Type Ginsenosides Research Articles

Characterization and protein engineering of a novel UDP-glycosyltransferase involved in pseudoginsenoside Rt5 biosynthesis from Panax japonicus

As one of rare high-value ocotillol (OCT)-type ginsenosides, pseudoginsenoside Rt5 has been identified with significant pharmacological activities. UDP-glycosyltransferases (UGTs) play pivotal roles in catalyzing the transfer of a glycosyl moiety from a donor to an acceptor. In this study, the novel UGT, PjUGT10, was screened from the transcriptome database of Panax japonicus and identified with the enzymatic activity of transferring a glucosyl group on OCT to produce Rt5. The catalytic efficiency of PjUGT10 was further enhanced by employing site-directed mutation. Notably, the variant M7 exhibited a remarkable 6.16 × 103-fold increase in kcat/Km towards 20S,24R-ocotillol and a significant 2.02 × 103-fold increase to UDP-glucose, respectively. Moreover, molecular dynamics simulations illustrated a reduced distance between 20S,24R-ocotillol and the catalytic residue His15 or UDP-glucose, favoring conformation interactions between the enzyme and substrates. Subsequently, Rt5 was synthesized in an engineered Escherichia coli strain M7 coupled with a UDP-glucose synthetic system. This study not only shed light on the protein engineering that can enhance the catalytic activity of PjUGT10, but also established a whole-cell approach for the production of Rt5.

Biotransformation of Ginsenoside Rb1 to Ginsenoside Rd and 7 Rare Ginsenosides Using Irpex lacteus with HPLC-HRMS/MS Identification.

The biotransformation of ginsenosides using microorganisms represents a promising and ecofriendly approach for the production of rare ginsenosides. The present study reports on the biotransformation of ginsenoside Rb1 using the fungus Irpex lacteus, resulting in the production of ginsenoside Rd and seven rare ginsenosides with novel structures. Employing high-performance liquid chromatography coupled with high-resolution tandem mass spectrometry, the identities of the transformation products were rapidly determined. Two sets of isomers with molecular weights of 980.56 and 962.55 were discovered among the seven rare ginsenosides, which were generated through the isomerization of the olefin chain in the protopanaxadiol (PPD)-type ginsenoside skeleton. Each isomer exhibited characteristic fragment ions and neutral loss patterns in their tandem mass spectra, providing evidence of their unique structures. Time-course experiments demonstrated that the transformation reaction reached equilibrium after 14 days, with Rb1 initially generating Rd and compound 5, followed by the formation of other rare ginsenosides. The biotransformation process catalyzed by I. lacteus was found to involve not only the typical deglycosylation reaction at the C-20 position but also hydroxylation at the C-22 and C-23 positions, as well as hydrogenation, transfer, and cyclization of the double bond at the C-24(25) position. These enzymatic capabilities extend to the structural modification of other PPD-type ginsenosides such as Rc and Rd, revealing the potential of I. lacteus for the production of a wider range of rare ginsenosides. The transformation activities observed in I. lacteus are unprecedented among fungal biotransformations of ginsenosides. This study highlights the application of a medicinal fungi-based biotransformation strategy for the generation of rare ginsenosides with enhanced structural diversity, thereby expanding the variety of bioactive compounds derived from ginseng.

Targeted preparation of six rare ginsenosides using two β-glucosidases from Bifidobacterium adolescentis

In this study, six rare protopanaxadiol (PPD)-type ginsenosides, namely, F2, CK, C-Mc1, C-Mc, CO, and CY, were prepared using enzymatic hydrolysis. Firstly, major (PPD)-type ginsenosides, including Rb1, Rb2, Rc, and Rd, were biotransformed by employing single and combined β-glucosidases BaBgl1A and BaBgl3A. Thin-layer chromatography (TLC) and high-performance liquid chromatography (HPLC) analyses revealed that ginsenosides F2, CO, and C-Mc1 could be produced by BaBgl1A, while rare ginsenosides CK, CY, and C-Mc could be produced by the combined use of BaBgl1A and BaBgl3A. Furthermore, optimal preparation conditions for these rare ginsenosides were elucidated, with yields exceeding 76.34%. Additionally, large quantities of rare ginsenosides were prepared to determine their structures. Characteristic absorption peaks in 13C NMR spectra and ion peaks in MALDI-TOF-MS suggested that the six high-purity rare ginsenosides (i.e., F2, CO and C-Mc1, CK, CY, and C-Mc) could be produced at high-efficiency. The findings of this study offer insights into novel enzymolysis methods for the targeted preparation of rare PPD-type ginsenosides, thus widening the range of raw materials that could be directed to in-depth biological activity research.

How to More Effectively Obtain Ginsenoside Rg5: Understanding Pathways of Conversion.

Ginsenoside Rg5, a relatively uncommon secondary ginsenoside, exhibits notable pharmacological activity and is commonly hypothesized to originate from the dehydration of Rg3. In this work, we compared different conversion pathways using Rb1, R-Rg3 and S-Rg3 as the raw material under simple acid catalysis. Interestingly, the results indicate that the conversion follows this reaction activity order Rb1 > S-Rg3 > R-Rg3, which is contrary to the common understanding of Rg5 obtained from Rg3 by dehydration. Our experimental results have been fully confirmed by theoretical calculations and a NOESY analysis. The DFT analysis reveals that the free energies of S-Rg3 and R-Rg3 in generating carbocation are 7.56 mol/L and 7.57 mol/L, respectively, which are significantly higher than the free energy of 1.81 mol/L when Rb1 generates the same carbocation. This finding aligns with experimental evidence suggesting that Rb1 is more prone to generating Rg5 than Rg3. The findings from the nuclear magnetic resonance (NMR) analysis suggest that the fatty chains (C22-C27) in R-Rg3 and S-Rg3 adopt a Gauche conformation and an anti conformation with C16-C17 and C13-C17, respectively, due to the relatively weak repulsive van der Waals force. Therefore, the configuration of R-Rg3 is more conducive to the formation of intramolecular hydrogen bonds between 20C-OH and 12C-OH, whereas S-Rg3 lacks this capability. Consequently, this also explains the fact that S-Rg3 is more prone to dehydration to generate Rg5 than R-Rg3. Additionally, our research reveals that the synthetic route of Rg5 derived from protopanaxadiol (PPD)-type ginsenosides (including Rb1, Rb2, Rb3, Rc and Rd) exhibits notable advantages in terms of efficacy, purity and yield when compared to the pathway originating from Rg3. Moreover, this study presents a highly effective and practical approach for the extensive synthesis of Rg5, thereby facilitating the exploration of its pharmacological properties and potential application in drug discovery.

Metabolome and transcriptome analyses identify the underground rhizome growth through the regulation of rhizome apices in Panax ginseng

Panax ginseng C. A. Mey. is a well-known oriental medicine as a stimulant and dietary supplement. The ginseng rhizome, as one of the principal medicinal organs, plays an important role in aboveground organ growth and root development, although no studies on ginseng rhizome growth have been recorded. In this study, we identified that shoot apical meristem (SAM) was included in the rhizome bud, which could regulate the underground rhizome growth of ginseng. In microscopic examination, ginseng SAM included the central zone, peripheral zone, rib zone, and organizing center; secondary root structures were observed in ginseng main roots and lateral roots; primary root structures were observed in ginseng fibrous roots; rhizome had a stem structure with pith and discontinuous cambium. The metabolites in different underground ginseng organs were identified using ultra-performance liquid chromatography-electrospray ionization-tandem mass spectrometry (UPLC-ESI-MS/MS), with oleanane (OA)-type ginsenosides accumulating primarily in the rhizome buds. In addition, ginseng rhizome buds contained a low level of 3-indoleacetonitrile (IAN, one type of auxin), a high amount of abscisic acid (ABA), and a high level of jasmonoyl-isoleucine (JA-Ile, active form of jasmonic acid). ABA and JA-Ile could drastically limit the shooting rate of ginseng embryonic calli, however IAN boosted the rooting rate. Furthermore, the expression of genes involved in ginsenoside biosynthesis, phytohormone production, and shoot stem cell regulatory pathways were studied. This is the first study of SAM in medicinal herbs, and we believe that the results may offer new information about the development of ginseng underground rhizomes.

Chemical profiling of Shengmai injection, tissue distribution and pharmacokinetic characteristics of ginsenosides after intravenous dosing Shengmai injection in rats with cerebral ischemia

Ethnopharmacological relevanceShengmai injection (SMI), consisting of Panax ginseng, Fructus schisandrae, and Radix ophiopogonis, has been widely used in the treatment of cardiovascular and cerebrovascular diseases. Aim of the studyThis study aimed to uncover the chemical profile of SMI, tissue distribution and pharmacokinetic characteristics of the main compounds after administration by combing UPLC-LTQ-Orbitrap-MS and UPLC-QQQ-MS. Materials and methodsUPLC-LTQ-Orbitrap-MS method was firstly established for the chemical profiling analysis of SMI. Then UPLC-QQQ-MS method was used to quantitatively analyze the contents of the main identified compounds in SMI and in the different tissues after intravenous dosing SMI in rats with cerebral ischemia. Finally, a new method was developed for the pharmacokinetic study of ginsenosides with considerable exposure. ResultsA total of 59 compounds were identified in SMI, including 25 ginsenosides, 25 lignans, four ophiopogon saponins, and five flavonoids. Among them, 26 compounds were confirmed by the standard substance. By UPLC-QQQ-MS, 23 chemical compounds were then quantitatively identified with their contents in SMI. Ginsenosides, as the main active compounds from Panax ginseng, showed the highest contents in SMI. Fifteen compounds including ginsenosides and Schisandrol were further found to have considerable exposure in different tissues. A rapid, sensitive, and specified method was then developed for simultaneously detecting the seven ginsenosides in the plasma and had good method validation. Pharmacokinetic evaluation showed that PPD type ginsenosides (Rd, Rb1, Rc) were all exhibited at higher levels of exposure in the plasma and had a much slower elimination rate, whereas PPT type ginsenosides (Re, Rg1, Rf, Rg2) underwent fast elimination. ConclusionThis study systematically revealed the ingredients of SMI and their tissue distribution. The pharmacokinetic characteristics of ginsenosides were also discovered. The findings provide a helpful reference for the pharmacological, toxicological, and clinical research on SMI.

Regulation of Nur77-TLR4/MyD88 signaling pathway is required for Ginsenoside Rc ameliorates hepatic fibrosis regression by deactivating hepatic stellate cells

HSCs (hepatic stellate cells) contribute to the excessive extracellular matrix (ECM) deposition plays a key role in the progression of hepatic fibrosis. The present study focused on the hepatoprotective effect of Ginsenoside Rc (Rc), one of the protopanaxadiol type ginsenoside, which has contributed to reverse activated HSCs to improve hepatic fibrosis via regulating Nur77-TLR4/MyD88 signaling pathway. We established the hepatic fibrosis model by intraperitoneal injection of carbon tetrachloride (CCl4). And HSCs were stimulated with TGF-β, followed by silencing of Nur77, and then incubated in Rc. Rc significantly alleviated histopathological changes, reduced serum alanine aminotransferase (ALT) and aspartate aminotransferase (AST) levels. Rc could upregulate the Nur77 and downregulate fibrosis markers in the liver of mice, including decreasing the expressions of α-SMA, Collagen-I, the ratio of TIMP-1/MMP-13. Rc significantly increased the expression of Nur77 and suppressed the production of ECM in HSCs. Rc inhibited TLR4 signaling pathway, consequently reversing the inflammatory response, including the production of MyD88, IRAK1, IRAK4 and IL-23. When Nur77 was knocked in TGF-β-stimulated HSCs, TLR4 and α-SMA production were increased. Rc suppressed these activatory effects in Nur77 knockdown HSCs. Rc reduced inflammatory reaction by regulating the Nur77-TLR4 signaling pathway while suppressing the fibrogenesis suggesting, underscoring a promising approach of Rc for the treatment in hepatic fibrosis. Targeting Nur77-TLR4 signaling in HSCs would be the potential strategy for Rc against hepatic fibrosis.

LED Light Irradiations Differentially Affect the Physiological Characteristics, Ginsenoside Content, and Expressions of Ginsenoside Biosynthetic Pathway Genes in Panax ginseng

Light is essential for plants and plays a vital role in their growth and development. Light irradiation affects the physiological characteristics and synthesis of secondary metabolites in plants. As a semi-shade perennial plant, Panax ginseng C.A. Mey. is sensitive to changes in the light environment. Different light irradiations significantly affect the secondary metabolic processes of P. ginseng. However, few studies have investigated the changes in ginsenoside content in P. ginseng under different light irradiation conditions. In this study, 3-year-old P. ginseng was cultured under white (CK) light, blue (B) light, red (R) light, green (G) light, and natural light (NL) to explore the effects of light irradiation on the physiological characteristics and ginsenoside secondary metabolism of P. ginseng. The B and CK treatments significantly increased the photosynthetic level in P. ginseng leaves. The total saponin content under blue and red light treatments increased by 28.81% and 21.64%, respectively, compared with the CK treatment. Blue and red light improved the transcription levels of ginsenoside biosynthetic pathway genes. Blue light upregulated the expression of HMGR, SS, SE, DS, CYP716A52, and CYP716A47, and the expression of HMGR, SS, SE, DS, and CYP716A47 under red light treatment was significantly upregulated in P. ginseng roots. Principal component and correlation analyses revealed that the physiological and ecological processes of P. ginseng exhibited different responses to light irradiation. The total saponin content in the roots was positively correlated with the content of protopanaxatriol -type ginsenosides and water use efficiency in leaves. Our study indicates that light conditions can be improved by blue and red light or by blue and red film covering to facilitate the accumulation of saponin during the ecological cultivation of P. ginseng.

Fusion of Michael-acceptors enhances the anti-inflammatory activity of ginsenosides as potential modulators of the NLRP3 signaling pathway

Ginsenosides are a promising group of secondary metabolites for developing anti-inflammatory agents. In this study, Michael acceptor was fused into the aglycone A-ring of protopanoxadiol (PPD)-type ginsenosides (MAAG), the main pharmacophore of ginseng, and its liver metabolites to produce novel derivatives and assess their anti-inflammatory activity in vitro. The structure–activity relationship of MAAG derivatives was assessed based on their NO-inhibition activities. Of these, a 4-nitrobenzylidene derivative of PPD (2a) was the most effective and dose-dependently inhibited the release of proinflammatory cytokines. Further studies indicated that 2a-induced downregulation on lipopolysaccharide (LPS)-induced iNOS protein expression and cytokine release may be related to its inhibitory effect on MAPK and NF-κB signaling pathways. Importantly, 2a almost completely inhibited LPS-induced production of mitochondrial reactive oxygen species (mtROS) and LPS-induced NLRP3 upregulation. This inhibition was higher than that by hydrocortisone sodium succinate, a glucocorticoid drug. Overall, the fusion of Michael acceptors into the aglycone of ginsenosides greatly enhanced the anti-inflammatory activities of the derivatives, and 2a alleviated inflammation considerably. These findings could be attributed to the inhibition of LPS-induced mtROS to block abnormal activation of the NLRP3 pathway.

Comparison of Phytochemical Profiles of Wild and Cultivated American Ginseng Using Metabolomics by Ultra-High Performance Liquid Chromatography-High-Resolution Mass Spectrometry

American ginseng (Panax quinquefolius L.) has been recognized as a valuable herb medicine, and ginsenosides are the most important components responsible for the health-beneficial effects. This study investigated the secondary metabolites responsible for the differentiation of wild and cultivated American ginsengs with ultrahigh-performance liquid chromatography-high resolution mass spectrometry (UHPLC-HRMS)-based metabolomic approach. An in-house ginsenoside library was developed to facilitate data processing and metabolite identification. Data visualization methods, such as heatmaps and volcano plots, were utilized to extract discriminated ion features. The results suggested that the ginsenoside profiles of wild and cultivated ginsengs were significantly different. The octillol (OT)-type ginsenosides were present in greater abundance and diversity in wild American ginsengs; however, a wider distribution of the protopanaxadiol (PPD)-and oleanolic acid (OA)-type ginsenosides were found in cultivated American ginseng. Based on the tentative identification and semi-quantification, the amounts of five ginsenosides (i.e., notoginsenoside H, glucoginsenoside Rf, notoginsenoside R1, pseudoginsenoside RT2, and ginsenoside Rc) were 2.3-54.5 fold greater in wild ginseng in comparison to those in their cultivated counterparts, and the content of six ginsenosides (chicusetsusaponin IVa, malonylginsenoside Rd, pseudoginsenoside Rc1, malonylfloralginsenoside Rd6, Ginsenoside Rd, and malonylginsenoside Rb1) was 2.6-14.4 fold greater in cultivated ginseng compared to wild ginseng. The results suggested that the in-house metabolite library can significantly reduce the complexity of the data processing for ginseng samples, and UHPLC-HRMS is effective and robust for identifying characteristic components (marker compounds) for distinguishing wild and cultivated American ginseng.

Specific and efficient hydrolysis of all outer glucosyls in protopanaxadiol type and protopanaxatriol type ginsenosides by a β-glucosidase from Thermoclostridium stercorarium

To develop a new method for enzymatic preparation of minor ginsenosides, T. stercorarium β-glucosidase (Tsbgl) was characterized and its activities of deglycosylation towards natural ginsenosides were examined. The substrates of 1 mmol l−1 were incubated with the enzyme of 38.3 U ml−1 at 65 ℃ and pH 5.0. The Km values of Tsbgl for ginsenosides Rb1, Rg1 and pNPG were 0.37 ± 0.03, 3.26 ± 0.19, and 1.24 ± 0.03 mmol l−1, and the Vmax values were 183.63 ± 7.15, 85.03 ± 4.90, and 117.66 ± 1.96 μmol mg−1 min−1, respectively. The molar conversion of ginsenosides Rb1, Rb2, Rb3, Rc, Re, Rg1, and Rf by Tsbgl within 6 h was 100%, 50.1%, 42.7%, 92.0%, 57.3%, 67.9%, and 76.8%, respectively. The yield of aglycone protopanaxadiol was 35.5 μmol l−1 h−1 for Rb1, while the yields of aglycone protopanaxatriol were 64.2 and 70.4 μmol l−1 h−1 for Rg1 and Rf. Tsbgl with good organic solvent tolerance, mild reaction conditions and broad substrate specificity, could completely remove all outer glucosyls at the C-3 and C-20 hydroxyls of protopanaxadiol-type ginsenosides, and the C-6 and C-20 hydroxyls of protopanaxatriol-type ginsenosides through various pathways, providing a specific and efficient way to produce minor ginsenosides.

Cloning and characterization of thermophilic endoglucanase and its application in the transformation of ginsenosides

A novel endoglucanase (BcelFp) was identified from Fervidobaterium pennivorans DSM9078 which had biotransformation activity for protopanaxadiol (PPD)-type ginsenosides. Sequence analysis of BcelFp revealed that it could be classified into glycoside hydrolase family 5 (GH5). The gene encoding a 323-amino acid protein was cloned and expressed in Escherichia coli. The recombinant enzyme was purified, and its molecular weight was approximate 37 kDa. The recombinant BcelFp exhibited an optimal activity at 95 oC and pH 5.5 and showed high thermostability. The endoglucanase had high selectivity for cleaving the outer glucose moiety at the C3 carbon of ginsenoside Rb1, Rb2, Rc and Rd, which produced stronger pharmacologically active gypenoside XVII (GypXVII), Compound O (CO), Compound Mc1 (CMc1) and F2, respectively. The Km values for Rb1, Rb2, Rc and Rd were 3.66 ± 0.04 µM, 4.02 ± 0.12 µM, 5.95 ± 0.03 µM, 0.67 ± 0.006 µM, respectively. The kcat/Km value of BcelFp for ginsenoside Rd was 27.91 mM-1s-1, which was much higher than that of the previously enzymes. This study was the first report of the highly efficient and selective transformation of GypXVII, CO, CMc1 and F2 from Rb1, Rb2, Rc and Rd by a GH5-family thermophilic endoglucanase.

Ultrahigh-performance liquid chromatography coupled to ion mobility quadrupole time-of-flight mass spectrometry profiling and unveiling the transformation of ginsenosides by the dual conditions of citric acid and high-pressure steaming.

Many methods have been reported for the production of rare ginsenosides, including heat treatment, acid hydrolysis, alkaline hydrolysis, enzymatic hydrolysis, and microbial transformation. However, the conversion of original ginsenosides to rare ginsenosides under the dual conditions of citric acid and high-pressure steam sterilization has rarely been reported. In this study, a method involving ultrahigh-performance liquid chromatography coupled to ion mobility quadrupole time-of-flight mass spectrometry was developed for analysis of chemical transformation of protopanaxatriol (PPT)-type ginsenosides Rg1 and Re, protopanaxadiol (PPD)-type ginsenoside Rb1 , and total ginsenosides in the dual conditions of citric acid and high-pressure steam sterilization. An internal ginsenoside database containing 126 known ginsenosides and 18 ginsenoside reference compounds was established to identify the transformation products and explore possible transformation pathways and mechanisms. A total of 54 ginsenosides have been preliminarily identified in the transformation products of PPD-type ginsenosides Rg1 and Re, PPD-type ginsenoside Rb1 , and total ginsenosides, and the possible transformation pathways were as follows: Rg1 , Re → 20(S)-Rh12 , 20(R)-Rh12 ; Rg1 , Re → 20(S)-Rh1 , 20(R)-Rh1 → Rk3 , Rh4 , Rh5 ; Rb1 → gypenoside LXXV; Rb1 → 20(S)-Rg3 , 20(R)-Rg3 → Rk1 , Rg5 ; Re → 20(S)-Rg2 , 20(R)-Rg2 → 20(S)-Rf2 , 20(R)-Rf2 , Rg4 , F4 . The results elucidated the possible transformation pathways and mechanisms of ginsenosides in the dual conditions of citric acid and high-pressure steam sterilization, which were helpful for revealing the mechanisms of ginsenosides and enhanced safety and quality control of pharmaceuticals and nutraceuticals. Meanwhile, a simple, efficient, and practical method was developed for the production of rare ginsenosides, which has the potential to produce diverse rare ginsenosides on an industrial scale.

In Vitro Biotransformation of Total Glycosides in Qiwei Baizhu Powder by the Gut Microbiota of Normal and Diarrheal Mice: Novel Insight Into the Biotransformation of Multi-Glycosides by the Gut Microbiota.

The gut microbiota (GM) is involved in the metabolism of glycosides and is beneficial for enhancing their bioactivity. However, the metabolism of multi-glycosides by the GM under normal and pathological conditions is unclear. In this study, the total glycosides (TG) of the traditional Chinese medicine (TCM) formula Qiwei Baizhu Powder (QWBZP) were extracted to represent a multi-glycoside system. Ultra-high-performance liquid chromatography quadrupole time-of-flight tandem mass spectrometry (UHPLC-Q-TOF-MS/MS) was used to rapidly identify the components and in vitro metabolites of QWBZP-TG. The metabolic profiles of QWBZP-TG in the GM of normal and diarrheal mice were also compared. A total of 68 compounds and seven metabolites were identified in the QWBZP-TG and metabolic samples, respectively. Deglycosylation was the main metabolic pathway of in vitro multi-glycoside metabolism. Liquiritin apioside, isoliquiritin apioside, liquiritin, protopanaxadiol (PPD)-type, and oleanane (OLE)-type ginsenosides were relatively easy to metabolize by the GM. At first, the deglycosylation capability of the GM of normal mice was superior to that of diarrheal mice, but the deglycosylation capability of diarrheal mice gradually recovered and produced abundant deglycosylation metabolites. In conclusion, deglycosylation metabolites may be the bioactive components of QWBZP. Glycoside-bacteria interaction may be a key mechanism for QWBZP to therapy diarrhea.

Insights into Recent Studies on Biotransformation and Pharmacological Activities of Ginsenoside Rd.

It is well known that ginsenosides—major bioactive constituents of Panax ginseng—are attracting more attention due to their beneficial pharmacological activities. Ginsenoside Rd, belonging to protopanaxadiol (PPD)-type ginsenosides, exhibits diverse and powerful pharmacological activities. In recent decades, nearly 300 studies on the pharmacological activities of Rd—as a potential treatment for a variety of diseases—have been published. However, no specific, comprehensive reviews have been documented to date. The present review not only summarizes the in vitro and in vivo studies on the health benefits of Rd, including anti-cancer, anti-diabetic, anti-inflammatory, neuroprotective, cardioprotective, ischemic stroke, immunoregulation, and other pharmacological effects, it also delves into the inclusion of potential molecular mechanisms, providing an overview of future prospects for the use of Rd in the treatment of chronic metabolic diseases and neurodegenerative disorders. Although biotransformation, pharmacokinetics, and clinical studies of Rd have also been reviewed, clinical trial data of Rd are limited; the only data available are for its treatment of acute ischemic stroke. Therefore, clinical evidence of Rd should be considered in future studies.

In Vitro Transformation of Protopanaxadiol Saponins in Human Intestinal Flora and Its Effect on Intestinal Flora.

Protopanaxadiol (PPD)-type ginsenosides are the main ginsenosides in ginseng (Panax ginseng C. A. Meyer) with potential therapeutic effects on diseases related to intestinal flora imbalance. This study aimed to investigate the in vitro metabolism of protopanaxadiol ginsenosides in human intestinal flora and their effect on the flora. Rapid resolution liquid chromatography coupled with quadruple-time-of-flight mass spectrometry (RRLC-Q-TOF MS) was utilised for the transformation of ginsenoside constituents for sample identification. Using 16S rDNA gene sequencing technique, the effect of PPD-type ginsenosides on gut microflora was analysed based on the indices of microflora diversity and gut microflora. The sample was transformed for 6 h, and the metabolites were ginsenoside Rb1, Rc, Rb2, Rb3, CO, Gyp-IX, Gyp-XVII, CMc-1, F2, Rg3, CK, Rh2, and PPD. The metabolites were CK, Rh2, and PPD when the samples were transformed for 60 h. The intestinal microflora were subjected to high-throughput sequencing using the Illumina MiSeq 2500 sequencing platform. In comparison with the faecal sample from the blank group, the protopanaxadiol saponin group significantly increased the relative abundance of Firmicutes and significantly decreased Bacteroidetes and Proteobacteria at the phylum level, whereas it significantly increased the relative abundance of Prevotella_9, Faecalibacterium, and Dialister and significantly decreased Escherichia-Shigella, Dorea, and Lachnoclostridium at the genus level. This study provides a basis for the determination of the pharmacodynamic material basis and pharmacodynamic targets of PPD-type ginsenosides based on the intestinal flora.

Single site mutations of glycosyltransferase with improved activity and regioselectivity for directed biosynthesis of unnatural protopanaxatriol-type ginsenoside product

Protopanaxatriol (PPT)-type ginsenosides are functional components in Panax species and exhibit diverse significant bioactivities. Glycosyltransferase Bs-YjiC from Bacillus subtilis 168 has been demonstrated to generate ginsenoside Rh1 and several unnatural PPT-type ginsenosides. However, the glycodiversification of ginsenosides and poor regioselectivity of glycosyltransferase might hamper the low-cost synthesis process of the desired product. The semi-rational design of Bs-YjiC is newly performed by structure-based guidance, and the small change of Bs-YjiC could target both activity improvement and regioselectivity enhancement. The created mutant F168M has 5.24 times of specific activity compared with WT and the increased conversion of 95.56% for PPT, and shows significantly improved regioselectivity of 87.28% for unnatural ginsenoside of 3-O-β-D-glucopyranosyl-12-O-β-D-glucopyranosyl-20(S)-protopanaxatriol, which is 8.83 times of the wild type (9.88%). The coupled catalytic strategy of mutant F168M and sucrose synthase AtSuSy (from Arabidopsis thaliana) is used for efficient regeneration of UDP-glucose, and unnatural PPT-type ginsenoside could reach a high titer of 8.66 g/L (regioselectivity 90.42%) in a fed-batch mode, which is 99 times of that by wild type (0.088 g/L). It represents the highest level of production reported to date, and achieves a maximum number of UDP-glucose regeneration cycles (RcMax = 39.92). This study exploits an effective biocatalyst for unnatural ginsenoside, thus facilitating study and medical application.

Ginsenoside compound K ameliorates palmitate-induced atrophy in C2C12 myotubes via promyogenic effects and AMPK/autophagy-mediated suppression of endoplasmic reticulum stress

BackgroundCompound K (CK) is among the protopanaxadiol (PPD)-type ginsenoside group, which produces multiple pharmacological effects. Herein, we examined the effects of CK on muscle atrophy under hyperlipidemic conditions along with its pro-myogenic effects. Further, the molecular pathways underlying the effects of CK on skeletal muscle have been justified. MethodsC2C12 myotubes were treated with palmitate and CK. C2C12 myoblasts were differentiated using CK for 4–5 days. For the in vivo experiments, CK was administered to mice fed on a high-fat diet for 8 weeks. The protein expression levels were analyzed using western blotting analysis. Target protein suppression was performed using small interfering (si) RNA transfection. Histological examination was performed using Jenner-Giemsa and H&E staining techniques. ResultsCK treatment attenuated ER stress markers, such as eIF2α phosphorylation and CHOP expression and impaired myotube formation in palmitate-treated C2C12 myotubes and skeletal muscle of mice fed on HFD. CK treatment augmented AMPK along with autophagy markers in skeletal muscle cells in vitro and in vivo experiments. AMPK siRNA or 3-MA, an autophagy inhibitor, abrogated the impacts of CK in C2C12 myotubes. CK treatment augmented p38 and Akt phosphorylation, leading to an enhancement of C2C12 myogenesis. However, AMPK siRNA abolished the effects of CK in C2C12 myoblasts. ConclusionThese findings denote that CK prevents lipid-induced skeletal muscle apoptosis via AMPK/autophagy-mediated attenuation of ER stress and induction of myoblast differentiation. Therefore, we may suggest the use of CK as a potential therapeutic approach for treating muscle-wasting conditions associated with obesity.

Research progress on naturally-occurring and semi-synthetic ocotillol-type ginsenosides in the genus Panax L. (Araliaceae).

Ocotillol (OT)-type ginsenosides, one subtype of ginsenosides, consist of a dammarane skeleton and a tetrahydrofuran ring. Most naturally-occurring OT-type ginsenosides exist in Panax species, particularly in Panax quinquefolius, which may be attributed to the warm and humid climate of its native areas. Till now, merely 28 types of naturally-occurring OT-type ginsenosides have been isolated. In contrast, semi-synthesized OT-type ginsenosides are attracted considerable attentions. These ginsenosides can be obtained through oxidation and cyclization of side chains of dammarane-type ginsenosides, and other methods, which may change their physical and chemical properties and further improve their bioavailabilities. It is also notable that the pharmacological activities of ginsenosides are closely related to the stereoisomers caused by the configuration at C-20. Semi-synthesis of OT-type ginsenosides can facilitate our understanding of the biosynthesis, transformation and metabolism of OT-type ginsenosides in the body. This review will systematically summarize the research progress on naturally-occurring and semi-synthetic OT-type ginsenosides, which provides a theoretical basis for their bioactivity-guided research.

Qualitatively and quantitatively investigating the metabolism of 20(S)-protopanaxadiol-type ginsenosides by gut microbiota of different species.

Ginsenosides Rb1, Rb2, Rb3 and Rc, four major protopanaxadiol (PPD)-type ginsenosides, can be metabolized by gut microbiota. The composition of gut microbiota varies in different species. Existing publications have reported the metabolite fates of ginsenosides by gut microbiota from single species. However, their microbiota-related metabolic species differences have not been evaluated yet. In current study, in vitro anaerobic incubations of PPD-type ginsenosides with gut microbiota from humans, rabbits and rats were conducted. The metabolites of each ginsenoside were then identified by LC-MS. A total of 15 metabolites from the four ginsenosides were identified. The major metabolic pathways were stepwise removals of the C-20 and C-3 sugar moieties to obtain aglycone PPD. The results showed that the hydrolysis rate of C-20 terminal β-D-glucopyranosyl was significantly higher than those of α-L-arabinopyranosyl, β-D-xylopyranosyl and α-L-arabinofuranosyl in different species. The activity of β-glucosidase, the metabolic rates of parent compounds and the formation rates of their metabolites were significantly higher in gut microbiota from rabbits than from humans and rats. Our research draws researchers' attention to the species differences of microbiota-related drug metabolism.