Introduction
Panax ginseng (Araliaceae) is a traditional medicinal plant that has been used therapeutically for thousands of years in East Asia. The name “Panax” means “all healing” or “all cure”, which describes the traditional belief that ginseng can heal all aspects of the body.1 The name “ginseng” is derived from Chinese word “Jin-chen”, meaning human body-shaped root.2 Ginseng, notably the root of P. ginseng, is the most valuable of all medicinal plants in Korea, China, and Japan.3,4 Ginseng can be commonly classified into Korean ginseng (P. ginseng), Chinese ginseng (P. notoginseng), and American ginseng (P. quinquefolium).5
Ginseng has been used as an adaptogenic agent and is known to have a positive effect on inflammation and aging, immune-modulating functions, the central nervous system, cardiovascular system, diabetes, and cancer, as well as having antioxidant, hypotensive, antitumor, cognitive, sedative, and analgesic benefits.6-12 Saponins are the major constituents of ginseng.13-15 To date, approximately 70 kinds of saponins have been isolated from ginseng and named as ginsenosides. Most of the aglycone moieties of ginsenosides are protopanaxadiol (PPD) and protopanaxatriol (PPT).16-17 The algycone of ginsenoside Ro is an oleanolic acid.18,19
As part of a continued chemical investigation of ginseng, the focus of this research is on the isolation and identification of compounds from ginseng by open column chromatography (CC), medium pressure liquid chromatography (MPLC), semi-preparative-high performance liquid chromatography (SemiPrep-HPLC), fast atom bombardment mass spectrometry (FAB-MS), and nuclear magnetic resonance (NMR).
Experimental
Plant materials − Dried and powdered white ginseng (P. ginseng) collected from Geumsan (2010), was supplied by Korea Food Research Institute, Sungnam, Republic of Korea.
Reagents and instruments − Solvents such as ethanol (EtOH), n-hexane, chloroform (CHCl3), ethyl acetate (EtOAc), and n-butanol (n-BuOH) (SamChun Pure Chemical Co., Pyeongtaek, Korea) were used in the MPLC mobile phase. HPLC-grade acetonitrile (ACN) and water were purchased from J.T. Baker (Phillipsburg, NJ, USA). Pyridine was used as NMR solution. All other solvents were analytical grade. EI-MS was conducted with a Jeol JMS-600W (Tokyo, Japan) mass spectrometer, and FAB-MS was performed with a Jeol JMS-AX505WA mass spectrometer. 1H- and 13C-NMR spectra were recorded with a Bruker AVANCE 500 NMR (Bremen, Germany) spectrometer using tetramethyl silane (TMS) as the internal standard. Chemical shifts are reported in parts per million (δ), and coupling constants (J) are expressed in Hertz. An Eyela rotary evaporator system (Tokyo, Japan) under reflux in vacuo was used for evaporation. Thin layer chromatography (TLC) was conducted with Kiesel gel 60 F254 (Art. 5715, Merck Co., Darmstadt, Germany) plates (silica gel, 0.25mm layer thickness), and compounds were visualized by spraying with 10% H2SO4 in methanol (MeOH), followed by heating to 100 ℃. CC was conducted with a LiChroprep RP-18 (40 - 63 μm, Merck Co., Germany) and Sephadex LH-20 (100 - 100G; Sigma-Aldrich Co., USA). MPLC (Biotage, Uppsala, Sweden) equipped with cartridges (KP-SIL, 39 × 225 mm) was used. SemiPrep-HPLC was carried out on an Agilent series 1260 separation system (Santa Clara, CA, USA) with fraction collector, 1260 Quat pump VL, a 1260 Variable Wavelength Detector, and an Eclipse XDB-C18 SemiPreparative column (5 μm, 150 × 9.4 mm), at an elution flow rate of 1.0 mL/min. Gas chromatography (GC) (HP 5890 series II, Hewlett-Packard, Avondale, PA) using a HP-5 capillary column (30 m × 0.32 mm i.d., 0.25 μm film thickness; Agilent, J&W Scientific, Folsom, CA) [column temperature: 230 ℃; detector temperature: 200℃; injector temperature: 200 ℃; He gas flow rate: 1 mL/min] was used for sugar determination.
Extraction and isolation − Dried and powdered white ginseng (7.0 kg) was extracted with EtOH (21 L × 3) under reflux, and the extracts were combined and evaporated, leaving a brown residue (139 g). The residue was dissolved in water (7 L) and partitioned successively with n-hexane (7 L × 3), CHCl3 (7 L × 3), EtOAc (7 L × 3), and n-BuOH (7 L × 3) to give the n-hexane (50 g), CHCl3 (11 g), EtOAc (11 g), and n-BuOH (50 g) fractions. The n-BuOH fraction of white ginseng (WGB) was subjected to MPLC eluted with a CHCl3/MeOH gradient (100:0 → 0:100). Fractions were combined according to their TLC behavior in order to obtain 13 fractions (WGB 1 →WGB 13). Fraction WGB 2 (2 g, Ve/Vt = 0.11, where Ve refers to the volume of eluent for the corresponding fraction and Vt represents the total elution volume) was repeatedly chromatographed on an MPLC eluted with CHCl3/MeOH (80:20 → 0:100) eluent (1,408 mL) to obtain 5 fractions (WGB 2.1 - 2.5). WGB 2.5 (1.1 g, Ve/Vt = 0.47) was separated a LiChroprep RP18 column (φ 1.0 × 32 cm) eluted with MeOH/water (1:3→1:0) eluent (2,370 mL) to obtain 7 fractions (WGB 2.5.1 - 2.5.7). WGB 2.5.4 (70 mg, Ve/Vt = 0.01) was further fractionated by SemiPrep-HPLC eluted with ACN/water (20:80 →0:100) to yield 9 additional fractions (WGB 2.5.4.1 - 2.5.4.9) including compound 8 (WGB 2.5.4.7, 3 mg) (Table 2). WGB 2.5.3 (100 mg, Ve/Vt = 0.01) was separated a LiChroprep RP18 column (φ 1.0 × 32 cm) eluted with MeOH/water (1:2 →1:0) to yield 4 additional fractions (WGB 2.5.3.1 - 2.5.3.4) including compound 12 (WGB 2.5.3.2, 3 mg). Fraction WGB 4 (8 g, Ve/Vt = 0.15) was repeatedly chromatographed on an MPLC eluted with CHCl3/MeOH (100:0 → 0:100) eluent (1,254 mL) to obtain 7 fractions (WGB 4.1 - 4.7). WGB 4-4 (250 mg, Ve/Vt = 0.05) was separated a LiChroprep RP18 column (φ 1.0 × 32 cm) eluted with MeOH/water (1:2 → 1:0) eluent (286 mL) to obtain 13 fractions (WGB 4.4.1 - 4.4.13). WGB 4-4-9 (180 mg, Ve/Vt = 0.08) was separated a LiChroprep RP18 column (φ 1.0 × 32 cm) eluted with MeOH/water (1:3 → 1:0) eluent (462mL) to obtain 21 fractions (WGB 4.4.9.1 - 4.4.9.21). WGB 4.4.9.5 (70 mg, Ve/Vt = 0.01) was further fractionated by SemiPrep-HPLC eluted with ACN/water (20:80 → 0:100) to yield 9 additional fractions (WGB 4.4.9.5.1 - 4.4.9.5.8) including compound 14 (WGB 4.4.9.5.2, 3 mg). The combined fractions (WGB 4.5, 4.6 and 4.7; 3 g, Ve/Vt = 0.42) were separated on an MPLC eluted with CHCl3/MeOH (90:10 → 0:100) eluent (748 mL) to obtain 6 fractions (WGB 4.5.1 - 4.5.6). WGB 4.5.6 (350 mg, Ve/Vt = 0.15) was separated a Sephadex LH-20 column (φ 1.0 × 32 cm) eluted with 70% MeOH eluent (580 mL) to obtain 3 fractions (WGB 4.5.6.1 - 4.5.6.3). WGB 4.5.6.2 (50mg, Ve/Vt = 0.66) was separated a LiChroprep RP18 column (φ 1.0 × 32 cm) eluted with MeOH/water (1:3 → 1:0) eluent (420 mL) to obtain 10 fractions (WGB 4.5.6.2.1 - 4.5.6.2.10) including compound 1 (WGB 4.5.6.2.10, 2.5 mg). WGB 4.5.2 (920 mg, Ve/Vt = 0.12) was separated on an MPLC eluted with CHCl3/MeOH (75:25 → 100:0) eluent (2,948 mL) to obtain 6 fractions (WGB 4.5.2.1 - 4.5.2.6). WGB 4.5.2.6 (340 mg, Ve/Vt = 0.57) was separated a LiChroprep RP18 column (φ 1.0 × 32 cm) eluted with MeOH/water (1:3 → 1:0) to yield 6 additional fractions (WGB 4.5.2.6.1 - 4.5.2.6.6) including compound 11 (WGB 4.5.2.6.2, 2.5 mg). WGB 4.4 (0.5 g, Ve/Vt = 0.1) was separated a LiChroprep RP18 column (φ 1.0 × 32 cm) eluted with MeOH/water (1:2 → 1:0) eluent (286 mL) to obtain 13 fractions (WGB 4.4.1 - 4.4.13) including compounds 16 (WGB 4.4.7, 10 mg) and 17 (WGB 4.4.9, 2 mg). WGB 4.4.11 (30 mg, Ve/Vt = 0.12) was further fractionated by LiChroprep RP18 column (φ 1.0 × 32 cm) to yield 5 additional fractions (WGB 4.4.11.1 - 4.4.11.5) including compound 19 (WGB 4.4.11.2, 1 mg). Fraction WGB 5 (8 g, Ve/Vt = 0.15) was repeatedly chromatographed on an MPLC eluted with CHCl3/MeOH (100:0 → 0:100) eluent (2,222 mL) to obtain 9 fractions (WGB 5.1 - 5.9). WGB 5.3 (100 mg, Ve/Vt = 0.04) was further fractionated by SemiPrep-HPLC eluted with ACN/water (20:80 →0:100) to yield 3 additional fractions (WGB 5.3.1 - 5.3.3) including compound 18 (WGB 5.3.3, 3 mg) (Table 2). WGB 5.6 (450 mg, Ve/Vt = 0.09) was repeatedly chromatographed on an MPLC eluted with CHCl3/MeOH (80:20 →70:30) eluent (1,892 mL) to obtain 9 fractions (WGB 5.6.1 - 5.6.9). WGB 5.6.4 (220 mg, Ve/Vt = 0.12) was separated a LiChroprep RP18 column (φ 1.0 × 32 cm) eluted with MeOH/water (1:3 → 1:0) to yield 7 additional fractions (WGB 5.6.4.1 - 5.6.4.7). WGB 5.6.4.4 (450 mg, Ve/Vt = 0.09) was repeatedly chromatographed on an MPLC eluted with CHCl3/MeOH (80:20 → 70:30) to obtain 6 fractions (WGB 5.6.4.4.1 - 5.6.4.4.6) including compounds 21 (WGB 5-6-4-4-3, 2.5 mg). WGB 5.8 (3.1 g, Ve/Vt = 0.24) was further chromatographed on an MPLC eluted with CHCl3/MeOH (80:20 →0:100) eluent (3,960 mL) to obtain 7 additional fractions (WGB 5.8.1 - 5.8.7) including compounds 3 (WGB 5.8.6, 4.5 mg) and 7 (WGB 5.8.4, 2.5 mg). WGB 5.8.5 (1.3 g, Ve/Vt = 0.17) was chromatographed on an MPLC eluted with CHCl3/MeOH (80:20→ 60:40) eluent (3,080 mL) to obtain 4 additional fractions (WGB 5.8.5.1 - 5.8.5.4) including compound 5 (WGB 5.8.5.4, 10.5 mg). WGB 5.8.5.2 (105 mg, Ve/Vt = 0.16) was separated a LiChroprep RP18 column (φ 1.0 × 32 cm) eluted with MeOH/water (1:3 → 1:0) to yield 11 additional fractions (WGB 5.8.5.2.1 - 5.8.5.2.11) including compounds 6 (WGB 5.8.5.2.10, 12.5 mg), 13 (WGB 5.8.5.2.4, 25.5 mg), and 15 (WGB 5.8.5.2.8, 12.5 mg). WGB 5.8.7 (24 mg, Ve/Vt = 0.15) was separated a LiChroprep RP18 column (φ 1.0 × 32 cm) eluted with MeOH/water (1:3 → 1:0) to yield 9 additional fractions (WGB 5.8.7.1 - 5.8.7.9) including compound 10 (WGB 5.8.7.8, 2.1 mg). Fraction 10 (7 g) was repeatedly chromatographed on an MPLC eluted with CHCl3/MeOH (100:0 → 0:100) eluent (3,300 mL) to obtain 5 fractions (WGB 10.1 - 10.5). WGB 10.5 (2.7 g, Ve/Vt = 0.47) was chromatographed on an MPLC eluted with CHCl3/MeOH (70:30 →0:100) eluent (1,694 mL) to obtain 5 additional fractions (WGB 10.5.1 - 10.5.5) including compound 2 (WGB 10.5.2, 4.5 mg). The combined fractions (WGB 10.5.3 and 10.5.4; 2.7 g, Ve/Vt = 0.47) were chromatographed on an MPLC eluted with CHCl3/MeOH (45:55→ 0:100) eluent (5,280 mL) to obtain 5 additional fractions (WGB 10.5.3.1 - 10.5.3.5) including compound 4 (WGB 10.5.3.2, 3.5 mg). WGB 10.5.3.5 (420 mg, Ve/Vt = 0.63) was separated a LiChroprep RP18 column (φ 1.0 × 32 cm) eluted with MeOH/water (1:3 → 1:0) to yield 11 additional fractions (WGB 10.5.3.5.1 - 10.5.3.5.11) including compound 20 (WGB 4.5.2.6.2, 1.2 mg). Fraction WGB 11 (3 g, Ve/Vt = 0.11) was separated a Sephadex LH-20 column (φ 2.0 × 32 cm) eluted with MeOH/water (1:3 → 1:0) eluent (418 mL) to obtain 4 fractions (WGB 11.1 - 11.4). WGB 11.2 (520 mg, Ve/Vt = 0.42) was separated a LiChroprep RP18 column (φ 1.0 × 32 cm) eluted with MeOH/water (1:1 → 1:0) to yield 4 fractions (WGB 11.2.1 - 11.2.4). WGB 11.2.4 (370 mg, Ve/Vt = 0.14) was separated a LiChroprep RP18 column (φ 1.0 × 32 cm) eluted with MeOH/water (1:3 → 1:0) to yield 7 additional fractions (WGB 11.2.4.1 - 11.2.4.7) including compound 9 (WGB 11.2.4.7, 1.5 mg).
Fig. 1.Chemical structures of PPD types.
Fig. 2.Chemical structures of PPT types.
Fig. 3.Chemical structures of oleanene types.
Compound 1; White amorphous powder; TLC (Rf = 0.28, CHCl3:MeOH:water = 60:40:2); IR (KBr): νmax 3355 and 1071 (hydroxyl groups and glycosidic linkage) cm−1; FAB-MS: m/z 1,115 [M+Na]+; 1H- and 13C-NMR (500 MHz, pyridine) data: Table 1.
Table 1.1H- and 13C-NMR data for compounds 1, 8, 10, 11, 12, 19, and 20
Table 2.Semi-preparative HPLC conditions for the separation of WGBs
Compound 8; White amorphous powder; TLC (Rf = 0.81, CHCl3:MeOH:H2O = 60:40:2); IR (KBr): νmax 3355 and 1073 (hydroxyl groups and glycosidic linkage) cm−1; FAB-MS: m/z 865 [M+Na]+; 1H- and 13C-NMR (500 MHz, pyridine) data: Table 1.
Compound 10; White amorphous powder; TLC (Rf = 0.17, CHCl3:MeOH:water = 70:30:2); IR (KBr): νmax 3344 and 1071 (hydroxyl groups and glycosidic linkage) cm−1; FAB-MS: m/z 983 [M+Na]+; 1H- and 13C-NMR (500 MHz, pyridine) data: Table 1.
Compound 11; White amorphous powder; TLC (Rf = 0.33, CHCl3:MeOH:water = 60:40:2); IR (KBr): νmax 3348 and 1071 (hydroxyl groups and glycosidic linkage) cm−1; FAB-MS: m/z 985 [M+Na]+; 1H- and 13C-NMR (500 MHz, pyridine) data: Table 1.
Compound 12; White amorphous powder; TLC (Rf = 0.61, CHCl3:MeOH:water = 70:30:2); IR (KBr): νmax 3363 and 1073 (hydroxyl groups and glycosidic linkage) cm−1; FAB-MS: m/z 793 [M+Na]+; 1H- and 13C-NMR (500MHz, pyridine) data: Table 1.
Compound 19; White amorphous powder; TLC (Rf = 0.46, CHCl3:MeOH:water = 70:30:2); IR (KBr): νmax 3362 and 1077 (hydroxyl groups and glycosidic linkage) cm−1; FAB-MS: m/z 839 [M+Na]+; 1H- and 13C-NMR (500 MHz, pyridine) data: Table 1.
Compound 20; White amorphous powder; TLC (Rf = 0.23, CHCl3:MeOH:water = 50:50:2); IR (KBr): νmax 3378 and 1073 (hydroxyl groups and glycosidic linkage) cm−1; FAB-MS: m/z 965 [M+Na]+; 1H- and 13C-NMR (500 MHz, pyridine) data: Table 1.
Acid hydrolysis of compounds 1, 8, 10, 11, 12, 19, and 20 − Compounds 1, 8, 10, 11, 12, 19, and 20 (each 10 mg) were refluxed with 5% HCl in 60% aqueous dioxane (10 mL) for 2 h. The reaction solution was evaporated under reduced pressure, and the hydrolysate was extracted with ether. The ether extract was evaporated to yield aglycone hederagenin, which was identified by direct comparison with an authentic sample. The water layer was neutralized with Ag2CO3 and filtered, and the filtrate was concentrated under reduced pressure. The residue was compared with standard sugars by cellulose TLC [pyridine-EtOAc-HOAc-water (36:36:7:21)], which showed the sugars to be xylopyranoside, rhamnopyranoside, glucopyranoside, and galactopyranoside.
Determination of the absolute configuration of sugars of compounds 1, 8, 10, 11, 12, 19, and 20 − Compounds 1, 8, 10, 11, 12, 19, and 20 (each 10 mg) were treated as above, the dried sugar mixture was dissolved in pyridine (0.1 mL), and then the solution was added to a pyridine solution (0.1 mL) of L-cysteine methyl ester hydrochloride (2 mg) and warmed at 60 ℃ for 1 h. The solvent was evaporated under a N2 stream and dried in vacuo. The residue was trimethylsilylated with TMS-HT (0.1 mL) at 60 ℃ for 30 min. After the addition of n-hexane and water, the n-hexane layer was removed and checked by GC. The retention times (tR) of the peaks were 6.18 (L-rhamnopyranoside), 8.85 (D-xylopyranoside), 22.03 (D-glucopyranoside), and 22.21 min (D-galactopyranoside).
Results and discussion
A chromatographic separation of the EtOH extract of P. ginseng root led to the isolation of compounds 1 - 21. These compounds were identified as ginsenosides by comparing their mass spectrometry (MS) and nuclear magnetic resonance (NMR) spectroscopic data in literature. Known compounds 1 - 21 can be divided into several groups. PPD, PPT, and oleanene are the three main groups of ginsenosides. Ginsenosides-Rb1 (2), -Rb2 (3), -Rb3 (4), -Rc (5), and -Rd (6) are PPD types. 20(S)-Notoginsenoside-R2 (7), 20(S)-O-glucoginsenoside-Rf (9), ginsenosides-Re (13), -Re5 (14), -Rf (15), -Rg1 (16), -Rg2 (17), and -Rh1 (18) are PPT types. Ginsenoside-Ro (21) is an oleanene type.17,20-24
Compound 1 was obtained as a white amorphous powder. Its molecular formula was determined to be C54H92O22 based on the fast atom bombardment (FAB)-MS ([M+Na]+, m/z 1,115) and NMR. The 1H-NMR spectrum showed one olefinic (δ 5.27), four anomeric (δ 4.92, 5.14, 5.31, and 6.44), and an L-rhamnopyranosyl-methyl (δ 1.78) proton signal. In the 13C-NMR spectrum, the chemical shifts of four anomeric carbons were noted at δ 98.7, 105.6, 106.5, and 102.3 (Table 1). Acid hydrolysis of 1 yielded D-glucopyranoside and L-rhamnopyranoside. Therefore, the anomeric carbon signals indicated three β-D-glucopyranosyl and one α-L-rhamnopyranosyl moieties. The significant downfield shift of C-2' (δ 83.8) in the inner β-D-glucopyranosyl moiety at C-3 of aglycone in the 13C-NMR spectrum of C-2' (δ 83.8) showed that the terminal β-D-glucopyranosyl moiety is linked to the inner β-D-glucopyranosyl moiety at C-3. Additionally, C-6''' (δ 70.7) was significantly downfield in the inner β-D-glucopyranosyl moiety at C-20 of aglycone in the 13C-NMR spectrum of C-6''' (δ 70.7), which showed that the terminal α-L-rhamnopyranosyl moiety is linked to the inner β-D-glucopyranosyl moiety at C-20. As a result, the structure of 1 was elucidated as gypenoside-V by spectral data analysis with an authentic sample in the literature.25-28 Compound 1 has been isolated from Gynostemma pentaphyllum.28
Compound 8 has a molecular formula of C44H74O15 based on the FAB-MS ([M+Na]+, m/z 865) and NMR. The 1H-NMR spectrum showed one olefinic (δ 5.26), two anomeric (δ 5.01 and 5.17), and a methyl proton signals of acetyl group (δ 2.05). In the 13C-NMR spectrum, the chemical shifts of two anomeric carbons were noted at δ 98.7 and 106.3 (Table 1). Acid hydrolysis of 8 yielded D-glucopyranoside. Therefore, the anomeric carbons signals indicated two β-D-glucopyranosyl moieties. In addition, these NMR features indicated two additional signals at δ 171.4 and 21.4, owing to the acetyl group. A difference in the chemical-shift value of C-6' (δ 65.7) allowed the acetyl group to be placed at C-6' of the β-D-glucopyranosyl moiety. As a result, the structure of 8 was elucidated as notoginsenoside-Rt (= yesanchinoside D) by spectral data analysis with an authentic sample in the literature.29-30 Compound 8 has been isolated from P. japonicus root.30
Compound 10 was obtained as a white amorphous powder. Its molecular formula was determined to be C48H80O19 based on the FAB-MS ([M+Na]+, m/z 983) and NMR. The 1H-NMR spectrum showed one exomethylene (δ 5.74 and 6.31), three anomeric (δ 5.17, 5.25, and 6.47), and a L-rhamnopyranosyl-methyl (δ 1.77) proton signal. In the 13C-NMR spectrum, the chemical shifts of three anomeric carbons were noted at δ 98.8, 102.4, and 102.4 (Table 1). Acid hydrolysis of 10 yielded D-glucopyranoside and L-rhamnopyranoside. Therefore, the anomeric carbon signals indicated two β-D-glucopyranosyl and an α-L-rhamnopyranosyl moieties. The significant downfield shift of C-2' (δ 79.4) in the inner β-D-glucopyranosyl moiety at C-6 of aglycone in the 13C-NMR spectrum of C-2' (δ 79.4) showed that the terminal α-L-rhamnopyranosyl moiety is linked to the inner β-D-glucopyranosyl moiety at C-6. As shown in Table 1, the 13C-NMR spectrum of 10 was quite similar to that of majoroside-F6 (11) except for the side chain. Additionally, C-1''' (δ 98.8) was shown in the β-D-glucopyranosyl moiety at C-20 of aglycone in the 13C-NMR spectrum. As a result, the structure of 10 was elucidated as 6-O-[α-L-rhamnop-yranosyl(1 → 2)-β-D-glucop-yranosyl]-20-O-β-D-glucopyranosyl-3β,12β,20(S)-dihydroxy-dammar-25-en-24-one by spectral data analysis with an authentic sample in the literature31. Compound 10 has been isolated from P. ginseng flower buds.31
Compound 11 was isolated as a white amorphous powder with a formula of C48H82O19 based on the FAB-MS ([M+Na]+, m/z 985) and NMR. The 1H-NMR spectrum showed two olefinic (δ 6.01 and 6.31), three anomeric (δ 5.18, 5.27, and 6.49), and an L-rhamnopyranosyl-methyl (δ 1.77) proton signals. In the 13C-NMR spectrum, the chemical shifts of three anomeric carbons were noted at δ 98.8 and 102.4 (Table 1). Acid hydrolysis of 11 yielded D-glucopyranoside and L-rhamnopyranoside. Therefore, the anomeric carbon signals indicated two β-D-glucopyranosyl and an α-L-rhamnopyranosyl moieties. The significant downfield shift of C-2' (δ 79.1) in the inner β-D-glucopyranosyl moiety at C-6 of aglycone in the 13C-NMR spectrum of C-2' (δ 79.1) showed that the terminal α-L-rhamnopyranosyl moiety is linked to the inner β-D-glucopyranosyl moiety at C-6. Furthermore, the olefinic carbon signals (δ 123.7 and 142.6) and an oxygenated carbon signal (δ 69.9) were observed, in which a double bond at C-23 and -24 and a hydroxyl group at C-25 of the chain. As results, the structure of 11 was elucidated as majoroside-F6 by spectral data analysis with an authentic sample in the literature.27 Compound 11 has been isolated from P. japonicus root.32
Compound 12 has a molecular formula of C42H70O13 based on the FAB-MS ([M+Na]+, m/z 793) and NMR. The 1H-NMR spectrum showed one olefinic (δ 5.27) and two anomeric (δ 5.10 and 5.17) proton signals. In the 13C-NMR spectrum, the chemical shifts of two anomeric carbons were noted at δ 98.8 and 106.4 (Table 1). Acid hydrolysis of 12 yielded D-glucopyranoside and D-xylopyranoside. Therefore, the anomeric carbon signals indicated a β-D-glucopyranosyl and β-D-xylopyranosyl moieties. The C-1' of β-D-xylopyranosyl moiety was attached to C-6 (δ 80.7) of the skeleton. As a result, the structure of 12 was elucidated as pseudoginsenoside-Rt3 by spectral data analysis with an authentic sample in the literature.33 Compound 12 has been isolated from P. pseudo-ginseng root.33
Compound 19 was obtained as colorless crystals. Its molecular formula was determined to be C42H72O15 based on the FAB-MS ([M+Na]+, m/z 839) and NMR. The 1HNMR spectrum showed two olefinic (δ 6.01 and 6.31) and two anomeric (δ 5.05 and 5.19) proton signals. In the 13C-NMR spectrum, the chemical shifts of two anomeric carbons were noted at δ 98.7 and 106.4 (Table 1). Acid hydrolysis of 19 yielded D-glucopyranoside. Therefore, the anomeric carbon signals indicated two β-D-glucopyranosyl moieties. As shown in Table 1, the 13C-NMR spectrum of 19 was quite similar to that of majoroside F6 (11), except for the α-L-rhamnopyranosyl moiety. Furthermore, the olefinic carbon signals (δ 123.7 and 142.6) and an oxygenated carbon signal (δ 70.4) were observed, in which a double bond at C-23 and -24 and a hydroxyl group at C-25 of the chain. As a result, the structure of 19 was elucidated as vinaginsenoside-R15 by spectral data analysis with an authentic sample in the literature.34 Compound 19 has been isolated from P. vietnamensis root.35
Compound 20 is a white amorphous powder. Its molecular formula was determined to be C48H78O18 based on the FAB-MS ([M+Na]+, m/z 965) and NMR. The 1H-NMR spectrum showed one olefinic (δ 5.36) and three anomeric (δ 4.47, 4.91, and 6.31) proton signals. In the 13C-NMR spectrum, the chemical shifts of three anomeric carbons were noted at δ 96.2, 105.8, and 106.3. The aglycone was recognized to be an oleanolic acid on 1H- and 13C-NMR analysis, with the typical olefinic carbons at δ 123.8 and 144.6. Moreover, the peak at δ 177.0 was indicated to be an ester carbon (Table 1). Acid hydrolysis of 20 yielded D-glucopyranoside and D-glactopyranoside. Therefore, the anomeric carbon signals indicated two β-D-glucopyranosyl and β-D-glactopyranosyl moieties. Additionally, C-1''' (δ 96.2) was shown in the β-D-glucopyranosyl moiety at C-28 of aglycone in the 13C-NMR spectrum. As a result, the structure of 20 was elucidated as calenduloside-B by spectral data analysis with an authentic sample in the literature [36]. Compound 20 has been isolated from Calendula officinalis root.36
Dammarane-type triterpenoid saponins were isolated and identified as protopanaxadiol ginsenosides [gypenoside-V (1), ginsenosides-Rb1 (2), -Rb2 (3), -Rb3 (4), -Rc (5), and -Rd (6)], protopanaxatriol ginsenosides [20(S)-notoginsenoside-R2 (7), notoginsenoside-Rt (8), 20(S)-O-glucoginsenoside-Rf (9), 6-O-[α-L-rhamnopyranosyl(1→2)-β-D-glucopyranosyl]-20-O-β-D-glucopyranosyl-3β,12β, 20(S)-dihydroxy-dammar-25-en-24-one (10), majoroside-F6 (11), pseudoginsenoside-Rt3 (12), ginsenosides-Re (13), -Re5 (14), -Rf (15), -Rg1 (16), -Rg2 (17), and -Rh1 (18), and vinaginsenoside-R15 (19)], and oleanene ginsenosides [calenduloside-B (20) and ginsenoside-Ro (21)] from P. ginseng root. To the best of our knowledge, this is the first report on the isolation of compounds 1, 8, 10, 11, 12, 19, and 20 from P. ginseng root.
P. ginseng is a popular herbal medicine used worldwide for a broad range of indications. Many clinical trials and systematic reviews are now available. Their conclusions are diverse, but for some indications, they are encouraging. So, P. ginseng root should be a various active experiments and more saponins isolation. Thus, these results will be useful information in the application of these ginsenosides from ginseng in the nutraceutical, pharmaceutical, and cosmeceutical areas.
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