Pairing metagenomics and metaproteomics to characterize ecological niches and metabolic essentiality of gut microbiomes

Tong Wang; Leyuan Li; Daniel Figeys; Yang-Yu Liu

doi:10.1093/ismeco/ycae063

Pairing metagenomics and metaproteomics to characterize ecological niches and metabolic essentiality of gut microbiomes

Tong Wang, Leyuan Li, Daniel Figeys, Yang-Yu Liu

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

4 Citations (Scopus)

Abstract

The genome of a microorganism encodes its potential functions that can be implemented through expressed proteins. It remains elusive how a protein's selective expression depends on its metabolic essentiality to microbial growth or its ability to claim resources as ecological niches. To reveal a protein's metabolic or ecological role, we developed a computational pipeline, which pairs metagenomics and metaproteomics data to quantify each protein's gene-level and protein-level functional redundancy simultaneously. We first illustrated the idea behind the pipeline using simulated data of a consumer-resource model. We then validated it using real data from human and mouse gut microbiome samples. In particular, we analyzed ABC-type transporters and ribosomal proteins, confirming that the metabolic and ecological roles predicted by our pipeline agree well with prior knowledge. Finally, we performed in vitro cultures of a human gut microbiome sample and investigated how oversupplying various sugars involved in ecological niches influences the community structure and protein abundance. The presented results demonstrate the performance of our pipeline in identifying proteins' metabolic and ecological roles, as well as its potential to help us design nutrient interventions to modulate the human microbiome.

Original language	English
Article number	ycae063
Pages (from-to)	ycae063
Journal	ISME Communications
Volume	4
Issue number	1
Early online date	1 May 2024
DOIs	https://doi.org/10.1093/ismeco/ycae063
Publication status	Published - 2024

Keywords

ecological niche functional redundancy gut microbiome metabolic essentiality metagenomics metaproteomics
metaproteomics
functional redundancy
gut microbiome
metagenomics
metabolic essentiality
ecological niche

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10.1093/ismeco/ycae063Licence: CC BY

ycae063Final published version, 2.6 MBLicence: CC BY

https://www.ncbi.nlm.nih.gov/pubmed/38808120

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title = "Pairing metagenomics and metaproteomics to characterize ecological niches and metabolic essentiality of gut microbiomes",

abstract = "The genome of a microorganism encodes its potential functions that can be implemented through expressed proteins. It remains elusive how a protein's selective expression depends on its metabolic essentiality to microbial growth or its ability to claim resources as ecological niches. To reveal a protein's metabolic or ecological role, we developed a computational pipeline, which pairs metagenomics and metaproteomics data to quantify each protein's gene-level and protein-level functional redundancy simultaneously. We first illustrated the idea behind the pipeline using simulated data of a consumer-resource model. We then validated it using real data from human and mouse gut microbiome samples. In particular, we analyzed ABC-type transporters and ribosomal proteins, confirming that the metabolic and ecological roles predicted by our pipeline agree well with prior knowledge. Finally, we performed in vitro cultures of a human gut microbiome sample and investigated how oversupplying various sugars involved in ecological niches influences the community structure and protein abundance. The presented results demonstrate the performance of our pipeline in identifying proteins' metabolic and ecological roles, as well as its potential to help us design nutrient interventions to modulate the human microbiome.",

keywords = "ecological niche functional redundancy gut microbiome metabolic essentiality metagenomics metaproteomics, metaproteomics, functional redundancy, gut microbiome, metagenomics, metabolic essentiality, ecological niche",

author = "Tong Wang and Leyuan Li and Daniel Figeys and Yang-Yu Liu",

note = "Data and code availability: All code for simulations used in this manuscript can be found at https://github.com/wt1005203/ecological_niches. Funding information: D.F. acknowledges grants from Natural Sciences and Engineering Research Council of Canada (NSERC), and the Government of Canada through Genome Canada and the Ontario Genomics Institute (OGI-114 and OGI-149). D.F. acknowledges a Distinguished Research Chair from the University of Ottawa. Y.-Y.L. is supported by grants R01AI141529, R01HD093761, RF1AG067744, UH3OD023268, U19AI095219, and U01HL089856 from the National Institutes of Health, USA; a pilot grant from the Biology of Trauma Initiative of Broad Institute, USA; and the Office of the Assistant Secretary of Defense for Health Affairs, through the Traumatic Brain Injury and Psychological Health Research Program (Focused Program Award) under award no. (W81XWH-22-S-TBIPH2), endorsed by the Department of Defense, USA.",

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AU - Liu, Yang-Yu

N1 - Data and code availability: All code for simulations used in this manuscript can be found at https://github.com/wt1005203/ecological_niches. Funding information: D.F. acknowledges grants from Natural Sciences and Engineering Research Council of Canada (NSERC), and the Government of Canada through Genome Canada and the Ontario Genomics Institute (OGI-114 and OGI-149). D.F. acknowledges a Distinguished Research Chair from the University of Ottawa. Y.-Y.L. is supported by grants R01AI141529, R01HD093761, RF1AG067744, UH3OD023268, U19AI095219, and U01HL089856 from the National Institutes of Health, USA; a pilot grant from the Biology of Trauma Initiative of Broad Institute, USA; and the Office of the Assistant Secretary of Defense for Health Affairs, through the Traumatic Brain Injury and Psychological Health Research Program (Focused Program Award) under award no. (W81XWH-22-S-TBIPH2), endorsed by the Department of Defense, USA.

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N2 - The genome of a microorganism encodes its potential functions that can be implemented through expressed proteins. It remains elusive how a protein's selective expression depends on its metabolic essentiality to microbial growth or its ability to claim resources as ecological niches. To reveal a protein's metabolic or ecological role, we developed a computational pipeline, which pairs metagenomics and metaproteomics data to quantify each protein's gene-level and protein-level functional redundancy simultaneously. We first illustrated the idea behind the pipeline using simulated data of a consumer-resource model. We then validated it using real data from human and mouse gut microbiome samples. In particular, we analyzed ABC-type transporters and ribosomal proteins, confirming that the metabolic and ecological roles predicted by our pipeline agree well with prior knowledge. Finally, we performed in vitro cultures of a human gut microbiome sample and investigated how oversupplying various sugars involved in ecological niches influences the community structure and protein abundance. The presented results demonstrate the performance of our pipeline in identifying proteins' metabolic and ecological roles, as well as its potential to help us design nutrient interventions to modulate the human microbiome.

AB - The genome of a microorganism encodes its potential functions that can be implemented through expressed proteins. It remains elusive how a protein's selective expression depends on its metabolic essentiality to microbial growth or its ability to claim resources as ecological niches. To reveal a protein's metabolic or ecological role, we developed a computational pipeline, which pairs metagenomics and metaproteomics data to quantify each protein's gene-level and protein-level functional redundancy simultaneously. We first illustrated the idea behind the pipeline using simulated data of a consumer-resource model. We then validated it using real data from human and mouse gut microbiome samples. In particular, we analyzed ABC-type transporters and ribosomal proteins, confirming that the metabolic and ecological roles predicted by our pipeline agree well with prior knowledge. Finally, we performed in vitro cultures of a human gut microbiome sample and investigated how oversupplying various sugars involved in ecological niches influences the community structure and protein abundance. The presented results demonstrate the performance of our pipeline in identifying proteins' metabolic and ecological roles, as well as its potential to help us design nutrient interventions to modulate the human microbiome.

KW - ecological niche functional redundancy gut microbiome metabolic essentiality metagenomics metaproteomics

KW - metaproteomics

KW - functional redundancy

KW - gut microbiome

KW - metagenomics

KW - metabolic essentiality

KW - ecological niche

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DO - 10.1093/ismeco/ycae063

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ER -

Pairing metagenomics and metaproteomics to characterize ecological niches and metabolic essentiality of gut microbiomes

Abstract

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