| Literature DB >> 27892922 |
Yuan Zhou1,2,3, Yongshuo Ma1, Jianguo Zeng3, Lixin Duan4, Xiaofeng Xue5, Huaisong Wang1, Tao Lin1,2, Zhiqiang Liu6, Kewu Zeng7, Yang Zhong1, Shu Zhang1, Qun Hu8, Min Liu1, Huimin Zhang1, James Reed9, Tessa Moses9, Xinyan Liu1, Peng Huang3, Zhixing Qing10, Xiubin Liu3, Pengfei Tu7, Hanhui Kuang8, Zhonghua Zhang1, Anne Osbourn9, Dae-Kyun Ro11, Yi Shang1,2, Sanwen Huang1,2.
Abstract
Differentiation of secondary metabolite profiles in closely related plant species provides clues for unravelling biosynthetic pathways and regulatory circuits, an area that is still underinvestigated. Cucurbitacins, a group of bitter and highly oxygenated tetracyclic triterpenes, are mainly produced by the plant family Cucurbitaceae. These compounds have similar structures, but differ in their antitumour activities and ecophysiological roles. By comparative analyses of the genomes of cucumber, melon and watermelon, we uncovered conserved syntenic loci encoding metabolic genes for distinct cucurbitacins. Characterization of the cytochrome P450s (CYPs) identified from these loci enabled us to unveil a novel multi-oxidation CYP for the tailoring of the cucurbitacin core skeleton as well as two other CYPs responsible for the key structural variations among cucurbitacins C, B and E. We also discovered a syntenic gene cluster of transcription factors that regulates the tissue-specific biosynthesis of cucurbitacins and may confer the loss of bitterness phenotypes associated with convergent domestication of wild cucurbits. This study illustrates the potential to exploit comparative genomics to identify enzymes and transcription factors that control the biosynthesis of structurally related yet unique natural products.Entities:
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Year: 2016 PMID: 27892922 PMCID: PMC5449191 DOI: 10.1038/nplants.2016.183
Source DB: PubMed Journal: Nat Plants ISSN: 2055-0278 Impact factor: 15.793