A pangenome and pantranscriptome of hexaploid oat

Raz Avni; Nadia Kamal; Lidija Bitz; Eric N. Jellen; Wubishet A. Bekele; Tefera T. Angessa; Petri Auvinen; Oliver Bitz; Brian Boyle; Francisco J. Canales; Craig H. Carlson; Brett Chapman; Harmeet Singh Chawla; Yutang Chen; Dario Copetti; Samara Correia de Lemos; Viet Dang; Steven R. Eichten; Kathy Esvelt Klos; Amit M. Fenn; Anne Fiebig; Yong Bi Fu; Heidrun Gundlach; Rajeev Gupta; Georg Haberer; Tianhua He; Matthias H. Herrmann; Axel Himmelbach; Catherine J. Howarth; Haifei Hu; Julio Isidro y Sánchez; Asuka Itaya; Jean Luc Jannink; Yong Jia; Rajvinder Kaur; Manuela Knauft; Tim Langdon; Thomas Lux; Sofia Marmon; Vanda Marosi; Klaus F.X. Mayer; Steve Michel; Raja Sekhar Nandety; Kirby T. Nilsen; Edyta Paczos-Grzęda; Asher Pasha; Elena Prats; Nicholas J. Provart; Adriana Ravagnani; Robert W. Reid; Jessica A. Schlueter; Alan H. Schulman; Taner Z. Sen; Jaswinder Singh; Mehtab Singh; Nick Sirijovski; Nils Stein; Bruno Studer; Sirja Viitala; Shauna Vronces; Sean Walkowiak; Penghao Wang; Amanda J. Waters; Charlene P. Wight; Weikai Yan; Eric Yao; Xiao Qi Zhang; Gaofeng Zhou; Zhou Zhou; Nicholas A. Tinker; Jason D. Fiedler; Chengdao Li; Peter J. Maughan; Manuel Spannagl; Martin Mascher

doi:10.1038/s41586-025-09676-7

A pangenome and pantranscriptome of hexaploid oat

Raz Avni
, Nadia Kamal
, Lidija Bitz
, Eric N. Jellen
, Wubishet A. Bekele
, Tefera T. Angessa
, Petri Auvinen
, Oliver Bitz
, Brian Boyle
, Francisco J. Canales
, Craig H. Carlson
, Brett Chapman
, Harmeet Singh Chawla
, Yutang Chen
, Dario Copetti
, Samara Correia de Lemos
, Viet Dang
, Steven R. Eichten
, Kathy Esvelt Klos
, Amit M. Fenn

Anne Fiebig, Yong Bi Fu, Heidrun Gundlach, Rajeev Gupta, Georg Haberer, Tianhua He, Matthias H. Herrmann, Axel Himmelbach, Catherine J. Howarth, Haifei Hu, Julio Isidro y Sánchez, Asuka Itaya, Jean Luc Jannink, Yong Jia, Rajvinder Kaur, Manuela Knauft, Tim Langdon, Thomas Lux, Sofia Marmon, Vanda Marosi, Klaus F.X. Mayer, Steve Michel, Raja Sekhar Nandety, Kirby T. Nilsen, Edyta Paczos-Grzęda, Asher Pasha, Elena Prats, Nicholas J. Provart, Adriana Ravagnani, Robert W. Reid, Jessica A. Schlueter, Alan H. Schulman, Taner Z. Sen, Jaswinder Singh, Mehtab Singh, Nick Sirijovski, Nils Stein, Bruno Studer, Sirja Viitala, Shauna Vronces, Sean Walkowiak, Penghao Wang, Amanda J. Waters, Charlene P. Wight, Weikai Yan, Eric Yao, Xiao Qi Zhang, Gaofeng Zhou, Zhou Zhou, Nicholas A. Tinker^*, Jason D. Fiedler^*, Chengdao Li^*, Peter J. Maughan^*, Manuel Spannagl^*, Martin Mascher^*

^*Corresponding author for this work

Institute of Biological, Environmental, and Rural Sciences

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

1 Citation (Scopus)

Abstract

Oat grain is a traditional human food that is rich in dietary fibre and contributes to improved human health . Interest in the crop has surged in recent years owing to its use as the basis for plant-based milk analogues . Oat is an allohexaploid with a large, repeat-rich genome that was shaped by subgenome exchanges over evolutionary timescales . In contrast to many other cereal species, genomic research in oat is still at an early stage, and surveys of structural genome diversity and gene expression variability are scarce. Here we present annotated chromosome-scale sequence assemblies of 33 wild and domesticated oat lines, along with an atlas of gene expression across 6 tissues of different developmental stages in 23 of these lines. We construct an atlas of gene-expression diversity across subgenomes, accessions and tissues. Gene loss in the hexaploid is accompanied by compensatory upregulation of the remaining homeologues, but this process is constrained by subgenome divergence. Chromosomal rearrangements have substantially affected recent oat breeding. A large pericentric inversion associated with early flowering explains distorted segregation on chromosome 7D and a homeologous sequence exchange between chromosomes 2A and 2C in a semi-dwarf mutant has risen to prominence in Australian elite varieties. The oat pangenome will promote the adoption of genomic approaches to understanding the evolution and adaptation of domesticated oats and will accelerate their improvement.

Original language	English
Number of pages	31
Journal	Nature
Early online date	29 Oct 2025
DOIs	https://doi.org/10.1038/s41586-025-09676-7
Publication status	Published - 29 Oct 2025

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ArticleFinal published version, 41.7 MBLicence: CC BY
Supplementary materialData, 3.26 MBLicence: CC BY

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Avni, R., Kamal, N., Bitz, L., Jellen, E. N., Bekele, W. A., Angessa, T. T., Auvinen, P., Bitz, O., Boyle, B., Canales, F. J., Carlson, C. H., Chapman, B., Chawla, H. S., Chen, Y., Copetti, D., Correia de Lemos, S., Dang, V., Eichten, S. R., Klos, K. E., ... Mascher, M. (2025). A pangenome and pantranscriptome of hexaploid oat. Nature. https://doi.org/10.1038/s41586-025-09676-7

@article{2d92645514144768a209016625d2da9a,

title = "A pangenome and pantranscriptome of hexaploid oat",

abstract = "Oat grain is a traditional human food that is rich in dietary fibre and contributes to improved human health . Interest in the crop has surged in recent years owing to its use as the basis for plant-based milk analogues . Oat is an allohexaploid with a large, repeat-rich genome that was shaped by subgenome exchanges over evolutionary timescales . In contrast to many other cereal species, genomic research in oat is still at an early stage, and surveys of structural genome diversity and gene expression variability are scarce. Here we present annotated chromosome-scale sequence assemblies of 33 wild and domesticated oat lines, along with an atlas of gene expression across 6 tissues of different developmental stages in 23 of these lines. We construct an atlas of gene-expression diversity across subgenomes, accessions and tissues. Gene loss in the hexaploid is accompanied by compensatory upregulation of the remaining homeologues, but this process is constrained by subgenome divergence. Chromosomal rearrangements have substantially affected recent oat breeding. A large pericentric inversion associated with early flowering explains distorted segregation on chromosome 7D and a homeologous sequence exchange between chromosomes 2A and 2C in a semi-dwarf mutant has risen to prominence in Australian elite varieties. The oat pangenome will promote the adoption of genomic approaches to understanding the evolution and adaptation of domesticated oats and will accelerate their improvement.",

author = "Raz Avni and Nadia Kamal and Lidija Bitz and Jellen, \{Eric N.\} and Bekele, \{Wubishet A.\} and Angessa, \{Tefera T.\} and Petri Auvinen and Oliver Bitz and Brian Boyle and Canales, \{Francisco J.\} and Carlson, \{Craig H.\} and Brett Chapman and Chawla, \{Harmeet Singh\} and Yutang Chen and Dario Copetti and \{Correia de Lemos\}, Samara and Viet Dang and Eichten, \{Steven R.\} and Klos, \{Kathy Esvelt\} and Fenn, \{Amit M.\} and Anne Fiebig and Fu, \{Yong Bi\} and Heidrun Gundlach and Rajeev Gupta and Georg Haberer and Tianhua He and Herrmann, \{Matthias H.\} and Axel Himmelbach and Howarth, \{Catherine J.\} and Haifei Hu and \{Isidro y S{\'a}nchez\}, Julio and Asuka Itaya and Jannink, \{Jean Luc\} and Yong Jia and Rajvinder Kaur and Manuela Knauft and Tim Langdon and Thomas Lux and Sofia Marmon and Vanda Marosi and Mayer, \{Klaus F.X.\} and Steve Michel and Nandety, \{Raja Sekhar\} and Nilsen, \{Kirby T.\} and Edyta Paczos-Grz{\c e}da and Asher Pasha and Elena Prats and Provart, \{Nicholas J.\} and Adriana Ravagnani and Reid, \{Robert W.\} and Schlueter, \{Jessica A.\} and Schulman, \{Alan H.\} and Sen, \{Taner Z.\} and Jaswinder Singh and Mehtab Singh and Nick Sirijovski and Nils Stein and Bruno Studer and Sirja Viitala and Shauna Vronces and Sean Walkowiak and Penghao Wang and Waters, \{Amanda J.\} and Wight, \{Charlene P.\} and Weikai Yan and Eric Yao and Zhang, \{Xiao Qi\} and Gaofeng Zhou and Zhou Zhou and Tinker, \{Nicholas A.\} and Fiedler, \{Jason D.\} and Chengdao Li and Maughan, \{Peter J.\} and Manuel Spannagl and Martin Mascher",

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

year = "2025",

month = oct,

day = "29",

doi = "10.1038/s41586-025-09676-7",

language = "English",

journal = "Nature",

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publisher = "Springer Nature",

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Avni, R, Kamal, N, Bitz, L, Jellen, EN, Bekele, WA, Angessa, TT, Auvinen, P, Bitz, O, Boyle, B, Canales, FJ, Carlson, CH, Chapman, B, Chawla, HS, Chen, Y, Copetti, D, Correia de Lemos, S, Dang, V, Eichten, SR, Klos, KE, Fenn, AM, Fiebig, A, Fu, YB, Gundlach, H, Gupta, R, Haberer, G, He, T, Herrmann, MH, Himmelbach, A, Howarth, CJ, Hu, H, Isidro y Sánchez, J, Itaya, A, Jannink, JL, Jia, Y, Kaur, R, Knauft, M, Langdon, T, Lux, T, Marmon, S, Marosi, V, Mayer, KFX, Michel, S, Nandety, RS, Nilsen, KT, Paczos-Grzęda, E, Pasha, A, Prats, E, Provart, NJ, Ravagnani, A, Reid, RW, Schlueter, JA, Schulman, AH, Sen, TZ, Singh, J, Singh, M, Sirijovski, N, Stein, N, Studer, B, Viitala, S, Vronces, S, Walkowiak, S, Wang, P, Waters, AJ, Wight, CP, Yan, W, Yao, E, Zhang, XQ, Zhou, G, Zhou, Z, Tinker, NA, Fiedler, JD, Li, C, Maughan, PJ, Spannagl, M & Mascher, M 2025, 'A pangenome and pantranscriptome of hexaploid oat', Nature. https://doi.org/10.1038/s41586-025-09676-7

TY - JOUR

T1 - A pangenome and pantranscriptome of hexaploid oat

AU - Avni, Raz

AU - Kamal, Nadia

AU - Bitz, Lidija

AU - Jellen, Eric N.

AU - Bekele, Wubishet A.

AU - Angessa, Tefera T.

AU - Auvinen, Petri

AU - Bitz, Oliver

AU - Boyle, Brian

AU - Canales, Francisco J.

AU - Carlson, Craig H.

AU - Chapman, Brett

AU - Chawla, Harmeet Singh

AU - Chen, Yutang

AU - Copetti, Dario

AU - Correia de Lemos, Samara

AU - Dang, Viet

AU - Eichten, Steven R.

AU - Klos, Kathy Esvelt

AU - Fenn, Amit M.

AU - Fiebig, Anne

AU - Fu, Yong Bi

AU - Gundlach, Heidrun

AU - Gupta, Rajeev

AU - Haberer, Georg

AU - He, Tianhua

AU - Herrmann, Matthias H.

AU - Himmelbach, Axel

AU - Howarth, Catherine J.

AU - Hu, Haifei

AU - Isidro y Sánchez, Julio

AU - Itaya, Asuka

AU - Jannink, Jean Luc

AU - Jia, Yong

AU - Kaur, Rajvinder

AU - Knauft, Manuela

AU - Langdon, Tim

AU - Lux, Thomas

AU - Marmon, Sofia

AU - Marosi, Vanda

AU - Mayer, Klaus F.X.

AU - Michel, Steve

AU - Nandety, Raja Sekhar

AU - Nilsen, Kirby T.

AU - Paczos-Grzęda, Edyta

AU - Pasha, Asher

AU - Prats, Elena

AU - Provart, Nicholas J.

AU - Ravagnani, Adriana

AU - Reid, Robert W.

AU - Schlueter, Jessica A.

AU - Schulman, Alan H.

AU - Sen, Taner Z.

AU - Singh, Jaswinder

AU - Singh, Mehtab

AU - Sirijovski, Nick

AU - Stein, Nils

AU - Studer, Bruno

AU - Viitala, Sirja

AU - Vronces, Shauna

AU - Walkowiak, Sean

AU - Wang, Penghao

AU - Waters, Amanda J.

AU - Wight, Charlene P.

AU - Yan, Weikai

AU - Yao, Eric

AU - Zhang, Xiao Qi

AU - Zhou, Gaofeng

AU - Zhou, Zhou

AU - Tinker, Nicholas A.

AU - Fiedler, Jason D.

AU - Li, Chengdao

AU - Maughan, Peter J.

AU - Spannagl, Manuel

AU - Mascher, Martin

PY - 2025/10/29

Y1 - 2025/10/29

N2 - Oat grain is a traditional human food that is rich in dietary fibre and contributes to improved human health . Interest in the crop has surged in recent years owing to its use as the basis for plant-based milk analogues . Oat is an allohexaploid with a large, repeat-rich genome that was shaped by subgenome exchanges over evolutionary timescales . In contrast to many other cereal species, genomic research in oat is still at an early stage, and surveys of structural genome diversity and gene expression variability are scarce. Here we present annotated chromosome-scale sequence assemblies of 33 wild and domesticated oat lines, along with an atlas of gene expression across 6 tissues of different developmental stages in 23 of these lines. We construct an atlas of gene-expression diversity across subgenomes, accessions and tissues. Gene loss in the hexaploid is accompanied by compensatory upregulation of the remaining homeologues, but this process is constrained by subgenome divergence. Chromosomal rearrangements have substantially affected recent oat breeding. A large pericentric inversion associated with early flowering explains distorted segregation on chromosome 7D and a homeologous sequence exchange between chromosomes 2A and 2C in a semi-dwarf mutant has risen to prominence in Australian elite varieties. The oat pangenome will promote the adoption of genomic approaches to understanding the evolution and adaptation of domesticated oats and will accelerate their improvement.

AB - Oat grain is a traditional human food that is rich in dietary fibre and contributes to improved human health . Interest in the crop has surged in recent years owing to its use as the basis for plant-based milk analogues . Oat is an allohexaploid with a large, repeat-rich genome that was shaped by subgenome exchanges over evolutionary timescales . In contrast to many other cereal species, genomic research in oat is still at an early stage, and surveys of structural genome diversity and gene expression variability are scarce. Here we present annotated chromosome-scale sequence assemblies of 33 wild and domesticated oat lines, along with an atlas of gene expression across 6 tissues of different developmental stages in 23 of these lines. We construct an atlas of gene-expression diversity across subgenomes, accessions and tissues. Gene loss in the hexaploid is accompanied by compensatory upregulation of the remaining homeologues, but this process is constrained by subgenome divergence. Chromosomal rearrangements have substantially affected recent oat breeding. A large pericentric inversion associated with early flowering explains distorted segregation on chromosome 7D and a homeologous sequence exchange between chromosomes 2A and 2C in a semi-dwarf mutant has risen to prominence in Australian elite varieties. The oat pangenome will promote the adoption of genomic approaches to understanding the evolution and adaptation of domesticated oats and will accelerate their improvement.

UR - https://www.scopus.com/pages/publications/105020189979

U2 - 10.1038/s41586-025-09676-7

DO - 10.1038/s41586-025-09676-7

M3 - Article

C2 - 41162711

AN - SCOPUS:105020189979

SN - 0028-0836

JO - Nature

JF - Nature

ER -

A pangenome and pantranscriptome of hexaploid oat

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