Delayed evolutionary branching in small populations

Authored by David Claessen, Roos Andre M de, Jens Andersson, Lennart Persson

Date Published: 2007

Sponsors: Netherlands Organization for Scientific Research (NWO)

Platforms: No platforms listed

Model Documentation: Other Narrative Mathematical description

Model Code URLs: Model code not found

Abstract

Question: How is the process of evolutionary branching influenced by demographic stochasticity? Mathematical methods: Adaptive dynamics of (i) a simple consumer-resource model and (ii) an analogous but individual-based model with finite population size. Key assumptions: Consumers have access to two habitats with dynamic resources. The fraction of time spent in each habitat is the evolving trait. System size influences absolute population size and hence demographic stochasticity but not the expected population densities. Reproduction is asexual. Predictions: Absolute population size is an ecological factor that controls the outcome of evolutionary dynamics by modifying the level of demographic stochasticity. Small populations are predicted to remain monomorphic generalists while large populations are predicted to split evolutionarily into specialized sub-populations. Underlying the delayed or absent evolutionary branching in small populations are (i) random genetic drift and (ii) extinction of incipient branches due to near-neutral stability.

Tags

Dispersal Model sympatric speciation Demographic stochasticity Strategies Size Polymorphism Adaptive-dynamics