Genome of wild olive and the evolution of oil biosynthesis

Turgay Unver; Zhangyan Wu; Lieven Sterck; Mine Turktas; Rolf Lohaus; Zhen Li; Ming Yang; Lijuan He; Tianquan Deng; Francisco Javier Escalante; Carlos Llorens; Francisco J. Roig; Iskender Parmaksiz; Ekrem Dundar; Fuliang Xie; Baohong Zhang; Arif Ipek; Serkan Uranbey; Mustafa Erayman; Emre Ilhan; Oussama Badad; Hassan Ghazal; David A. Lightfoot; Pavan Kasarla; Vincent Colantonio; Huseyin Tombuloglu; Pilar Hernandez; Nurengin Mete; Oznur Cetin; Marc Van Montagu; Huanming Yang; Qiang Gao; Gabriel Dorado; Yves Van de Peer

doi:10.1073/pnas.1708621114

Genome of wild olive and the evolution of oil biosynthesis

Turgay Unver
, Zhangyan Wu
, Lieven Sterck
, Mine Turktas
, Rolf Lohaus
, Zhen Li
, Ming Yang
, Lijuan He
, Tianquan Deng
, Francisco Javier Escalante
, Carlos Llorens
, Francisco J. Roig
, Iskender Parmaksiz
, Ekrem Dundar
, Fuliang Xie
, Baohong Zhang
, Arif Ipek
, Serkan Uranbey
, Mustafa Erayman
, Emre Ilhan

Oussama Badad, Hassan Ghazal, David A. Lightfoot, Pavan Kasarla, Vincent Colantonio, Huseyin Tombuloglu, Pilar Hernandez, Nurengin Mete, Oznur Cetin, Marc Van Montagu, Huanming Yang, Qiang Gao, Gabriel Dorado, Yves Van de Peer

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

234 Scopus citations

Abstract

Here we present the genome sequence and annotation of the wild olive tree (Olea europaea var. sylvestris), called oleaster, which is considered an ancestor of cultivated olive trees. More than 50,000 protein-coding genes were predicted, a majority of which could be anchored to 23 pseudochromosomes obtained through a newly constructed genetic map. The oleaster genome contains signatures of two Oleaceae lineage-specific paleopolyploidy events, dated at ∼28 and ∼59 Mya. These events contributed to the expansion and neofunctionalization of genes and gene families that play important roles in oil biosynthesis. The functional divergence of oil biosynthesis pathway genes, such as FAD2, SACPD, EAR, and ACPTE, following duplication, has been responsible for the differential accumulation of oleic and linoleic acids produced in olive compared with sesame, a closely related oil crop. Duplicated oleaster FAD2 genes are regulated by an siRNA derived from a transposable element-rich region, leading to suppressed levels of FAD2 gene expression. Additionally, neofunctionalization of members of the SACPD gene family has led to increased expression of SACPD2, 3, 5, and 7, consequently resulting in an increased desaturation of steric acid. Taken together, decreased FAD2 expression and increased SACPD expression likely explain the accumulation of exceptionally high levels of oleic acid in olive. The oleaster genome thus provides important insights into the evolution of oil biosynthesis and will be a valuable resource for oil crop genomics.

Original language	English
Pages (from-to)	E9413-E9422
Journal	Proceedings of the National Academy of Sciences of the United States of America
Volume	114
Issue number	44
DOIs	https://doi.org/10.1073/pnas.1708621114
State	Published - 31 Oct 2017
Externally published	Yes

Keywords

Fatty-acid biosynthesis
Oil crop
Polyunsaturated fatty-acid pathway
Whole-genome duplication
siRNA regulation

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10.1073/pnas.1708621114

Cite this

Unver, T., Wu, Z., Sterck, L., Turktas, M., Lohaus, R., Li, Z., Yang, M., He, L., Deng, T., Escalante, F. J., Llorens, C., Roig, F. J., Parmaksiz, I., Dundar, E., Xie, F., Zhang, B., Ipek, A., Uranbey, S., Erayman, M., ... Van de Peer, Y. (2017). Genome of wild olive and the evolution of oil biosynthesis. Proceedings of the National Academy of Sciences of the United States of America, 114(44), E9413-E9422. https://doi.org/10.1073/pnas.1708621114

@article{c63d106aa7434940bd8b0e827cda0f4d,

title = "Genome of wild olive and the evolution of oil biosynthesis",

abstract = "Here we present the genome sequence and annotation of the wild olive tree (Olea europaea var. sylvestris), called oleaster, which is considered an ancestor of cultivated olive trees. More than 50,000 protein-coding genes were predicted, a majority of which could be anchored to 23 pseudochromosomes obtained through a newly constructed genetic map. The oleaster genome contains signatures of two Oleaceae lineage-specific paleopolyploidy events, dated at ∼28 and ∼59 Mya. These events contributed to the expansion and neofunctionalization of genes and gene families that play important roles in oil biosynthesis. The functional divergence of oil biosynthesis pathway genes, such as FAD2, SACPD, EAR, and ACPTE, following duplication, has been responsible for the differential accumulation of oleic and linoleic acids produced in olive compared with sesame, a closely related oil crop. Duplicated oleaster FAD2 genes are regulated by an siRNA derived from a transposable element-rich region, leading to suppressed levels of FAD2 gene expression. Additionally, neofunctionalization of members of the SACPD gene family has led to increased expression of SACPD2, 3, 5, and 7, consequently resulting in an increased desaturation of steric acid. Taken together, decreased FAD2 expression and increased SACPD expression likely explain the accumulation of exceptionally high levels of oleic acid in olive. The oleaster genome thus provides important insights into the evolution of oil biosynthesis and will be a valuable resource for oil crop genomics.",

keywords = "Fatty-acid biosynthesis, Oil crop, Polyunsaturated fatty-acid pathway, Whole-genome duplication, siRNA regulation",

author = "Turgay Unver and Zhangyan Wu and Lieven Sterck and Mine Turktas and Rolf Lohaus and Zhen Li and Ming Yang and Lijuan He and Tianquan Deng and Escalante, \{Francisco Javier\} and Carlos Llorens and Roig, \{Francisco J.\} and Iskender Parmaksiz and Ekrem Dundar and Fuliang Xie and Baohong Zhang and Arif Ipek and Serkan Uranbey and Mustafa Erayman and Emre Ilhan and Oussama Badad and Hassan Ghazal and Lightfoot, \{David A.\} and Pavan Kasarla and Vincent Colantonio and Huseyin Tombuloglu and Pilar Hernandez and Nurengin Mete and Oznur Cetin and \{Van Montagu\}, Marc and Huanming Yang and Qiang Gao and Gabriel Dorado and \{Van de Peer\}, Yves",

year = "2017",

month = oct,

day = "31",

doi = "10.1073/pnas.1708621114",

language = "英语",

volume = "114",

pages = "E9413--E9422",

journal = "Proceedings of the National Academy of Sciences of the United States of America",

issn = "0027-8424",

publisher = "National Academy of Sciences",

number = "44",

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Unver, T, Wu, Z, Sterck, L, Turktas, M, Lohaus, R, Li, Z, Yang, M, He, L, Deng, T, Escalante, FJ, Llorens, C, Roig, FJ, Parmaksiz, I, Dundar, E, Xie, F, Zhang, B, Ipek, A, Uranbey, S, Erayman, M, Ilhan, E, Badad, O, Ghazal, H, Lightfoot, DA, Kasarla, P, Colantonio, V, Tombuloglu, H, Hernandez, P, Mete, N, Cetin, O, Van Montagu, M, Yang, H, Gao, Q, Dorado, G & Van de Peer, Y 2017, 'Genome of wild olive and the evolution of oil biosynthesis', Proceedings of the National Academy of Sciences of the United States of America, vol. 114, no. 44, pp. E9413-E9422. https://doi.org/10.1073/pnas.1708621114

TY - JOUR

T1 - Genome of wild olive and the evolution of oil biosynthesis

AU - Unver, Turgay

AU - Wu, Zhangyan

AU - Sterck, Lieven

AU - Turktas, Mine

AU - Lohaus, Rolf

AU - Li, Zhen

AU - Yang, Ming

AU - He, Lijuan

AU - Deng, Tianquan

AU - Escalante, Francisco Javier

AU - Llorens, Carlos

AU - Roig, Francisco J.

AU - Parmaksiz, Iskender

AU - Dundar, Ekrem

AU - Xie, Fuliang

AU - Zhang, Baohong

AU - Ipek, Arif

AU - Uranbey, Serkan

AU - Erayman, Mustafa

AU - Ilhan, Emre

AU - Badad, Oussama

AU - Ghazal, Hassan

AU - Lightfoot, David A.

AU - Kasarla, Pavan

AU - Colantonio, Vincent

AU - Tombuloglu, Huseyin

AU - Hernandez, Pilar

AU - Mete, Nurengin

AU - Cetin, Oznur

AU - Van Montagu, Marc

AU - Yang, Huanming

AU - Gao, Qiang

AU - Dorado, Gabriel

AU - Van de Peer, Yves

PY - 2017/10/31

Y1 - 2017/10/31

N2 - Here we present the genome sequence and annotation of the wild olive tree (Olea europaea var. sylvestris), called oleaster, which is considered an ancestor of cultivated olive trees. More than 50,000 protein-coding genes were predicted, a majority of which could be anchored to 23 pseudochromosomes obtained through a newly constructed genetic map. The oleaster genome contains signatures of two Oleaceae lineage-specific paleopolyploidy events, dated at ∼28 and ∼59 Mya. These events contributed to the expansion and neofunctionalization of genes and gene families that play important roles in oil biosynthesis. The functional divergence of oil biosynthesis pathway genes, such as FAD2, SACPD, EAR, and ACPTE, following duplication, has been responsible for the differential accumulation of oleic and linoleic acids produced in olive compared with sesame, a closely related oil crop. Duplicated oleaster FAD2 genes are regulated by an siRNA derived from a transposable element-rich region, leading to suppressed levels of FAD2 gene expression. Additionally, neofunctionalization of members of the SACPD gene family has led to increased expression of SACPD2, 3, 5, and 7, consequently resulting in an increased desaturation of steric acid. Taken together, decreased FAD2 expression and increased SACPD expression likely explain the accumulation of exceptionally high levels of oleic acid in olive. The oleaster genome thus provides important insights into the evolution of oil biosynthesis and will be a valuable resource for oil crop genomics.

AB - Here we present the genome sequence and annotation of the wild olive tree (Olea europaea var. sylvestris), called oleaster, which is considered an ancestor of cultivated olive trees. More than 50,000 protein-coding genes were predicted, a majority of which could be anchored to 23 pseudochromosomes obtained through a newly constructed genetic map. The oleaster genome contains signatures of two Oleaceae lineage-specific paleopolyploidy events, dated at ∼28 and ∼59 Mya. These events contributed to the expansion and neofunctionalization of genes and gene families that play important roles in oil biosynthesis. The functional divergence of oil biosynthesis pathway genes, such as FAD2, SACPD, EAR, and ACPTE, following duplication, has been responsible for the differential accumulation of oleic and linoleic acids produced in olive compared with sesame, a closely related oil crop. Duplicated oleaster FAD2 genes are regulated by an siRNA derived from a transposable element-rich region, leading to suppressed levels of FAD2 gene expression. Additionally, neofunctionalization of members of the SACPD gene family has led to increased expression of SACPD2, 3, 5, and 7, consequently resulting in an increased desaturation of steric acid. Taken together, decreased FAD2 expression and increased SACPD expression likely explain the accumulation of exceptionally high levels of oleic acid in olive. The oleaster genome thus provides important insights into the evolution of oil biosynthesis and will be a valuable resource for oil crop genomics.

KW - Fatty-acid biosynthesis

KW - Oil crop

KW - Polyunsaturated fatty-acid pathway

KW - Whole-genome duplication

KW - siRNA regulation

UR - https://www.scopus.com/pages/publications/85032730181

U2 - 10.1073/pnas.1708621114

DO - 10.1073/pnas.1708621114

M3 - 文章

C2 - 29078332

AN - SCOPUS:85032730181

SN - 0027-8424

VL - 114

SP - E9413-E9422

JO - Proceedings of the National Academy of Sciences of the United States of America

JF - Proceedings of the National Academy of Sciences of the United States of America

IS - 44

ER -

Genome of wild olive and the evolution of oil biosynthesis

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Keywords

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