Project description:DNA replication forks that are stalled by DNA damage activate an S phase checkpoint that prevents irreversible fork arrest and cell death. The increased cell death caused by DNA damage in budding yeast cells lacking the Rad53 checkpoint protein kinase is partially suppressed by deletion of the EXO1 gene. Here,we identified that loss of the histone deacetylase complex Rpd3L promotes survival of rad53∆ cells exposed to DNA damaging agents. From epistasis analysis, we show that this suppression operates in a separate pathway from the previously described suppression by deletion of EXO1.

Project description:Transcription-replication conflicts (TRCs) can provoke genome instability. Progressing transcription and replication machineries profoundly impact their underlying chromatin template and thus, conflict sites are vulnerable to chromatin and epigenome alterations. Here, we engineered an inducible TRC reporter system using a genome-integrated R-loop-prone sequence. Using this system, we characterized the dynamic changes of the local chromatin structure inflicted by TRCs, leading to reduced nucleosome occupancy and replication fork blockage. Consequently, inducing a handful TRCs on the genome results in a measurable global replication stress response. We also find a TRC-specific increase in H3K79 methylation at the R-loop forming TRC-site. Accordingly, inhibition of the H3K79 methyltransferase DOT1L leads to increased cellular TRCs and exacerbated DNA damage response, suggesting that deposition of this mark is required for effective detection and resolution of TRCs. Thus, our work highlights the molecular dynamics and reveals specific epigenetic modifiers bookmarking TRC sites, relevant to cancer and other diseases.

Project description:Transcription-replication conflicts (TRCs) can provoke genome instability. Progressing transcription and replication machineries profoundly impact their underlying chromatin template and thus, conflict sites are vulnerable to chromatin and epigenome alterations. Here, we engineered an inducible TRC reporter system using a genome-integrated R-loop-prone sequence. Using this system, we characterized the dynamic changes of the local chromatin structure inflicted by TRCs, leading to reduced nucleosome occupancy and replication fork blockage. Consequently, inducing a handful TRCs on the genome results in a measurable global replication stress response. We also find a TRC-specific increase in H3K79 methylation at the R-loop forming TRC-site. Accordingly, inhibition of the H3K79 methyltransferase DOT1L leads to increased cellular TRCs and exacerbated DNA damage response, suggesting that deposition of this mark is required for effective detection and resolution of TRCs. Thus, our work highlights the molecular dynamics and reveals specific epigenetic modifiers bookmarking TRC sites, relevant to cancer and other diseases.

Project description:Transcription-replication conflicts (TRCs) can provoke genome instability. Progressing transcription and replication machineries profoundly impact their underlying chromatin template and thus, conflict sites are vulnerable to chromatin and epigenome alterations. Here, we engineered an inducible TRC reporter system using a genome-integrated R-loop-prone sequence. Using this system, we characterized the dynamic changes of the local chromatin structure inflicted by TRCs, leading to reduced nucleosome occupancy and replication fork blockage. Consequently, inducing a handful TRCs on the genome results in a measurable global replication stress response. We also find a TRC-specific increase in H3K79 methylation at the R-loop forming TRC-site. Accordingly, inhibition of the H3K79 methyltransferase DOT1L leads to increased cellular TRCs and exacerbated DNA damage response, suggesting that deposition of this mark is required for effective detection and resolution of TRCs. Thus, our work highlights the molecular dynamics and reveals specific epigenetic modifiers bookmarking TRC sites, relevant to cancer and other diseases.

Project description:Chromatin is dynamically reorganized when DNA replication forks are challenged. However, the process of epigenetic reorganization and its implication for fork stability is poorly understood. Here, we discover a checkpoint regulated cascade of chromatin signaling that activates 5 the histone methyltransferase EHMT2/G9a to catalyze heterochromatin assembly at stressed replication forks. Using biochemical and single molecule chromatin fiber approaches, we show that G9a together with SUV39h1 induces chromatin compaction by accumulating the repressive modifications, H3K9me1/me2/me3, in the vicinity of stressed replication forks. This closed conformation is also favored by the G9a-dependent exclusion of the H3K9-demethylase 10 JMJD1A/KDM3A, which facilitates heterochromatin disassembly upon fork restart. Untimely heterochromatin disassembly from stressed forks by KDM3A enables PRIMPOL access, triggering ssDNA gap formation and sensitizing cells towards chemotherapeutic drugs. These findings may help explaining chemotherapy resistance and poor prognosis observed in cancer patients displaying elevated level of G9a/H3K9me3.

Project description:Dynamic recycling and de novo deposition of histones are fundamental for chromatin restoration. Histone post-translational modifications (PTMs) are assumed to have a causal role in establishing distinct chromatin structures. However, it remains unknown how specific histone PTMs are regulated at broken replication fork. To get better insight into histone PTMs during DNA damage response, we combined NCC (Nascent chromatin capture) with SILAC-MS for identification of histone PTMs at replication forks upon CPT (camptothecin).

Project description:The proteins from the Fanconi Anemia (FA) pathway of DNA repair maintain DNA replication fork integrity by preventing the unscheduled degradation of nascent DNA at regions of stalled replication forks. Here, we ask if the bacterial pathogen H. pylori exploits the fork stabilisation machinery to generate double stand breaks (DSBs) and genomic instability. Specifically, we study if the H. pylori virulence factor CagA generates host genomic DSBs through replication fork destabilisation and collapse. An inducible gastric cancer model was used to examine global CagA-dependent transcriptomic and proteomic alterations, using RNA sequencing and SILAC-based mass spectrometry, respectively. The transcriptional alterations were confirmed in gastric cancer cell lines infected with H. pylori. Functional analysis was performed using chromatin fractionation, pulsed-field gel electrophoresis (PFGE), and single molecule DNA replication/repair fiber assays. We found a core set of 31 DNA repair factors including the FA genes FANCI, FANCD2, BRCA1, and BRCA2 that were downregulated following CagA expression. H. pylori infection of gastric cancer cell lines showed downregulation of the aforementioned FA genes in a CagA-dependent manner. Consistent with FA pathway downregulation, chromatin purification studies revealed impaired levels of Rad51 but higher recruitment of the nuclease MRE11 on the chromatin of CagA-expressing cells, suggesting impaired fork protection. In line with the above data, fibre assays revealed higher fork degradation, lower fork speed, daughter strands gap accumulation, and impaired re-start of replication forks in the presence of CagA, indicating compromised genome stability. By downregulating the expression of key DNA repair genes such as FANCI, FANCD2, BRCA1, and BRCA2, H. pylori CagA compromises host replication fork stability and induces DNA DSBs through fork collapse. These data unveil an intriguing example of a bacterial virulence factor that induces genomic instability by interfering with the host replication fork stabilisation machinery.

Project description:Methylated H3K4 (H3K4me) is highly conserved and has been widely considered to be involved in transcriptional control. However, this once popular model was recently challenged by multiple groups, because blocking this modification does not appreciably affect transcription. Thus, the function of the H3K4me remains unclear. To investigate how H3K4 methylation influences the processes of transcription and replication under HU-stress, we used chromatin immunoprecipitation-sequencing (ChIP-seq) to identify genomic sites of active transcription marked by Rpb3, a subunit of RNA Polymerase II, and sites of replication pausing marked by DNA Pol2, a subunit of DNA Polymerase e. Our data lead us to the surprising conclusion that H3K4me pauses the progression of replication forks, and we propose that high levels of H3K4me deposited by high transcriptional activity result in a large cushioning effect on fork progression to protect against transcription-replication collisions (TRCs), which cause genome instability.

Project description:Deregulation of RNA Polymerase II (RNAPII) by oncogenic signaling leads to collisions of RNAPII with DNA synthesis machinery (transcription-replication conflicts, TRCs). TRCs can result in DNA damage and underlie genomic instability in tumor cells. Here we provide evidence that elongating RNAPII promotes activation of the ATM kinase at TRCs to drive DNA repair. We show the ATPase Wrnip1 that binds and protects stalled replication forks, associates with RNAPII and limits ATM activation. Wrnip1 binding to elongating RNAPII requires catalytic activity of the ubiquitin ligase Huwe1. Mutation of Huwe1 promotes the transfer of Wrnip1 onto replisome and induces TRCs stimulating ATM activation on RNAPII. This mechanism is evoked early upon replicative stress to induce Wrnip1 translocation and ATM signaling at TRCs. Thus, although primarily considered as genotoxic events, TRCs can provide a mechanism to maintain genome stability under replicative stress.

Project description:Deregulation of RNA Polymerase II (RNAPII) by oncogenic signaling leads to collisions of RNAPII with DNA synthesis machinery (transcription-replication conflicts, TRCs). TRCs can result in DNA damage and underlie genomic instability in tumor cells. Here we provide evidence that elongating RNAPII promotes activation of the ATM kinase at TRCs to drive DNA repair. We show the ATPase Wrnip1 that binds and protects stalled replication forks, associates with RNAPII and limits ATM activation. Wrnip1 binding to elongating RNAPII requires catalytic activity of the ubiquitin ligase Huwe1. Mutation of Huwe1 promotes the transfer of Wrnip1 onto replisome and induces TRCs stimulating ATM activation on RNAPII. This mechanism is evoked early upon replicative stress to induce Wrnip1 translocation and ATM signaling at TRCs. Thus, although primarily considered as genotoxic events, TRCs can provide a mechanism to maintain genome stability under replicative stress.