Michelle M. Muza–Moons scite author profile

SummaryInfection of intestinal epithelial cells with enteropathogenic Escherichia coli (EPEC) disrupts tight junction (TJ) architecture and barrier function. The aim of this study was to determine the impact of EPEC on TJ protein interactions and localization. Human intestinal epithelial cells (T84) were infected for 1, 3 or 6 h with EPEC. To probe the TJ protein-protein interactions, co-immunoprecipitations were performed. The associations between ZO-1, occludin and claudin-1 progressively decreased after infection. Corresponding morphological changes were analysed by immunofluorescence confocal microscopy. Tight junction proteins progressively lost their apically restricted localization. Freeze-fracture electron microscopy revealed the appearance of aberrant strands throughout the lateral membrane that contained claudin-1 and occludin as determined by immunogold labelling. These structural alterations were accompanied by a loss of barrier function. Mutation of the gene encoding EspF, important in the disruption of TJs by EPEC, prevented the disruption of TJs. Tight junction structure normalized following eradication of EPEC with gentamicin and overnight recovery. This is the first demonstration that a microbial pathogen can cause aberrant TJ strands in the lateral membrane of host cells. We speculate that the disruption of integral and cytoplasmic TJ protein interactions following EPEC infection allows TJ strands to form or diffuse into the lateral plasma membrane.

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Disruptionof Cell Polarity by Enteropathogenic Escherichia coli EnablesBasolateral Membrane Proteins To Migrate Apically and ToPotentiate PhysiologicalConsequences

Muza–Moons

Koutsouris

Hecht

2003

Infect Immun

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Enteropathogenic Escherichia coli (EPEC) disrupts the structure and barrier function of host intestinal epithelial tight junctions (TJs). The impact of EPEC on TJ "fence function," i.e., maintenance of cell polarity, has not been investigated. In polarized cells, proteins such as ␤ 1 -integrin and Na ؉ /K ؉ ATPase are restricted to basolateral (BL) membranes. The outer membrane EPEC protein intimin possesses binding sites for the EPEC translocated intimin receptor (Tir) and ␤ 1 -integrin. Restriction of ␤ 1 -integrin to BL domains, however, precludes opportunity for interaction. We hypothesize that EPEC perturbs TJ fence function and frees BL proteins such as ␤ 1 -integrin to migrate to apical (AP) membranes of host cells, thus allowing interactions with bacterial adhesins such as intimin. The aim of this study was to determine whether EPEC alters the polar distribution of BL proteins, in particular ␤ 1 -integrin, and if such redistribution contributes to pathogenesis. Human intestinal epithelial T84 cells and EPEC strain E2348/69 were used. Selective biotinylation of AP or BL membrane proteins and confocal microscopy showed the presence of ␤ 1 -integrin and Na ؉ /K ؉ ATPase on the AP membrane following infection. ␤ 1 -Integrin antibody afforded no protection against the initial EPECinduced decrease in transepithelial electrical resistance (TER) but halted the progressive decrease at later time points. While the effects of EPEC on TJ barrier and fence function were Tir dependent, disruption of cell polarity by calcium chelation allowed a tir mutant to be nearly as effective as wild-type EPEC. In contrast, deletion of espD, which renders the type III secretory system ineffective, had no effect on TER even after calcium chelation, suggesting that the putative ␤ 1 -integrin-intimin interaction serves to provide intimate contact, like that of Tir and intimin, making translocation of effector molecules more efficient. We conclude that the initial alterations of TJ barrier and fence function by EPEC are Tir dependent but that later disruption of cell polarity and accessibility of EPEC to BL membrane proteins, such as ␤ 1 -integrin, potentiates the physiological perturbations.

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CD4+ Tissue-resident Memory T Cells Expand and Are a Major Source of Mucosal Tumour Necrosis Factor α in Active Crohn’s Disease

Bishu

Zaatari

Hayashi

et al. 2019

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Background and Aims Tumour necrosis factor [TNF]α- and IL-17A-producing T cells are implicated in Crohn’s disease [CD]. Tissue-resident memory T [TRM] cells are tissue-restricted T cells that are regulated by PR zinc finger domain 1 [PRDM1], which has been implicated in pathogenic Th17 cell responses. TRM cells provide host defence but their role in CD is unknown. We thus examined CD4+ TRM cells in CD. Methods Colon samples were prospectively collected at endoscopy or surgery in CD and control subjects. Flow cytometry and ex vivo assays were performed to characterise CD4+ TRM cells. Results CD4+ TRM cells are the most abundant memory T cell population and are the major T cell source of mucosal TNFα in CD. CD4+ TRM cells are expanded in CD and more avidly produce IL-17A and TNFα relative to control cells. There was a unique population of TNFα+IL-17A+ CD4+ TRM cells in CD which are largely absent in controls. PRDM1 was highly expressed by CD4+ TRM cells but not by other effector T cells. Suppression of PRDM1 was associated with impaired induction of IL17A and TNFA by CD4+ TRM cells Conclusions CD4+ TRM cells are expanded in CD and are a major source of TNFα, suggesting that they are important in CD. PRDM1 is expressed by TRM cells and may regulate their function. Collectively, this argues for prospective studies tracking CD4+ TRM cells over the disease course.

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Patient-focused IBD Applications Review

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Muza–Moons

2017

Gastroenterology

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Mo1877 – Tumor Necrosis Factor α and Il-17A Producing Cd4+ Tissue Resident Memory T-Cells are Expanded in Crohn’s and are Inhibited by the Anti-Inflammtory Microbial Metabolite Butyrate

Bishu¹,

El–Zaatari²,

Hayashi³

et al. 2019

Gastroenterology

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