A sugar chain–dependent two-component chemical defense in Hedera helix reveals substrate-driven β-glucosidase evolution in Apiales

Plants have evolved diverse chemical strategies to defend against herbivores and pathogens, yet the mechanisms underlying their origin and diversification remain unclear. Here, we identify a sugar chain–dependent triterpenoid saponin defense system in Hedera helix that exemplifies adaptive innovation in plant chemical defenses. Three glycosyltransferases sequentially assemble a glucose–glucose–rhamnose chain at the C-28 position of α-hederin to form the detoxified precursor hederacoside C. Upon tissue disruption, the β-glucosidase HhGH1 hydrolyzes the entire sugar chain, regenerating α-hederin, a potent hemolytic saponin. Reconstitution of this system in Nicotiana benthamiana conferred strong herbivore resistance, demonstrating its ecological functionality and portability. Intriguingly, comparative genomics and biochemical analysis revealed that β-glucosidases across Apiales diversified in response to triterpenoid glycosylation, illustrating how substrate-driven enzyme evolution and metabolic innovation together generate new adaptive defense strategies in plants.