|Year : 2017 | Volume
| Issue : 51 | Page : 613-622
Chemotaxonomic diversity of three Ficus species: Their discrimination using chemometric analysis and their role in combating oxidative stress
Nawal Al-Musayeib1, Sherif S Ebada2, Haidy A Gad2, Fadia S Youssef2, Mohamed Lotfy Ashour2
1 Department of Pharmacognosy, College of Pharmacy, King Saud University, Riyadh, Saudi Arabia
2 Department of Pharmacognosy, Faculty of Pharmacy, Ain Shams University, Abbassia, Cairo, Egypt
|Date of Submission||25-Feb-2016|
|Date of Acceptance||01-Feb-2017|
|Date of Web Publication||11-Oct-2017|
Mohamed Lotfy Ashour
Department of Pharmacognosy, Faculty of Pharmacy, Ain Shams University, African Unity Organization Street, Abbassia, Cairo 11566
Source of Support: None, Conflict of Interest: None
| Abstract|| |
Background: Genus Ficus (Moraceae) constitutes more than 850 species and about 2000 varieties and it acts as a golden mine that could afford effective and safe remedies combating many health disorders. Objectives: Discrimination of Ficus cordata, Ficus ingens, and Ficus palmata using chemometric analysis and assessment of their role in combating oxidative stress. Materials and Methods: Phytochemical profiling of the methanol extracts of the three Ficus species and their successive fractions was performed using high-performance liquid chromatography/electrospray ionization mass spectrometry. Their discrimination was carried out using the obtained spectral data applying chemometric unsupervised pattern-recognition techniques, namely, principal component analysis and hierarchical cluster analysis. In vitro hepatoprotective and antioxidant evaluation of the samples was performed using human hepatocellular carcinoma cells challenged by carbon tetrachloride (CCl4). Results: Altogether, 22 compounds belonging to polyphenolics, flavonoids, and furanocoumarins were identified in the three Ficus species. Aviprin is the most abundant compound in F. cordata while chlorogenic acid and psoralen were present in high percentages in F. ingens and F. palmata, respectively. Chemometric analyses showed that F. palmata and F. cordata are more closely related chemically to each other rather than F. ingens. The ethyl acetate fractions of all the examined species showed a marked hepatoprotective efficacy accounting for 54.78%, 55.46%, and 56.42% reduction in serum level of alanine transaminase and 56.82%, 54.16%, and 57.06% suppression in serum level of aspartate transaminase, respectively, at 100 μ g/mL comparable to CCl4-treated cells. Conclusion: Ficus species exhibited a notable antioxidant and hepatoprotective activity owing to their richness in polyphenolics and furanocoumarins.
Abbreviations used: ALT: Alanine transaminase, AST: Aspartate transaminase, CCl4:Carbon tetrachloride, DMEM: Dulbecco's Modified Eagle's medium, DMSO: Dimethyl sulfoxide, EDTA: Ethylenediaminetetraacetic acid, FBS: Fetal bovine serum, FCA: Ficus cordata remaining aqueous fraction, FCB: Ficus cordata n-butanol fraction, FCE: Ficus cordata ethyl acetate fraction, FCP: Ficus cordata petroleum ether fraction, FCT: Ficus cordata total methanol extract, FIA: Ficus ingens remaining aqueous fraction, FIB: Ficus ingens n-butanol fraction, FIE: Ficus ingens ethyl acetate fraction, FIP: Ficus ingens petroleum ether fraction, FIT: Ficus ingens total methanol extract, FPA: Ficus palmata remaining aqueous fraction, FPB: Ficus palmata n-butanol fraction, FPE: Ficus palmata ethyl acetate fraction, FPP: Ficus palmata petroleum ether fraction, FPT: Ficus palmata total methanol extract, GSH: Reduced glutathione,HepG2 cells: Human hepatocellular carcinoma, HPLC-ESI-MS: High-performance liquid chromatography/electrospray ionization mass spectrometry, and SOD: Superoxide dismutase.
|How to cite this article:|
Al-Musayeib N, Ebada SS, Gad HA, Youssef FS, Ashour ML. Chemotaxonomic diversity of three Ficus species: Their discrimination using chemometric analysis and their role in combating oxidative stress. Phcog Mag 2017;13, Suppl S3:613-22
|How to cite this URL:|
Al-Musayeib N, Ebada SS, Gad HA, Youssef FS, Ashour ML. Chemotaxonomic diversity of three Ficus species: Their discrimination using chemometric analysis and their role in combating oxidative stress. Phcog Mag [serial online] 2017 [cited 2022 Oct 2];13, Suppl S3:613-22. Available from: http://www.phcog.com/text.asp?2017/13/51/613/216359
- Ficus cordata, Ficus ingens, and Ficus palmata were analyzed using high-performance liquid chromatography/electrospray ionization mass spectrometry that revealed their richness with polyphenolics and furanocoumarins
- Discrimination of the three species was performed using spectral data coupled with chemometrics that showed that F.palmata and F.cordata are chemically related to each other rather than F.ingens
- In vitro hepatoprotective and antioxidant evaluation was performed using human hepatocellular carcinoma cells. The ethyl acetate fractions of all the examined species showed a marked hepatoprotective efficacy
- Ficus species exhibited notable activities due to polyphenolics and furanocoumarins.
| Introduction|| |
Oxidative stress can be defined as an evident imbalance between the appearance of reactive oxygen species and the competence of the biological system to detoxify these hazardous intermediates effectively or to restore the explicit deterioration caused by them. Besides, it has recently been recognized as a predisposing factor to many fatal diseases as neurodegenerative disorders, including, Parkinson's disease, Alzheimer's disease as well as aging. Moreover, it is strongly correlated to liver diseases contributing to their ability to aggravate the inflammatory, metabolic, and proliferative hepatic changes that consequently leads to structural and functional anomalies in the liver.
Genus Ficus (family Moraceae) constitutes more than 850 species and about 2000 varieties, most of which are native to old-world tropics. Many of Ficus species are employed for many ornamental purposes whereas the fruits of others are edible., It has been widely implemented in African folk medicine for the treatment of many ailments such as convulsions and respiratory diseases. In addition, many members of Ficus were previously reported in both traditional Chinese medicine and Ayurveda medicine as a cure for many diseases such as diabetes, liver cirrhosis, and many inflammatory conditions.
Many biological activities, including antioxidant, hepatoprotective, antidiabetic, anti-inflammatory, antipyretic, antimicrobial, antimalarial, and hypotensive activities, have been ascribed to the genus Ficus.,,, This could be probably due to the predominance of alkaloids, furanocoumarins, flavonoids, stilbenes, phenylpropanoids, lignans, chromones, and terpenoids in the genus.,,
Ficus cordata exists in two separate areas in Africa, namely, the southwest of the continent and the northern subtropics. Its leaves are highly popular for possessing antimicrobial and hepatoprotective activity in addition to relief of ataxia as well as muscle tremor.,, However, Ficus ingens, the red-leaved fig, spreads in the tropical regions of Africa and southern Arabia. Recently, it has been reported to possess potent analgesic, anti-inflammatory as well as hepatoprotective effects that could be attributed to the presence of many active secondary metabolites., On the other hand, Ficus palmata, the wild fig, was adopted in the folk medicine for the relief of constipation, lung, and bladder ailments. It manifests potent antimicrobial, antioxidant, and nephroprotective efficacies owing to the presence of many phytoconstituents.,,
Nowadays, there is a revival of interest in herbal drugs due to the widespread belief that “green medicine” is relatively safer and more dependable than the costly synthetic drugs., Thus, adulteration of medicinal plants due to the presence of various species and varieties that are morphologically similar but biologically different constitutes a great obstacle threatening the future of herbal drug discovery. Therefore, chemometrics as an efficient discriminatory tool was adopted to differentiate between morphologically and chemotaxonomically related species.
In the forgoing study, we investigated comparatively the in vitro antioxidant and hepatoprotective activities of the methanol extracts prepared from the leaves of F. cordata, F. ingens, and F. palmata and their successive fractions. This was performed through the assessment of various hepatic markers as aspartate transaminase (AST) and alanine transaminase (ALT) in addition to different antioxidant parameters as reduced glutathione (GSH) and superoxide dismutase (SOD). In addition, profiling of the major secondary metabolites prevalent in these extracts and fractions was performed using high-performance liquid chromatography/electrospray ionization mass spectrometry (HPLC-ESI-MS) to correlate the activity with the predominant phytoconstituents and to discriminate the three related Ficus species applying chemometric multivariate data analysis. The latter was performed for the first time using unsupervised pattern-recognition techniques using both hierarchical cluster analysis (HCA) and principal component analysis (PCA).
| Materials and Methods|| |
The aerial parts of F. cordata Thunb., F. ingens Miq., and F. palmata Forssk. (Moraceae) were collected from fully mature trees growing wild in the southern region of Saudi Arabia (Asir district, mainly Abha 900 Km away from Riyadh) in April 2010. The location is described by 18° 13′ 1″ N, 42° 30′ 19″ E, elevation 2400 m. The rainfall is estimated by 3–50 mm per annum and the average low and high temperatures are 12°C and 26°C, respectively. Samples from at least 19 trees for F. cordata, 13 trees for F. palmata, and 11 trees for F. ingens species were collected during the same vegetative phase to provide 1.0, 0.85, and 0.82 kg dried plant materials for the plants, respectively. They were kindly identified and authenticated morphologically by Dr. M. Atiqur Rahman, Plant Taxonomist, College of Pharmacy, King Saud University. Voucher specimens of F. cordata (#15133), F. ingens (#15187), and F. palmata (#15163) were deposited in the herbarium of the Pharmacognosy Department, College of Pharmacy, King Saud University.
Chemicals and kits
Media and all the required reagents for cell culture formation and maintenance comprising bovine serum albumin, Dulbecco's Modified Eagle's medium (DMEM), fetal bovine serum (FBS), and penicillin/streptomycin solution were bought from Lonza (Basel, Switzerland). Ellman's reagent and reduced GSH were purchased from Sigma-Aldrich (St. Louis, MO, USA), whereas silymarin, (Indena S.P.A, Milano, Italy) was obtained from Medical Union Pharmaceuticals Company (Cairo, Egypt). Kits for estimation of ALT, AST, and SOD activities were acquired from Biodiagnostics (Cairo, Egypt). Validation for all kits used was performed at the Department of Pharmacology, Ain Shams University (Cairo, Egypt), before experiments. Solvents for LC-MS analysis were kindly acquired from Sigma-Aldrich (Steinheim, Germany). All other utilized solvents in extraction and fractionation were of analytical and highest purity grades.
Human hepatocellular carcinoma (HepG2) cell lines were obtained from the Egyptian Holding Company for Biological Products and Vaccines (VACSERA; Giza, Egypt) and then maintained in the tissue culture facility (Faculty of Pharmacy, Ain Shams University, Cairo, Egypt). They were kept in DMEM complete media (L-glutamine supplemented with 10% heat-inactivated FBS, 100 IU/mL penicillin, and 100 μg/mL streptomycin). Cells were grown at 37°C in a humidified atmosphere of 5% CO2. The cells were maintained as monolayer culture by serial subculturing. All the experiments were performed with cells in the logarithmic growth phase.
Preparation of crude plant extracts
The aerial parts of different Ficus species were air-dried and crushed into coarse powder to give 100 g each. Then, they were extracted with methanol (1.5 L) using a Soxhlet apparatus for 8 h. The obtained extracts were filtered and evaporated under vacuum at low temperature (45°C) till dryness using a rotary evaporator (Buchi, Switzerland) to give total methanol extract (F*T) for each. The methanol extracts were suspended in water and successively extracted with petroleum ether (F*P), ethyl acetate (F*E), and n-butanol (F*nB) to afford the corresponding subfractions in addition to the remaining aqueous fraction (F*A).
High-performance liquid chromatography-mass spectrometry analysis
All samples were prepared at a concentration of 40 μg in 1 mL methanol. The HPLC analysis was conducted on Agilent 1100 Series using Knauer column (250 mm × 2 mm, ID), prepacked with Eurospher 100–5 C18, with an integrated precolumn. For a standard LC-MS analysis, a solvent gradient started with acetonitrile: nanopure H2O (10:90), adjusted with 0.1% formic acid, and reached to 100% acetonitrile in 35 min was implemented. A Finnigan LCQ-DECA MS connected to a photodiode array detector with the standard flow cell (10 mm path length, 14 μL volume, and 40 bar maximum pressure) was used for MS analysis. The samples were dissolved in water/methanol mixtures and injected into HPLC/ESI-MS setup. ESI interface was used in both negative and positive ion modes under the following conditions: drying and nebulizing gas, N2; capillary temperature, 250°C; spray voltage, 4.48 kV; capillary voltage, 39.6 V; tube lens voltage, 10.00 V; and full scan mode in mass range m/z 100–2000.
In vitro antioxidant and hepatoprotective activity assessment
The hepatoprotective activity of samples was tested in vitro at three different concentrations (25, 50, and 100 μg/mL) and compared to the standard hepatoprotective agent silymarin at the same concentrations. HepG2 monolayer cultures were pretreated with the assigned samples for 1 h. An aliquot of 40 mM carbon tetrachloride (CCl4) in 0.05% dimethyl sulfoxide was added and incubation was continued for another 2 h. The supernatant medium and cell lysate were then collected and stored at −20°C until analysis. The positive control (silymarin) was assayed in cells maintained in culture medium and treated only with CCl4 (40 mM) while the untreated control consisted of cells kept in phosphate-buffered saline. The levels of ALT and AST were assessed spectrophotometrically at 546 nm in the supernatant using commercially available kits according to the manufacturer's instructions as previously reported (Biodiagnostics, Cairo, Egypt).
The concentration of GSH and the activity of SOD were evaluated in cell lysates. GSH was determined by mixing equal volumes of the supernatant of a cell culture extract and 10% trichloroacetic acid–0.005 M ethylenediaminetetraacetic acid solution. This solution was then subjected to centrifugation at 6000 rpm for 15 min. To 0.5 mL of the resulting supernatant, 0.85 ml phosphate buffer (0.1 M, pH = 8) and 0.05 ml of 10 mM Ellman's reagent 5,5'-dithiobis-(2-nitrobenzoic acid) were added, and the optical density of the stable yellow color developed by the reduction of Ellman's reagent through the SH-group in GSH was measured colorimetrically at 412 nm.
SOD activity was determined in the cell lysate through inhibition of pyrogallol autoxidation. Cytosolic fraction (20 μl) was added to a microcuvette containing 10 μL pyrogallol solution (10 mM dissolved in 10 mM HCl) and 1 ml Tris–HCl buffer (50 mM, pH = 8.2) containing 1 mM diethylene triamino pentaacetic acid. The change in absorbance per minute at 420 nm was recorded for 2 min.
All the spectrophotometric measurements were carried out using a Shimadzu ultraviolet (UV)-1601 spectrophotometer (Kyoto, Japan).
Statistical and chemometric data analyses
Statistical analysis for biological assessment was expressed as means ± standard error of mean. Statistical comparison between different groups was performed using one-way analysis of variance, followed by Tukey–Kramer multiple comparison tests, to judge the difference between various groups. Statistical significance was accepted at P < 0.05. Graphs were plotted using GraphPad Prism version 5 software (GraphPad Software, Inc. La Jolla, CA, USA). The data obtained from LC-MS for all samples and their replicates were transferred to an excel sheet by MS Excel® for multivariate analysis. The chemometric analysis of the data was performed using unsupervised pattern-recognition techniques applying both HCA and PCA. HCA was performed using Hierarchical Clustering Explorer 3.5 (Human-Computer Interaction Laboratory, University of Maryland, College Park, MD, USA), whereas PCA was performed by Unscrambler ® 9.7 (CAMO SA, Oslo, Norway). The data were subjected to preprocessing by mean centering of the raw data of all the samples before the analyses. The HCA was used to classify the sample into clusters applying the average group linkage method for cluster building in which the distance between clusters was calculated using Pearson's correlation method. Meanwhile, in PCA, the constructed scatter score plots of the initial PCs are indicative of the similarity and variations among samples.
| Results and Discussion|| |
High-performance liquid chromatography/electrospray ionization mass spectrometry profiling of the samples
HPLC-ESI-MS profiling of the major secondary metabolites in the aerial parts of three Ficus species reveals their richness in polyphenolics and furanocoumarins. Different polyphenolics and furanocoumarins were tentatively identified from the petroleum ether, ethyl acetate, butanol, and remaining aqueous fractions of F. cordata, F. ingens, and F. palmata by comparing their UV and LC-MS spectra (in both positive and negative ionization modes) with the published data [Table 1],[Table 2],[Table 3].,,,,,,,,,,,,,,,,,,,
|Table 1: The identified compounds in the various fractions of Ficus cordata aerial part by high-performance liquid chromatography/electrospray ionization mass spectrometry|
Click here to view
|Table 2: The identified compounds in the various fractions of Ficus ingens aerial part by high-performance liquid chromatography/electrospray ionization mass spectrometry|
Click here to view
|Table 3: The identified compounds in the various fractions of Ficus palmata aerial part by high-performance liquid chromatography/electrospray ionization mass spectrometry|
Click here to view
The results showed that polyphenolics comprising neochlorogenic acid (2), cryptochlorogenic acid (5), and chlorogenic acid (7) were mostly abundant in the different fractions of F. ingens. Besides, several flavonoid glycosides such as acanthophorbins A (22) and B (30), myricitrin (23), infectoriin (25), quercetin-3,4'-dirhamnoside (31) together with a prenylated flavonoid, and 2'-O- methylartonin V (12) were identified in various fractions of all examined species. The identified furanocoumarins can be distributed into two major subclasses either glucosylated furanocoumarins or their aglycones. Glucosylated furanocoumarins include corylifonol-6-O-glucoside (11), cnidiosides A (13) and B (15), psoralenoside (17), and aviprin-3'-O-glucoside (28). The aglycones encompass corylifonol (19), psoralic acid (27), dihydropsoralic acid (20), aviprin (33) together with psoralen (32), and bergapten (34) in addition to 11-methoxyvincamajine (18), an alkaloid, that has been identified in the ethyl acetate fraction of F. cordata [Figure 1]. The obtained chromatograms were displayed in the supplementary materials.
|Figure 1: Chemical structures of polyphenolics and furanocoumarins identified in Ficus cordata, Ficus ingens, and Ficus palmata|
Click here to view
Chemometric data analysis
The diversity of secondary metabolites, presents in various fractions of the three examined Ficus species as revealed by the HPLC-ESI-MS analyses, acts as a fundamental discriminatory tool through applying the unsupervised pattern-recognition techniques represented by PCA and HCA. PCA score plots showed the ability of all fractions to discriminate all the examined Ficus species without any overlapping by explaining 100% of the variance in the data, as shown in the first two PC1 and PC2.
In addition, the loading plots can partly express the influence of the different variables on the separation between classes. In both the petroleum ether and ethyl acetate fractions, acanthophorbin B and psoralen were the main active constituents discriminating F. ingens and F. palmata, respectively. Regarding F. cordata, bergapten and 11-methoxyvincamajine were the main characteristic components with the greatest influence on its segregation in the petroleum ether and ethyl acetate fractions, respectively.
Meanwhile, neochorogenic acid and infectoriin were the main discriminating markers for F. ingens and F. palmata, respectively, in both the n-butanol and remaining aqueous fractions [Figure S6c and d]. Corylifonol-6-O-glucoside and aviprin represent the strongest variables for the segregation of F. cordata in n-butanol and the remaining aqueous fractions, respectively.
PCA score plot of all the tested samples [Figure 2] resulted in two orthogonal PCs, which explained about 70% of the variance in 180-dimensional space using only the first two components (the first PC accounts for 42% of the total variance followed by the second PC 28%). PCA plot could significantly discriminate F. ingens species in all the tested fractions (Ficus ingens petroleum ether fraction [FIP], Ficus ingens ethyl acetate fraction [FIE], Ficus ingens n-butanol fraction [FIB], and Ficus ingens remaining aqueous fraction [FIA]), where it was observed on the left side upward quadrant, whereas the right side of the plot, Ficus palmata petroleum ether fraction (FPP), and Ficus palmata ethyl acetate fraction (FPE) were located. However, Ficus palmata n-butanol fraction (FPB) and Ficus palmata remaining aqueous fraction (FPA) were clustered together with Ficus cordata petroleum ether fraction (FCP), Ficus cordata ethyl acetate fraction (FCE), Ficus cordata n-butanol fraction (FCB), and Ficus cordata remaining aqueous fraction (FCA). This PCA pattern indicated the chemical closeness of F. palmata to F. cordata.
|Figure 2: Principal component analysis score plot constructed from high-performance liquid chromatography/electrospray ionization mass spectrometry profile as the analytical data (n = 3), illustrating the discrimination of three Ficus species combining all the previously tested fractions obtained from the total methanol extracts of their aerial parts|
Click here to view
Moreover, HCA was performed by applying the average group linkage method for cluster building, and the distance between clusters is computed by Pearson's correlation method. The obtained dendrogram showed four main clusters, revealing the close distance of F. palmata to F. cordata that confirmed that both species are more closely related chemically to each other rather than F. ingens [Figure 3].
|Figure 3: Hierarchical cluster analysis dendrogram constructed from high-performance liquid chromatography/electrospray ionization mass spectrometry profile as the analytical data (n = 3), illustrating the distances between three Ficus species various fractions of the total methanol extracts of their aerial parts|
Click here to view
Antioxidant and hepatoprotective assessment
The evaluation of the antioxidant and hepatoprotective activity was carried out in vitro using the HepG2 cells, where CCl4 was chosen as a hepatotoxic agent to induce the oxidative stress in cell lines. In general, a marked elevation in the serum level of ALT and AST enzymes (P < 0.05) was noticed in CCl4-treated cells estimated by 65.90 and 49.38%, respectively, comparable to normal cells.
The ethyl acetate fraction of all the examined Ficus species showed significant concentration-dependent amelioration of CCl4-induced damage as evidenced from values of ALT and AST. It is worthy to mention that FCE, FIE, and FPE produced 54.78%, 55.46%, and 56.42% reduction in serum level of ALT and 56.82%, 54.16%, and 57.06% suppression in serum level of AST, respectively, at 100 μg/ml. They showed superior activity when compared to silymarin that showed 37.27% and 51.99% decrease in ALT and AST, respectively, at 100 μg/mL [Table 4],[Table 5],[Table 6]. This was subsequently followed by the n-butanol fraction that also showed a pronounced decline in ALT and AST levels with concomitant improvement of CCl4-induced damage. FCB, FIB, and FPB treated cells showed 33.81%, 48.30%, and 50.60% reduction in ALT and 52.80%, 52.69%, and 55.94% decline in AST, respectively, at a dose of 100 μg/mL.
|Table 4: Antioxidant and hepatoprotective activities of the various fractions of Ficus cordata aerial part (alanine transaminase, aspartate transaminase, reduced glutathione, and superoxide dismutase)|
Click here to view
|Table 5: Antioxidant and hepatoprotective activities of the various fractions of Ficus ingens aerial part (alanine transaminase, aspartate transaminase, reduced glutathione, and superoxide dismutase)|
Click here to view
|Table 6: Antioxidant and hepatoprotective activities of the various fractions of F. palmata aerial part (alanine transaminase, aspartate transaminase, reduced glutathione, and superoxide dismutase)|
Click here to view
Moreover, at a dose of at 100 μg/ml, FCT, FCP, and FCA displayed moderate amelioration in HepG2 cells damage induced by CCl4 showing 33.93%, 24.09%, and 29.89% decline in ALT and 34.40%, 48.00%, and 46.94% lowering in AST serum levels, respectively. On the other hand, FIT, FIP, and FIA showed 25.35%, 29.70%, and 37.26% decrease in ALT as well as 34.58%, 42.26%, and 52.13% reduction in AST, respectively. However, FPT, FPP, and FPA were nonsignificant from the normal control as well as the silymarin-treated cells revealing 39.21%, 32.16%, and 42.58% fall in ALT leakage from hepatic cells as well as 48.63%, 48.09%, and 57.71% lowering in AST levels [Figure 4].
|Figure 4: Effect of pretreatment of human hepatocellular carcinoma cells with the various fractions of the total methanol extracts of the aerial parts of three Ficus species at a dose of 100 μg/mL on various hepatoprotective and antioxidant parameters alanine transaminase (a), aspartate transaminase (b), reduced glutathione (c), and superoxide dismutase (d). Data are measured in triplicates (n = 3) and presented as means ± standard error of mean|
Click here to view
Regarding pretreatment of HepG2 cells with the n-butanol fractions, namely, FCB, FIB, and FPB resulted in a pronounced elevation in the antioxidant parameters showing 113.05%, 151.83%, and 133.55% increase for GSH and 412.50%, 483.34%, and 550.50% rise for SOD with respect to CCl4-treated cells at a dose of 100 μg/ml [Table 4],[Table 5],[Table 6]. Besides, at a 100 μg/mL dose, the ethyl acetate fractions of all tested species exhibited prosperous antioxidant capabilities producing 111.23%, 143.86%, and 120.89% elevation in GSH and 487.34%, 541.88%, and 604.28% increase in SOD, respectively. In addition, FIA, FPT, and FPA showed powerful antioxidant activity resulting in 129.76%, 121.67%, and 141.90% rise in GSH with concomitant rise in SOD by 600%, 596.42%, and 496.68%, respectively, whereas FCT, FCP, FCA, FIT, FIP, and FPP produce mild antioxidant activity as evidenced from GSH and SOD values [Figure 4].
To sum up, the ethyl acetate fraction followed by the n-butanol fractions of all the examined Ficus species showed significant antioxidant and hepatoprotective effects as evidenced by the amelioration of AST and ALT as well as replenishing of GSH and SOD in the treated cells [Figure 4]. These could be partly explained in view of the presence of plenty of phytoconstituents as the ethyl acetate followed by n-butanol exhibited the best extractive power of the polyphenolics and furanocoumarins reflected by the higher number of peaks identified in the respective HPLC chromatograms. Polyphenolics and furanocoumarins act as free radical scavengers mediated by their ability to bind transition metals, iron and copper by adjacent –OH groups, or other chelating structures and thus inhibiting the free radical chain reactions and explaining their antioxidant potential.,
| Conclusion|| |
The methanol extracts as well as the successive fractions of the aerial parts of F. cordata, F. ingens, and F. palmata are rich sources of polyphenolics and furanocoumarins as tentatively identified by the HPLC-ESI-MS. These secondary metabolites serve as powerful discriminatory tools for the three species through applying chemometrics multivariate analysis techniques particularly unsupervised pattern-recognition techniques, namely, PCA and HCA. In addition, polyphenolics and furanocoumarins greatly contributed to the hepatoprotective activity of the tested samples and their tendency to combat oxidative stress. This will shed a light on the potential use of the various Ficus species as promising hepatoprotective agents. However, isolation of the secondary metabolites with subsequent in vivo biological assessment is required to ascertain the claimed results.
The authors would like to acknowledge Dr. Eckhard Roth (BIO-MAR Company) and Prof. Dr. Peter Proksch, (Heinrich-Heine Universität, Düsseldrof, Germany) for conducting LC-MS analyses using their facilities.
Financial support and sponsorship
Conflicts of interest
There are no conflicts of interest.
| References|| |
Hybertson BM, Gao B, Bose SK, McCord JM. Oxidative stress in health and disease: The therapeutic potential of Nrf2 activation. Mol Aspects Med 2011;32:234-46.
Samarghandian S, Borji A. Anticarcinogenic effect of saffron (Crocus sativus
L.) and its ingredients. Pharmacognosy Res 2014;6:99-107.
Jayaram S, Dharmesh SM. Assessment of antioxidant potentials of free and bound phenolics of Hemidesmus indicus
(L) R. Br against oxidative damage. Pharmacognosy Res 2011;3:225-31.
Mousa O, Vuorela P, Kiviranta J, Wahab SA, Hiltunen R, Vuorela H. Bioactivity of certain Egyptian Ficus
species. J Ethnopharmacol 1994;41:71-6.
Lansky EP, Paavilainen HM. Traditional herbal medicines for modern times. Figs: The Genus Ficus
. Boca Raton: CRC Press FL; 2011.
Jona R, Gribaudo I. Ficus
spp. New York: Trees III, Springer; 1991.
Wakeel O, Aziba P, Ashorobi R, Umukoro S, Aderibigbe A, Awe E. Neuropharmacological activities of Ficus platyphylla
stem bark in mice. Afr J Biomed Res 2004;7:75-8.
Badgujar SB, Patel VV, Bandivdekar AH, Mahajan RT. Traditional uses, phytochemistry and pharmacology of Ficus
carica: A review. Pharm Biol 2014;52:1487-503.
Jain R, Rawat S, Jain SC. Phytochemicals and antioxidant evaluation of Ficus racemosa
root bark. J Pharm Res 2013;6:615-9.
Donfack H, Kengap R, Ngameni B, Chuisseu P, Tchana A, Buonocore D, et al
. Ficus cordata
Thunb (Moraceae) is a potential source of some hepatoprotective and antioxidant compounds. Pharmacologia 2011;2:137-45.
Abd El Raheim MD, Soliman GA, Zaghloul AM, Alqasoumi SI, Awaad AS, Radwan AM, et al
. Chemical constituents and protective effect of Ficus ingens
(Miq.) Miq. on carbon tetrachloride-induced acute liver damage in male Wistar albino rats. J Saudi Chem Soc 2013;17:125-33.
Alqasoumi SI, Basudan OA, Al-Rehaily AJ, Abdel-Kader MS. Phytochemical and pharmacological study of Ficus palmata
growing in Saudi Arabia. Saudi Pharm J 2014;22:460-71.
Damu AG, Kuo PC, Shi LS, Li CY, Kuoh CS, Wu PL, et al.
Phenanthroindolizidine alkaloids from the stems of Ficus septica
. J Nat Prod 2005;68:1071-5.
Pistelli L, Chiellini EE, Morelli I. Flavonoids from Ficus pumila.
Biochem Syst Ecol 2000;28:287-9.
Ragab EA, Mohammed Ael-S, Abbass HS, Kotb SI. A new flavan-3-ol dimer from Ficus spragueana
leaves and its cytotoxic activity. Pharmacogn Mag 2013;9:144-8.
Poumale HM, Kengap RT, Tchouankeu JC, Keumedjio F, Laatsch H, Ngadjui BT. Pentacyclic triterpenes and other constituents from Ficus cordata
(Moraceae). Z Naturforsch B 2008;63:1335-8.
Kuete V, Ngameni B, Simo CC, Tankeu RK, Ngadjui BT, Meyer JJ, et al.
Antimicrobial activity of the crude extracts and compounds from Ficus chlamydocarpa
and Ficus cordata
(Moraceae). J Ethnopharmacol 2008;120:17-24.
Odunbaku O, Ilusanya O, Akasoro K. Antibacterial activity of ethanolic leaf extract of Ficus exasperata
on Escherichia coli
and Staphylococcus albus.
Sci Res Essay 2008;3:562-4.
Iqbal D, Khan MS, Khan A, Khan MS, Ahmad S, Srivastava AK, et al. In vitro screening for ß-hydroxy-ß-methylglutaryl-CoA reductase inhibitory and antioxidant activity of sequentially extracted fractions of Ficus palmata Forsk. Biomed Res Int 2014;2014:762620.
Saklani S, Chandra S. Antimicrobial activity, nutritional profile and quantitative study of different fractions of Ficus palmate.
Int Res J Plant Sci 2011;2:332-7.
Cragg GM, Newman DJ. Natural products: A continuing source of novel drug leads. Biochim Biophys Acta 2013;1830:3670-95.
Ernst E. Herbal medicines put into context: Their use entails risks, but probably fewer than with synthetic drugs. Br Med J 2003;327:881.
Reitman S, Frankel S. A colorimetric method for the determination of serum glutamic oxalacetic and glutamic pyruvic transaminases. Am J Clin Pathol 1957;28:56-63.
Ellman M. A spectrophotometric method for determination of reduced glutathione in tissues. Anal Biochem 1959;74:214-26.
Nishikimi M, Roa N, Yogi K. Colorimetric determination of superoxide dismutase in tissue. Biochem Biophys Res Commun 1972;46:849-54.
Gad HA, El-Ahmady SH, Abou-Shoer MI, Al-Azizi MM. A modern approach to the authentication and quality assessment of thyme using UV spectroscopy and chemometric analysis. Phytochem Anal 2013;24:520-6.
Pauli GF, Kuczkowiak U, Nahrstedt A. Solvent effects in the structure dereplication of caffeoyl quinic acids. Magn Reson Chem 1999;37:827-36.
Nakatani N, Kayano S, Kikuzaki H, Sumino K, Katagiri K, Mitani T. Identification, quantitative determination, and antioxidative activities of chlorogenic acid isomers in prune (Prunus domestica
L.). J Agric Food Chem 2000;48:5512-6.
Laurent D, Guella G, Mancini I, Roquebert MF, Farinole F, Pietra F. A new cytotoxic tetralone derivative from Humicola grisea
, a filamentous fungus from wood in the southeastern lagoon of New Caledonia. Tetrahedron 2002;58:9163-7.
Hamed AI, Springuel IV, El-Emary NA. Benzofuran glycosides from Psoralea plicata
seeds. Phytochemistry 1999;50:887-90.
Chen CC, Huang YL, Huang FI, Wang CW, Ou JC. Water-soluble glycosides from Ruta graveolens
. J Nat Prod 2001;64:990-2.
Jayasinghe UL, Samarakoon TB, Kumarihamy BM, Hara N, Fujimoto Y. Four new prenylated flavonoids and xanthones from the root bark of Artocarpus nobilis
. Fitoterapia 2008;79:37-41.
Kim SB, Chang BY, Han SB, Hwang BY, Kim SY, Lee MK. A new phenolic glycoside from Cnidium monnieri
fruits. Nat Prod Res 2013;27:1945-8.
Qiao CF, Han QB, Mo SF, Song JZ, Xu LJ, Chen SL, et al.
Psoralenoside and isopsoralenoside, two new benzofuran glycosides from Psoralea corylifolia
. Chem Pharm Bull (Tokyo) 2006;54:714-6.
Morfaux AM, Mouton P, Massiot G, Le Men-Olivier L. Alkaloids from stem-bark of Tonduzia pittieri.
Zeng LM, Wang CJ, Su JY, Li D, Owen NL, Lu Y, et al
. Flavonoids from the red alga Acanthophora spicifera.
Chin J Chem 2001;19:1097-100.
Furusawa M, Ito T, Nakaya KI, Tanaka T, Ibrahim I, Iinuma M, et al
. Flavonol glycosides in two Diospyros
plants and their radical scavenging activity. Heterocycles 2003;60:2557-63.
Jain N, Ahmed M, Kamil M, Ilyas M. Isolation and characterization of luteolin 6-O-β-D-glucopyranoside 3'-O-α-L-rhamnoside from Ficus infectoria.
J Chem Res Synop 1990;12:396-7.
Koul S, Dhar K, Thakur R. A new coumarin glucoside from Prangos pabularia.
Poumale HM, Randrianasolo R, Rakotoarimanga JV, Raharisololalao A, Krebs HC, Tchouankeu JC, et al.
Flavonoid glycosides and other constituents of Psorospermum androsaemifolium
BAKER (Clusiaceae). Chem Pharm Bull (Tokyo) 2008;56:1428-30.
Marzouk MS, El-Toumy SA, Merfort I, Nawwar MA. Polyphenolic metabolites of Rhamnus disperma.
Masuda T, Takasugi M, Anetai M. Psoralen and other linear furanocoumarins as phytoalexins in Glehnia littoralis.
Hiermann A, Schantl D, Schubert-Zsilavecz M, Reiner J. Coumarins from Peucedanum ostruthium.
Tesso H, König WA, Kubeczka KH, Bartnik M, Glowniak K. Secondary metabolites of Peucedanum tauricum
fruits. Phytochemistry 2005;66:707-13.
Ngadjui BT, Dongo E, Happi EN, Bezabih MT, Abegaz BM. Prenylated flavones and phenylpropanoid derivatives from roots of Dorstenia psilurus.
Greenham JR, Grayer RJ, Harborne JB, Reynolds V. Intra- and interspecific variations in vacuolar flavonoids among Ficus
species from the Budongo Forest, Uganda. Biochem Syst Ecol 2007;35:81-90.
Knasmüller S, Parzefall W, Sanyal R, Ecker S, Schwab C, Uhl M, et al.
Use of metabolically competent human hepatoma cells for the detection of mutagens and antimutagens. Mutat Res 1998;402:185-202.
Korkina LG. Phenylpropanoids as naturally occurring antioxidants: From plant defense to human health. Cell Mol Biol (Noisy-le-grand) 2007;53:15-25.
Diwan R, Shinde A, Malpathak N. Phytochemical composition and antioxidant potential of Ruta graveolens
L. in vitro
culture lines. J Bot 2012;2012:Article ID:685427. [Doi: 10.1155/2012/685427].
[Figure 1], [Figure 2], [Figure 3], [Figure 4]
[Table 1], [Table 2], [Table 3], [Table 4], [Table 5], [Table 6]