Self-renewing Monolayer of Primary Colonic or Rectal Epithelial Cells

Overview

Journal Cell Mol Gastroenterol Hepatol

Specialty Gastroenterology

Date 2017 Dec 6

PMID 29204504

Citations 123

Authors

Yuli Wang

Matthew DiSalvo

Dulan B Gunasekara

Johanna Dutton

Angela Proctor

Michael S Lebhar

Ian A Williamson

Jennifer Speer

Riley L Howard

Nicole M Smiddy

Scott J Bultman

Christopher E Sims

Scott T Magness

Nancy L Allbritton

Affiliations

Soon will be listed here.

Abstract

Background & Aims: Three-dimensional organoid culture has fundamentally changed the in vitro study of intestinal biology enabling novel assays; however, its use is limited because of an inaccessible luminal compartment and challenges to data gathering in a three-dimensional hydrogel matrix. Long-lived, self-renewing 2-dimensional (2-D) tissue cultured from primary colon cells has not been accomplished.

Methods: The surface matrix and chemical factors that sustain 2-D mouse colonic and human rectal epithelial cell monolayers with cell repertoires comparable to that in vivo were identified.

Results: The monolayers formed organoids or colonoids when placed in standard Matrigel culture. As with the colonoids, the monolayers exhibited compartmentalization of proliferative and differentiated cells, with proliferative cells located near the peripheral edges of growing monolayers and differentiated cells predominated in the central regions. Screening of 77 dietary compounds and metabolites revealed altered proliferation or differentiation of the murine colonic epithelium. When exposed to a subset of the compound library, murine organoids exhibited similar responses to that of the monolayer but with differences that were likely attributable to the inaccessible organoid lumen. The response of the human primary epithelium to a compound subset was distinct from that of both the murine primary epithelium and human tumor cells.

Conclusions: This study demonstrates that a self-renewing 2-D murine and human monolayer derived from primary cells can serve as a physiologically relevant assay system for study of stem cell renewal and differentiation and for compound screening. The platform holds transformative potential for personalized and precision medicine and can be applied to emerging areas of disease modeling and microbiome studies.

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