Enterohemorrhagic Escherichia coli (EHEC) disrupts intestinal barrier integrity in translational canine stem cell-derived monolayers

Abstract

ABSTRACT This study addresses the gap in translatable in vitro models for investigating Enterohemorrhagic E. coli (EHEC) infections, particularly relevant to both canine and human health. EHEC is known to induce acute colitis in dogs, leading to symptoms like hemorrhagic diarrhea and hemolytic uremic syndrome, similar to those observed in humans. However, understanding the pathophysiology and developing treatment strategies have been challenging due to the lack of effective models that replicate the clinical disease caused by EHEC in both species. Our approach involved the development of colonoid-derived monolayers using intestinal tissues from healthy, client-owned dogs. These monolayers were exposed to EHEC, and the impact of EHEC was assessed through several techniques, including trans-epithelial electrical resistance (TEER) measurement, immunofluorescence staining for junction proteins and mucus, and scanning electron microscopy for morphological analysis. Modified culture with saline, which was intended to prevent bacterial overgrowth, maintained barrier integrity and cell differentiation. EHEC infection led to significant decreases in TEER and ZO-1 expression, but not in E-cadherin levels or mucus production. In addition, EHEC elicited a notable increase in tumor necrosis factor-alpha production, highlighting its distinct impact on canine intestinal epithelial cells compared to non-pathogenic E. coli . These findings closely replicate in vivo observations in dogs and humans with EHEC enteropathy, validating the canine colonoid-derived monolayer system as a translational model to study host-pathogen interactions in EHEC and potentially other clinically significant enteric pathogens. IMPORTANCE This study develops a new model to better understand Enterohemorrhagic E. coli (EHEC) infections, a serious bacterial disease affecting both dogs and humans, characterized by symptoms such as hemorrhagic diarrhea and hemolytic uremic syndrome. Traditional research models have fallen short of mimicking how this disease manifests in patients. Our research used intestinal tissues from healthy dogs to create layers of cells, known as colonoid-derived monolayers, which we then exposed to EHEC. We assessed the damage caused by the bacteria using several techniques, observing significant changes similar to those seen in actual cases of the disease. The model proved effective in replicating the interaction between the host and the pathogen, marking an important step toward understanding EHEC’s effects and developing treatments. This canine colonoid-derived monolayer system not only bridges a crucial gap in current research but also offers a promising platform for studying other enteric pathogens affecting both canine and human health.