Yang Tingxing, Chen Jitong, Shi Ningwei, Fan Baolian, Yi Runxiang, Liang Shun, Ji Aijia, Liu Zhongqiu, Li Chi, Wang Qing, Duan Lixin
Guangdong Engineering Research Center of Biosynthesis and Metabolism of Effective Components of Chinese Medicine, International Institute for Translational Chinese Medicine, School of Pharmaceutical Sciences, Guangzhou University of Chinese Medicine, Guangzhou 510006, P. R. China.
Xiamen Key Laboratory of Traditional Chinese Medicine Bio-engineering, Xiamen Medical College, Xiamen 361023, P. R. China.
J Agric Food Chem. 2024 Dec 18;72(50):27902-27911. doi: 10.1021/acs.jafc.4c06937. Epub 2024 Dec 8.
Benth, known as the "king of fruits", is rich in triterpenoid compounds, particularly ursane-type and oleanane-type triterpenic acids. These secondary metabolites have been widely applied in medicine, cosmetics, agriculture, and other fields. To date, key enzyme genes involved in triterpenoid metabolic pathways in remain unexplored. This study employed transcriptome sequencing analysis combined with synthetic biology approaches involving heterologous expression in yeast to identify crucial genes responsible for the biosynthesis of triterpenoid components in : Two 2,3-oxidosqualene cyclases (AeOSC2 and AeOSC3) were characterized to catalyze the formation of major triterpene scaffolds, α-amyrin [precursor of ursolic acid (UA)], β-amyrin [precursor of oleanolic acid (OA)], and ψ-taraxasterol, and two cytochrome P450s (AeCYP716A8 and AeCYP716A9) mediating three-step oxidation at the C-28 position of ursane-type and oleanane-type triterpene scaffolds to form UA, OA, and intermediate oxidation products. We successfully reconstructed the biosynthetic pathway of ursane- and oleanane-type triterpenoids from in a heterologous yeast host and elucidated the two-step enzymatic reactions involved in triterpenoid biosynthesis. These findings lay the foundation for further understanding the biosynthesis of key active components in .
山竹,被誉为“水果之王”,富含三萜类化合物,尤其是乌苏烷型和齐墩果烷型三萜酸。这些次生代谢产物已广泛应用于医药、化妆品、农业及其他领域。迄今为止,山竹中三萜代谢途径所涉及的关键酶基因仍未被探索。本研究采用转录组测序分析,并结合在酵母中进行异源表达的合成生物学方法,以鉴定负责山竹中三萜类成分生物合成的关键基因:鉴定出两种2,3-氧化角鲨烯环化酶(AeOSC2和AeOSC3)可催化主要三萜骨架α-香树脂醇[熊果酸(UA)的前体]、β-香树脂醇[齐墩果酸(OA)的前体]和ψ-蒲公英甾醇的形成,以及两种细胞色素P450(AeCYP716A8和AeCYP716A9)介导乌苏烷型和齐墩果烷型三萜骨架在C-28位的三步氧化反应,以形成UA、OA和中间氧化产物。我们成功地在异源酵母宿主中重建了山竹中乌苏烷型和齐墩果烷型三萜类化合物的生物合成途径,并阐明了三萜类生物合成中涉及的两步酶促反应。这些发现为进一步了解山竹中关键活性成分的生物合成奠定了基础。
