1.Optimization of UDP-glucose supply module and production of ginsenoside F1 in Saccharomyces cerevisiae.
Jin-He WANG ; Dong WANG ; Wei-Xian LI ; Ying HUANG ; Zhu-Bo DAI ; Xue-Li ZHANG
China Journal of Chinese Materia Medica 2019;44(21):4596-4604
Ginsenoside F1 is a rare ginsenoside in medicinal plants such as Panax ginseng,P. notogingseng and P. quinquefolius. It has strong pharmacological activities of anti-tumor,anti-oxidation and anti-aging. In order to directly produce ginsenoside F1 by using inexpensive raw materials such as glucose,we integrated the codon-optimized P.ginseng dammarenediol-Ⅱ synthase(Syn Pg DDS),P.ginseng protopanaxadiol synthase(Syn Pg PPDS),P. ginseng protopanaxatriol synthase(Syn Pg PPTS) genes and Arabidopsis thaliana cytochrome P450 reductase(At CPR1) gene into triterpene chassis strain BY-T3. The transformant BY-PPT can produce protopanaxatriol. Then we integrated the Sacchromyces cerevisiae phosphoglucomutase 1(PGM1),phosphoglucomutase 2(PGM2) and UDP-glucose pyrophosphorylase 1(UGP1) genes into chassis strain BY-PPT. The UDP-glucose supply module increased UDP-glucose production by 8. 65 times and eventually reached to 44. 30 mg·L-1 while confirmed in the transformant BY-PPT-GM. Next,we integrated the UDPglucosyltransferase Pg3-29 gene which can catalyze protopanaxatriol to produce ginsenoside F1 into chassis strain BY-PPT-GM. The transformant BY-F1 produced a small amount of ginsenoside F1 which was measured as 0. 5 mg·L-1. After the fermentation process was optimized,the titer of ginsenoside F1 could be increased by 900 times to 450. 5 mg·L-1. The high-efficiency UDP-glucose supply module in this study can provide reference for the construction of cell factories for production of saponin,and provide an important basis for further obtaining high-yield ginsenoside yeast cells.
Ginsenosides/metabolism*
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Glucose
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Panax
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Saccharomyces cerevisiae/metabolism*
;
Uridine Diphosphate Glucose
2.Discovery and confirmation of protein action site AK1 of ginsenosides in brain based on DARTS technology.
Fei-Yan CHEN ; Wei QIN ; Rui-Mei LI ; Yao CHENG ; Zhu ZHU ; Lin CHEN ; Yu-Nan ZHAO
China Journal of Chinese Materia Medica 2022;47(5):1336-1342
This study aims to explore the targets of ginsenosides in brain based on drug affinity responsive target stability(DARTS) technology. Specifically, DARTS technology was combined with label-free liquid chromatography tandem mass spectrometry(LC-MS) to screen out the proteins in the brain that might interact with ginsenosides. Based on the screening results, adenylate kinase 1(AK1) was selected for further confirmation. First, the His-AK1 fusion protein was yielded successively through the construction of recombinant prokaryotic expression vector, expression of target protein, and purification of the fusion protein. Biolayer interferometry(BLI) was employed to detect the direct interaction of Rg_1, Re, Rb_1, Rd, Rh_2, F1, Rh_1, compound K(CK), 25-OH-PPD, protopanaxa-diol(PPD), and protopanaxatriol(PPT) with AK1, thereby screening the ginsenoside monomer or sapogenin that had strong direct interaction with the suspected target protein AK1. Then, the BLI was used to further determine the kinetic parameters for the binding of PPD(strongest interaction with AK1) to His-AK1 fusion protein. Finally, molecular docking technology was applied to analyze the binding properties between the two. With DARTS and LC-MS, multiple differential proteins were screened out, and AK1 was selected based on previous research for target verification. Fusion protein His-AK1 was obtained by prokaryotic expression, and the response(nm) of Re, Rg_1, Rd, Rb_1, Rh_1, Rh_2, F1, PPT, PPD, 25-OH-PPD, and CK with His-AK1 was respectively 0.003 1, 0.001 9, 0.042 8, 0.022 2, 0.013 4, 0.037 3, 0.013 9, 0.030 7, 0.140 2, 0.016 0, and 0.040 8. The K_(on), K_(off), and K_D values of PPD and His-AK1 were determined by the BLI as 1.22×10~2 mol~(-1)·L·s~(-1), 1.04×10~(-2) s~(-1), 8.52×10~(-5) mol·L~(-1). According to the molecular docking result, PPD bound to AK1 with the absolute value of the docking score of 3.438, and hydrogen bonds mainly formed between the two. Thus, AK1 is one of the protein action sites of ginsenosides in the brain. The direct interaction between ginsenoside metabolite PPD and AK1 is the strongest.
Brain/metabolism*
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Chromatography, Liquid
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Ginsenosides
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Molecular Docking Simulation
;
Technology
3.Effect of total ginsenosides on protective enzymes of Mythimna separata larvae.
Shi-qiang TAN ; Lian-xue ZHANG ; Lin MA ; Ai-hua ZHANG
China Journal of Chinese Materia Medica 2014;39(22):4283-4287
Under indoors simulating natural growing condition, the 4th-instar Mythimna separata larvae were fed by using poi- son leaf disk method. The effect of total ginsenosides on the protective enzymes (PPO, T-SOD, CAT and POD) of M. separata larvae was studied. The total ginsenosides could influence the protective enzymes of 4th-instar M. separata larvae significantly. After treated by total ginsenosides, the PPO activities increased firstly then decreased, and tended to equilibrium, and reached the maximum after 48 h. Furthermore, the total ginsenosides disturbed the dynamic balance of SOD, CAT and POD of M. separata larvae, and the yield of O2-* speeded. The results suggest that the total ginsenosides influence the protective enzymes of 4th-instar M. separata larvae, and disturb the original dynamic balance of protective enzymes. Consequently the insect suffers from the harm of O2-*.
Animals
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Enzymes
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metabolism
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Ginsenosides
;
metabolism
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Larva
;
metabolism
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Lepidoptera
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metabolism
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Oxygen
;
metabolism
4.Advances in studies on biotransformation of ginsensides.
Cong-Liang GUO ; Xiu-Ming CUI ; Xiao-Yan YANG ; Shuang WU
China Journal of Chinese Materia Medica 2014;39(20):3899-3904
Ginseng saponins are a type of important active substances in the ginseng genus plants. They have notable pharmacological activities of antineoplastic, neuroprotective, and hepatoprotective activities, which have been drawn more attention to obtain minor ginsenosides by all kinds of methods. In this review, we discussed the latest progress for enrichment of minor ginsenosides by biological transformation of major ginsenosides. At the same time, we have a brief outlook of the research at bioconversion of ginseng saponins.
Bacteria
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metabolism
;
Biotransformation
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Drugs, Chinese Herbal
;
chemistry
;
metabolism
;
Ginsenosides
;
chemistry
;
metabolism
;
Panax
;
chemistry
;
metabolism
5.Effects of acid and alkali stress on ginsenoside content and histochemical localization of ginsenoside in adventitious root of Panax ginseng.
Tie-Jun LI ; Mei-Lan LIAN ; Chun-Hui SHAO ; Dan YU ; Xuan-Chun PIAO
China Journal of Chinese Materia Medica 2013;38(24):4277-4280
To investigate the effect of acid and alkali stress on ginsenoside content of Panax ginseng, adventitious roots culture in bioreactors were incubated for 30 d and pH value was adjusted. Ginsenoside content increased by reducing or raising the pH in culture medium, the muxium ginsenoside content was determined on the 5th days after acid treatment and on the 7th days after alkali treatment. The result of histochemical localization of ginsenoside revealed that the red color from light to dark were found in the adventitious root tissue, and ginsenoside mainly located in the pericycle cells where appeared the dark red color.
Ginsenosides
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metabolism
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Hydrogen-Ion Concentration
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Panax
;
metabolism
;
physiology
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Plant Roots
;
metabolism
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Stress, Physiological
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Time Factors
6.Biotransformation in vivo/vitro and bioactive properties of rare ginsenoside IH901.
Yuxing TONG ; Zhizhong ZHENG ; Qingxuan TONG ; Yi LIN ; Yanlin MING
Chinese Journal of Biotechnology 2012;28(6):684-695
Recent metabolomics research revealed a new ginseng ginsenoside IH901 that is synthesized by intestinal microbial transformation in oral administration of ginseng. IH901 shows various biological activities, including anti-tumor, anti-inflammatory, anti-diabetic, and anti-aging. In recent years, great effort has been made to prepare IH901 by microbial and enzymatic transformation in a large scale. In this paper, we reviewed the biotransformation pathways both in vivo and in vitro and bioactive properties of rare ginsenoside IH901.
Biotransformation
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Ginsenosides
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metabolism
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pharmacokinetics
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Humans
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Intestines
;
metabolism
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microbiology
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Panax
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chemistry
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Sapogenins
;
metabolism
7.Discovery of biomarkers related to abnormal lipid metabolism in liver and serum and intervention mechanism of ginsenoside Rb_1 in hyperlipidemia rats based on non-targeted metabolomics.
China Journal of Chinese Materia Medica 2023;48(14):3922-3933
Through the non-targeted metabolomics study of endogenous substances in the liver and serum of hyperlipidemia rats, the biomarkers related to abnormal lipid metabolism in hyperlipidemia rats were found, and the target of ginsenoside Rb_1 in improving hyperlipidemia was explored and its mechanism was elucidated. The content of serum biochemical indexes of rats in each group was detected by the automatic biochemical analyzer. The metabolite profiles of liver tissues and serum of rats were analyzed by HPLC-MS. Principal component analysis(PCA) and orthogonal partial least squares-discriminant analysis(OPLS-DA) were used to compare and analyze the metabolic data in the normal group, the hyperlipidemia group, and the ginsenoside Rb_1 group, and screen potential biomar-kers. The related metabolic pathways were further constructed by KEGG database analysis. The results showed that hyperlipemia induced dyslipidemia in rats, which was alleviated by ginsenoside Rb_1. The non-targeted metabolomics results showed that there were 297 differential metabolites in the liver tissues of hyperlipidemia rats, 294 differential metabolites in the serum samples, and 560 diffe-rential metabolites in the hyperlipidemia rats treated by ginsenoside Rb_1. Perillic acid and N-ornithyl-L-taurine were common metabolites in the liver and serum samples, which could be used as potential biomarkers for ginsenoside Rb_1 in the improvement of hyperlipidemia. As revealed by pathway enrichment in the liver and serum, ginsenoside Rb_1 could participate in the metabolic pathway of choline in both the liver and serum. In addition, ginsenoside Rb_1 also participated in the ABC transporter, alanine, aspartic acid, and glutamate metabolism, protein digestion and absorption, β-alanine metabolism, taurine and hypotaurine metabolism, caffeine metabolism, valine, leucine, and isoleucine biosynthesis, arachidonic acid metabolism, and methionine and cysteine metabolism to improve dyslipidemia in rats.
Rats
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Animals
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Hyperlipidemias/drug therapy*
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Metabolome
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Ginsenosides/metabolism*
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Lipid Metabolism
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Metabolomics/methods*
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Liver/metabolism*
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Biomarkers
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Taurine
8.Effect of light intensity on growth, accumulation of ginsenosides, and expression of related enzyme genes of Panax quinquefolius.
Zi-Qi LIU ; Yi WANG ; Xiu WANG ; Na PENG ; Shan-Shan YANG ; Hui-Hui SHAO ; Xiao-Lin JIAO ; Wei-Wei GAO
China Journal of Chinese Materia Medica 2022;47(18):4877-4885
Appropriate light intensity is favorable for the photosynthesis, biomass accumulation, key enzyme activity, and secondary metabolite synthesis of medicinal plants. This study aims to explore the influence of light intensity on growth and quality of Panax quinquefolius. To be specific, sand culture experiment was carried out in a greenhouse under the light intensity of 40, 80, 120, and 160 μmol·m~(-2)·s~(-1), respectively. The growth indexes, photosynthetic characteristics, content of 6 ginsenosides of the 3-year-old P. quinquefolius were determined, and the expression of ginsenoside synthesis-related enzyme genes in leaves, main roots, and fibrous roots was determined. The results showed that the P. quinquefolius growing at 80 μmol·m~(-2)·s~(-1) light intensity had the most biomass and the highest net photosynthetic rate. The total biomass of P. quinquefolius treated with 120 μmol·m~(-2)·s~(-1) light intensity was slightly lower than that with 80 μmol·m~(-2)·s~(-1). The root-to-shoot ratio in the treatment with 120 μmol·m~(-2)·s~(-1) light intensity was up to 6.86, higher than those in other treatments(P<0.05),and the ginsenoside content in both aboveground and underground parts of P. quinquefolius in this treatment was the highest, which was possibly associated with the high expression of farnesylpyrophosphate synthase(FPS), squalene synthase(SQS), squalene epoxidase(SQE), oxidosqualene cyclase(OSC), dammarenediol-Ⅱ synthase(DS), and P450 genes in leaves and SQE and DS genes in main roots. In addition, light intensities of 120 and 160 μmol·m~(-2)·s~(-1) could promote PPD-type ginsenoside synthesis in leaves by triggering up-regulation of the expression of upstream ginsenoside synthesis genes. The decrease in underground biomass accumulation of the P. quinquefolius grown under weak light(40 μmol·m~(-2)·s~(-1)) and strong light(160 μmol·m~(-2)·s~(-1)) was possibly attributed to the low net photosynthetic rate, stomatal conductance, and transpiration rate in leaves. In the meantime, the low expression of SQS, SQE, OSC, and DS genes in the main roots might led to the decrease in ginsenoside content. However, there was no significant correlation between the ginsenoside content and the expression of synthesis-related genes in the fibrous roots of P. quinquefolius. Therefore, the light intensity of 80 and 120 μmol·m~(-2)·s~(-1) is beneficial to improving yield and quality of P. quinquefolius. The above findings contributed to a theoretical basis for reasonable shading in P. quinquefolius cultivation, which is of great significance for improving the yield and quality of P. quinquefolius through light regulation.
Farnesyl-Diphosphate Farnesyltransferase/metabolism*
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Ginsenosides
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Panax/metabolism*
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Plant Roots/metabolism*
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Sand
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Squalene Monooxygenase
9.Purification of a ginsenoside-Rb1 hydrolase from Helix snailase.
Xin LIU ; Yu CUI ; Ling YANG ; Sheng-Li YANG
Chinese Journal of Biotechnology 2005;21(6):929-933
Through a combination of twice DEAE chromatography by NaCl stepwise and gradient elution with gel filtration chromatography, a kind of ginsenoside-Rb1 hydrolase from crude Helix snailase was separated. The hydrolase was purified to apparent homogeneity on SDS-PAGE. It was estimated that the purified hydrolase was consisted of four identical subunits with a molecular mass of 110-115 kD by SDS-PAGE and gel filtration chromatography. The Km and Vmax values for ginsenoside-Rb1 were calculated to be 0.790 mmol/L and 10.192 micromol/(min x mg) of protein respectively. The ginsenoside-Rb1 hydrolase could only hydrolyze the glycosidic bond at the C20 position of ginsenoside-Rb1 into ginsenoside-Rd.
Animals
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Catalysis
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Ginsenosides
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metabolism
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Helix (Snails)
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enzymology
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Hydrolases
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chemistry
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isolation & purification
;
metabolism
10.Effect of ginsenosides on level of sex hormone receptors in human liver cell line HL-7702.
Yong LI ; Da-li ZHANG ; Peng WANG
Chinese Journal of Integrated Traditional and Western Medicine 2009;29(12):1110-1113
OBJECTIVETo investigate the effect of ginsenoside (GSS) in regulating level of sex hormone receptors in human liver cell line HL-7702.
METHODSThe growth of HL-7702 were detected by MTT [3-(4,5-Dimethylthiazol-2-yl)-2,5-diphenyltetrazolium bromide] assay for choosing the available concentration of GSS; and the effect of GSS on sex hormone receptors in HL-7702 cells were detected by immuno-histochemistry, Western blot and RT-PCR.
RESULTSGSS significantly enhance the protein and mRNA expressions of estrogen receptor (ER), progesterone receptor (PR), androgen receptor (AR) in HL7702 cell in a dose-dependent manner, the levels of expressions in the GSS treated group were higher than those in the solvent control group respectively (P < 0.05).
CONCLUSIONGSS can up-regulate the protein and mRNA expressions of sex hormone receptors in HL-7702.
Cell Line ; Ginsenosides ; pharmacology ; Hepatocytes ; cytology ; drug effects ; metabolism ; Humans ; Receptors, Estrogen ; metabolism