Spatial Population Expansion Promotes the Evolution of Cooperation in an Experimental Prisoner’s Dilemma

Cooperation is ubiquitous in nature, but explaining its existence remains a central interdisciplinary challenge [1–3]. Cooperation is most difficult to explain in the Prisoner’s Dilemma game, where cooperators always lose in direct competition with defectors despite increasing mean fitness [1, 4, 5]...

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Published in:Current biology 2013-05, Vol.23 (10), p.919-923
Main Authors: Van Dyken, J. David, Müller, Melanie J.I., Mack, Keenan M.L., Desai, Michael M.
Format: Article
Language:English
Subjects:
Cooperative Behavior
evolution
Game Theory
humans
invasive species
pathogens
phenotype
Saccharomyces cerevisiae
Saccharomyces cerevisiae - physiology
yeasts
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Summary:Cooperation is ubiquitous in nature, but explaining its existence remains a central interdisciplinary challenge [1–3]. Cooperation is most difficult to explain in the Prisoner’s Dilemma game, where cooperators always lose in direct competition with defectors despite increasing mean fitness [1, 4, 5]. Here we demonstrate how spatial population expansion, a widespread natural phenomenon [6–11], promotes the evolution of cooperation. We engineer an experimental Prisoner’s Dilemma game in the budding yeast Saccharomyces cerevisiae to show that, despite losing to defectors in nonexpanding conditions, cooperators increase in frequency in spatially expanding populations. Fluorescently labeled colonies show genetic demixing [8] of cooperators and defectors, followed by increase in cooperator frequency as cooperator sectors overtake neighboring defector sectors. Together with lattice-based spatial simulations, our results suggest that spatial population expansion drives the evolution of cooperation by (1) increasing positive genetic assortment at population frontiers and (2) selecting for phenotypes maximizing local deme productivity. Spatial expansion thus creates a selective force whereby cooperator-enriched demes overtake neighboring defector-enriched demes in a “survival of the fastest.” We conclude that colony growth alone can promote cooperation and prevent defection in microbes. Our results extend to other species with spatially restricted dispersal undergoing range expansion, including pathogens, invasive species, and humans. •Spatial population expansion selects for cooperation at population frontiers•Spatial expansion causes high genetic relatedness and strong intergroup competition•“Survival of the fastest” at expanding frontiers selects for high group productivity•Colony growth promotes microbial cooperation and helps suppress cheaters
ISSN:0960-9822
1879-0445
DOI:10.1016/j.cub.2013.04.026