Stable coexistence of ecologically identical species: conspecific aggregation via reproductive interference

Authored by Lasse Ruokolainen, Ilkka Hanski

Date Published: 2016

DOI: 10.1111/1365-2656.12490

Sponsors: Academy of Finland

Platforms: R

Model Documentation: Other Narrative Mathematical description

Model Code URLs: http://onlinelibrary.wiley.com.ezproxy1.lib.asu.edu/store/10.1111/1365-2656.12490/asset/supinfo/jane12490-sup-0001-AppendixS1.R?v=1&s=d2b849ee804d594afe70522063947cbd8a57d6de

Abstract

Stable coexistence of ecologically identical species is not possible according to the established ecological theory. Many coexistence mechanisms have been proposed, but they all involve some form of ecological differentiation among the competing species. The aggregation model of coexistence would predict coexistence of identical species if there would be a mechanism that generates spatially aggregated distributions that are not completely correlated among the species. Our aim is to demonstrate that continued dispersal, triggered by reproductive interference between ecologically identical species, is such a mechanism. This study has been motivated by species using ephemeral patchy resources, such as decomposing fruits, fungal sporophores, carrion, and dung. We analyse an individual-based model with sexual reproduction, in which the progeny develops in ephemeral resource patches and the new generation disperses to a new set of patches. We assume spatially restricted dispersal, that patches differ in detectability, and that unmated females continue dispersal. In the model, reproductive interference (males spend some time searching for and/or attempting to mate with heterospecific females) reduces the mating rate of females, especially in the less common species, which leads to increased dispersal and reduces spatial correlation in species' distributions. For a wide range of parameter values, coexisting species show a systematic difference in their relative abundances due to two opposing forces: (1) uncommon species have reduced growth rate (Allee effect), which decreases abundance; (2) an abundance difference between the species reduces interspecific spatial correlation, which in turn reduces interspecific competition and allows the rarer species to persist at low density. Our results demonstrate a new mechanism for coexistence that is not based on ecological differentiation between species.

Tags

Competition behavior Dynamics Dispersal patterns resource Patchy environment Drosophila Carrion fly community Mating status