Intestinal Epithelial Cell PTPN2 Restricts Intestinal Permeability and Tight-Junction Remodelling Caused by Adherent-invasive E. coli in Mice

Abstract

Background: Alterations in epithelial tight junction proteins can compromise the ability of the intestinal mucosa to act as a barrier between luminal contents and underlying tissues. The resulting increase in intestinal permeability can give rise to conditions such as inflammatory bowel disease (IBD). Additionally, expansion of pathobionts, such as adherent-invasive Escherichia coli (AIEC), are associated with IBD. Mice deficient in the IBD gene candidate, Ptpn2, exhibit increased intestinal permeability and a pronounced expansion of a novel murine AIEC ( mAIEC). This study aimed to investigate how PTPN2 expression in intestinal epithelial cells protects intestinal barrier properties after mAIEC infection. Methods: Tamoxifen-inducible, intestinal epithelial cell (IEC)-specific knockout mice ( Ptpn2 ΔIEC ) and control littermates ( Ptpn2 fl/fl ) were infected with either PBS, non-invasive E. coli K12, or mcherry-tagged mAIEC ( mAIEC red ). FITC-Dextran (FD4) and Rhodamine-Dextran (RD70) permeability probes were administered by oral-gavage and serum collected after 5hrs. Results: Ptpn2 ΔIEC mice exhibited intestinal region-specific higher mAIEC red - but not K12 - bacterial load compared to Ptpn2 fl/fl mice ( P=0.038). E. coli K12 increased FD4 but not RD70 permeability in Ptpn2 ΔIEC mice compared with Ptpn2 fl/fl mice ( P=0.0025). mAIEC red also had no effect on RD70, but caused an even greater increase in FD4 permeability in Ptpn2 ΔIEC vs. Ptpn2 fl/fl mice ( P< 0.0001). Ptpn2 fl/fl mice infected with mAIEC red also exhibited increased FD4 permeability compared to PBS-treated littermates ( P =0.0210). To identify if increased FD4 permeability was due to changes in expression of relevant tight-junction proteins, we performed western blot analysis on isolated IECs. Ptpn2 ΔIEC + mAIEC red mice had decreased expression of occludin ( P=0.0030) and the adherens junction protein, E-cadherin ( P=0.0142). Expression of the cation pore, claudin-2, was increased in PBS and K12-infected Ptpn2 ΔIEC vs. Ptpn2 fl/fl mice ( P=0.015). Interestingly, mAIEC red increased claudin-2 expression in Ptpn2 fl/fl mice compared to PBS controls ( P=0.0105) however, Ptpn2 ΔIEC + mAIEC red mice exhibited decreased claudin-2 levels compared to Ptpn2 fl/fl + mAIEC red mice ( P=0.0436). Immunofluorescence staining of claudin-2 confirmed reduced claudin-2 in Ptpn2 ΔIEC + mAIEC red mice. Furthermore, we observed gaps in ZO-1 membrane localization in Ptpn2 ΔIEC mice treated with PBS and K12 but not in their Ptpn2 fl/fl controls. ZO-1 membrane localization was dramatically depleted in Ptpn2 ΔIEC + mAIEC red mice compared to the Ptpn2 fl/fl + mAIEC red controls. Conclusion: Intestinal epithelial PTPN2 exhibits a major role in maintaining intestinal homeostasis by preserving intestinal barrier function and the integrity of tight-junction protein localization. Given that loss of PTPN2 in vivo also provokes expansion of adherent-invasive E. coli, these studies indicate that PTPN2 is an important mediator of host-microbiota crosstalk. This is the full abstract presented at the American Physiology Summit 2023 meeting and is only available in HTML format. There are no additional versions or additional content available for this abstract. Physiology was not involved in the peer review process.