Generation of genome-scale metabolic reconstructions for 773 members of the human gut microbiota

Magnúsdóttir, Stefanía; Heinken, Almut; Kutt, Laura; Ravcheev, Dmitry A.; Bauer, Eugen; Noronha, Alberto; Greenhalgh, Kacy; Jäger, Christian; Bagińska, Joanna; Wilmes, Paul; Fleming, Ronan M. T.; Thiele, Ines

doi:10.1038/nbt.3703

Cited by 625 publications

(835 citation statements)

References 70 publications

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“…In a recent study from our group, the growth of 96 phylogenetically diverse gut bacteria was characterized across 19 different media (15 defined and 4 complex media compositions) (43). From this list, a total of 47 bacteria are also included in the AGORA collection, a recently published collection of 773 semi-manually curated models of human gut bacteria (57). These models, however, could not reproduce the metabolic needs experimentally observed by Tramontano et al ., highlighting the need for the use of validated growth media for species that are distant from model organisms.…”

Section: Resultsmentioning

confidence: 99%

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

Machado

Andrejev

Tramontano

et al. 2018

Nucleic Acids Research

450

542

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Genome-scale metabolic models are instrumental in uncovering operating principles of cellular metabolism, for model-guided re-engineering, and unraveling cross-feeding in microbial communities. Yet, the application of genome-scale models, especially to microbial communities, is lagging behind the availability of sequenced genomes. This is largely due to the time-consuming steps of manual curation required to obtain good quality models. 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 show that CarveMe models perform closely to manually curated models in reproducing experimental phenotypes (substrate utilization and gene essentiality). Additionally, we build a collection of 74 models for human gut bacteria and test their ability to reproduce growth on a set of experimentally defined media. Finally, we create a database of 5587 bacterial models and demonstrate its potential for fast generation of microbial community 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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Section: Resultsmentioning

confidence: 99%

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

Machado

Andrejev

Tramontano

et al. 2018

Nucleic Acids Research

450

542

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“…Humans acquire riboflavin (vitamin B 2 ) both through their diet and from riboflavin-producing gut microbes. The machinery required for riboflavin synthesis has been found in the genomes of most Bacteroidetes, Fusobacteria, and Proteobacteria examined, while a complete riboflavin operon was only present in about half of the Firmicutes and almost no Actinobacteria (44, 61). Riboflavin can be used as a redox mediator by Faecalibacterium prausnitzii to facilitate extracellular electron transfer, which consequently promotes its growth (34).…”

Section: Gwas Reveal Tissues Pathways and Genes Consistently Associmentioning

confidence: 99%

The Relationship Between the Human Genome and Microbiome Comes into View

et al. 2017

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The microbiome’s involvement in health and disease, and the complexity of its composition and function, make it intriguing to consider human genetic factors that impact microbiome composition. Genes may influence health through their ability to promote a stable microbial community in the gut. Studies of heritability yield a consistent subset of microbes that are impacted by genes, but the use of genome-wide association studies (GWAS) to identify specific genetic variants associated with microbiota phenotypes has proven challenging. Processing microbiome datasets into traits to be modeled and reducing the burden of multiple testing are just some of the technical hurdles in microbiome GWAS. Studies to date are small by GWAS standards, making cross-study comparisons and validations particularly important in identifying authentic signals. Cross-study comparisons are hampered by differences in analytical approaches. Nevertheless, some consistent associations have emerged between populations, most notably between Bifidobacteria and the lactase non-persister genotype. These early successes open the way for the microbiome to be incorporated into studies that quantify interactions among genotype, environment, and the microbiome for predicting disease susceptibility.

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“…The analysis of associations between these metabolite patterns and psychiatric symptoms calls for application of state of the art systems biology approaches and subsequent intervention studies to validate candidate metabolites. Recent advances in analysis of the complete metabolic repertoire of 753 bacterial strains [49] already make it possible to predict which metabolites are produced in ensembles of bacteria allowing development of targeted metabolomics.…”

Section: Introductionmentioning

confidence: 99%

Gut microbiota, metabolism and psychopathology: A critical review and novel perspectives

Groen

Clercq

Nieuwdorp

et al. 2018

Critical Reviews in Clinical Laboratory Sciences

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Generation of genome-scale metabolic reconstructions for 773 members of the human gut microbiota

Cited by 625 publications

References 70 publications

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

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

The Relationship Between the Human Genome and Microbiome Comes into View

Gut microbiota, metabolism and psychopathology: A critical review and novel perspectives

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