Glycyrrhiza, a commonly used medicinal herb: Review of species classification, pharmacology, active ingredient biosynthesis, and synthetic biology

Background: Licorice is extensively and globally utilized as a medicinal herb and is one of the traditional Chinese herbal medicines with valuable pharmacological effects. Its therapeutic components primarily reside within its roots and rhizomes, classifying it as a tonifying herb. As more active ingredients in licorice are unearthed and characterized, licorice germplasm resources are gaining more and more recognition. However, due to the excessive exploitation of wild licorice resources, the degrading germplasm reserves fail to meet the requirements of chemical extraction and clinical application.

Aim of review: This article presents a comprehensive review of the classification and phylogenetic relationships of species in genus Glycyrrhiza, types of active components and their pharmacological activities, licorice omics, biosynthetic pathways of active compounds in licorice, and metabolic engineering. It aims to offer a unique and comprehensive perspective on Glycyrrhiza, integrating knowledge from diverse fields to offer a comprehensive understanding of this genus. It will serve as a valuable resource and provide a solid foundation for future research and development in the molecular breeding and synthetic biology fields of Glycyrrhiza.

Key scientific concepts of review: Licorice has an abundance of active constituents, primarily triterpenoids, flavonoids, and polysaccharides. Modern pharmacological research unveiled its multifaceted effects encompassing anti-inflammatory, analgesic, anticancer, antiviral, antioxidant, and hepatoprotective activities. Many resources of Glycyrrhiza species remain largely untapped, and multiomic studies of the Glycyrrhiza lineage are expected to facilitate new discoveries in the fields of medicine and human health. Therefore, strategies for breeding high-yield licorice plants and developing effective biosynthesis methods for bioactive compounds will provide valuable insights into resource conservation and drug development. Metabolic engineering and microorganism-based green production provide alternative strategies to improve the production efficiency of natural products.