Project description:MePCE is a multifunctional protein that regulates the Positive Transcription Elongation Factor b (P-TEFb) partitioning between the nucleosol and chromatin. While the role of MePCE in sequestering P-TEFb in the nucleoplasm through the 7SK ribonuclear protein complex (RNPc) is well understood, its functions on chromatin remain obscure. In order to address this gap in our knowledge, we performed mass spectrometry of MePCE interactors on chromatin. Our analysis revealed that chromatin-associated-MePCE mainly interacts with factors involved in R-loop processing and DNA repair factors. Consistent with this initial finding, MePCE is rapidly recruited to laser-mediated DNA damage and AsiSI-mediated DNA double stranded breaks (DSBs). Moreover, MePCE depletion specifically impairs DSB repair by homologous recombination (HR). To explore the molecular mechanism behind the observed HR defect, we took advantage of an inducible AsiSI system to analyze the effect of MePCE depletion in DSB repair factor recruitment and R-loop levels at over 100 genomic site-specific DSBs. Consistent with impaired HR, MePCE depletion decreases RAD51 loading and enhances R-loop levels specifically at DSBs. Analysis of R-loop protein complexes by mass spectrometry revealed that in addition to decreasing specific R-loop processing factors and chromatin remodelers, MePCE depletion increased the interaction with R-loops of the other constitutive member of the 7SK RNPc, LARP7, which is degraded by BRCA1/BARD1 upon DSB. Overall, our results uncover dynamic regulation of the 7SK RNPc at DSBs during the repair process and explain the recently observed synthetic lethality of MePCE and BRCA1 deficiency.

Project description:MePCE is a multifunctional protein that regulates the Positive Transcription Elongation Factor b (P-TEFb) partitioning between the nucleosol and chromatin. While the role of MePCE in sequestering P-TEFb in the nucleoplasm through the 7SK ribonuclear protein complex (RNPc) is well understood, its functions on chromatin remain obscure. In order to address this gap in our knowledge, we performed mass spectrometry of MePCE interactors on chromatin. Our analysis revealed that chromatin-associated-MePCE mainly interacts with factors involved in R-loop processing and DNA repair factors. Consistent with this initial finding, MePCE is rapidly recruited to laser-mediated DNA damage and AsiSI-mediated DNA double stranded breaks (DSBs). Moreover, MePCE depletion specifically impairs DSB repair by homologous recombination (HR). To explore the molecular mechanism behind the observed HR defect, we took advantage of an inducible AsiSI system to analyze the effect of MePCE depletion in DSB repair factor recruitment and R-loop levels at over 100 genomic site-specific DSBs. Consistent with impaired HR, MePCE depletion decreases RAD51 loading and enhances R-loop levels specifically at DSBs. Analysis of R-loop protein complexes by mass spectrometry revealed that in addition to decreasing specific R-loop processing factors and chromatin remodelers, MePCE depletion increased the interaction with R-loops of the other constitutive member of the 7SK RNPc, LARP7, which is degraded by BRCA1/BARD1 upon DSB. Overall, our results uncover dynamic regulation of the 7SK RNPc at DSBs during the repair process and explain the recently observed synthetic lethality of MePCE and BRCA1 deficiency.

Project description:Cells have developed effective mechanisms, namely homologous recombination (HR) and non-homologous end-joining (NHEJ), to repair DNA double-strand breaks (DSBs), which are considered to be the most deleterious type of damage that can challenge genome integrity. While these pathways coexist to repair DSBs, the mechanisms by which one of these pathways is chosen to repair a particular DSB remain unclear. Here, we show that the chromatin context in which a break occurs participates in this choice and that transcriptionnaly active chromatin channels repair to HR. By using a human cell line expressing a restriction enzyme fused to the ligand binding domain of the oestrogen receptor (AsiSI-ER)2,3, together with a genome wide chromatin immunoprecipitation-sequencing (ChIP-seq) approach, we establish that distinct DSBs induced across the genome are not necessarily repaired by the same pathway. Indeed, we identify an HR-prone subset of DSBs that recruit the HR protein RAD51, undergo resection, and rely on RAD51 for efficient repair. These DSBs are located in actively transcribed genes, and repair at such DSBs can be switched to RAD51-independent repair pathway upon transcriptional inhibition. Moreover, we show that HR is targeted to transcribed loci thanks to the elongation-associated H3K36me3 histone mark. Indeed depletion of HYPB, the main H3K36 tri methyltransferase severally impedes the use of HR at those DSBs. Our study, thereby demonstrates a clear role for chromatin in DSB repair pathway choice in human cells.

Project description:Successful R-loop homeostasis consists of its timely biogenesis and removal throughout the genome to regulate diverse cellular processes. Yet, they are considered hazardous source to our genome when their turnover goes awry. Here, we report HELZ, a novel player in R-loop homeostasis and DNA repair pathway. HELZ mediates resistance to several DNA damaging agents, and localizes to DSBs and its depletion increases R-loops fostering genomic instability. Loss of HELZ results in impaired homologous recombination (HR) due to R-loops accumulation, with an increase in classical-non-homologous end joining (c-NHEJ), suggesting a role for HELZ in regulating DSB repair pathway choice. Rad51 retention at DSBs is governed by HELZ mediated R-loop accumulation. Mechanistically, our data show that HELZ complexes with BRCA1 and facilitates its recruitment to DSBs in an R-loop dependent manner. Collectively, our data support a model in which HELZ recruits BRCA1 and facilitates R loop resolution at DSBs to promote HR and therefore maintains genome stability.

Project description:AT-rich interactive domain-containing protein 1A (ARID1A), a SWI/SNF chromatin remodeling complex subunit, is frequently mutated across various cancer entities. ARID1A contributes to DNA damage response pathways, and we previously reported that ARID1A loss is associated with mutational signatures linked to DNA repair defects. Here we show that ARID1A is promoting both DNA double-strand breaks (DSBs) repair pathways, non-homologous end-joining (NHEJ) and homologous recombination (HR). ARID1A is accumulated at DSBs after DNA damage and regulates the chromatin loop formation at DSB sites by interacting with the cohesin subunit RAD21 and CTCF insulator protein promoting their enrichment around the DSBs. Further analysis demonstrates that ARID1A’s involvement in DSB repair is accompanied by alterations of chromatin accessibility and distribution of activating histone marks at DSBs. ARID1A binds to and promotes the recruitment of the HDAC1 to control transcription repression at these DSBs. Altogether, ARID1A simultaneously regulates DSB repair and transcription silencing in transcriptionally active chromatin. ARID1A depletion resulted in defective DSB repair, which subsequently led to accumulation of micronuclei, activation of cGAS-STING pathway and an increased expression of immunomodulatory cytokines and chemokines upon IR treatment. Furthermore, low ARID1A expression in cancer patients receiving radiotherapy was associated with higher infiltration of several immune cells. The high mutation rate of ARID1A in various cancer types highlights its clinical relevance as a promising biomarker that correlates with the level of immune regulatory cytokines and can estimate the levels of tumor-infiltrating immune cells and response to combination of radio- and immunotherapy.

Project description:AT-rich interactive domain-containing protein 1A (ARID1A), a SWI/SNF chromatin remodeling complex subunit, is frequently mutated across various cancer entities. ARID1A contributes to DNA damage response pathways, and we previously reported that ARID1A loss is associated with mutational signatures linked to DNA repair defects. Here we show that ARID1A is promoting both DNA double-strand breaks (DSBs) repair pathways, non-homologous end-joining (NHEJ) and homologous recombination (HR). ARID1A is accumulated at DSBs after DNA damage and regulates the chromatin loop formation at DSB sites by interacting with the cohesin subunit RAD21 and CTCF insulator protein promoting their enrichment around the DSBs. Further analysis demonstrates that ARID1A’s involvement in DSB repair is accompanied by alterations of chromatin accessibility and distribution of activating histone marks at DSBs. ARID1A binds to and promotes the recruitment of the HDAC1 to control transcription repression at these DSBs. Altogether, ARID1A simultaneously regulates DSB repair and transcription silencing in transcriptionally active chromatin. ARID1A depletion resulted in defective DSB repair, which subsequently led to accumulation of micronuclei, activation of cGAS-STING pathway and an increased expression of immunomodulatory cytokines and chemokines upon IR treatment. Furthermore, low ARID1A expression in cancer patients receiving radiotherapy was associated with higher infiltration of several immune cells. The high mutation rate of ARID1A in various cancer types highlights its clinical relevance as a promising biomarker that correlates with the level of immune regulatory cytokines and can estimate the levels of tumor-infiltrating immune cells and response to combination of radio- and immunotherapy.

Project description:Precise double-strand break (DSB) signaling and repair is paramount for maintaining genome stability. Homologous recombination (HR) is the chosen DSB repair pathway when cyclin-dependent kinase (CDK) activity is high, as it correlates well with the availability of an intact sister chromatid to be used as a template. However, the late stages of mitosis, anaphase and telophase, are paradoxical scenarios since high CDK levels favor HR repair despite sister chromatids being no longer aligned. To identify factors that specifically are involved in DSB repair in late mitosis, we have now undertaken a comparative proteomic analysis in Saccharomyces cerevisiae and found that Msc1, a poorly characterized protein previously identified as important in meiotic HR, is significantly enriched upon both random and guided DSBs. We further show that the knockout mutant for MSC1 is more sensitive to DSBs in late mitosis, and that msc1Δ has a delayed repair of DBSs as indicated by increased Rad53 hyperphosphorylation, fewer Rad52 repair factories and slower HR completion. We have found that Msc1 is an NE protein that faces the NE lumen and tends to form patches in nuclear halves that contain Rad52 factories. Either depletion or overexpression of Msc1 leads to DSB-independent abnormal nuclear morphologies in late mitosis, including blebbing, compartmentalization and premature signs of karyokinesis. In this regard, one of the two Msc1 orthologs in Schizosaccharomyces pombe, Les1, has been shown to regulate karyokinesis. We discuss how Msc1 may protect the late NE from abnormal events during DSB repair, providing a previously unreported link between NE homeostasis and DSB repair in late mitosis.

Project description:We have investigated whether components of Polycomb repressive complex 1 (PRC1) are recruited to double-strand breaks (DSBs) generated by inducible expression of the AsiSI restriction enzyme in normal human fibroblasts. Using chromatin immunoprecipitation and deep sequencing (ChIP-seq), which detects PRC1 proteins at common sites throughout the genome, we did not find evidence for recruitment of PRC1 components to AsiSI-induced DSBs. In contrast, the S2056 phosphorylated form of DNA-PKcs and other DNA repair proteins were detected at a subset of AsiSI sites that are predominantly at the 5’ ends of transcriptionally active genes. Our data question the idea that PcG protein recruitment provides a link between DSB repairs and transcriptional repression. Single chromatin preparations from treated and untreated cells (+/- OHT), immunoprecipitated with two antibodies (pDNA-PKcs and MEL18) were sequenced as technical replicates, along with the corresponding input DNAs

Project description:DNA double-strand breaks (DSBs) are highly cytotoxic DNA lesions, whose accurate repair by non-homologous end-joining (NHEJ) or homologous recombination (HR) is crucial for genome integrity and is strongly influenced by the local chromatin environment. Here, we identify SCAI (Suppressor of Cancer Cell Invasion) as a 53BP1-interacting chromatin-associated protein that promotes the functionality of several DSB repair pathways in mammalian cells. SCAI undergoes prominent enrichment at DSB sites through dual mechanisms involving 53BP1-dependent recruitment to DSB-surrounding chromatin and 53BP1-independent accumulation at resected DSBs. Cells lacking SCAI display reduced DSB repair capacity, hypersensitivity to DSB-inflicting agents and genome instability. We demonstrate that SCAI is a mediator of 53BP1-dependent repair of heterochromatin-associated DSBs, facilitating ATM kinase signaling at DSBs in repressive chromatin environments. Moreover, we establish an important role of SCAI in meiotic recombination, as SCAI deficiency in mice leads to germ cell loss and subfertility associated with impaired retention of the DMC1 recombinase on meiotic chromosomes. Collectively, our findings uncover SCAI as a physiologically important component of both NHEJ- and HR-mediated pathways that potentiates DSB repair efficiency in specific chromatin contexts.

Project description:We have investigated whether components of Polycomb repressive complex 1 (PRC1) are recruited to double-strand breaks (DSBs) generated by inducible expression of the AsiSI restriction enzyme in normal human fibroblasts. Using chromatin immunoprecipitation and deep sequencing (ChIP-seq), which detects PRC1 proteins at common sites throughout the genome, we did not find evidence for recruitment of PRC1 components to AsiSI-induced DSBs. In contrast, the S2056 phosphorylated form of DNA-PKcs and other DNA repair proteins were detected at a subset of AsiSI sites that are predominantly at the 5’ ends of transcriptionally active genes. Our data question the idea that PcG protein recruitment provides a link between DSB repairs and transcriptional repression.