Understanding disease-associated metabolic changes in human colonic epithelial cells using the iColonEpithelium metabolic reconstruction.

Publication Title

PLoS Comput Biol

Authors

Boyu Jiang
Nick Quinn-Bohmann, Institute for Systems Biology, Seattle, Washington, United States of America.
Christian Diener, Institute for Systems Biology, Seattle, Washington, United States of America.Follow
Vignesh Bose Nathan
Yu Han-Hallett
Lavanya Reddivari
Sean M Gibbons, Institute for Systems Biology, Seattle, Washington, United States of America.Follow
Priyanka Baloni

Document Type

Article

Publication Date

7-1-2025

Keywords

Humans; Colon; Epithelial Cells; Gastrointestinal Microbiome; Intestinal Mucosa; Models, Biological; Computational Biology; Metabolic Networks and Pathways; Crohn Disease; Colitis, Ulcerative; washington; isb

Abstract

The colonic epithelium plays a key role in the host-microbiome interactions, allowing uptake of various nutrients and driving important metabolic processes. To unravel detailed metabolic activities in the human colonic epithelium, our present study focuses on the generation of the first cell-type-specific genome-scale metabolic model (GEM) of human colonic epithelial cells, named iColonEpithelium. GEMs are powerful tools for exploring reactions and metabolites at the systems level and predicting the flux distributions at steady state. Our cell-type-specific iColonEpithelium metabolic reconstruction captures genes specifically expressed in the human colonic epithelial cells. iColonEpithelium is also capable of performing metabolic tasks specific to the colonic epithelium. A unique transport reaction compartment has been included to allow for the simulation of metabolic interactions with the gut microbiome. We used iColonEpithelium to identify metabolic signatures associated with inflammatory bowel disease. We used single-cell RNA sequencing data from Crohn's Diseases (CD) and ulcerative colitis (UC) samples to build disease-specific iColonEpithelium metabolic networks in order to predict metabolic signatures of colonocytes in both healthy and disease states. We identified reactions in nucleotide interconversion, fatty acid synthesis and tryptophan metabolism were differentially regulated in CD and UC conditions, relative to healthy control, which were in accordance with experimental results. The iColonEpithelium metabolic network can be used to identify mechanisms at the cellular level, and we show an initial proof-of-concept for how our tool can be leveraged to explore the metabolic interactions between host and gut microbiota.

Area of Special Interest

Digestive Health

Specialty/Research Institute

Gastroenterology

DOI

10.1371/journal.pcbi.1013253