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Bioactive Constituents, Metabolites, and Functions
Flavoalkaloids with Pyrrolidinone Ring from Chinese Ancient Cultivated Tea Xi-Gui Jian Cheng, Fei-Hua Wu, Pu Wang, Jia-Ping Ke, Xiao-Chun Wan, Ming-Hua Qiu, and Guan-Hu Bao J. Agric. Food Chem., Just Accepted Manuscript • DOI: 10.1021/acs.jafc.8b02266 • Publication Date (Web): 05 Jul 2018 Downloaded from http://pubs.acs.org on July 7, 2018
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Journal of Agricultural and Food Chemistry
Flavoalkaloids with Pyrrolidinone Ring from Chinese Ancient Cultivated Tea Xi-Gui Jian Cheng1, Fei-Hua Wu3, Pu Wang3, Jia-Ping Ke1, Xiao-Chun Wan1, Ming-Hua Qiu2,*, Guan-Hu Bao1,* 1
Natural Products Laboratory, International Joint Laboratory of Tea Chemistry and
Health effects, State Key Laboratory of Tea Plant Biology and Utilization, Anhui Agricultural University, 230036, Hefei, People’s Republic of China 2
State Key Laboratory of Phytochemistry and Plant Resources in West China,
Kunming Institute of Botany, Chinese Academy of Sciences, Kunming 650201, People's Republic of China. 3
School of Traditional Chinese Pharmacy, China Pharmaceutical University, Nanjing
211198, People's Republic of China.
*
Telephone: +86-0871-5223327.
Fax: +86-0871-5223325,
E-mail:
Fax:
E-mail:
[email protected] *
Telephone:
+86-551-65786401.
+86-551-65786765.
[email protected]. 1
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2
Abstract: The Chinese Xi-Gui tea is one ancient cultivated variety of Camellia
3
sinensis var. assamica. It has been used for producing expensive and elite tea in China
4
presently.
5
(−)-6-(5'''S)-N-ethyl-2-pyrrolidinone-epicatechin-3-O-gallate
6
pyrrolidinone
7
(−)-6-(5'''R)-N-ethyl-2-pyrrolidinone-epicatechin-3-O-gallate (etc-pyrrolidinone F,2)
8
(−)-8-(5'''S)-N-ethyl-2-pyrrolidinone-epicatechin-3-O-gallate (etc-pyrrolidinone G, 3a),
9
(−)-8-(5'''S)-N-ethyl-2-pyrrolidinone-catechin-3-O-gallate (etc-pyrrolidinone I, 4a),
10
(−)-8-(5'''R)-N-ethyl-2-pyrrolidinone-catechin-3-O-gallate (etc-pyrrolidinone J, 4b),
11
and
12
(−)-8-(5'''R)-N-ethyl-2-pyrrolidinone-epicatechin-3-O-gallate (etc-pyrrolidinone H,3b)
13
together with the known flavoalkaloids etc-pyrrolidinones A−D (5, 6, 7a, ,7b ) were
14
detected and isolated from Xi-Gui green tea. Their structures were identified by
15
comprehensive NMR spectroscopic analyses. Absolute configurations of 1−3 were
16
established by comparison of the CD analyses with epicatechin-3-O-gallate (ECG).
17
Compounds 1−4 were evaluated for their protection against high glucose induced cell
18
senescence on human umbilical vein endothelia cells (HUVECs) and showed
19
significant protection effects (p < 0.01) at both 1.0 and 10 µM. Discussion on the
20
possible evolution of tea plant divergent from related food plants on the basis of
21
phytochemical view was also provided.
22
Keywords: etc-pyrrolidinone, (−)-epicatechin-O-gallate (ECG), Camellia sinensis,
23
(−)-catechin-O-gallate (CG), human umbilical vein endothelia cells (HUVECs)
Five
one
new
E,
new
etc-pyrrolidinone
naturally
occurring
24
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flavoalkaloids, (ester-type
catechins
E,
natural
1),
product
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25
Introduction
26
Tea, with numerous health benefits as well as special flavor, is one of the most
27
popular non-alcoholic drinks worldwide. The chemical constituents of tea have long
28
been studied, leading to discover a variety of compounds with different structural
29
skeletons.1 Recently, new catechins and their derivatives have been isolated from
30
different types of tea, including the B ring fission catechins from dark tea,
31
phenylpropanoidated catechins from dark tea as well as green tea and its leaves.2 A
32
caffeoylated catechin with impressive anti-acetylcholinesterase activity as well as its
33
neuroprotective effect through interaction with neutrophil gelatinase-associated
34
lipocalin was reported from the special purple tea Zijuan together with its biosynthetic
35
pathway in tea leaves.3,4 Carboxymethyl and carboxyl catechins were also found in
36
Pu-er ripe tea.5 Most interestingly, Wang reported three methylene bridged dimeric
37
imidazole alkaloids from Keemun black tea, which may evidence possible caffeine
38
catabolism pathway in tea plants.6 Additionally, several flavoalkaloids with a
39
pyrrolidinone ring substituted on the A ring of catechins had been found in black,7
40
Pu-er,8 white, and green tea as well as tea leaves.9
41
Flavoalkaloids are a unique class of secondary metabolites with the typical flavonoid
42
skeleton linked with a nitrogen containing 5-membered ring substituted at the position
43
C-6 or/and C-8 of the A ring of flavonoid core structure,10-14 which have attracted
44
academic interest not only in the unique nitrogen containing moieties, but also in the
45
pronounced diversity of biological activity, such as anticancer,15 antiviral properties,16
46
inhibition of advanced glycation end products (AGE),9,17 antioxidant activity,18 etc.
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Flavoalkaloids were found widely distributed in plants. In food materials, they had
48
been found from Actinidia arguta,17 Litchi chinensis,18 besides Camellia sinensis.
49
In tea, a dozen of flavoalkaloids have been reported, all sharing a characteristic ethyl
50
group (-CH2CH3) at the nitrogen atom.7-9 To find more flavoalkaloids from tea, we
51
screened different tea materials by ultra performance liquid chromatography coupled
52
with photodiode array detection and high resolution electrospray ionization mass
53
spectrometry (UPLC-PDA-HR-ESI-MS), indicating that the Chinese ancient
54
cultivated tea Xi-Gui (Xi-Gui) contains relative higher amount of this class of
55
compounds. Xi-Gui (Camellia sinensis var. assamica) grows in Mountain Manglu,
56
Xi-Gui village, Bangdong Town, Lincang County, in Yunnan province.19 Its excellent
57
flavor gets popular with the local residents. However, the low commercial output and
58
special geographical location result in expensive price and no systematic chemical
59
study. Therefore, Xi-Gui green tea was the preferential choice for our continuing
60
study from a natural product approach.
61
UPLC
62
(−)-epicatechin-3-O-gallate (ECG) than that of (−)-epigallocatechin-3-O-gallate
63
(EGCG). Through repeated column chromatography (CC) and comprehensive
64
spectroscopic analyses, we isolated and identified five pairs of flavoallkaloid
65
diastereomers from this Chinese elite tea. In this paper, the isolation, structural
66
elucidation, and protective effects against high dose of glucose induced senescence on
67
human umbilical vein endothelia cells (HUVECs) of the isolated flavoalkaloids (1-4)
68
as well as ECG were presented. The possible reason was also given for the higher
analyses
indicated
that
Xi-Gui
has
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a
higher
amount
of
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69
content of pyrrolidinonated ECG than that of EGCG in this cultivar. Additionally, we
70
discussed the evolutionary relationship between Actinidia arguta (Chinese kiwifruit)
71
and Camellia sinensis on the basis of the similarity and difference in the structure of
72
flavoalkaloids isolated from these species.
73
Materials and Methods
74
Chemicals. (+)-Catechin (C), (−)-gallocatechin (GC), (−)-catechin-3-O-gallate (CG),
75
and (−)-gallocatechin-3-O-gallate (GCG) standards were purchased from Chengdu
76
Pury Technology Co. Ltd (Chengdu, China). (−)-Epicatechin (EC), EGCG, ECG, and
77
(−)-epigallocatechin (EGC) were purified and identified in our laboratory. Analytical
78
grade of petroleum ether, ethyl acetate, methanol, and dichloromethane were
79
purchased from Chengdu Kelong Chemical Reagent Co., Ltd (Chengdu, China).
80
HPLC grade of methanol, acetonitrile, and formic acid were purchased from Duksan
81
Pure Chemicals Co., Ltd (Ulsan, Korea). HUVECs were bought from Shanghai
82
Honsun Bio Co. (Shanghai, China). Dulbecco’s minimum essential medium (DMEM,
83
Lot No. 1791930) was from Gibco Co. (CA, U.S.A.). Fetal bovine serum (FBS, Lot
84
No. 086005041) was from Genetimes Technology, Inc. (Shanghai, China). Beyotime
85
Institute of Biotechnology (Songjiang, Shanghai) provided the β-galactosidase
86
staining kit for cell senescence. The materials included MCI-Gel CHP20P (Mitsubishi
87
Ltd., Japan), silica gel (Yantai Jiangyou Silicon Development co., Ltd., Shandong,
88
China), Toyopearl HW-40F (Tosoh Bioscience Shanghai Co., Ltd., Shanghai, China),
89
Sephadex LH-20 (GE Healthcare Bio-Sciences AB, Sweden), ODS C-18 (ODS, Fuji
90
Silysia Chemical Ltd., Japan) were filled in open column chromatography (CC) to
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purify compounds for this study.
92
HPLC semi-preparation was performed on a Waters e2695 combined with a Waters
93
2998 PDA detector (Waters, Milford, Massachusetts, U.S.A.). The semi-preparative
94
column was X Bridge Prep C18 (10 × 250 mm i.d., 5 µm) (Waters, Wexford, Ireland).
95
An FTIR-650 spectrometer was used to observe IR spectrum which purchased from
96
Tianjin Gang Dong Sci. & Tech. Development Co., Ltd (Tianjin, China). Optical
97
rotation was measured on MCP 100 modular circular polarimeter (Anton Paar GmbH,
98
Graz, Austria). 1H and 13C NMR, HMBC, HSQC, ROESY, and 1H-1H COSY spectra
99
were recorded with a DD2 (600 MHz) spectrometer in DMSO-d6 (Agilent Inc., Santa
100
Clara, CA, U.S.A.). CD spectra were measured by a Jasco-810-CD apparatus (Jasco,
101
Tokyo, Japan). Mass spectra were performed on Agilent 1290 UPLC with a
102
photodiode detector array (PDA) coupled to a 6545 time-of-flight (TOF) mass
103
spectrometer with electrospray ionization (ESI) source (Agilent Inc., Santa Clara, CA,
104
U.S.A.). The melting point (m.p.) was observed on SGWX-4 micromelting point
105
apparatus purchased from Beijing Century Science Instruments Co., Ltd (Beijing,
106
China).
107
Tea Materials and Extraction for UPLC Quantification. Xi-Gui was bought from
108
Mount Manglu, Xi-Gui Village, Bangdong, Lincang County, Yunnan province, China,
109
in 2016. The other teas Longjingchangye, Shuchazao, Zijuan, Lu´an GuaPian, Kuding,
110
Fuding-Dabai were plucked in May 2017 from the tea base of Anhui Agricultural
111
University (Hefei, Anhui, China). The detailed extraction method can be found in the
112
literature.20 Briefly, ground tea powder 0.5 g was extracted in 20 mL 70% aqueous
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methanol by ultrasonic extraction. The tea extract were centrifuged at 10k rpm and
114
then run through a 0.22 µm filter to store the supernatant.
115
UPLC Quantification of Major Catechins and Caffeine in Xi-Gui
116
The gradient elution of mobile phase A was 0.17% aqueous acetic acid and mobile
117
phase B was acetonitrile in UPLC (Waters, USA) analysis. Details about UPLC
118
method can be found at our previous paper.20 Each sample was repeated trice. The
119
calculated regression equation, relative standard deviation (RSD, including
120
repeatability and reproducibility), correlation coefficient, limit of detection (LOD),
121
limit of quantification (LOQ), and the recovery ratio was also same as those in
122
literature.4
123
Extraction and Isolation. Xi-Gui (5 kg) was ground and extracted by petroleum
124
ether, ethyl acetate, and methanol (each for five times), successively.3 The methanol
125
extract was concentrated under reduced pressure at room temperature to afford a
126
methanol-soluble residue (805 g). This methanol residue was mixed into
127
dichloromethane (1:3, v/v) to provide dichloromethane-soluble fraction and an
128
aqueous phase (593 g). The aqueous phase was concentrated and subjected to
129
MCI-Gel CHP20P CC (water/methanol = 1:0−0:1) to obtain fractions A1−A21 and
130
then the fraction A7 (96 g) was subjected to Toyopearl HW-40F CC and eluted with
131
methanol/water (4:6, v/v), to yield eight fractions (C1 to C8). Fraction C8 (26 g) was
132
then subjected to Sephadex LH-20 CC (methanol/water = 1:9−0:1) to provide
133
fractions D1−D30. D19 was performed on repeated HPLC eluted with gradient
134
acetonitrile/water (gradient elution of acetonitrile was set as follows: 0−35 min, 19%)
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to produce compound 1 (85 mg), 2 (80 mg), 3 (105 mg), 4 (116 mg), 5 (15 mg), 6 (8
136
mg), 7 (35 mg), respectively (Figure S1).
137
UPLC−ESI-MS/MS Analysis. UPLC−ESI−MS/MS analysis was performed on an
138
Agilent 1290 UPLC instrument with a PDA coupled to a 6545 time-of-flight (TOF)
139
mass spectrometer with ESI source in negative mode. The analysis was obtained by
140
using an ACQUITY UPLC® BEH Shield RP18 column (2.1 × 150 mm, i.d., 1.7 µm)
141
and Agilent qualitative analysis software for data acquisition. The solvent system and
142
the gradient elution condition are same as that in literature.9 The tea sample was
143
gained by ultrasonic extracting 0.25 g of tea powder after ground in 10 mL of
144
methanol for five times within 10 h (20 min each time) for UPLC−ESI−MS/MS
145
analysis. Mass spectra were achieved in full scan MS mode from m/z 100 to 1700.
146
Assay for Protection against High Dose Glucose Induced Senescence on HUVECs.
147
Healthy HUVEC cells were transferred into cell culture bottles under sterile
148
conditions. 10% FBS DMEM medium was placed in a 5% CO2 incubator and
149
incubated at 37 °C. The culture medium was changed once every 1-2 days. After 3-5
150
days of inoculation, the cells grew densely in monolayer and fused and island shaped.
151
When the cells were grown to the fusion stage, they were digested by 0.25% trypsin
152
and passaged by 1:4.21
153
Compounds 1−4, and ECG were dissolved in DMSO, and then diluted to the desired
154
concentrations (1.0 and 10 µM) with the medium, and the final concentration of
155
DMSO was not more than 0.1%. Metformin (300 µM) was used as the positive
156
control. HUVEC cells from logarithmic growth phase were digested into single cell
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suspension, and 10% FBS DMEM medium was suspended and inoculated in 6-well
158
plates. It was divided into normal group, model group, and drug group. The normal
159
group was HUVECs and the model group was HUVECs co-cultured with 33 mM
160
glucose, and the drug group was HUVECs co-cultured with high glucose plus tested
161
compounds. After 48 h, the culture supernatant was abandoned. Each group was
162
operated according to the instruction of the β-galactosidase staining kit. Finally, the
163
cell senescence was observed by inverted fluorescence microscope (model,
164
IX51S8F-3, from Sigma).
165
Statistical Analysis
166
All assay experiments were obtained ≥ triplicate and the values were presented as
167
mean ± SD. One way ANOVA with Turkey tests was applied to determine significant
168
differences (*P < 0.05, **P < 0.01, ***P < 0.001). GraphPad Prism (version 6.0)
169
software was applied for statistical analysis.
170
Results and Discussion
171
UPLC Quantification of Major Catechins and Caffeine in Xi-Gui tea
172
To quantify the major constituents from Xi-Gui and other green tea, we used UPLC
173
method (Figure 1).20 Table 1 shows that Xi-Gui has the same 8 major catechins as
174
those from other teas with comparative amount. It has the strikingly highest amount of
175
ECG among all the tested samples,which is even significantly higher than that of
176
EGCG (P < 0.01). ECG may help the heart failure patients through improving
177
contractile function as well as reducing pathological remodeling in the dysfunctional
178
heart, suggesting that Xi-Gui tea with the highest amount of ECG may be useful in
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decreasing cardiac mortality and could be developed as related healthy products.22
180
However, the amount of EGCG, EGC, and EC from Xi-Gui is the smallest among all
181
the samples. Additionally, it also has the highest amount of caffeine, C, which
182
followed by the amounts of GC and CG.
183
Isolation and Identification of Flavoalkaloids from Xi-Gui. Xi-Gui was extracted
184
by petroleum ether, ethyl acetate, and methanol, successively, for phytochemical
185
investigation. The methanol-soluble extract was concentrated and then extracted with
186
dichloromethane. The aqueous residue was fractionated by opened CC and
187
semi-preparative HPLC to provide six flavoalkaloids (Figure 2), two new pure
188
compounds (1 and 2) and two pairs of isomers (3a and 3b, 4a and 4b) in addition to
189
the known flavoalkaloids etc-pyrrolidinones A−D (5, 6, 7a, 7b).9
190
Compounds 1−4 showed the similar IR spectrum, which suggested the presence of
191
hydroxyl groups (broad peak around 3397 cm-1), carbonyl group (around 1695 cm-1),
192
aromatic rings (around 1620, 1520 cm-1).9 Their ESI−HR−MS showed the same
193
deprotonated molecular ion peak at m/z 552.1551 [M-H]− (calcd for 552.1506)
194
corresponding to the molecular formula C28H27NO11, with 16 degrees of unsaturation.
195
The odd number of the molecular weight (553) also suggested the presence of a
196
nitrogen atom in the molecule. The UV λmax (MeOH) peaks of compounds 1−4 are at
197
around 207, 278 nm (Figure S1). The 1H and 13C NMR data of the isomers 1−4 are
198
nearly the same (Table 2 and 3). Above experimental results suggest that these
199
flavoalkaloids are diastereomers.
200
Compound 1 was observed as a white amorphous powder, m.p.: 204-205 °C, [α]25D
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-65.1 (c 0.1, methanol). The 1H and
13
202
existence of an ECG skeleton in the molecule could be easily deduced from the 1H
203
NMR spectrum compared with that of ECG (Table 2, Figure S2 & S3). The typical
204
proton signals for rings A, B, and C are similar to those of ECG (Table 2), at δH 5.07
205
(1H, br s, H-2), 5.38 (1H, br s, H-3), 3.04 (1H, m, H-4β), 2.79 (1H, d, J = 16.8 Hz,
206
H-4α) (ring C), 6.86 (1H, d, J = 1.2 Hz, H-2'), 6.66 (1H, d, J = 8.4 Hz, H-5'), 6.75 (1H,
207
dd, J = 1.2 Hz, 8.4 Hz, H-6') (ring B), 6.01 (1H, s) (ring A), 6.82 (2H, s) (galloyl-2H),
208
respectively. A single proton signal at A-ring suggested H-6 or 8 of was substituted.
209
Besides signals from ECG unit, the 1H (δH at 2.26 and 2.40 m for H-3''', 2.01 and 2.26
210
m for H-4''', 5.23 m for H-5''', 2.41 and 3.39 m for H-6''', 0.89 for H-7''') and 13C NMR
211
spectra showed signals attributable to a carbonyl (δC 173.3, C-2'''), two methylenes (δC
212
31.1, 23.3, C-3''' and 4'''), a methine (δC 51.5, C-5'''), and an ethyl group (δC 34.3, 12.5,
213
C-6''' and 7'''). The presence of a partial structure of −CH2−CH2−CH− can be deduced
214
by the 1H−1H COSY correlations. HMBC spectrum indicated that the methine carbon
215
(δC 51.5, C-5''') were correlated with the methylene signals (δH 3.39, 2.41, H-6''') at
216
the N-ethyl group. The methylene protons (δH 2.26, 2.40 H-3''') were correlated with
217
the carbonyl carbon (δC 173.3, C-2'''). These HMBC and 1H−1H COSY correlations
218
outlined the presence of an N-ethyl-2-pyrrolidinone ring (Figure 3).9 The only one
219
strong ROESY correlation of the signal (δH 6.01, H-8) with 7-OH proton (δH 9.32)
220
(Figure S11) revealed that the N-ethyl-2-pyrrolidinone moiety was attached at C-6
221
position, which can also be demonstrated by the HMBC correlations between H-5'''
222
(δH 5.23) and C-5 (δC 154.5), C-7 (δC 155.7) (Figure 3). The key HMBC correlations
C NMR data of 1 are shown in Table 2. The
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223
between H-4 (δH 2.79) and C-5, 9, and 10 (δC at 154.5, 154.6, 98.4, respectively) can
224
also assign the NMR data of related positions (Figure 3). Thus, the structure of 1 can
225
be decided as 6-N-ethyl-2-pyrrolidinone ECG.
226
Compound 2 was obtained as a white amorphous powder, m.p.: 206-207 °C, [α]25D
227
-135.6 (c 0.1, methanol). Comparing the ESI-HR-MS, 1H, and 13C NMR spectra with
228
those of 1 and ECG (Table 2), compound 2 was determined to be an isomer of 1. The
229
strong ROESY correlation of the signal at A−ring (δH 6.03, H-8) with 7-OH proton
230
(δH 9.45), and the signals (δH 2.76, 3.02, H-4α, 4β) with 5-OH proton (δH 8.55)
231
(Figure S19) both revealed the attachment of N-ethyl-2-pyrrolidinone group at C-6
232
position, indicating that the proton signal (δH 6.03) belongs to H-8 (Table 2).23
233
Besides the similar key HMBC correlations to those of compound 1, correlations
234
between 5-OH (δH 8.55) and C-5, 6, and 10 (δC at 154.9, 107.1, 98.8, respectively)
235
were also observed in the HMBC spectrum of compound 2 (Figure 3).23
236
The absolute configurations at C−2/3 of both flavoalkaloids (1 and 2) were confirmed
237
to be 2R, 3R by comparing NMR data as well as CD curves with that of ECG (Figure
238
S40).8,9,24 Thus, compounds 1 and 2 share the same structure core 6-pyrrolidinone
239
ECG with the only difference at the position C-5'''. The CD spectra of 1 and 2 were
240
compared after subtracting the CD spectrum from each other (Figure 4A).8,9,24 For 1,
241
the arithmetically isolated CD curves of C-5''' showed a strong positive cotton effect
242
(CE) at 211 nm (∆ε+21.0) and was determined to be of the 5'''S-configuration.
243
Therefore,
244
(−)-6-(5'''S)-N-ethyl-2-pyrrolidinone-epicatechin-3-O-gallate
the
structure
of
compound
1
was
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determined and
to
named
be as
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Journal of Agricultural and Food Chemistry
245
etc-pyrrolidinone E. Meanwhile, compound 2 presented a negative CE at 211 nm (∆ε
246
− 21.0) comparing with that of 1 by the arithmetically subtracted CD curves (Figure
247
4A) and thus was determined to have a 5''' R-configuration. Therefore, the structure of
248
compound
249
(−)-6-(5'''R)-N-ethyl-2-pyrrolidinone-epicatechin-3-O-gallate
250
etc-pyrrolidinone F.
251
Compounds (5"'S) 3a and (5"'R) 3b are a mixture (Figure S20) in the format of
252
colorless amorphous powder, m.p.: 203-204 °C, [α]25D -168.6 (c 0.07, methanol). The
253
1
254
Furthermore, 3a and 3b can be identified by 2D NMR spectroscopy with similar
255
analyses to those of 1 and 2 (Figure S43). Additionally, the ROESY correlations of
256
both protons (3a: δH 6.04, 3b: 6.09) with 5-OH and 7-OH proton (δH 9.40, δH 9.24)
257
(Figure S27) confirmed that the two protons are both H-6, and thus, the
258
N-ethyl-2-pyrrolidinone group at 3a and 3b were both decided to be linked to the C-8
259
position.
260
(−)-8-N-ethyl-2-pyrrolidinone-epicatechin-3-O-gallate. The positive CE around 203
261
nm (∆ε+11.1) of compound 3 apparently originated from the chirality of 5'''-S
262
(Figure S40A).24 Since both compound 3 and ECG have the same CE contribution
263
from C-2R and 3R, we also used the same subtracting method to establish the only
264
remaining stereocenter at C-5''' of compound 3 through subtracting the CD spectrum
265
of ECG from that of compound 3. At the same time, the C-5'''R and S can contribute
266
opposite CE,24 the substracting result should be from the remaining stereocenter of the
H and
was
2
determined
to and
be named
as
13
C NMR spectra of 3a and 3b show similarity to those of 1 and 2.
So,
compounds
3a
and
3b
were
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determined
to
be
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267
major compound.24 Compound 3 (major is 3a) presented a positive CE at 207 nm (∆ε
268
+17.1) comparing with that of ECG8,9,24 (Figure 4B). Thus the major one 3a was
269
determined to have a 5'''S-configuration and named as etc-pyrrolidinone G while the
270
minor
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(−)-8-(5'''R)-N-ethyl-2-pyrrolidinone-epicatechin-3-O-gallate
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etc-pyrrolidinone H.
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Compounds (5"'R) 4a and (5"'S) 4b are a colorless amorphous powder, m.p.:
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206-207 °C, [α]25D -330.8 (c 0.1, methanol). Compounds 4a and 4b are also a mixture
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(Figure S28). The negative [α]25D value suggested that compound 4 should have a 3R
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configuration as that of compounds 1-3 too,25 because a 3S configuration will
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contribute a positive value, indicating that it possesses an ECG or CG skeleton.
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However, it cannot possess an ECG skeleton because 1-3 are all the diastereomers
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with the ECG skeleton already. The key ROESY correlations between H-2 and both
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H-4α and 4β can establish the α orientation of H-2, different from those of
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compounds 1−3, and 5−7 which all only have the ROESY correlations between H-2
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and H-4β, indicating that they all share a β orientation of H-2 (Figure 5, S42),
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suggesting that compound 4 has a CG skeleton. Additionlally, the HPLC appearance
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(Figure S1), 1H and 13C NMR spectra of compounds 4a and 4b were similar to those
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of CG (such as that CG was eluted later then ECG in the HPLC spectrum and
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8-pyrrolidinone CG was also eluted later than 8-pyrrolidinone ECG, Figure 1).25-28
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Thus, in combination with other 2D NMR correlations including COSY and HMBC
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(Figure
one
S43),
3b
compound
was
4
determined
was
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as named
established
as
as
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(−)-8-N-ethyl-2-pyrrolidinone-catechin-3-O-gallate, sharing a CG skeleton. Using the
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same CD spectrum subtracting method as we analyzed with the case of compound 3,
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compound 4 (major is 4a) presented a negative cotton effect at 212 nm (∆ε -21.3)
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comparing with that of CG by the arithmetically subtracted CD curves (Figure 4B).
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The major compound 4a was thus determined to have a 5'''R-configuration and named
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as etc-pyrrolidinone I. The minor one 4b was determined as 5'''S-configuration and
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named as etc-pyrrolidinone J.
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To further study flavoalkaloids from tea, we try to screen different tea materials to
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find a tea variety with high content of this class of compounds, leading to find that
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Xi-Gui is the highest one with an amount of about 100 ppm compared to several ppm
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in white tea Fuding-Dabai on the basis of the isolated quantity.9 However, complete
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separation of all the diastereomers are not achieved yet since flavoalkaloids tend to
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appear as pairs of diastereomers naturally.9,17,18,24 It seems those with pyrrolidinone
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substituted at the position C-8 are always difficult to be separated. Presently, we have
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only got four completely pure 6-pyrrolidinonated flavoalkaloids. We also found that
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the contents of these flavoalkaloids may be related to that of the structure core
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compounds. For example, the highest amount of ECG (Table 1) may contribute to the
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highest amount of pyrrolidinonated ECG in Xi-Gui, while the relative highest EGCG
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leads to the correspondingly highest pyrrolidinonated EGCG in Fuding-Dabai.9
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UPLC−ESI-MS/MS Detection of the Isolated Flavoalkaloids in Xi-Gui. In this
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study, the isolated six flavoalkaloids (1−4b) can be detected in Xi-Gui by
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UPLC−ESI-MS/MS analysis guided by the selected mother ion (deprotonated
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molecular weight m/z 552.1545 [M-H]−) (Figure 6). The result shows that these six
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flavoalkaloids (1−4b) exist originally in Xi-Gui (Figure 6A), which also implies that
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the original flavoalkaloids present in tea are not only in the epi-type such as
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pyrrolidinonated EGCG and ECG,9 but also in other type such as pyrrolidinonated CG,
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although the amount is different. The fragmental peaks at 400, 382, 236, 169, 125
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(Figure 6B) in the MS/MS spectrum correspond to the elucidated fragmental
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structures as shown in Figure 6C, which further confirmed the identified
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structures.8,9,29
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Protection against High Dose Glucose Induced Senescence on HUVECs by
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Flavoalkaloids 1−4.
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The β-galactosidase was located in cytoplasm, and the positive product was blue. The
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rate of β-galactosidase positive cells in the cell aging model group (high glucose
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group, HG, 30 mM) was significantly higher than that in the normal control group (P
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= 0.000). Figure 7 implies that the positive control methformin (300 µM) and all
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pyrrolidinonated ECG (1−4) together with ECG (1.0 and 10µM) can prevent
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endothelia dysfunction and be helpful in protection against vascular cell aging (P
