Genome sequence of cultivated Upland cotton (Gossypium hirsutum TM-1) provides insights into genome evolution

Authors: LI, FUGUANG - Cotton Research Institute - China; FAN, GUANGYI - Beijing Genome Institute; LU, CUIRUI - Cotton Research Institute - China; XIAO, GUANGHUI - Peking University; ZOU, CHANGSONG - Cotton Research Institute - China; Kohel, Russell; MA, ZHIYING - Agricultural University Of Hebei; SHANG, HAIHONG - Cotton Research Institute - China; MA, XIONGFENG - Cotton Research Institute - China; WU, JIANYONG - Cotton Research Institute - China; LIANG, XINMING - Bgi Shenzhen; HUANG, GAI - Peking University; Percy, Richard; LIU, KUN - Cotton Research Institute - China; YANG, WEIHUA - Cotton Research Institute - China; CHEN, WENBIN - Bgi Shenzhen; DU, XIONGMING - Cotton Research Institute - China; SHI, CHENGCHENG - Bgi Shenzhen; YUAN, YOULU - Cotton Research Institute - China; YE, WUWEI - Cotton Research Institute - China; LIU, XIN - Bgi Shenzhen; ZHANG, XUEYAN - Cotton Research Institute - China; LIU, WEIQING - Bgi Shenzhen; WEI, HENGLING - Cotton Research Institute - China; WEI, SHOUJUN - Cotton Research Institute - China; HUANG, GUODONG - Bgi Shenzhen; ZHANG, XIANLONG - Huazhong Agricultural University; ZHU, SHUIJIN - Zhejiang University; ZHANG, HE - Bgi Shenzhen; SUN, FENGMING - Bgi Shenzhen; WANG, XINGFEN - Agricultural University Of Hebei; LIANG, JIE - Bgi Shenzhen; WANG, JIAHAO - Bgi Shenzhen; HE, QIANG - Bgi Shenzhen; HUANG, LEIHUAN - Bgi Shenzhen; WANG, JUN - Bgi Shenzhen; CUI, JINJIE - Cotton Research Institute - China; SONG, GUOLI - Cotton Research Institute - China; WANG, KUNBO - Cotton Research Institute - China; XU, XUN - Beijing Genome Institute; Yu, John; ZHU, YUXIAN - Wuhan University; YU, SHUXUN - Cotton Research Institute - China

Submitted to: Nature Biotechnology
Publication Type: Peer Reviewed Journal
Publication Acceptance Date: 3/15/2015
Publication Date: 5/1/2015
Citation: Li, F., Fan, G., Lu, C., Xiao, G., Zou, C., Kohel, R.J., Ma, Z., Shang, H., Ma, X., Wu, J., Liang, X., Huang, G., Percy, R.G., Liu, K., Yang, W., Chen, W., Du, X., Shi, C., Yuan, Y., Ye, W., Liu, X., Zhang, X., Liu, W., Wei, H., Wei, S., Huang, G., Zhang, X., Zhu, S., Zhang, H., Sun, F., Wang, X., Liang, J., Wang, J., He, Q., Huang, L., Wang, J., Cui, J., Song, G., Wang, K., Xu, X., Yu, J., Zhu, Y., Yu, S. 2015. Genome sequence of cultivated Upland cotton (Gossypium hirsutum TM-1) provides insights into genome evolution. Nature Biotechnology. 33:524-530.

Interpretive Summary: Complete DNA sequencing of commercial Upland cotton (Gossypium hirsutum) is difficult due to its relatively large and complex genome. Much of the complexity of cotton's genetic makeup is due to its being the product of hybridization between two ancestral species. In this study we sequenced, assembled, and analyzed the world's most important cultivated Upland cotton genome. The success of this accomplishment required that we first successfully sequence the parental species of Upland cotton as a preliminary effort. Among many benefits, DNA sequence information will support gene discovery for important agronomic and quality traits and will facilitate high-resolution association studies that will result in development of molecular markers for expedited breeding and selection of traits of interest. The sequencing of the Upland cotton genome will also lay the foundation for understanding of the evolutionary and functional significance of multi-genome plants.

Technical Abstract: Genetic and genomic analyses of Upland cotton (Gossypium hirsutum) are difficult because it has a complex allotetraploid (AADD; 2n = 4x = 52) genome. Here we sequenced, assembled and analyzed the world's most important cultivated cotton genome with 246.2 gigabase (Gb) clean data obtained using whole-genome shotgun sequencing technology and an additional set of 100,187 bacterial artificial chromosomes (BACs) representing about five-fold genome coverage. A total of 89.2% of the 2,173 Mb scaffolds were anchored and oriented to 26 pseudochromosomes with assistance from a high-resolution genetic map that comprises 39,662 single-nucleotide polymorphism (SNP) markers. The Upland cotton is suggested to have originated from paleo-hexaploidy of an eudicot with successive polyploidization and finally the fusion of an A and D genome ancestral species 1-2 million years ago (MYA). The allotetraploid genome contained 76,943 protein-coding genes that displayed high degrees of conserved gene order with the two reported ancestral diploid cotton genomes. Transposable elements (TEs) accounted for 67.2% of the allotetraploid genome and Dt-originated (in which 't' indicates tetraploid) TEs seemed more active than that of the At after the allopolyploidiztion. Gene loss studies through quartet alignment indicated that genome downsizing occurred in the allotetraploid cotton shortly after the allopolyploidy and the Dt subgenome evolved faster than At. The Upland cotton genome is found to couple with the evolvement of different regulatory mechanisms regarding two important gene families, Cellulose Synthase (CesA) and 1-aminocyclopropane-1-carboxylic acid oxidase1 and 3 (ACO1,3), that are essential for the production of long and spinnable fiber cells used by the modern textile industry.