ObjectiveHelicobacter pyloriinfection is the most prevalent bacterial infection worldwide. Besides being the most important risk factor for gastric cancer development, epidemiological data show that infected individuals harbour a nearly twofold increased risk to develop colorectal cancer (CRC). However, a direct causal and functional connection betweenH. pyloriinfection and colon cancer is lacking.DesignWe infected twoApc-mutant mouse models and C57BL/6 mice withH. pyloriand conducted a comprehensive analysis ofH. pylori-induced changes in intestinal immune responses and epithelial signatures via flow cytometry, chip cytometry, immunohistochemistry and single cell RNA sequencing. Microbial signatures were characterised and evaluated in germ-free mice and via stool transfer experiments.ResultsH. pyloriinfection accelerated tumour development inApc-mutant mice. We identified a uniqueH. pylori-driven immune alteration signature characterised by a reduction in regulatory T cells and pro-inflammatory T cells. Furthermore, in the intestinal and colonic epithelium,H. pyloriinduced pro-carcinogenic STAT3 signalling and a loss of goblet cells, changes that have been shown to contribute—in combination with pro-inflammatory and mucus degrading microbial signatures—to tumour development. Similar immune and epithelial alterations were found in human colon biopsies fromH. pylori-infected patients. Housing ofApc-mutant mice under germ-free conditions ameliorated, and early antibiotic eradication ofH. pyloriinfection normalised the tumour incidence to the level of uninfected controls.ConclusionsOur studies provide evidence thatH. pyloriinfection is a strong causal promoter of colorectal carcinogenesis. Therefore, implementation ofH. pyloristatus into preventive measures of CRC should be considered.
The gastric pathogen Helicobacter pylori infects half of the world’s population and is a major risk factor for gastric cancer development. In order to attach to human gastric epithelial cells and inject the oncoprotein CagA into host cells, H. pylori utilizes the outer membrane protein HopQ that binds to the cell surface protein CEACAM, which can be expressed on the gastric mucosa. Once bound, H. pylori activates a number of signaling pathways, including canonical and non-canonical NF-κB. We investigated whether HopQ–CEACAM interaction is involved in activating the non-canonical NF-κB signaling pathway. Different gastric cancer cells were infected with the H. pylori wild type, or HopQ mutant strains, and the activation of non-canonical NF-κB was related to CEACAM expression levels. The correlation between CEACAM levels and the activation of non-canonical NF-κB was confirmed in human gastric tissue samples. Taken together, our findings show that the HopQ–CEACAM interaction is important for activation of the non-canonical NF-κB pathway in gastric epithelial cells.
OBJECTIVE
H. pylori infection is the most prevalent bacterial infection worldwide. Besides being the most important risk factor for gastric cancer development, epidemiological data show that infected individuals harbor a nearly two-fold increased risk to develop colorectal cancer (CRC). However, a direct causal and functional connection between H. pylori infection and colon cancer is lacking.
DESIGN
We infected two Apc-mutant mouse models and C57BL/6 mice with H. pylori and conducted a comprehensive analysis of H. pylori-induced changes in intestinal immune responses and epithelial signatures via flow cytometry, chip cytometry, immunohistochemistry and single cell RNA sequencing. Microbial signatures were characterized and evaluated in germ-free mice and via stool transfer experiments.
RESULTS
H. pylori infection accelerated tumor development in Apc-mutant mice. We identified a unique H. pylori-driven immune alteration signature characterized by a reduction in regulatory T-cells and proinflammatory T-cells. Furthermore, in the intestinal and colonic epithelium, H. pylori induced pro-carcinogenic STAT3 signaling and a loss of goblet cells, changes that have been shown to contribute - in combination with pro-inflammatory and mucus degrading microbial signatures - to tumor development. Similar immune and epithelial alterations were found in human colon biopsies from H. pylori-infected patients. Housing of Apc-mutant mice under germ-free conditions ameliorated, and early antibiotic eradication of H. pylori infection normalized the tumor incidence to the level of uninfected controls.
CONCLUSIONS
Our studies provide evidence that H. pylori infection is a strong causal promoter of colorectal carcinogenesis. Therefore, implementation of H. pylori status into preventive measures of CRC should be considered.
Background
Murine Helicobacter species have gained increasing awareness in mouse facilities over the last years. Infections with Helicobacter species may have an impact effect on the health of mice and might pose a zoonotic risk to researchers. To minimize the interference with experiments and hence contribute to the 3Rs, a reliable method of monitoring Helicobacter infections in animal facilities needs to be available. The aim of this study was to improve and validate the detection of the most common murine Helicobacter species.
Material and Methods
A multiplex PCR assay was developed for identification of Helicobacter hepaticus, H. bilis, H. muridarum, H. rodentium, and H. typhlonius that could simultaneously detect these five strains in fecal samples. To ensure the quality of the results, the method was validated based on recommendations for in‐house developed tests.
Results
The method established was highly sensitive and specific. All five strains were detectable with a detection limit of 102 bacteria. Eight different mouse facilities were tested with the validated assay, and the following prevalence were found: H. rodentium 57%, H. hepaticus 46%, H. typhlonius 17%, H. bilis 12%, and H. muridarum 0%.
Conclusion
The multiplex PCR is a reliable, economic, and time‐saving diagnostic tool for routine health monitoring. Further prevalence studies are needed to confirm the high prevalence and hence importance of H. rodentium, as until now this agent is not yet listed in FELASA recommendations.
The understanding of gut virome and its role in Helicobacter pylori-driven colorectal cancer (CRC), as well as the long-term impact of H. pylori eradication via antibiotic treatment on it could contribute to better understanding the mechanisms of the disruption of gut bacteriome homeostasis involved in H. pylori-driven colorectal carcinogenesis and antibiotic therapy for H. pylori eradication. In the dynamic analysis of viral genome shotgun metagenomic of samples from lower gastrointestinal tract of the Apc+/1638N and C57BL/6 mice with H. pylori infection and eradication, stable viral abundance and replacement of bursted unique viral contigs in infected and uninfected Apc+/1638N mice were observed. Temperate phages, which encoding comprehensive microbial functional genes and targeting various susceptible hosts, were expanded extremely prior to cancer exacerbation. In addition, short-term antibiotic exposure for H. pylori eradication was able to alter the gut virome and thrive the antibiotic resistance genes (ARGs) in the viral genome for at least 6 months. Collectively, these results point toward a potential role of the altered, but dynamically balanced gut virome, characterized by the expanded temperate phages, in contributing to the H. pylori-driven CRC, and indicate that viral genome may act as ARG reservoir for the antibiotic resistance of bacteria after the antibiotics therapy to H. pylori eradication.
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