Phenotypic Assortment Mediates The Effect Of Social Selection In A Wild Beetle Population
Document Type
Article
Publication Date
10-1-2011
Published In
Evolution
Abstract
Social interactions often have major fitness consequences, but little is known about how specific interacting phenotypes affect the strength of natural selection. Social influences on the evolutionary process can be assessed using a multilevel selection approach that partitions the effects of social partner phenotypes on fitness (referred to as social or group selection) from those of the traits of a focal individual (nonsocial or individual selection). To quantify the contribution of social selection to total selection affecting a trait, the patterns of phenotypic association among interactants must also be considered. We estimated selection gradients on male body size in a wild population of forked fungus beetles (Bolitotherus cornutus). We detected positive nonsocial selection and negative social selection on body size operating through differences in copulation success, indicating that large males with small social partners had highest fitness. In addition, we found that, in low-density demes, the phenotypes of focal individuals were negatively correlated with those of their social partners. This pattern reversed the negative effect of group selection on body size and led to stronger positive selection for body size. Our results demonstrate multilevel selection in nature and stress the importance of considering social selection whenever conspecific interactions occur nonrandomly.
Recommended Citation
Vincent A. Formica; J. W. McGlothlin; Corlett Wolfe Wood , '08; Malcolm Elliot Augat , '09; R. E. Butterfield; Mollie Elyse Barnard , '10; and E. D. Brodie III.
(2011).
"Phenotypic Assortment Mediates The Effect Of Social Selection In A Wild Beetle Population".
Evolution.
Volume 65,
Issue 10.
2771-2781.
DOI: 10.1111/j.1558-5646.2011.01340.x
https://works.swarthmore.edu/fac-biology/86
Comments
Data associated with this article are available through Dryad.