐telangiectasia mutated (ATM) phosphorylates multiple substrates, including histone H2AX. Traditionally, research on NHEJ factors was performed using in vivo mouse models and murine cells. However, the current knowledge of the genetic interactions between NHEJ factors in human cells is incomplete. Here, we obtained genetically modified human HAP1 cell lines, which lacked one or two NHEJ factors, including LIG4, XRCC4, XLF, PAXX, DNA‐PKcs, DNA‐PKcs/XRCC4, and DNA‐PKcs/PAXX. We examined the genomic instability of HAP1 cells, as well as their sensitivity to DSB‐inducing agents. In addition, we determined the genetic interaction between XRCC4 paralogues (XRCC4, XLF, and PAXX) and DNA‐PKcs. We found that in human cells, XLF, but not PAXX or XRCC4, genetically interacts with DNA‐PKcs. Moreover, ATM possesses overlapping functions with DNA‐PKcs, XLF, and XRCC4, but not with PAXX in response to DSBs. Finally, NHEJ‐deficient HAP1 cells show increased chromosomal and chromatid breaks, when compared to the WT parental control. Overall, we found that HAP1 is a suitable model to study the genetic interactions in human cells.

A P53-Independent DNA Damage Response Suppresses Oncogenic Proliferation and Genome Instability

SummaryThe Mre11-Rad50-Nbs1 complex is a DNA double strand break sensor that mediates a tumor suppressive DNA damage response (DDR) in cells undergoing oncogenic stress, yet the mechanisms underlying this effect are poorly understood. Using a novel genetically inducible mammary epithelial cell model, we demonstrate that Mre11 suppresses proliferation and DNA damage induced by diverse oncogenic drivers through a p53-independent mechanism. Expression of a hypomorphic mutant allele of Mre11 exacerbates oncogene-driven increases in R-loops and results in a copy number loss phenotype enriched in gene-coding regions that is revealed by whole genome sequencing of mammary hyperplasia and breast tumors. Mre11 complex dysfunction is identified in a subset of human triple-negative breast cancers, and is associated with increased sensitivity to DNA damaging therapy and inhibitors of ATR and PARP. Thus, deficiencies in the Mre11-dependent DDR drive proliferation and genome instability patterns in p53-deficient breast cancers, and represent an opportunity for therapeutic exploitation.

Hypovitaminosis D exacerbates the DNA damage load in human uterine fibroids, which is ameliorated by vitamin D3 treatment.

Uterine fibroids (UFs) are the most common benign neoplastic threat to women's health and associated with DNA damage and genomic instability. Hypovitaminosis D is a known risk factor for UFs, especially among African Americans. Vitamin D3 has been shown to effectively inhibit UF phenotype, but its mechanisms remain unclear. We hypothesize that Vitamin D3 ameliorates UFs by recovering the damaged DNA repair system, thus inhibits tumor progression. We compared the DNA damage status and Vitamin D receptor (VDR) expression between normal myometrial and UF primary cells. Unrepaired DNA double-strand breaks (DSBs) accumulated but VDR expression decreased in UFs. The RNA and protein levels of key DNA repair members belonging to DNA DSB sensors (MRE11, NBS1, RAD50), mediators and effectors (CHECK2, BRCA1, RAD51) were downregulated in UFs compared with myometrial cells. VDR KD induced DSB accumulation and DNA damage response (DDR) defects in myometrial cells. Using the DNA damage PCR array, the expression of many additional DNA repair genes was downregulated in VDR KD cells. Treatment of UF cells with Vitamin D3 (100 nM) significantly decreased DNA damage and restored DDR concomitant with VDR induction. Notably, the PCR array demonstrated that among 75 downregulated genes after VDR KD, 67 (89.3%) were upregulated after vitamin D3 treatment. These studies demonstrate a novel link between DNA damage and the vitamin D3/VDR axis in UFs. Vitamin D3 suppresses the UF phenotype through orchestrated targeting at multiple molecules in DNA repair pathways, thus offering novel mechanistic insights into the clinical effectiveness of vitamin D3 on UFs.