Abstract
BackgroundAlthough Campylobacter jejuni-infections have a high prevalence worldwide and represent a significant socioeconomic burden, it is still not well understood how C. jejuni causes intestinal inflammation. Detailed investigation of C. jejuni-mediated intestinal immunopathology is hampered by the lack of appropriate vertebrate models. In particular, mice display colonization resistance against this pathogen.Methodology/Principal FindingsTo overcome these limitations we developed a novel C. jejuni-infection model using gnotobiotic mice in which the intestinal flora was eradicated by antibiotic treatment. These animals could then be permanently associated with a complete human (hfa) or murine (mfa) microbiota. After peroral infection C. jejuni colonized the gastrointestinal tract of gnotobiotic and hfa mice for six weeks, whereas mfa mice cleared the pathogen within two days. Strikingly, stable C. jejuni colonization was accompanied by a pro-inflammatory immune response indicated by increased numbers of T- and B-lymphocytes, regulatory T-cells, neutrophils and apoptotic cells, as well as increased concentrations of TNF-α, IL-6, and MCP-1 in the colon mucosa of hfa mice. Analysis of MyD88−/−, TRIF−/−, TLR4−/−, and TLR9−/− mice revealed that TLR4- and TLR9-signaling was essential for immunopathology following C. jejuni-infection. Interestingly, C. jejuni-mutant strains deficient in formic acid metabolism and perception induced less intestinal immunopathology compared to the parental strain infection. In summary, the murine gut flora is essential for colonization resistance against C. jejuni and can be overcome by reconstitution of gnotobiotic mice with human flora. Detection of C. jejuni-LPS and -CpG-DNA by host TLR4 and TLR9, respectively, plays a key role in immunopathology. Finally, the host immune response is tightly coupled to bacterial formic acid metabolism and invasion fitness.Conclusion/SignificanceWe conclude that gnotobiotic and “humanized” mice represent excellent novel C. jejuni-infection and -inflammation models and provide deep insights into the immunological and molecular interplays between C. jejuni, microbiota and innate immunity in human campylobacteriosis.
Highlights
In industrialized countries Campylobacter jejuni is among the most frequent causative agents of bacterial enteritis [1]
We demonstrate that TLR4- and, strikingly, TLR9-mediated signaling are essentially involved in C. jejuni-induced immunopathology
Given that the commensal murine gut microbiota is essential for the resistance against C. jejuni colonization and suitable mouse models of C. jejuni-infection are scarce, we established a novel murine experimental system to investigate the interplay (‘‘menage atrois’’) of the gut microbiota and innate immune system on the host side with the pathogen after oral C. jejuni-infection and permanent intestinal colonization
Summary
In industrialized countries Campylobacter jejuni is among the most frequent causative agents of bacterial enteritis [1]. The Gramnegative pathogen is transmitted via the food chain from farm animals to humans by the ingestion of undercooked meat, nonpasteurized milk, and water [2,3]. After infection C. jejuni colonizes the human distal small intestine and colon. After active invasion of colonic epithelial cells, C. jejuni induces mucosal inflammation characterized by neutrophil infiltration, crypt abscesses, focal ulcerations, and plasma cell proliferation [4,5,6]. Campylobacter jejuni-infections have a high prevalence worldwide and represent a significant socioeconomic burden, it is still not well understood how C. jejuni causes intestinal inflammation. Mice display colonization resistance against this pathogen
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