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:ATP-dependent chromatin remodelers are commonly mutated in human cancer. Mammalian SWI/SNF complexes comprise three conserved multi-subunit chromatin remodelers (cBAF, ncBAF and PBAF) that share the BRG1 (also known as SMARCA4) subunit responsible for the main ATPase activity. BRG1 is the most frequently mutated Snf2-like ATPase in cancer. Here we have investigated the role of SWI/SNF in genome instability, a hallmark of cancer cells, given its role in transcription, DNA replication and DNA damage repair. We show that depletion of BRG1 increases R-loops and R-loop-dependent DNA breaks, as well as transcription-replication conflicts. BRG1 colocalizes with R-loops and replication fork blocks, as determined by FANCD2 foci, with BRG1 depletion being epistatic to FANCD2 silencing. Our study, extended to other components of SWI/SNF, uncovers a key role of the SWI/SNF complex, in particular cBAF, in helping resolve R-loop-mediated transcription-replication conflicts; thus, unveiling a novel mechanism by which chromatin remodeling protects genome integrity.

Project description:Oncogene-induced replication stress constitutes an early obstacle for pre-cancerous cells to overcome to progress towards malignancy. Fanconi anaemia signalling represents a major genomic maintenance pathway that is activated in response to replication stress, impinging on stalled replication fork stability and recovery. Here, we report that upon replication stress, phosphorylation of the FANCD2 N-terminus by CHK1 triggers FBXL12-dependent proteasomal degradation of FANCD2, facilitating clearance of FANCD2 at stalled replication forks. This mechanism is required to promote efficient and faithful DNA replication under conditions of CYCLIN E- and drug-induced replication stress. Notably, reconstitution of FANCD2 with mutations in the N-terminal phosphodegron fail to re-establish fork progression in FANCD2-deficient human fibroblasts in response to replication stress. In the absence of FBXL12, FANCD2 becomes trapped on chromatin leading to replication stress, excessive DNA damage, and cell death. In human cancers, FBXL12, CYCLIN E, and Fanconi anaemia signalling are positively correlated and upregulation or amplification of FBXL12 is linked to reduced survival in patients with high CYCLIN E expressing breast tumours. Finally, depletion of FBXL12 exacerbated oncogene-induced replication stress and sensitised breast cancer cells to drug-induced replication stress by WEE1 inhibition. Collectively, our results indicate that FBXL12 constitutes a vulnerability of CYCLIN E-overexpressing cancer cells and may represent a novel target for cancer therapy.

Project description:The sources of genome instability, a hallmark of cancer, remain incompletely understood. One potential source is DNA re-replication, which arises when the mechanisms that prevent re-initiation of replication origins within a single cell cycle are compromised. Using the budding yeast Saccharomyces cerevisiae, we previously showed that DNA re-replication is extremely potent at inducing gross chromosomal alterations and that this arises in part because of the susceptibility of re-replication forks to break. Here, we examine the ability of DNA re-replication to induce nucleotide level mutations. During normal replication these mutations are restricted by three overlapping error avoidance mechanisms: the nucleotide selectivity of replicative polymerases, their proofreading activity, and mismatch repair. Using lys2InsEA14, a frameshift reporter that is poorly proofread, we show that re-replication induces up to a 30x higher rate of frameshift mutations and that this mutagenesis is due to passage of the re-replication fork, not secondary to re-replication fork breakage. Re-replication can also induce comparable rates of frameshift and base substitution mutations in a more general mutagenesis reporter CAN1, when the proofreading activity of DNA polymerase ε is inactivated. Finally, we show that the induction of lys2InsEA14 frameshift mutations by re-replication is dependent on mismatch repair. These results suggest that the mismatch repair associated with re-replication is attenuated, although at most sequences DNA polymerase proofreading provides enough error correction to mitigate the mutagenic consequences. Thus, re-replication can facilitate nucleotide level mutagenesis in addition to inducing gross chromosomal alterations, broadening its potential role in genome instability.

Project description:DNA replication is a complex process tightly regulated to ensure faithful genome duplication, and its perturbation leads to DNA damage and genomic instability. Replication stress is commonly associated with slow and stalled replication forks. Recently, accelerated replication has emerged as a non-canonical form of replication stress. However, the molecular basis underlying fork acceleration is largely unknown. Here we show that mutated HRAS activation leads to increased topoisomerase 1 (TOP1) expression leading to aberrant replication fork acceleration and DNA damage by decreasing RNA-DNA hybrids or R-loops. In these cells, restoration of TOP1 expression or mild replication inhibition rescues the perturbed replication and reduces DNA damage. Furthermore, TOP1 or RNaseH1 overexpression induces accelerated replication and DNA damage, highlighting the importance of TOP1 equilibrium in regulating R-loop homeostasis to ensure faithful DNA replication and genome integrity. Altogether, our results reveal a novel mechanism of oncogene-induced DNA damage induced by aberrant replication fork acceleration.

Project description:Although H.pylori infection is known to induce host genomic double strand breaks, (DSBs), the role of CagA, a central virulence factor with oncogenic properties in DSB generation remains unclear. Here, using transcriptomic and proteomic analyses, we show that CagA downregulates the expression of major DNA repair factors such as FANCD2, BRCA1 and BRCA2 of the Fanconi Anemia (FA) pathway of DNA repair and leads to compromised host replication fork speed, stability and toxic DSB induction. Our results highlight the mechanism of CagA-mediated genome instability at the level of replication forks and can be used to devise strategies that mitigate the genotoxic effects of H.pylori-infection.

Project description:R-loops are three-stranded nucleic acid structures composed of an RNA:DNA hybrid and displaced DNA strand. These structures can halt DNA replication when formed co- transcriptionally in the opposite orientation to replication fork progression. Recent studies have shown that replication forks stalled by co-transcription R-loops can be restarted by a mechanism involving fork cleavage by MUS81 endonuclease, followed by reactivation of transcription, and fork religation by the DNA ligase IV (LIG4)/XRCC4 complex. However, how R-loops are eliminated to allow the sequential restart of transcription and replication in this pathway remains elusive. Here, we identified the human DDX17 helicase as a factor that associates with R-loops and counteracts R-loop-mediated replication stress to preserve genome stability. We show that DDX17 unwinds RNA:DNA hybrids in vitro and promotes MUS81-dependent restart of R-loop-stalled forks in human cells in a manner dependent on its helicase activity. Loss of DDX17 helicase induces accumulation of R-loops and the formation of R-loop-dependent anaphase bridges and micronuclei. These findings establish DDX17 as a component of the MUS81-LIG4 pathway for resolution of R-loop-mediated transcription- replication conflicts, which may be involved in R-loop unwinding.

Project description:Non-scheduled R loops represent a major source of DNA damage and replication stress. Cells have different ways to prevent R loop accumulation. One mechanism relies on the conserved THO complex in association with co-transcriptional RNA processing factors including the RNA-dependent ATPase UAP56/DDX39B and histone modifiers such as the SIN3 deacetylase in humans. We investigated the function of UAP56/DDX39B in R loop removal. We show that UAP56 depletion causes R loop accumulation, R loop-mediated genome instability and replication fork stalling. We demonstrate an RNA-DNA helicase activity in UAP56 and that its overexpression suppresses R loops and genome instability induced by depleting 5 different unrelated factors. UAP56/DDX39B localizes to active chromatin and prevents the accumulation of RNA-DNA hybrids over the entire genome. We propose that, in addition to its RNA processing role, UAP56/DDX39B is a key helicase required to eliminate harmful co-transcriptional RNA structures that otherwise would block transcription and replication.

Project description:To ensure efficient genome duplication, cells have evolved a multitude of factors that promote unperturbed DNA replication, and protect, repair and restart damaged forks. Here we identify DONSON as a novel fork protection factor, and report biallelic DONSON mutations in individuals with microcephalic dwarfism. We demonstrate that DONSON is a component of the replisome that stabilises forks during normal genome replication. Loss of DONSON leads to severe replication-associated DNA damage arising from nucleolytic cleavage of stalled replication forks. Furthermore, ATR-dependent ,signalling in response to replication stress is impaired in DONSON-deficient cells, resulting in decreased checkpoint activity, and potentiating chromosomal instability. Hypomorphic mutations substantially reduce DONSON protein levels and impair fork stability in patient cells, consistent with defective DNA replication underlying the disease phenotype In summary, we identify mutations in DONSON as a common cause of microcephalic dwarfism, and establish DONSON as a critical replication fork protein required for mammalian DNA replication and genome stability

Project description:Oncogene-induced replication stress constitutes an early obstacle for pre-cancerous cells to overcome to progress towards malignancy. Fanconi anaemia signalling represents a major genomic maintenance pathway that is activated in response to replication stress, impinging on stalled replication fork stability and recovery. We report that upon replication stress, phosphorylation of the FANCD2 N-terminus by CHK1 triggers FBXL12-dependent proteasomal degradation of FANCD2, facilitating clearance of FANCD2 at stalled replication forks and promoting replication recovery. Monoubiquitination of FANCD2 at K561 by the Fanconi anaemia core complex regulates clamping of the FANCD2-FANCI heterodimer onto DNA. To investigate if K561-monoubiquitination influences FANCD2 phosphorylation and/or polyubiquitination by FBXL12, we performed MS-based proteomics using HEK293 cells co-transfected with the monoubiquitin-deficient FANCD2 mutant (K561R) and FANCI, or a CHK1 phosphorylation-deficient FANCD2-AA (S8A/S10A) mutant as control. To induce rapid activation of CHK1, we inhibited WEE1 kinase using AZD1775, immunoprecipitated FANCD2 from chromatin extracts and performed MS analysis. The MS data revealed several phosphorylated N-terminal peptides in the K561R-FANCD2 sample, including S8, S10 and also S15 demonstrating that K561R is phosphorylated in response to replication stress induced by AZD1775.