In vitro organo-protective effect of bark extracts from Syzygium guineense var macrocarpum against ferric-nitrilotriacetate-induced stress in wistar rats homogenates

Free radicals are produced from various physiological mechanisms owing to their significant biological roles in a myriad of signaling pathways at a reasonable dose [1, 2]. They are involved in defense mechanisms against pathogenic microorganisms and/or cancer cells and detoxification of harmful molecules [3]. Besides, reactive oxygen species (ROS) play vital roles in cells including stimulation of the signal transduction pathways, cell cycle regulation enzyme activation, and protein modification [4, 5]. In normal cells, free radicals are continuously produced in lower concentrations and can be neutralized by endogenous antioxidant species. Indeed, human body is endowed with protective mechanisms against deleterious effects of free radicals including both enzymatic and non enzymatic antioxidants [6]. However, when the naturally-occurring equilibrium between anti- and pro-oxidant agents is lost, higher ROS levels bypass the antioxidant function leading to a biochemical/physiological state described as oxidative stress [7, 8]. Oxidative stress refers to a state of imbalance between the production of free radicals and/reactive metabolites and removal of the latter by antioxidants [9]. Several factors are known to be responsible of this state. Among them, tobacco, alcohol, UV rays, medications, toxic metals, herbicides, nutritional failure or genetic defects responsible of non/poor expression of a gene encoding a protein or an antioxidant enzyme protein involved in the synthesis of an antioxidant could be listed [10]. Besides those exogenous factors, there are also endogenous sources mainly intracellular metabolism involving the mitochondrial respiratory chain, the defective autophagy of mitochondria and defective metabolism of redox metals [4, 11]. Oxidative stress can cause tremendous harmful effects including alteration of the protein structures and hence loss of vital functions. Evidence has indicated that oxidative stress is a potentiating factor of the onset of a broad range of diseases [12‐14]. Among these, hemolytic anemia and β-hemoglobinopathies (sickle cell anemia and thalassemia), cancer, atherosclerosis and, Alhzeimer’s disease are believed to be aggravated by ROS [15‐17]. These deleterious effects are counteracted by natural antioxidants [18, 19].

Numerous research results demonstrated that natural antioxidant molecules are anticarcinogenic anti-angiogenic and potent inhibitors of sickle cell haemoglobin polymerization [18, 20‐22]. Phenolics-enriched plant extracts exhibited strong antioxidant and beneficial effect against chemically-induced stress in vitro [23‐25] and in vivo [26, 27]. This justifies the upsurge of interest that naturally-occurring antioxidants from spices, vegetables, and herbs has been gaining [16, 23, 25, 28].

Syzygium guineense (Wild) DC. is a leafy forest tree of the Myrtaceae family, found in many parts of Africa both wild and domesticated which comprises three varieties. It is used in African traditional medicine to treat epilepsy, stomach-ache, diarrhoea, malaria, coughs, broken bones, wounds, asthma, sore throat, intercostal pain and as a tonic. The powdered bark is used as an antispasmodic and purgative [29]. The antibacterial properties of the aqueous extract of S. guineense have been demonstrated on different strains of bacteria responsible for diarrhea [30]. Ethanol extracts of the stem bark of S. guineense showed molluscicidal activities and cardioprotective properties, mainly due to the reduction of blood pressure [31]. Antibacterial activity of triterpenes isolated from S. guineense has been demonstrated [32]. Other biological properties such as anti-inflammatory, analgesic and immunological activities of different part of S. guineense have been reported [33]. The chemical composition of essential oil from S. guineense was also investigated [34]. A recent study demonstrated that leaves, stem bark and roots of S. guineense have antioxidant properties and are rich in polyphenols [23]. Almost all these biological properties are about the guineense variety. Up-to-date, no study investigating either the in vitro antioxidant activity or the protective effects of extracts of the macrocarpum variety has been carried out. Hence, this study attempted to investigate the in vitro free radical scavenging potential, antioxidant activity and the protective effect of S. guineense var macrocarpum barks extracts against ferric nitiloacetate-induced stress in the liver, heart and kidney and brain tissues of Wistar rats homogenates as well as their polyphenolic profile.

A wide range of methods have been described for the free radical trapping potential and antioxidant properties of plant-derived components. DPPH is one of the most used assays to assess the antioxidant potential of tremendous naturally food derived and plant extracts. Results of DPPH free radical scavenging potential of different plant extracts are summarized in Table 1A. The DPPH free radical scavenging potential increases with the plant extract concentration. Inhibitory potential expressed as percentages ranged from (59.52 ± 0.56 to 93.57 ± 1.68 %) for the aqueous extract which presented a significant and lowest inhibitory potential compared to the ethanol extract (94.40 ± 0.13 %). However, Vitamin C had the most potent inhibitory potential (98.31 ± 0.27 %). These results suggest that these extracts are rich in hydrogen atom and or electron donating-substances as phenolic derived compounds, glycosylated derived compounds and anthocyans capable of pairing with the unstable DPPH ^o radical [47].

Besides the scavenging of free radicals, group I antioxidants also quench protons to suppress their reactivity. ABTS⁺ cation scavenging potential of plant extracts was also investigated (Table 1B). Conversely to the results obtained with DPPH^•, the aqueous extract was more efficient to inhibit ABTS radical among the extracts and Vit C with a scavenging percentage of 97.15 ± 0.71 % demonstrated the highest inhibitory effects. The difference in activity found here between the different tested extracts can be due to the difference in number of hydroxyl groups present in molecules extracted by each solvent. Indeed, previous studies showed that the higher the number of free hydroxyl groups present in polyphenols, the higher their scavenging potential [48]. Moreover, the position of the hydroxyl group also influences the activity of the molecule [49, 50]. The 50 % inhibitory concentrations (IC₅₀) for the DPPH and ABTS⁺ radicals are displayed respectively in (Table 1A and B). From these results the ethanolic extract exhibited the lowest IC₅₀ values (1.944 μg/mL and 3.871 μg/μL) both for the DPPH^• and ABTS⁺ free radical scavenging efficiency.

The chelation of transition metals such as iron is a crucial in the prevention of radical generation which damage target biomolecules. Indeed, iron acts as catalyst in the Harber-Weiss reaction to generate the highly reactive hydroxyl radical. FRAP assay was used to investigate the capacity of plant extracts to act as preventive antioxidants. Results are displayed on Table 2. All the tested samples demonstrated a preventive antioxidant potential with different capacity depending of the tested extracts. However, the aqueous extract showed the significant best ferric reducing power compared to the other samples. In addition to the ferric reducing antioxidant power, the phosphomolybdenum antioxidant capacity of plant extracts investigated to better elucidate the antioxidant mechanism demonstrated that the best antioxidant capacity was exhibited by the aqueous ethanol extract. Moreover, the antioxidant capacity of this extract was twice higher than that of Butylated HydroxyToluene (BHT) used as the standard antioxidant.

Concerning the total phenol content, the ethanolic extract presented the highest content compared to the others. The same trend was observed with flavonoids and flavonols content (Table 2). These results highlighted the close relationship between the richness of plant extracts in polyphenols and their antioxidant capacity even though the antioxidant capacity depends on the mechanism involved. This suggestion is supported by the correlation coefficients values between total phenol content and FRAP assay (0.988), FRAP and flavonoids (1.00) and flavonol content (1.00) (Tables 3 and 4). The nature of the polyphenol and its concentration significantly affect the antioxidant activity of the extract. Our results from HPLC profile (Fig. 1 and Table 5) demonstrated a variety of polyphenol is different concentration which include phenolic acids (p-coumaric acid; syringic acid), flavonoids (catechin and caffeic acid) and other phenolic compounds.

Oxidation of biomolecules is currently considered as the main molecular mechanism involved in the toxicity process that lead to cell death. The iron complex of the chelating agent nitrilotriacetic acid was used to induce lipid peroxidation. Our results show that Fe³⁺- NTA led to a significant increase of lipid peroxidation associated with SOD, catalase, and glutathione peroxidase activity depletion in all tissues assayed compared to the negative control. These results are in accordance with those of [51] which showed Fe³⁺-NTA to be nephrotoxic, hepatotoxic. Indeed, Fe³⁺- NTA may act through the generation of free radicals with simultaneous decrease in antioxidant defenses.

Lipid peroxidation is commonly quantified in research studies by measuring the accumulation of the by-products that result from this process. One of these by-products is malondialdehyde (MDA). The results of the protective effects of plant extracts against lipid peroxidation (Fig. 2) show that this property varied according to the plant extract and tissue homogenate. All the extracts lowered significantly (p < 0.05) the level of MDA when compared to the negative control. However, the aqueous- ethanolic extract exhibited the best protective activity by lowering 93, 13 and 6 fold respectively the MDA content in the liver, kidney and brain homogenates comparatively to the negative control. Conversely, in the heart homogenates the ethanol counterpart was the most active inhibitory effects of lipid peroxidation. These results highlight the beneficial effect of these plant extracts since lipid peroxidation is a major problem for food industry as well as for human health and it is associated to many diseases. Moreover, the inhibition of lipid peroxidation is confirmed by the restoration and potentialization of SOD, catalase, and peroxidase activities in plant-treated homogenates.

SODs are the first line of defense against oxidative stress among the highly sophisticated antioxidant system evolved by mammalian cells to cope with deleterious effects of ROS. The ability of the extracts to restore the SOD activity after oxidative stress induced are summarized in the Fig. 3. The ability of plant extracts to protect SODs is homogenate-dependent. In the liver, all the fractions exhibited a protective capacity (although not significant comparatively to the negative control). In the heart homogenate conversely, the ethanol extract was the most efficient among the tested extract whereas, the aqueous and aqueous-ethanolic counterparts restored more efficiently the enzyme activity in the brain and kidney homogenates respectively. The ability of the samples to protect the cells may be linked to their antioxidant content. Antioxidant molecules may act either as electron donors or hydrogen atom donors as pointed out by the DPPH^• and ABTS⁺ radicals scavenging potential or by modulating the antioxidant enzymes activities. Besides the aforementioned mechanisms, metal transition chelation is not to be excluded to this process. Indeed, numerous studies [52, 53] have shown that flavonoids present in the investigated samples in a significant higher amounts are efficient iron chelators. Furthermore, they can also act as hydrogen donors and superoxide anion quenchers.

The ability of the plant extracts to potentiate the activity of catalase was also investigated since SODs are assisted by catalase in the conversion of hydrogen peroxide to water and oxygen. Results demonstrated that the exposure of liver, heart, brain and kidney homogenates to Fe³⁺-NTA reduces significantly the catalase activity in the negative control (homogenate treated only by the oxidant) while the treatment with all the sample extracts reversed significantly the depletion of the catalase activity (Fig. 4) in all the homogenates except the kidney where only the aqueous-ethanolic extract was significantly efficient. The aqueous extract exhibited the best protective effect of catalase both in the liver and brain homogenates whereas the aqueous-ethanolic and ethanol counterparts potentiate more the catalase activity in the kidney and heart homogenates respectively.

Removal of hydroperoxide which generates free radical is another way of preventing oxidation. Hydroperoxides can be reduced by enzymes such as glutathione peroxidase which cleared off the organism by eliminating organic hydroperoxide as well as hydrogen peroxide and peroxinitrites. The Fig. 5 displays the peroxidase protective potential of plant extracts against Fe³⁺ NTA-induced oxidative stress. From these results, aqueous extract was the most active sample both in the liver and kidney homogenates while the aqueous-ethanolic and ethanol extracts augmented more efficiently the activity of peroxidase in the heart and brain homogenates respectively. These results further confirmed the ability of these plant extract to protect biomolecules from oxidative damage since hydroperoxides decomposed rapidly to give many secondary products such as lipid free radicals which subsequently contribute to increase the oxidation of other molecules such as proteins, nucleic acids and other lipids leading to cancer, neurodegenerative pathologies and ageing [54].

Reduced glutathione (GSH) is often considered as the body’s master antioxidant since it is used as a cofactor by multiple peroxidases, transhydrogenases, and glutathione S- transferases enzymes. Figure 6 exhibits the reduced glutathione levels in different organ homogenates. The aqueous extract showed the most beneficial effect (p < 0.05) compared to the other samples by repleting GSH levels in all the homogenates. Furthermore, this beneficial effect is higher than that of vitamin C and quercetin used as positive controls except in the liver homogenate. This result further confirms the ability of these plant extracts to protect vital organs from deleterious effects of ROS since GSH is largely known to minimize the lipid peroxidation of cellular membranes and other such targets that are known to occur with oxidative stress [55].

The Spearman correlation (Table 5A) studied was assessed to determine the degree of association between free radical scavenging efficacy and polyphenolic metabolites content in the one hand and between enzymatic antioxidant, lipid peroxidation markers of different homogenates (Table 5B). In general, results showed a positive and significant correlation between ABTS and FRAP (0.781; 0.05) on one hand, and ABTS and total phenol content (0.795; 0.05), flavonols (0.781; 0.05) and flavonoid (0.781; 0.05) on the other hand (Table 5A). Few significant and positive correlation were found between some markers of protective effects of the plant extracts investigated mainly SOD and peroxidase (Table 5B).

The plurality of methods used addition to the complexity of oxidative stress and variability of results from each method, have led us to perform a principal component analysis (PCA) to better determine the best extracts purely from a statistical point of view.

From this analysis and the obtained results indicated that flavonols, total phenol content, flavonoids, and FRAP, are strongly correlated to the F₁ axis with contribution percentages of 18.917, for flavonols, flavonoids and FRAP, and 18.914 for the total phenol content whereas phosphomolybdenum, and DPPH are closely loaded to F₂ axis with 37.858 and 58.711 % contribution respectively (Fig. 7).

From the biplot (Fig. 7a’) the overall antioxidant effectiveness of plant extracts taking into account all the performed assays is as follows SGFEtOH/H₂O > SGFH₂O > SGFEtOH. Therefore the aqueous ethanolic extract of S. guineense var macrocarpum could be considered as the best extract regarding the antioxidant and protective effects.