Metabolomics of the Protective Effect of <i>Ampelopsis grossedentata</i> and Its Major Active Compound Dihydromyricetin on the Liver of High-Fat Diet Hamster

Fan, Lanlan; Qu, Xiaosheng; Yi, Tao; Peng, Yong; Jiang, Manjing; Miao, Jianhua; Xiao, Peigen

doi:https://doi.org/10.1155/2020/3472578

Evidence-Based Complementary and Alternative Medicine

On this page

Abstract Introduction Materials and Methods Results Discussion Conclusions Abbreviations Data Availability Conflicts of Interest Authors’ Contributions Acknowledgments Supplementary Materials References Copyright Related Articles

Research Article | Open Access

Volume 2020 | Article ID 3472578 | https://doi.org/10.1155/2020/3472578

Metabolomics of the Protective Effect of Ampelopsis grossedentata and Its Major Active Compound Dihydromyricetin on the Liver of High-Fat Diet Hamster

Lanlan Fan,^1,2Xiaosheng Qu,²Tao Yi,³Yong Peng,⁴Manjing Jiang,¹Jianhua Miao,²and Peigen Xiao⁴

Academic Editor: Samra Bashir

Received03 Jul 2019

Revised30 Sept 2019

Accepted05 Oct 2019

Published28 Jan 2020

Abstract

The flavonoid dihydromyricetin (DMY) is the main component of Ampelopsis grossedentata (Hand-Mazz) W. T. Wang (AG), a daily beverage and folk medicine used in Southern China to treat jaundice hepatitis, cold fever, and sore throat. Recently, DMY and AG were shown to have a beneficial effect on lipid metabolism disorder. However, the mechanisms of how DMY and AG protect the liver during lipid metabolism disorder remain unclear. In this study, we first analyzed the chemical compounds of AG by HPLC-DAD-ESI-IT-TOF-MSⁿ. Of the 31 compounds detected, 29 were identified based on previous results. Then, the effects of DMY and AG on high-fat diet hamster livers were studied and the metabolite levels and metabolic pathway activity of the liver were explored by ¹H NMR metabolomics. Compared to the high-fat diet group, supplementation of AG and DMY attenuated the high-fat-induced increase in body weight, liver lipid deposition, serum triglycerides and total cholesterol levels, and normalized endogenous metabolite concentrations. PCA and PLS-DA score plots demonstrated that while the metabolic profiles of hamsters fed a high-fat diet supplemented with DMY or AG were both far from those of hamsters fed a normal diet or a high-fat diet alone, they were similar to each other. Our data suggest that the underlying mechanism of the protective effect of DMY and AG might be related to an attenuation of the deleterious effect of high-fat diet-induced hyperlipidemia on multiple metabolic pathways including amino acid metabolism, ketone body metabolism, energy metabolism, tricarboxylic acid cycle, and enhanced fatty acid oxidation.

1. Introduction

Ampelopsis grossedentata (Hand-Mazz.) W. T. Wang (AG), also known as Vine tea, is a plant species mainly distributed in central and southern China which is rich in flavonoids, polysaccharides, and polyphenols. First used by the Zhuang and Yao people [1], it became later also widely used in Tujia, Lahu, Dong, Jinuo, and Hakka areas. Besides consumption as a tea prepared from the tender stems and leaves, AG is also used to treat jaundice hepatitis, cold fever, and sore throat. Next too its antioxidant [2] and anti-inflammatory effects [3], it can also normalize blood lipid [4] and sugar [5] levels and attenuate liver injuries [6].

Dihydromyricetin (DMY), which is the main flavonoid of AG with a content of up to 35% [7], showed antiproliferation capacities in lung [8], breast, [9], and ovarian cancer [10], improvements on hypertension [11], hyperlipidemia [12, 13] and abnormal blood sugar levels [14], as well as neuroprotective activity against Alzheimer’s disease [15], Parkinson’s disease [16], alcohol addiction, depression [17], and dermatoprotection [18]. In addition, a preventive effect on myocardial fibrosis [19], myocardial hypertrophy [20], and cardiac ischemia/reperfusion injury [21] was reported.

The liver plays an important role in the digestion, absorption, oxidation, decomposition, and transformation of nutrients such as lipids, proteins, and sugars [22]. Abnormal accumulation and distribution of lipids and their metabolites in the body result in lipid metabolic disorder which is an important inducer of diabetes, atherosclerosis, nephrotic syndrome, and cardio- and cerebrovascular disease. Considering the health impact of chronic metabolic diseases such as hyperlipidemia, safe and reliable functional compounds from natural sources are highly needed. Based on the remarkable blood lipid regulating characteristics described in the literature [23–26], both AG and DMY might possess great health-promoting potentials; however, their capacity to prevent liver injury as well as the underlying mechanisms is unknown.

Metabolomics, reflecting the overall changes of the organism by studying the changes of endogenous metabolite levels, has recently played an important role in revealing the pharmacodynamics and mechanism of some disease [27–29] or traditional Chinese medicine [30].

Since up to 85% cholesterol is synthesized extrahepatic in male hamsters, hyperlipidemia can be caused in a relatively short period of time. Thus, as the lipid metabolism of hamsters is similar to that of human, especially male hamsters are widely used as a model organism of lipid metabolism disorder [31, 32].

In this study, the chemical compounds of AG were first analyzed by liquid chromatography-mass spectrometry. Then, the lipid metabolism disorder model of hamster was induced by high-fat diet, and the preventive effect of AG and DMY on hyperlipidemia and hyperglycemia was studied by liver metabolomics.

2. Materials and Methods

2.1. Chemicals and Materials

Acetonitrile and formic acid, both LC-MS grade, were purchased from Fisher (Fair Lawn, New Jersey, USA) and Sigma-Aldrich (St. Louis, USA), respectively. For sample extraction, analytical grade methanol and ethanol was used while deionized water was obtained from a Milli-Q water purification system (Millipore, Bedford, MA, USA).

Ampelopsis grossedentata (Hand-Mazz.) W. T. Wang (AG) was purchased from Dayaoshan natural plant development Co. Ltd. (Guangxi, China) and identified by Professor Yi Cai from Guangxi University of Chinese Medicine (Figure 1). Dihydromyricetin (DMY) was purchased from Chengdu preferred Biological Technology Co., Ltd. (Chengdu, China) with purity above 98%.

(a)

(b)

2.2. Sample Preparation

For LC-MS analysis, the AG sample was crushed through an 80-mesh sieve and dried at 50°C to constant mass. Next, 0.5 g powder was dissolved in 50 mL of methanol and ultrasonically extracted for 40 min. The extract was filtered, the primary filtrate was discarded, and the filtrate was diluted 100 times and filtered through a 0.22 μm filter. For the animal experiments, 150 g AG power was soaked in 5000 mL boiling water for 15 min and concentrated to 0.6 g crude drug/ml.

2.3. HPLC-DAD-ESI-IT-TOF-MSⁿ Analysis

High-performance liquid chromatography with a diode array detector and combined with electrospray ionization ion trap time-of-flight multistage mass spectrometry (HPLC–DAD–ESI-IT-TOF-MSⁿ) analyses was performed with a Shimadzu LCMS-IT-TOF instrument including two LC-20AD pumps, a SIL-20AC autosampler, a CTO-20A column oven, a SPD-M20A PDA detector, a CBM-20A system controller, an ESI ion source, and an IT-TOF mass spectrometer (Shimadzu, Kyoto, Japan).

The chromatography separations were performed on a Merck Purospher STAR RP-18 column (250 mm × 4.6 mm, 5 μm) with a column temperature of 40°C. The mobile phase consisted of 0.1% formic acid (v/v) (A) and acetonitrile (B) using a gradient program of 50–58% B in 0–17 min, 58–70% B in 17–20 min, 70–85% B in 20–26 min, and 85–90% B in 26–35 min. The solvent flow rate was 1.0 mL/min. The PDA detector wavelength was 350 nm.

For ESI-IT-TOF-MSⁿ analysis, the mass spectrometer was programmed to execute a full scan over m/z 100–1000 (MS¹) and m/z 50–1000 (MS² and MS³) in both positive-ion (PI) and negative-ion (NI) detection modes with the following settings: a flow rate of 0.2000 mL/min, a heat block and curved desolvation line temperature of 250°C, a flow rate of the nebulizing nitrogen gas of 1.5 L/min, an interface voltage of (+) 4.5 kV and (−) −3.5 kV, a detector voltage of 1.70 kV, an ion accumulation time of 20 ms, and a relative collision-induced dissociation energy of 50%. Trifluoroacetic acid sodium solution (2.5 mM) was used to calibrate the mass range from 50 to 1000 Da. All data were recorded and analyzed with Shimadzu LCMS solution Version 3.60, Formula Predictor Version 1.2, and Accurate Mass Calculator (Shimadzu, Kyoto, Japan).

After collecting LC/MS data, the mass spectrum of each chromatographic peak was extracted based on excimer ions ([M + H]+, [M − H]−) and loading ions ([M + NH₄]⁺, [M + Na]⁺, [M + Cl]⁻, [M + HCOO]⁻, etc.). With PeakView 1.2 software, the relative molecular mass of the primary mass spectrometry was obtained and the molecular formula was fitted in the mass deviation range of 5 × 10⁻⁶. The chemical compounds of AG and its genus were then collected and sorted out with the Scifinder and Reaxys databases. Next, secondary mass spectrometry information of the chromatographic peak and the corresponding fragment ions of the compound were obtained and the chemical composition was compared with the literature based on the cleavage of the ions and the reference substance.

2.4. Animal Experiments

Animal care and procedures were approved by and conducted according to the standards of the Guangxi University of Chinese Medicine (Nanning, China). Male LVG hamsters (110–130 g, 8 weeks old, Vital River Laboratory Animal Technology Co., Ltd., Beijing, China) were maintained in a temperature-controlled (22–25°C) room on a 12 h : 12 h light-dark cycle with food and water ad libitum. One week after adaptive feeding, the hamsters were randomly divided into five groups with six animals in each group: normal diet group (ND), high-fat diet group (HFD), high-fat diet supplemented with Ampelopsis grossedentata group (2 g/kg.d) (HFD + AG), high-fat diet supplemented with dihydromyricetin group (173 mg/kg.d) (HFD + DMY), and high-fat diet supplemented with simvastatin group (2.5 mg/kg.d) (HFD + ST). The AG dose was derived through dose conversion of literature data [1], whereas the DMY dose was calculated based on its content in AG. The high-fat diet consisted of 73.5% basic feed, 24.5% lard, and 2% cholesterol. At week 8, the animals were fasted for 12 hours and anesthetized with intraperitoneally injection of 3% pentobarbital sodium (0.3 mL/100 g), and blood was drawn from the ophthalmic plexus veins. The blood samples were centrifuged at 3000 rpm for 10 min, and the serum levels of total cholesterol (TC), triglycerides (TG), high-density lipoprotein (HDL), low-density lipoprotein (LDL), aspartate aminotransferase (AST), and alanine aminotransferase (ALT) were measured by the Automatic Biochemical analyzer (HITACHI 7600, Hitachi High-Tech Co., Ltd., Japan). After the blood was collected, the animals were sacrificed and the liver of each group was weighed, frozen sections were taken, and oil red O staining was used to mark the fat. The remaining samples were frozen in liquid nitrogen and stored at −80°C. Hepatic lipids including hepatic TC and TG were measured by commercial kits (Applygen Technologies Inc., Beijing, China).

2.5. Liver Metabolomics

Fifty milligrams frozen dried liver sample powder was washed twice in 1000 μL purified water and centrifuged at 13000 rpm for 15 min. After the last wash, 450 μL supernatant was mixed with 50 μL DSS (4,4-dimethyl-4-silapentane-1-sulfonic acid) standard solution (Anachro, Canada). All NMR spectra were acquired using a standard Bruker noesygppr1d pulse sequence on a Bruker AV III 600 MHz spectrometer equipped with an inverse cryoprobe operating at 600.13 MHz (Bruker Biospin, Milton, Canada). In total, 256 scans were collected into 32768 data points over a spectral width of 8000 Hz. Fourier transformation, phase adjustment, and baseline correction of the ¹H NMR free induction decay (FID) signal was done with Chenomx NMR suit (version 8.1, Chenomx, Edmonton, Canada). DSS-d6 peak (0.0 ppm) was used as the standard for all chemical shifts of the spectrograms. Reverse convolution was performed to adjust the peak shape. The variable matrix was used as the source data for subsequent PCA and PLS-DA analysis. The distribution and relative quantification of the identified metabolites were analyzed by Ward’s Hierarchical Clustering and visualized with a heatmap. In the heatmap, the red and blue colors indicate higher and lower relative content compared to the average value, respectively. The identification of biomarkers and the analysis of metabolic pathways were carried out using the Human Metabolomics Database (HMDB) and the Kyoto Encyclopedia of Genes and Genomes (KEGG). The metabolic pathways were visualized using MetPA network software (http://metpa.metabolomics.ca/) [33]. Each circle in the graph represents a differential metabolic pathway obtained through metabolic pathway analysis, and the color of each circle represents the magnitude of value: the more red the color, the smaller the value (see supplementary material). The higher the significance, the larger the value of the corresponding −log(p). The size of the circle indicates the influence of the metabolic pathway, thus the bigger the circle, the greater its influence. As such, the closer the position of the circle is to the upper right side of the diagonal line in the resulting figure, the more likely the metabolic pathway is biologically relevant.

2.6. Statistical Analysis

The data were expressed as the mean ± standard error of the mean (SEM). One-way ANOVA was used to analyze significant differences among multiple groups, while couple comparisons were performed via the t test. Statistical values of and were considered significant.

3. Results

3.1. HPLC-DAD-ESI-IT-TOF-MSⁿ Analysis of Ampelopsis grossedentata

For the detection of the chemical compounds of AG, both the positive- and negative-ion modes of the mass spectrometer were tested. The AG sample was analyzed under the “2.3” chromatographic and mass spectrometric conditions to obtain the base peak intensity (BPI) chromatograms in HPLC-DAD-ESI-IT-TOF-MSⁿ (Figure 2.) In total, 31 flavonoid compounds were obtained of which 29 could be identified based on our previous results [34] and literature data [35–40] (Table 1 and Figure 3). Of note, the retention time of DMY was 20.387 min.

3.2. Analysis of AG and DMY on Physiology of Hamsters on a High-Fat Diet

LVG hamsters were randomly divided into five groups with six animals in each group: a normal diet group (ND), a high-fat diet group (HFD), a high-fat diet group supplemented with 2 g/kg.d AG (HFD + AG), a high-fat diet group supplemented with 173 mg/kg.d DMY (HFD + DMY), and a high-fat diet group supplemented with 2.5 mg/kg.d simvastatin (HFD + SV). The water extract of AG and DMY was given from the start of the high-fat diet to check their preventive effects, while SV was given two weeks after the lipid metabolism disorder model was set up.

The obtained ¹H NMR sample spectra were analyzed in combination with the Chenomx self-contained database. In total, 66 metabolites and their corresponding absolute concentration values were obtained in liver samples (Supplementary material Figures 1 and 2).

Earlier, a dyslipidemia hamster model was produced after 2 weeks of high-fat diet [31]. After 8 weeks, at the end of the experiment, the blood serum of the animals fed a high-fat diet was lipemic, showing a milky white semisolid (data not shown). Compared to ND, a significant increase in the body weight, liver index, liver TC and TG, serum TC, TG, HDL, LDL, ALT, and AST levels was observed in HFD, HFD + AG, HFD + DMY, and HFD + SV (Figure 4). Compared to HFD, body weight, liver index, liver TC and TG, serum TC, TG, LDL, ALT, and AST levels were significantly lower in HFD + AG and HFD + DMY. Compared to HFD, HDL was higher in HFD + AG and HFD + DMY (Figure 4). Although most effects of AG and DMY on regulating blood lipids and hepatic lipids were similar to those observed with SV, AG and DMY had more beneficial effects on HDL, AST, and ALT than SV.

(a)

(b)

(c)

(d)

(e)

(f)

(g)

(h)

(i)

(j)

During anatomy, the shape and color of the liver of the individual animals were examined. Livers of ND showed a glossy dark red color and had a greasy feeling, a regular shape, sharp edges, and a grainy surface. Livers of HFD were larger compared to those of ND and had a yellow-brownish color, and the tissue cut surface had a greasy feeling. Livers of HFD + AG and HFD + DMY were larger compared to those of ND and had a pink color and a regular shape. The livers of HFD + SV were smaller compared to those of HFD and had a yellow-brownish color and granular bumps on the surface.

Oil red O staining indicated that livers from HFD had more lipid deposition compared to ND (Figures 5(a) and 5(b)). Livers from HFD + AG and HFD + DMY had less lipid deposition compared to HFD (Figures 5(c) and 5(d)). Livers from HFD + SV had less lipid deposition compared to HFD, although larger fat particles were still visible (Figure 5(e)).

(a)

(b)

(c)

(d)

(e)

3.3. Analysis of AG and DMY on Liver Metabolome of Hamsters on a High-Fat Diet

Endogenous metabolites in the liver of hamsters belonging to the different experimental groups were detected by ¹H NMR (Table 2). Unsupervised PCA and PLS-DA, used for dimensionality reduction of multidimensional data, indicated that ND and HFD were separated from each other suggesting that the generation of the high-fat diet model was successful (Figures 6(a), and 6(b)). In addition, HFD + AG and HFD + DMY were separated from HFD, indicating that the lipid metabolism disorder of the high-fat diet hamster was partially alleviated or contained through AG or DMY supplementation (Figures 6(a), and 6(b)). There was little overlap between the 95% confidence region of HFD + AG and HFD + DMY, indicating that both groups had similar effects on liver metabolism of animals on high-fat diet.

(a)

(b)

(c)

(d)

(e)

(f)

(g)

Based on the results of the cluster analysis, the distribution and relative quantification of the identified metabolites were visualized with a heatmap. Similar to PCA and PLS-DA, ND and HFD belonged to two different clusters in the heatmap, while there was some overlap between HFD + AG and HFD + DMY (Figure 6(g)).

Variable importance in projection (VIP) is a weighted sum of squares of the PLS loadings taking into account the amount of explained Y-variation in each dimension and shows important features identified by PLS-DA (Figure 6(c)). After treatment with high-fat diet, the affected metabolic pathways included synthesis and degradation of ketone bodies, alanine, aspartate and glutamate metabolism, glycine, serine, and threonine metabolism, taurine and hypotaurine metabolism, D-glutamine and D-glutamate metabolism, arginine and proline metabolism, beta-alanine metabolism, pantothenate and CoA biosynthesis, and pyruvate metabolism (Figure 6(d), details are shown in Supplementary material Table 1).

Comparing HFD to HFD + AG or HFD + DMY, respectively, indicated that the effects of the different treatments on high-fat diet were overlapping. Affected metabolic pathways included alanine, aspartate, and glutamate metabolism; synthesis and degradation of ketone bodies; glycine, serine, and threonine metabolism; taurine and hypotaurine metabolism; arginine and proline metabolism; β-alanine metabolism; pantothenate and CoA biosynthesis; and pyruvate metabolism (Figure 6(e) and 6(f), Supplementary material Tables 2 and 3). Interestingly, supplementation of high-fat diet with AG or DMY resulted in a huge increase of trimethylamine (TMA) (Figure 7 and Table 2) compared to HFD.

4. Discussion

The current study consisted of two parts. First, the chemical composition of AG was analyzed by HPLC-DAD-ESI-IT-TOF-MSⁿ. Then, the effect of AG and DMY on the metabolome of livers from high-fat diet hamsters was analyzed by ¹H NMR.

4.1. Analysis of the Chemical Composition of AG

With HPLC-DAD-ESI-IT-TOF-MSⁿ, 31 compounds were detected in AG extracts, 29 of which could be identified based on our previous results [34] and literature [35–40]. Of these 29 identified compounds, most were flavonoids, in addition to a small amount of polyphenols, triterpenoids, and others. The presence of calycosin-7-O-β-D-glucoside (10^#) in AG was reported for the first time in [41].

4.2. Effect of High-Fat Diet on the Liver of Hamster

In male hamsters, 85% of cholesterol derives from extrahepatic synthesis sources meaning that hyperlipidemia can be induced in a relatively short period of time. Moreover, the lipid metabolism of hamsters is similar to that of human suggesting male hamsters are a suitable model organism of lipid metabolism disorder [31, 32]. In the current study, lipid metabolism disorder was induced in male hamsters by feeding them a high-fat diet consisting of 24.5% lard and 2% cholesterol. Because of the high content of fat and cholesterol, the blood serum became lipemic at the end of the treatment period. Animals on a high-fat diet had increased body and liver weight, higher serum levels of TC and TG, and more lipid deposition compared to control suggesting that our lipid metabolism disorder model was successfully established.

The effect of high-fat diet on the metabolome of the liver was analyzed with ¹H NMR. The results show that the content of glutamic acid and aspartic acid increased while that of alanine decreased (Figure 7 and Table 2).

As fat intake increases, free fatty acids formed by increased lipid hydrolysis undergo beta-oxidation to produce acetyl coenzyme A (CoA) which then condenses with oxaloacetic acid and further converts into alpha-ketoglutarate via tricarboxylic acid (TCA) cycling. Alpha-ketoglutarate can be aminated or transaminated to produce glutamic acid whereas oxaloacetic acid can be converted into aspartic acid.

Due to the high fat intake, the utilization of glucose in the animal is reduced and subsequently the synthesis of hepatic glycogen in the liver is increased. Consequently, this leads to a decreased glucose levels and, ultimately, alanine synthesized from pyruvate by alanine transaminase decreases.

The levels of the ketone bodies, especially 3-hydroxybutyric acid—intermediates produced in the liver during fatty acid oxidation—were higher in hamsters on high-fat diet (Figure 7). In the extrahepatic tissues, these ketone bodies undergo ketosis to form acetyl-CoA. If present in large amounts, acetyl-CoA inhibits the activity of the pyruvate dehydrogenase complex and restricts the utilization of sugar. At the same time, acetyl-CoA can activate pyruvate carboxylase and promote gluconeogenesis. Extrahepatic tissues use ketone body oxidation to supply energy, which on its turn reduces the demand for glucose.

However, conversion of fat into sugar is inefficient. In fact, due to the energy need to maintain normal physiological functions, depleted blood glucose levels during prolonged hyperlipidemia was shown before [35, 42].

Next to decreased glucose levels, the levels of succinic acid in the TCA cycle increased, whereas the levels of fumaric acid and maleic acid decreased (Figure 7).

Taken together, the results indicate that high-fat diet in hamsters results in a disturbed lipid metabolism, accompanied by a disturbed amino acid, sugar, and energy metabolism (Figure 7).

4.3. Compensatory Effect of AG and DMY on the Liver of Hamsters on a High-Fat Diet

In the present study, the effect of AG and DMY on high-fat diet-induced lipid metabolism disorder was analyzed. Compared to animals with high-fat diet only, supplementation of high-fat diet with AG or DMY resulted in lower body weight and liver index, lower levels of liver TC and TG, lower levels of serum TC, TG, LDL, ALT, and AST, increased levels of serum HDL, and less liver lipid depositions (Figures 4 and 5). Furthermore, a boost of the high-fat diet-induced increase in fatty acid oxidation and the synthesis of alpha-ketoglutarate, glutamic acid, and aspartic acid was observed in those animals supplemented with AG or DMY (Figure 7). Increased levels of alpha-ketoglutarate resulted in higher levels of succinic acid and fumaric acid in the TCA cycle. Co-administration of AG or DMY during high-fat diet prevented the increase of 3-hydroxybutyric acid, acetoacetate, and acetone slightly, suggesting reduced ketone body synthesis.

In addition, compared to animals fed a high-fat diet, supplementation of AG or DMY during high-fat diet resulted in lower levels of serine, glycine, and threonine (Figure 7). Since these amino acids can be converted to pyruvic acid and subsequently glycogen, it is suggested that supplementation of AG or DMY preserves liver glycogen production during high-fat diet.

Taurine can promote the oxidative decomposition of fatty acids by neutralizing cholic acid in the liver and leads to the formation of taurocholic acid. Taurocholic acid is then secreted into the digestive tract with bile to promote the digestion and absorption of fat and fat-soluble vitamins. Metabolism of pantothenic acid results in the formation of CoA. Considering the central role of CoA in fatty acid beta-oxidation, a lack of pantothenic acid inhibits lipid metabolism. In addition to the increased taurine levels induced by high-fat diet, which promote fat metabolism, supplementation of AG or DMY during high-fat diet resulted in a further increase of taurine levels compared to animals on a high-fat diet only (Figure 7). Moreover, while high-fat diet led to a decrease in pantothenic acid levels, supplementation of AG or DMY during high-fat diet could maintain the pantothenic acid levels (Figure 7). Combined, these data suggest that supplementation of AG or DMY during high-fat diet can significantly increase fatty acid oxidation.

Supplementation of high-fat diet with AG or DMY resulted in a huge increase of trimethylamine (TMA) (Table 2) compared to HFD. TMA is synthesized from dietary sources such as carnitine or choline by the microbiota. Interestingly, higher levels of choline were observed in liver of HFD + Ag or HFD + DMY compared to HFD (Table 2). Next, TMA is converted to trimethylamine N-oxide (TMAO) by hepatic flavin monooxygenases 3 (FMO3) [43]. In fact, TMAO was shown earlier to attenuate high-fat high-cholesterol diet-induced steatohepatitis through modulating the gut microbiota and as such reducing cholesterol absorption and hepatic cholesterol overload in rats [44]. Thus, our data might suggest that enhanced TMA levels could be another mechanism by which AG or DMY might be beneficial for lipid metabolic disorder.

Taken together, our data suggest that the protective effect of AG and DMY on the liver during high-fat diet might act by preserving the efficacy of multiple metabolic pathways including enhanced fatty acid oxidation and improved amino acid metabolism and ketone body synthesis.

5. Conclusions

In the current study, 31 chemicals were detected and 29 flavonoids were identified in Ampelopsis grossedentata by HPLC-DAD-ESI-IT-TOF-MSⁿ. When supplemented to hamsters on a high-fat diet, Ampelopsis grossedentata and its main active ingredient dihydromyricetin could control the body weight and reduce the blood levels of TC and TG. Liver slice staining indicated that both Ampelopsis grossedentata and dihydromyricetin could effectively inhibit the formation of hepatic fat granules. Metabolomics studies suggested that Ampelopsis grossedentata and dihydromyricetin can influence the metabolism of hamsters. Our data indicated that the mechanism of Ampelopsis grossedentata and dihydromyricetin is basically overlapping and might involve the regulation of liver lipid metabolism during a high-fat diet by modulating amino acid metabolism, promoting fatty acid oxidation, promoting the increase of pantothenic acid and taurine, and enhanced levels of trimethylamine. Our results provide a scientific basis for elucidating the mechanism of action by which vine tea and DMY might be able to improve lipid metabolism disorders.

Abbreviations

AG:	Ampelopsis grossedentata (Hand-Mazz) W. T. Wang
DMY:	Dihydromyricetin
TCA:	Tricarboxylic acid
CoA:	Coenzyme A
TMA:	Trimethylamine
TMAO:	Trimethylamine N-oxide.

Data Availability

The data used to support the findings of this study are available from the corresponding author upon request.

Conflicts of Interest

The authors declare that they have no conflicts of interest.

Authors’ Contributions

Lanlan Fan, Xiaosheng Qu, and Tao Yi authors contributed equally to this work. Fan wrote and revised the paper, Qu conducted animal experiments and determination of physiological and biochemical indexes, and Yi analyzed metabonomic data.

Acknowledgments

This work was financially supported by the National Science Fund (31660095) of China, the China Postdoctoral Science Foundation (2014M552537XB), the Guangxi Key Laboratory of Efficacy Study on Chinese Materia Medica (17-259-20), the Specific Subject of the Dominant Discipline Construction of Chinese Pharmacy (ZYX2015002), the Project of Cultivating High-Level Talent Teams in the Qi Huang Project (2018002), and Talent Cultivation Construction Project of Professor Yang Shilin’s Team (YSL17002) from the Guangxi University of Chinese Medicine. We would like to thank the technicians from Anachro Technologies Inc. for their technical support in the determination of samples

Supplementary Materials

Figure 1: representative 600 MHz ¹H-NMR spectra and PLS-DA analysis of ¹H-NMR spectral data. Figure 1: representative ¹H-NMR spectra at 600 MHz of the liver (a) and plasma (b) from golden hamster dosed with high-fat diet supplemented with Ampelopsis grossedentata group (2 g/kg.d). Figure 2: liver ¹H NMR spectrum: (a) normal diet (ND); (b) high-fat diet (HFD); (c) high-fat diet supplemented with Ampelopsis grossedentata (HFD + AG); (d), high-fat diet supplemented with dihydromyricetin group (HFD + DMY). Table 1: metabolic pathway analysis of golden hamster (HFD vs ND). Table 2: metabolic pathway analysis of golden hamster (HFD vs HFD + AG). Table 3: metabolic pathway analysis of golden hamster (HFD vs HFD + DMY). (Supplementary Materials)

References

Food and Drug Administration of Guangxi Zhuang Autonomous Region, Quality Standard of Zhuang Medicine in Guangxi Zhuang Autonomous Region, vol. 1, Guangxi Science and Technology Press, Nanning, China, 2008.
Q. Gao, R. Ma, L. Chen et al., “Antioxidant profiling of vine tea (Ampelopsis grossedentata): off-line coupling heart-cutting HSCCC with HPLC-DAD-QTOF-MS/MS,” Food Chemistry, vol. 225, pp. 55–61, 2017.
View at: Publisher Site | Google Scholar
Y. Chen, Y. Zhang, Y. Dai, and Z. Tang, “Systems pharmacology approach reveals the antiinflammatory effects of Ampelopsis grossedentata on dextran sodium sulfate-induced colitis,” World Journal of Gastroenterology, vol. 24, no. 13, pp. 1398–1409, 2018.
View at: Publisher Site | Google Scholar
W. Wan, B. Jiang, L. Sun, L. Xu, and P. Xiao, “Metabolomics reveals that vine tea (Ampelopsis grossedentata) prevents high-fat-diet-induced metabolism disorder by improving glucose homeostasis in rats,” PLoS One, vol. 12, no. 8, Article ID e0182830, 2017.
View at: Publisher Site | Google Scholar
J. Chen, Y. Wu, J. Zou, and K. Gao, “α-glucosidase inhibition and antihyperglycemic activity of flavonoids from Ampelopsis grossedentata and the flavonoid derivatives,” Bioorganic & Medicinal Chemistry, vol. 24, no. 7, pp. 1488–1494, 2016.
View at: Publisher Site | Google Scholar
T. Murakami, M. Miyakoshi, D. Araho et al., “Hepatoprotective activity of tocha, the stems and leaves of Ampelopsis grossedentata, and ampelopsin,” BioFactors, vol. 21, no. 1–4, pp. 175–178, 2004.
View at: Publisher Site | Google Scholar
L. Fan, L. He, W. Wei, F. Cao, Y. Zhang, and J. Miao, “Content determination of dihydromyricetin and myricetin in leaves of Ampelopsis grossedentata by UPLC and investigation of their thermal stability,” China Pharmacy, vol. 23, no. 35, pp. 3316–3319, 2012.
View at: Google Scholar
K. J. Fan, B. Yang, Y. Liu, X. D. Tian, and B. Wang, “Inhibition of human lung cancer proliferation through targeting stromal fibroblasts by dihydromyricetin,” Molecular Medicine Reports, vol. 16, no. 6, pp. 9758–9762, 2017.
View at: Publisher Site | Google Scholar
F. Z. Zhou, “Synergy and attenuation effects of dihydromyricetin on tumor-bearing mice affected by breast cancer treated with chemotherapy,” Journal of South China University of Technology, vol. 39, no. 9, pp. 147–151, 2011.
View at: Publisher Site | Google Scholar
Y. Zhou, F. Shu, X. Liang et al., “Ampelopsin induces cell growth inhibition and apoptosis in breast cancer cells through ROS generation and endoplasmic reticulum stress pathway,” PLoS One, vol. 9, no. 2, Article ID e89021, 2014.
View at: Publisher Site | Google Scholar
Q. Li, J. Wang, X. Zhu et al., “Dihydromyricetin prevents monocrotaline-induced pulmonary arterial hypertension in rats,” Biomedicine & Pharmacotherapy, vol. 96, pp. 825–833, 2017.
View at: Publisher Site | Google Scholar
T. T. Liu, Y. Zeng, K. Tang, X. M. Chen, W. Zhang, and X. L. Xu, “Dihydromyricetin ameliorates atherosclerosis in LDL receptor deficient mice,” Atherosclerosis, vol. 262, pp. 39–50, 2017.
View at: Publisher Site | Google Scholar
Y. Zeng, Y. Peng, K. Tang et al., “Dihydromyricetin ameliorates foam cell formation via LXRα-ABCA1/ABCG1-dependent cholesterol efflux in macrophages,” Biomedicine & Pharmacotherapy, vol. 101, pp. 543–552, 2018.
View at: Publisher Site | Google Scholar
H. Ling, Z. Zhu, J. Yang et al., “Dihydromyricetin improves type 2 diabetes-induced cognitive impairment via suppressing oxidative stress and enhancing brain-derived neurotrophic factor-mediated neuroprotection in mice,” Acta Biochimica et Biophysica Sinica, vol. 50, no. 3, pp. 298–306, 2018.
View at: Publisher Site | Google Scholar
J. Liang, A. Kerstin Lindemeyer, Y. Shen et al., “Dihydromyricetin ameliorates behavioral deficits and reverses neuropathology of transgenic mouse models of Alzheimer’s disease,” Neurochemical Research, vol. 39, no. 6, pp. 1171–1181, 2014.
View at: Publisher Site | Google Scholar
Z. X. Ren, Y. F. Zhao, T. Cao, and X. C. Zhen, “Dihydromyricetin protects neurons in an MPTP induced model of Parkinson’s disease by suppressing glycogen synthase kinase-3 beta activity,” Acta Pharmacologica Sinica, vol. 37, no. 10, pp. 1315–1324, 2016.
View at: Publisher Site | Google Scholar
J. Liang, Y. Shen, X. M. Shao et al., “Dihydromyricetin prevents fetal alcohol exposure-induced behavioral and physiological deficits: the roles of GABAA receptors in adolescence,” Neurochemical Research, vol. 39, no. 6, pp. 1147–1161, 2014.
View at: Publisher Site | Google Scholar
J. Zhang, Y. Chen, H. Luo et al., “Recent update on the pharmacological effects and mechanisms of dihydromyricetin,” Frontiers in Pharmacology, vol. 9, p. 1204, 2018.
View at: Publisher Site | Google Scholar
Q. Song, L. Liu, J. Yu et al., “Dihydromyricetin attenuated Ang II induced cardiac fibroblasts proliferation related to inhibitory of oxidative stress,” European Journal of Pharmacology, vol. 807, pp. 159–167, 2017.
View at: Publisher Site | Google Scholar
Y. Chen, H. Q. Luo, L. L. Sun et al., “Dihydromyricetin attenuates myocardial hypertrophy induced by transverse aortic constriction via oxidative stress inhibition and SIRT3 pathway enhancement,” International Journal of Molecular Sciences, vol. 19, no. 9, p. 2592, 2018.
View at: Publisher Site | Google Scholar
L. Wei, X. Sun, X. Qi, Y. Zhang, Y. Li, and Y. Xu, “Dihydromyricetin ameliorates cardiac ischemia/reperfusion injury through Sirt3 activation,” BioMed Research International, vol. 2019, Article ID 6803943, 9 pages, 2019.
View at: Publisher Site | Google Scholar
R. Taub, “Liver regeneration: from myth to mechanism,” Nature Reviews Molecular Cell Biology, vol. 5, no. 10, pp. 836–847, 2004.
View at: Publisher Site | Google Scholar
C. E. Liu, H. Y. Wang, Y. D. Wang, and J. Zhang, “Study on Ampelsis grossedentata to lower plasma lipids level,” Food Science, vol. 26, no. 11, pp. 237–240, 2005.
View at: Google Scholar
Y. Li, Z. Tan, T. Li, B. Xiao, and Q. Dai, “Effects of Ampelopsis grossedentata on hyperlipidemia and myocardial enzymes in rats,” Acta Nutrimenta Sinica, vol. 6, pp. 506–509, 2006.
View at: Google Scholar
X. Zeng, G. Wei, H. Fei et al., “Effect of total flavonoids of Ampelopsis grossedentata on blood lipid and hemorrheologyin in atherosclerosis rats,” Chongqing Medicine, vol. 5, pp. 518–520, 2014.
View at: Google Scholar
Y. S. Zhang, Z. X. Ning, S. Z. Yang, and H. Wu, “Antioxidation properties and mechanism of action of dihydromyricetin from Ampelopsis grossedentata,” Acta Pharmaceutica Sinica, vol. 38, no. 4, pp. 241–244, 2003.
View at: Google Scholar
J. C. Shen, L. Y. Lian, Y. Zhang et al., “Dynamic Analysis of metabolic response in gastric ulcer (GU) rats with electroacupuncture treatment using ¹H NMR-based metabolomics,” Evidence-Based Complementary Alternative Medicine, vol. 2019, Article ID 1291427, 12 pages, 2019.
View at: Publisher Site | Google Scholar
E. J. Kim, Y. S. Hong, S. H. Seo, S. E. Park, C. S. Na, and H. S. Son, “Metabolite markers for characterizing Sasang constitution type through GC-MS and ¹H NMR-based metabolomics study,” Evidence-Based Complementary Alternative Medicine, vol. 2019, Article ID 8783496, 11 pages, 2019.
View at: Publisher Site | Google Scholar
X. Li, H. Chen, W. Jia, and G. Xie, “A metabolomics-based strategy for the quality control of traditional Chinese medicine: shengmai injection as a case study,” Evidence-Based Complementary Alternative Medicine, vol. 2013, Article ID 836179, 8 pages, 2013.
View at: Publisher Site | Google Scholar
J. Hao, H. Hu, J. Liu et al., “Integrated metabolomics and network pharmacology study on immunoregulation mechanisms of Panax ginseng through macrophages,” Evidence-Based Complementary Alternative Medicine, vol. 2019, Article ID 3630260, 14 pages, 2019.
View at: Publisher Site | Google Scholar
Z. X. Miao, L. Yang, C. Y. Jiang, Y. H. Wang, and H. B. Zhu, “Evaluation of dose-related effects of 2′, 3′, 5′-tri-O-acetyl-N6-(3-hydroxylaniline) adenosine using NMR-based metabolomics,” Acta Pharmaceutica Sinica, vol. 49, no. 5, pp. 679–685, 2014.
View at: Google Scholar
F. Guo, T. Zi, L. Liu, R. Feng, and C. Sun, “A ¹H-NMR based metabolomics study of the intervention effect of mangiferin on hyperlipidemia hamsters induced by a high-fat diet,” Food & Function, vol. 8, no. 7, pp. 2455–2464, 2017.
View at: Publisher Site | Google Scholar
J. Chong, M. Yamamoto, and J. Xia, “MetaboAnalystR 2.0: from raw spectra to biological insights,” Metabolites, vol. 9, no. 3, p. 57, 2019.
View at: Publisher Site | Google Scholar
L. Fan, T. Yi, F. Xu et al., “Characterization of flavonoids in the ethomedicine fordiae cauliflorae radix and its adulterant millettiae pulchrae radix by HPLC-DAD-ESI-IT-TOF-MSn,” Molecules, vol. 18, no. 12, pp. 15134–15152, 2013.
View at: Publisher Site | Google Scholar
D. Wang, J. Liu, J. Zhang, and S. Zheng, “The chemical constituents of Ampelopsis grossedentata,” Subtropical Plant Research Communications, vol. 27, no. 2, pp. 39–44, 1998.
View at: Google Scholar
Y. Zhang, W. Yang, and H. Xiong, “Basic constituent of Ampelopsis grossedentata,” Natural Product Research Development, vol. 13, no. 5, pp. 46–48, 2001.
View at: Google Scholar
W. Yan, Z. Liling, R. Li, and Y. Wang, “Studies on the chemical constituents from Ampelopsis grossedentata,” Journal of Chinese Medicinal Materials, vol. 25, no. 4, pp. 254–256, 2002.
View at: Google Scholar
Y. Cheng, “Research development of Ampelopsis grossedentata,” Economic Forest Researches, vol. 22, no. 3, pp. 51–56, 2004.
View at: Google Scholar
Q. Du, P. Chen, G. Jerz, and P. Winterhalter, “Preparative separation of flavonoid glycosides in leaves extract of Ampelopsis grossedentata using high-speed counter-current chromatography,” Journal of Chromatography A, vol. 1040, no. 1, pp. 147–149, 2004.
View at: Publisher Site | Google Scholar
G. He, G. Pei, F. Du, Y. Ou, and B. Li, “Studies on the chemical constituents of Ampelopsis grossedentata,” Modern Chinese Medicine, vol. 9, no. 12, pp. 11–13, 2007.
View at: Google Scholar
X. X. Qi, Y. Dong, C. X. Shan, Y. Y. Xiang, and X. D. Wang, “Analysis of the main components in herbal pairs: astrogali radix and Salviae miltiorrhizae by UPLC-Q-TOF/MS,” Journal of Nanjing University of Traditional Chinese Medicine, vol. 23, no. 1, pp. 93–96, 2017.
View at: Google Scholar
C. Y. Jiang, K. M. Yang, L. Yang, Z. X. Miao, Y. H. Wang, and H. B. Zhu, “A ¹H NMR based metabonomics approach to progression of coronary atherosclerosis in a hamster model,” Acta Pharmaceutica Sinica, vol. 48, no. 4, pp. 495–502, 2013.
View at: Google Scholar
M. T. Velasquez, A. Ramezani, A. Manal, and D. S. Raj, “Trimethylamine N-oxide: the good, the bad and the unknown,” Toxins, vol. 8, no. 11, p. 326, 2016.
View at: Publisher Site | Google Scholar
Z. H. Zhao, F. Z. Xin, D. Zhou et al., “Trimethylamine N-oxide attenuates high-fat high-cholesterol diet-induced steatohepatitis by reducing hepatic cholesterol overload in rats,” World Journal of Gastroenterology, vol. 25, no. 20, pp. 2450–2462, 2019.
View at: Publisher Site | Google Scholar

Copyright

Copyright © 2020 Lanlan Fan et al. This is an open access article distributed under the Creative Commons Attribution License, which permits unrestricted use, distribution, and reproduction in any medium, provided the original work is properly cited.

PDF Download Citation

Download other formats

Order printed copies

Views

1176

Downloads

1133

Citations

Evidence-Based Complementary and Alternative Medicine

Metabolomics of the Protective Effect of Ampelopsis grossedentata and Its Major Active Compound Dihydromyricetin on the Liver of High-Fat Diet Hamster

Abstract

1. Introduction

2. Materials and Methods

2.1. Chemicals and Materials

2.2. Sample Preparation

2.3. HPLC-DAD-ESI-IT-TOF-MSn Analysis

2.4. Animal Experiments

2.5. Liver Metabolomics

2.6. Statistical Analysis

3. Results

3.1. HPLC-DAD-ESI-IT-TOF-MSn Analysis of Ampelopsis grossedentata

3.2. Analysis of AG and DMY on Physiology of Hamsters on a High-Fat Diet

3.3. Analysis of AG and DMY on Liver Metabolome of Hamsters on a High-Fat Diet

4. Discussion

4.1. Analysis of the Chemical Composition of AG

4.2. Effect of High-Fat Diet on the Liver of Hamster

4.3. Compensatory Effect of AG and DMY on the Liver of Hamsters on a High-Fat Diet

5. Conclusions

Abbreviations

Data Availability

Conflicts of Interest

Authors’ Contributions

Acknowledgments

Supplementary Materials

References

Copyright

2.3. HPLC-DAD-ESI-IT-TOF-MSⁿ Analysis

3.1. HPLC-DAD-ESI-IT-TOF-MSⁿ Analysis of Ampelopsis grossedentata