Total saikosaponin yield in Bupleurum chinense DC. roots depends on the root biomass production and the saikosaponin content in roots, which are both affected by abiotic factors. Bupleurum chinense is relatively shade tolerant. To test how total saikosaponin yield responds to light conditions, different light intensities (500, 200, and 50 mu mol m(-2)s(-1)) were established in artificial climate incubators. Responses of plant morphological and physiological characteristics and of saikosaponin synthesis to different light intensities were measured to find suitable light conditions for improving total saikosaponin yield. Among these light conditions, moderately low light intensity (MLI, 200 mu mol m(-2)s(-1)) produced plants with the highest leaf area, chlorophyll content, effective quantum yield of PSII (Phi(PSU)), photochemical quenching coefficient (q(p)), electron transport rate (ETR), maximum carboxylation efficiency (V-cmax), maximum electron transport rate (J(max)), and triose phosphate utilization rate (V-TPU), which suggests a well-functioning photosynthetic apparatus capable of fully utilizing the limited light energy. Moreover, the plants had the highest root-shoot ratio, saikosaponin content, and total saikosaponin yield, which indicates that they allocated more resources to storage and defensive adaptations. Under extremely low light intensity (ELI, 50 mu mol m(-2) s(-1)), more energy was partitioned to photoprotection, and strong oxidation resistance developed, but saikosaponin accumulation and root biomass were lowest due to greatly reduced carbon assimilation. The MU improved both the quantity and the quality of herbal extracts from B. chinense: the total saikosaponin yield was 1.3 times the corresponding value of the control (500 mu mol m(-2)s(-1)), and lower illumination levels were counterproductive. Our results suggest that B. chinense would be suitable for introducing to an agroforestry system.

• 出版日期2018-10-15
• 单位北京师范大学