Allee effect promotes diversity in traveling waves of colonization

Most mathematical studies on expanding populations have focused on the rate of range expansion of a population. However, the genetic consequences of population expansion remain an understudied body of theory. Describing an expanding population as a traveling wave solution derived from a classical re...

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Bibliographic Details
Published in:Proceedings of the National Academy of Sciences - PNAS 2012-06, Vol.109 (23), p.8828-8833
Main Authors: Roques, Lionel, Garnier, Jimmy, Hamel, François, Klein, Etienne K.
Format: Article
Language:English
Subjects:
Analysis of PDEs
Biological Sciences
Computer Simulation
Demography
Evolution
Fractions
Genetic diversity
Genetic Variation
Genetics, Population
Mathematical models
Mathematics
Modeling
Models, Biological
Physical Sciences
Population
Population Density
Population Dynamics
Population genetics
Population growth rate
Population structure
Surfing
Traveling waves
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Summary:Most mathematical studies on expanding populations have focused on the rate of range expansion of a population. However, the genetic consequences of population expansion remain an understudied body of theory. Describing an expanding population as a traveling wave solution derived from a classical reaction-diffusion model, we analyze the spatio-temporal evolution of its genetic structure. We show that the presence of an Allee effect (i.e., a lower per capita growth rate at low densities) drastically modifies genetic diversity, both in the colonization front and behind it. With an Allee effect (i.e., pushed colonization waves), all of the genetic diversity of a population is conserved in the colonization front. In the absence of an Allee effect (i.e., pulled waves), only the furthest forward members of the initial population persist in the colonization front, indicating a strong erosion of the diversity in this population. These results counteract commonly held notions that the Allee effect generally has adverse consequences. Our study contributes new knowledge to the surfing phenomenon in continuous models without random genetic drift. It also provides insight into the dynamics of traveling wave solutions and leads to a new interpretation of the mathematical notions of pulled and pushed waves.
ISSN:0027-8424
1091-6490
DOI:10.1073/pnas.1201695109