Whole‐genome sequence data of Hypericum perforatum and functional characterization of melatonin biosynthesis by N‐acetylserotonin O‐methyltransferase

金丝桃苷 贯叶连翘 生物 褪黑素 突变体 拟南芥 次生代谢物 遗传学 基因组 基因 药理学 神经科学
作者
Wen Zhou,Ying Wang,Bin Li,Linda Petijová,Suying Hu,Qian Zhang,Junfeng Niu,Donghao Wang,Shiqiang Wang,Yang Dong,Eva Čellárová,Zhezhi Wang
出处
期刊:Journal of Pineal Research [Wiley]
卷期号:70 (2) 被引量:40
标识
DOI:10.1111/jpi.12709
摘要

Hypericum perforatum is among the most commonly used herbal remedies and supplements. The aerial plant parts are often used to treat depression. Due to the lack of genomic information of H. perforatum, the gene networks regulating secondary metabolite synthesis remain unclear. Here, we present a high-quality genome for H. perforatum with a 2.3-Mb scaffold N50. The draft assembly covers 91.9% of the predicted genome and represents the fourth sequenced genus in the order Malpighiales. Comparing this sequence with model or related species revealed that Populus trichocarpa and Hevea brasiliensis could be grouped into one branch, while H. perforatum and Linum usitatissimum are grouped in another branch. Combined with transcriptome data, 40 key genes related to melatonin, hyperforin, and hypericin synthesis were screened and analyzed. Five N-acetylserotonin O-methyltransferases (HpASMT1-HpASMT5) were cloned and functionally characterized. Purified HpASMT3 protein converted N-acetylserotonin into melatonin with a Vmax of about 1.35 pkat/mg protein. HpASMT1 and HpASMT3 overexpression in Arabidopsis mutants caused 1.5-2-fold higher melatonin content than in mutant and wild-type plants. The endogenous reactive oxygen species (ROS) in transgenic plants was significantly lower than ROS in mutant and wild-type plants, suggesting higher drought tolerance. The obtained genomic data offer new resources for further study on the evolution of Hypericaceae family, but also provide a basis for further study of melatonin biosynthetic pathways in other plants.

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