首页|期刊导航|中国中药杂志|高效合成小白菊内酯衍生物kauniolide酿酒酵母细胞工厂构建

高效合成小白菊内酯衍生物kauniolide酿酒酵母细胞工厂构建OA

Construction of efficient yeast cell factory for kauniolide,a parthenolide derivative

中文摘要英文摘要

小白菊内酯衍生物 kauniolide 是阿格拉宾、山莴苣素、山莴苣苦素等多种愈创木烷型倍半萜类化合物合成的重要中间体.然而通过化学合成存在反应条件苛刻、化学试剂用量较多等问题,严重制约了其进一步开发与利用.该研究通过系统代谢工程改造策略,构建高效合成小白菊内酯衍生物 kauniolide 酿酒酵母细胞工厂.在实验室保有的高产法尼基焦磷酸(FPP)酿酒酵母底盘菌中异源表达 kauniolide 前体木香烃内酯生物合成途径基因(HaGAS、TpGAO、TpCOS、AaCPR),可初步检测到木香烃内酯,滴度为 6.1 mg·L-1.引入 AaADH1、AaALDH1 和引入 AaCYB5 后,提升吉玛烯 A 酸的合成效率并促进电子传递,增强 CYP450 酶的催化效率,木香烃内酯滴度为 71.5 mg·L-1.进一步筛选不同启动子 PGAL1、PTDH3、PTEF1、PTPI1、PsptGAL2 和PskGAL2 调控 TpKLS 基因的表达强度,采用 skGAL2 启动子驱动 TpKLS 基因的菌株表达效果最优,kauniolide 滴度达到 28.2 mg·L-1.最后通过半理性设计并结合计算机辅助技术改造 TpKLS 的催化效能,获得最优突变体 TpKLSV204R,其催化活性为野生型的2.7 倍.最终通过摇瓶发酵实现前体木香烃内酯滴度为35.0 mg·L-1,目标产物kauniolide 滴度提升至71.1 mg·L-1,为目前酿酒酵母体系中的最高报道水平.该研究为该化合物的规模化生物合成及为下游合成途径挖掘提供技术支撑与参考.

Kauniolide,a parthenolide derivative,serves as a key biosynthetic intermediate for various guaianolide-type sesquiterpenoids,such as agrabin,lactucin,and lactupicrin.However,its chemical synthesis is often hampered by demanding reaction conditions and high reagent consumption,which severely limit further development and application.To address this,this study employed systematic metabolic engineering strategies to construct an efficient yeast cell factory for kauniolide production.First,the biosynthetic pathway genes for costunolide—the direct precursor of kauniolide(HaGAS,TpGAO,TpCOS,AaCPR)—were heterologously expressed in a lab-engineered yeast chassis strain with high farnesyl pyrophosphate(FPP)production.This initial strain produced costunolide at a titer of 6.1 mg·L-1.Subsequently,the co-expression of AaADH1,AaALDH1,and AaCYB5 was implemented to enhance the germacrene A acid synthesis and promote electron transfer,thereby boosting the catalytic efficiency of the key cytochrome P450 enzymes.This modification increased the costunolide titer to 71.5 mg·L-1.To optimize the conversion of costunolide to kauniolide,a promoter compatibility screen for the TpKLS gene was conducted.Among the tested promoters(PGAL1,PTDH3,PTEF1,PTPI1,PsptGAL2,and PskGAL2),the strain harboring the PskGAL2-driven TpKLS construct showed the highest performance,achieving a kauniolide titer of 28.2 mg·L-1.Furthermore,to further enhance the pathway flux,the catalytic efficiency of the TpKLS enzyme was improved through semi-rational design coupled with computer-aided design.The best-performing mutant,TpKLSV204R,exhibited a 2.7-fold higher catalytic activity compared to the wild-type enzyme.The final engineered strain,when cultivated in shake-flask fermentation,produced costunolide and kauniolide at titers of 35.0 and 71.1 mg·L-1,respectively.The kauniolide titer represents the highest level reported to date in a yeast system.In conclusion,this study successfully constructed an efficient yeast cell factory for kauniolide by reconstructing and optimizing its heterologous biosynthetic pathway.It provides a solid technical foundation and a valuable reference for the scalable biosynthesis of kauniolide and the exploration of its downstream derivatives.

韩洋;谭洪虎;苏平;黄璐琦

中国中医科学院 中药资源中心 道地药材品质保障与资源持续利用全国重点实验室,北京 100700中国中医科学院 中药资源中心 道地药材品质保障与资源持续利用全国重点实验室,北京 100700中国中医科学院 中药资源中心 道地药材品质保障与资源持续利用全国重点实验室,北京 100700中国中医科学院 中药资源中心 道地药材品质保障与资源持续利用全国重点实验室,北京 100700

kauniolide倍半萜内酯TpKLS功能改造代谢工程

kauniolidesesquiterpene lactoneTpKLSfunctional modificationmetabolic engineering

《中国中药杂志》 2026 (7)

1882-1890,9

中央本级重大增减支项目(2060302)中国中医科学院科技创新工程项目(CI2023E002,CI2024C004YN)

10.19540/j.cnki.cjcmm.20260106.401

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