Background
Metabolic syndrome (MetS) is considered as a major worldwide problem that is characterized by hypertension, hyperinsulinemia and obesity. This syndrome is affecting more than quarter of the world population, due to lack of physical activity and high calorie nutrition [
1]. People affected by metabolic syndrome are in high risk of developing cardiovascular complications [
2]. This is attributed to the effect of hyperglycaemia and oxidative stress on vascular biology [
3]. Vascular endothelia play a major role in maintaining cardiovascular homeostasis through releasing a number of mediators that regulate platelet aggregation, coagulation, fibrinolysis, and vascular tone [
4]. Hyperglycemia causes vascular damage in different cells of vascular cell wall leading to endothelial dysfunction and reduction in NO production that give rise to vasoconstriction [
5]. Therefore, MetS is associated with changes in vascular responsiveness to vasoconstrictors and vasodilators. The changes in vascular reactivity are responsible for the development of many vascular complications [
6]. Consequently, searching for drugs that have the ability to overcome endothelial dysfunction will help in the treatment of diabetic complications.
Herbal drugs are commonly used worldwide due to its high efficacy, few side effects, and relatively low cost. Many plants and its active constituents have been reported for their antidiabetic activity [
7]. Some phenolic compounds were reported to have relaxant effect on vasoconstriction [
8,
9]. Mangosteen is used traditionally throughout Southeast Asia for preventing some diseases including hypertension,, obesity, and diabetic complications [
10]. Moreover, it revealed an antidiabetic effect through α-glucosidase inhibition [
11]. Also, the fruit causes a decrease in body mass index (BMI) indicating its possible anti-obesity effect. However, the fruit juice has shown anti-obesity potential, accordingly, more detailed studies are required to confirm its efficacy in the prevention and/or treatment of obesity and diabetes [
10]. In addition, mangosteen showed a remarkable vaso-relaxant effect on isolated rat aorta [
12] and inhibited advanced glycation end products (AGEs) formation at the levels of Amadori product and protein aggregation through saving protein thiol [
13]. The phytochemical screening of
G. mangostana revealed the presence of phenolic compounds, including prenylated xanthones, benzophenones, flavonoids, and anthocyanins [
13‐
15].
Current study aims at the examination of the potential protective effect of methanol extract of G. mangostana (GMT) fruit hulls on the exaggerated vasoconstriction in MetS aortae. In addition; the main bioactive fraction and compounds, as well as the possible mechanism of action will be determined.
Methods
General
Electron spray ionization mass (ESIMS) was recorded on an LCQ DECA mass spectrometer (Thermo Finnigan, Bremen, Germany) coupled with an Agilent 1100 HPLC using photodiode array detector. NMR spectra were recorded on a Bruker DRX-400 MHz Ultrashield spectrometer (Bruker BioSpin, Billerica, MA, USA). CD3OD was used as a solvent, and TMS as the internal reference. Pre-coated thin layer chromatography (TLC) plates; silica gel 60 F254 were purchased from Merck, Darmstadt, Germany. Silica gel 60 (70–230 mesh), Diaion HP-20, and polyamide 6 (Merck, Darmstadt, Germany) were used for different column chromatographic procedures.
Chemicals
Compounds used for the biological study; 4-Amino-5-methylamino-2′,7′-difluorofluorescein diacetate (DAF-FM) and 2′,7′-dichlorofluorescein diacetate (DCF) were obtained from Molecular Probes, New York, USA. In addition, methylene blue (MB), Nω-Nitro-L-arginine methyl ester hydrochloride (L-NAME), indomethacin (INDO), tetraethylammonium chloride (TEA), and phenylephrine (PE) were obtained from Sigma-Aldrich (Munich, Germany). Ultrapure deionized water was used for dissolving all chemicals except DAF-FM, DCF, and INDO, which were dissolved in dimethylsulphoxide (DMSO). Final DMSO concentration in the assay media did not exceed 0.1 %.
Plant material
G. mangostana fruits were obtained from the market in Kingdom Saudi Arabia in December 2014. The fruits were air dried and a voucher specimen was kept in the herbarium of Faculty of Pharmacy, King Abdulaziz University (no. GM1424). The identity of the plant was kindly authenticated by Dr. Emad Al-Sharif, Associate Professor of Plant Ecology, Dept. of Biology, Faculty of Science & Arts, Khulais, King Abdulaziz University, Saudi Arabia.
Extraction and isolation
The dried pulverised
G. mangostana fruit hulls (500 gm) were exhaustively extracted with methanol using Ultraturrax. The collected methanol extracts were evaporated under vacuum to produce a brown residue of the total methanol extract (GMT, 20 g). GMT was suspended in water (500 mL) and fractionated with chloroform to produce a CHCl
3- soluble fraction (Fr I). The remaining aqeous layer was concentrated and applied to a Diaion HP-20 column (6 × 110 cm, 250 g) and eluted successively with H
2O, 50 % MeOH and 100 % MeOH (1 L, each). The collected fractions were separately evaporated under vaccum to obtain fractions II (2 gm), III (7 gm) and IV (4 gm), respectively [
13]. Part of fraction III (FR. III) was chromatographed on polyamide column (6 × 100 cm, 250 g) and eluted with H
2O and increasing amounts of MeOH until pure MeOH, the obtained fractions were pooled into four main subfractions (A-D) based on TLC investigations. Subfraction A (10–20 % MeOH) was purified on a silica gel column (25 × 2 cm, 50 g) using CHCl
3:MeOH (9.5:0.5,
v/v) to give compounds
1 (14 mg) and
2 (125 mg). Subfraction B (30 % MeOH) was chromatographed on silica gel column (25 × 2 cm, 50 g) and eluted with CHCl
3:MeOH (9.5:0.5,
v/v) to afford compounds
3 (32 mg) and
4 (50 mg). Subfraction C (40–60 % MeOH) was applied to silica gel column (25 × 2 cm, 50 g) using CHCl
3:MeOH (9:1,
v/v) to yield
5 (150 mg). Finally, Silica gel column (25 × 2 cm, 50 g) of subfraction D (70–100 % MeOH) using CHCl
3:MeOH (8:2,
v/v) gave
6 (30 mg).
Animals
The current study was conducted using 72 male Wistar rats (6–8 weeks old). They were supplied by the Animal house, King Abdulaziz University, Jeddah, Saudi Arabia. Animals were acclimatized in animal facility for seven days before the experiment. They were maintained on a 12-h light–dark cycle, and stable temperature (22 ± 2 oC). Experimental protocol was ethically approved by the Unit of Biomedical Ethics, Faculty of Medicine, King Abdulaziz University (Reference # 329–16).
The metabolic syndrome (MetS) was induced in rats by adding fructose (10 %) to every day drinking water and salt (3 %) to the diet for 12 weeks while control rats received standard diet. The induction of MetS was confirmed by a stable hyperinsulinemia (2.5–3.5 ng/dL) after 12 weeks of high fructose/high salt diet. This protocol was found effective in inducing vascular complications associated with MetS as indicated in previous work from our laboratories [
16]. Animals were killed by decapitation and the thoracic aorta was carefully excised and washed with ice-cold Krebs-Henseleit buffer (KHB; NaCl 118.1, KCl 4.69, KH
2PO
4 1.2, NaHCO
3 25.0, glucose 11.7, MgSO
4 0.5, and CaCl
2 2.5 mM). The aorta was cut into rings (~3 mm length) after cleaning from fat and connective tissue. A glucose meter (ACCU-CHEK, Roche, Mannheim, Germany) was used to measure glucose level from tail blood. An immunosorbent assay (ELISA, Millipore, Billerica, MA, USA) with anti-rat insulin monoclonal antibodies was used to measure serum insulin.
Vascular reactivity
Vascular reactivity of the isolated aortae was performed using the isolated artery techniques as previously described [
17‐
20]. In brief, aortae isolated from MetS animals were incubated with the vehicle (0.1 % DMSO) or different concentrations of GMT (10–100 μg/mL), fractions (I, III, IV) (1–10 μg/mL) or isolated compounds (all at 10–100 μM) for 30 min before studying the vasoconstriction responses to the standard vasoconstrictor phenylephrine (PE). For studying the contractile responsiveness of aortae, increments in tension to cumulative additions of PE (10
−9 to 10
−5 M) were recorded.
Direct vasodilatation
A set of experiments were carried out for investigating the direct vasodilation effect of GMT, fractions (I, III, and IV), or isolated compounds 1–6. In these experiments, cumulative concentrations of GMT or fractions (I, III, and IV) all at concentrations (1–100 μg/mL) or isolated compounds 1–6 (Conc. 10–100 μM) were added to the organ bath, containing isolated aortae pre-contracted with PE (10 μM) and the decreases in tension was recorded. Final vehicle concentration (0.4 % DMSO) did not show any effect on PE (10 μM) precontraction in our preliminary data. In other sets of experiments, L-NAME (100 μM), MB (5 μM), TEA (10 mM), INDO (5 μM) or the vehicle (0.1 % DMSO) were added 30 min before investigating the direct vasodilator effect of Fr. III and compounds 2, 4, and 5 as above.
NO generation
The NO generation from isolated aorta was investigated using the fluorescence probes 4-amino-5-methylamino-2′,7′-difluorofluorescein diacetate (DAF-FM) as in previous work from our laboratories [
9,
21‐
23] with some modifications. Briefly, isolated aortic rings (~3 mm length) was added to 96 well black plate wells containing 110 μL saline and 2.5 μM DAF-FM with or without acetylcholine (100 μM), Fr. III (1 μg/mL) or compounds
2,
4, and
5 (Conc. 100 μM) for 3 min (incubated at 37 °C). At the end, 90 μL volumes were transferred into new wells and the fluorescence intensity (λex = 485, λex = 525) were measured using monochromator SpectraMax® M3 plate reader (Molecular devices, California, USA). The fluorescence intensity of the DAF-FM plus acetylcholine, Fr. III or any of the compounds before addition of aortic rings were recorded and subtracted to avoid any interference from the tested substance own fluorescence.
ROS generation
The reactive oxygen species (ROS) generation from isolated aortic rings (~3 mm length) was investigated using the fluorescence probes 2′,7′-dichlorofluorescein diacetate (DCF) as previously described [
24,
25] with some modifications. Briefly, isolated aortae were added to 96 well black plate wells, containing 110 μL volumes of saline and 2.5 μM DCF with or without Fr. III (1 μg/mL) or compounds
2,
4, and
5 (Conc. 100 μM) for 30 min at 37 °C. At the end 90 μL volumes were transferred to new wells and the fluorescence intensity were measured (λex = 485, λex = 525) using monochromator SpectraMax® M3 plate reader. The fluorescence intensity of the DCF plus tested substances before addition of aortic rings were recorded and subtracted to avoid any interference from the tested substance own fluorescence.
Statistical analysis
Values are expressed as mean ± SEM and N = 6. Statistical analysis was carried out by the one or two (as indicated in figure legends) way analysis of variance (ANOVA) followed by Dunnett’s post hoc test using the statistical software Prism 5® (Graphpad, CA, USA). Probability levels less than 0.05 were considered statistically significant.
Discussion
The current study is the first report on the protective effect of G. mangostana (GM) on exaggerated vasoconstriction in MetS. A multidisciplinary approach was employed for studying vasoconstriction, dilatation, NO, and ROS production to find out the active metabolite in GM through bioassay-guided process.
It is widely accepted that development of hypertension in normal persons and in MetS is dependent greatly on changes in vascular reactivity. Exaggerated vasoconstriction and or impaired vasodilation are usually correlated with increase in blood pressure [
31,
32]. In the current study, isolated aortae from MetS animals showed overstated response upon exposure to PE which is in agreement with previous reports showing that different vasoconstrictors produced exaggerated response in MetS [
33,
34]. Several reports revealed the role of phenolic compounds in alleviating the exaggerated vasoconstriction and hence alleviating hypertension in MetS [
8,
9]. GM is known for its high content of phenolic constituents such as xanhtone, flavonoids and benzophenones and its anti-diabetic activity [
15].
In the present study, GMT significantly alleviated the exaggerated vasoconstriction in MetS aortae in a concentration dependent manner. This effect seemed to be mediated by direct vasodilatation activity as indicated by the data presented here. The bioassay-guided fractionation procedures revealed that Fr. III was mainly responsible for the observed activity while fraction I (xanthone rich fraction) showed weak activity. Chemical investigation of the bioactive fraction resulted in isolation of six major metabolites (1–6). Only compounds 2, 4, and 5 showed significant vasodilation suggesting that they are the main active metabolites responsible for the observed vasodilation in Fr. III and hence the total extract of GM.
The observed vasodilation produced by Fr III as well as compounds
2,
4, and
5 seemed to be through stimulating NO generation from the vasculature as Fr. III relaxation was completely blocked by the nitric oxide synthase inhibitor and partially inhibited by guanylate cyclase inhibitor. Meanwhile, it was not affected by the calcium-activated potassium channels blocker or the cyclooxygenase inhibitor. The vasorelaxation responses of Fr. III are almost similar to the responses of compounds
2,
4, and
5. The reason may be competition between the active compounds on the same relaxation pathway as they are all inhibited by L-NAME and MB as have not found any vasoconstricting compound among the isolated metabolites of Fr. III. This suggests stimulating NO generation as a main mechanism by which Fr III as well as compounds
2,
4, and 5 induce vasodilation. The NO generation measurement in the present work reinforced this assumption as Fr. III generated nitric oxide from isolated vessels even better than acetylcholine (standard endothelial NO generator). The same was true for vasorelaxation activity. In addition, compounds
2,
4, and
5 generated nitric oxide to a level comparable to acetylcholine. The ability of flavonoid nucleus as in
2 to stimulate NO generation was previously reported [
9], meanwhile; benzophenone nucleus in
4 is reported here for the first time for this activity. Furthermore, epicatechin (
5) (flavanol nucleus) was known for its vasorelaxant activity through increasing NO levels in the vasculature [
35,
36]. It was reported that the NO-preserving activity of (−)-epicatechin on vascular endothelial cells was due to inhibition of endothelial NADPH oxidase activity [
37].
The assumption that compounds 2, 4, and 5 are the main active metabolites responsible for activity of Fr. III and hence the total extract of GM was confirmed by the observed alleviation of exaggerated vasoconstriction when incubating them with MetS aortae for only thirty minutes.
The involvement of ROS (endogenous or exogenous) in vascular tone by acting as a mediator for signal transduction in endothelial cells was reported before [
34,
38,
39]. In this work, fructose was used to induce MetS resulting in elevation of ROS as previously reported [
40,
41]. Production of ROS in MetS resulted in occurrence of different vascular diseases which could be attributed to the ability of ROS to decrease bioavailability of NO and endothelial dysfunction. Moreover, ROS is responsible for vascular diseases through its ability to produce many oxidized and nitrated secondary metabolites [
42]. In the present study, Fr. III and compounds
4 and
5 suppressed ROS in MetS aortae. This could also be one of the mechanisms by which GM alleviated exaggerated vasoconstriction and induced vasodilation through increasing NO bioavailability as a result of inhibiting ROS.
Acknowledgements
This project was funded by the National Plan for Science, Technology and Innovation (MAARIFAH)-King Abdulaziz City for Science and Technology-the Kingdom of Saudi Arabia-award number (No. 12-BIO3087-03). The authors also, acknowledge with thanks the Science and Technology Unit, King Abdulaziz University for technical support.