Unifying quantification methods for sexual selection and assortative mating using information theory
DATE:
2024-08
UNIVERSAL IDENTIFIER: http://hdl.handle.net/11093/7323
EDITED VERSION: https://linkinghub.elsevier.com/retrieve/pii/S0040580924000650
DOCUMENT TYPE: article
ABSTRACT
Sexual selection plays a crucial role in modern evolutionary theory, offering valuable insight into evolutionary
patterns and species diversity. Recently, a comprehensive definition of sexual selection has been proposed,
defining it as any selection that arises from fitness differences associated with nonrandom success in the
competition for access to gametes for fertilization. Previous research on discrete traits demonstrated that nonrandom mating can be effectively quantified using Jeffreys (or symmetrized Kullback-Leibler) divergence,
capturing information acquired through mating influenced by mutual mating propensities instead of random
occurrences. This novel theoretical framework allows for detecting and assessing the strength of sexual selection
and assortative mating.
In this study, we aim to achieve two primary objectives. Firstly, we demonstrate the seamless alignment of the
previous theoretical development, rooted in information theory and mutual mating propensity, with the aforementioned definition of sexual selection. Secondly, we extend the theory to encompass quantitative traits. Our
findings reveal that sexual selection and assortative mating can be quantified effectively for quantitative traits by
measuring the information gain relative to the random mating pattern. The connection of the information indices
of sexual selection with the classical measures of sexual selection is established.
Additionally, if mating traits are normally distributed, the measure capturing the underlying information of
assortative mating is a function of the square of the correlation coefficient, taking values within the non-negative
real number set [0, +∞).
It is worth noting that the same divergence measure captures information acquired through mating for both
discrete and quantitative traits. This is interesting as it provides a common context and can help simplify the
study of sexual selection patterns