金丝桃柚皮素中金丝桃苷的平行生物合成途径。

IF 7.6 Q1 GENETICS & HEREDITY 园艺研究(英文) Pub Date : 2023-08-17 eCollection Date: 2023-09-01 DOI:10.1093/hr/uhad166
Yingying Wang, Zhirong Cui, Qianqian Li, Shuai Zhang, Yongyi Li, Xueyan Li, Lingyi Kong, Jun Luo
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引用次数: 0

摘要

金丝桃苷在药用和食用植物中都是一种具有生物活性的黄酮类半乳糖苷。它在花蕾的生长中起着重要的生理作用。然而,金丝桃苷的生物合成途径尚未在植物中得到系统的阐明,包括其原始来源金丝桃科。我们小组在金丝桃的花蕾中发现了丰富的金丝桃苷,并对其转录组进行了测序,以研究金丝桃苷的生物合成机制。经过基因筛选和功能验证,鉴定出四种关键酶。具体而言,HmF3Hs(黄烷酮3-羟化酶)和HmFLSs(黄酮醇合成酶)可以催化黄烷酮转化为二氢黄酮醇,也可以催化二氢黄酮酚转化为黄酮醇。HmFLS还可以以不同的效率将黄烷酮转化为黄酮醇和黄酮。HmF3'H(类黄酮3'-羟化酶)广泛作用于4'-羟基类黄酮,产生3',4'-二羟基黄烷酮、二氢黄酮醇、黄酮醇和黄酮类化合物。HmGAT(类黄酮3-O-半乳糖基转移酶)将黄酮醇转化为相应的3-O-半乳糖苷,包括金丝桃苷。由此描述了平行的金丝桃苷生物合成路线,其中一条通过喂食柚皮素在大肠杆菌BL21(DE3)中成功重建,导致金丝桃苷产量为25mg/l。总之,这项研究不仅有助于我们了解金丝桃苷在花发育和生物活性方面的内在催化机制,而且为这些酶家族提供了有价值的见解。
本文章由计算机程序翻译,如有差异,请以英文原文为准。

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The parallel biosynthesis routes of hyperoside from naringenin in Hypericum monogynum.

Hyperoside is a bioactive flavonoid galactoside in both medicinal and edible plants. It plays an important physiological role in the growth of flower buds. However, the hyperoside biosynthesis pathway has not been systematically elucidated in plants, including its original source, Hypericaceae. Our group found abundant hyperoside in the flower buds of Hypericum monogynum, and we sequenced its transcriptome to study the biosynthetic mechanism of hyperoside. After gene screening and functional verification, four kinds of key enzymes were identified. Specifically, HmF3Hs (flavanone 3-hydroxylases) and HmFLSs (flavonol synthases) could catalyze flavanones into dihydroflavonols, as well as catalyzing dihydroflavonols into flavonols. HmFLSs could also convert flavanones into flavonols and flavones with varying efficiencies. HmF3'H (flavonoid 3'-hydroxylase) was found to act broadly on 4'-hydroxyl flavonoids to produce 3',4'-diydroxylated flavanones, dihydroflavonols, flavonols, and flavones. HmGAT (flavonoid 3-O-galactosyltransferase) would transform flavonols into the corresponding 3-O-galactosides, including hyperoside. The parallel hyperoside biosynthesis routes were thus depicted, one of which was successfully reconstructed in Escherichia coli BL21(DE3) by feeding naringenin, resulting in a hyperoside yield of 25 mg/l. Overall, this research not only helped us understand the interior catalytic mechanism of hyperoside in H. monogynum concerning flower development and bioactivity, but also provided valuable insights into these enzyme families.

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