The Brassica oleracea genome reveals the asymmetrical evolution of polyploid genomes

Shengyi Liu(Chinese Academy of Agricultural Sciences), Yumei Liu(Institute of Vegetables and Flowers), Xinhua Yang(BGI Group (China)), Chaobo Tong(Chinese Academy of Agricultural Sciences), David Edwards(Australian Centre for Plant Functional Genomics), Isobel A. P. Parkin(Agriculture and Agri-Food Canada), Meixia Zhao(Chinese Academy of Agricultural Sciences), Jianxin Ma(Purdue University West Lafayette), Jingyin Yu(Chinese Academy of Agricultural Sciences), Shunmou Huang(Chinese Academy of Agricultural Sciences), Xiyin Wang(North China University of Science and Technology), Junyi Wang(BGI Group (China)), Kun Lu(Southwest University), Zhiyuan Fang(Institute of Vegetables and Flowers), Ian Bancroft(University of York), Tae‐Jin Yang(Seoul National University), Qiong Hu(Chinese Academy of Agricultural Sciences), Xinfa Wang(University of Georgia), Zhen Yue(BGI Group (China)), Haojie Li(Sichuan Academy of Agricultural Sciences), Linfeng Yang(BGI Group (China)), Jian Wu(Institute of Vegetables and Flowers), Qing Zhou(BGI Group (China)), Wanxin Wang(Institute of Vegetables and Flowers), Graham J.W. King(Southern Cross University), J. Chris Pires(University of Missouri), Changxin Lu(BGI Group (China)), Zhangyan Wu(BGI Group (China)), Perumal Sampath(Seoul National University), Zhuo Wang(BGI Group (China)), Hui Guo(University of Georgia), Shengkai Pan(BGI Group (China)), Limei Yang(BGI Group (China)), Jiumeng Min(BGI Group (China)), Dong Zhang(University of Georgia), Dianchuan Jin(North China University of Science and Technology), Wanshun Li(BGI Group (China)), Harry Belcram, Jinxing Tu(Huazhong Agricultural University), Mei Guan(Hunan Agricultural University), QI Cun-kou(Jiangsu Academy of Agricultural Sciences), Dezhi Du(Academy of Agricultural and Forestry Sciences), Jiana Li(Southwest University), Liangcai Jiang(Sichuan Academy of Agricultural Sciences), Jacqueline Batley(Australian Research Council), Andrew Sharpe(Saskatchewan Research Council (Canada)), Beom‐Seok Park(National Academy of Agricultural Science), Pradeep Ruperao(Australian Centre for Plant Functional Genomics), Feng Cheng(Institute of Vegetables and Flowers), Nomar Espinosa Waminal(Seoul National University), Yin Huang(BGI Group (China)), Caihua Dong(Chinese Academy of Agricultural Sciences), Li Wang(North China University of Science and Technology), Jingping Li(Southwest University), Zhiyong Hu(Chinese Academy of Agricultural Sciences), Mu Zhuang(Institute of Vegetables and Flowers), Yi Huang(BGI Group (China)), Junyan Huang(Chinese Academy of Agricultural Sciences), Jiaqin Shi(Chinese Academy of Agricultural Sciences), Desheng Mei(Chinese Academy of Agricultural Sciences), Jing Liu(Chinese Academy of Agricultural Sciences), Tae‐Ho Lee(University of Georgia), Jinpeng Wang(BGI Group (China)), Huizhe Jin(University of Georgia), Zaiyun Li(Huazhong Agricultural University), Xun Li(Hunan Agricultural University), Jiefu Zhang(Jiangsu Academy of Agricultural Sciences), Lu Xiao(Academy of Agricultural and Forestry Sciences), Yongming Zhou(Huazhong Agricultural University), Zhongsong Liu(Hunan Agricultural University), Xuequn Liu(South Central Minzu University), Rui Qin(South Central Minzu University), Xu Tang(University of Georgia), Wenbin Liu(BGI Group (China)), Yupeng Wang(University of Georgia), Yangyong Zhang(Institute of Vegetables and Flowers), Jonghoon Lee(Seoul National University), Hyun Hee Kim(Sahmyook University), France Denœud(Centre National de la Recherche Scientifique), Xun Xu(BGI Group (China)), Xinming Liang(BGI Group (China)), Wei Hua(Chinese Academy of Agricultural Sciences), Xiaowu Wang(University of Georgia), Jun Wang(BGI Group (China)), Boulos Chalhoub, Andrew H. Paterson(University of Georgia)
Nature Communications
May 23, 2014
10.1038/ncomms4930
Cited by 1,230Open Access
Full Text

Abstract

Polyploidization has provided much genetic variation for plant adaptive evolution, but the mechanisms by which the molecular evolution of polyploid genomes establishes genetic architecture underlying species differentiation are unclear. Brassica is an ideal model to increase knowledge of polyploid evolution. Here we describe a draft genome sequence of Brassica oleracea, comparing it with that of its sister species B. rapa to reveal numerous chromosome rearrangements and asymmetrical gene loss in duplicated genomic blocks, asymmetrical amplification of transposable elements, differential gene co-retention for specific pathways and variation in gene expression, including alternative splicing, among a large number of paralogous and orthologous genes. Genes related to the production of anticancer phytochemicals and morphological variations illustrate consequences of genome duplication and gene divergence, imparting biochemical and morphological variation to B. oleracea. This study provides insights into Brassica genome evolution and will underpin research into the many important crops in this genus. Brassica oleracea is plant species comprising economically important vegetable crops. Here, the authors report the draft genome sequence of B. oleracea and, through a comparative analysis with the closely related B. rapa, reveal insights into Brassicaevolution and divergence of interspecific genomes and intraspecific subgenomes.

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