A single-locus quantitative genetic model incorporating DNA methylation

L. Ayres; H. Bovenhuis; M.P.L. Calus

doi:10.1016/j.jtbi.2025.112110

A single-locus quantitative genetic model incorporating DNA methylation

L. Ayres^*, H. Bovenhuis, M.P.L. Calus

^*Corresponding author for this work

Research output: Contribution to journal › Article › Academic › peer-review

Abstract

We describe a single-locus quantitative genetic model that incorporates effects due to DNA methylation. Extending Fisher's decomposition of the genotypic value, we distinguish two quantities to predict an individual's phenotypic or genetic values: the “basic genetic value” and the “expressed genetic value”. We show how these quantities relate to the concept of breeding value and derive their corresponding formulas, along with those for phenotypic variance and covariance between relatives. The resulting parameters are influenced by several factors, including the population distribution of DNA methylation levels, the functional relationship between methylation and phenotype, the magnitudes of genetic and methylation effects, and allele frequencies. We show that under the conditions modeled, the presence of DNA methylation does not bias estimated breeding values.

Original language	English
Article number	112110
Journal	Journal of Theoretical Biology
Volume	607
DOIs	https://doi.org/10.1016/j.jtbi.2025.112110
Publication status	Published - 21 Jun 2025

Keywords

Breeding value
DNA methylation
Epigenetics
Genomic prediction
Quantitative genetics
Single locus

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10.1016/j.jtbi.2025.112110Licence: CC BY

https://edepot.wur.nl/693147Licence: CC BY

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title = "A single-locus quantitative genetic model incorporating DNA methylation",

abstract = "We describe a single-locus quantitative genetic model that incorporates effects due to DNA methylation. Extending Fisher's decomposition of the genotypic value, we distinguish two quantities to predict an individual's phenotypic or genetic values: the “basic genetic value” and the “expressed genetic value”. We show how these quantities relate to the concept of breeding value and derive their corresponding formulas, along with those for phenotypic variance and covariance between relatives. The resulting parameters are influenced by several factors, including the population distribution of DNA methylation levels, the functional relationship between methylation and phenotype, the magnitudes of genetic and methylation effects, and allele frequencies. We show that under the conditions modeled, the presence of DNA methylation does not bias estimated breeding values.",

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AU - Bovenhuis, H.

AU - Calus, M.P.L.

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N2 - We describe a single-locus quantitative genetic model that incorporates effects due to DNA methylation. Extending Fisher's decomposition of the genotypic value, we distinguish two quantities to predict an individual's phenotypic or genetic values: the “basic genetic value” and the “expressed genetic value”. We show how these quantities relate to the concept of breeding value and derive their corresponding formulas, along with those for phenotypic variance and covariance between relatives. The resulting parameters are influenced by several factors, including the population distribution of DNA methylation levels, the functional relationship between methylation and phenotype, the magnitudes of genetic and methylation effects, and allele frequencies. We show that under the conditions modeled, the presence of DNA methylation does not bias estimated breeding values.

AB - We describe a single-locus quantitative genetic model that incorporates effects due to DNA methylation. Extending Fisher's decomposition of the genotypic value, we distinguish two quantities to predict an individual's phenotypic or genetic values: the “basic genetic value” and the “expressed genetic value”. We show how these quantities relate to the concept of breeding value and derive their corresponding formulas, along with those for phenotypic variance and covariance between relatives. The resulting parameters are influenced by several factors, including the population distribution of DNA methylation levels, the functional relationship between methylation and phenotype, the magnitudes of genetic and methylation effects, and allele frequencies. We show that under the conditions modeled, the presence of DNA methylation does not bias estimated breeding values.

KW - Breeding value

KW - DNA methylation

KW - Epigenetics

KW - Genomic prediction

KW - Quantitative genetics

KW - Single locus

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DO - 10.1016/j.jtbi.2025.112110

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SN - 0022-5193

VL - 607

JO - Journal of Theoretical Biology

JF - Journal of Theoretical Biology

M1 - 112110

ER -

A single-locus quantitative genetic model incorporating DNA methylation

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Keywords

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