Chemical Constituents of the Terrestrial Stems of Ephedra sinica and their PPAR-γ Ligand-Binding Activity

• Abstract
• Introduction
• Results and Discussion
• Materials and Methods
• General experimental procedures
• Plant material
• Extraction and isolation
• Compound 10
• Derivatization of 10
• PPAR-γ ligand-binding activity
• Statistical analyses
• Supporting information
• References

Abstract

Bioassay-guided fractionation of the MeOH extract of Ephedra sinica terrestrial stems, using a PPAR-γ ligand binding assay, resulted in the isolation of 10 compounds, including one new bisabolane-type sesquiterpenoid (10). The structure of the new compound was determined by extensive spectroscopic analysis, including two-dimensional (2D) NMR. Among the isolated compounds, the sitosterol derivatives (1 and 2), flavonoid glucoside (7), and the new sesquiterpenoid (10), showed significant PPAR-γ ligand-binding activity.

Introduction

Ephedra sinica is described in the Japanese Pharmacopoeia (17^th edition) as one of the original plants from which the crude drug Ephedra Herb has been obtained [1]. Ephedra Herb has long been used as an antitussive and expectorant in traditional Japanese medicine [2] [3]. The terrestrial stems of E. sinica are well known to contain ephedrine alkaloids, (-)-ephedrine and (+)-pseudoephedrine, and tannins ephedrannin A and B [4] [5] [6]. The ephedrine alkaloids in Ephedra Herb are mainly responsible for exerting pharmaceutical effects as well as adverse effects [7] [8]. In addition, only a few bioactive constituents of Ephedra Herb, except for ephedrine alkaloids, have been reported [9]. Pharmacological studies of minor constituents of Ephedra Herb, such as sesquiterpenes and monoterpenes, are needed. As part of our continuous search for bioactive secondary metabolites of traditional medicines, a MeOH extract of E. sinica was found to exhibit peroxisome proliferator-activated receptor (PPAR)-γ ligand-binding activity. To identify the secondary metabolites in E. sinica having PPAR-γ ligand-binding activity, bioassay-guided fractionation of the MeOH extract of E. sinica terrestrial stems was carried out. This led to the isolation of 10 compounds (1–10), including a new bisabolane-type sesquiterpenoid (10) ([Fig. 1]). This paper is a report on the structural determination of the new sesquiterpene obtained by extensive spectroscopic analysis, including 2D NMR data. The isolated compounds were evaluated for their PPAR-γ ligand-binding activity.

Results and Discussion

The terrestrial stems of E. sinica (5.4 kg dry weight) were extracted with MeOH at 50°C. After removing the solvent, the MeOH extract (665 g) was applied to a porous polymer polystyrene resin (Diaion HP-20) column. The MeOH, EtOH, and EtOAc-eluted portions showed PPAR-γ ligand-binding activity ([Fig. 2]). Thus, the MeOH and EtOH-soluble fractions were passed through column chromatography on silica gel and octadecylsilanized (ODS) silica gel producing compounds 1–10. Compounds 1–9 were identified as β-sitosterol (1) [10], 7β-hydroxysitosterol (2) [11], 7α-hydroxysitosterol (3) [11], kaempferol-3-O-rhamnoside (4) [12], kaempferol-3-O-(4″-trans-p-coumaroyl)-rhamnopyranoside (5) [13], kaempferol-3-O-(4″-cis-p-coumaroyl)-rhamnopyranoside (6) [14], herbacetin-7-O-glucopyranoside (7) [6], mahuanin A (8) [15], and ephedrannin A (9) [16], respectively ([Fig. 1]).

Compound 10 (C₁₆H₂₂O₄) was obtained as a colorless oil, which was determined by high-resolution electrospray ionization time-of-flight mass spectrometry (HR-ESI-TOF-MS, m/z 301.1413 [M + Na]⁺, calcd. for C₁₆H₂₂NaO₄ 301.1416) and ¹³C NMR (16 carbon signals) data. The IR spectrum of 10 showed absorption bands of carbonyl groups at 1700 and 1644 cm^-1. The ¹³C NMR spectrum exhibited two carbonyl carbon signals at δ _C 172.0 and 168.1, and the HMBC spectrum displayed a correlation peak between δ _C 168.1 and a methyl singlet signal at δ _H 3.74. On the other hand, treatment of 10 with bis(trimethylsilyl)trifluoroacetamide (BSTFA) in pyridine produced the corresponding trimethylsilyl (TMS) derivative of 10 (C₁₉H₃₀O₄Si; GC/MS, m/z: 350.1 [M + TMS]). These data implied the presence of two carboxy groups in the molecule of 10, one is free and another is methyl ester. The ¹H NMR and ¹H-¹H COSY spectra disclosed the following spin-coupling correlations: δ _H 7.16 (H-2)/ 2.73 (H-3a) and 2.20 (H-3b)/2.89 (H-4) / 2.12 (H-5a) and 1.74 (H-5b) /2.54 (H-6a) and 2.24 (H-6b), and the H-2 olefinic proton and H₂–6 methylene protons showed long-range correlations with the quaternary olefinic carbon at δ _C 129.2 (C-1) and the carbonyl carbon of the carboxy group at δ _C 172.0 (C-7). These data provided evidence of the presence of a cyclohexene group bearing a carboxy group at C-1. The other the spin-coupling correlations δ _H 1.06 (Me-14) and 1.05 (Me-15)/2.44 (H-13)/6.09 (H-12)/6.35 (H-11)/7.16 (H-10) were consistent with a 4-methyl-2-pentene group. The HMBC correlations from H₂–3, H-4, H₂–5, and H-11 to the olefinic carbon at δ _C 131.8 (C-8) and from H-4 to the carbonyl carbon of the methyl carboxylate group at δ _C 168.1 (C-9) indicated that C-4 of the cyclohexene group, C-9 carbonyl group, and C-10 of the 4-methyl-2-pentene group were linked to the C-8 olefinic carbon, and a double bond was present between C-8 and C-10 ([Fig. 3]). The spin-coupling constant of H-10/H-11 (J = 11.4 Hz) and H-11/H-12 (J = 15.0 Hz) and NOE correlations between H-10 and H-12 and between H-11 and H₂–3 allowed the geometry at C-8 and C-11 to be established as 8E and 11E. In ESI-TOF/MS-MS analysis of 10, the prominent fragment ion-peak at m/z 207 originated from a loss of the C₍₁₁₎H-C₍₁₂₎H-C₍₁₃₎H-Me₍₁₄₎(Me₍₁₅₎) moiety of 10. Other minor peaks observed at m/z 245, 235, 233, 201, 179, and 163 corresponded to the proposed fragments as depicted in the Supporting Information. Thus, the structure of 10 was established as a bisabolane-type sesquiterpenoid as shown in [Fig. 1]. Compound 10 showed no specific rotation and was assumed to be a racemate.

The isolated compounds 1, 2, and 4–10 were evaluated for their PPAR-γ ligand-binding activity using a nuclear receptor cofactor assay system ([Fig. 4]). Kaempferol was used as a positive control. Compounds 1, 2, 7, and 10 exhibited significant PPAR-γ ligand-binding activity, among which the new bisabolane-type sesquiterpenoid 10 was the most potent. In the kaempferol derivatives (4–7), the glycosylation at the C-2 hydroxy group by a rhamnosyl moiety (4–6) reduced the PPAR-γ ligand activity.

In conclusion, a new bisabolane-type sesquiterpenoid (10) and nine known compounds (1–9) were isolated from the MeOH extract of E. sinica terrestrial stems. Compounds 1, 2, 7, and 10 showed significant PPAR-γ ligand-binding activity, among which the new bisabolane derivative 10 was the most potent. In a previous study, terpenoids with a cyclohexene ring were reported to act as a native retinoid X receptor agonist [17]. With expectation, 10 exhibited PPAR-γ ligand-binding activity.

Materials and Methods

General experimental procedures

The instruments and experimental conditions were the same as those described in a previous paper [18]. All solvents used for extraction and isolation were high grade (> 99%) (Fujifilm Wako Pure Chemical). Purities of all isolated compounds (> 95%) were confirmed by NMR and TLC analysis.

Plant material

The dried terrestrial parts (5.4 kg) of E. sinica Stapf (Ephedraceae) were collected from the Medicinal Plant Garden of the Tokyo University of Pharmacy and Life Sciences, Tokyo, Japan on July 10, 2015. This genetic resource was introduced to the garden in December 1981. The plant material was authenticated by one of the authors (K. M.) and was also identified according to the ITS rDNA sequence [19]. A voucher specimen has been deposited in the Herbarium of Tokyo University of Pharmacy and Life Sciences (KS-2015–001).

Extraction and isolation

The terrestrial stems of E. sinica (5.4 kg) were extracted with MeOH (50 L) at 50°C. After evaporation of MeOH under reduced pressure at 40°C, the MeOH extract (665 g) was subjected to a Diaion HP-20 column (2200 g, 85 mm i.d. × 600 mm) and successively partitioned by eluting with MeOH-H₂O (3:7), MeOH-H₂O (1:1), MeOH, EtOH, and EtOAc (each 10 L) in order of decreasing polarity. The EtOH-eluted fraction (55 g) was passed through a silica gel column (2000 g, 85 mm i.d. × 600 mm) eluted with gradient mixtures of hexane-EtOAc (4:1; 3:1; 2:1; 1:1) and MeOH, which produced 9 fractions (Frs. A-I). Fr. C was separated by a silica gel column (1800 g, 80 mm i.d. × 400 mm) eluted with hexane-EtOAc (7:1; 4:1; 1:1) and, sequentially, an ODS silica gel column eluted with MeCN-H₂O (3:1; 4:1; 5:1) to yield 1 (44.8 mg), 2 (1.5 mg), and 3 (4.3 mg). The MeOH-eluted portion (120 g) was chromatographed on silica gel (2700 g, 45 mm i.d. × 430 mm) eluted with MeCN-H₂O (1:3; 1:2; 1:1; 2:1) to give 10 subfractions (Frs. a-j). Fr. a was subjected to a Sephadex LH-20 column (470 g, 25 mm i.d. × 300 mm) eluted with MeOH-H₂O (1:1; 2:1) to give 4 (58.0 mg), 7 (6.7 mg), and 8 (17.0 mg). Fr. e was subjected to a Sephadex LH-20 column (470 g, 25 mm i.d. × 300 mm) eluted with MeOH-H₂O (2:1) and a silica gel column eluted with CHCl₃-MeOH-H₂O (100:10:1; 50:10:1; 30:10:1) to yield 5 (25.2 mg), 6 (6.2 mg), and 9 (7.1 mg). Fr. i was subjected to a Sephadex LH-20 column (470 g, 25 mm i.d. ×300 mm) eluted with MeOH-H₂O (2:1) and an ODS silica gel column eluted with MeCN-H₂O (2:1) to yield 10 (14.9 mg). Separation and isolation were guided a PPAR-γ ligand-binding activity and TLC analysis of the fractions.(Fig. 1S–8S).

Compound 10

An amorphous solid; [α]_D ²⁵–0.22 (c 0.10, CHCl₃); IR ν _max (film) cm^-1: 3414 (OH), 1700 and 1644 (C=O); ¹H and ¹³C NMR (500 and 125 MHz, CDCl₃), see [Table 1]; HR-ESI-TOF-MS (m/z: 301.1413 [M + Na]⁺, calcd. for C₁₆H₂₂NaO₄: 301.1416).

Derivatization of 10

A mixture of 10 (0.5 mg) and BSTFA (50 µL) in pyridine (50 µL) was sealed in a glass vial and placed at 60°C for 3 h. The reaction mixture was evaporated under a gentle stream of nitrogen to give the TMS derivative of 10.

PPAR-γ ligand-binding activity

PPAR-γ agonist activity was examined using a nuclear receptor cofactor assay system (EnBio RCAS for PPAR-γ; EnBioTec Laboratories) according to the manufacturer’s instructions. Briefly, a peptide of cyclic AMP response element-binding protein (CBP) was immobilized on the bottom of a microtiter plate. After adding the recombinant human PPAR-γ solution to the wells, DMSO (purity > 99.5%) as a control, or a positive control or isolated compounds were added, respectively. The binding of the PPAR-γ ligand complex to the CBP on the plate was detected by measuring the absorbance at 450 nm. This assay involves a cell-free system using nuclear receptors and cofactors. Pioglitazone (purity > 98.0%) and kaempferol (purity > 97.0%) were used as positive controls (TCI). All other reagents or solvents used were of biochemical reagent grade.

Statistical analyses

Data are represented as the mean±standard error of the mean (SEM) of three experiments performed in triplicate. Dunnett’s test was used and the level of significance is indicated by p values.

Supporting information

1D and 2D NMR and MS/MS spectra of 10 are available as Supporting Information.

Conflict of Interest

The authors declare that they have no conflict of interest.

Acknowledgements

We thank Hirokazu Ando and Yohei Sasaki for identifying E. sinica according to the ITS rDNA sequence.

• References

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• 12 Bernal F, Cuca L, Yamaguchi L. Coy-Barrera E. LC-DAD-UV and LC-ESI-MS-based analyses, antioxidant capacity, and antimicrobial activity of a polar fraction from Iryanthera ulei leaves. Rec Nat Prod 2013; 7: 152-156
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• 14 Si CL, Yu GJ, Du ZG, Huang XF, Fan S, Du HS, Hu WC. A new cis-p-coumaroyl flavonol glycoside from the inner barks of Sophora japonica L. Holzforschung 2016; 70: 39-45
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• 15 Rawat MSM, Prasad D, Joshi RK, Pant G. Proanthocyanidins from Prunus armeniaca roots. Phytochemistry 1999; 50: 321-324
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• 16 Kim IS, Park YJ, Yoon SJ, Lee HB. Ephedrannin A and B from roots of Ephedra sinica inhibit lipopolysaccharide-induced inflammatory mediators by suppressing nuclear factor-κB activation in RAW 264.7 macrophages. Int Immunopharmacol 2010; 10: 1616-1625
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• 17 Okitsu T, Sato K, Iwatsuka K, Sawada N, Nakagawa K, Okano T, Wada A. Replacement of the hydrophobic part of 9-cis-retinoic acid with cyclic terpenoid moiety results in RXR-selective agonistic activity. Bioorg Med Chem 2011; 19: 2939-2949
  CrossrefPubMedGoogle Scholar
• 18 Matsuo Y, Maeda S, Ohba C, Fukaya H, Mimaki Y. Vetiverianines A, B, and C: Sesquiterpenoids from Vetiveria zizanioides Roots. J Nat Prod 2016; 79: 2175-2180
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• 19 Long C, Kakiuchi N, Takahashi A, Komatsu K, Cai S, Mikage M. Phylogenetic Analysis of the DNA Sequence of the Non-Coding Region of Nuclear Ribosomal DNA and Chloroplast of Ephedra Plants in China. Planta Med 2004; 70: 1080-1084
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Correspondence

• References

• 1 Ministry of Health Law, Japan The Japanese pharmacopoeia. 17th edition Tokyo: Ministry of Health Law; 2016: 1589
  Google Scholar
• 2 Minamizawa K, Goto H, Shimada Y, Terasawa K, Haji A. Effects of eppikahangeto, a Kampo formula, and Ephedrae herba against citric acid-induced laryngeal cough in guinea pigs. J Pharm Sci 2006; 101: 118-125
  CrossrefPubMedGoogle Scholar
• 3 Abourashed EA, Alfy AT, Khan IA, Walker L. Ephedra in perspective – a current review. Phytother Res 2003; 17: 703-712
  CrossrefPubMedGoogle Scholar
• 4 Kim HK, Choi YH, Chang WT, Verpoorte R. Quantitative analysis of ephedrine analogues from Ephedra species using ¹H-NMR. Chem Pharm Bull 2003; 51: 1382-1385
  CrossrefPubMedGoogle Scholar
• 5 Amakura Y, Yoshimura M, Yamakami S, Yoshida T, Wakana D, Hyuga M, Goda Y. Characterization of phenolic constituents from Ephedra herb extract. Molecules 2013; 18: 5326-5334
  CrossrefPubMedGoogle Scholar
• 6 Nawwar MA, El-Sissi HI, Barakat HH. Flavonoid constituents of Ephedra alata . Phytochemistry 1984; 23: 2937-2939
  CrossrefPubMedGoogle Scholar
• 7 Shekelle P, Hardy ML, Morton SC, Maglione M, Suttorp M, Roth E, Jungvig L, Mojica WA, Gagné J, Rhodes S, McKinnon E. Ephedra and ephedrine for weight loss and athletic performance enhancement: Clinical efficacy and side effects. Evid Rep Technol Assess (Summ). 2003; 76: 1-4
  PubMedGoogle Scholar
• 8 Kobayashi Y. Analgesic effects and side effects of ephedra herb extract and ephedrine alkaloids-free ephedra herb extract. Yakugaku Zasshi 2017; 137: 187-194
  CrossrefPubMedGoogle Scholar
• 9 Hyuga S, Hyuga M, Yoshimura M, Amakura Y, Goda Y, Hanawa T. Herbacetin, a constituent of ephedrae herba, suppresses the HGF-induced motility of human breast cancer MDA-MB-231 cells by inhibiting c-Met and Akt phosphorylation. Planta Med 2013; 79: 1525-1530
  Article in Thieme ConnectPubMedGoogle Scholar
• 10 Morales G, Sierra P, Mancilla A, Paredes A, Loyola LA, Gallardo O, Borquez J. Secondary metabolites from four medicinal plants from northern Chile: antimicrobial activity and biotoxicity against Artemia salina . J Chin Chem Soc 2003; 48: 13-18
  PubMedGoogle Scholar
• 11 Cui EJ, Park JH, Park HJ, Chung IS, Kim JY, Yeon SW, Baek NI. Isolation of sterols from cowpea (Vigna sinensis) seeds and their promotion activity on HO-1. J Korean Soc Appl Biol Chem 2011; 54: 362-366
  CrossrefPubMedGoogle Scholar
• 12 Bernal F, Cuca L, Yamaguchi L. Coy-Barrera E. LC-DAD-UV and LC-ESI-MS-based analyses, antioxidant capacity, and antimicrobial activity of a polar fraction from Iryanthera ulei leaves. Rec Nat Prod 2013; 7: 152-156
  PubMedGoogle Scholar
• 13 Kaouadji M, Morand JM, Garcia J. Further acylated kaempferol rhamnosides from Platanus acerifolia buds. J Nat Prod 1993; 56: 1618-1621
  CrossrefPubMedGoogle Scholar
• 14 Si CL, Yu GJ, Du ZG, Huang XF, Fan S, Du HS, Hu WC. A new cis-p-coumaroyl flavonol glycoside from the inner barks of Sophora japonica L. Holzforschung 2016; 70: 39-45
  CrossrefPubMedGoogle Scholar
• 15 Rawat MSM, Prasad D, Joshi RK, Pant G. Proanthocyanidins from Prunus armeniaca roots. Phytochemistry 1999; 50: 321-324
  CrossrefPubMedGoogle Scholar
• 16 Kim IS, Park YJ, Yoon SJ, Lee HB. Ephedrannin A and B from roots of Ephedra sinica inhibit lipopolysaccharide-induced inflammatory mediators by suppressing nuclear factor-κB activation in RAW 264.7 macrophages. Int Immunopharmacol 2010; 10: 1616-1625
  CrossrefPubMedGoogle Scholar
• 17 Okitsu T, Sato K, Iwatsuka K, Sawada N, Nakagawa K, Okano T, Wada A. Replacement of the hydrophobic part of 9-cis-retinoic acid with cyclic terpenoid moiety results in RXR-selective agonistic activity. Bioorg Med Chem 2011; 19: 2939-2949
  CrossrefPubMedGoogle Scholar
• 18 Matsuo Y, Maeda S, Ohba C, Fukaya H, Mimaki Y. Vetiverianines A, B, and C: Sesquiterpenoids from Vetiveria zizanioides Roots. J Nat Prod 2016; 79: 2175-2180
  CrossrefPubMedGoogle Scholar
• 19 Long C, Kakiuchi N, Takahashi A, Komatsu K, Cai S, Mikage M. Phylogenetic Analysis of the DNA Sequence of the Non-Coding Region of Nuclear Ribosomal DNA and Chloroplast of Ephedra Plants in China. Planta Med 2004; 70: 1080-1084
  Article in Thieme ConnectPubMedGoogle Scholar

• Supplementary Material