TY - JOUR
T1 - Systematic characterization of human gut microbiome-secreted molecules by integrated multi-omics
AU - De Saedeleer, Bianca
AU - Malabirade, Antoine
AU - Ramiro-Garcia, Javier
AU - Habier, Janine
AU - Trezzi, Jean-Pierre
AU - Peters, Samantha L.
AU - Daujeumont, Annegrät
AU - Halder, Rashi
AU - Jäger, Christian
AU - Busi, Susheel Bhanu
AU - May, Patrick
AU - Oertel, Wolfgang
AU - Mollenhauer, Brit
AU - Laczny, Cédric C.
AU - Hettich, Robert L.
AU - Wilmes, Paul
N1 - This project has received funding from the European Research Council (ERC) under the European Union’s Horizon 2020 research and innovation program (grant agreement No. 863664). This work was further supported by the Luxembourg National Research Fund (FNR; CORE/ 16/BM/11333923 and CORE/15/BM/10404093), and the Michael J. Fox Foundation under grant No. 14701 to PW. SBB was supported by a Synergia grant (CRSII5_180241) through the Swiss National Science Foundation. The mass spectrometry-based proteome measurements at ORNL were supported by U.S. National Institutes of Health grant 1R01-GM-103600. Oak Ridge National Laboratory is managed by University of Tennessee-Battelle LLC for the Department of Energy under contract DOE-AC05-00OR22725.
PY - 2021/12/21
Y1 - 2021/12/21
N2 - The human gut microbiome produces a complex mixture of biomolecules that interact with human physiology and play essential roles in health and disease. Crosstalk between micro-organisms and host cells is enabled by different direct contacts, but also by the export of molecules through secretion systems and extracellular vesicles. The resulting molecular network, comprised of various biomolecular moieties, has so far eluded systematic study. Here we present a methodological framework, optimized for the extraction of the microbiome-derived, extracellular biomolecular complement, including nucleic acids, (poly)peptides, and metabolites, from flash-frozen stool samples of healthy human individuals. Our method allows simultaneous isolation of individual biomolecular fractions from the same original stool sample, followed by specialized omic analyses. The resulting multi-omics data enable coherent data integration for the systematic characterization of this molecular complex. Our results demonstrate the distinctiveness of the different extracellular biomolecular fractions, both in terms of their taxonomic and functional composition. This highlights the challenge of inferring the extracellular biomolecular complement of the gut microbiome based on single-omic data. The developed methodological framework provides the foundation for systematically investigating mechanistic links between microbiome-secreted molecules, including those that are typically vesicle-associated, and their impact on host physiology in health and disease.
AB - The human gut microbiome produces a complex mixture of biomolecules that interact with human physiology and play essential roles in health and disease. Crosstalk between micro-organisms and host cells is enabled by different direct contacts, but also by the export of molecules through secretion systems and extracellular vesicles. The resulting molecular network, comprised of various biomolecular moieties, has so far eluded systematic study. Here we present a methodological framework, optimized for the extraction of the microbiome-derived, extracellular biomolecular complement, including nucleic acids, (poly)peptides, and metabolites, from flash-frozen stool samples of healthy human individuals. Our method allows simultaneous isolation of individual biomolecular fractions from the same original stool sample, followed by specialized omic analyses. The resulting multi-omics data enable coherent data integration for the systematic characterization of this molecular complex. Our results demonstrate the distinctiveness of the different extracellular biomolecular fractions, both in terms of their taxonomic and functional composition. This highlights the challenge of inferring the extracellular biomolecular complement of the gut microbiome based on single-omic data. The developed methodological framework provides the foundation for systematically investigating mechanistic links between microbiome-secreted molecules, including those that are typically vesicle-associated, and their impact on host physiology in health and disease.
UR - https://pubmed.ncbi.nlm.nih.gov/35106519
U2 - 10.1038/s43705-021-00078-0
DO - 10.1038/s43705-021-00078-0
M3 - Article
C2 - 35106519
SN - 2730-6151
VL - 1
JO - ISME Communications
JF - ISME Communications
IS - 1
ER -