The evolutionary genomics of meiotic drive

Daven C. Presgraves; R. Kelly Dawe; Kelly A. Dyer; Lila Fishman; Soumitra A. Bhide; Sasha L. Bradshaw; Meghan J. Brady; Alejandro Burga; Cécile Courret; Brandon L. Fagen; Ana Beatriz Stein Machado Ferretti; Reka K. Kelemen; Jun Kitano; Yiran Liu; Emiliano Martí; Theresa Erlenbach; Josephine A. Reinhardt; Laura Ross; Jan Niklas Runge; Callie M. Swanepoel; Beatriz Vicoso; Aaron A. Vogan; Anna K. Lindholm; Amanda M. Larracuente; Robert L. Unckless

doi:10.1093/molbev/msag020

The evolutionary genomics of meiotic drive

Daven C. Presgraves
, R. Kelly Dawe
, Kelly A. Dyer
, Lila Fishman
, Soumitra A. Bhide
, Sasha L. Bradshaw
, Meghan J. Brady
, Alejandro Burga
, Cécile Courret
, Brandon L. Fagen
, Ana Beatriz Stein Machado Ferretti
, Reka K. Kelemen
, Jun Kitano
, Yiran Liu
, Emiliano Martí
, Theresa Erlenbach
, Josephine A. Reinhardt
, Laura Ross
, Jan Niklas Runge
, Callie M. Swanepoel

Beatriz Vicoso, Aaron A. Vogan, Anna K. Lindholm, Amanda M. Larracuente, Robert L. Unckless

Division of Biological and Biomedical Sciences

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

Abstract

Meiotic drivers are selfish genetic elements that gain transmission advantages by distorting equal, Mendelian segregation. For decades, biologists have considered meiotic drivers as interesting, albeit esoteric, case studies. It is now clear, however, that meiotic drive is more common and phylogenetically widespread than previously supposed. Indeed, intensive study of a few well-known cases has begun to reveal the evolutionary genomic consequences of meiotic drive. We argue here that many features of genome evolution, content, and organization that are seemingly inexplicable by organismal adaptation or nearly neutral processes are instead best accounted for by recurrent histories of meiotic drive. We review how meiotic drive can affect the evolution of sequences, gene copy numbers, genes with functions in meiosis and gametogenesis, signatures of “selection,” chromosome rearrangements, and karyotype evolution. We also explore the interactions of meiotic drive elements with other classes of selfish genetic elements, including satellite DNAs, transposable elements, and with the endogenous host genes involved in drive suppression. Finally, we argue that some aspects of drive-mediated genome evolution are now sufficiently well established that we might reverse the direction of discovery—rather than ask how drive affects genome evolution, we can use genome data to discover new putative drive elements.

Original language	English
Article number	msag020
Journal	Molecular Biology and Evolution
Volume	43
Issue number	2
DOIs	https://doi.org/10.1093/molbev/msag020
State	Published - Feb 26 2026

Keywords

genome evolution
meiotic drive
selfish genetic elements

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10.1093/molbev/msag020

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Presgraves, D. C., Kelly Dawe, R., Dyer, K. A., Fishman, L., Bhide, S. A., Bradshaw, S. L., Brady, M. J., Burga, A., Courret, C., Fagen, B. L., Ferretti, A. B. S. M., Kelemen, R. K., Kitano, J., Liu, Y., Martí, E., Erlenbach, T., Reinhardt, J. A., Ross, L., Runge, J. N., ... Unckless, R. L. (2026). The evolutionary genomics of meiotic drive. Molecular Biology and Evolution, 43(2), Article msag020. https://doi.org/10.1093/molbev/msag020

@article{10e91575cd0d454c8514773c8bce2b2e,

title = "The evolutionary genomics of meiotic drive",

abstract = "Meiotic drivers are selfish genetic elements that gain transmission advantages by distorting equal, Mendelian segregation. For decades, biologists have considered meiotic drivers as interesting, albeit esoteric, case studies. It is now clear, however, that meiotic drive is more common and phylogenetically widespread than previously supposed. Indeed, intensive study of a few well-known cases has begun to reveal the evolutionary genomic consequences of meiotic drive. We argue here that many features of genome evolution, content, and organization that are seemingly inexplicable by organismal adaptation or nearly neutral processes are instead best accounted for by recurrent histories of meiotic drive. We review how meiotic drive can affect the evolution of sequences, gene copy numbers, genes with functions in meiosis and gametogenesis, signatures of “selection,” chromosome rearrangements, and karyotype evolution. We also explore the interactions of meiotic drive elements with other classes of selfish genetic elements, including satellite DNAs, transposable elements, and with the endogenous host genes involved in drive suppression. Finally, we argue that some aspects of drive-mediated genome evolution are now sufficiently well established that we might reverse the direction of discovery—rather than ask how drive affects genome evolution, we can use genome data to discover new putative drive elements.",

keywords = "genome evolution, meiotic drive, selfish genetic elements",

author = "Presgraves, \{Daven C.\} and \{Kelly Dawe\}, R. and Dyer, \{Kelly A.\} and Lila Fishman and Bhide, \{Soumitra A.\} and Bradshaw, \{Sasha L.\} and Brady, \{Meghan J.\} and Alejandro Burga and C{\'e}cile Courret and Fagen, \{Brandon L.\} and Ferretti, \{Ana Beatriz Stein Machado\} and Kelemen, \{Reka K.\} and Jun Kitano and Yiran Liu and Emiliano Mart{\'i} and Theresa Erlenbach and Reinhardt, \{Josephine A.\} and Laura Ross and Runge, \{Jan Niklas\} and Swanepoel, \{Callie M.\} and Beatriz Vicoso and Vogan, \{Aaron A.\} and Lindholm, \{Anna K.\} and Larracuente, \{Amanda M.\} and Unckless, \{Robert L.\}",

note = "Publisher Copyright: {\textcopyright} The Author(s) 2026.",

year = "2026",

month = feb,

day = "26",

doi = "10.1093/molbev/msag020",

language = "English",

volume = "43",

journal = "Molecular Biology and Evolution",

issn = "0737-4038",

publisher = "Oxford University Press",

number = "2",

}

Presgraves, DC, Kelly Dawe, R, Dyer, KA, Fishman, L, Bhide, SA, Bradshaw, SL, Brady, MJ, Burga, A, Courret, C, Fagen, BL, Ferretti, ABSM, Kelemen, RK, Kitano, J, Liu, Y, Martí, E, Erlenbach, T, Reinhardt, JA, Ross, L, Runge, JN, Swanepoel, CM, Vicoso, B, Vogan, AA, Lindholm, AK, Larracuente, AM & Unckless, RL 2026, 'The evolutionary genomics of meiotic drive', Molecular Biology and Evolution, vol. 43, no. 2, msag020. https://doi.org/10.1093/molbev/msag020

TY - JOUR

T1 - The evolutionary genomics of meiotic drive

AU - Presgraves, Daven C.

AU - Kelly Dawe, R.

AU - Dyer, Kelly A.

AU - Fishman, Lila

AU - Bhide, Soumitra A.

AU - Bradshaw, Sasha L.

AU - Brady, Meghan J.

AU - Burga, Alejandro

AU - Courret, Cécile

AU - Fagen, Brandon L.

AU - Ferretti, Ana Beatriz Stein Machado

AU - Kelemen, Reka K.

AU - Kitano, Jun

AU - Liu, Yiran

AU - Martí, Emiliano

AU - Erlenbach, Theresa

AU - Reinhardt, Josephine A.

AU - Ross, Laura

AU - Runge, Jan Niklas

AU - Swanepoel, Callie M.

AU - Vicoso, Beatriz

AU - Vogan, Aaron A.

AU - Lindholm, Anna K.

AU - Larracuente, Amanda M.

AU - Unckless, Robert L.

PY - 2026/2/26

Y1 - 2026/2/26

N2 - Meiotic drivers are selfish genetic elements that gain transmission advantages by distorting equal, Mendelian segregation. For decades, biologists have considered meiotic drivers as interesting, albeit esoteric, case studies. It is now clear, however, that meiotic drive is more common and phylogenetically widespread than previously supposed. Indeed, intensive study of a few well-known cases has begun to reveal the evolutionary genomic consequences of meiotic drive. We argue here that many features of genome evolution, content, and organization that are seemingly inexplicable by organismal adaptation or nearly neutral processes are instead best accounted for by recurrent histories of meiotic drive. We review how meiotic drive can affect the evolution of sequences, gene copy numbers, genes with functions in meiosis and gametogenesis, signatures of “selection,” chromosome rearrangements, and karyotype evolution. We also explore the interactions of meiotic drive elements with other classes of selfish genetic elements, including satellite DNAs, transposable elements, and with the endogenous host genes involved in drive suppression. Finally, we argue that some aspects of drive-mediated genome evolution are now sufficiently well established that we might reverse the direction of discovery—rather than ask how drive affects genome evolution, we can use genome data to discover new putative drive elements.

AB - Meiotic drivers are selfish genetic elements that gain transmission advantages by distorting equal, Mendelian segregation. For decades, biologists have considered meiotic drivers as interesting, albeit esoteric, case studies. It is now clear, however, that meiotic drive is more common and phylogenetically widespread than previously supposed. Indeed, intensive study of a few well-known cases has begun to reveal the evolutionary genomic consequences of meiotic drive. We argue here that many features of genome evolution, content, and organization that are seemingly inexplicable by organismal adaptation or nearly neutral processes are instead best accounted for by recurrent histories of meiotic drive. We review how meiotic drive can affect the evolution of sequences, gene copy numbers, genes with functions in meiosis and gametogenesis, signatures of “selection,” chromosome rearrangements, and karyotype evolution. We also explore the interactions of meiotic drive elements with other classes of selfish genetic elements, including satellite DNAs, transposable elements, and with the endogenous host genes involved in drive suppression. Finally, we argue that some aspects of drive-mediated genome evolution are now sufficiently well established that we might reverse the direction of discovery—rather than ask how drive affects genome evolution, we can use genome data to discover new putative drive elements.

KW - genome evolution

KW - meiotic drive

KW - selfish genetic elements

UR - https://www.scopus.com/pages/publications/105031632626

U2 - 10.1093/molbev/msag020

DO - 10.1093/molbev/msag020

M3 - Article

C2 - 41589062

AN - SCOPUS:105031632626

SN - 0737-4038

VL - 43

JO - Molecular Biology and Evolution

JF - Molecular Biology and Evolution

IS - 2

M1 - msag020

ER -

The evolutionary genomics of meiotic drive

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