Issue 18, 2015

Patchiness in a microhabitat chip affects evolutionary dynamics of bacterial cooperation

Abstract

Localized interactions are predicted to favour the evolution of cooperation amongst individuals within a population. One important factor that can localize interactions is habitat patchiness. We hypothesize that habitats with greater patchiness (greater edge-to-area ratio) can facilitate the maintenance of cooperation. This outcome is believed to be particularly relevant in pathogenic microbes that can inhabit patchy habitats such as the human respiratory tract. To test this hypothesis in a simple but spatially controlled setting, we designed a transparent microhabitat chip (MHC) with multiple patchiness treatments at the 100 micron scale. The MHC is a closed system that sustains bacterial replication and survival for up to 18 hours, and allows spatial patterns and eco-evolutionary dynamics to be observed undisturbed. Using the opportunistic pathogen Pseudomonas aeruginosa, we tracked the growth of wild-type cooperators, which produce the public good pyoverdin, in competition with mutant defectors or cheaters that use, but do not produce, pyoverdin. We found that while defectors on average outperformed cooperators in all habitats, habitat patchiness significantly alleviated the ecological pressure against cooperation due to defection, leading to coexistence. Our results confirmed that habitat-level spatial heterogeneity can be important for cooperation. The MHC enables novel experiments, allows multiple parameters to be precisely varied and studied simultaneously, and will help uncover dynamical features of spatial ecology and the evolution of pathogens.

Graphical abstract: Patchiness in a microhabitat chip affects evolutionary dynamics of bacterial cooperation

Supplementary files

Article information

Article type
Paper
Submitted
24 May 2015
Accepted
24 Jul 2015
First published
24 Jul 2015

Lab Chip, 2015,15, 3723-3729

Author version available

Patchiness in a microhabitat chip affects evolutionary dynamics of bacterial cooperation

E. W. Tekwa, D. Nguyen, D. Juncker, M. Loreau and A. Gonzalez, Lab Chip, 2015, 15, 3723 DOI: 10.1039/C5LC00576K

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