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- Title
Revealing proteome-level functional redundancy in the human gut microbiome using ultra-deep metaproteomics.
- Authors
Li, Leyuan; Wang, Tong; Ning, Zhibin; Zhang, Xu; Butcher, James; Serrana, Joeselle M.; Simopoulos, Caitlin M. A.; Mayne, Janice; Stintzi, Alain; Mack, David R.; Liu, Yang-Yu; Figeys, Daniel
- Abstract
Functional redundancy is a key ecosystem property representing the fact that different taxa contribute to an ecosystem in similar ways through the expression of redundant functions. The redundancy of potential functions (or genome-level functional redundancy FR g ) of human microbiomes has been recently quantified using metagenomics data. Yet, the redundancy of expressed functions in the human microbiome has never been quantitatively explored. Here, we present an approach to quantify the proteome-level functional redundancy FR p in the human gut microbiome using metaproteomics. Ultra-deep metaproteomics reveals high proteome-level functional redundancy and high nestedness in the human gut proteomic content networks (i.e., the bipartite graphs connecting taxa to functions). We find that the nested topology of proteomic content networks and relatively small functional distances between proteomes of certain pairs of taxa together contribute to high FR p in the human gut microbiome. As a metric comprehensively incorporating the factors of presence/absence of each function, protein abundances of each function and biomass of each taxon, FR p outcompetes diversity indices in detecting significant microbiome responses to environmental factors, including individuality, biogeography, xenobiotics, and disease. We show that gut inflammation and exposure to specific xenobiotics can significantly diminish the FR p with no significant change in taxonomic diversity. Here, Li et al. show that functional redundancy, which has not previously been quantified at the proteome level, can arise when different microbes play similar roles in the gut microbiome, revealing that proteomes are nested among gut microbes, favoring high functional redundancy.
- Subjects
GUT microbiome; HUMAN microbiota; BIPARTITE graphs; BIOMASS; XENOBIOTICS
- Publication
Nature Communications, 2023, Vol 14, Issue 1, p1
- ISSN
2041-1723
- Publication type
Article
- DOI
10.1038/s41467-023-39149-2