Signal transduction of atractylodin biosynthesis in Atractylodes lancea cell induced by endophytic fungal elicitor mediated with nitric oxide followed by salicylic acid / 中草药

ABSTRACT

Objective: To investigate the signal molecules and signal transduction involved in endophytic fungal elicitor-induced atractylodin biosynthesis and the effect of an endophytic fungal elicitor on the key enzyme activity in Atractylodes lancea. Methods: Content changes of nitric oxide (NO), salicylic acid (SA), and atractylodin were detected under the endophytic fungal elicitor treatment by plant cell suspension culture technology. Results: The endophytic fungal elicitor remarkably promoted NO burst and the biosynthesis of SA and atractyodin by activating nitric oxide synthase (NOS), phenylalanine ammonia lyase (PAL), and acetyl coenzyme A carboxylase (ACC), respectively. NOS inhibitor PBITU could inhibit the NO and SA accumulation and the atractyodin biosynthesis induced by the elicitor. And atractyodin biosynthesis could also be triggered by exogenous NO or SA. The results indicated that NO and SA were the necessary signal molecules and NO burst was mediated by NOS induced by endophytic fungal elicitor. NO quencher cPITO could effectively remove NO burst in A. lancea cell induced by endophytic fungal elicitor and notably inhibit the biosynthesis promotion of SA and atractyodin in A. lancea cell induced by endophytic fungal elicitor. Exogenous SNP could reverse the cPITO inhibition on the activity of PAL and ACC and the synthesis of SA and atractylodin. This suggested that NO was an upstream signal molecule mediated endophytic fungal elicitor to accelerate the biosynthesis of SA and atractyodin. Conclusion: Endophytic fungal elicitor mediated through NO followed by SA could promote atractyodin biosynthesis by activating ACC in A. lancea.