AI Article Synopsis
- Biologists aim to understand how species distribution affects biodiversity, incorporating factors like ecological niches, dispersal dynamics, and evolution.
- An individual-based model showed that lower regional species diversity encourages species to evolve for higher dispersal probabilities, which influences competition and habitat monopolization.
- The study highlights that in less diverse areas, like isolated islands and changing environments, the evolution of dispersal traits significantly impacts biodiversity and species interactions.
Article Abstract
Biologists have long sought to predict the distribution of species across landscapes to understand biodiversity patterns and dynamics. These efforts usually integrate ecological niche and dispersal dynamics, but evolution can also mediate these ecological dynamics. Species that disperse well and arrive early might adapt to local conditions, which creates an evolution-mediated priority effect that alters biodiversity patterns. Yet, dispersal is also a trait that can evolve and affect evolution-mediated priority effects. We developed an individual-based model where populations of competing species can adapt not only to local environments but also to different dispersal probabilities. We found that lower regional species diversity selects for populations with higher dispersal probabilities and stronger evolution-mediated priority effects. When all species evolved dispersal, they monopolized fewer patches and did so at the same rates. When only one of the species evolved dispersal, it evolved lower dispersal than highly dispersive species and monopolized habitats once freed from maladaptive gene flow. Overall, we demonstrate that dispersal evolution can shape evolution-mediated priority effects when provided with a greater ecological opportunity in species-poor communities. Dispersal- and evolution-mediated priority effects probably play greater roles in species-poor regions like the upper latitudes, isolated islands and in changing environments. This article is part of the theme issue 'Diversity-dependence of dispersal: interspecific interactions determine spatial dynamics'.
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| http://www.ncbi.nlm.nih.gov/pmc/articles/PMC11391303 | PMC |
| http://dx.doi.org/10.1098/rstb.2023.0129 | DOI Listing |
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- The study highlights that in less diverse areas, like isolated islands and changing environments, the evolution of dispersal traits significantly impacts biodiversity and species interactions.
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