Abstract
Ginsenosides, the most active components in Panax ginseng, exhibit pharmacological and therapeutic properties but are limited by their low abundance. Jasmonates (JAs), a class of stress-induced phytohormones, are integral in modulating plant defense responses and the biosynthesis of secondary metabolites, including ginsenosides. Jasmonoyl-isoleucine (JA-Ile), the primary bioactive JA compound, is biosynthesized by JA-Ile synthase 1 (JAR1). In this study, we cloned the 1555 bp PgJAR1 gene from ginseng roots and analyzed its structure, enzyme activity, and expression pattern. The PgJAR1 protein encompasses all the hallmark elements characteristic of the GH3 family. It exhibits N/C-terminal domains analogous to ANL, three ATP/AMP-binding motifs, and distinct secondary structures: an N-terminal beta-barrel with beta-sheets and alpha-helices, and a C-terminal beta-sheet surrounded by alpha-helices, similarly to AtGH3.11/AtJAR1. The recombinant PgJAR1 enzyme expressed in Escherichia coli BL21 specifically catalyzed jasmonic acid (JA) to JA-Ile. PgJAR1 is predominantly expressed in leaves and is upregulated by MeJA treatment. Moderate transient overexpression of PgJAR1 promoted the biosynthesis of both JA-Ile and ginsenosides, highlighting the crucial role of PgJAR1 in JA-Ile biosynthesis and its positive impact on ginsenoside accumulation. Nevertheless, elevated JA-Ile levels can impede cellular growth, reducing ginsenoside production. Consequently, balancing JA-Ile biosynthesis through PgJAR1 expression is essential for optimizing ginseng cultivation and enhancing its medicinal properties. Modulating endogenous JA-Ile levels offers a strategy for increasing ginsenoside production in ginseng plants.