Haploblocks contribute to parallel climate adaptation following global invasion of a cosmopolitan plant

Paul Battlay; Brandon T. Hendrickson; Jonas I. Mendez-Reneau; James S. Santangelo; Lucas J. Albano; Jonathan Wilson; Aude E. Caizergues; Nevada King; Adriana Puentes; Amelia Tudoran; Cyrille Violle; Francois Vasseur; Courtney M. Patterson; Michael Foster; Caitlyn Stamps; Simon G. Innes; Rémi Allio; Fabio Angeoletto; Daniel N. Anstett; Julia Anstett; Anna Bucharova; Mattheau S. Comerford; Santiago David; Mohsen Falahati-Anbaran; William Godsoe; César González-Lagos; Pedro E. Gundel; Glen Ray Hood; Christian Lampei; Carlos Lara; Adrián Lázaro-Lobo; Deleon Silva Leandro; Thomas J.S. Merritt; Nora Mitchell; Mitra Mohammadi Bazargani; Angela Moles; Maureen Murúa; Juraj Paule; Vera Pfeiffer; Joost A.M. Raeymaekers; Diana J. Rennison; Rodrigo S. Rios; Jennifer K. Rowntree; Adam C. Schneider; Kaitlin Stack Whitney; Ítalo Tamburrino; Acer VanWallendael; Paul Y. Kim; Rob W. Ness; Marc T.J. Johnson; Kathryn A. Hodgins; Nicholas J. Kooyers

doi:10.1038/s41559-025-02751-2

Haploblocks contribute to parallel climate adaptation following global invasion of a cosmopolitan plant

Paul Battlay^*
, Brandon T. Hendrickson
, Jonas I. Mendez-Reneau
, James S. Santangelo
, Lucas J. Albano
, Jonathan Wilson
, Aude E. Caizergues
, Nevada King
, Adriana Puentes
, Amelia Tudoran
, Cyrille Violle
, Francois Vasseur
, Courtney M. Patterson
, Michael Foster
, Caitlyn Stamps
, Simon G. Innes
, Rémi Allio
, Fabio Angeoletto
, Daniel N. Anstett
, Julia Anstett

Anna Bucharova, Mattheau S. Comerford, Santiago David, Mohsen Falahati-Anbaran, William Godsoe, César González-Lagos, Pedro E. Gundel, Glen Ray Hood, Christian Lampei, Carlos Lara, Adrián Lázaro-Lobo, Deleon Silva Leandro, Thomas J.S. Merritt, Nora Mitchell, Mitra Mohammadi Bazargani, Angela Moles, Maureen Murúa, Juraj Paule, Vera Pfeiffer, Joost A.M. Raeymaekers, Diana J. Rennison, Rodrigo S. Rios, Jennifer K. Rowntree, Adam C. Schneider, Kaitlin Stack Whitney, Ítalo Tamburrino, Acer VanWallendael, Paul Y. Kim, Rob W. Ness, Marc T.J. Johnson, Kathryn A. Hodgins, Nicholas J. Kooyers^*

^*Corresponding author for this work

Monash University
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University of California at Berkeley
University of Toronto
Swedish University of Agricultural Sciences
Université de Montpellier
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Universidade Federal de Rondonópolis
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University of Marburg
University of Massachusetts Boston
Norwegian University of Science and Technology
Lincoln University
Universidad Adolfo Ibáñez
Universidad de Talca
Universidad de Buenos Aires
Wayne State University
Universidad Católica de la Santísima Concepción
Biodiversity Research Institute IMIB
Universidade Federal de Mato Grosso
Laurentian University
University of Wisconsin-Eau Claire
University of New South Wales
Universidad Mayor
Free University of Berlin
Washington State University Pullman
Nord University
University of California at San Diego
Universidad de La Serena
University of Wisconsin-La Crosse
Rochester Institute of Technology
Universidad de Chile
North Carolina State University

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Abstract

The role of rapid adaptation during species invasions has historically been minimized with the assumption that introductions consist of few colonists and limited genetic diversity. While overwhelming evidence suggests that rapid adaptation is more prevalent than originally assumed, the demographic and adaptive processes underlying successful invasions remain unresolved. Here we leverage a large whole-genome sequence dataset to investigate the relative roles of colonization history and adaptation during the worldwide invasion of the forage crop, Trifolium repens (Fabaceae). We show that introduced populations encompass high levels of genetic variation with little evidence of bottlenecks. Independent colonization histories on different continents are evident from genome-wide population structure. Five haploblocks—large haplotypes with limited recombination—on three chromosomes exist as standing genetic variation within the native and introduced ranges and exhibit strong signatures of parallel climate-associated adaptation across continents. Field experiments in the native and introduced ranges demonstrate that three of the haploblocks strongly affect fitness and exhibit patterns of selection consistent with local adaptation across each range. Our results provide strong evidence that large-effect structural variants contribute substantially to rapid and parallel adaptation of an introduced species throughout the world.

Original language	English
Pages (from-to)	1441-1455
Number of pages	15
Journal	Nature Ecology and Evolution
Volume	9
Issue number	8
DOIs	https://doi.org/10.1038/s41559-025-02751-2
Publication status	Published - 8 Jul 2025

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This output contributes to the following UN Sustainable Development Goals (SDGs)

SDG 15 Life on Land

ASJC Scopus subject areas

Ecology, Evolution, Behavior and Systematics
Ecology

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Battlay, P., Hendrickson, B. T., Mendez-Reneau, J. I., Santangelo, J. S., Albano, L. J., Wilson, J., Caizergues, A. E., King, N., Puentes, A., Tudoran, A., Violle, C., Vasseur, F., Patterson, C. M., Foster, M., Stamps, C., Innes, S. G., Allio, R., Angeoletto, F., Anstett, D. N., ... Kooyers, N. J. (2025). Haploblocks contribute to parallel climate adaptation following global invasion of a cosmopolitan plant. Nature Ecology and Evolution, 9(8), 1441-1455. https://doi.org/10.1038/s41559-025-02751-2

@article{00f135ce730541d49cc477b960eec690,

title = "Haploblocks contribute to parallel climate adaptation following global invasion of a cosmopolitan plant",

abstract = "The role of rapid adaptation during species invasions has historically been minimized with the assumption that introductions consist of few colonists and limited genetic diversity. While overwhelming evidence suggests that rapid adaptation is more prevalent than originally assumed, the demographic and adaptive processes underlying successful invasions remain unresolved. Here we leverage a large whole-genome sequence dataset to investigate the relative roles of colonization history and adaptation during the worldwide invasion of the forage crop, Trifolium repens (Fabaceae). We show that introduced populations encompass high levels of genetic variation with little evidence of bottlenecks. Independent colonization histories on different continents are evident from genome-wide population structure. Five haploblocks—large haplotypes with limited recombination—on three chromosomes exist as standing genetic variation within the native and introduced ranges and exhibit strong signatures of parallel climate-associated adaptation across continents. Field experiments in the native and introduced ranges demonstrate that three of the haploblocks strongly affect fitness and exhibit patterns of selection consistent with local adaptation across each range. Our results provide strong evidence that large-effect structural variants contribute substantially to rapid and parallel adaptation of an introduced species throughout the world.",

author = "Paul Battlay and Hendrickson, \{Brandon T.\} and Mendez-Reneau, \{Jonas I.\} and Santangelo, \{James S.\} and Albano, \{Lucas J.\} and Jonathan Wilson and Caizergues, \{Aude E.\} and Nevada King and Adriana Puentes and Amelia Tudoran and Cyrille Violle and Francois Vasseur and Patterson, \{Courtney M.\} and Michael Foster and Caitlyn Stamps and Innes, \{Simon G.\} and R{\'e}mi Allio and Fabio Angeoletto and Anstett, \{Daniel N.\} and Julia Anstett and Anna Bucharova and Comerford, \{Mattheau S.\} and Santiago David and Mohsen Falahati-Anbaran and William Godsoe and C{\'e}sar Gonz{\'a}lez-Lagos and Gundel, \{Pedro E.\} and Hood, \{Glen Ray\} and Christian Lampei and Carlos Lara and Adri{\'a}n L{\'a}zaro-Lobo and \{Silva Leandro\}, Deleon and Merritt, \{Thomas J.S.\} and Nora Mitchell and \{Mohammadi Bazargani\}, Mitra and Angela Moles and Maureen Mur{\'u}a and Juraj Paule and Vera Pfeiffer and Raeymaekers, \{Joost A.M.\} and Rennison, \{Diana J.\} and Rios, \{Rodrigo S.\} and Rowntree, \{Jennifer K.\} and Schneider, \{Adam C.\} and \{Stack Whitney\}, Kaitlin and {\'I}talo Tamburrino and Acer VanWallendael and Kim, \{Paul Y.\} and Ness, \{Rob W.\} and Johnson, \{Marc T.J.\} and Hodgins, \{Kathryn A.\} and Kooyers, \{Nicholas J.\}",

note = "Publisher Copyright: {\textcopyright} The Author(s) 2025.",

year = "2025",

month = jul,

day = "8",

doi = "10.1038/s41559-025-02751-2",

language = "English",

volume = "9",

pages = "1441--1455",

journal = "Nature Ecology and Evolution",

issn = "2397-334X",

publisher = "Nature Research",

number = "8",

}

Battlay, P, Hendrickson, BT, Mendez-Reneau, JI, Santangelo, JS, Albano, LJ, Wilson, J, Caizergues, AE, King, N, Puentes, A, Tudoran, A, Violle, C, Vasseur, F, Patterson, CM, Foster, M, Stamps, C, Innes, SG, Allio, R, Angeoletto, F, Anstett, DN, Anstett, J, Bucharova, A, Comerford, MS, David, S, Falahati-Anbaran, M, Godsoe, W, González-Lagos, C, Gundel, PE, Hood, GR, Lampei, C, Lara, C, Lázaro-Lobo, A, Silva Leandro, D, Merritt, TJS, Mitchell, N, Mohammadi Bazargani, M, Moles, A, Murúa, M, Paule, J, Pfeiffer, V, Raeymaekers, JAM, Rennison, DJ, Rios, RS, Rowntree, JK, Schneider, AC, Stack Whitney, K, Tamburrino, Í, VanWallendael, A, Kim, PY, Ness, RW, Johnson, MTJ, Hodgins, KA & Kooyers, NJ 2025, 'Haploblocks contribute to parallel climate adaptation following global invasion of a cosmopolitan plant', Nature Ecology and Evolution, vol. 9, no. 8, pp. 1441-1455. https://doi.org/10.1038/s41559-025-02751-2

TY - JOUR

T1 - Haploblocks contribute to parallel climate adaptation following global invasion of a cosmopolitan plant

AU - Battlay, Paul

AU - Hendrickson, Brandon T.

AU - Mendez-Reneau, Jonas I.

AU - Santangelo, James S.

AU - Albano, Lucas J.

AU - Wilson, Jonathan

AU - Caizergues, Aude E.

AU - King, Nevada

AU - Puentes, Adriana

AU - Tudoran, Amelia

AU - Violle, Cyrille

AU - Vasseur, Francois

AU - Patterson, Courtney M.

AU - Foster, Michael

AU - Stamps, Caitlyn

AU - Innes, Simon G.

AU - Allio, Rémi

AU - Angeoletto, Fabio

AU - Anstett, Daniel N.

AU - Anstett, Julia

AU - Bucharova, Anna

AU - Comerford, Mattheau S.

AU - David, Santiago

AU - Falahati-Anbaran, Mohsen

AU - Godsoe, William

AU - González-Lagos, César

AU - Gundel, Pedro E.

AU - Hood, Glen Ray

AU - Lampei, Christian

AU - Lara, Carlos

AU - Lázaro-Lobo, Adrián

AU - Silva Leandro, Deleon

AU - Merritt, Thomas J.S.

AU - Mitchell, Nora

AU - Mohammadi Bazargani, Mitra

AU - Moles, Angela

AU - Murúa, Maureen

AU - Paule, Juraj

AU - Pfeiffer, Vera

AU - Raeymaekers, Joost A.M.

AU - Rennison, Diana J.

AU - Rios, Rodrigo S.

AU - Rowntree, Jennifer K.

AU - Schneider, Adam C.

AU - Stack Whitney, Kaitlin

AU - Tamburrino, Ítalo

AU - VanWallendael, Acer

AU - Kim, Paul Y.

AU - Ness, Rob W.

AU - Johnson, Marc T.J.

AU - Hodgins, Kathryn A.

AU - Kooyers, Nicholas J.

PY - 2025/7/8

Y1 - 2025/7/8

N2 - The role of rapid adaptation during species invasions has historically been minimized with the assumption that introductions consist of few colonists and limited genetic diversity. While overwhelming evidence suggests that rapid adaptation is more prevalent than originally assumed, the demographic and adaptive processes underlying successful invasions remain unresolved. Here we leverage a large whole-genome sequence dataset to investigate the relative roles of colonization history and adaptation during the worldwide invasion of the forage crop, Trifolium repens (Fabaceae). We show that introduced populations encompass high levels of genetic variation with little evidence of bottlenecks. Independent colonization histories on different continents are evident from genome-wide population structure. Five haploblocks—large haplotypes with limited recombination—on three chromosomes exist as standing genetic variation within the native and introduced ranges and exhibit strong signatures of parallel climate-associated adaptation across continents. Field experiments in the native and introduced ranges demonstrate that three of the haploblocks strongly affect fitness and exhibit patterns of selection consistent with local adaptation across each range. Our results provide strong evidence that large-effect structural variants contribute substantially to rapid and parallel adaptation of an introduced species throughout the world.

AB - The role of rapid adaptation during species invasions has historically been minimized with the assumption that introductions consist of few colonists and limited genetic diversity. While overwhelming evidence suggests that rapid adaptation is more prevalent than originally assumed, the demographic and adaptive processes underlying successful invasions remain unresolved. Here we leverage a large whole-genome sequence dataset to investigate the relative roles of colonization history and adaptation during the worldwide invasion of the forage crop, Trifolium repens (Fabaceae). We show that introduced populations encompass high levels of genetic variation with little evidence of bottlenecks. Independent colonization histories on different continents are evident from genome-wide population structure. Five haploblocks—large haplotypes with limited recombination—on three chromosomes exist as standing genetic variation within the native and introduced ranges and exhibit strong signatures of parallel climate-associated adaptation across continents. Field experiments in the native and introduced ranges demonstrate that three of the haploblocks strongly affect fitness and exhibit patterns of selection consistent with local adaptation across each range. Our results provide strong evidence that large-effect structural variants contribute substantially to rapid and parallel adaptation of an introduced species throughout the world.

UR - https://www.scopus.com/pages/publications/105010101001

UR - https://pearl.plymouth.ac.uk/bms-research/2257/

U2 - 10.1038/s41559-025-02751-2

DO - 10.1038/s41559-025-02751-2

M3 - Article

C2 - 40629086

AN - SCOPUS:105010101001

SN - 2397-334X

VL - 9

SP - 1441

EP - 1455

JO - Nature Ecology and Evolution

JF - Nature Ecology and Evolution

IS - 8

ER -

Haploblocks contribute to parallel climate adaptation following global invasion of a cosmopolitan plant

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