Functional innovations of three chronological mesohexaploid Brassica rapa genomes
详细信息 查看全文
- 作者:Jungeun Kim ; Jeongyeo Lee ; Jae-Pil Choi ; Inkyu Park ; Kyungbong Yang…
- 关键词:Brassica rapa ; Chronological genomes ; Fast ; evolving genes ; Single ; retention genes ; Multi ; retention genes
- 刊名:BMC Genomics
- 出版年:2014
- 出版时间:December 2014
- 年:2014
- 卷:15
- 期:1
- 全文大小:1,813 KB
- 参考文献:1. Nagaharu, U (1935) Genome analysis in Brassica with special reference to the experimental formation of B. napus and peculiar mode of fertilization. Japan J Bot 7: pp. 389-452
2. Priya, P, Jagannath, A, Bisht, NC, Padmaja, KL, Sharma, S, Gupta, V, Pradhan, AK, Pental, D (2008) Comparative mapping of Brassica juncea and Arabidopsis thaliana using Intron Polymorphism (IP) markers: homoeologous relationships, diversification and evolution of the A, B and C Brassica genomes. BMC Genomics 9: pp. 113 CrossRef
3. Lagercrantz, U (1998) Comparative mapping between Arabidopsis thaliana and Brassica nigra indicates that Brassica genomes have evolved through extensive genome replication accompanied by chromosome fusions and frequent rearrangements. Genetics 150: pp. 1217-1228
4. Parkin, IA, Gulden, SM, Sharpe, AG, Lukens, L, Trick, M, Osborn, TC, Lydiate, DJ (2005) Segmental structure of the Brassica napus genome based on comparative analysis with Arabidopsis thaliana. Genetics 171: pp. 765-781 CrossRef
5. Wang, X, Wang, H, Wang, J, Sun, R, Wu, J, Liu, S, Bai, Y, Mun, JH, Bancroft, I, Cheng, F, Huang, S, Li, X, Hua, W, Wang, J, Wang, X, Freeling, M, Pires, JC, Paterson, AH, Chalhoub, B, Wang, B, Hayward, A, Sharpe, AG, Park, BS, Weisshaar, B, Liu, B, Li, B, Liu, B, Tong, C, Song, C, Duran, C (2011) The genome of the mesopolyploid crop species Brassica rapa. Nat Genet 43: pp. 1035-1039 CrossRef
6. Yu, J, Zhao, M, Wang, X, Tong, C, Huang, S, Tehrim, S, Liu, Y, Hua, W, Liu, S (2013) Bolbase: a comprehensive genomics database for Brassica oleracea. BMC Genomics 14: pp. 664 CrossRef
7. Levin, DA (1983) Polyploidy and novelty in flowering plants. Am/ Nat 122: pp. 1-25 CrossRef
8. Stephens, SG (1951) Possible significance of duplications in evolution. Adv Genet 4: pp. 247-265 CrossRef
9. Jackson, S, Chen, ZJ (2010) Genomic and expression plasticity of polyploidy. Curr Opin Plant Biol 13: pp. 153-159 CrossRef
10. Inititiative, TG (2000) Analysis of the genome sequence of the flowering plant Arabidopsis thaliana. Nature 408: pp. 796-815 CrossRef
11. Tang, H, Bowers, JE, Wang, X, Ming, R, Alam, M, Paterson, AH (2008) Synteny and collinearity in plant genomes. Science 320: pp. 486-488 CrossRef
12. Franzke, A, Lysak, MA, Al-Shehbaz, IA, Koch, MA, Mummenhoff, K (2011) Cabbage family affairs: the evolutionary history of Brassicaceae. Trends Plant Sci 16: pp. 108-116 CrossRef
13. Yang, YW, Lai, KN, Tai, PY, Li, WH (1999) Rates of nucleotide substitution in angiosperm mitochondrial DNA sequences and dates of divergence between Brassica and other angiosperm lineages. J Mol Evol 48: pp. 597-604 CrossRef
14. Town, CD, Cheung, F, Maiti, R, Crabtree, J, Haas, BJ, Wortman, JR, Hine, EE, Althoff, R, Arbogast, TS, Tallon, LJ, Vigouroux, M, Trick, M, Bancroft, I (2006) Comparative genomics of Brassica oleracea and Arabidopsis thaliana reveal gene loss, fragmentation, and dispersal after polyploidy. Plant Cell 18: pp. 1348-1359 CrossRef
15. Lysak, MA, Berr, A, Pecinka, A, Schmidt, R, McBreen, K, Schubert, I (2006) Mechanisms of chromosome number reduction in Arabidopsis thaliana and related Brassicaceae species. Proc Natl Acad Sci U S A 103: pp. 5224-5229 CrossRef
16. Schranz, ME, Lysak, MA, Mitchell-Olds, T (2006) The ABC's of comparative genomics in the Brassicaceae: building blocks of crucifer genomes. Trends Plant Sci 11: pp. 535-542
文摘
Background The Brassicaceae family is an exemplary model for studying plant polyploidy. The Brassicaceae knowledge-base includes the well-annotated Arabidopsis thaliana reference sequence; well-established evidence for three rounds of whole genome duplication (WGD); and the conservation of genomic structure, with 24 conserved genomic blocks (GBs). The recently released Brassica rapa draft genome provides an ideal opportunity to update our knowledge of the conserved genomic structures in Brassica, and to study evolutionary innovations of the mesohexaploid plant, B. rapa. Results Three chronological B. rapa genomes (recent, young, and old) were reconstructed with sequence divergences, revealing a trace of recursive WGD events. A total of 636 fast evolving genes were unevenly distributed throughout the recent and young genomes. The representative Gene Ontology (GO) terms for these genes were ‘stress response-and ‘development-both through a change in protein modification or signaling, rather than by enhancing signal recognition. In retention patterns analysis, 98% of B. rapa genes were retained as collinear gene pairs; 77% of those were singly-retained in recent or young genomes resulting from death of the ancestral copies, while others were multi-retained as long retention genes. GO enrichments indicated that single retention genes mainly function in the interpretation of genetic information, whereas, multi-retention genes were biased toward signal response, especially regarding development and defense. In the recent genome, 13,302, 5,790, and 20 gene pairs were multi-retained following Brassica whole genome triplication (WGT) events with 2, 3, and 4 homoeologous copies, respectively. Enriched GO-slim terms from B. rapa homomoelogues imply that a major effect of the B. rapa WGT may have been to acquire environmental adaptability or to change the course of development. These homoeologues seem to more frequently undergo subfunctionalization with spatial expression patterns compared with other possible events including nonfunctionalization and neofunctionalization. Conclusion We refined Brassicaceae GB information using the latest genomic resources, and distinguished three chronologically ordered B. rapa genomes. B. rapa genes were categorized into fast evolving, single- and multi-retention genes, and long retention genes by their substitution rates and retention patterns. Representative functions of the categorized genes were elucidated, providing better understanding of B. rapa evolution and the Brassica genus.