The Lamiaceae family is renowned for its terpenoid-based medicinal components,but Leonurus,which has traditional medicinal uses,stands out for its alkaloid-rich composition.Leonurine,the principal active compound foun...The Lamiaceae family is renowned for its terpenoid-based medicinal components,but Leonurus,which has traditional medicinal uses,stands out for its alkaloid-rich composition.Leonurine,the principal active compound found in Leonurus,has demonstrated promising effects in reducing blood lipids and treating strokes.However,the biosynthetic pathway of leonurine remains largely unexplored.Here,we present the chromosome-level genome sequence assemblies of Leonurus japonicus,known for its high leonurine production,and Leonurus sibiricus,characterized by very limited leonurine production.By integrating genomics,RNA sequencing,metabolomics,and enzyme activity assay data,we constructed the leonurine biosynthesis pathway and identified the arginine decarboxylase(ADC),uridine diphosphate glucosyltransferase(UGT),and serine carboxypeptidase-like(SCPL)acyltransferase enzymes that catalyze key reactions in this pathway.Further analyses revealed that the UGT–SCPL gene cluster evolved by gene duplication in the ancestor of Leonurus and neofunctionalization of SCPL in L.japonicus,which contributed to the accumulation of leonurine specifically in L.japonicus.Collectively,our comprehensive study illuminates leonurine biosynthesis and its evolution in Leonurus.展开更多
基金supported by the National Natural Science Foundation of China(32170349 to P.X.)the Chenshan Special Fund for the Shanghai Landscaping Administration Bureau Program(G232402 to P.X.)the Ministry of Science and Technology of the People's Republic of China(YDZX20223100001003 to Y.-H.H.).
文摘The Lamiaceae family is renowned for its terpenoid-based medicinal components,but Leonurus,which has traditional medicinal uses,stands out for its alkaloid-rich composition.Leonurine,the principal active compound found in Leonurus,has demonstrated promising effects in reducing blood lipids and treating strokes.However,the biosynthetic pathway of leonurine remains largely unexplored.Here,we present the chromosome-level genome sequence assemblies of Leonurus japonicus,known for its high leonurine production,and Leonurus sibiricus,characterized by very limited leonurine production.By integrating genomics,RNA sequencing,metabolomics,and enzyme activity assay data,we constructed the leonurine biosynthesis pathway and identified the arginine decarboxylase(ADC),uridine diphosphate glucosyltransferase(UGT),and serine carboxypeptidase-like(SCPL)acyltransferase enzymes that catalyze key reactions in this pathway.Further analyses revealed that the UGT–SCPL gene cluster evolved by gene duplication in the ancestor of Leonurus and neofunctionalization of SCPL in L.japonicus,which contributed to the accumulation of leonurine specifically in L.japonicus.Collectively,our comprehensive study illuminates leonurine biosynthesis and its evolution in Leonurus.