Kevin Champagne-Jorgensen - Mining for disease-associated microbial

Journal article

A. Pu, N. Fettig, Alexandros Polyzois, Gary Chao, Ikbel Naouar, L. S. Hohman, Marissa A Fontaine, Michelle Zuo, K. Champagne-Jorgensen, Julia Copeland, Donny Chan, Katherine M Davis, Ruoqi Yu, S. Popple, Natalia A. Carranza García, D. Guttman, Kathy D McCoy, V. Ramaglia, F. Schroeder, J. Gommerman, L. Osborne
bioRxiv, 2025

Semantic Scholar DOI

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APA Click to copy
Pu, A., Fettig, N., Polyzois, A., Chao, G., Naouar, I., Hohman, L. S., … Osborne, L. (2025). Mining for disease-associated microbial metabolites in an age-dependent model of multiple sclerosis. BioRxiv.

Chicago/Turabian Click to copy
Pu, A., N. Fettig, Alexandros Polyzois, Gary Chao, Ikbel Naouar, L. S. Hohman, Marissa A Fontaine, et al. “Mining for Disease-Associated Microbial Metabolites in an Age-Dependent Model of Multiple Sclerosis.” bioRxiv (2025).

MLA Click to copy
Pu, A., et al. “Mining for Disease-Associated Microbial Metabolites in an Age-Dependent Model of Multiple Sclerosis.” BioRxiv, 2025.

BibTeX Click to copy

@article{a2025a,
  title = {Mining for disease-associated microbial metabolites in an age-dependent model of multiple sclerosis},
  year = {2025},
  journal = {bioRxiv},
  author = {Pu, A. and Fettig, N. and Polyzois, Alexandros and Chao, Gary and Naouar, Ikbel and Hohman, L. S. and Fontaine, Marissa A and Zuo, Michelle and Champagne-Jorgensen, K. and Copeland, Julia and Chan, Donny and Davis, Katherine M and Yu, Ruoqi and Popple, S. and García, Natalia A. Carranza and Guttman, D. and McCoy, Kathy D and Ramaglia, V. and Schroeder, F. and Gommerman, J. and Osborne, L.}
}

Abstract

Age is a risk factor for the neurological decline and physical disability that characterize progressive multiple sclerosis (MS). The intestinal microbiota and the bioactive compounds it produces can influence aging, immunity, and the central nervous system (CNS). Here, we use an experimental autoimmune encephalomyelitis (EAE) model that mimics features of progressive MS in aged, but not young, mice to address the intersection of age and the microbiota on EAE outcomes. Although the microbiota of SJL/J mice aged under controlled laboratory conditions does not promote an ‘aged’ non-remitting EAE phenotype, young mice harboring heterochronic human fecal microbiota transplants (hFMT) developed a range of EAE phenotypes. Metabolomic profiling of mice colonized with an aged hFMT that promoted non-remitting EAE indicated a severe reduction in circulating levels of the microbiota-derived tryptophan metabolite indole 3-propionic acid (IPA). IPA-supplementation enforced remission in mice colonized with the non-remitting hFMT, demonstrating the utility of this in vivo pipeline for discovering metabolites associated with progressive MS-like disease. Summary The microbiota is a critical determinant of disease susceptibility in mouse models of MS. Here, Pu & Fettig et al. demonstrate that disease outcomes (remitting or non-remitting) are microbiota-responsive, and describe an in vivo pipeline that can be mined for microbial metabolites with therapeutic potential for progressive MS.