An Open-Format Enteroid Culture System for Interrogation of Interactions Between and the Intestinal Epithelium

Overview

Journal Front Cell Infect Microbiol

Specialties Cell Biology
Infectious Diseases
Microbiology

Date 2019 Sep 27

PMID 31555604

Citations 15

Authors

Lisa Luu

Luke J Johnston

Hayley Derricott

Stuart D Armstrong

Nadine Randle

Catherine S Hartley

Carrie A Duckworth

Barry J Campbell

Jonathan M Wastling

Janine L Coombes

Affiliations

Soon will be listed here.

Abstract

When transmitted through the oral route, first interacts with its host at the small intestinal epithelium. This interaction is crucial to controlling initial invasion and replication, as well as shaping the quality of the systemic immune response. It is therefore an attractive target for the design of novel vaccines and adjuvants. However, due to a lack of tractable infection models, we understand surprisingly little about the molecular pathways that govern this interaction. The culture of small intestinal epithelium as 3D enteroids shows great promise for modeling the epithelial response to infection. However, the enclosed luminal space makes the application of infectious agents to the apical epithelial surface challenging. Here, we have developed three novel enteroid-based techniques for modeling infection. In particular, we have adapted enteroid culture protocols to generate collagen-supported epithelial sheets with an exposed apical surface. These cultures retain epithelial polarization, and the presence of fully differentiated epithelial cell populations. They are susceptible to infection with, and support replication of, . Using quantitative label-free mass spectrometry, we show that infection of the enteroid epithelium is associated with up-regulation of proteins associated with cholesterol metabolism, extracellular exosomes, intermicrovillar adhesion, and cell junctions. Inhibition of host cholesterol and isoprenoid biosynthesis with Atorvastatin resulted in a reduction in parasite load only at higher doses, indicating that synthesis may support, but is not required for, parasite replication. These novel models therefore offer tractable tools for investigating how interactions between and the host intestinal epithelium influence the course of infection.

Citing Articles

Bacterial attachment and junctional transport function in induced apical-out polarized and differentiated canine intestinal organoids.

Yoshida S, Nakazawa M, Kawasaki M, Ambrosini Y Front Vet Sci. 2025; 11:1483421.

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Motility-dependent processes in tachyzoites and bradyzoites: same same but different.

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A novel model of the small intestinal epithelium in co-culture with 'gut-like' dendritic cells.

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Organoid-based system and reporter for the study of sexual reproduction.

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