Abstract
Heterotrophic bacteria—bacteria that utilize organic carbon sources—are taxonomically and functionally diverse across environments. It is challenging to map metabolic interactions and niches within microbial communities due to the large number of metabolites that could serve as potential carbon and energy sources for heterotrophs. Whether their metabolic niches can be understood using general principles, such as a small number of simplified metabolic categories, is unclear. Here we perform high-throughput metabolic profiling of 186 marine heterotrophic bacterial strains cultured in media containing one of 135 carbon substrates to determine growth rates, lag times and yields. We show that, despite high variability at all levels of taxonomy, the catabolic niches of heterotrophic bacteria can be understood in terms of their preference for either glycolytic (sugars) or gluconeogenic (amino and organic acids) carbon sources. This preference is encoded by the total number of genes found in pathways that feed into the two modes of carbon utilization and can be predicted using a simple linear model based on gene counts. This allows for coarse-grained descriptions of microbial communities in terms of prevalent modes of carbon catabolism. The sugar–acid preference is also associated with genomic GC content and thus with the carbon–nitrogen requirements of their encoded proteome. Our work reveals how the evolution of bacterial genomes is structured by fundamental constraints rooted in metabolism.
| Original language | English |
|---|---|
| Pages (from-to) | 1799-1808 |
| Number of pages | 10 |
| Journal | NATURE MICROBIOLOGY |
| Volume | 8 |
| Issue number | 10 |
| Early online date | 31 Aug 2023 |
| DOIs | |
| Publication status | Published - Oct 2023 |
Bibliographical note
Funding Information:We thank S. Estrela (Yale University and Stanford University) for providing community composition data from their enrichment experiments (Fig. ); A. Sichert for assembling genomes; and M. d. Bello, X. Shan, T. Hwa as well as all members of the Cordero laboratory and Simons PriME collaboration for their enriching discussions. We acknowledge funding from the Simons Collaboration: Principles of Microbial Ecosystems (PriME) award number 542395 (O.X.C.) and Simons Foundation Postdoctoral Fellowship Award number 599207 (M.G.).
Publisher Copyright:
© 2023, The Author(s), under exclusive licence to Springer Nature Limited.
Funding
We thank S. Estrela (Yale University and Stanford University) for providing community composition data from their enrichment experiments (Fig. ); A. Sichert for assembling genomes; and M. d. Bello, X. Shan, T. Hwa as well as all members of the Cordero laboratory and Simons PriME collaboration for their enriching discussions. We acknowledge funding from the Simons Collaboration: Principles of Microbial Ecosystems (PriME) award number 542395 (O.X.C.) and Simons Foundation Postdoctoral Fellowship Award number 599207 (M.G.). We thank S. Estrela (Yale University and Stanford University) for providing community composition data from their enrichment experiments (Fig. 4d); A. Sichert for assembling genomes; and M. d. Bello, X. Shan, T. Hwa as well as all members of the Cordero laboratory and Simons PriME collaboration for their enriching discussions. We acknowledge funding from the Simons Collaboration: Principles of Microbial Ecosystems (PriME) award number 542395 (O.X.C.) and Simons Foundation Postdoctoral Fellowship Award number 599207 (M.G.).
| Funders | Funder number |
|---|---|
| Simons Collaboration: Principles of Microbial Ecosystems | |
| Simons Foundation | 599207 |
| Yale University | |
| Stanford University | |
| H2020 Environment | 542395 |