Inhibitory Effect of Aqueous Extract of Moringa oleifera and Newbuoldia laevis Leaves on Ferrous Sulphate and Sodium Nitroprusside Induced Oxidative Stress in Rat’s Testes in Vitro ()
1. Introduction
Infertility is a major clinical problem, affecting people medically and psychosocially. Published literature data indicates that 15% of all couples in the United States are infertile, and the male factor is responsible for 25% of these cases [1]. In many cases the cause of male infertility, oxidative stress (OS) has been identified as one of the major factors that affects fertility status and thus, has been extensively studied in recent years. Spermatozoa, like any other aerobic cell, are constantly facing the “oxygen-paradox” [2]. Oxygen is essential to sustain life as physiological levels of reactive oxygen species (ROS) are necessary to maintain normal cell function [3]. Conversely, breakdown products of oxygen such as ROS can be detrimental to cell function and survival [4]. Reactive oxygen species are present as free radicals. Examples of ROS include the hydroxyl superoxide radical, hydrogen peroxide, peroxyl radical, and hypochlorite ion. These are the common forms of ROS that have been considered injurious to sperm survival and function when present in abundance.
Although iron is necessary physiologically as components of many enzymes and proteins, free iron in the cytosol and mitochondria could cause considerable oxidative damage by acting catalytically in the production of ROS which have the potential to damage cellular lipids, nucleic acids, proteins and carbohydrate resulting in wide ranging impairment in cellular function and integrity [5]. The mechanism by which iron can cause this deleterious effect is that Fe (II) can react with hydrogen peroxide (H2O2) to produce the hydroxyl radical (OH) via the Fenton reaction, whereas superoxide can react with iron (III) to regenerate iron (II) that can participate in the Fenton reaction [6]. The overproduction of ROS can lead to direct attack on the polyunsaturated fatty acids of the cell membranes and induce lipid peroxidation. The mammalian spermatozoa are rich in polyunsaturated fatty acids (PUFA) and thus, are very susceptible to ROS attack which results in a decrease sperm motility [7].
Sodium nitroprusside (SNP) is an anti-hypertensive drug, which acts by relaxing smooth vascular muscle; consequently it dilates peripheral arteries and veins. However, it could cause cytotoxicity through the release of cyanide ion and/or nitric oxide (NO). ROS can directly attack the polyunsaturated fatty acids of the cell membranes and induce lipid peroxidation. Malondialdehyde (MDA) is the end product of lipid peroxidation, which is a process where reactive oxygen species (ROS) degrade polyunsaturated fatty acids. MDA is a reactive aldehyde and is one of the many reactive electrophile species that cause toxic stress in cells. The production of this aldehyde is used as a biomarker to measure the level of oxidative stress in an organism [8].
Recently, a lot of attention has been focused on the role of the antioxidative defense system in fighting oxidative stress [9,10]. Endogeneous antioxidants in plants may play an important role in antioxidative defense against oxidative damage [11], possibly preserving the biological functions of cells [12]. There is increasing interest in the protective biological function of natural antioxidants contained in dietary plants, which are candidates for the prevention of oxidative damage [13,14]. These antioxidants are polyphenolic compounds, which are found in all plants and in all parts of the plants (tree bark, stalks, leaves, fruits, roots, flowers, pods and seeds) [14].
Phenolic compounds are an important group of secondary metabolites, which are synthesized by plants because of plant adaptation to biotic and abiotic stress condition such as infection, water stress, and cold stress [15]. In recent years, phenolic compounds have attracted the interest of researchers because of their antioxidants capacity; they can protect the human body from free radicals, which are formed due to normal natural metabolism in aerobic cells. The antiradical activity of flavonoids and phenolics is principally based on the structural relationship between different parts of their chemical structure [16]. Polyphenolics are common constituents of the human diet, present in most foods and beverages of plant origin. They are considered to contribute to the prevention of various degenerative diseases. This assumption originally came from in vitro studies, showing the antioxidant properties of several polyphenolics and their ability to modulate the activity of various enzymes. Research suggests that many flavonoids are more potent antioxidant than vitamins C and E [17,18].
Moringa oleifera, also called horse radish or drumstick tree and known by many native names in Nigeria such as zogalle (in Hausa), okweoyibo (in Igbo), eweigbake (in Yoruba) and dogalla (in Taroh), belongs to the monogeneric family Moringaceae [19]. M. oleifera is well known for its nutritional as well as medicinal values by many communities in Northern Nigeria. The leaf of this plant is used as vegetable in soup preparation or cooked and mixed with grounded groundnut cake and other spices. Medicinally, the plant was reported to exhibit anti-inflammatory, antihypertensive and anti-ulcer activities [20,21]. The plant is also well known for its use in traditional therapies as abortifacient and infertility control [22]. Phytochemical investigation on the plant revealed the presence of moringine and moringinine alkalodis in the root; pterygospermine alkaloid in the flower, fatty acids and fixed oils in the seed.
Newbuoldia laevis (Bignoniaceae) commonly known as African Border tree (Hausa-Aduruku or Bareshi, IgboOgirisie, Yoruba-Akoko) is used for therapeutic purpose against a number of diseases. In Ivory Coast and Nigeria, stem bark decoctions of N. laevis is used for the treatment of epilepsy and convulsions in children [23]. After pulping, as a paste, the bark is used for treatment of rheumatism, especially for the painful arthritis of the knees [23]. In Nigeria, decoctions of leaves and roots made from boiling are used in the treatment of breast tumors and improve male fertility [24]. Although a lot had been reported on the chemical characterization of phytoconstituents and antioxidant properties of M. oleifera and N. laevis, there is still limited information on its potential use in the management and prevention of infertility diseases associated with oxidative stress. Hence, the objective of this study is to investigate the inhibitory effect of water extractable phytochemicals from Moringa oleifera and Newbuoldia laevis leaves on Fe2+ and SNP induced lipid peroxidation in rat testes in vitro.
2. Materials and Methods
2.1. Collection and Identification of Plant Samples
Fresh samples of Moringa oleifera and Newbuoldia laevis leaves were purchased in Akure metropolis, Nigeria. Authentication of the leaves was carried out in the Department of Plant Science, Ekiti State University, Ado Ekiti, Nigeria. The voucher specimen number given were UHAE 332 and UHAE 331 for Moringa oleifera and Newbuoldia laevis leaves respectively.
2.2. Chemicals and Reagents
Chemicals and reagents used such as thiobarbituric acid (TBA), 1,10-phenanthroline, deoxyribose, gallic acid, Folin-Ciocalteau’s reagent were procured from SigmaAldrich, Inc., (St Louis, MO), trichloroacetic acid (TCA) was sourced from Sigma-Aldrich, Chemie GmbH (Steinheim, Germany), dinitrophenyl hydrazine (DNPH) from ACROS Organics (New Jersey, USA), hydrogen peroxide, methanol, acetic acid and FeCl3 were sourced from BDH Chemicals Ltd., (Poole, England), thiourea, CuSO4·5H2O, H2SO4, sodium carbonate, AlCl3, potassium acetate, Tris-HCl buffer, sodium dodecyl sulphate, FeSO4, potassium ferricyanide and ferric chloride were of analytical grade while the water was glass distilled.
2.3. Aqueous Extract Preparation
The samples were washed under running water, air dried after which the dried samples were ground to powder and kept dry in an air-tight container prior to the extraction. 1 g each of the samples was weighed into 20 mL of distilled water and was left for 24 hours [25]. The mixture after 24 hours was filtered and the filtrate centrifuged at 805 × g for 10 minutes. The clear supernatant collected was used for the assay.
2.4. Determination of Total Phenolic Content
The total phenolic content was determined on the extracts using the method reported by Singleton et al. [26]. Appropriate dilutions of the extracts were oxidized with 2.5 mL of 10% Folin-Ciocalteau’s reagent (v/v) and neutralized by 2.0 mL of 7.5% sodium carbonate The reaction mixture was incubated for 40 minutes at 45˚C and the absorbance was measured at 765 nm in the spectrophotometer (JENWAY 6305, Barloworld Scientific, Dunmow, United Kingdom). The total phenolic content was subsequently calculated as gallic acid equivalent using gallic acid standard curve.
2.5. Determination of Total Flavonoid Content
The total flavonoid content of both extracts was determined using a slightly modified method reported by Meda et al. as described below briefly [27]. 0.5 mL of appropriately diluted sample was mixed with 0.5 mL methanol, 50 µL 10% AlCl3, 50 µL 1 M Potassium acetate and 1.4 mL water, and allowed to incubate at room temperature for 30 minutes. The absorbance of the reaction mixture was subsequently measured at 415 nm and the total flavonoid content was subsequently calculated using quercetin standard curve.
2.6 Determination of Vitamin C Content
Vitamin C content of the water extracts was determined using the method of Benderitter et al. as described below briefly [28]. 75 μL DNPH (2 g dinitrophenyl hydrazine, 230 mg thiourea and 270 mg CuSO4·5H2O in 100 mL of 5 M H2SO4) were added to 500 μL reaction mixture (300 μL of an appropriate dilution of the polar extract with 100 μL 13.3% trichloroacetic acid (TCA) and water). The reaction mixtures were subsequently incubated for 3 h at 37˚C, then 0.5 mL of 65% H2SO4 (v/v) was added to the medium; followed by absorbance measurment at 520 nm. The vitamin C content of the samples was subsequently calculated as ascorbic acid equivalent.
2.7. Lipid Peroxidation Assay
2.7.1. Experimental Animals
Male Wistar albino rats weighing between 190 and 250 g were purchased from the Central Animal House, Department of Biochemistry, University of Ilorin, Ilorin, Nigeria. They were housed in stainless steel cages under controlled conditions of a 12-hour light/dark cycle, 50% humidity, and 28˚C temperature. The rats were allowed asses to food and water ad libitum. The animals were used in accordance with the procedure approved by the Animal Ethics Committee of the Federal University of Technology, Akure, Nigeria.
2.7.2. Preparation of Tissue Homogenates
The rats were decapitated under mild diethyl ether anaesthesia and the testes (tissue) were rapidly dissected and placed on ice and weighed. This tissue was subsequently homogenized in cold saline (1/10 w/v) with about 10 strokes at approximately 1200 rev/min in a Teflon glass homogenizer (Mexxcare, mc14 362, Aayushi Design Pvt. Ltd., India). The homogenate was centrifuged (KX3400C Kenxin Intl. Co. Hong Kong) for 10 minutes at 3000 × g to yield a pellet that was discarded, and a low-speed supernatant (SI), which was kept for lipid peroxidation assay [29].
2.8. Lipid Peroxidation and Thiobarbibutric Acid Reactions
The lipid peroxidation assay was carried out using the modified method of Ohkawa et al. as described below briefly [30]. 100 µL of the SI fraction was mixed with a reaction mixture containing 30 µL of 0.1 M pH 7.4 Tris-HCl buffer, extract (100 µL) and 30 µL of 25 µM freshly prepared FeSO4. The volume was made up to 300 µL by water before incubation at 37˚C for 2 hours. The color reaction was developed by adding 300 µL 8.1% SDS (Sodium dodecyl sulphate) to the reaction mixture containing SI, this was subsequently followed by the addition of 600 µL of acetic acid/HCl (pH 3.4) mixture and 600 µL of 0.8% Thiobarbituric acid (TBA). This mixture was incubated at 100˚C for 1 hour. Thiobarbituric acid reactive species (TBARS) produced were measured at 532 nm and expressed as Malondialdehyde (MDA) produced (% control) using Malondialdehyde standard curve (0 - 0.035 mM).
2.9. DPPH Free Radical Scavenging Ability
The free radical scavenging ability of the extracts against DPPH (1,1-diphenyl-2 picrylhydrazyl) free radical was evaluated as described by Gyamfi et al. [31]. Briefly, an appropriate dilution of the extracts (1 mL) was mixed with 1 mL of 0.4 mM methanolic solution containing DPPH radicals, the mixture was left in the dark for 30 min and the absorbance was measured at 516 nm. The control was carried out using 2 mL DPPH solution without the test samples. The DPPH free radical scavenging ability was subsequently calculated.
DPPH scavenging ability (%) = [(Absorbance of Control − Absorbance of Samples)/Absorbance of Control] × 100.
2.10. Fe2+ Chelation Assay
The Fe2+ chelating ability of both extracts were determined using a modified method of Minotti and Aust [32] with a slight modification by Puntel et al., [33]. Freshly prepared 500 μM FeSO4 (150 μL) was added to a reaction mixture containing 168 μL of 0.1M Tris-HCl (pH 7.4), 218 μL saline and the extracts (0 - 25 μL). The reaction mixture was incubated for 5min, before the addition of 13 μL of 0.25% 1,10-phenanthroline (w/v). The absorbance was subsequently measured at 510 nm in a spectrophotometer. The Fe (II) chelating ability was subsequently calculated with respect to the reference (which contains all the reagents without the test sample).
2.11. Determination of Reducing Property
The reducing property of the extracts was determined by assessing the ability of the extract to reduce FeCl3 solution as described by Oyaizu [34]. A 2.5 mL aliquot was mixed with 2.5 mL of 200 mM sodium phosphate buffer (pH 6.6) and 2.5 mL of 1% potassium ferricyanide. The mixture was incubated at 50˚C for 20 min and then 2.5 mL of 10% trichloroacetic acid was added. This mixture was centrifuged at 650 rpm for 10 min. 5 mL of the supernatant was mixed with an equal volume of water and 1 mL of 0.1% ferric chloride. The absorbance was measured at 700 nm. The ferric reducing antioxidant property was subsequently calculated using ascorbic acid as standard.
2.12. Data Analysis
The results of the replicates were pooled and expressed as mean ± standard deviation. Analysis of variance and the t-test were carried out [35]. Significance was accepted at P ≤ 0.05.
3. Results and Discussion
3.1. Vitamin C, Total Phenolic and Flavonoid Contents
Many plants are rich sources of phytochemicals, and intakes of these plant chemicals have protective potential against degenerative diseases [36]. The vitamin C content of Moringa oleifera and Newbuoldia laevis leaves is presented in Table 1. The result revealed that there was no significant (P < 0.05) different between the vitamin C content of Moringa oleifera and Newbuoldia laevis leaves. Vitamin C has been reported to contribute to the antioxidant activities of plant food. Ascorbic acid is a good reducing agent and exhibits its antioxidant activities by electron donation [17,37]. It helps the immune system to fight off infections and tumor cells, supports the cardiovascular system by facilitating fat metabolism and protecting tissues from free radical damage, and it assists the nervous system by converting certain amino acids into neurotransmitters. As a water-soluble antioxidant, vitamin C is in a unique position to “scavenge” aqueous peroxyl radicals before these destructive substances damage the lipids [38]. The vitamin C content of the leaves is higher than that of related spices such as basil, bird pepper, black pepper, cinnamon, nutmeg, oregano, parsley and rosemary [39], and some commonly consumed green leafy vegetables in Nigeria [17,34], green and red pepper [23] and some commonly consumed and underutilized tropical legumes [40]. It is also worth noting that the vitamin C content of the leaf is higher than its total phenolic content. The high vitamin C content of the leafy spices will definitely contribute additively or synergistically to the observed antioxidant and medicinal properties of the leaves.
Furthermore, the total phenolic content of Moringa oleifera leaves (13.1 mg/g) had a significantly (P < 0.05) higher total phenolic content than Newbuoldia laevis (11.1 mg/g). However, the values obtained are lower than what was reported for some hot peppers [25] and green teas [41], but higher than ginger varieties [42] and some tropical leafy vegetables. Phenolic compounds can protect the human body from free radicals. They are strong antioxidants capable of removing free radicals, chelate metal catalysts, activate antioxidant enzymes, reduce alpha-tocopherol radicals and inhibit oxidases [43]. Also, the total flavonoid content of Moringa oleifera leaf (0.11 mg/g) was significantly (P < 0.05) higher than Newbuoldia laevis leaf (0.093 mg/g). However, the values
Table 1. Total Phenolic, flavonoid and vitamin C content of Moringa oleifera and Newbuoldia laevis leaves.
obtained are lower than what was reported for tropical clove bud [44] and some tropical green leafy vegetables [45]. The presence of derivatives of flavonoids has been found in many spices; moreover, numerous studies have conclusively shown that the majority of the antioxidant activity may be from compounds such as flavonoids, isoflavones, flavones, anthocyanins, catechin and isocatechin rather than from vitamins C, E and β-carotene [46]. Flavonoids have antioxidant activity and could therefore lower cellular oxidative stress. Polyphenols are considered to be strong antioxidants due to the redox properties of their hydroxyl groups [47].
3.2. Inhibition of Fe2+ Induced Lipid Peroxidation
Lipids are considered to be the most susceptible macromolecules and are present in male reproductive organ. One of the byproducts of lipid peroxidation is malondialdehyde, this byproduct has been used in various biochemical assays to monitor the degree of peroxidative damage sustained by spermatozoa [48,49]. Testicular toxicity due to Fe2+ impairs fertility [50]. The finding that Fe2+ caused a significant increase in the MDA content of the testes homogenate agreed with earlier report where Fe2+ was shown to be a potent initiator of lipid peroxidation [25]. The increased lipid peroxidation in the presence of Fe2+ could be attributed to the fact that Fe2+ can catalyze one-electron transfer reactions that generate reactive oxygen species, such as the reactive OH˙, which is formed from H2O2 through the Fenton reaction. Iron also decomposes lipid peroxides, thus generating peroxyl and alkoxyl radicals, which favors the propagation of lipid oxidation [51]. In the testes, Fe induced lipid peroxidation destroys the structure of lipid matrix in the membranes of spermatozoa, and it is associated with loss of motility and impairment of spermatogenesis [52]. Therefore, possible depletion of iron could decrease oxidative stress throughout the whole body. The ability of the water extractible phytochemicals from Moringa oleifera and Newbuoldia laevis leaves to inhibit Fe2+ induced lipid peroxidation in the testes homogenate is presented in Figure 1. The result revealed that incubation of the testes homogenate in the presence of Fe2+ caused a significant increase in the MDA content of the rat testes homogenate (137.5%) when compared with the basal testes homogenate (100%). However, the aqueous extract from Moringa oleifera and Newbuoldia laevis leaves inhibited MDA production in rat’s testes in a dose-dependent manner (0 - 0.63 mg/ml). Nevertheless, judging by the EC50 (extract concentration causing 50% enzyme inhibition) values in Table 2, Moringa oleifera leaf (EC50 = 0.29 mg/ml) had a significantly higher inhibitory effect on Fe2+ induced lipid peroxidation in the testes homogenate than Newbuoldia laevis leaf (EC50 = 0.58 mg/ml). The
Figure 1. Inhibition of Fe2+ induced lipid peroxidation in rat testes by aqueous extract of Moringa oleifera and Newbuoldia laevis leaves.
decrease in the Fe2+ induced lipid peroxidation in the rat testes homogenates in the presence of the extracts could be as the result of the ability of the extracts to chelate Fe2+ and/or scavenge free radicals produced by the Fe2+ catalyzed production of reactive oxygen species (ROS) in the rat testes.
3.3. DPPH Radical Scavenging and Fe2+ Chelating Assay
Antioxidants carry out their protective role on cells either by preventing the production of free radicals or by neutralizing/scavenging free radicals produced in the body or by reducing/chelating the transition metal composition of foods [53,54]. In an attempt to explain the main mechanism through which the water extractable phytochemicals in the plant extracts protect testes tissue against Fe2+ induced lipid peroxidation, the DPPH radical scavenging and Fe2+ chelating abilities were assessed.
The prevention of the chain initiation step by scavenging various reactive species such as free radicals is considered to be an important antioxidant mode of action [55]. DPPH is a free radical donor that accepts an electron or hydrogen to become a stable diamagnetic molecule [56]. The tendencies of electron or hydrogen donation are critical factors in characterizing antioxidant activity that involves free radical scavenging [57]. Foods of plant origin usually contain natural antioxidants that can scavenge free radicals [14]. The DPPH radical scavenging ability of the aqueous extract from Moringa oleifera and Newbuoldia laevis leaves as represented in Figure 2 revealed that both extracts scavenged DPPH radicals in a dose-dependent manner (0 - 3.33 mg/ml).
Both plant extracts chelate Fe2+ at the concentration of the extracts tested with Moringa oleifera leaf extract better chelator than Newbuoldia laevis leaf extract (Figure 3). This result however, is in agreement with the Fe2+ induced lipid peroxidation (Figure 1), phenolic content (Table 1) and antioxidant activity of the extracts, suggesting that Fe2+ chelation may be one of the possible mechanisms through which antioxidant phytochemicals from Moringa oleifera and Newbuoldia laevis leaf extracts prevent lipid peroxidation in tissue by forming a complex with Fe2+, thus preventing the initiation of lipid peroxidation.
3.4. Ferric Reducing Ability
Furthermore, the reducing power of the extractable phytochemicals from Moringa oleifera and Newbuoldia laevis leaf expressed as ascorbic acid equivalent (AAE) is presented in Figure 4. The result revealed that aqueous
Table 2. EC50 values of Inhibition of Fe2+ and SNP induced lipid peroxidation in rat testes by aqueous extract of Moringa oleifera and Newbuoldia laevis leaves.
Figure 2. DPPH radical scavenging ability of aqueous extract of Moringa oleifera and Newbuoldia laevis leaves.
Figure 3. Fe2+ chelating ability of aqueous extract of Moringa oleifera and Newbuoldia laevis leaves.
Figure 4. Ferric reducing antioxidant properties (FRAP) of aqueous extract of Moringa oleifera and Newbuoldia laevis leaves.
extract of Moringa oleifera leaf has a significantly higher reducing power than aqueous extract of Newbuoldia laevis leaf. The reducing power as characterized by the ability of the plant extracts to reduce Fe3+ to Fe2+ is a potent antioxidation defense mechanism, and two mechanisms available to affect this reducing power is by electron transfer and hydrogen atom transfer [16]. Allhorn et al. [58] reported that the reducing property can be a novel antioxidation defense mechanism, possibly through the ability of the antioxidant compound to reduce ferric ion. Therefore, the higher reducing ability of the Moringa oleifera leaf extract may have contributed to the greater protective effect observed. The higher reducing power of the Moringa oleifera leaf may be related to the higher water extractable antioxidant phytochemicals present in it (Table 1).
3.5. Inhibition of SNP Induced Lipid Peroxidation
Likewise, incubation of rat’s testes tissue homogenates in the presence of sodium nitroprusside also caused a significant increase in the rat testes malondialdehyde (MDA) content as shown in Figure 5; however, both extracts inhibited MDA production content in both tissues in a dose-dependent (0 - 0.63 mg/ml). However, judging by t he EC50 value in Table 2, there was no significant difference between the aqueous extract of Moringa oleifera and Newbuoldia laevis leaves. The protective properties of the plant extracts against sodium nitroprusside induced lipid peroxidation in the testes could be because of the ability of the antioxidant phytochemicals present in the aqueous extract to quench-scavenge the nitrous radical and Fe produced from the decomposition of sodium nitroprusside.
Figure 5. Inhibition of SNP induced lipid peroxidation in rat testes by aqueous extract of Moringa oleifera and Newbuoldia laevis leaves.
4. Conclusion
The aqueous extract of Moringa oleifera and Newbuoldia laevis leaves were able to protect the testes homogenate from Fe2+ and SNP induced lipid peroxidation in vitro. And part of the mechanisms through which the water extractable phytochemicals in the leaves protect the testes from oxidative stress may be through their antioxidant activity; DPPH scavenging ability, Fe2+ chelating and reducing power. Therefore, rat testes stress could be potentially managed/prevented by these plant extracts and can prove useful infertility treatment.
NOTES
#Corresponding author.