Efficient Biosynthesis of Furanocoumarin Intermediate Marmesin by Engineered Escherichia coli

Marmesin, a plant dihydrofuranocoumarin, is an important intermediate in the synthesis of linear furanocoumarins and exhibits a variety of pharmacological activities. However, due to the lack of efficient prenyltransferases, the incompatibility of redox partners for P450 enzymes, and the insufficient supply of precursor (DMAPP), the microbial synthesis of marmesin remained at an extremely low level. Here, we report the efficient biosynthesis of marmesin in Escherichia coli by screening the robust 6-prenyltransferase PpPT1 and marmesin synthase PpDCΔ2–29 from Peucedanum praeruptorum. Next, the activities of PpPT1 and PpDCΔ2–29 were enhanced using fusion protein tags and redox partner engineering, respectively. In addition, the synthesis of marmesin was further improved by strengthening the methylerythritol phosphate (MEP) pathway to increase the availability of DMAPP and by optimizing the modular pathway in the engineered strain. Finally, the titer of marmesin reached 203.69 mg L–1 in the fed-batch fermentation with a molar conversion rate of umbelliferone of 81.4%, which is the highest titer for marmesin production using engineered microorganisms. The applied strategy and marmesin-producing strain constructed in this study lay the foundation for the green production of valuable complex furanocoumarins.