Seung-Mi Kang

EFFECTS OF METHYL JASMONATE AND SALICYLIC ACID ON THE PRODUCTION OF BILOBALIDE AND GINKGOLIDES IN CELL CULTURES OF GINKGO BILOBA

SummaryIn an attempt to increase productivity, the effects of the elicitors methyl jasmonate (MJ) and salicylic acid (SA) on the production of bilobalide (B), ginkgolide A (GA), and ginkgolide B (GB) were studied in cell suspension cultures of Ginkgo biloba. MJ treatments increased the amounts of B, GA, and GB, concomitant with a slight decrease in cell growth. After treatment of 0.01 mM MJ, levels of GA and GB increased 4.3-and 8.2-fold over controls by 12 h and declined after 24h. The 1.0mM MJ treatment produced a maximal release of B after 12h of exposure and increased the concentration of B in the culture medium up to 6.25-fold compared with the controls. Treatment with 1.0mM SA transiently enhanced GA and GB production up to 3.1-and 6.1-fold, respectively, compared with the control. However, treatment 1.0 mM SA did not have a significant effect on B production. When treated with 0.01 mM SA, the level of B in the cells was increased 5.4-fold over controls by 12h and declined after 24h. The concentrations and exposure times of both MJ and SA were factors that strongly affected the production of B, GA, and GB. The results from this study suggest that MJ and SA directly or indirectly increased the production of B, GA, and GB in cells, and stimulated the release of these metabolites into the culture medium.

Enhanced production of scopolamine by bacterial elicitors in adventitious hairy root cultures of Scopolia parviflora

In an attempt to increase productivity, the effect of elicitation on tropane alkaloids (TA) biosynthesis was studied in adventitious hairy root cultures of Scopolia parviflora. Two Gram-positive strains and one Gram-negative strain of bacteria were used as biotic elicitors. The raw bacterial elicitors affected the tropane alkaloid profile by increasing the scopolamine concentration, while the autoclaved bacterial elicitors produced similar effects on the control. The conversion ratio of hyoscyamine to scopolamine was increased following elicitation using raw bacterial elicitors. The bacterial elicitor inhibited the expression of H6H (hyoscyamine 6β-hydoxylase) whereas the expression of PMT (putrescine N-methyltransferase) was raised by elicitation. These results have important implications for the large-scale production of tropane alkaloids.

Effect of biotic elicitors on the accumulation of bilobalide and ginkgolides in Ginkgo biloba cell cultures

The effect of biotic elicitors on the production of bilobalide and ginkgolides in Ginkgo biloba cell suspension cultures was studied. The treatment of cell cultures with Candida albicans and Staphylococcus aureus as elicitors increased the amounts of bilobalide (BB), ginkgolide A (GA) and ginkgolide B (GB), with slight growth inhibition. The native bacterial elicitor was more effective for secondary metabolite accumulations both in cells and culture medium than autoclaved. However, exposure times of the cells to the elicitors strongly influenced the production of BB, GA and GB. This study suggests that biotic elicitors can regulate the production of BB, GA and GB either directly or indirectly. These results also describe the establishment of optimum conditions that determine the effects of biotic elicitors on secondary metabolism of bilobalides.

ENHANCED PRODUCTION OF TROPANE ALKALOIDS IN SCOPOLIA PARVIFLORA BY INTRODUCING THE PMT (PUTRESCINE N-METHYLTRANSFERASE) GENE

SummaryIn wild-type Scopolia parvilfora (Solanaceae) tissues, only the roots express the enzyme putrescine N-methyltransferase (PMT; EC 2.1.1.53), which is the first specific precursor of the tropane alkaloids. Moreover, the tropanane alkaloid levels were the highest in the root (0.9 mg g−1 on a dry weight basis), followed by the stem and then the leaves. We metabolically engineered S. parviflora by introducing the tobacco pmt gene into its genome by a binary vector system that employs disarmed Agrobacterium rhizogenes. The kanamycin-resistant hairy root lines were shown to bear the pmt gene and to overexpress its mRNA and protein product by at least two-fold, as determined by polymerase chain reaction (PCR) and Northern and Western blottings, respectively. The transgenic lines also showed higher PMT activity and were morphologically aberrant in terms of slower growth and the production of lateral roots. The overexpression of pmt markedly elevated the scopolamine and hyoscyamine levels in the transgenic lines that showed the highest pmt mRNA and PMT protein levels. Thus, overexpression of the upstream regulator of the tropane alkaloid pathway enhanced the biosynthesis of the final product. These observations may be useful in establishing root culture systems that generate large yields of tropane alkaloids.

Enzymatic release of ferulic acid fromIpomoea batatas L. (sweet potato) stem

Ferulic acid is a phenolic compound that serves as a major biosynthetic precursor of vanillin in higher plants. We investigated the ability of the 3 commercial enzymes—Ultraflo L, Viscozyme L, and α-Amylase—to induce the release ferulic acid from theIpomoea batatas L. (sweet potato) stem. The rate of release for ferulic acid was optimal when Ultraflo L (1.0%) was used compared with the other enzymes, whereas Viscozyme L was most effective for the release of vanillic acid and vanillin. Thus, these enzymes may be useful for the large-scale production of ferulic acid and other phenolic compounds from sweet potato stem.

Variation of ginkgolides and bilobalide contents in leaves and cell cultures ofGinkgo biloba L.

Ginkgolides (GK) and bilobalide are valuable compounds that belong to the lactone terpene. The contents of these metabolites were determined by HPLC from female and male tree ofGinkgo biloba L. The productivity ofG. biloba cells was also compared with the corresponding individual trees. High variations in the ginkgolides and bilobalide were observed from different individuals, plant parts, and cultured cells. The ginkgolides and bilobalide contents were different depending on the plant parts. Callus was obtained from various plant tissues, and NAA was better at callogenesis than 2,4-D in both the female and male trees. The plants and their corresponding cells showed considerable variation in their ginkgolides and bilobalide concentrations. The ginkgolides and bilobalide contents were not correlated with the production between dominant trees and their corresponding cells. Light irradiation enhanced the production of GK-A and GK-B, however, the concentration of bilobalide decreased under dark conditions.

Enhanced production of tropane alkaloids in transgenic Scopolia parviflora hairy root cultures over-expressing putrescine N-methyl transferase (PMT) and hyoscyamine-6β-hydroxylase (H6H)

Scopolia parviflora adventitious roots were metabolically engineered by co-expression of the two gene putrescine N-methyl transferase (PMT) and hyoscyamine-6β-hydroxylase (H6H) cDNAs with the aid of Agrobacterium rhizogenes. The transformed roots developed into morphologically distinct S. parviflora PMT1 (SpPMT1), S. parviflora PMT1 (SpPMT2), and S. parviflora H6H (SpH6H) transgenic hairy root lines. Consequent to the introduction of these key enzyme genes, the production of the alkaloids hyoscyamine and scopolamine was enhanced. Among the transgenic hairy root lines, SpPMT2 line possessed the highest growth index. The treatment of transgenic hairy roots with growth regulators further enhanced the production of scopolamine. Thus, the results suggest that PMT1, PMT2, and H6H genes may not only be involved in the metabolic regulation of alkaloid production but also that these genes may play a role in the root development.