Bacterial social interactions drive the emergence of differential spatial colony structures

Bacterial social interactions drive the emergence of differential spatial colony structures

Social interactions have been increasingly recognized as one of the major factors that contribute to the dynamics and function of bacterial communities. To understand their functional roles and enable the design of robust synthetic consortia, one fundamental step is to determine the relationship bet...

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Bibliographic Details
Published in:BMC systems biology Vol. 9; no. 1; p. 59
Main Authors: Blanchard, Andrew E, Lu, Ting
Format: Journal Article
Language:English
Published: England BioMed Central Ltd 16-09-2015
BioMed Central
Subjects:
Analysis
Bacteria - cytology
Bacteria - growth & development
Computational Biology - methods
Consortia
Microbial Interactions
Models, Biological
Social aspects
Spatio-Temporal Analysis
Surveys
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Summary:Social interactions have been increasingly recognized as one of the major factors that contribute to the dynamics and function of bacterial communities. To understand their functional roles and enable the design of robust synthetic consortia, one fundamental step is to determine the relationship between the social interactions of individuals and the spatiotemporal structures of communities. We present a systematic computational survey on this relationship for two-species communities by developing and utilizing a hybrid computational framework that combines discrete element techniques with reaction-diffusion equations. We found that deleterious interactions cause an increased variance in relative abundance, a drastic decrease in surviving lineages, and a rough expanding front. In contrast, beneficial interactions contribute to a reduced variance in relative abundance, an enhancement in lineage number, and a smooth expanding front. We also found that mutualism promotes spatial homogeneity and population robustness while competition increases spatial segregation and population fluctuations. To examine the generality of these findings, a large set of initial conditions with varying density and species abundance was tested and analyzed. In addition, a simplified mathematical model was developed to provide an analytical interpretation of the findings. This work advances our fundamental understanding of bacterial social interactions and population structures and, simultaneously, benefits synthetic biology for facilitated engineering of artificial microbial consortia.
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ISSN:1752-0509
1752-0509
DOI:10.1186/s12918-015-0188-5