Enhancement of ginsenoside biosynthesis in high-density cultivation of Panax notoginseng cells by various strategies of methyl jasmonate elicitation

A single addition of 200 M methyl jasmonate (MJA) to high-density cell cultures of Panax notoginseng enhanced ginsenoside production in both shake-flask (250 ml) and airlift bioreactor (ALR; 1 l working volume). Repeated elicitation with two additions of 200 M MJA during cultivation further induced the ginsenoside biosynthesis in both cultivation vessels. The content of ginsenosides Rg₁, Re, Rb₁ and Rd in the ALR was increased from, respectively, 0.18±0.01, 0.21±0.01, 0.21±0.02 and 0 mg per100 mg dry cell weight (DW) in untreated cell cultures (control) to 0.32±0.02, 0.36±0.02, 0.72±0.06 and 0.08±0.01 mg per100 mg DW with a single addition of MJA and further increased to 0.43±0.02, 0.46±0.03, 1.09±0.07 and 0.14±0.02 mg per100 mg DW with two additions of MJA. Interestingly, the activity of the Rb₁ biosynthetic enzyme (UDPG-ginsenoside Rd glucosyltransferase), was also increased with a single elicitation by MJA and increased again by a repeated elicitation, which coincided well with the trend in the increase in Rb₁ content. In order to further improve the cell density and ginsenoside production, a strategy of MJA repeated elicitation combined with sucrose feeding was adopted. The final cell density and total ginsenoside content in the ALR reached 27.3±1.5 g/l and 2.02±0.06 mg per100 mg DW; and the maximum production of ginsenoside Rg₁, Re, Rb₁ and Rd was 111.8±4.7, 117.2±4.6, 290.2±5.1 and 32.7±8.1 mg/l, respectively. The strategies demonstrated and the information obtained in this work are useful for the efficient large-scale production of bioactive ginsenosides by plant cell cultures.     

Efficient elicitation of ginsenoside biosynthesis in cell cultures ofPanax notoginseng by using self-chemically-synthesized jasmonates

A series of fluorine and hydroxyl containing jasmonate derivatives, which were chemically synthesized in our institute, were investigated for their effects on the biosynthesis and heterogeneity of ginsenosides in suspension cultures ofPanax notoginseng cells. Compared to the control (without addition of elicitors), 100 μM of each of the jasmonate was added on day 4 to the suspension cultures ofP. notoginseng cells. It was observed that, jasmonates greatly enhanced the ginsenoside content and the ratio of Rb group to Rg group (i.e. (Rb₁+Rd)/(Rg₁+Re)) in theP. notoginseng cells. Some of the synthetic jasmonates, such as pentafluoropropyl jasmonate (PFPJA), 2-hydroxyethyl jasmonate (HEJA) and 2-hydroxyethoxyethyl jasmonate (HEEJA), could promote the ginsenoside content to 2.55±0.11, 3.65±0.13 and 2.94±0.06 mg/100 mg DW, respectively, compared to that of 0.64±0.06 mg/100 mg DW for the control and 2.17±0.04 mg/100 mg DW by the commercially available methyl jasmonate (MJA); and they could change the respective Rb: Rg ratio to 1.60±0.04, 1.87±0.01 and 1.56±0.05, compared to that of 0.47±0.01 for the control and 1.42±0.06 by MJA. The results suggest that suitable esterification of MJA with fluorine or hydroxyl group could increase the elicitation activity to induce plant secondary metabolism. The information obtained from this study is useful for hyper-production of heterogeneous products by plant cell cultures.     

Novel synthetic jasmonates as highly efficient elicitors for taxoid production by suspension cultures of Taxus chinensis

Suspension cultures of Taxus chinensis were used as a model plant cell system to evaluate novel synthetic jasmonates as elicitors for stimulating the biosynthesis of secondary metabolites. Significant increases in accumulation of taxuyunnanine C (Tc) were observed in the presence of newly synthesized 2-hydroxyethyl jasmonate (HEJA) and trifluoroethyl jasmonate (TFEJA) without their inhibition on cell growth. Addition of 100 microM HEJA or TFEJA on day 7 led to a high Tc content of 44.3 +/- 1.1mg/g or 39.7 +/- 1.1 mg/g (at day 21), while the Tc content was 14.0 +/- 0.1 mg/g and 32.4 +/- 1.6 mg/g for the control and that with addition of 100 microM methyl jasmonate (MJA), respectively. The superior stimulating ability of HEJA and TFEJA over MJA, which was generally considered as the best chemical for eliciting taxoid biosynthesis, suggests that the novel jasmonate analogues may have great potential in application to other cell culture systems for effcient elicitation of plant secondary metabolites.     

High Density Cultivation of Panax notoginseng Cell Cultures with Methyl Jasmonate Elicitation in a Centrifugal Impeller Bioreactor

True ginseng roots contain “active compounds” called ginsenosides. The enhanced production of useful bioactive ginsenosides by high‐density cell cultures of Panax notoginseng in a self‐developed centrifugal impeller bioreactor (CIB) was achieved by adding methyl jasmonic acid (MJA) during cultivation. The production of the major, individual ginsenosides Rg₁, Re and Rb₁ was significantly enhanced in both 3‐L and 30‐L CIBs. The production titer of Rg₁, Re and Rb₁ ginsenosides in the 30‐L CIB was improved from 42 ± 8, 42 ± 9 and 41 ± 6 mg/L without MJA elicitation, to 104 ± 6, 71 ± 5 and 95 ± 6 mg/L with MJA elicitation, respectively. The ratio of Rb/Rg was slightly improved by MJA treatment in a 3‐L CIB but no apparent difference was observed in a 30‐L CIB. This work is useful for the understanding of the effects of large‐scale production on the individual ginseng saponins produced by plant cell cultures     

Highly selective microbial transformation of major ginsenoside Rb(1) to gypenoside LXXV by Esteya vermicola CNU120806

Aims

This study examined the biotransformation pathway of ginsenoside Rb₁ by the fungus Esteya vermicola CNU 120806.

Methods and Results

Ginsenosides Rb₁ and Rd were extracted from the root of Panax ginseng. Liquid fermentation and purified enzyme hydrolysis were employed to investigate the biotransformation of ginsenoside Rb₁. The metabolites were identified and confirmed using NMR analysis as gypenoside XVII and gypenoside LXXV. A mole yield of 95·4% gypenoside LXXV was obtained by enzymatic conversion (pH 5·0, temperature 50°C). Ginsenoside Rd was used to verify the transformation pathway under the same reaction condition. The product Compound K (mole yield 49·6%) proved a consecutive hydrolyses occurred at the C‐3 position of ginsenoside Rb₁.

Conclusions

Strain CNU 120806 showed a high degree of specific β‐glucosidase activity to convert ginsenosides Rb₁ and Rd to gypenoside LXXV and Compound K, respectively. The maximal activity of the purified glucosidase for ginsenosides transformation occurred at 50°C and pH 5·0. Compared with its activity against pNPG (100%), the β‐glucosidase exhibited quite lower level of activity against other aryl‐glycosides. Enzymatic hydrolysate, gypenoside LXXV and Compound K were produced by consecutive hydrolyses of the terminal and inner glucopyranosyl moieties at the C‐3 carbon of ginsenoside Rb₁ and Rd, giving the pathway: ginsenoside Rb₁→ gypenoside XVII → gypenoside LXXV; ginsenoside Rd→F₂→Compound K, but did not hydrolyse the 20‐C, β‐(1‐6)‐glucoside of ginsenoside Rb₁ and Rd.

Significance and Impact of the Study

The results showed an important practical application on the preparation of gypenoside LXXV. Additionally, this study for the first time provided a high efficient preparation method for gypenoside LXXV without further conversion, which also gives rise to a potential commercial enzyme application.     

Ginsenoside Rd production from the major ginsenoside Rb<Subscript>1</Subscript> by <Emphasis Type="Italic">β</Emphasis>-glucosidase from <Emphasis Type="Italic">Thermus caldophilus</Emphasis>

Under optimum conditions (pH 5, 75°C, and 0.2 U purified enzyme ml⁻¹), 4 mg ginsenoside Rd was produced from 5 mg reagent-grade ginsenoside Rb₁ in 5 ml after 30 min by β-glucosidase from Thermus caldophilus GK24. Using a ginseng root extract containing 1 mg ginsenoside Rb₁ ml⁻¹ and 3.2 mg additional ginsenosides ml⁻¹, 1.23 mg ginsenoside Rd ml⁻¹ was produced after 18 h; the concentrations of ginsenosides Rb₁, Rb₂, and Rc used for ginsenoside Rd production were 0.77, 0.17, and 0.19 mg ml⁻¹, respectively.     

Manipulation of ginsenoside heterogeneity of <Emphasis Type="Italic">Panax notoginseng</Emphasis> cells in flask and bioreactor cultivations with addition of phenobarbital

Structure-similar ginsenosides have different or even totally opposite biological activities, and manipulation of ginsenoside heterogeneity is interesting and significant to biotechnological application. In this work, addition of 1 mM phenobarbital to cell cultures of Panax notoginseng at a relatively high inoculation size of 7.6 g dry cell weight (DW)/L enhanced the production of protopanaxatriol-type (Rg₁ + Re) ginsenosides in both shake flask and airlift bioreactor (ALR, 1 L working volume). The content of Rg₁ + Re in the ALR was increased from 42.5 ± 4.0 mg per gram DW in untreated cell cultures (control) to 56.4 ± 4.6 mg per gram DW with addition of 1.0 mM phenobarbital. The maximum productivity of Rg₁ + Re in the ALR reached 5.66 ± 0.38 mg L⁻¹ d⁻¹, which was almost 3.3-fold that of control. The maximum ratio of the detectable ginsenosides protopanaxatriol:protopanaxadiol (Rb₁) was 7.6, which was about twofold that of control. The response of protopanaxadiol 6-hydroxylase (P6H) activity to phenobarbital addition coincided with the above-mentioned change of ginsenoside heterogeneity (distribution). Phenobarbital addition is considered as a useful strategy for manipulating the ginsenoside heterogeneity in bioreactor with enhanced biosynthesis of protopanaxatriol by P. notoginseng cells.     

A new ginsenosidase from Aspergillus strain hydrolyzing 20-O-multi-glycoside of PPD ginsenoside

A ginsenosidase specifically hydrolyzing multi-20-O-glycosides of protopanaxadiol type ginsenosides such as ginsenoside Rb₁, Rb₃, Rb₂ and Rc, named ginsenosidase type II, was isolated and purified from Aspergillus sp.g48p strain. The molecular weight of the enzyme was 60 kDa. Ginsenosidase type II was demonstrated to hydrolyze multi-20-O-glycoside of protopanaxadiol type ginsenoside Rb₁, Rb₃, Rb₂ and Rc; i.e. the ginsenosidase type II hydrolyzes 20-O-β-glucoside of the ginsenoside Rb₁, 20-O-β-xyloside of ginsenoside Rb₃, 20-O-α-arabinoside(p) of ginsenoside Rb₂ and α-arabinoside(f) of ginsenoside Rc to produce mainly ginsenoside Rd, and small amount of Rg₃. However, it did not hydrolyze 3-O-β-glucosides of ginsenoside Rb₁, Rb₃, Rb₂ and Rc which was different with the ginsenosidase type I previously reported, either did not hydrolyze the glycosides of protopanaxatriol type ginsenoside such as ginsenoside Re, Rf and Rg₁, showing significant difference from all previously described glycosidases.     

Impact of external calcium and calcium sensors on ginsenoside Rb1 biosynthesis by Panax notoginseng cells

The effects of external calcium concentrations on biosynthesis of ginsenoside Rb1 and several calcium signal sensors were quantitatively investigated in suspension cultures of Panax notoginseng cells. It was observed that the synthesis of intracellular ginsenoside Rb1 in 3-day incubation was dependent on the medium Ca2+ concentration (0-13 mM). At an optimal Ca2+ concentration of 8 mM, a maximal ginsenoside Rb1 content of 1.88 +/- 0.03 mg g(-1) dry weight was reached, which was about 60% and 25% higher than that at Ca2+ concentrations of 0 and 3 mM, respectively. Ca2+ feeding experiments confirmed the Ca2+ concentration-dependent Rb1 biosynthesis. In order to understand the mechanism of the signal transduction from external Ca2+ to ginsenoside biosynthesis, the intracellular content of calcium and calmodulin (CaM), activities of calcium/calmodulin-dependent NAD kinase (CCDNK) and calcium-dependent protein kinase (CDPK), and activity of a new biosynthetic enzyme of ginsenoside Rb1, i.e., UDPG:ginsenoside Rd glucosyltransferase (UGRdGT), in the cultured cells were all analyzed. The intracellular calcium content and CCDNK activity were increased with an increase of external Ca2+ concentration within 0-13 mM. In contrast, the CaM content and activities of CDPK and UGRdGT reached their highest levels at 8 mM of initial Ca2+ concentration, which was also optimal to the ginsenoside Rb1 synthesis. A similar Ca2+ concentration-dependency of the intracellular contents of calcium and CaM and activities of CCDNK, CDPK, and UGRdGT was confirmed in Ca2+ feeding experiments. Finally, a possible model on the effect of external calcium on ginsenoside Rb1 biosynthesis via the signal transduction pathway of CaM, CDPK, and UGRdGT is proposed. Regulation of external Ca2+ concentration is considered a useful strategy for manipulating ginsenoside Rb1 biosynthesis by P. notoginseng cells.     

Highly selective biotransformation of ginsenoside Rb<Subscript>1</Subscript> to Rd by the phytopathogenic fungus<Emphasis Type="Italic"> Cladosporium fulvum</Emphasis> (<Emphasis Type="Italic">syn</Emphasis>.<Emphasis Type="Italic"> Fulvia fulva</Emphasis>)

Fourteen phytopathogenic fungi were tested for their ability to transform the major ginsenosides to the active minor ginsenoside Rd. The transformation products were identified by TLC and HPLC, and their structures were assigned by NMR analysis. Cladosporium fulvum, a tomato pathogen, was found to transform major ginsenoside Rb₁ to Rd as the sole product. The following optimum conditions for transforming Rd by C. fulvum were determined: the time of substrate addition, 24 h; substrate concentration, 0.25 mg ml⁻¹; temperature, 37°C; pH 5.0; and biotransformation period, 8 days. At these optimum conditions, the maximum yield was 86% (molar ratio). Further, a preparative scale transformation with C. fulvum was performed at a dose of 100 mg of Rb₁ by a yield of 80%. This fungus has potential to be applied on the preparation for Rd in pharmaceutical industry.     

Purification and characterization of UDPG:ginsenoside Rd glucosyltransferase from suspended cells of Panax notoginseng

Heterogeneity of ginsenosides is an interesting and important issue because those structure-similar secondary metabolites have different or even totally opposite pharmacological activities. In this work, a new enzyme UDP-glucose:ginsenoside Rd glucosyltransferase (UGRdGT), which catalyzes the formation of ginsenoside Rb₁ from ginsenoside Rd [Biotechnol. Bioeng. 89: 444–52, 2005], was purified approximately 145-fold from suspended cells of Panax notoginseng with an overall yield of 0.2%. Purification to apparent homogeneity, as judged by SDS-PAGE, was successfully achieved by using sequential ammonium sulphate precipitation, anion-exchange chromatography and native PAGE. The enzyme had a molecular mass of 36 kDa, and its activity was optimal at pH 8.5 and 35 °C. The enzyme activity was enhanced by Mn²⁺, Ca²⁺ and Mg²⁺, but strongly inhibited by Zn²⁺, Hg²⁺, Co²⁺, Fe²⁺ and Cu²⁺. The apparent K_m value for UDP-glucose and ginsenoside Rd was 0.32 and 0.14 mM, respectively. The biotransformation yield from ginsenoside Rd to Rb₁ by UGRdGT in 50 mM Tris–HCl buffer at pH 8.5 and 35 °C was over 80%. This work provides a basis for further molecular study on the ginsenoside Rb₁ biosynthesis by P. notoginseng cells and it is also useful for potential application to in vitro biotransformation from ginsenoside Rd to Rb₁.     

Conversion of Major Ginsenoside Rb1 to Ginsenoside F2 by Caulobacter leidyia

Ginsenoside Rb₁ is the most predominant ginsenoside in Panax species (ginseng) and the hydrolysis of this ginsenoside produces pharmaceutically active compounds. Caulobacter leidyia GP45, one of the isolates having strong β-glucosidase-producing activity, converted ginsenoside Rb₁ to the active metabolites by 91%. The structures of the resultant metabolites were identified by NMR. Ginsenoside Rb₁ had been consecutively converted to ginsenoside Rd (1), F₂ (2) and compound K (3) via the hydrolyses of 20-C β-(1→6)-glucoside, 3-C β-(1→2)-glucoside, and 3-C β-glucose of ginsenoside Rb₁.     

Microbial transformation of ginsenosides Rb1, Rb3 and Rc by Fusarium sacchari

Aims: This study examined the transformation pathways of ginsenosides G‐Rb₁, G‐Rb₃, and G‐Rc by the fungus Fusarium sacchari. Methods and Results: Ginsenosides G‐Rb₁, G‐Rb₃ and G‐Rc were isolated from leaves of Radix notoginseng, and their structural identification was confirmed using NMR. Transformation of G‐Rb₁, G‐Rb₃ and G‐Rc by Fusarium sacchari was respectively experimented. Kinetic evolutions of G‐Rb₁, G‐Rb₃ and G‐Rc and their metabolites during the cell incubation were monitored by HPLC analysis. High‐performance liquid chromatography (HPLC) was used for monitoring the transformation kinetics of bioactive compounds during F. sacchari metabolism. Conclusions: Ginsenoside C‐K was transformed by F. sacchari from G‐Rb₁ via G‐Rd or via G‐F₂, or from G‐Rb₁ via firstly Rd and then G‐F₂, and C‐Mx was transformed by F. sacchari or directly from Rb₃, or from Rb₃ via Gy‐IX, while G‐Mc was transformed by F. sacchari directly from G‐Rc. Furthermore, C‐K could be also formed from G‐Rc via notoginsenoside Fe (N‐Fe). Significance and Impact of the Study: The results showed an important practical application in the preparation of ginsenoside C‐K. As our precious research indicated C‐K possessed much more antitumor activities than C‐Mx and G‐Mc, so according to the transformation pathways proposed by this work, the production of antitumor compound C‐K may be performed by biotransformation of G‐Rb₁ previously isolated from PNLS.     

Methyl jasmonate elicitation enhanced synthesis of ginsenoside by cell suspension cultures of Panax ginseng in 5-l balloon type bubble bioreactors

The effects of methyl jasmonate (MJ) elicitation on the cell growth and accumulation of ginsenoside in 5-l bioreactor suspension cultures of Panax ginseng were investigated. Ginsenoside accumulation was enhanced by elicitation by MJ (in the range 50–400 M); however, fresh weight, dry weight and growth ratio of the cells was strongly inhibited by increasing MJ concentration. The highest ginsenoside yield was obtained at 200 M MJ. In the second experiment, 200 M MJ was added on day 15 during the cultivation. The ginsenoside, Rb group, and Rg group ginsenoside content increased 2.9, 3.7, and 1.6 times, respectively, after 8 days of MJ treatment. Rb group gisnsenosides accumulated more than Rg group ginsenosides. Among Rb group ginsenosides, Rb1 content increased significantly by four times but the contents of Rb2, Rc and Rd increased only slightly. Among Rg group ginsenosides, Rg1 and Re showed 2.3-fold and 3.0-fold increments, respectively, whereas there was only a slight increment in Rf group ginsenosides. These results suggest that MJ elicitation is beneficial for ginsenoside production using 5-l bioreactor cell suspension cultures.     

Bioconversion of ginsenosides Rb(1), Rb(2), Rc and Rd by novel β-glucosidase hydrolyzing outer 3-O glycoside from Sphingomonas sp. 2F2: cloning, expression, and enzyme characterization

A new β-glucosidase gene (bglSp) was cloned from the ginsenoside converting Sphingomonas sp. strain 2F2 isolated from the ginseng cultivating filed. The bglSp consisted of 1344 bp (447 amino acid residues) with a predicted molecular mass of 49,399 Da. A BLAST search using the bglSp sequence revealed significant homology to that of glycoside hydrolase superfamily 1. This enzyme was overexpressed in Escherichia coli BL21 (DE3) using a pET21-MBP (TEV) vector system. Overexpressed recombinant enzymes which could convert the ginsenosides Rb₁, Rb₂, Rc and Rd to the more pharmacological active rare ginsenosides gypenoside XVII, ginsenoside C-O, ginsenoside C-Mc₁ and ginsenoside F₂, respectively, were purified by two steps with Amylose-affinity and DEAE-Cellulose chromatography and characterized. The kinetic parameters for β-glucosidase showed the apparent K_m and V_max values of 2.9 ± 0.3 mM and 515.4 ± 38.3 μmol min⁻¹ mg of protein⁻¹ against p-nitrophenyl-β-d-glucopyranoside. The enzyme could hydrolyze the outer C3 glucose moieties of ginsenosides Rb₁, Rb₂, Rc and Rd into the rare ginsenosides Gyp XVII, C-O, C-Mc₁ and F₂ quickly at optimal conditions of pH 5.0 and 37 °C. A little ginsenoside F₂ production from ginsenosides Gyp XVII, C-O, and C-Mc₁ was observed for the lengthy enzyme reaction caused by the side ability of the enzyme.     

Effects of external calcium on the biotransformation of ginsenoside Rb1 to ginsenoside Rd by <Emphasis Type="Italic">Paecilomyces bainier</Emphasis> 229-7

Calcium is a known signalling molecule in eukaryotic cells and plays a central role in the regulation of many cellular processes. In the following study, we report on the effect of external calcium treatments on the biotransformation of ginsenoside Rb1 to ginsenoside Rd by Paecilomyces bainier 229-7. We observed that the intracellular calcium content of P. bainier 229-7 mycelia was increased in response to exposure to high external Ca²⁺ concentrations. Both ginsenoside Rd biotransformation and β-glucosidase activity were both found to be dependent on the external calcium concentration. At an optimal Ca²⁺ concentration of 45 mM, maximal ginsenoside Rd bioconversion rate of 92.44% was observed and maximal β-glucosidase activity of 0.1778 U was reached in a 72-h biotransformation. The Ca²⁺ channel blocker Verapamil blocked the trans-membrane influx of calcium and decreased ginsenoside Rd biotransformatiom. In addition, β-glucosidase activity and ginsenoside Rd content decreased by 36.0 and 29.2% respectively after a 72-h incubation in the presence of 0.05 mM Calmodulin (CaM) antagonist Perphenazine. These results suggest that both Ca²⁺ channels and CaM are involved in ginsenoside Rd biotransformation via regulation of β-glucosidase activity. This is the first report regarding the effects of calcium signal transduction on biotransformation and enzyme activity in fungi.     

Microbial transformation of ginsenoside Rb<Subscript>1</Subscript> by <Emphasis Type="Italic">Acremonium strictum</Emphasis>

Preparative-scale fermentation of ginsenoside Rb₁ (1) with Acremonium strictum AS 3.2058 gave three new compounds, 12β-hydroxydammar-3-one-20 (S)-O-β-d-glucopyranoside (7), 12β, 25-dihydroxydammar-(E)-20(22)-ene-3-O-β-d-glucopyranosyl-(1→2)-β-d-glucopyranoside (8), and 12β, 20 (R), 25-trihydroxydammar-3-O-β-d-glucopyranosyl-(1→2)-β-d-glucopyranoside (9), along with five known compounds, ginsenoside Rd (2), gypenoside XVII (3), ginsenoside Rg₃ (4), ginsenoside F₂ (5), and compound K (6). The structural elucidation of these metabolites was based primarily on one- and two-dimensional nuclear magnetic resonance and high-resolution electron spray ionization mass spectra analyses. Among these compounds, 2–6 are also the metabolites of ginsenoside Rb₁ in mammals. This result demonstrated that microbial culture parallels mammalian metabolism; therefore, A. strictum might be a useful tool for generating mammalian metabolites of related analogs of ginsenosides for complete structural identification and for further use in pharmaceutical research in this series of compounds. In addition, the biotransformation kinetics was also investigated.     

A novel synthetic fluoro-containing jasmonate derivative acts as a chemical inducing signal for plant secondary metabolism

A novel fluoro-containing jasmonate derivative was chemically synthesized and evaluated as a potential elicitor with respect to the induction of plant defense responses and the biosynthesis of plant secondary metabolites. A bioactive taxuyunnanine C (Tc)-producing cell line of Taxus chinensis was taken as a model plant cell system. The presence of novel synthesized pentafluoropropyl jasmonate (PFPJA) induced two early and important events in plant defense responses, including an oxidative burst and activation of l-phenylalanine ammonia lyase. In addition, PFPJA was found to significantly increase Tc accumulation, without any inhibition of cell growth. Moreover, Tc accumulation was increased more in the presence of PFPJA compared with methyl jasmonate (MJA) and previously reported trifluoroethyl jasmonate (TFEJA). For example, addition of 100 M PFPJA on day 7 led to a high Tc content (38.2±0.3 mg/g) at day 21, while the Tc content was 29.3±0.3 mg/g and 34.9±0.9 mg/g with the addition of 100 M MJA and TFEJA, respectively. Quantitative structure–activity analysis of fluoro-containing jasmonates suggests that the increase in the fluoro-groups introduced into the carboxyl side-chain of MJA resulted in a higher stimulatory activity for Tc biosynthesis, which corresponds well with the markedly increased lipophilicity after fluorine introduction. These results indicate that newly synthesized fluoro-containing PFPJA can act as a powerful chemical inducing signal for secondary metabolism in plant cell cultures.