Nongenetic Inheritance and the Evolution of Costly Female Preference

Overview

Journal J Evol Biol

Publisher Oxford University Press

Specialty Biology

Date 2012 Nov 21

PMID 23163399

Citations 21

Authors

R Bonduriansky

T Day

Affiliations

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Abstract

In species where males provide neither direct benefits nor paternal care, it is typically assumed that female preferences are maintained by indirect selection reflecting genetic benefits to offspring of preferred males. However, it remains unclear whether populations harbour sufficient genetic variation in fitness to support costly female preferences - a problem called the 'lek paradox'. Here, we ask whether indirect selection on female preferences can be maintained by nongenetic inheritance. We construct a general model that can be used to represent either genetic or nongenetic inheritance, depending on the choice of parameter values. Interestingly, we find that costly preference is most likely to evolve and persist when fitness depends on an environmentally induced factor that can be transmitted over a single generation only, such as an environment-dependent paternal effect. Costly preference can also be supported when fitness depends on a highly mutable factor that can persist over multiple generations, such as an epigenetic mark, but the necessary conditions are more restrictive. Our findings show that nongenetic inheritance provides a plausible hypothesis for the maintenance of costly female preferences in species where males provide no direct benefits to females. Nongenetic paternal inheritance of fitness can occur in species lacking conventional forms of paternal care. Indeed, transmission of paternal condition via sperm-borne nongenetic factors may be more likely to evolve than conventional forms of paternal investment because sperm-borne effects are protected from cuckoldry. Our results furnish a novel example of an interaction between genetic and nongenetic inheritance that can lead to otherwise unexpected evolutionary outcomes.

Citing Articles

Separating the effects of paternal age and mating history: Evidence for sex-specific paternal effect in eastern mosquitofish.

Aich U, Chowdhury S, Jennions M Evolution. 2022; 76(7):1565-1577.

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Effects of genetic vs. environmental quality on condition-dependent morphological and life history traits in a neriid fly.

Hooper A, Bonduriansky R J Evol Biol. 2022; 35(6):803-816.

PMID: 35514040 PMC: 9325454. DOI: 10.1111/jeb.14014.

Role of environmentally induced epigenetic transgenerational inheritance in evolutionary biology: Unified Evolution Theory.

Skinner M, Nilsson E Environ Epigenet. 2021; 7(1):dvab012.

PMID: 34729214 PMC: 8557805. DOI: 10.1093/eep/dvab012.

Mapping the past, present and future research landscape of paternal effects.

Rutkowska J, Lagisz M, Bonduriansky R, Nakagawa S BMC Biol. 2020; 18(1):183.

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Can paternal effects via seminal fluid contribute to the evolution of polyandry?.

Simmons L, Lovegrove M Biol Lett. 2020; 16(11):20200680.

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