Shiga toxin (Stx) is implicated in the development of hemorrhagic colitis and hemolytic-uremic syndrome, but early symptoms of enterohemorrhagic Escherichia coli (EHEC) infection such as non-bloody diarrhea may be Stx-independent. In this study, we defined the effects of EHEC, in the absence of Stx, on the intestinal epithelium using a murine model. EHEC colonization of intestines from two groups of antibiotic-free and streptomycin-treated C57Bl/6J mice were characterized and compared. EHEC colonized the cecum and colon more efficiently than the ileum in both groups; however, greater amounts of tissue-associated EHEC were detected in streptomycin-pretreated mice. Imaging of intestinal tissues of mice infected with bioluminescent EHEC further confirmed tight association of the bacteria to the cecum and colon. Greater numbers of EHEC were also cultured from stool of streptomycin-pretreated mice, as compared to those that received no antibiotic. Transmission electron microscopy demonstrated that EHEC infection leads to microvillous effacement of mouse colonocytes. Hematoxylin and eosin staining of colonic tissues of infected mice revealed a slight increase in the number of lamina propria polymorphonuclear leukocytes. Transmucosal electrical resistance, a measure of epithelial barrier function, was reduced in colonic tissues of infected animals. Increased mucosal permeability to 4KDa FITC-Dextran was also observed in colonic tissues of infected mice. Immunofluorescence microscopy revealed that EHEC infection resulted in redistribution of the tight junction proteins occludin and claudin-3 and increased expression of claudin-2 while ZO-1 localization remained unaltered. Quantitative real-time PCR revealed that EHEC altered mRNA transcription of Ocln, Cldn2 and Cldn3. Most notably, claudin-2 expression was significantly increased and correlated with increased intestinal permeability. Our data indicate that C57Bl/6J mice serve as an in vivo model to study the physiological effects of EHEC infection on the intestinal epithelium and suggest that altered transcription of tight junction proteins plays a role in the increase in intestinal permeability.
Infectious diarrhea is a major contributor of child morbidity and mortality in developing nations. Murine models to study the pathogenesis of infectious diarrhea caused by organisms such as enteropathogenic E. coli (EPEC) and enterohemorrhagic E. coli (EHEC) are not fully characterized. More emphasis has been placed on infection of mice with the murine specific pathogen Citrobacter rodentium. While these three organisms are genetically related they are not identical. Our goal was to better characterize the murine model of EPEC and EHEC infection by using bioluminescent bacteria to determine temporal and spatial colonization of these two human pathogens. EPEC and EHEC were transformed with a bacterial luciferase expression plasmid containing the constitutive OmpC promoter. C57BL/6 mice were orally inoculated with bioluminescent EPEC or EHEC and bacterial localization in the intestine was monitored ex vivo and in vivo by IVIS. At 3 days after infection, EPEC, EHEC and Citrobacter rodentium were all localized in the cecum and colon. EPEC colonization peaked at day 2-3 and was undetectable by day 7. The bioluminescent EPEC adheres to the cecum and colon of the mouse intestine. However, when EPEC infected mice were administered xylazine/ketamine for in vivo live imaging, the EPEC persisted at high densities for up to 31 days. This is the first report of a bioluminescent imaging of luciferase expressing EPEC in a mouse model.
Aims
Arbuscular mycorrhizal fungi (AMF) are symbiotic partners of many invasive plants, however, it is still unclear how AMF contribute to traits that are important for the successful invasion of their host and how environmental factors, such as nutrient conditions, influence this. This study was to explore the effects of Glomus versiforme (GV) and Glomus mosseae (GM) on the growth and disease resistance of the invasive plant Wedelia trilobata under different nutrient conditions.
Methods and Results
We found that GV and GM had higher root colonization rates resulting in faster W. trilobata growth under both low‐N and low‐P nutrient conditions compared to the normal condition. Also, the colonization of W. trilobata by GV significantly reduced the infection area of the pathogenic fungus Rhizoctonia solani under low‐N conditions.
Conclusions
These results demonstrated that AMF can promote the growth and pathogenic defence of W. trilobata in a nutrient‐poor environment, which might contribute to their successful invasion into certain type of habitats.
Significance and Impact of the Study
In this study, we report for the first time that AMF can promote growth and disease resistance of W. trilobata under nutrient‐poor environment, which contribute to a better understanding of plant invasion.
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