Biotransformation of Saponins by Endophytes Isolated from Panax notoginseng

The biotransformation of the major saponins in Panax notoginseng, including the ginsenosides Rg1, Rh1, Rb1, and Re, by endophytes isolated from P. notoginseng was studied. One hundred and thirty‐six endophytes were isolated and screened for their biotransformational abilities. The results showed that five of the tested endophytes were able to transform these saponins. These five strains were identified based on their ITS or 16S rDNA sequences, which revealed that they belonged to the genera Fusarium, Nodulisporium, Brevundimonas, and Bacillus genera. Ten transformed products were isolated and identified, including a new compound 6‐O‐[α‐L ‐rhamnopyranosyl‐(1→2)‐β‐D ‐glucopyranosyl]‐20‐O‐β‐D ‐glucopyranosyldammarane‐3,6,12,20,24,25‐hexaol ( 3 ), and nine known compounds, compound K ( 1 ), ginsenoside F2 ( 2 ), vinaginsenoside R13 ( 4 ), vinaginsenoside R22 ( 5 ), pseudo‐ginsenoside RT4 ( 6 ), (20S)‐protopanaxatriol ( 7 ), ginsenoside Rg1 ( 8 ), vinaginsenoside R15 ( 9 ), and (20S)‐3‐O‐β‐D ‐glucopyranosyl‐6‐O‐β‐D ‐glucopyranosylprotopanaxatriol ( 10 ). This is the first study on the biotransformation of chemical components in P. notoginseng by endophytes isolated from the same plant.     

Conversion of major ginsenoside Rb1 to 20(S)-ginsenoside Rg3 by Microbacterium sp. GS514

Ginseng saponin, the most important secondary metabolite in ginseng, has various pharmacological activities. Many studies have been directed towards converting major ginsenosides to the more active minor ginsenoside, Rg3. Due to the difficulty in preparing ginsenoside Rg3 enzymatically, the compound has been mainly produced by either acid treatment or heating. A microbial strain GS514 was isolated from soil around ginseng roots in a field and used for enzymatic preparation of the ginsenoside Rg3. Blast results of the 16S rRNA gene sequence of the strain GS514 established that the strain GS514 belonged to the genus Microbacterium. Its 16S rRNA gene sequence showed 98.7%, 98.4% and 96.1% identity with those of M. esteraromaticum, M. arabinogalactanolyticum and M. lacticum. Strain GS514 showed a strong ability to convert ginsenoside Rb1 or Rd into Rg3. Enzymatic production of Rg3 occurred by consecutive hydrolyses of the terminal and inner glucopyranosyl moieties at the C-20 carbon of ginsenoside Rb1 showing the biotransformation pathway: Rb1-->Rd-->Rg3.     

Application of ultra-performance LC-TOF MS metabolite profiling techniques to the analysis of medicinal <Emphasis Type="Italic">Panax</Emphasis> herbs

The morphological appearance and some ingredients of Panax ginseng, Panax notoginseng and Panax japonicus of the Panax genus are similar. However, their pharmacological activities are obviously different due to the significant differences in the types and quantity of saponins in each herb. In the present study, ultra-performance liquid chromatography-quadrupole time-of-flight mass spectrometry (UPLC-QTOFMS) was used to profile the abundances of metabolites in the three medicinal Panax herbs. Multivariate statistical analysis technique, that is, principle component analysis (PCA) and partial least squares-discriminant analysis (PLS-DA) were used to discriminate between the Panax samples. PCA of the analytical data showed a clear separation of compositions among the three medicinal herbs. The critical markers such as chikusetsusaponin IVa, ginsenoside R0, ginsenoside Rc, ginsenoside Rb1, ginsenoside Rb2 and ginsenoside Rg2 accountable for such variations were identified through the corresponding loading weights, and the tentative identification of biomarkers is completed by the accurate mass of TOFMS and high resolution and high retention time reproducibility performed by UPLC. The proposed analytical method coupled with multivariate statistical analysis is reliable to analyze a group of metabolites present in the herbal extracts and other natural products. This method can be further utilized to evaluate chemical components obtained from different plants and/or the plants of different geographical locations, thereby classifying the medicinal plant resources and potentially elucidating the mechanism of inherent phytochemical diversity.     

Transformation of Ginsenosides Rb1 and Re from <Emphasis Type="Italic">Panax ginseng</Emphasis> by Food Microorganisms

Ginsenosides Rb1 and Re, respectively belonging to the major protopanaxadiol and protopanaxatriol ginsenosides, were transformed using cell-free extracts from food microorganisms. Rb1 was transformed into compound K via Rd and F2 by Bifidobacterium sp. Int57, Bif. sp. SJ32, Aspergillus niger and A.␣usamii. Lactobacillus delbrueckii, and Leuconostoc paramesenteroides transformed Rb1 into Rh2 via Rd and F2. Bifidobacterium sp. SH5 transformed Rb1 into F2 via Rd. Re was transformed into Rh1 via Rg2 by Bif. sp. Int57 and Bif. sp. SJ32. A. niger transformed Re into Rh1 via Rg1. A. usamii transformed Re into Rg2. Transformation of Rb1 proceeded at a higher rate and needed less amount of enzymes than that of Re. Taken together, these processes would allow a specific bioconversion process possible to obtain specific ginsenosides using an appropriate combination of ginsenoside substrates and specific microbial enzymes.     

Antimelanogenic Activity of Ocotillol‐Type Saponins from Panax vietnamensis

The ocotillol (OCT)‐type saponins have been known as a tetracyclic triterpenoid, possessing five‐ or six‐membered epoxy ring in the side chain. Interestingly, this type saponin was mostly found in Panax vietnamensis Ha et Grushv ., Araliaceae (VG), hence making VG unique from the other Panax spp. Five OCT‐type saponins, majonoside R2, vina‐ginsenoside R2, majonoside R1, pseudoginsenoside RT4, vina‐ginsenoside R11, together with three protopanaxadiol (PPD)‐type saponins and four protopanaxatriol (PPT)‐type saponins from VG were evaluated for their antimelanogenic activity. All of isolates were found to be active. More importantly, the five OCT‐type saponins inhibited melanin production in B16‐F10 mouse melanoma cells, without showing any cytotoxicity. Besides ginsenoside Rd and ginsenoside Rg3 in PPD and notoginsenoside R1 in PPT‐type saponins, majonoside R2 was the most potent melanogenesis inhibitory activity in OCT‐type saponins. In this article, we highlighted antimelanogenic activity of OCT‐type saponins and potential structure–activity relationship (SAR) of ginsenosides. Our results suggested that OCT‐type saponins could be used as a depigmentation agent.     

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.     

Induction and Characterization of Adventitious Roots Directly from the Explants of <Emphasis Type="Italic">Panax notoginseng</Emphasis>

Adventitious roots from leafstalks and lateral roots were obtained directly from explants of Panax notoginseng. The lateral root explants were more sensitive to the induction of adventitious roots using indole-3-butyric acid. HPLC analysis of saponins extracted from the adventitious roots indicated that several protopanaxatriol saponins were present but ginsenoside Rd was missing, compared with the saponins extracted from the raw herbs. The dry weight of primary adventitious root culture of Panax notoginseng increased 5.25 times during multiplication in a classical shaking-flask system, suggesting that it is a culture system with great potential for scale-up. Revisions requested 13 July 2005; Revisions received 1 September 2005     

Nitrogen and phosphorus as the factors affecting ginsenoside production in hairy root cultures of <Emphasis Type="Italic">Panax quinquefolium</Emphasis> cultivated in shake flasks and nutrient sprinkle bioreactor

The study assesses the influence of different concentrations of nitrogen and phosphorus sources on ginsenoside biosynthesis in Panax quinquefolium hairy roots cultivated in shake flasks and a nutrient sprinkle bioreactor. The saponin content was determined using HPLC. The maximum yield (12.45 mg g^?1 dw) of the sum of six examined ginsenosides (Rb1, Rb2, Rc, Rd, Re and Rg1) in hairy roots cultivated in shake flasks was achieved in modified Gamborg B-5 medium containing 0.83 mM l^?1 phosphate, 12.4 mM l^?1 nitrate and 0.5 mM l^?1 ammonium. The yield itself was 1.93 times higher than that achieved in standard Gamborg medium. The modified medium also favourably influenced the biosynthesis of studied saponins in bioreactor cultures. The saponin content (35.11 mg g^?1 d.w.) was 2.75-times higher than that achieved in control medium.     

Efficient induction of ginsenoside biosynthesis and alteration of ginsenoside heterogeneity in cell cultures of Panax notoginseng by using chemically synthesized 2-hydroxyethyl jasmonate

Chemically synthesized 2-hydroxyethyl jasmonate (HEJA) was for the first time employed to induce the ginsenoside biosynthesis and to manipulate the product heterogeneity in plant cell cultures. The dose response and timing of HEJA elicitation were investigated in cell suspension cultures of Panax notoginseng. The optimal concentration and timing of HEJA addition for both cell growth and ginsenoside accumulation was identified to be 200 μM added on day 4. It was interestingly found that HEJA could stimulate ginsenosides biosynthesis and change their heterogeneity more efficiently than methyl jasmonate (MJA), i.e., the total ginsenoside content and the Rb/Rg ratio increased about 60 and 30% with HEJA elicitation than that by MJA, respectively. The activity of Rb₁ biosynthetic enzyme, i.e., UDPG-ginsenoside Rd glucosyltransferase (UGRdGT), was also higher in the former case. A maximal production titer of ginsenoside Rg₁, Re, Rb₁, and Rd was 47.4±4.8, 52.3±4.4, 190±18, and 12.1±2.5 mg/l with HEJA elicitation, which was about 1.3-, 1.3-, 1.7-, and 2.1-fold than that using MJA, respectively. Early signal events in plant defense response, including oxidative burst and jasmonic acid (JA) biosynthesis, were also examined. Levels of H₂O₂ and NO in medium and l-phenylalanine ammonia lyase activity in cells were not affected by addition of MJA and HEJA. On the other hand, the JA content in cells was increased with external jasmonates elicitation, and it was inhibited with the addition of JA biosynthesis inhibitors. The results suggest that oxidative burst might not be involved in the jasmonates-elicited signal transduction pathway, and MJA and HEJA may induce the ginsenoside biosynthesis via induction of endogenous JA biosynthesis and key enzymes (such as UGRdGT) in the ginsenoside biosynthetic pathway of P. notoginseng cells. The information is useful for hyperproduction of plant-specific heterogeneous products.     

Fermentation of ginseng extracts by Penicillium simplicissimum GS33 and anti-ovarian cancer activity of fermented products

A total of 58 isolates of β-glucosidase-producing microorganisms were isolated from soil around the wild ginseng roots under forest using Esculin-R2A agar. Among these isolates, strain GS33 showed a strong ability to convert ginsenosides Rb1, Rb2, Rc, and Rd into F2, Rg3, C-K, and convert ginsenoside Rg1 into Rh1, and F1. Fermented ginseng products can inhibit ES-2 cells growth and the IC₅₀ value was 0.73 mg ml^?1. Phylogenetic analysis based on 16S rRNA gene sequences indicated that the strain GS33 belongs to the genus Penicillium and is most closely related to Penicillium simplicissimum (99 %).     

人参生殖器官皂苷含量动态变化

为了明确从现蕾、开花到结实过程中的人参生殖器官中各单体皂苷含量的动态变化,应用HPLC法测定了人工栽培的五年生人参不同时期生殖器官中的人参单体皂苷Rb1、Rb2、Rb3、Rc、Rd、Re、Rg1和Rg3的含量。结果显示:从现蕾到果实成熟的过程中,人参单体皂苷Rb1、Rb2、Rb3、Rc、Rd、Re、Rg1和Rg3的含量的平均值分别为0.643%,0.189%,1.026%,1.014%,1.941%,8.381%,0.724%和0.041mg.g-1。从现蕾到果实成熟的过程中,人参单体皂苷Rb1含量的最高值在7月16日,单体皂苷Rb3、Rc、Rd和Rg1含量的最高值在7月11日,单体皂苷Rb2和Rg2含量的最高值在8月7日。     

Purification method improvement and characterization of a novel ginsenoside-hydrolyzing beta-glucosidase from Paecilomyces Bainier sp. 229

The purification method for a novel ginsenoside-hydrolyzing beta-glucosidase from Paecilomyces Bainier sp. 229 was successfully simplified by the application of microcrystalline cellulose (MCC) as a novel chromatographic matrix. Only two chromatographic steps, Q-Sepharose FF and MCC column in sequence, were required to purify the enzyme to apparent homogeneity. The purified enzyme, with a native molecular weight estimated to be 305 KDa, was composed of three identical subunits of approximately 102 KDa each. The optimal enzyme activity was observed at pH 3.5 at 55 degrees C. It was stable within pH 3-7 and at temperatures lower than 50 degrees C. The optimal substrate for the enzyme was p-nitrophenyl-beta-D-glucoside, followed by ginsenoside Rd, gentiobiose, and ginsenoside Rb1. It converted ginsenoside Rb1 to ginsenoside Rg3 specifically and efficiently. The hydrolyzing pathway of ginsenoside Rb1 by the enzyme was Rb1-->Rd-->Rg3. The specific activities against ginsenoside Rb1 and Rd were 56.7 micromol/min/mg and 129.4 micromol/min/mg respectively.     

云南栽培西洋参皂甙的高压液相色谱定量分析

采用N-18ODS柱,以CH_3CN:H_2O(31:69 v/v)中加入50mM KH_2PO_4和CH_3CN:H_2O:H_3PO_4(20:80:0.5 v/v)为流动相,在202 nm紫外吸收波长检测下,测定了云南丽江引种栽培的西洋参中丙二酸人参皂甙(malonyl ginsenoside)Rb_1、Rb_2、Rc、人参皂甙(ginsenosidc)Rb_1、Rb_2、Rc、Rd、Ro和Rc、Rgl等10种主要皂甙的含量,讨论了不同的栽培年代、采收季节、地下部位以及商品等级中皂甙含量的变化,对该地区西洋参的生产提出了建议。     

Microbial conversion of ginsenoside Rd from Rb1 by the fungus mutant Aspergillus niger strain TH-10a

Ginsenoside Rd, one of the ginsenosides with significant pharmaceutical activities, is getting more and more attractions on its biotransformation. In this study, a novel fungus mutant, the Aspergillus niger strain TH-10a, which can efficiently convert ginsenoside Rd from Rb1, was obtained through screening survival library of LiCl and ultraviolet (UV) irradiation. The transformation product ginsenoside Rd, generated by removing the outer glucose residue from the position C20 of ginsenoside Rb1, was identified through high-performance liquid chromatography (HPLC) analysis. Factors for the microbial culture and biotransformation were investigated in terms of the carbon sources, the nitrogen sources, pH values, and temperatures. This showed that maximum mycelia growth could be obtained at 28°C and pH 6.0 with cellobiose and tryptone as the carbon source and the nitrogen source, respectively. The highest transformation rate (～86%) has been achieved at 32°C and pH 5.0 with the feeding time of substrate 48 hr. Also, Aspergillus niger strain TH-10a could tolerate even 40 mg/mL ginseng root extract as substrate with 60% bioconversion rate after 72 hr of treatment at the optimal condition. Our results highlight a novel ginsenoside Rd transformation fungus and illuminate its potentially practical application in the pharmaceutical industries.     

Studies on the biochemical action of ginseng saponin. I. Purification from ginseng extract of the active component stimulating serum protein biosynthesis.

Systematic isolation and purification of the biologically active component of ginseng extract were followed by observing the incorporation of labeled leucine into serum protein at 6 hr after a single intraperitoneal injection in a mouse. Ginseng saponin mixture (fraction 5) exhibited high activity for such incorporation. Seven saponins were isolated from fraction 5 by means of preparative TLC, and assayed. Administration of all these saponins (ginsenoside-Rb2, Rc, Rc2, Rd, Re, and Rg1)except for ginsenoside-Rb1, caused an increase of leucine incorporation over that in control animals. The incorporation rate was directly proportional to the dose in the case of ginsenoside-Rd, which had the highest activity. The increase specific radio-activity of serum protein was not due to a decrease in the pool size of free amino acids in the liver. It was conclusively shown that the active component stimulating serum protein biosynthesis is saponin.     

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.     

Microbial transformation of ginsenoside Rg3 to ginsenoside Rh2 by <Emphasis Type="Italic">Esteya vermicola</Emphasis> CNU 120806

In the present investigation, we successfully employed a cell-free extract of Esteya vermicola CNU 120806 to convert ginsenoside Rg3 to Rh2. Three important factors including pH, temperature and substrate concentration were optimized for the preparation of Rh₂. The optimal condition was obtained as follows: 50°C, pH 5.0 and substrate concentration of 3 mg ml⁻¹. The yield of conversion was up to 90.7%. In order to identify the specificity of the β-glucosidase activity of Esteya vermicola CNU 120806, ginsenoside Re (protopanaxatriol saponins) was treated under the same reaction system. Interestingly, no new metabolite was generated, which elucidated that the enzymatic process only occurred by hydrolysis of the terminal glucopyranosyl moieties at the C-3 carbon of ginsenoside Rg₃. The crude enzyme extract can be used for commercial ginsenoside Rh₂ preparation.     

培养条件对三七愈伤组织生长和皂苷积累的影响

以MS为基础培养基,改变激素配比、氮源和光照等因素,以分光光度法和HPLC法分析三七愈伤组织培养过程中皂苷含量的变化。结果表明:培养条件对三七愈伤组织中皂苷积累有一定影响,激素配比对愈伤组织中皂苷含量的影响最大,在0.5 mg·L-12,4-D+1.0 mg·L-16-BA组合下,培养物中总皂苷含量最多,达到4.72%±0.29%;在总氮量为60 mmol·L-1条件下,45 mmol·L-1KNO3+7.5 mmol·L-1NH4NO3(NO3-/NH4+=7∶1)时,愈伤组织皂苷含量最多,达到4.71%±0.17%;分别在1 000 lx和500 lx光强下每天光照12 h的愈伤组织,皂苷含量均低于黑暗培养的愈伤组织,三者皂苷含量分别为1.94%±0.31%、2.38%±0.12%和3.57%±0.27%,光照引起愈伤组织表面变绿及细胞分化,可能是抑制愈伤组织中皂苷合成与积累的主要原因;HPLC检测发现,三七愈伤组织和根中均含有Rg1、Re、Rb1及Rd四种皂苷,但栽培三七根含有R1皂苷,而三七愈伤组织中未检测到R1,其原因需要进一步研究。该研究结果为未来愈伤组织培养成为部分代替人工栽培生产三七天然产物的潜在途径提供了研究基础。