Methanol extract of Melastoma malabathricum leaves exerted antioxidant and liver protective activity in rats

Liver is the largest organ in the human body and is a key organ of metabolism [1, 2]. Despite its considerable regenerative capacity, continuous and various exposures to xenobiotics, environmental pollutants, and chemotherapeutic agents could suppress and possibly overcome the natural protective mechanisms of the liver, leading to liver malfunction and later if it is not treated properly leads to injury. Despite the remarkable progresses in conventional medical therapies in the last 20 years, drugs available for the treatment of liver diseases were often limited in efficacy and could have triggered various unwanted side effects when compared to other medical therapies for liver diseases which were often difficult to handle [3]. Moreover, some of these modern hepatoprotective drugs did not offer protection against injury to the vital organ despite their direct or indirect action to improve the liver function. In response to these factors that limit the use of conventional drugs, attempts were continuously made by scientists all over the world working in the area of hepatoprotective drug discovery to identify new sources of agents with potential liver protective activity [4, 5].

Interestingly, in line with increase in patients attempt to use complementary and alternative medicines, particularly herbal/plant-based therapies, to cure various diseases, efforts are increasingly being carried out by scientists to investigate the hepatoprotective potential of various medicinal plants. One of the medicinal plants that have been widely used in the Malay traditional medicine is Melastoma malabathricum L., which is locally known as “Senduduk”. This small shrub belongs to the family Melastomaceae and is native to tropical and temperate Asia, including Malaysia, and the Pacific Islands. Despite being a well-known herb in Malaysia wherein its leaves, shoots and roots are prepared in various ways to treat various types of diseases (i.e. to treat cuts or wounds, puerperal infections, high blood pressure, diabetes, dysentery, diarrhea, piles, leucorrhea, epilepsy, ulcers, gastric ulcers, scar, skin diseases, pimple and black spot at skin, hemorrhoidal bleeding, rheumatism, arthritis, prolonged fever, cancer and tenderness in the legs, to stop bleeding, to prevent scarring from smallpox, and to relieve a toothache), attempts to scientifically investigate and confirm those claims are however lacking [6]. Scientifically, various types of extracts from different parts of M. malabathricum have been prepared and tested using a variety of in vitro and in vivo test models. The plant has been reported to possess various types of pharmacological activities (i.e. antibacterial, antiviral, antiparasitic, cytotoxicity, anticoagulant, platelet-activating factor inhibitory, wound healing, antiulcer, antidiarrheal, antivenom, anti-inflammatory, antinociceptive and antipyretic) at different doses or concentrations [7].

Various phytochemical constituents have been isolated and identified from various parts and extracts of M. malabathricum[8]. Focusing, particularly, on the leaves, several bioactive compounds have been identified from different types of extracts, namely: i) 70% acetone extract – isoquercitrin 6″-O-gallate, malabathrin-A, -B, -C, -D, -E and -F, 1,4,6-tri-O- galloyl-β-D-glucoside, 1,2,4,6-tetra-O- galloyl-β-D-glucoside, strictinin, casuarictin, pedunculagin, nobotanin-B, -D, -G, -H and -J, pterocarinin C, new complex tannins in which an ellagitannin and a flavan-3-ol are bound by a C-glycosidic linkage belonging to type II + tannins, casuarinin, (−)-epicatechin gallate, (−)-epicatechin, stachyurin, procyanidin-B2 and -B5, stenophyllanins A and B, alienanin B, and brevifolincarboxylic acid; ii) methanol extract – ursolic acid, 2-hydroxyursolic acid and asiatic acid, as well as glycerol-1,2-dilinolenyl-3-O-β-Dgalactopyranoside and glycerol 1,2-dilinolenyl-3-O- (4,6-di-O- isopropylidene)-β-D-galactopyranoside, 2,5,6-trihydroxynaphtoic carbonic acid, methyl-2,5,6-trihydroxynaphtalene carbonate, flavonol glycoside derivative, quercitrin and kaempferol-3-O-(2′,6′-di-O-p-trans-coumaroyl)-β-glucoside; iii) hexane fraction of methanol extract – β-sitosterol, α-amyrin, uvaol, quercetin, quercitrin, rutin, and sitosterol-3-O-β-D-glucopyranoside; iv) 90% aqueous methanolic extract – ursolic acid, 2α-hydroxyursolic acid and asiatic acid, β-sitosterol 3- O-β-Dglucopyranoside, glycerol 1,2-dilinolenyl-3-O-β-D-galactopyranoside and glycerol 1,2-dilinolenyl-3-O-(4,6-O- isopropylidene)-β-D-galactopyranoside; v) ethyl acetate extract – 2,5,6-trihydroxynaphtoic carbonic acid, methyl-2,5,6-trihydroxynaphtalene carbonate, and flavonol glycoside derivative, quercetin and quercitrin; and vi) hexane extract – 2,5,6-trihydroxynaphtoic carbonic acid, methyl-2,5,6-trihydroxynaphtalene carbonate, and flavonol glycoside derivative, α-amyrin, patriscabatrine and auranamide.

Based on the previously demonstrated anti-inflammatory activity of M. malabathricum and the reports relating, at least, the anti-inflammatory and antioxidant activities to the hepatoprotective mechanism [9‐11], the present study was carried out with an attempt to explore the antioxidant and hepatoprotective activities of M. malabathricum. It is postulated that M. malabathricum leaves extract, which possesses the anti-inflammatory activities, will also exert antioxidant and hepatoprotective activities. Therefore, the aim of the present study was to determine the hepatoprotective activity of methanol extract of M. malabathricum (MEMM) using the paracetamol-induced liver damage in rats as the animal model. In addition, the antioxidant activity, phytochemical content and HPLC profile of MEMM were also verified to support the hepatoprotective potential of the extract.

Paracetamol-induced liver injury model is a conventional model used to investigate the hepatoprotective activity of extracts/compounds [19]. In the present study, paracetamol (3 g/kg)) increased the liver weight and liver/body weight ratio of rats as previously reported and, upon biochemical analysis of the blood samples, increased ALT, ALP and AST, the liver enzymes in the serum. Histopathological observation of paracetamol-treated liver tissues revealed severe destruction of the liver normal architecture accompanied by reduction in the number of viable cells. Other observations include massive necrotic cells around the centrilobular zone expanding to parenchymal zone, which is distinguished by pyknosis and karyolysis nuclear.

Various mechanisms may be linked to the damage of the liver by different toxins. For examples, the CCl₄ is transformed by the cytochrome P450 system to produce highly reactive trichloromethyl free radicals whereas upon the administration of high dose of paracetamol, the sulfation and glucuronodation routes become saturated causing the high percentage of paracetamol molecules to be oxidized to highly reactive N-acetyl-p-benzoquinone imine (NAPQI) [20]. NAPQI, in particular, binds covalently to hepatocellular macromolecules [21, 22] that lead to activation of several biochemical processes (e.g. oxidative stress and glutathione (GSH) depletion) resulting in hepatotoxic effect [23]. NAPQI also acts on DNA, proteins, cellular proteins causing the dysfunction and death of hepatocytes that leads to liver necrosis [24]. Moreover, NAPQI bind to GSH to form conjugates, which will oxidize and convert GSH to glutathione disulfide (GSSG). This, in turn, reduces the GSH level in blood and liver [25]. The depletion of GSH level in blood and liver triggers the mitochondrial dysfunction, increase of lipid peroxidation and, lastly, development of acute hepatic necrosis. The necrotized hepatic parechymal usually releases pool of several enzymes, such as AST and ALT into the circulation [26] that is regarded as specific enzyme for detection of liver abnormalities [27, 28]. Moreover, AST is also considered as an essential marker as it is susceptible to mitochondrial deformation primarily in zone 3, centrilobular zone [27, 28].

The present study demonstrated the ability of MEMM to exert hepatoprotective activity and supported our earlier hypothesis that the extract possessed anti-inflammatory, antioxidant activities and also hepatoprotective effects. The hepatoprotective potential of MEMM was further supported by the ability of the extract to reduce the serum liver enzymes (ALT and AST) level and the liver/body weight ratio, and the histopathological findings. However, through this study also the consumption of MEMM for 7 days was found to reduce the body weight of rats. This finding is in accordance with previous studies by Shimoda et al. [29] and Auvichayapat et al. [30], who reported on the presence of extracts such as green tea extract or green bean coffee extract, that reduced body weight of rats, respectively. Although the exact compound(s) that caused the suppression of rats’ body weight was not yet determined and not part of the objective of the present study, the presence of high polyphenolic compounds as well as flavonoids in MEMM [12] is suggested to play a significant role based on previous report by Yang et al. [31] and Pichiah et al. [32]. According to Shimoda et al. [29] the body weight loss effect is usually seen with extracts containing high polyphenols (i.e. green tea extract and coffee). Previous study demonstrated that that modest weight loss, which is approximately 5-10% of the initial body weight, is correlated with marked advancements in various risk factors [33]. The ability of MEMM to trigger a body weight loss effect as seen in the present study is suggested to cause no adverse effect to the body because MEMM considerably prevented the increase in body weight of approximately 10%. Since MEMM is a crude extract containing several types of compounds, including quercetin, quercitrin and rutin, it is also plausible to propose that the ability to reduce rats’ body weight involves synergistic action of those compounds as reported by Yang et al. [31].

Lately, much interest has been given towards the possible involvement of oxidative stress in the initiation and/or progression of paracetamol-induced hepatotoxicity. Reactive oxygen and nitrogen intermediates, generated by hepatic paranchymal and non-paranchymal cells are thought to play important roles that lead to paracetamol-induced injury [34‐36]. Therefore, any compounds with high antioxidant capability are potential candidate for further development as hepatoprotective agents. Of various potential candidates, plants have been prominent source of either new or known extracts and bioactive compounds with diverse pharmacological activities. Plants have been reported to exert antioxidant activity whereas antioxidant activity has been suggested as the possible mechanism responsible for the protection against paracetamol-induced liver injury. Interestingly, our hypothesis is in accordance with report made by Gupta et al. [37] that the combination of hepatoprotective and antioxidant activities synergistically exerts the processes of initiation and progress of hepatocellular damage. In the present study, the MEMM has been shown to possess a high antioxidant effect through the DPPH- and superoxide anion- radical scavenging, and ORAC assays. Moreover, the extract also contained a very high TPC value wherein several reports have demonstrated the correlation between the high TPC value and the high antioxidant potential [38, 39]. Therefore, it is plausible to suggest that the mechanism of hepatoprotection exhibited by MEMM may, in part, include its ability to self-act as a free radical scavenger that might intercept those free radicals involved in paracetamol metabolism by the microsomal enzymes [23]. Therefore, by ensnaring oxygen related radicals the MEMM could hamper their interaction with polyester fatty acids and would eliminate the enhancement of lipids peroxidative processes leading to MDA formation [36‐39]. With regards to the contribution of the bioactive compounds towards the observed antioxidant activity of MEMM, the involvement of quercetin, quercitrin and rutin are worth mentioning based on previous reports [40‐42].

Other than the oxidation processes, the inflammatory processes have been thought to be intimately involved in the chemical-induced hepatotoxic processes [43]. The inflammatory processes activated by toxic agents like PCM produce various mediators, which are involved in the production of ROS and NO that can affect liver damage or repair. Therefore, it is likely to propose that the extracts/compounds exerting an anti-inflammatory activity may also show hepatoprotective activity. Based on the histological observations and scoring of the hepatotoxic liver, pre-treatment with MEMM reduced the appearance of inflammation suggesting the involvement of anti-inflammatory mechanism [6, 44]. The potential of the bioactive compounds in the anti-inflammatory activity of MEMM could be contributed by quercetin, quercitrin and rutin, in accordance with previous reports [45‐47].

Phytochemical constituents have been known to play important role in determining the pharmacological potentials of various medicinal plants. Various types of bioactive compounds have been isolated, identified and scientifically proven to possess certain types of pharmacological activities from various types of plants. In term of the MEMM, flavonoids, tannins, saponins and steroids have been identified in the extract, which has also been reported to possess high TPC value [12]. The presence of flavonoids and tannins [48], triterpenoids and flavonoids [49, 50], flavonol [51], flavonoids [52], triterpene, amides and flavonoids [53], flavonoids, phenolics, triterpenes, tritepenoids, tannins, saponins and steroids [54] from the leaves of M. malabathricum extracted using various organic solvents extracts have been reviewed elsewhere [8]. In term of the pharmacological activities, flavonoids exhibited antioxidant [55, 56], anti-inflammatory [57] and hepatoprotective [56, 57] activities; condensed tannins possess free radical scavenging and antioxidant, anti-inflammatory and hepatoprotective activities [58]; saponins exhibited hepatoprotective activity via modulation of its antioxidant [59] and anti-inflammatory activities [60]. Based on all of the above reports, the MEMM-induced hepatoprotective activity is believed to involve synergistic action of, at least, flavonoids, saponins and condensed tannins. The HPLC analysis of MEMM at 366 nm demonstrated the presence of 4 major peaks with λ_max falling in the region of 234.9, 254.3-367.2, 204.9-348.2 and 255.5-369.4 nm. These peaks may represent flavonoid-types of bioactive compounds (e.g. flavonoids subgroups are flavones, flavanones, flavonols, dihydroflavonols, and flavanonols) (Ali et al., 2010). The UV–vis spectra of flavonoids consist of two absorbance bands labeled as band A and band B [61]. For flavones and flavonols, band A falls in the range of 310–350 nm and 350–385 nm while band B lies in the range of 250–290 nm, respectively. In the case of flavanones and dihydroflavonols, the wavelength of band A is often in the range of 300–330 nm while band B falls in the range of 277–295 nm. Furthermore, many polyphenols including flavonols demonstrated maximal absorbance at the wavelengths between 270 and 290 nm [52]. Based on their respective wavelength in the chromatogram, we suggested that peak 2 and peak 4 might probably be the flavonoid-types of compounds. Further HPLC analysis in preliminary attempt to standardize the extract demonstrated that the MEMM contained quercetin, quercitrin and rutin.

The MEMM exhibited hepatoprotection against paracetamol-induced liver injury model, which could be, partly, attributed to its antioxidant activity and, linked to the presence and synergistic action of flavonoids, tannins and saponins. Further studies are warranted and are being planned to determine the possible hepatoprotective mechanism(s) involved and, to isolate and identified the responsible bioactive compounds.