A Multiomic Network Approach to Uncover Disease Modifying Mechanisms of Inborn Errors of Metabolism

Aaron Bender; Pablo Ranea-Robles; Evan G. Williams; Mina Mirzaian; J. Alexander Heimel; Christiaan N. Levelt; Ronald J. Wanders; Johannes M. Aerts; Jun Zhu; Johan Auwerx; Sander M. Houten; Carmen A. Argmann

doi:10.1002/jimd.70045

A Multiomic Network Approach to Uncover Disease Modifying Mechanisms of Inborn Errors of Metabolism

Aaron Bender
, Pablo Ranea-Robles
, Evan G. Williams
, Mina Mirzaian
, J. Alexander Heimel
, Christiaan N. Levelt
, Ronald J. Wanders
, Johannes M. Aerts
, Jun Zhu
, Johan Auwerx
, Sander M. Houten^*
, Carmen A. Argmann^*

^*Corresponding author for this work

Icahn School of Medicine at Mount Sinai
University of Granada
University of Luxembourg
Erasmus University Rotterdam
Netherlands Institute for Neuroscience
University of Amsterdam
Amsterdam UMC
Leiden University
Swiss Federal Institute of Technology Lausanne

Research output: Contribution to journal › Article › Academic › peer-review

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Abstract

For many inborn errors of metabolism (IEM) the understanding of disease mechanisms remains limited, in part explaining their unmet medical needs. The expressivity of IEM disease phenotypes is affected by disease-modifying factors, including rare and common polygenic variation. We hypothesize that we can identify these modulating pathways using molecular signatures of IEM in combination with multiomic data and gene regulatory networks generated from non-IEM animal and human populations. We tested this approach by identifying and subsequently validating glucocorticoid signaling as a candidate modifier of mitochondrial fatty acid oxidation disorders, and recapitulating complement signaling as a modifier of inflammation in Gaucher disease. Our work describes a novel approach that can overcome the rare disease–rare data dilemma and reveal new IEM pathophysiology and potential drug targets using multiomics data in seemingly healthy populations.

Original language	English
Article number	e70045
Journal	Journal of inherited metabolic disease
Volume	48
Issue number	4
DOIs	https://doi.org/10.1002/jimd.70045
Publication status	Published - 1 Jul 2025

Keywords

Bayesian gene regulatory networks
QTL mapping
genetic reference population
metabolomics
mouse models
transcriptomics

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Bender, A., Ranea-Robles, P., Williams, E. G., Mirzaian, M., Heimel, J. A., Levelt, C. N., Wanders, R. J., Aerts, J. M., Zhu, J., Auwerx, J., Houten, S. M., & Argmann, C. A. (2025). A Multiomic Network Approach to Uncover Disease Modifying Mechanisms of Inborn Errors of Metabolism. Journal of inherited metabolic disease, 48(4), Article e70045. https://doi.org/10.1002/jimd.70045

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title = "A Multiomic Network Approach to Uncover Disease Modifying Mechanisms of Inborn Errors of Metabolism",

abstract = "For many inborn errors of metabolism (IEM) the understanding of disease mechanisms remains limited, in part explaining their unmet medical needs. The expressivity of IEM disease phenotypes is affected by disease-modifying factors, including rare and common polygenic variation. We hypothesize that we can identify these modulating pathways using molecular signatures of IEM in combination with multiomic data and gene regulatory networks generated from non-IEM animal and human populations. We tested this approach by identifying and subsequently validating glucocorticoid signaling as a candidate modifier of mitochondrial fatty acid oxidation disorders, and recapitulating complement signaling as a modifier of inflammation in Gaucher disease. Our work describes a novel approach that can overcome the rare disease–rare data dilemma and reveal new IEM pathophysiology and potential drug targets using multiomics data in seemingly healthy populations.",

keywords = "Bayesian gene regulatory networks, QTL mapping, genetic reference population, metabolomics, mouse models, transcriptomics",

author = "Aaron Bender and Pablo Ranea-Robles and Williams, \{Evan G.\} and Mina Mirzaian and Heimel, \{J. Alexander\} and Levelt, \{Christiaan N.\} and Wanders, \{Ronald J.\} and Aerts, \{Johannes M.\} and Jun Zhu and Johan Auwerx and Houten, \{Sander M.\} and Argmann, \{Carmen A.\}",

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year = "2025",

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doi = "10.1002/jimd.70045",

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AU - Bender, Aaron

AU - Ranea-Robles, Pablo

AU - Williams, Evan G.

AU - Mirzaian, Mina

AU - Heimel, J. Alexander

AU - Levelt, Christiaan N.

AU - Wanders, Ronald J.

AU - Aerts, Johannes M.

AU - Zhu, Jun

AU - Auwerx, Johan

AU - Houten, Sander M.

AU - Argmann, Carmen A.

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AB - For many inborn errors of metabolism (IEM) the understanding of disease mechanisms remains limited, in part explaining their unmet medical needs. The expressivity of IEM disease phenotypes is affected by disease-modifying factors, including rare and common polygenic variation. We hypothesize that we can identify these modulating pathways using molecular signatures of IEM in combination with multiomic data and gene regulatory networks generated from non-IEM animal and human populations. We tested this approach by identifying and subsequently validating glucocorticoid signaling as a candidate modifier of mitochondrial fatty acid oxidation disorders, and recapitulating complement signaling as a modifier of inflammation in Gaucher disease. Our work describes a novel approach that can overcome the rare disease–rare data dilemma and reveal new IEM pathophysiology and potential drug targets using multiomics data in seemingly healthy populations.

KW - Bayesian gene regulatory networks

KW - QTL mapping

KW - genetic reference population

KW - metabolomics

KW - mouse models

KW - transcriptomics

UR - https://www.scopus.com/pages/publications/105006853903

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DO - 10.1002/jimd.70045

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JO - Journal of inherited metabolic disease

JF - Journal of inherited metabolic disease

IS - 4

M1 - e70045

ER -

A Multiomic Network Approach to Uncover Disease Modifying Mechanisms of Inborn Errors of Metabolism

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Keywords

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