Identifying Metabolic Shifts in Crohn's Disease Using' Omics-driven Contextualized Computational Metabolic Network Models

Overview

Journal Sci Rep

Specialty Science

Date 2023 Jan 5

PMID 36604447

Authors

Philip Fernandes

Yash Sharma

Fatima Zulqarnain

Brooklyn McGrew

Aman Shrivastava

Lubaina Ehsan

Dawson Payne

Lillian Dillard

Deborah Powers

Isabelle Aldridge

Jason Matthews

Subra Kugathasan

Facundo M Fernandez

David Gaul

Jason A Papin

Sana Syed

Affiliations

Soon will be listed here.

Abstract

Crohn's disease (CD) is a chronic inflammatory disease of the gastrointestinal tract. A clear gap in our existing CD diagnostics and current disease management approaches is the lack of highly specific biomarkers that can be used to streamline or personalize disease management. Comprehensive profiling of metabolites holds promise; however, these high-dimensional profiles need to be reduced to have relevance in the context of CD. Machine learning approaches are optimally suited to bridge this gap in knowledge by contextualizing the metabolic alterations in CD using genome-scale metabolic network reconstructions. Our work presents a framework for studying altered metabolic reactions between patients with CD and controls using publicly available transcriptomic data and existing gene-driven metabolic network reconstructions. Additionally, we apply the same methods to patient-derived ileal enteroids to explore the utility of using this experimental in vitro platform for studying CD. Furthermore, we have piloted an untargeted metabolomics approach as a proof-of-concept validation strategy in human ileal mucosal tissue. These findings suggest that in silico metabolic modeling can potentially identify pathways of clinical relevance in CD, paving the way for the future discovery of novel diagnostic biomarkers and therapeutic targets.

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