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:The H.pylori CagA oncoprotein induces replication fork collapse and DNA double strand breaks through Fanconi Anemia pathway downregulation

Project description:Helicobacter pylori (H.pylori) infection is a significant risk factor for gastric cancer (GC) development. A growing body of evidence suggests a causal link between infection with H.pylori and increased DNA breakage in the host cells. While several mechanisms have been proposed for this damage, their relative impact on the overall bacterial genotoxicity is unknown. Moreover, the link between the formation of DNA damage following infection and the emergence of cancerous structural variants (SV) in the genome of infected cells remained unexplored. To resolve these gaps, we constructed high-resolution map of genomic H.pylori-induced recurrent break sites. Our data indicated that these sites are ubiquitous across cell types, localized at replication-related fragile sites, and their breakage is dependent on replication. Consistent with that, we found that H.pylori inflicts nucleotide depletion, and that rescuing the nucleotide pool largely reduced H.pylori-induced DNA breaks. Intriguingly, we found that this genotoxic mechanism operates independently of the H.pylori virulence factor, CagA, which was previously implicated in increasing DNA damage by downregulating the DNA damage response. Finally, we show that sites of recurrent H.pylori-mediated breaks coincide with chromosomal deletions observed in patients with intestinal-type GC, and that this link potentially elucidates the persistent transcriptional alterations observed in cancer driver genes. These findings establish the link between H.pylori genotoxicity, and its oncogenic potential.

Project description:Helicobacter pylori infection promotes chronic inflammation and plethora of DNA damages including strand breaks, base alterations, point mutations, microsatellite instability and epigenetic alterations. The gastric epitheliaI cells, in order to prevent genomic instability, require an integrous DNA damage repair (DDR) machinery which, however, has been reported to be modulated by the infection. CagA is a major Hp virulence factor that deregulates host cell functions such as proliferation, apoptosis and chromosomal integrity. Its pathogenic activity is partly regulated by tyrosine phosphorylation on repeated EPIYA-motifs. Our aim was to identify putative effects of H. pylori infection and CagA protein on DDR machinery, investigating the transcriptome of AGS cells, infected with P12 H. pylori wild-type strain, as well as, its corresponding CagA knock-out and the CagA phosphorylation-defective mutant following tyrosine (EPIYA) substitution by phenylalanine (EPIFA) in the EPIYA-C motifs. Upon RNA-Sequencing on polyA-selected transcripts we performed Differential Expression Analysis, Pathway Enrichment Analysis and visualization on KEGG Pathway Maps per DDR mechanism. Key DDR components that were observed to be downregulated in a CagA-related manner were validated via Western Blot utilizing AGS and the non-cancerous GES1 cell lines. Transcriptome analysis revealed that a notable number of DDR genes were downregulated during H. pylori infection resulting to potential modulation of Base Excision Repair, Mismatch Repair and a more intricate deregulation of Nucleotide Excision Repair, Homologous Recombination and Non-Homologous End-Joining. CagA contributes to MUTYH, FEN1, APE1, POLD1 and LIG1 downregulation and those observations were verified on the protein expression level, with the exception of APE1 that was on contrary observed to be upregulated. Our study accentuates the role of CagA, as a significant contributor of the H. pylori infection-mediated DDR modulation, disrupting the balance between DNA damage introduction and repair thus favoring genomic instability and potentially contributing to gastric carcinogenesis.

Project description:Comprehensive analysis of microRNA expression were performed with 238 rat genes of microRNA between CagA-expressing and -non-expressing cells. CagA expression was controlled by tetracycline-off system in RGM1 cells.

Project description:Comprehensive analysis of microRNA expression were performed with 238 rat genes of microRNA between CagA-expressing and -non-expressing cells. CagA expression was controlled by tetracycline-off system in RGM1 cells. In the study presented here, RGM1 cells were used to acquire expression profiles of 238 microRNA genes.

Project description:In this study, cultured H.pylori was used to infect the normal gastric epithelial cell line GES-1, to construct the H.pylori infection model. lncRNA microarray was applied for detecting the lncRNA in H.pylori infection model.

Project description:Helicobacter pylori(H. pylori), a gastrointestinal pathogen, is known to increase the risk of gastric cancer by activating chronic pro-inflammatory signaling pathways in epithelial cells. Cytotoxin-related protein A (CagA) is known to play an important role in gastric cancer development. CagA has been reported to induce tumors by inducing overexpression of YAP/TAZ, a component of Hippo signaling, and dysregulation of the pathway, thereby promoting cell proliferation and resistance to apoptosis. However, the role of H.pylori-mediated YAP/TAZ has not yet been fully investigated. Our study aimed to investigate the role of YAP/TAZ in H.pylori-mediated Hippo pathway dysregulation in gastric carcinogenesis using H.pylori-infected gastric cancer cell lines, knockout mice, and patient-derived organoids. CagA-mediated YAP overexpression in gastric epithelial cells induced intestinal epithelial metaplasia and induced intracellular rearrangement of the binding protein ZO1, thereby conferring cell motility.

Project description:The NEIL3 DNA glycosylase is a base excision repair enzyme that excises bulky base lesions from DNA. Although NEIL3 has been shown to unhook interstrand crosslinks (ICL) in Xenopus extracts, how NEIL3 participants in ICL repair in human cells and its corporation with the canonical Fanconi anemia (FA)/BRCA pathway remain unclear. Here we show that the NEIL3 and the FA/BRCA pathways are non-epistatic in psoralen-ICL repair. The NEIL3 pathway is the major pathway for repairing psoralen-ICL, and the FA/BRCA pathway is only activated when NEIL3 is not present. Mechanistically, NEIL3 is recruited to psoralen-ICL in a rapid, PARP-dependent manner. Importantly, the NEIL3 pathway repairs psoralen-ICLs without generating double-strand breaks (DSBs), unlike the FA/BRCA pathway. In addition, we found that the RUVBL1/2 complex physically interact with NEIL3 and function within the NEIL3 pathway in psoralen-ICL repair. Moreover, TRAIP is important for the recruitment of NEIL3 but not FANCD2, and knockdown of TRAIP promotes FA/BRCA pathway activation. Interestingly, TRAIP is non-epistatic with both NEIL3 and FA pathways in psoralen-ICL repair, suggesting that TRAIP may function upstream of the two pathways. Taken together, the NEIL3 pathway is the major pathway to repair psoralen-ICL through a unique DSB-free mechanism in human cells.

Project description:The twenty-three Fanconi Anemia proteins cooperate in a DNA repair pathway, called the FA/BRCA pathway, required for the monoubiquitination of FANCD2 and the excision of interstrand DNA crosslinks (ICLs). The CCAR1 (cell division cycle and apoptosis regulator 1) protein is also a regulator of ICL repair, though its possible function in the FA/BRCA pathway remains unknown. Here, we demonstrate that CCAR1 plays a unique upstream role in the FA/BRCA pathway and is required for FANCA protein expression and FANCD2 monoubiquitination. Interestingly, loss of CCAR1 results in retention of a poison exon in the FANCA transcript, thereby leading to reduced FANCA protein expression. A unique domain of CCAR1, the so-called EF-hand domain, binds to the spliceosome SF3B complex and is required for its mRNA splicing activity. Taken together, CCAR1 is a unique splicing factor, required for normal splicing of the FANCA mRNA and perhaps other mRNAs involved in various cellular pathways.