نوع المستند : مقالات علمیة محکمة
المؤلف
Nutrition and Food Sciences Department, Faculty of Home Economics Minufiya University, Shibin El-Kom, Egypt
المستخلص
الموضوعات الرئيسية
Introduction
Male sexual dysfunction composed of several problems associated with sperm concentration, motility and hormonal imbalance e.g., low testosterone level, which are caused by alcoholism, drug abuse, aging and cigarette smoking, antidepressant drugs and exposure of toxic chemicals (Khan, 2012 and Othman et al.,2014). Furthermore, testicular oxidative stress plays a role in a number of conditions known to be detrimental to male fertility (Turner and Lysiak, 2008) and exposure to pesticide is one of the factors known to produce testicular oxidative stress leading to an increase in damaged apoptotic germ cells (Samanta and Chainy, 1997). Pesticides are being used as an integral part of modern agriculture practices. However, use of these pesticides is not highly regulated in developing countries (Ranjan et al., 2014).Carbendazim is extensively used on controlling various fungal pathogens and also used as a preservative in paint, textile, papermaking, leather industry and warehousing practices, as well as a preservative of fruits (Selmanoglu et al., 2001).It causes deleterious effects on various aspects of male reproduction in hamsters, mice, rats and humans. The effects include the decreased total sperm count, motility, increased incidence of sperm abnormalities (Akbarsha et al., 2001).
Pomegranate (Punica granatum) has been used in the folk medicine of many cultures especially in the Middle East (Gurib-Fakim, 2006).Fresh juice is rich in vitamin C, and polyphenolic compounds such as anthocyanins, punicalagin, ellagic and gallic acid (Seeram et al., 2005) which can directly or indirectly reduce oxidative damage by preventing the excessive generation of free radicals (Al-Olayan et al., 2014). Pomegranate juice consumption increases significantly sperm quality, spermatogenic cell density, antioxidant activity and testosterone level in male rats (Turk et al., 2008). Therefore, this study aims to investigate the protective role of pomegranate juice on changes induced by carbendazim in sperm characteristics in rats.
Material and Methods:
Materials
Carbendazim (purity > 98.0%) was provided by Weihai Pesticide Factory (Shandong, China). Kits were purchased from (Alkan Medical Company, St. El Doky, Cairo, Egypt). All other chemicals and reagents were obtained from El-Gomhoreya Company, Cairo, Egypt.
Pomegranate fruit (Punica granatum) was purchased from Shiben El-Kom, Minufiya, Egypt.
Preparation of pomegranate juice:
The fresh pomegranate was washed with tab water and squeezed without adding water in a Braun blender (Type 4979 made in Hungary) at a maximum speed for 15 minute. The juice was filtrated through cheesecloth. The pure filtrated juice was stored at -20 ºC until used.
Animals:
Thirty fife adult male Sprague–Dawley rats weighing (170±5 g), at the beginning of the experiment, were obtained from Medical Insects Research Institute, Doki, Cairo, Egypt. Rats were housed individually in wire cages under the normal laboratory conditions. Rats were fed on standard diet for one week as an adaptation period. Diet was introduced to rats in special food cups to avoid scattering of food. Also, water was provided to rats by glass tubes projecting through the wire cages from an inverted bottle supported to one side of the cage. Food and fresh water were provided checked daily. Standard diet was prepared from fine ingredients according to AIN-93 guidelines (Reeves et al., 1993). All animals were received care in compliance with the Egyptian rules for animal protection.
Experimental groups:
Rats were randomly divided into two main groups, the first group, negative control group (n=7) fed standard diet. The second group ,Carbendazimgroups (n=28) were exposed to carbendazim dissolved in corn oil by oral gavage at dosage of 150 mg/kg daily for 60 consecutive days to cover the spermatogenic cycle according to Hershberger, et al. (1969). The negative control rats were administered to the equal volume redistilled water and corn oil. Carbendazimgroups were divided into four subgroups (7 rats each) as follow: subgroup 1 served as positive control group, subgroup 2,3 and 4 received basal diet and given fresh pomegranate juice orally by gavages 5, 10 and15 μl/g of body weight respectively once a day for 60 days, as described by Park et al., (2003). After 60 days, the animals were euthanized by decapitation. The testes, seminal vessel and prostate were promptly excised, weighed. The right testis from each animal was removed and was stored at −80◦ C for further analysis. testicular homogenate was prepared in ice cold 0.1 M potassium phosphate buffer (pH 7.4). The homogenate was centrifuged at 4000 rpm for 15 min to harvest supernatant. Supernatant was used for estimation the various biochemical determinations. Serum was removed by centrifugation of the blood (5 minutes at 3000 rpm). Serum was transferred into clean cuvette tube and stored at -20°C until analysis.
Methods
Chemical composition and determine of bioactive compounds:
Protein, fat, moisture, ash and ascorbic acid contents were determined in pomegranate juice according to AOAC, (2012). The carbohydrate was calculated by difference. The determination of total phenols was carried out by using Folin-Ciocalteuas described by Chun et al., (2003). Total phenolic compounds were expressed as mg gallic acid equivalents / 100 g dry weight sample. Total flavonoids were determined using a method described by Franke et al., (2004).Total flavonoids were expressed as mg catechin / 100 g dry weight sample. Anthocyanin was determined as described by Lako et al., (2007).
Enzymatic antioxidant status, oxidative stress and testosterone hormone
Homogenate of testes were used in determination of Catalase, glutathione transferase (GTH) and malonaldehyde (MDA) according to the methods described by Aebi, (1983), Habig et al., (1973) and Ohkawaet al., (1979)respectively. Testosterone hormone was assayed in serum using kit according to manufacturer's protocol.
Sperm count, motility, sperm viability and sperm abnormalities
In brief, seminal fluid was diluted with 0.2% of eosin solution and was observed under the microscope for sperm count and motility described by Ngoula, et al., (2007). Sperm viability and sperm abnormalities were carried out by mixing the drop of seminal fluid with the drop of eosin and nigrosin stain and observed under the microscope according to Bearden and Fuquay, (1997).
Histopathology examination
The left testes were collected and immediately fixed with10% buffered formalin, dehydrated in ascending concentration of ethanol (70, 80 and 90%), cleared in zylene and embedded in paraffin. Sections (4–5μm) were prepared and then stained with hematoxylin and eosin dye according to Bancroft and Stevens, (1996).
Statistical analysis:
Results were expressed as the mean ± SD. Data for multiple variable comparisons were analyzed by one-way analysis of variance (ANOVA). For the comparison of significance between groups, Duncan’s test was used as a post hoc test according to the statistical package program (SPSS version 17.0).
Results and discussion
Vitamin C, total flavonoids, anthocyanins and total phenols contents of fresh pomegranate juice were presented in Fig (1). Fresh pomegranate juice had 85, 136.5, 184.83 and1328.57 mg/L for vitamin C, total flavonoids, anthocyanins and total phenols respectively. These results are in the same trend of Hassan et al., (2012) who showed that vitamin C and anthocyanins content ranged between 27.7-94.8 and 45-1480 mg/L respectively. Also total phenolic compounds of pomegranate juice were in the range values (1245 to 2076 mg/L) reported by özgen et al., (2008). On the other side total flavonoids of pomegranate juice were much higher than the value (5.25 mg rutin/100 ml) reported by Elfalleh et al., (2012).
Data in Table (2) showed the effect of pomegranate juice on antioxidant enzymes and oxidative stress parameter of testicular tissues in rats. The repeated administration of carbendazim (CBZ) resulted in increase in lipid peroxidation (MDA) and decrease glutathione transferase (GST) and catalase activities in testicular tissue in CBZ control compared with negative control. Increase of lipid peroxidation could be due to carbendazim-induced formation of free radicals. These findings are supported by Rajeswary et al. (2007) and Metwally et al. (2011) who reported that exposure rats to CBZ resulted in a significant increase in testicular tissue level of MDA whereas glutathione peroxidase and catalase enzymes activities were significantly decreased. Moreover carbendazim induces testicular oxidative stress leading to generation of free radicals and alterations in the antioxidants or oxygen free radical scavenging enzymes such as catalase and glutathione transferase (Rajeswary et al., 2007). After administration of rats with CBZ + 10 and 15µL/g BW of pomegranate juice (PJ) for 60 days, the levels of GST and catalase activities were increased and MDA decreased in testicular tissue as compared to CBZ control rats. However the levels of GST and catalase in the CBZ + 5µL/g BW of PJ group did not differ from CBZ control group. Our results show that the protective effect of pomegranate juice may be due to both an increase in the activity of the antioxidant-defense system and an inhibition of lipid peroxidation production. This results confirmed the results of Afaq et al., (2005) who reported thatpomegranate is an important source of anthocyanins and phenolic compounds which are known for their properties in scavenging free radicals and inhibiting lipid oxidation in vitro (Li et al., 2006). In the same table the results indicated that in CBZ + 15µL/g BW of PJ, GST, catalase activities and MDA were restored to negative control values. These results are agreement with Turk rt al., (2008) who demonstrated that increases observed in sperm CAT and GSH activities of high dose PJ(1 ml/day) group when compared to the control, the low (0.25 ml/day) and middle (0.5 ml/day) doses of PJ groups.
The effect of pomegranate juice on testosterone, sperm count, sperm motility, live sperm and sperm abnormality of rats are shown in Table (3). Plasma testosterone level was significant decrease (p ≤ 0.05) in CBZ groups as compared with negative control group. This decrease may be due to the increasing of lipid peroxidation(LPO), decrease GST and catalase activities as a result of expose to CBZ. These results confirmed the results of Santos et al., 2004) who reported that secretion of testosterone is probably impaired due to excessive oxidative stress and the degeneration of Leydig cells. Likewise Lu et al., (2006) showed that if antioxidant system cannot neutralized produce reactive oxygen species, the mitochondrial membrane will be stripped and led to inhibition of testosterone production. Co administration of carbendazium with pomegranate juice led to improve the level of testosterone as well as the testosterone level showed an increasing tendency with increasing dose PJ. This increase of testosterone level may be due to the ability of pomegranate to reduce oxidative stress caused by CBZ administration. The result of this study came in accordance with that reported by Al- Olayan et al., (2014) who observed that treatment of rats with pomegranate juice ameliorated the toxic effects of CCl4 and the levels of testosterone was increased. Also the results indicated that, after treatment of rats with CBZ for 60 days, the sperm count, sperm motility, live perm were decreased significantly (P ≤ 0.05) in carbendazim groups as compared to negative control group while, sperm abnormality had opposite trend. Our results corroborate the findings of Ranjan et al., (2014) who observed that significant decline in total sperm count, live sperm percentage and increased sperm abnormalities after 45 and 90 days of exposed rats to CBZ as compared to control. Metwally et al., (2011)found that significantly reduced in total sperm count and motility in rats after exposure to CBZ.Data in the same table showed no significant differences (P > 0.05) in sperm motility, live sperm and sperm abnormality were observed in CBZ control and CBZ +5 µL/g BW of PJ groups. On the other side supplementation rats with 10 and 15 µL/g BW of PJ had positive effect on sperm count, sperm motility, live perm and sperm abnormality. This positive effect may be related to phenolic compounds, vitamine C and anthocyanins present in pomegranate juice. The highest improvement in percent of sperm count, sperm motility, live sperm and sperm abnormality were found in CBZ group supplemented with 15 µL/g BW of PJ. These results indicated that there was partial restoration in testosterone, sperm count, live sperm percent and sperm abnormalities in the CBZ supplemented with 10 and 15 µL/g BW of PJ group as compared to CBZ control and CBZ+5µL/g BW of PJ groups. These results are agreement with Mansouret al., (2013) who noted that PJ consumption significantly increased epididymis sperm concentration and sperm motility parameters and decreased abnormal sperm production. Also Turk et al., (2008) demonstrated that consumption high dose of PJ for seven weeks caused increased spermatogenic cell density, epididymal sperm concentration, sperm motility and decreased abnormal sperm rate related with decreased lipid peroxidation in male rats as compared with control group. Benefits of pomegranate juice on sperm quality and male fertility of rats were reported by Sonmez et al., (2005).
Table (4) showed the effect of pomegranate juice on testes, seminal vessel and prostate weights of rats. There were significant decrease (p ≤ .05) in testes weight among CBZ control, CBZ + 5 µL/g BW of PJ groups and negative control and CBZ +10 and 15 µL/g BW of PJ groups. This observation is in consonance with Q Guo et al., (2009) who found thatthe testis weights was decreased after exposure to carbendazim at 100 and 200 mg/kg for 80 days, indicating that carbendazim had adverse effect on the development of rats testes. Moreover in general toxicity studies, it is well known that the changes in organ weights are sensitive indicators of the detection of potentially toxic chemicals (Bailey et al., 2004 and Kim et al., 2004).The values of testes, seminal vessel and prostate weights in CBZ control group were significantly (P≤ 0.05) lower than negative control group and CBZ groups supplemented with PJ with the exception of testes weight for CBZ group given 5 µL/g BW of PJ which was similar (P >0.05) to CBZ group. Supplementation rats with 10 and 15 µL/g BW of pomegranate juice did not significant differ (P > 0.05) in their effect on seminal vessel and prostate weights. Also no significant difference was found in testis and prostate weights between CBZ + 15 µL/g BW of PJ and negative control groups. The reduction of prostate weight can be explained by the loss of secretion from the prostate which caused by a drop in testosterone production (Salem et al.,2012).
Fig. (2) showed the testis histopathology of negative,positive and carbendazim rats administrated with different concentration of pomegranate juice. The control rats showed that no histopathological changes , normal spermatogenesis, well preserved Sertoli cells and well delineated tubular basement membrane were observed. However, CBZ control and CBZ + 5 µL/g BW of PJ groups showed degeneration and necrosis of spermatogoneal cells lining seminiferous tubules and interstitial oedema. Supplementation rats with 10 and 15 µL/g BW of pomegranate juice caused reduce the toxic effects of carbendazim and improve the testes tissue .These results agree with those reported by Gongchang et al., (2009) and Ibtihag et al., (2011).
Conclusion
The results obtained proved the pomegranate juice potentials to counteract all carbendazium - induced changes thus allowing recovery of the rats from oxidative stress and hence contributing in improving fertility. Farm workers may have highest persons for exposure to potential hazards of pesticides. Therefore, it is recommended to supplement pomegranate juice for these individuals for protecting them from side effects of pesticides on fertility.
Acknowledgments
I thank professor Abdel-Hamid Abdel-Mageed Nahas. Researcher in Mammalian Toxicology Department, Central Agricultural Pesticide Laboratory,for his cooperation and aid in determination of sperm count, motility, sperm viability and sperm abnormalities.
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Fig (1) : Vitamin C, T. flavonoids, anthocyanins and T. phenols contents of fresh pomegranate juice.
Table (2): Effect of pomegranate juice on antioxidant enzymes and oxidative stress parameters in in testicular tissues rats.
Parameters |
Negative control group |
Carbendazim groups |
|||
CBZ control |
CBZ ±PJ (5 μL/g of B.W) |
CBZ ±PJ (10 μL/g of B.W) |
CBZ ±PJ (15 μL/g of B.W) |
||
MDA (nmol/g tissue) |
10.03d ± 0.54 |
17.10a ± 1.02 |
14.63b ± 1.3 |
12.57c ± 1.03 |
10.23d ± 0.57 |
GST(µmol/g tissue) |
0.67 a ± 0.02 |
0.40 c ± 0.01 |
0.42 c ± 0.02 |
0.49 b ± 0.01 |
0.65 a ± 0.02 |
CAT (U/g tissue) |
5.63 a ± 0.13 |
2.89 c ± 0.11 |
2.99 c ± 0.10 |
4.30 b ± 0.01 |
5.60 a ± 0.21 |
Data are expressed as mean ± SD. Means in the same row with different letters are significantly different (p < 0.05).PJ : pomegranate juice, CBZ: carbendazim, MDA: malonaldehyde ,GST: Glutathione transferase., CAT:catalase
Table (3): Effect of pomegranate juice on serum testosterone, sperm count, sperm motility, live and abnormality of rats.
Parameters |
Negative control |
Carbendazim groups |
|||
CBZ control |
CBZ ±PJ (5 μL/g of B.W) |
CBZ ±PJ (10 μL/g of B.W) |
CBZ ±PJ (15 μL/g of B.W) |
||
T.T (ng/dl) |
5.04a ± 0.08 |
1.03e ± 0.05 |
1.71d ± 0.03 |
2.40c ± 0.09 |
3.42b ± 0.07 |
Sperm count (%) |
94.75a ± 1.7 |
40.50e ± 2.4 |
44.00d ± 0.82 |
47.25c ± 2.2 |
61.50b ± 1.9 |
Sperm motility(%) |
77.52a ± 2.4 |
37.75d ± 2.1 |
39.82d ± 0.97 |
43.63c ± 2.0 |
47.37b ± 3.3 |
Live (%) |
87.50a ± 1.7 |
54.50c ± 1.3 |
55.25c ± 1.7 |
84.00b ± 1.8 |
86.00a ± 0.82 |
Abnormality (%) |
10.88c ± 0.67 |
46.00a ± 4.5 |
45.50a ± 4.2 |
15.75b ± 0.96 |
13.50bc ± 1.3 |
Data are expressed as mean ± SD. Means in the same row with different letters are significantly different (p < 0.05).PJ : pomegranate juice, CBZ: carbendazim,T.T: testosterone .
Table (4): Effect of fresh pomegranate juice on testes, seminal vessel , and prostate weights of rats.
Parameters |
Negative control group |
Carbendazim groups |
|||
CBZ control |
CBZ ±PJ (5 μL/g of B.W) |
CBZ ±PJ (10 μL/g of B.W) |
CBZ ±PJ (15 μL/g of B.W) |
||
Testes weight (mg) |
2.25a ± 0.06 |
1.88 c ± 0.05 |
1.79 c ± 0.05 |
2.06 b ± 0.06 |
2.21 a ± 0.06 |
Seminal vessel(mg) |
0.31 a ± 0.01 |
0.22 d ± 0.01 |
0.25 c ± 0.02 |
0.26 bc ± 0.01 |
0.27 b ± 0.01 |
Prostate (mg) |
0.33 a ± 0.01 |
0.23 c ± 0.01 |
0.31 b ± 0.004 |
0.33 a ± 0.01 |
0.34 a ± 0.01 |
Data are expressed as mean ± SD. Means in the same row with different letters are significantly different (p < 0.05).PJ : pomegranate juice, CBZ: carbendazim
Negative control rats
CBZ control rats CBZ rats ±PJ (5 μL/g of B.W)
CBZ rats ±PJ (10 μL/g of B.W) CBZ rats ±PJ (15 μL/g of B.W)
CBZ: carbendazim , PJ : pomegranate juice
Fig (2): Testis histopathology of negative, positive and carbendazim rats administrated with different concentration of pomegranate juice