The genetic architecture of repeated local adaptation to climate in distantly related plants

James R. Whiting; Tom R. Booker; Clément Rougeux; Brandon M. Lind; Pooja Singh; Mengmeng Lu; Kaichi Huang; Michael C. Whitlock; Sally N. Aitken; Rose L. Andrew; Justin O. Borevitz; Jeremy J. Bruhl; Timothy L. Collins; Martin C. Fischer; Kathryn A. Hodgins; Jason A. Holliday; Pär K. Ingvarsson; Jasmine K. Janes; Momena Khandaker; Daniel Koenig; Julia M. Kreiner; Antoine Kremer; Martin Lascoux; Thibault Leroy; Pascal Milesi; Kevin D. Murray; Tanja Pyhäjärvi; Christian Rellstab; Loren H. Rieseberg; Fabrice Roux; John R. Stinchcombe; Ian R.H. Telford; Marco Todesco; Jaakko S. Tyrmi; Baosheng Wang; Detlef Weigel; Yvonne Willi; Stephen I. Wright; Lecong Zhou; Sam Yeaman

doi:10.1038/s41559-024-02514-5

The genetic architecture of repeated local adaptation to climate in distantly related plants

James R. Whiting^*, Tom R. Booker, Clément Rougeux, Brandon M. Lind, Pooja Singh, Mengmeng Lu, Kaichi Huang, Michael C. Whitlock, Sally N. Aitken, Rose L. Andrew, Justin O. Borevitz, Jeremy J. Bruhl, Timothy L. Collins, Martin C. Fischer, Kathryn A. Hodgins, Jason A. Holliday, Pär K. Ingvarsson, Jasmine K. Janes, Momena Khandaker, Daniel KoenigJulia M. Kreiner, Antoine Kremer, Martin Lascoux, Thibault Leroy, Pascal Milesi, Kevin D. Murray, Tanja Pyhäjärvi, Christian Rellstab, Loren H. Rieseberg, Fabrice Roux, John R. Stinchcombe, Ian R.H. Telford, Marco Todesco, Jaakko S. Tyrmi, Baosheng Wang, Detlef Weigel, Yvonne Willi, Stephen I. Wright, Lecong Zhou, Sam Yeaman^*

^*Corresponding author for this work

Division of Plant Sciences

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

15 Citations (Scopus)

Abstract

Closely related species often use the same genes to adapt to similar environments. However, we know little about why such genes possess increased adaptive potential and whether this is conserved across deeper evolutionary lineages. Adaptation to climate presents a natural laboratory to test these ideas, as even distantly related species must contend with similar stresses. Here, we re-analyse genomic data from thousands of individuals from 25 plant species as diverged as lodgepole pine and Arabidopsis (~300 Myr). We test for genetic repeatability based on within-species associations between allele frequencies in genes and variation in 21 climate variables. Our results demonstrate significant statistical evidence for genetic repeatability across deep time that is not expected under randomness, identifying a suite of 108 gene families (orthogroups) and gene functions that repeatedly drive local adaptation to climate. This set includes many orthogroups with well-known functions in abiotic stress response. Using gene co-expression networks to quantify pleiotropy, we find that orthogroups with stronger evidence for repeatability exhibit greater network centrality and broader expression across tissues (higher pleiotropy), contrary to the ‘cost of complexity’ theory. These gene families may be important in helping wild and crop species cope with future climate change, representing important candidates for future study.

Original language	English
Pages (from-to)	1933-1947
Number of pages	15
Journal	Nature Ecology and Evolution
Volume	8
Issue number	10
DOIs	https://doi.org/10.1038/s41559-024-02514-5
Publication status	Published - Oct 2024

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Whiting, J. R., Booker, T. R., Rougeux, C., Lind, B. M., Singh, P., Lu, M., Huang, K., Whitlock, M. C., Aitken, S. N., Andrew, R. L., Borevitz, J. O., Bruhl, J. J., Collins, T. L., Fischer, M. C., Hodgins, K. A., Holliday, J. A., Ingvarsson, P. K., Janes, J. K., Khandaker, M., ... Yeaman, S. (2024). The genetic architecture of repeated local adaptation to climate in distantly related plants. Nature Ecology and Evolution, 8(10), 1933-1947. https://doi.org/10.1038/s41559-024-02514-5

@article{1b38c0cc000a4400a99d38441d35d5be,

title = "The genetic architecture of repeated local adaptation to climate in distantly related plants",

abstract = "Closely related species often use the same genes to adapt to similar environments. However, we know little about why such genes possess increased adaptive potential and whether this is conserved across deeper evolutionary lineages. Adaptation to climate presents a natural laboratory to test these ideas, as even distantly related species must contend with similar stresses. Here, we re-analyse genomic data from thousands of individuals from 25 plant species as diverged as lodgepole pine and Arabidopsis (~300 Myr). We test for genetic repeatability based on within-species associations between allele frequencies in genes and variation in 21 climate variables. Our results demonstrate significant statistical evidence for genetic repeatability across deep time that is not expected under randomness, identifying a suite of 108 gene families (orthogroups) and gene functions that repeatedly drive local adaptation to climate. This set includes many orthogroups with well-known functions in abiotic stress response. Using gene co-expression networks to quantify pleiotropy, we find that orthogroups with stronger evidence for repeatability exhibit greater network centrality and broader expression across tissues (higher pleiotropy), contrary to the {\textquoteleft}cost of complexity{\textquoteright} theory. These gene families may be important in helping wild and crop species cope with future climate change, representing important candidates for future study.",

author = "Whiting, {James R.} and Booker, {Tom R.} and Cl{\'e}ment Rougeux and Lind, {Brandon M.} and Pooja Singh and Mengmeng Lu and Kaichi Huang and Whitlock, {Michael C.} and Aitken, {Sally N.} and Andrew, {Rose L.} and Borevitz, {Justin O.} and Bruhl, {Jeremy J.} and Collins, {Timothy L.} and Fischer, {Martin C.} and Hodgins, {Kathryn A.} and Holliday, {Jason A.} and Ingvarsson, {P{\"a}r K.} and Janes, {Jasmine K.} and Momena Khandaker and Daniel Koenig and Kreiner, {Julia M.} and Antoine Kremer and Martin Lascoux and Thibault Leroy and Pascal Milesi and Murray, {Kevin D.} and Tanja Pyh{\"a}j{\"a}rvi and Christian Rellstab and Rieseberg, {Loren H.} and Fabrice Roux and Stinchcombe, {John R.} and Telford, {Ian R.H.} and Marco Todesco and Tyrmi, {Jaakko S.} and Baosheng Wang and Detlef Weigel and Yvonne Willi and Wright, {Stephen I.} and Lecong Zhou and Sam Yeaman",

note = "Publisher Copyright: {\textcopyright} The Author(s) 2024.",

year = "2024",

month = oct,

doi = "10.1038/s41559-024-02514-5",

language = "English",

volume = "8",

pages = "1933--1947",

journal = "Nature Ecology and Evolution",

issn = "2397-334X",

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Whiting, JR, Booker, TR, Rougeux, C, Lind, BM, Singh, P, Lu, M, Huang, K, Whitlock, MC, Aitken, SN, Andrew, RL, Borevitz, JO, Bruhl, JJ, Collins, TL, Fischer, MC, Hodgins, KA, Holliday, JA, Ingvarsson, PK, Janes, JK, Khandaker, M, Koenig, D, Kreiner, JM, Kremer, A, Lascoux, M, Leroy, T, Milesi, P, Murray, KD, Pyhäjärvi, T, Rellstab, C, Rieseberg, LH, Roux, F, Stinchcombe, JR, Telford, IRH, Todesco, M, Tyrmi, JS, Wang, B, Weigel, D, Willi, Y, Wright, SI, Zhou, L & Yeaman, S 2024, 'The genetic architecture of repeated local adaptation to climate in distantly related plants', Nature Ecology and Evolution, vol. 8, no. 10, pp. 1933-1947. https://doi.org/10.1038/s41559-024-02514-5

TY - JOUR

T1 - The genetic architecture of repeated local adaptation to climate in distantly related plants

AU - Whiting, James R.

AU - Booker, Tom R.

AU - Rougeux, Clément

AU - Lind, Brandon M.

AU - Singh, Pooja

AU - Lu, Mengmeng

AU - Huang, Kaichi

AU - Whitlock, Michael C.

AU - Aitken, Sally N.

AU - Andrew, Rose L.

AU - Borevitz, Justin O.

AU - Bruhl, Jeremy J.

AU - Collins, Timothy L.

AU - Fischer, Martin C.

AU - Hodgins, Kathryn A.

AU - Holliday, Jason A.

AU - Ingvarsson, Pär K.

AU - Janes, Jasmine K.

AU - Khandaker, Momena

AU - Koenig, Daniel

AU - Kreiner, Julia M.

AU - Kremer, Antoine

AU - Lascoux, Martin

AU - Leroy, Thibault

AU - Milesi, Pascal

AU - Murray, Kevin D.

AU - Pyhäjärvi, Tanja

AU - Rellstab, Christian

AU - Rieseberg, Loren H.

AU - Roux, Fabrice

AU - Stinchcombe, John R.

AU - Telford, Ian R.H.

AU - Todesco, Marco

AU - Tyrmi, Jaakko S.

AU - Wang, Baosheng

AU - Weigel, Detlef

AU - Willi, Yvonne

AU - Wright, Stephen I.

AU - Zhou, Lecong

AU - Yeaman, Sam

PY - 2024/10

Y1 - 2024/10

N2 - Closely related species often use the same genes to adapt to similar environments. However, we know little about why such genes possess increased adaptive potential and whether this is conserved across deeper evolutionary lineages. Adaptation to climate presents a natural laboratory to test these ideas, as even distantly related species must contend with similar stresses. Here, we re-analyse genomic data from thousands of individuals from 25 plant species as diverged as lodgepole pine and Arabidopsis (~300 Myr). We test for genetic repeatability based on within-species associations between allele frequencies in genes and variation in 21 climate variables. Our results demonstrate significant statistical evidence for genetic repeatability across deep time that is not expected under randomness, identifying a suite of 108 gene families (orthogroups) and gene functions that repeatedly drive local adaptation to climate. This set includes many orthogroups with well-known functions in abiotic stress response. Using gene co-expression networks to quantify pleiotropy, we find that orthogroups with stronger evidence for repeatability exhibit greater network centrality and broader expression across tissues (higher pleiotropy), contrary to the ‘cost of complexity’ theory. These gene families may be important in helping wild and crop species cope with future climate change, representing important candidates for future study.

AB - Closely related species often use the same genes to adapt to similar environments. However, we know little about why such genes possess increased adaptive potential and whether this is conserved across deeper evolutionary lineages. Adaptation to climate presents a natural laboratory to test these ideas, as even distantly related species must contend with similar stresses. Here, we re-analyse genomic data from thousands of individuals from 25 plant species as diverged as lodgepole pine and Arabidopsis (~300 Myr). We test for genetic repeatability based on within-species associations between allele frequencies in genes and variation in 21 climate variables. Our results demonstrate significant statistical evidence for genetic repeatability across deep time that is not expected under randomness, identifying a suite of 108 gene families (orthogroups) and gene functions that repeatedly drive local adaptation to climate. This set includes many orthogroups with well-known functions in abiotic stress response. Using gene co-expression networks to quantify pleiotropy, we find that orthogroups with stronger evidence for repeatability exhibit greater network centrality and broader expression across tissues (higher pleiotropy), contrary to the ‘cost of complexity’ theory. These gene families may be important in helping wild and crop species cope with future climate change, representing important candidates for future study.

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U2 - 10.1038/s41559-024-02514-5

DO - 10.1038/s41559-024-02514-5

M3 - Article

C2 - 39187610

AN - SCOPUS:85202469978

SN - 2397-334X

VL - 8

SP - 1933

EP - 1947

JO - Nature Ecology and Evolution

JF - Nature Ecology and Evolution

IS - 10

ER -

The genetic architecture of repeated local adaptation to climate in distantly related plants

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