Metabolic specialization and the assembly of microbial communities

Metabolic specialization is a general biological principle that shapes the assembly of microbial communities. Individual cell types rarely metabolize a wide range of substrates within their environment. Instead, different cell types often specialize at metabolizing only subsets of the available substrates. What is the advantage of metabolizing subsets of the available substrates rather than all of them? In this perspective piece, we argue that biochemical conflicts between different metabolic processes can promote metabolic specialization and that a better understanding of these conflicts is therefore important for revealing the general principles and rules that govern the assembly of microbial communities. We first discuss three types of biochemical conflicts that could promote metabolic specialization. Next, we demonstrate how knowledge about the consequences of biochemical conflicts can be used to predict whether different metabolic processes are likely to be performed by the same cell type or by different cell types. We then discuss the major challenges in identifying and assessing biochemical conflicts between different metabolic processes and propose several approaches for their measurement. Finally, we argue that a deeper understanding of the biochemical causes of metabolic specialization could serve as a foundation for the field of synthetic ecology, where the objective would be to rationally engineer the assembly of a microbial community to perform a desired biotransformation.

[1]  Maitreya J. Dunham,et al.  Synthetic ecology: A model system for cooperation , 2007, Proceedings of the National Academy of Sciences.

[2]  Inna Dubchak,et al.  The integrated microbial genomes (IMG) system , 2005, Nucleic Acids Res..

[3]  R. MacLean,et al.  Constraints on microbial metabolism drive evolutionary diversification in homogeneous environments , 2007, Journal of evolutionary biology.

[4]  Joshua S Weitz,et al.  An integrative approach to understanding microbial diversity: from intracellular mechanisms to community structure , 2010, Ecology letters.

[5]  Nigel F. Delaney,et al.  Darwinian Evolution Can Follow Only Very Few Mutational Paths to Fitter Proteins , 2006, Science.

[6]  R. Lenski,et al.  The population genetics of ecological specialization in evolving Escherichia coli populations , 2000, Nature.

[7]  Anu Raghunathan,et al.  Comparative genome sequencing of Escherichia coli allows observation of bacterial evolution on a laboratory timescale , 2006, Nature Genetics.

[8]  U. Alon,et al.  Optimality and evolutionary tuning of the expression level of a protein , 2005, Nature.

[9]  M. Saier Families of transmembrane sugar transport proteins , 2000, Molecular microbiology.

[10]  R. MacLean,et al.  Resource competition and social conflict in experimental populations of yeast , 2006, Nature.

[11]  L. Wackett,et al.  Molecular Basis of a Bacterial Consortium: Interspecies Catabolism of Atrazine , 2000, Applied and Environmental Microbiology.

[12]  M. Doebeli,et al.  Complexity and Diversity , 2010, Science.

[13]  C. M. Pease,et al.  A critique of methods for measuring life history trade‐offs , 1988 .

[14]  A. F. Bennett,et al.  Experimental tests of the roles of adaptation, chance, and history in evolution. , 1995, Science.

[15]  Huan‐Xiang Zhou,et al.  Macromolecular crowding and confinement: biochemical, biophysical, and potential physiological consequences. , 2008, Annual review of biophysics.

[16]  Jeffrey E. Barrick,et al.  Genome evolution and adaptation in a long-term experiment with Escherichia coli , 2009, Nature.

[17]  M. Doebeli,et al.  A model for the evolutionary dynamics of cross-feeding polymorphisms in microorganisms , 2002, Population Ecology.

[18]  R. Lenski,et al.  Negative Epistasis Between Beneficial Mutations in an Evolving Bacterial Population , 2011, Science.

[19]  Timothy S. Ham,et al.  Production of the antimalarial drug precursor artemisinic acid in engineered yeast , 2006, Nature.

[20]  B. Kerr,et al.  Big questions, small worlds: microbial model systems in ecology. , 2004, Trends in ecology & evolution.

[21]  M. A. de Menezes,et al.  Intracellular crowding defines the mode and sequence of substrate uptake by Escherichia coli and constrains its metabolic activity , 2007, Proceedings of the National Academy of Sciences.

[22]  B. Palsson,et al.  Escherichia coli K-12 undergoes adaptive evolution to achieve in silico predicted optimal growth , 2002, Nature.

[23]  J. Kreft,et al.  Why is metabolic labour divided in nitrification? , 2006, Trends in microbiology.

[24]  Souichiro Kato,et al.  Stable Coexistence of Five Bacterial Strains as a Cellulose-Degrading Community , 2005, Applied and Environmental Microbiology.

[25]  Susan M. Huse,et al.  Microbial Population Structures in the Deep Marine Biosphere , 2007, Science.

[26]  Dan S. Tawfik,et al.  The 'evolvability' of promiscuous protein functions , 2005, Nature Genetics.

[27]  P. Rainey,et al.  The ecology and genetics of microbial diversity. , 2004, Annual review of microbiology.

[28]  C. Gross,et al.  Multiple sigma subunits and the partitioning of bacterial transcription space. , 2003, Annual review of microbiology.

[29]  R. Lenski,et al.  Microbial genetics: Evolution experiments with microorganisms: the dynamics and genetic bases of adaptation , 2003, Nature Reviews Genetics.

[30]  Rick L. Stevens,et al.  The RAST Server: Rapid Annotations using Subsystems Technology , 2008, BMC Genomics.

[31]  Thomas P. Curtis,et al.  Estimating prokaryotic diversity and its limits , 2002, Proceedings of the National Academy of Sciences of the United States of America.

[32]  M. Doebeli,et al.  Epistasis and frequency dependence influence the fitness of an adaptive mutation in a diversifying lineage , 2010, Molecular ecology.

[33]  S. Bonhoeffer,et al.  Evolution of Cross‐Feeding in Microbial Populations , 2004, The American Naturalist.

[34]  Anton van Leeuwenhoek Environmental Shotgun Sequencing : Its Potential and Challenges for Studying the Hidden World of Microbes , 2007 .

[35]  P. Fay Oxygen relations of nitrogen fixation in cyanobacteria. , 1992, Microbiological reviews.

[36]  Murray Wolinsky,et al.  Response to Comment by Volkov et al. on "Computational Improvements Reveal Great Bacterial Diversity and High Metal Toxicity in Soil" , 2006, Science.

[37]  T. Ferenci,et al.  Maintaining a healthy SPANC balance through regulatory and mutational adaptation , 2005, Molecular microbiology.

[38]  K. Timmis,et al.  Towards elucidation of microbial community metabolic pathways: unravelling the network of carbon sharing in a pollutant-degrading bacterial consortium by immunocapture and isotopic ratio mass spectrometry. , 1999, Environmental microbiology.

[39]  T. Hwa,et al.  Interdependence of Cell Growth and Gene Expression: Origins and Consequences , 2010, Science.