Meiotic gene evolution: Can you teach a new dog new tricks?

Andrew H Lloyd; Marion Ranoux; Sonia Vautrin; Natasha Glover; Joelle Fourment; Delphine Charif; Frederic Choulet; Gilles Lassalle; William Marande; Joseph Tran; Fabienne Granier; Lise Pingault; Arnaud Remay; Catherine Marquis; Harry Belcram; Boulos Chalhoub; Catherine Feuillet; Hélène Bergès; Pierre Sourdille; Eric Jenczewski

doi:10.1093/molbev/msu119

Meiotic gene evolution: Can you teach a new dog new tricks?

Andrew H Lloyd
, Marion Ranoux
, Sonia Vautrin
, Natasha Glover
, Joelle Fourment
, Delphine Charif
, Frederic Choulet
, Gilles Lassalle
, William Marande
, Joseph Tran
, Fabienne Granier
, Lise Pingault
, Arnaud Remay
, Catherine Marquis
, Harry Belcram
, Boulos Chalhoub
, Catherine Feuillet
, Hélène Bergès
, Pierre Sourdille
, Eric Jenczewski

Institut Jean-Pierre Bourgin
Génétique, Diversité, Écophysiologie des Céréales
The French Plant Genomic Resources Center
Institut de Génétique, Environnement et Protection des Plantes
MRC Population Health Research Unit

Allbwn ymchwil: Cyfraniad at gyfnodolyn › Erthygl › adolygiad gan gymheiriaid

50 Dyfyniadau (Scopus)

Crynodeb

Meiosis, the basis of sex, evolved through iterative gene duplications. To understand whether subsequent duplications have further enriched the core meiotic "tool-kit," we investigated the fate of meiotic gene duplicates following whole genome duplication (WGD), a common occurrence in eukaryotes. We show that meiotic genes return to a single copy more rapidly than genome-wide average in angiosperms, one of the lineages in which WGD is most vividly exemplified. The rate at which duplicates are lost decreases through time, a tendency that is also observed genome-wide and may thus prove to be a general trend post-WGD. The sharpest decline is observed for the subset of genes mediating meiotic recombination; however, we found no evidence that the presence of these duplicates is counterselected in two recent polyploid crops selected for fertility. We therefore propose that their loss is passive, highlighting how quickly WGDs are resolved in the absence of selective duplicate retention.

Iaith wreiddiol	Saesneg
Tudalennau (o-i)	1724-1727
Nifer y tudalennau	4
Cyfnodolyn	Molecular Biology and Evolution
Cyfrol	31
Rhif cyhoeddi	7
Dyddiad ar-lein cynnar	01 Ebr 2014
Dynodwyr Gwrthrych Digidol (DOIs)	https://doi.org/10.1093/molbev/msu119
Statws	Cyhoeddwyd - 01 Gorff 2014
Cyhoeddwyd yn allanol	Ie

Mynediad at Ddogfen

10.1093/molbev/msu119

Cysylltiad parhaol

Dolen barhaus

Ffeiliau eraill a chysylltiadau

Dolen i’r cyhoeddiad yn Scopus

Andrew Lloyd
- anl50aber.acuk
- Athrofa'r Gwyddorau Biolegol, Amgylcheddol a Gwledig - UKRI Future Leaders Fellow
Unigolyn: Ymchwil

Dyfynnu hyn

Lloyd, A. H., Ranoux, M., Vautrin, S., Glover, N., Fourment, J., Charif, D., Choulet, F., Lassalle, G., Marande, W., Tran, J., Granier, F., Pingault, L., Remay, A., Marquis, C., Belcram, H., Chalhoub, B., Feuillet, C., Bergès, H., Sourdille, P., & Jenczewski, E. (2014). Meiotic gene evolution: Can you teach a new dog new tricks? Molecular Biology and Evolution, 31(7), 1724-1727. https://doi.org/10.1093/molbev/msu119

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title = "Meiotic gene evolution: Can you teach a new dog new tricks?",

abstract = "Meiosis, the basis of sex, evolved through iterative gene duplications. To understand whether subsequent duplications have further enriched the core meiotic {"}tool-kit,{"} we investigated the fate of meiotic gene duplicates following whole genome duplication (WGD), a common occurrence in eukaryotes. We show that meiotic genes return to a single copy more rapidly than genome-wide average in angiosperms, one of the lineages in which WGD is most vividly exemplified. The rate at which duplicates are lost decreases through time, a tendency that is also observed genome-wide and may thus prove to be a general trend post-WGD. The sharpest decline is observed for the subset of genes mediating meiotic recombination; however, we found no evidence that the presence of these duplicates is counterselected in two recent polyploid crops selected for fertility. We therefore propose that their loss is passive, highlighting how quickly WGDs are resolved in the absence of selective duplicate retention. ",

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author = "Lloyd, \{Andrew H\} and Marion Ranoux and Sonia Vautrin and Natasha Glover and Joelle Fourment and Delphine Charif and Frederic Choulet and Gilles Lassalle and William Marande and Joseph Tran and Fabienne Granier and Lise Pingault and Arnaud Remay and Catherine Marquis and Harry Belcram and Boulos Chalhoub and Catherine Feuillet and H{\'e}l{\`e}ne Berg{\`e}s and Pierre Sourdille and Eric Jenczewski",

note = "{\textcopyright} The Author 2014. Published by Oxford University Press on behalf of the Society for Molecular Biology and Evolution. All rights reserved. For permissions, please e-mail: [email protected].",

year = "2014",

month = jul,

day = "1",

doi = "10.1093/molbev/msu119",

language = "English",

volume = "31",

pages = "1724--1727",

journal = "Molecular Biology and Evolution",

issn = "0737-4038",

publisher = "Oxford University Press",

number = "7",

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Lloyd, AH, Ranoux, M, Vautrin, S, Glover, N, Fourment, J, Charif, D, Choulet, F, Lassalle, G, Marande, W, Tran, J, Granier, F, Pingault, L, Remay, A, Marquis, C, Belcram, H, Chalhoub, B, Feuillet, C, Bergès, H, Sourdille, P & Jenczewski, E 2014, 'Meiotic gene evolution: Can you teach a new dog new tricks?', Molecular Biology and Evolution, cyfrol. 31, rhif 7, tt. 1724-1727. https://doi.org/10.1093/molbev/msu119

TY - JOUR

T1 - Meiotic gene evolution

T2 - Can you teach a new dog new tricks?

AU - Lloyd, Andrew H

AU - Ranoux, Marion

AU - Vautrin, Sonia

AU - Glover, Natasha

AU - Fourment, Joelle

AU - Charif, Delphine

AU - Choulet, Frederic

AU - Lassalle, Gilles

AU - Marande, William

AU - Tran, Joseph

AU - Granier, Fabienne

AU - Pingault, Lise

AU - Remay, Arnaud

AU - Marquis, Catherine

AU - Belcram, Harry

AU - Chalhoub, Boulos

AU - Feuillet, Catherine

AU - Bergès, Hélène

AU - Sourdille, Pierre

AU - Jenczewski, Eric

PY - 2014/7/1

Y1 - 2014/7/1

N2 - Meiosis, the basis of sex, evolved through iterative gene duplications. To understand whether subsequent duplications have further enriched the core meiotic "tool-kit," we investigated the fate of meiotic gene duplicates following whole genome duplication (WGD), a common occurrence in eukaryotes. We show that meiotic genes return to a single copy more rapidly than genome-wide average in angiosperms, one of the lineages in which WGD is most vividly exemplified. The rate at which duplicates are lost decreases through time, a tendency that is also observed genome-wide and may thus prove to be a general trend post-WGD. The sharpest decline is observed for the subset of genes mediating meiotic recombination; however, we found no evidence that the presence of these duplicates is counterselected in two recent polyploid crops selected for fertility. We therefore propose that their loss is passive, highlighting how quickly WGDs are resolved in the absence of selective duplicate retention.

AB - Meiosis, the basis of sex, evolved through iterative gene duplications. To understand whether subsequent duplications have further enriched the core meiotic "tool-kit," we investigated the fate of meiotic gene duplicates following whole genome duplication (WGD), a common occurrence in eukaryotes. We show that meiotic genes return to a single copy more rapidly than genome-wide average in angiosperms, one of the lineages in which WGD is most vividly exemplified. The rate at which duplicates are lost decreases through time, a tendency that is also observed genome-wide and may thus prove to be a general trend post-WGD. The sharpest decline is observed for the subset of genes mediating meiotic recombination; however, we found no evidence that the presence of these duplicates is counterselected in two recent polyploid crops selected for fertility. We therefore propose that their loss is passive, highlighting how quickly WGDs are resolved in the absence of selective duplicate retention.

KW - duplication

KW - evolution

KW - genome

KW - meiosis

KW - polyploidy

KW - whole genome duplication

UR - https://www.scopus.com/pages/publications/84903692243

U2 - 10.1093/molbev/msu119

DO - 10.1093/molbev/msu119

M3 - Article

C2 - 24694832

SN - 0737-4038

VL - 31

SP - 1724

EP - 1727

JO - Molecular Biology and Evolution

JF - Molecular Biology and Evolution

IS - 7

ER -

Meiotic gene evolution: Can you teach a new dog new tricks?

Crynodeb

Mynediad at Ddogfen

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Ffeiliau eraill a chysylltiadau

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Proffiliau

Andrew Lloyd

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