Metabolic engineering of anthocyanin pathway inArtemisia annuacells does not exclude the expression of artemisinin pathway

Abstract

AbstractArtemisia annuais the only medicinal crop to produce artemisinin for the treatment of malignant malaria. Unfortunately, hundreds of thousands of people still lose their life every year due to the lack of sufficient artemisinin. Artemisinin is considered to result from the spontaneous autoxidation of dihydroartemisinic acid in the presence of reactive oxygen species (ROS) in an oxidative condition of glandular trichomes (GTs),; however, whether increasing antioxidative compounds can inhibit artemisinin biosynthesis in plant cells is unknown. Anthocyanins are potent antioxidants that can remove ROS in plant cells. To date, no anthocyanins have been structurally elucidated fromA. annua. In this study, our goals were to engineer anthocyanins inA. annuacells and to understand the artemisinin biosynthesis in anthocyanin-producing cells. ArabidopsisPAP1(AtPAP1) was used to engineer four types of transgenic anthocyanin-producingA. annua(TAPA1 to 4) cells. Three wild type cell types were developed as controls. TAPA1 cells produced the highest contents of total anthocyanins. LC-MS analysis detected 17 anthocyanin or anthocyanidin compounds. Crystallization, LC/MS/MS and NMR analyses identified cyanidin, pelargonidin, one cyanin, and one pelargonin. An integrative analysis characterized that four types of TAPA cells expressed the artemisinin pathway and TAPA1 cells produced the highest artemisinin and artemisinic acid. The contents of arteannuin B were similar in seven cell types. These data showed that the engineering of anthocyanins does not eliminate the biosynthesis of artemisinin in cells. These data allow us to propose a new hypothesis that enzymes catalyze the formation of artemisinin from DHAA in non-GT cells. These findings show a new platform to increase artemisinin production via non-GT cells ofA. annua.