Cooperation is beneficial for the species as a whole, but, at the level of an
individual, defection pays off. Natural selection is then expected to favor
defectors and eliminate cooperation. This prediction is in stark contrast with
the abundance of cooperation at all levels of biological systems: from cells
cooperating to form a biofilm or an organism to ecosystems and human societies.
Several explanations have been proposed to resolve this paradox, including
direct reciprocity, kin, and group selection. However, our work builds upon an
observation that selection on cooperators might depend both on their relative
frequency in the population and on the population density. We find that this
feedback between the population and evolutionary dynamics can substantially
increase the frequency of cooperators at the front of an expanding population,
and can even lead to a splitting of cooperators from defectors. After
splitting, only cooperators colonize new territories, while defectors slowly
invade them from behind. Since range expansions are very common in nature, our
work provides a new explanation of the maintenance of cooperation

Korolev, Kirill S.

English

arXiv

Species expand their geographical ranges following an environmental change, long range dispersal, or a new adaptation. Range expansions not only bring an ecological change, but also affect the evolution of the expanding species. Although the dynamics of deleterious, neutral, and beneficial mutations have been extensively studied in expanding populations, the fate of alleles under frequency-dependent selection remains largely unexplored. The dynamics of cooperative alleles are particularly interesting because selection can be both frequency and density dependent, resulting in a coupling between population and evolutionary dynamics. This coupling leads to an increase in the frequency of cooperators at the expansion front, and, under certain conditions, the entire front can be taken over by cooperators. Thus, a mixed population wave can split into an expansion wave of only cooperators followed by an invasion wave of defectors. After the splitting, cooperators increase in abundance by expanding into new territories faster than they are invaded by defectors. Our results not only provide an explanation for the maintenance of cooperation but also elucidate the effect of eco-evolutionary feedback on the maintenance of genetic diversity during range expansions. When cooperators do not split away, we find that defectors can spread much faster with cooperators than they would be able to on their own or by invading cooperators. This enhanced rate of expansion in mixed waves could counterbalance the loss of genetic diversity due to the founder effect for mutations under frequency-dependent selection. Although we focus on cooperator-defector interactions, our analysis could also be relevant for other systems described by reaction-diffusion equations

Kirill S Korolev

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PLoS Computational Biology

The fate of cooperation during range expansions.

Korolev, Kirill Sergeevich

DSpace@MIT

The Fate of Cooperation during Range Expansions

Korolev Kirill S.

Public Library of Science (PLOS)

Kirill S. Korolev

CiteSeerX

<div><p>Species expand their geographical ranges following an environmental change, long range dispersal, or a new adaptation. Range expansions not only bring an ecological change, but also affect the evolution of the expanding species. Although the dynamics of deleterious, neutral, and beneficial mutations have been extensively studied in expanding populations, the fate of alleles under frequency-dependent selection remains largely unexplored. The dynamics of cooperative alleles are particularly interesting because selection can be both frequency and density dependent, resulting in a coupling between population and evolutionary dynamics. This coupling leads to an increase in the frequency of cooperators at the expansion front, and, under certain conditions, the entire front can be taken over by cooperators. Thus, a mixed population wave can split into an expansion wave of only cooperators followed by an invasion wave of defectors. After the splitting, cooperators increase in abundance by expanding into new territories faster than they are invaded by defectors. Our results not only provide an explanation for the maintenance of cooperation but also elucidate the effect of eco-evolutionary feedback on the maintenance of genetic diversity during range expansions. When cooperators do not split away, we find that defectors can spread much faster with cooperators than they would be able to on their own or by invading cooperators. This enhanced rate of expansion in mixed waves could counterbalance the loss of genetic diversity due to the founder effect for mutations under frequency-dependent selection. Although we focus on cooperator-defector interactions, our analysis could also be relevant for other systems described by reaction-diffusion equations.</p> </div

Kirill S. Korolev (395827)

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The fate of cooperation during range expansions

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The fate of cooperation during range expansions

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