Platyconic Acid A, a Genuine Triterpenoid Saponin from the Roots of Platycodon grandiflorum

Abstract

A genuine triterpenoid saponin, platyconic acid A (1) was isolated from the roots extract of Platycodon grandiflorum, together with five known saponins: deapioplatycoside E (2), platycoside E (3), platycodin D₃ (4), platycodin D₂ (5) and platycodin D (6). The structure of 1 was determined on the basis of spectral analysis and chemical evidence.

Introduction

The species Platycodon grandiflorum A. DC (Campanulaceae) is a perennial herb found throughout northeast Asia. The roots have been used as food and frequently employed as a folk remedy for bronchitis, asthma, pulmonary tuberculosis, hyperlipidemia, diabetes and inflammatory diseases. Many pharmacological activities of the species such as, cytotoxicity, inhibition of pancreatic lipase, inhibition of nitric oxide synthase and cyclooxygenase II, protection of oxidative hepatotoxicity and cognitive enhancing activity have been reported [1,2,3,4,5,6].

Triterpenoid saponins with unique chemical features on an oleanene backbone were known as the main chemical constituents of the species and more than 30 kinds of saponin components such as platycodin D have been reported so far [7,8,9,10,11,12,13].

In a previous paper, we reported the isolation of a novel triterpenoid saponin, deapioplatycoside E, from the species [1]. In continuation of our phytochemical investigation of the MeOH extract, we have now isolated a new genuine saponin which we have named platyconic acid A (1) and identified as platycogenic acid-A 3-O-[β-d-glucopyranoside]-28-O-[β-d-apiofuranosyl-(1 3)-β-d-xylopyranosyl-(1 4)-α-l-rhamnopyranosyl-(1 2)-α-l-arabinopyranosyl] ester. It had been reported that two artifacts potentially derived from 1, a methylester 1a and a lactonized product, platyconate A lactone (1b), were isolated from the extract treated with excess amount of diazomethane [13]. From this result, the authors suggested the presence in the plant extract of the corresponding genuine saponin, 1, even though they had failed to isolate it. In this paper, we briefly describe an isolation of the genuine

Figure 1. Compounds 1-6 from the root extract of P. grandiflorum.

Figure 1. Compounds 1-6 from the root extract of P. grandiflorum.

saponin, platyconic acid A (1) from the roots and its structure elucidation on the basis of spectroscopic analyses and the comparison of ¹³C-NMR data with those of the related saponins 1a-e, which were obtained by chemical modification of 1 (Figure 1).

Results and Discussion

The molecular formula of 1 was established as C₅₇H₉₀O₂₉ by MALDI-TOF/MS experiment (m/z) 1284 [M+2Na] and ¹³C-NMR data. The IR spectrum showed a hydroxyl group at 3402 cm^-1 and an ester group at 1726 cm^-1, respectively. The ¹H-NMR and ¹³C-NMR spectral data of 1 indicated the presence of a sapogenin 2,3,16,23-tetrahydroxyolean-12-ene-24,28-dioic acid (platycogenic acid A) and oligosaccharide moieties. The ¹³C-NMR spectral data of 1 (Table 1) was superimposable with those of the reported platyconic acid A methyl ester (1a), the main difference being the methoxy signal (δ 51.3) in 1a, which was not present in 1. Instead, the carboxyl signal (δ 175.5) of 1a was found to be shifted downfield at δ 181.4 (Table 1). These spectral data strongly implied that 1 was an acid congener of 1a, a genuine saponin. All proton and carbon signals of 1 were assigned by the aid of two-dimensional NMR experiments such as COSY, DEPT, HMQC and HMBC and by the comparison with the data of 1a in the literature [13]. Besides, some chemical modifications of 1 were undertaken to confirm the proposed structure. Compound 1 was found to be easily converted to 1a by treatment with diazomethane, as mentioned on previous report [13]. On the other hand, the acid hydrolysis of 1 under different conditions afforded two kinds of prosapogenin, 1c, 1d, and an artificial sapogenin 1e (platycogenic acid-A lactone), all of which provided evidence supporting the proposed structure of 1 [8]. From these results obtained from the spectroscopic data and chemical evidence, the structure of 1

Table 1. ¹³C-NMR spectroscopic data (δ) of 1-1e.

	1	1a	1b	1c	1d	1e
C-1	46.7	45.8	41.6	41.7	41.4	42.0
C-2	69.6	69.8	82.8	83.6	83.5	84.6
C-3	83.3	84.4	89.8	89.5	89.5	81.8
C-4	56.3	56.1	53.9	54.5	54.5	55.2
C-5	49.6	50.1	52.5	52.3	52.2	52.1
C-6	20.3	20.5	19.5	19.8	19.7	20.1
C-7	33.7	33.7	33.6	33.9	33.8	34.0
C-8	40.0	40.3	40.7	40.8	40.6	38.2
C-9	47.2	47.6	48.5	48.5	48.5	49.1
C-10	37.2	37.4	37.9	38.0	38.0	36.9
C-11	24.4	24.4	24.7	25.0	25.0	25.2
C-12	122.9	123.0	122.3	122.6	122.2	121.3
C-13	144.2	144.4	145.0	145.6	146.2	147.3
C-14	42.2	42.4	42.5	42.7	42.7	43.1
C-15	36.2	36.1	36.0	36.5	36.9	36.7
C-16	73.8	74.1	73.9	74.4	75.0	75.9
C-17	49.5	50.1	50.0	50.2	49.3	50.8
C-18	41.3	41.6	41.6	41.6	41.9	40.9
C-19	47.1	47.2	47.2	47.6	47.7	48.1
C-20	30.6	30.8	30.7	30.8	30.3	28.3
C-21	35.9	36.1	36.0	36.4	36.8	34.2
C-22	31.7	31.4	31.3	31.4	31.5	31.5
C-23	63.5	64.5	57.5	57.6	57.5	58.3
C-24	181.4	175.5	177.7	178.6	178.6	179.5
C-25	16.1	15.8	17.4	17.8	17.7	18.3
C-26	17.4	17.6	18.1	18.5	18.4	19.1
C-27	27.0	27.2	27.4	27.7	27.7	26.9
C-28	175.8	175.8	175.8	176.3	180.4	185.0
C-29	33.3	33.1	33.0	33.7	33.3	31.7
C-30	24.8	25.2	25.2	25.2	25.2	25.7
24-OCH3		51.3
	1	1a	1b	1c	1d
glucose
C-1	106.0	106.3	105.1	105.7	105.7
C-2	74.8	75.3	75.0	75.6	75.7
C-3	78.2	78.5	78.2	79.0	79.2
C-4	71.8	72.0	71.8	71.5	71.8
C-5	78.2	78.1	78.2	78.8	78.8
C-6	61.8	63.0	62.9	63.0	63.0
arabinose
C-1	93.4	93.7	93.7	94.1
C-2	75.5	75.7	75.7	75.8
C-3	70.3	70.1	70.2	70.8
C-4	66.2	65.8	65.9	66.8
C-5	61.8	63.0	62.9	63.8
rhamnose
C-1	101.2	101.1	101.1	101.7
C-2	71.8	72.0	72.0	72.4
C-3	72.3	72.4	72.4	73.2
C-4	83.3	83.6	83.6	84.3
C-5	68.4	68.7	68.6	69.1
C-6	18.4	18.1	18.3	18.8
xylose
C-1	106.2	106.5	106.5	107.4
C-2	74.7	75.0	75.0	76.2
C-3	85.2	85.5	85.6	79.2
C-4	68.9	69.5	69.5	71.8
C-5	66.5	66.8	66.8	67.9
apiose
C-1	110.8	111.2	111.2
C-2	77.8	77.9	77.9
C-3	80.1	80.0	80.0
C-4	74.3	75.0	75.0
C-5	65.1	65.8	65.7

Data for 1a and 1b from ref. [13]

Table 1. ¹³C-NMR spectroscopic data (δ) of 1-1e.

	1	1a	1b	1c	1d	1e
C-1	46.7	45.8	41.6	41.7	41.4	42.0
C-2	69.6	69.8	82.8	83.6	83.5	84.6
C-3	83.3	84.4	89.8	89.5	89.5	81.8
C-4	56.3	56.1	53.9	54.5	54.5	55.2
C-5	49.6	50.1	52.5	52.3	52.2	52.1
C-6	20.3	20.5	19.5	19.8	19.7	20.1
C-7	33.7	33.7	33.6	33.9	33.8	34.0
C-8	40.0	40.3	40.7	40.8	40.6	38.2
C-9	47.2	47.6	48.5	48.5	48.5	49.1
C-10	37.2	37.4	37.9	38.0	38.0	36.9
C-11	24.4	24.4	24.7	25.0	25.0	25.2
C-12	122.9	123.0	122.3	122.6	122.2	121.3
C-13	144.2	144.4	145.0	145.6	146.2	147.3
C-14	42.2	42.4	42.5	42.7	42.7	43.1
C-15	36.2	36.1	36.0	36.5	36.9	36.7
C-16	73.8	74.1	73.9	74.4	75.0	75.9
C-17	49.5	50.1	50.0	50.2	49.3	50.8
C-18	41.3	41.6	41.6	41.6	41.9	40.9
C-19	47.1	47.2	47.2	47.6	47.7	48.1
C-20	30.6	30.8	30.7	30.8	30.3	28.3
C-21	35.9	36.1	36.0	36.4	36.8	34.2
C-22	31.7	31.4	31.3	31.4	31.5	31.5
C-23	63.5	64.5	57.5	57.6	57.5	58.3
C-24	181.4	175.5	177.7	178.6	178.6	179.5
C-25	16.1	15.8	17.4	17.8	17.7	18.3
C-26	17.4	17.6	18.1	18.5	18.4	19.1
C-27	27.0	27.2	27.4	27.7	27.7	26.9
C-28	175.8	175.8	175.8	176.3	180.4	185.0
C-29	33.3	33.1	33.0	33.7	33.3	31.7
C-30	24.8	25.2	25.2	25.2	25.2	25.7
24-OCH3		51.3
	1	1a	1b	1c	1d
glucose
C-1	106.0	106.3	105.1	105.7	105.7
C-2	74.8	75.3	75.0	75.6	75.7
C-3	78.2	78.5	78.2	79.0	79.2
C-4	71.8	72.0	71.8	71.5	71.8
C-5	78.2	78.1	78.2	78.8	78.8
C-6	61.8	63.0	62.9	63.0	63.0
arabinose
C-1	93.4	93.7	93.7	94.1
C-2	75.5	75.7	75.7	75.8
C-3	70.3	70.1	70.2	70.8
C-4	66.2	65.8	65.9	66.8
C-5	61.8	63.0	62.9	63.8
rhamnose
C-1	101.2	101.1	101.1	101.7
C-2	71.8	72.0	72.0	72.4
C-3	72.3	72.4	72.4	73.2
C-4	83.3	83.6	83.6	84.3
C-5	68.4	68.7	68.6	69.1
C-6	18.4	18.1	18.3	18.8
xylose
C-1	106.2	106.5	106.5	107.4
C-2	74.7	75.0	75.0	76.2
C-3	85.2	85.5	85.6	79.2
C-4	68.9	69.5	69.5	71.8
C-5	66.5	66.8	66.8	67.9
apiose
C-1	110.8	111.2	111.2
C-2	77.8	77.9	77.9
C-3	80.1	80.0	80.0
C-4	74.3	75.0	75.0
C-5	65.1	65.8	65.7

Data for 1a and 1b from ref. [13]

was determined unambiguously as a that of the genuine saponin, platyconic acid A (platycogenic acid-A 3-O-β-d-glucopyranoside]-28-O-[β-d-apiofuranosyl-(1 3)-β-d-xylopyranosyl-(1 4)-α-l-rhamno- pyranosyl-(1 2)-α-l-arabinopyranoside. This is the first report on the isolation of compound 1 from natural sources.

Figure 2 shows the HPLC profile of the MeOH root extract.

Figure 2. HPLC profile of saponin fraction from the MeOH root extract of P. grandiflorum.

Figure 2. HPLC profile of saponin fraction from the MeOH root extract of P. grandiflorum.

Platyconic acid A (1), deapioplatycoside E (2), platycoside E (3), platycodin D₃ (4), platycodin D₂ (5) and platycodin D (6).

Conclusions

During the phytochemical survey of the roots extract of Platycodon grandiflorum, a new triterpenoid saponin 1 was isolated and identified on the basis of spectral analysis and chemical evidence as a genuine saponin, which we have named platyconic acid A.

Experimental

General

Optical rotations were determined using a Rudolph Autopol IV polarimeter. MS spectra were measured on a Voyager PE Biosystems USA MALDI-TOF/MS Spectrometer. ¹H-NMR and ¹³C-NMR spectra was recorded on a Brucker AVANCE 800 NMR spectrometer using TMS as an internal standard. Preparative HPLC used a Futecs NS-3000i system equipped with an Optimapak column (50 x 250 mm, 10 μm, RSTech) and a ELSD (sofTA, USA).

Plant Material

The species, P. grandiflorum cultivated for three years at the mountainside of Kyungnam Province, Korea was harvested in September 2003. A voucher specimen (Herbarium No. JS-03024) has been preserved at the Herbarium of JangSaeng Doraji Co. LTD., Jinju, Korea.

Extraction and Isolation

Dried roots of P. grandiflorum (5 kg) were extracted three times with methanol at room temperature for 7 days. Concentration of the solvent gave a brown syrupy extract (1.4 kg) which was suspended in water and then partitioned successively with ethyl acetate (63 g) and n-butanol (130 g). The n-butanol layer was suspended in H₂O (2 L) and poured onto a Diaion HP-20 column (Φ = 5.0 × 100 cm), which was stabilized with H₂O. The column was washed with H₂O (2 L) and then eluted with MeOH (5 L). The eluate was concentrated in a reduced pressure to give a crude saponin mixture (75 g).

Characterization of platyconic acid A (1)

Obtained as a white amorphous powder, = - 8.89 (c 1, MeOH); IR ν_max: 3402, 2927, 1726, 1076 and 1033 cm^-1; MALDI-TOF/MS m/z: 1284 [M+2Na]; C₅₇H₉₀O₂₉; ¹H-NMR (pyridine-d₅, 800 MHz): δ 0.98, 1.10, 1.52, 1.69, 1.75 (each 3H, H-25, 26, 27, 29, 30), 2.75 (1H, d, J = 13.3Hz, H-18), 5.61 (1H, brs, H-12); ¹³C-NMR (pyridine-d₅, 200 MHz): see Table 1.

Preparation of 1a by treatment of 1 with diazomethane

Compound 1 (200 mg) was dissolved in MeOH (10 mL), to which 10 equivalents of CH₂N₂ in ether was added and the resulting mixture was stirred overnight, then it was evaporated to dryness and purified by ODS gel column chromatography (MeOH-H₂O) to afford 1a (140 mg) as an amorphous powder.

Preparation of 1c and 1d by partial hydrolysis of 1

Compound 1 (100 mg) was dissolved in 0.1 N HCl in MeOH (10 mL) and stirred at room temperature overnight. The solvent was removed under nitrogen to provide a colorless solid, which was purified by ODS to afford 1c (60 mg) as an amorphous powder. In a similar manner, 1 (100 mg) was dissolved in 1 N HCl in MeOH (10 mL) and refluxed on water bath for 1 hr. The reaction mixture was concentrated in vacuo to yield a colorless solid which was purified by ODS column chromatography to afford 1d (42 mg) as an amorphous powder.

Preparation of 1e by acid hydrolysis of 1

Compound 1 (100 mg) was dissolved in 4 N HCl in MeOH (10 mL) and refluxed on a water bath for 6 hr. The reaction mixture was concentrated in vacuo to yield a colorless solid which was purified by ODS column chromatography to afford 1e (21 mg) as an amorphous powder.

HPLC analysis of the roots extract of P. grandiflorum

A portion of the saponin fraction prepared from the roots extract of P. grandiflorum as described above in Extraction and Isolation (20 g) was purified by repeated preparative HPLC. The residue was dissolved in distilled water and passed through a solid-phase-extraction cartridge (RP-C₁₈, CEREX No. 600-3506). The cartridge was washed with excess amount of distilled water and eluted with MeOH. The MeOH solution was injected onto an Optimapak column (4.6 x 250 mm, 5 µm, RSTech) maintained at 40°C on a Futecs NS-3000i system equipped with an ELSD detector (sofTA, USA). A mixture of 50 mM ammonium acetate solution (NH₄Ac), acetonitrile and methanol was used as mobile phase as follows: eluent A = 85:10:5 NH₄Ac-acetonitrile-methanol; eluent B = 55:40:5 NH₄Ac-acetonitrile-methanol; flow rate: 0.8 mL/min; gradient: 0-5 min (0-15% B), 5-28 min (15-38% B), 28-33 min (38-40% B), 33-53 min (40-43% B), 53-63 min (43-60% B), 63-81 min (60-100% B). This allowed isolation of the six triterpenoid saponins 1-6, i.e., 660 mg of 1 (t_R 42.8 min), 420 mg of 2 (t_R 19.1 min), 1,450 mg of 3 (t_R 20.3 min), 320 mg of 4 (t_R 28.4 min), 56 mg of 5 (t_R 49.5 min) and 980 mg of 6 (t_R 51.4 min) (Figure 2). Compounds 2-6 were identified by direct comparison of their physical and spectral data (¹H-NMR and ¹³C-NMR) with those in the literature [1,13,14,15].