Fast automated reconstruction of genome-scale metabolic models for microbial species and communities

AbstractGenome-scale metabolic models are instrumental in uncovering operating principles of cellular metabolism and model-guided re-engineering. Recent applications of metabolic models have also demonstrated their usefulness in unraveling cross-feeding within microbial communities. Yet, the application of genome-scale models, especially to microbial communities, is lagging far behind the availability of sequenced genomes. This is largely due to the time-consuming steps of manual cura-tion required to obtain good quality models and thus physiologically meaningful simulation results. Here, we present an automated tool – CarveMe – for reconstruction of species and community level metabolic models. We introduce the concept of a universal model, which is manually curated and simulation-ready. Starting with this universal model and annotated genome sequences, CarveMe uses a top-down approach to build single-species and community models in a fast and scalable manner. We build reconstructions for two model organisms, Escherichia coli and Bacillus subtillis, as well as a collection of human gut bacteria, and show that CarveMe models perform similarly to manually curated models in reproducing experimental phenotypes. Finally, we demonstrate the scalability of CarveMe through reconstructing 5587 bacterial models. Overall, CarveMe provides an open-source and user-friendly tool towards broadening the use of metabolic modeling in studying microbial species and communities.

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Model-based and phylogenetically adjusted quantification of metabolic interaction between microbial species

PLoS Computational Biology ◽

10.1371/journal.pcbi.1007951 ◽

2020 ◽

Vol 16 (10) ◽

pp. e1007951

Author(s):

Tony J. Lam ◽

Moses Stamboulian ◽

Wontack Han ◽

Yuzhen Ye

Keyword(s):

Dominant Role ◽

Bacterial Species ◽

Community Analysis ◽

Microbial Interactions ◽

Phylogenetic Distance ◽

Metabolic Cooperation ◽

Bacterial Interactions ◽

Microbial Species ◽

Metabolic Models ◽

Genome Scale

Microbial community members exhibit various forms of interactions. Taking advantage of the increasing availability of microbiome data, many computational approaches have been developed to infer bacterial interactions from the co-occurrence of microbes across diverse microbial communities. Additionally, the introduction of genome-scale metabolic models have also enabled the inference of cooperative and competitive metabolic interactions between bacterial species. By nature, phylogenetically similar microbial species are more likely to share common functional profiles or biological pathways due to their genomic similarity. Without properly factoring out the phylogenetic relationship, any estimation of the competition and cooperation between species based on functional/pathway profiles may bias downstream applications. To address these challenges, we developed a novel approach for estimating the competition and complementarity indices for a pair of microbial species, adjusted by their phylogenetic distance. An automated pipeline, PhyloMint, was implemented to construct competition and complementarity indices from genome scale metabolic models derived from microbial genomes. Application of our pipeline to 2,815 human-gut associated bacteria showed high correlation between phylogenetic distance and metabolic competition/cooperation indices among bacteria. Using a discretization approach, we were able to detect pairs of bacterial species with cooperation scores significantly higher than the average pairs of bacterial species with similar phylogenetic distances. A network community analysis of high metabolic cooperation but low competition reveals distinct modules of bacterial interactions. Our results suggest that niche differentiation plays a dominant role in microbial interactions, while habitat filtering also plays a role among certain clades of bacterial species.

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Critical assessment of genome-scale metabolic models of Arabidopsis thaliana

Molecular Omics ◽

10.1039/d1mo00351h ◽

2022 ◽

Author(s):

Javad Zamani ◽

Sayed-Amir Marashi ◽

Tahmineh Lohrasebi ◽

Mohammad-Ali Malboobi ◽

Esmail Foroozan

Keyword(s):

Arabidopsis Thaliana ◽

Flux Balance Analysis ◽

Critical Assessment ◽

Flux Balance ◽

Balance Analysis ◽

Metabolic Models ◽

Living Organisms ◽

Genome Scale

Genome-scale metabolic models (GSMMs) have enabled researchers to perform systems-level studies of living organisms. As a constraint-based technique, flux balance analysis (FBA) aids computation of reaction fluxes and prediction of...

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Model-guided identification of novel gene amplification targets for improving succinate production in Escherichia coli NZN111

Integrative Biology ◽

10.1039/c7ib00077d ◽

2017 ◽

Vol 9 (10) ◽

pp. 830-835 ◽

Cited By ~ 2

Author(s):

Xingxing Jian ◽

Ningchuan Li ◽

Qian Chen ◽

Qiang Hua

Keyword(s):

Escherichia Coli ◽

Metabolic Engineering ◽

Gene Amplification ◽

Metabolic Networks ◽

Computational Analysis ◽

Succinate Production ◽

Novel Gene ◽

Metabolic Models ◽

Genome Scale

Reconstruction and application of genome-scale metabolic models (GEMs) have facilitated metabolic engineering by providing a platform on which systematic computational analysis of metabolic networks can be performed.

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A metabolite-centric view on flux distributions in genome-scale metabolic models

BMC Systems Biology ◽

10.1186/1752-0509-7-33 ◽

2013 ◽

Vol 7 (1) ◽

pp. 33 ◽

Cited By ~ 14

Author(s):

S Riemer ◽

René Rex ◽

Dietmar Schomburg

Keyword(s):

Metabolic Models ◽

Genome Scale

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Consistency, Inconsistency and Ambiguity of Metabolite Names in Biochemical Databases Used for Genome Scale Metabolic Modelling

10.1101/503664 ◽

2018 ◽

Cited By ~ 1

Author(s):

Nhung Pham ◽

Ruben Van Heck ◽

Jesse van Dam ◽

Peter Schaap ◽

Edoardo Saccenti ◽

...

Keyword(s):

Systems Medicine ◽

Biochemical Reactions ◽

Metabolic Modelling ◽

Research Areas ◽

Limit Model ◽

Metabolic Models ◽

Genome Scale ◽

Manual Verification

Genome scale metabolic models (GEMs) are manually curated repositories describing the metabolic capabilities of an organism. GEMs have been successfully used in different research areas, ranging from systems medicine to biotechnology. However, the different naming conventions (namespaces) of databases used to build GEMs limit model reusability and prevent the integration of existing models. This problem is known in the GEM community but its extent has not been analyzed in depth. In this study, we investigate the name ambiguity and the multiplicity of non-systematic identifiers and we highlight the (in)consistency in their use in eleven biochemical databases of biochemical reactions and the problems that arise when mapping between different namespaces and databases. We found that such inconsistencies can be as high as 83.1%, thus emphasizing the need for strategies to deal with these issues. Currently, manual verification of the mappings appears to be the only solution to remove inconsistencies when combining models. Finally, we discuss several possible approaches to facilitate (future) unambiguous mapping.

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