GYAGrasas y Aceites0017-3495Consejo Superior de Investigaciones CientificasGYA201813_e243-110417210.3989/gya.1104172ArticlesIn vivo correlation of olive leaves extract on some oxidative stress markers in streptozotocin-induced diabetes mellitus in ratsAcción de extractos de hojas de olivo sobre marcadores del estrés oxidativo en diabetes mellitus inducida por estreptozotocina en ratasIn vivo correlation of olive leaves extract on some oxidative stress markers in streptozotocin-induced diabetes mellitus in ratsAfifyA.M.R.El-BeltagiH.S.*FayedS.A.El-AnsaryA.E.Biochemistry Dept, Faculty of Agriculture, Cairo University, P.O. 12613, Gamma st., Giza, Cairo- EgyptCorresponding author: helbeltagi@agr.cu.edu.eg
ORCID ID: Afify AMR https://orcid.org/0000-0001-8096-7649, El-Beltagi HS https://orcid.org/0000-0003-4433-2034, Fayed SA https://orcid.org/0000-0002-3449-6679, El-Ansary AE https://orcid.org/0000-0003-0585-1229
Diabetes mellitus type two (T2DM) is one of the most extensive diseases in the world. Herbal therapy remains a possible adjunct therapy to sustain better glycemic control and reduce complications arising from diabetes. In order to evaluate the curative impacts of olive leaf extract (OLE) on streptozotocin (STZ)-induced diabetic rats, twenty-four Wistar male adult rats were divided into four equal groups; control, diabetic control (45 mg/kg STZ), normal rats treated with OLE (17.8 mg/kg b.wt.), and diabetic rats treated with OLE (45 mg/kg STZ + 17.8 mg/kg b.wt.). The OLE extract was investigated for in vitro antioxidant activity using the DPPH• assay. The phenolic, tannin, and flavonoid contents were determined. The activity of GPX, SOD, and GSH in RBC lysate, CAT in plasma and MDA in serum were measured. The OLE prevented the decrease in GSH and kept MDA around the normal range in the treated diabetic rats. The current study suggests that OLE might be used safely to ameliorate T2DM and its accompanying oxidative stress.
RESUMEN
Acción de extractos de hojas de olivo sobre marcadores del estrés oxidativo en diabetes mellitus inducida por estreptozotocina en ratas. La diabetes mellitus tipo dos (DM2) es una de las enfermedades más extensas en el mundo. La terapia con hierbas sigue siendo una terapia complementaria para mantener un mejor control de la glucemia y reducir las complicaciones de la diabetes. Con el fin de evaluar los efectos curativos del extracto de hojas de olivo (OLE) en ratas diabéticas inducidas por estreptozotocina (STZ), veinticuatro ratas Wistar machos adultos se dividieron en cuatro grupos iguales; control, control diabético (45 mg/ kg STZ), ratas normales tratadas con OLE (17.8 mg/kg b.wt) y ratas diabéticas tratadas con OLE (45 mg / kg STZ + 17.8 mg / kg b.wt.). El extracto OLE se investigó para determinar la actividad antioxidante in vitro usando ensayos DPPH•. Se determinaron los fenoles, los taninos y el contenido de flavonoides. Se midió la actividad de GPX, SOD y GSH en lisado de RBC, CAT en plasma y MDA en suero. El OLE evitó la disminución de GSH y mantuvo MDA alrededor del rango normal en las ratas diabéticas tratadas. El estudio actual sugiere que OLE podría utilizarse de forma segura para mejorar la DM2 y el estrés oxidativo que le acompaña.
KEYWORDSAntioxidant enzymes activityDiabetes mellitus type twoFlavonoidsOlive leaves extractOxidative stressPhenolicsPALABRAS CLAVEActividad de enzimas antioxidantesDiabetes mellitus tipo dosEstrés oxidativoExtracto de hojas de olivoFenólicos Flavonoides1. INTRODUCTION
Oxidative stress reflects an imbalance between free radical production and antioxidant defense mechanisms which results in the damaging of some molecules (El-Beltagi et al., 2017). Oxidative stress has been recorded to play a key role in the incidence and development of diabetes mellitus type two (T2DM) and consequently its complications. In diabetic subjects, disorders of the oxidative systems cause disequilibrium in endothelial function, which further causes inflammation (Ceriello et al., 2013). Oxidative stress plays a vital role during the progression of diabetic nephropathy (El-Beltagi et al., 2016). One of the risk elements in T2DM and its complications is oxidative stress. So, preventing oxidative stress could be an efficient way to assure an integrated management of T2DM (Adefegha and Oboh 2016). The causes which led to hyperglycemia can be linked to a metabolic stress situation and deficient glucose circulation in insulin-targetted tissues such as liver, adipose tissue and skeletal muscle (Hadrich et al., 2016).
Olive tree (Olea europaea L.) leaves have been broadly used in traditional therapy in European and Mediterranean countries as herbal teas, extracts, and powder. Olive leaf infusions and/or decoctions have been traditionally used to treat diabetes. The olive leaf has been recently accepted as a safe product in the category of food additives, permitted by the European Food Safety Authority (EFSA) (EFSA NDA Panel, 2014). Promising results associated with the valuable effects of olive leaf extract on health related to the high quantity of phenolic compounds might inspire the industry to consider the value of olive leaves as a source of antioxidants for the production of medicines, cosmetics, and nutraceuticals (Afify et al., 2017). Olive leaves were presented to be an abundant source of possibly valuable phytochemicals. Polyphenolic compounds play a key role in their biological effects. Olive leaf extract is a recognized source of oleuropein, its main efficient component that displayed various potential pharmaceutical properties such as antioxidant, anti-mutagen and anti-genotoxic characteristics (Hassen et al., 2015).
The aim of the current research was to reveal the effect of an aqueous extract of olive leaves on the oxidative status accompanying T2DM, and therefore decrease the harmful effects of oxidative stress which are responsible for diabetes complications.
2. MATERIALS AND METHODS2.1. Materials
Streptozotocin was acquired from Sigma chemicals (St Louis, Mo, USA), at 97% purity. All other reagents used were of analytical grade.
2.2. Methods
Preparation of olive aqueous extract. An aqueous extract of olive leaves was prepared by washing dry leaves and cutting them into small pieces with a blender. Olive leaf powder (25 g) was soaked in 200 mL of distilled water and boiled for three minutes. The extract was collected and freeze dried on the same day; the fluid was about 195 mL. The extract was redissolved in distilled wáter.
Diabetes induction. T2DM was induced by intraperitoneally injecting a single dose of STZ per body weight (45 mg/kg b.wt.) dissolved in 0.01 M citrate buffer (pH 4.5) immediately before use. The rats had free access to food and water and were given a 5% glucose solution to drink overnight to encounter hypoglycaemic shock. The rats were checked daily for the presence of glycosuria. The rats were considered to be diabetic if glycosuria was present for 3 consecutive days. Three days after STZ injection, fasting blood samples were obtained and blood sugar was determined (≥ 300 mg/dL).
Animals. Twenty-four male Wistar rats (120 ± 10 g) were purchased from the animal house of Helwan station for experimental animals, Helwan, Egypt. The rats were retained in polyethylene cages in groups of 6 rats per cage in a controlled environment (25 ± 2 °C, 50–60% relative humidity and 12-hour light-dark cycle) for two weeks for adaptation. The rats were divided into four equal groups of 6 rats each. All experimental treatments were approved by Cairo University Ethics Committee for the Care and Use of Experimental Animals in Education and Scientific Research (CU-IACUC) and the approval number was CUIIS1616.
Experimental animal design. The animals were randomly allocated into four groups as follows:
Group 1: normal control.
Group 2: diabetic control (45 mg/kg STZ).
Group 3: normal rats treated with olive leaves extract (17.8 mg/kg b.wt.).
Group 4: diabetic rats treated with olive leafs extract (17.8 mg/kg b.wt.). Olive leaf extract was dissolved in distilled water and then given by oral gavage administration five days a week during the study period (10 weeks). The dose was calculated as 20 mg oleuropein/kg b.wt. Throughout this period, the rats were fed on a diet (TD.94045 AIN-93G Purified Diet) and water. The vitamin mix (AIN-93-VX) (1%) and mineral mix (AIN-93G-MX] (3.5%).
Blood sample preparation. Blood samples were collected from the orbital sinus under anesthesia as follows: ~ 3 mL in EDTA-coated tubes and ~ 2 mL in plain tubes, centrifuged at 3000 rpm for 10 min at 4 °C to get plasma and serum, respectively. The rats were sacrificed by cervical dislocation at the end of the study period.
2.3. Phytochemical compound determination2.3.1. Determination of phenolic content
Phenolic content was determined by using Folin-Ciocalteu reagent according to Ainsworth and Gillespie (2007). Briefly, 0.1 mL of sample aqueous extracts were added to 0.2 mL of 10% Folin-Ciocalteu reagent and vortexed thoroughly and then 0.8 mL of Na2CO3 (700 mM) were added into each tube and the assay tubes were incubated at room temperature for 2 h in the dark. Absorbance was measured at 765 nm. Gallic acid was used as reference standard. Results were expressed as mg of gallic acid equivalents (GAE)/g dry weight.
2.3.2. Determination of tannin content
The tannins contents of olive leaf extract were measured by the Folin-Denis method according to Saxena et al., (2013). Accurately 0.5 g of the powdered olive leaf extract was moved to a 250 mL conical flask. Seventy-five mL water were added. The flask was heated gently and boiled for 30 min then centrifuged at 2000 rpm for 20 min. The supernatant was collected in a 100 mL volumetric flask and the volume was made up. One mL of the sample extract was transferred to a 100 mL volumetric flask containing 75 mL water. Five mL of Folin-Denis reagent were added; 10 mL of a Na2CO3 (700 mM) solution was diluted to 100 mL with water and shaken well. The absorbance was read at 700 nm after 30 min. Tannic acid was used to prepare the standard curve. The color formed was determined at 500 nm using a Spectrophotometer. The results were expressed as mg of tannic acid equivalents (TAE)/g dry weight.
2.3.3. Determination of flavonoids content
Flavonoids were determined according to the method of Zhishen et al., (1999). Olive leaf extract (0.4 mL) was added to 4 mL H2O. Then 0.3 mL 5% NaNO2 were added. After 5 min, 0.3 mL 10% AlCl3 were added. After six min, 2 mL NaOH (1 M) were added and the total volume was made up to 10 mL with distilled water. The pink color was measured at 510 nm against a blank reagent using Spectrophotometer. Rutin was used to prepare the standard curve. Flavonoid content was calculated as mg/100 g on a dry weight basis. The results were expressed as mg of rutin equivalents (RuE)/g dry weight.
2.4. Total antioxidant activity2.4.1. DPPH free radical scavenging assay
The antioxidant activity of olive leaf extract was determined according to the method reported by Brand-Williams et al., (1995). Briefly, 2.4 mg of DPPH were dissolved in 100 mL methanol and 3.9 mL of this solution were added to 0.1 mL of olive leaf extract. The final concentration was 1.78 mg/mL and four dilutions were made; 1.424, 1.068 and 0.712 mg/mL. The mixture was shaken vigorously and allowed to stand in the dark for 30 min at room temperature. Then the absorbance was measured at 515 nm using a T80 PG UV/VIS Spectrophotometer. Methanol was used as a blank to zero the spectrophotometer and DPPH• was the control. DPPH• free radical scavenging activity was expressed as the inhibition percentage and was calculated from the equation:
DPPH radical scavenging activity(%)=Absorbance of control–Absorbance of sampleAbsorbance of sample×100
Biochemical analysis. Blood samples were collected from orbital vinus under anesthesia as follows: 3 mL in EDTA-coated tubes and 2 mL in plain tubes, centrifuged at 3000 rpm for 10 min at 4 °C to get plasma for CAT and serum for MDA and RBCs for GPX, SOD, and GSH analysis, respectively. The rats were sacrificed by cervical dislocation at the end of the study period.
2.4.2. Determination of MDA (Malondialdehyde) activity
The estimation of lipid peroxide is a colorimetric reaction with TBA (thiobarbituric acid) and was carried out as illustrated by Uchiyama and Mihara (1978), the measured lipid peroxide is calculated as malondialdehyde.
2.4.3. Determination of GSH activity
Reduced glutathione was estimated according to the method of Beutler et al., (1963).
2.4.4. Determination of SOD activity
Superoxide dismutase (SOD) was determined using the method of Nishikimi et al., (1972) as follows: the reaction mixture consists of 1.0 mL buffer (pH 8.5), 0.1 mL nitroblue tetrazolium (NBT) and 0.1 mL NADH, mixed with 0.05 mL sample. The reaction was started by adding 0.01 mL phenazine methosulphate (PMS); then the increase in absorbance was read at wavelength 560 nm for five minutes.
2.4.5. Determination of CAT activity
Catalase activity (CAT) was determined using the method of Aebi (1983). The reaction mixture contained 0.05 mL sample, and 0.50 mLbuffer (pH 7.0). The reaction was initiated by adding H2O2, then the resulting color was read at wavelength 510 nm.
2.4.6. Determination of GPX activity
Briefly, 0.5 mL of supernatant, 0.2 mL of Tris buffer, 0.1 mL of sodium azide and 0.2 mL of ethylene diamine tetra acetic acid were mixed together. Then 0.2 mL of glutathione followed by 0.1 mL of H2O2 were added to the mixture. The tubes were shaken well and incubated at 37 °C for 10 min beside a blank tube which contained all the reagents except the sample. The reaction was stopped after 10 min by adding 0.5 mL of 10% TCA. The tubes were centrifuged and the supernatant was used for the determination of glutathione.
2.5. Statistical analysis
Values are presented as means ± SEM. Statistical analysis was carried out using the “costat” statistic computer program. Statistical analysis was based on One-way analysis of variance ANOVA followed by student-Newman Keuls test, and least significant difference (LSD) at P < 0.05. A Pearson product-moment correlation coefficient was used to describe the relationships between enzymatic and non-enzymatic antioxidants.
3. RESULTS AND DISCUSSION3.1. Phytochemical compound contents
Table 1 shows that the content of tannins in olive leaf extract was 21.59 ± 1.25 mg TAE /g dry weight, while the phenolic content was 144.97 ± 2.12 mg GAE /g dry weight and flavonoid content was 143.01 ± 2.52 mg Ru/g dry weight. These results are consistent with the findings of Al-Marazeeq et al., (2016), who found that the total quantity of polyphenols in the water extract of olive leaves was 158 mg GAE/g extract. However, the tannin content in our extract was much higher than reported by Al-Marazeeq et al., (2016), who found that the tannin content was 8 mg GAE/g extract. The huge variance in tannins could be attributed to the cultivar difference. This explanation was supported by Brahmi et al., (2013) who found significant differences in tannins among two cultivars of olives, representing 8.10 mg/g dry weight in cv. Chemlali and 20.47 mg/g dry weight in cv. neb jmel.
Phytochemical contents in olive leaves extract
Phytochemicals
Olive leaves extract
Tannins (mg TAE/g dwt)
21.59 ± 1.25
Phenolics (mg GAE/g dwt)
144.97 ± 2.12
Flavonoids (mg RuE/g dwt)
143.01 ± 2.52
Values are represented as mean ± SEM of triplicate determinations.
At the same time, Sifaoui et al., (2014) found that phenolic compounds in different varieties of O.europaea leaves ranged from 46.809 mg GAE/g to 153.917 mg GAE/g of dry extract. The results found that flavenoid contents varied among species, in the range of 42.754 to 18.397 mg RuE/g of dry extracts (Sifaoui et al., 2014). These findings are similar to those that reported by Stanković et al., (2017), who published that flavonoid content in the olive leaves from different cultivars varied between 52.40 and 129.39 mg of RuE/g dry weight. Stanković et al., (2017) found that the phenolic content of O. europaea L. leaves from different cultivars was in the range of 127.18–314.69 mg of GAE/g and they concluded that the differences in polyphenolic contents between olive leaf varieties could be due to varietal and ecological influences.
3.2. DPPH free radical scavenging activity of olive leaf extract
The antioxidant activity of olive leaf extract was measured using the DPPH method with four concentrations 0.712, 1.068, 1.424 and 1.78 mg/mL (Table 2). The results revealed that the antioxidant activity of olive leaf extract was significantly time and concentration dependent. While our olive leaf extract’s antioxidant activity was 62.54% for 0.712 mg/mL, Abaza et al., (2011) found that the antioxidant activity of the 0.5 mg/mL water olive leaf extract was 20.83%.
Antioxidant activity of olive leaves extract against DPPH free radical.
Concentration (mg/mL)
Antioxidant activity (%)
15 min
30 min
0.712
57.46 ± 0.025dB
62.54 ± 0.026dA
1.068
61.59 ± 0.076cB
66.14 ± 0.234cA
1.424
65.98 ± 0.025bB
70.64 ± 0.130bA
1.78
66.81 ± 0.051aB
71.54 ± 0.026aA
LSD 0.05
0.16
0.44
Values are represented as mean ± SEM of triplicate determinations. The mean values with a different small letter within a column indicate significant differences (p < 0.05). The mean values with a different capital letter within a row indicate significant differences (p < 0.05).
The antioxidant effect of extracts on DPPH free radical scavenging may be due to their hydrogen-donating capability, which decreases the stable olive leaf extract DPPH radical to the yellow DPPH-H. Antioxidants can capture the free radical chain of oxidation and form stable free radicals, avoiding further oxidation propagation (Xie et al., 2015). The phenolic compound content was highly correlated with DPPH antioxidant values, but moderate to weak correlation was found between the flavonoid content value and radical scavenging activity (Sifaoui et al., 2014). The reason for the antioxidant effect of olive leaf extract is the hydrolysis of oleuropein to hydroxytyrosol with the parallel increase in the antioxidant capacity of the extract and the synergistic effect of phenolic compounds in the olive leaf extract (Zafer and Filiz 2010).
Olive leaf extract showed marked antioxidant properties in the in vitro systems and exhibited a good bioavailability with 40% of the polyphenols being absorbed by the organism. These antioxidant properties were attributed to the phenolic metabolites that can preserve a strong antioxidant activity and show a significant antioxidant action in vivo (Martin-Vertedor et al., 2016). Moreover, Hayes et al., (2011) proved that OLE is able to scavenge free radicals at physiological pH, therefore preventing the initiation and propagation of free-radical-mediated chain reactions which contribute to oxidative stress.
Martin-Vertedor et al., (2016) revealed that the most abundant compound in the olive leaf extract was oleuropein. In fact, oleuropein represented more than 50% of the total recognized compounds in olive leaves,followed by hydroxytyrosol, then many other phenolics (Charoenprasert and Mitchell, 2012). Oleuropein inhibitted the activities of free radicals and inhibitted oxidative stress in diabetic-induced rats (Qadir et al., 2016). The potent antioxidant activity of olive leaf extract could be attributed to its high total polyphenolic compound content, and oleuropein (Salah et al., 2012).
3.3. Changes in MDA and GSH of normal and diabetic rats
The results in Table 3 revealed a significant increase in the MDA serum level of diabetic rats as compared to normal control rats (23.70 ± 1.66 nmol/mL). Diabetic rats received olive leaf extract decreased MDA formation in serum to the level of 15.07 nmol/mL and this decrease was significant when compared to the normal control group (13.41 nmol/mL). Table (3) shows the effect of olive leaf extract on GSH concentration in diabetic rats. The induction of diabetes resulted in a depletion of glutathione as shown in the diabetic control group (8.22 mg/dL) compared to normal control (13.55 mg/dL). However, the treatment of rats with olive leaf extract improved the GSH in diabetic rats treated with olive leaf extract (14.33 mg/dL).
MDA in Serum and GSH in RBC lysate from normal, diabetic and treated groups.
Groups
MDA (nmol/mL)
GSH (mg/dL)
Zero time
10 wees
Zero time
10 weeks
Normal Control
12.93 ± 1.18aA
13.41 ± 0.73bA
13.55 ± 0.97aA
13.55 ± 0.59bA
Diabetic Control
12.43 ± 1.14aB
23.70 ± 1.66aA
13.78 ± 0.80aA
8.22 ± 0.89cB
Normal rats treated with OLE
13.41 ± 0.73aA
12.10 ± 0.85bA
14.33 ± 1.00aB
18.66 ± 1.15aA
Diabetic rats treated with OLE
12.10 ± 0.85aA
15.07 ± 0.25bA
13.00 ± 0.33aA
14.33 ± 0.58bA
LSD 0.05
4.55
3.29
3.49
2.73
Values are mean ± SEM. Each group contains 6 rats. The mean values with a different small letter within a column indicate significant differences (p < 0.05). The mean values with a different capital letter within a row indicate significant differences (p < 0.05).
A negative correlation was noticed between GSH and hyperglycemia, which means that rising serum glucose reduced the antioxidant capacity (Qadir et al., 2016). There is an inverse correlation which has been revealed among glucose level and enzymatic and non-enzymatic antioxidants (Qadir et al., 2016). The consumption oleuropein-rich olive leaf extract reduced plasma MDA levels in subjects, which was associated with higher plasma levels of metabolites derived from oleuropein (Garcia-Villalba et al., 2014).
3.4. Changes in SOD, CAT, and GPX of normal and diabetic rats
Superoxide dismutase showed the lowest value (27.7 U/mL) in the diabetic control group (Table 4). Olive leaf extract improved SOD levels in the treated diabetic group (31.40 U/mL) to be near the value of the normal control (35.9 U/mL) and normal rats which were treated with olive leaf extract (36.40 U/mL) (Table 4).
Effect of aqueous extract of olive leaves on SOD in RBC lysate, CAT in plasma and GPX in RBC lysate levels from STZ-induced diabetic rats.
Groups
SOD (U/mL)
CAT (U/mL)
GPX (U/mL)
Zero time
10 weeks
Zero time
10 weeks
Zero time
10 weeks
Normal Control
36.2 ± 0.2aA
35.9 ± 0.5aA
8.04 ± 0.33aA
8.20 ± 0.85aA
1426.58 ± 74.88aA
1469.81 ± 86.46aA
Diabetic Control
35.4 ± 0.2aA
27.7 ± 2.7bB
7.49 ± 0.51aA
4.07 ± 0.36bB
1556.27 ± 149.75aA
907.82 ± 74.88cB
Normal rats treated with OLE
36.2 ± 0.4aA
36.4 ± 0.1aA
7.94 ± 0.44aA
7.62 ± 0.41aA
1491.43 ± 64.84aA
1642.73 ± 86.00aA
Diabetic rats treated with OLE
35.2 ± 0.1aA
31.4 ± 1.9abA
7.46 ± 0.48aA
8.41 ± 0.05aA
1426.58 ± 129.69aA
1253.66 ± 114.38bA
LSD 0.05
0.97
5.47
1.68
1.64
464.85
299.06
Values are mean ± SEM. Each group contains 6 rats. The mean values with a different small letter within a column indicate significant differences (p < 0.05). The mean values with a different capital letter within a row indicate significant differences (p < 0.05).
In vivo effects of olive leaf extract on catalase levels in the plasma of rats were estimated. It was observed that the olive leaf extract exhibited a high level of catalase (8.41 U/mL) in the treated diabetic group compared to diabetic group and gave a value of 4.07 U/mL. The normal treated group was also low with the value 7.62 U/mL, but this decrease did not reach the statistically significant difference when correlated to the normal control 8.20 U/mL. The results presented in Table (4) indicate that diabetes induction affects the GPX level. As expected from the GSH results, the GPX level falls dramatically in the diabetic group (907.82 U/mL) when compared to normal control group (1469.81 U/mL). The olive leaf extract retrieved the GPX value in the treated diabetic group with a value of 1253.66 U/mL. Exactly like the GSH results’ trend, the normal rats that received olive leaf extract showed the highest GPX value (1642.73 U/mL), significantly. The current findings are consistent with those reported by Park et al., (2013) who showed that the concentrations of SOD were lower in the diabetic group than in the control group. Though the SOD level in their olive leaf extract-treated diabetic group tended to rise compared with the diabetic group. Also, the plasma CAT level was higher in the olive leaf-supplemented group than in the diabetic group. In addition, GPX activity was lower in the diabetic group than in the normal control group; however, GPX activity in the olive leaf-supplemented group was significantly higher than that in the diabetic group (Park et al., 2013). The administration of olive leaf extract led to a reduction in the severe alterations of GSH and MDA in diabetic rats. These findings clearly showed that olive leaf extract plays a defensive role against oxidative stress damage in diabetic rats. In the Park et al., (2013) study, treatment with olive leaves relieved oxidative stress through the elevation of plasma antioxidant enzymes; SOD and CAT levels were significantly lower in the diabetic control group and greater in animals from the olive leaf supplemented group.
The GPX level also tracked a similar trend to that of SOD and CAT levels which increased in the diabetic olive leaf treated group. These results suggest that olive leaf extract prompted a protecting effect by inducing the scavenging of ROS, thus decreasing diabetes-related complications. The antioxidant effect of olive leaf extract could be clarified on the basis that olive leaf extract induced the protein synthesis of antioxidant enzymes (Salah et al., 2017).
Olive leaf extract has been ascribed with antioxidant, antihypertensive, hypoglycemic, hypocholesterolemic, anti-inflammatory, antiatherogenic, chemopreventive, anti-cancer properties and also against metabolic disorders (Bulotta et al., 2014). The present results showthat endogenous antioxidants such as CAT, SOD, and GPX decreased while, MDA levels increased, which revealed that oxidative stress was reinforced in STZ-diabetic rats.
3.5. Pearson correlation between antioxidant parameters
A Pearson product-moment correlation coefficient was computed to evaluate the relationship between different enzymatic and non-enzymatic antioxidant parameters. The results suggest that all the correlations were statistically significant.
The statistical analysis indicated that a strong negative correlation was found between both MDA and SOD (r2 = 0.62, p ≤ 0.05), and between MDA and GPX (r2 = 0.68, p ≤ 0.05) (Fig 1 A and B). In addition, a strong negative correlation was found between MDA and CAT (r2 = 0.58, p ≤ 0.05) and between MDA and GSH (r2 = 0.57, p ≤ 0.05) (Fig 1C and D). Park et al., (2013) also found a negative correlation between GSH and MDA. El-Beltagi et al., (2016) assumed that the depletion of GSH might be partly responsible for the elevated lipid peroxidation. On the other hand, a strong positive correlation was found between SOD and GPX (r2 = 0.53, p ≤ 0.05) (Fig 2 A). Park et al., (2013) verified a positive correlation among SOD and GPX. However, a weak positive correlation takes place between SOD and CAT (r2 = 0.31, p ≤ 0.05) (Fig 2 B).
Correlation between: A. MDA (nmol/mL) and SOD (U/mL), B. MDA (nmol/mL) and GPX (U/mL), C. MDA (nmol/mL) and CAT (U/mL), D. MDA (nmol/mL) and GSH (mg/dL).
Correlation between: A. SOD (U/mL) and GPX (U/mL), B. SOD (U/mL) and CAT (U/mL).
The present results demonstrated that olive leaf extract may have a direct promising application in the pharmaceutical field, due to the existence of bioactive compounds. Oleuropein and hydroxytyrosol, which are main polyphenolic constituents of olive leaves, restored the antioxidant distresses in diabetic rats. In the current study, it is difficult to make an overall assumption about structure-antioxidant activity relationships with the small number of antioxidant molecules under assessment. So, further research should be carried out to investigate the bioactive compounds in olive leaf extract which are responsible for its biological effects.
4. CONCLUSIONS
It could be concluded that Olive leaf extract had high antioxidant activity, and this activity was time-concentration dependent. Olive leaf extract showed a healing effect on the diabetic state by controlling oxidative stress in diabetic rats. Therefore, using olive leaf extract as a pharmaceutical product could be useful for diabetic individuals.
ACKNOWLEDGMENTS
The authors would like to show their appreciation to the Faculty of Agriculture, Cairo University, Department of Biochemistry, for continuing cooperation to support research that provided the facilities necessary to accomplish the most wanted objectives of this research.
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