**4. Results and discussion**

*Animal Models in Medicine and Biology*

**2.6 Production of superoxide radicals**

**2.7 DNA fragmentation**

**2.8 Lipid peroxidation**

**3. Statistical analysis**

The mitochondrial toxicity test (MTT test) is a colorimetric test often used for the determination of cell metabolic activity. The main principle of the test is the application of yellow tetrazolium bromide (Sigma-Aldrich, St. Louis, USA) and its subsequent reaction with insoluble mitochondrial succinate dehydrogenase produced by cell mitochondria. This reaction ends with the formation of a blue-violet formazan [15]. The amount of formed formazan is directly proportional to the level of metabolic activity of the cells. We evaluated this test spectrophotometrically at

For the detection of the superoxide radical concentration, we used the nitroblue tetrazolium or NBT test. The principle of this method is the application of nitroblue tetrazolium (Sigma-Aldrich, St. Louis, USA) to the semen sample. This substance reacts with cellular superoxide to form derivates of formazan. Following washing with PBS and centrifugation (1250 rpm, 5 min), the concentration of formasan derivates was evaluated spectrophotometrically [16] at wavelengths of 620 against

This type of DNA damage is characterized by both single and double DNA strand breaks. Several types of DNA damage may be observed in mammalian germ cells and are often associated with male infertility. Nowadays various tests are available to detect sperm DNA damage. DNA fragmentation arises from various reasons such as deficiencies in recombination during spermatogenesis, abnormal sperm maturation, abortive apoptosis, or oxidative stress [17, 18]. In our research we used the chromatin-dispersion test by using the Halomax diagnostic kit (Halotech, Madrid, Spain). This kit can analyze the integrity of the DNA molecule and is based on a controlled DNA denaturation process to facilitate the subsequent removal of the proteins contained in each spermatozoon. The main principle of this method is that damaged spermatozoa create halos formed by loops of fragmented DNA at the head of the sperm which are not present in normal spermatozoa. For the evaluation we used a fluorescent microscope (Leica, Holzheim, Germany) and a magnification of 40×. At least 300 cells were evaluated for DNA fragmentation in each slide

Lipid peroxidation is a process of membrane lipid degeneration caused by free radicals [19]. The extent of lipid peroxidation in our samples was expressed as the amount of malondialdehyde (MDA) production following the addition of thiobarbituric acid (Sigma-Aldrich, St. Louis, USA) and exposure to heat (100°C, 1 h). The MDA concentration in the samples was evaluated spectrophotomerically at a wavelength of 540 nm (Multiscan reader, Thermo Fisher, Vantaa, Finland).

The data we obtained were statistically processed using GraphPad Prism (version 6.0 for Windows, GraphPad Software incorporated, San Diego, California,

570 against 620 nm (Multiscan reader, Thermo Fisher, Vantaa, Finland).

570 nm (Multiscan reader, Thermo Fisher, Vantaa, Finland).

containing agarose with processed spermatozoa.

**2.5 Test of metabolic activity**

**96**

When we compared the sperm motility of individual groups (**Figure 2**), we found statistically significant differences (P < 0.001) when comparing the experimental group ZDF with the control W group as well as with the ZDN experimental group. Similarly to our results, Ohta et al. [20] reported a reduction in the sperm motility in rats with obesity in comparison with the control group. They tried to demonstrate the potential link between obesity and a reduction of sperm motility, which ultimately affects the fertility of rats. Simas et al. [21] also reported a decrease of morphologically normal spermatozoa in rats with diabetes. The most common abnormalities found were sperm head deformations and flagella deformities. There is a very close connection between the sperm volume and percentage of motile spermatozoa. Both types of diabetes have a serious impact on the sperm quality, and a lot of studies examine the effect of diabetes on the male fertility. Condorelli et al. [22] showed different pathophysiological effects in type 1 and type 2 of diabetes on the sperm function and quality. The aim of their experiment was to compare DM1 and DM2 patients with healthy and fertile subjects. Male patients suffering from diabetes mellitus type 2 have several contraindications. Among these, the most prominent include low sperm volume, higher concentration of mitochondrial superoxide anions, an increased reactive oxygen species production in the seminal fluid, and lipoperoxidation. The study showed that DM2 caused an inflammatory condition and increased the level of oxidative stress which led to an increased sperm DNA fragmentation and a decreased vitality of spermatozoa. In our experiments we also observed several contraindications in the rats which suffered from diabetes mellitus type 2 including a decreased motility and vitality of sperm cells, a lower mitochondrial activity, followed by higher levels of superoxide production and lipid peroxidation. On the other hand, a combination of DM2 and obesity has more serious consequences to male fertility.

#### **Figure 2.**

*Differences in the sperm motility among the observed groups. W, Wistar rats, control group; ZDN, nonobese ZDF rats with diabetes mellitus type 2; ZDF, ZDF rats with obesity and diabetes mellitus type 2. \*\*\*(P < 0.001). W, compared to the Wistar group; ZDN, compared to the ZDN group.*

Numerous studies have shown the negative impact of obesity on the semen quality. Obesity causes a decrease of sperm concentration and motility and an increased DNA fragmentation index, and it is often associated with erectile dysfunction. Fernandez et al. [23] examined the impact of obesity on the fertility in male Wistar rats which were fed a high-fat diet and compared these with the control group consisting of nonobese rats. Similarly to our study, their results reported that obese animals have a low sperm quality caused by a decreased percentage of spermatozoa with progressive motility which may lead to the development of subfertility. We also recorded higher levels of non-motile spermatozoa in obese rats which were fed with a high-caloric diet.

The evaluation of the membrane integrity of spermatozoa (**Figure 3**) showed statistically significant differences (P < 0.001) among the groups. The sperm vitality of the ZDF experimental group was significantly lower than the control W group as well as with the ZDN experimental group. Sabeti et al. [24] also observed statistically significant differences (P < 0.05) in the viability between the experimental and control group of rats suffering from diabetes.

The membrane integrity is also affected by the level of cholesterol in the organism. Normal levels of cholesterol are highly important for the membrane fluidity and sperm motility. If there is an increase in the cholesterol levels because of the presence of obesity, then more cholesterol is incorporated into the lipid bilayer of the cells, leading to its adverse effects on the membrane integrity. These facts support the theory that changes in the levels of systemic cholesterol, triglyceride, and free fatty acids are associated with alterations of the cell membrane dynamics, sperm motility, morphology, and susceptibility to DNA damage [25].

As the graph shows, there were no statistically significant differences between any of the studied groups (**Figure 4**). In our opinion this condition could show that diabetes and obesity affect other semen parameters, but the integrity of the acrosome remains unchanged. It is important to know that diabetes mellitus type 2 in combination with obesity does not cause acrosome deformations. This theory was supported by Ding et al. [3] who studied differences between diabetes mellitus type 1 and type 2. In their study, they found that diabetes mellitus type 1 has a markedly impaired glycation process and synthesis of proteins, leading to the development of acrosome integrity disorders, while diabetes mellitus type 2 has less serious consequences to the acrosome. The acrosome integrity was the only parameter which remained stable. It could be caused by the presence of acid hydrolases

#### **Figure 3.**

*Differences in the membrane integrity or viability among the observed groups. W, Wistar rats, control group; ZDN, nonobese ZDF rats with diabetes mellitus type 2; ZDF, ZDF rats with obesity and diabetes mellitus type 2. \*\*\*(P < 0.001). W, compared to the Wistar group; ZDN, compared to the ZDN group.*

**99**

**Figure 5.**

*ZDF Rats: A Suitable Model to Study Male Reproductive Dysfunction in Diabetes Mellitus…*

and lysosomal proteins because the acrosome does not need carbohydrates for its function. The presence of polyunsaturated fatty acids in the plasma membrane could exhibit protective effects against the negative activity of ROS and prevent alterations to the acrosome. This theory was also supported by Reddy et al. [26] who

*Acrosome integrity among the observed groups. W, Wistar rats, control group; ZDN, nonobese ZDF rats with diabetes mellitus type 2; ZDF, ZDF rats with obesity and diabetes mellitus type 2. W, compared to the Wistar* 

The evaluation of the MTT test (**Figure 5**) showed statistically significant differences (P < 0.5) between the experimental group ZDF and the experimental group ZDN as well as between the experimental group ZDN and the control group W. Another statistically significant difference (P < 0.01) was observed between the ZDN group and the W group. Our results show that the lowest values of mitochondrial activity were observed in the experimental ZDF group. Mitochondrial activity is closely related to the motility as mitochondria are the energy-metabolic center of the cell. We also observed the lowest sperm motility values in ZDF group of rats (**Figure 1**). In the analysis of diabetic rats, Simas et al. [21] reported a significant decrease in the metabolic activity of these rats compared to the control group. Experimental animals had an induced DM1. In all group of rats with diabetes, they observed an increase of inactive mitochondria which caused a

*Mitochondrial activity among the observed groups. W, Wistar rats, control group; ZDN, nonobese ZDF rats with diabetes mellitus type 2; ZDF, ZDF rats with obesity and diabetes mellitus type 2. \*\*(P < 0.01); \*(P < 0.5).* 

*W, compared to the Wistar group; ZDN, compared to the ZDN group.*

tested diabetic-induced reproductive toxicity in male Wistar rats.

*DOI: http://dx.doi.org/10.5772/intechopen.89939*

**Figure 4.**

*group; ZDN, compared to the ZDN group.*

*ZDF Rats: A Suitable Model to Study Male Reproductive Dysfunction in Diabetes Mellitus… DOI: http://dx.doi.org/10.5772/intechopen.89939*

**Figure 4.**

*Animal Models in Medicine and Biology*

with a high-caloric diet.

and control group of rats suffering from diabetes.

Numerous studies have shown the negative impact of obesity on the semen quality. Obesity causes a decrease of sperm concentration and motility and an increased DNA fragmentation index, and it is often associated with erectile dysfunction. Fernandez et al. [23] examined the impact of obesity on the fertility in male Wistar rats which were fed a high-fat diet and compared these with the control group consisting of nonobese rats. Similarly to our study, their results reported that obese animals have a low sperm quality caused by a decreased percentage of spermatozoa with progressive motility which may lead to the development of subfertility. We also recorded higher levels of non-motile spermatozoa in obese rats which were fed

The evaluation of the membrane integrity of spermatozoa (**Figure 3**) showed statistically significant differences (P < 0.001) among the groups. The sperm vitality of the ZDF experimental group was significantly lower than the control W group as well as with the ZDN experimental group. Sabeti et al. [24] also observed statistically significant differences (P < 0.05) in the viability between the experimental

The membrane integrity is also affected by the level of cholesterol in the organism. Normal levels of cholesterol are highly important for the membrane fluidity and sperm motility. If there is an increase in the cholesterol levels because of the presence of obesity, then more cholesterol is incorporated into the lipid bilayer of the cells, leading to its adverse effects on the membrane integrity. These facts support the theory that changes in the levels of systemic cholesterol, triglyceride, and free fatty acids are associated with alterations of the cell membrane dynamics,

As the graph shows, there were no statistically significant differences between any of the studied groups (**Figure 4**). In our opinion this condition could show that diabetes and obesity affect other semen parameters, but the integrity of the acrosome remains unchanged. It is important to know that diabetes mellitus type 2 in combination with obesity does not cause acrosome deformations. This theory was supported by Ding et al. [3] who studied differences between diabetes mellitus type 1 and type 2. In their study, they found that diabetes mellitus type 1 has a markedly impaired glycation process and synthesis of proteins, leading to the development of acrosome integrity disorders, while diabetes mellitus type 2 has less serious consequences to the acrosome. The acrosome integrity was the only parameter which remained stable. It could be caused by the presence of acid hydrolases

*Differences in the membrane integrity or viability among the observed groups. W, Wistar rats, control group; ZDN, nonobese ZDF rats with diabetes mellitus type 2; ZDF, ZDF rats with obesity and diabetes mellitus type* 

*2. \*\*\*(P < 0.001). W, compared to the Wistar group; ZDN, compared to the ZDN group.*

sperm motility, morphology, and susceptibility to DNA damage [25].

**98**

**Figure 3.**

*Acrosome integrity among the observed groups. W, Wistar rats, control group; ZDN, nonobese ZDF rats with diabetes mellitus type 2; ZDF, ZDF rats with obesity and diabetes mellitus type 2. W, compared to the Wistar group; ZDN, compared to the ZDN group.*

and lysosomal proteins because the acrosome does not need carbohydrates for its function. The presence of polyunsaturated fatty acids in the plasma membrane could exhibit protective effects against the negative activity of ROS and prevent alterations to the acrosome. This theory was also supported by Reddy et al. [26] who tested diabetic-induced reproductive toxicity in male Wistar rats.

The evaluation of the MTT test (**Figure 5**) showed statistically significant differences (P < 0.5) between the experimental group ZDF and the experimental group ZDN as well as between the experimental group ZDN and the control group W. Another statistically significant difference (P < 0.01) was observed between the ZDN group and the W group. Our results show that the lowest values of mitochondrial activity were observed in the experimental ZDF group. Mitochondrial activity is closely related to the motility as mitochondria are the energy-metabolic center of the cell. We also observed the lowest sperm motility values in ZDF group of rats (**Figure 1**). In the analysis of diabetic rats, Simas et al. [21] reported a significant decrease in the metabolic activity of these rats compared to the control group. Experimental animals had an induced DM1. In all group of rats with diabetes, they observed an increase of inactive mitochondria which caused a

**Figure 5.**

*Mitochondrial activity among the observed groups. W, Wistar rats, control group; ZDN, nonobese ZDF rats with diabetes mellitus type 2; ZDF, ZDF rats with obesity and diabetes mellitus type 2. \*\*(P < 0.01); \*(P < 0.5). W, compared to the Wistar group; ZDN, compared to the ZDN group.*

decrease of mitochondrial activity. Like Simas et al., we also observed low levels of mitochondrial activity in the ZDF group when compared to other groups. A decrease of mitochondrial activity was also observed in the experimental ZDN group. This phenomenon could be because diabetes mellitus had a negative impact on the metabolism of carbohydrates, which are the source of energy for a proper mitochondrial function.

Results of the superoxide radical production (NBT test) (**Figure 6**) showed statistically significant differences (P < 0.05; P < 0.01) when we compared both experimental groups with the control group W. In the experimental ZDF group, we recorded the highest superoxide radical production. This finding suggests that the group of ZDF rats is more at risk for the onset of oxidative stress, which negatively affects the viability of spermatozoa produced by these rats. Sabeti et al. [24] demonstrated that the abnormal production and presence of the superoxide radicals in combination with obesity leads to a reduced semen quality and sperm viability. Overproduction of superoxide may also be due to an increase in metabolic functions in order to maintain the homeostasis in obese individuals. Amaral et al. [27] reported no significant differences in the testicular cell concentration between diabetic and nondiabetic rats, but there was a massive decline in the sperm cell concentration due to the influence of hyperglycemia in late stages of spermatogenesis and increased production of reactive oxygen species (ROS) that may lead to the development of oxidative stress. The consequences of oxidative damage include the loss of motility due to lipid peroxidation, induction of DNA damage of the sperm nucleus, and defects in spermatogenesis affecting the final fertilizing potential of sperm cells.

The oxidative environment in testicular tissue of patients with DM2 may result in cellular damage, including lipid peroxidation, formation of carbonyl groups, and DNA damage which causes sperm abnormalities. In fact, this negative condition contributes to a reduction in the sperm motility and viability followed by an increased percentage of abnormalities in the sperm cells of rats [28].

**Figure 7** points out the levels of DNA fragmentation between the experimental groups and the control. After evaluation of our results, we found statistically significant differences between the DNA fragmentation following the presence of diabetes mellitus type 2 and obesity. Statistically significant differences (P < 0.001) were observed when we compared the experimental ZDF group with the ZDN group and the control W group and also when we compared the experimental ZDN group with the control W group. As seen from our results, a continuous increase in

#### **Figure 6.**

*Production of superoxide among the observed groups. W, Wistar rats, control group; ZDN, nonobese ZDF rats with diabetes mellitus type 2; ZDF, ZDF rats with obesity and diabetes mellitus type 2. \*\*(P < 0.01); \*(P < 0.5). W, compared to the Wistar group; ZDN, compared to the ZDN group.*

**101**

**Figure 8.**

*ZDF Rats: A Suitable Model to Study Male Reproductive Dysfunction in Diabetes Mellitus…*

DNA fragmentation was present, depending on the presence of diabetes mellitus type 2, obesity, or both. Abbasihormozi et al. [29] found the link between leptin receptor mutation and higher levels of DNA fragmentation as a consequence of a higher production of reactive oxygen species. Leptin is an adipose tissue-derived hormone which has an important role in the metabolism and energy homeostasis and ensures a proper function of the neuroendocrine and reproductive system. A direct administration of leptin could affect male infertility by ROS overproduction or hormone profile modulation, but the exact mechanism of the effect of leptin on

*Levels of DNA fragmentation among the observed groups. W, Wistar rats, control group; ZDN, nonobese ZDF rats with diabetes mellitus type 2; ZDF, ZDF rats with obesity and diabetes mellitus type 2. \*\*\* (P < 0.001). W,* 

As with the evaluation of the superoxide radical production, we found statistically significant differences (P < 0.001) in the case of the concentration of malondialdehyde (**Figure 8**) among both experimental groups (ZDN and ZDF) with the control group (W) and also when comparing the experimental group ZDF with the second experimental group ZDN. Like us, Simas et al. [21] evaluated that there was an increase in the MDA concentration in diabetic rats when compared to all other groups. They also recorded a direct correlation between the superoxide radical production values and MDA concentration. Vignera et al. [30] found a link between

*Concentration of malondialdehyde (MDA) among the observed groups. W, Wistar rats, control group; ZDN, nonobese ZDF rats with diabetes mellitus type 2; ZDF, ZDF rats with obesity and diabetes mellitus type 2.* 

*\*\*\*(P < 0.001); \*(P < 0.5). W, compared to the Wistar group; ZDN, compared to the ZDN group.*

*DOI: http://dx.doi.org/10.5772/intechopen.89939*

spermatogenesis is still not understood.

*compared to the Wistar group; ZDN, compared to the ZDN group.*

**Figure 7.**

*ZDF Rats: A Suitable Model to Study Male Reproductive Dysfunction in Diabetes Mellitus… DOI: http://dx.doi.org/10.5772/intechopen.89939*

**Figure 7.**

*Animal Models in Medicine and Biology*

mitochondrial function.

decrease of mitochondrial activity. Like Simas et al., we also observed low levels of mitochondrial activity in the ZDF group when compared to other groups. A decrease of mitochondrial activity was also observed in the experimental ZDN group. This phenomenon could be because diabetes mellitus had a negative impact on the metabolism of carbohydrates, which are the source of energy for a proper

Results of the superoxide radical production (NBT test) (**Figure 6**) showed statistically significant differences (P < 0.05; P < 0.01) when we compared both experimental groups with the control group W. In the experimental ZDF group, we recorded the highest superoxide radical production. This finding suggests that the group of ZDF rats is more at risk for the onset of oxidative stress, which negatively affects the viability of spermatozoa produced by these rats. Sabeti et al. [24] demonstrated that the abnormal production and presence of the superoxide radicals in combination with obesity leads to a reduced semen quality and sperm viability. Overproduction of superoxide may also be due to an increase in metabolic functions in order to maintain the homeostasis in obese individuals. Amaral et al. [27] reported no significant differences in the testicular cell concentration between diabetic and nondiabetic rats, but there was a massive decline in the sperm cell concentration due to the influence of hyperglycemia in late stages of spermatogenesis and increased production of reactive oxygen species (ROS) that may lead to the development of oxidative stress. The consequences of oxidative damage include the loss of motility due to lipid peroxidation, induction of DNA damage of the sperm nucleus, and defects in spermatogenesis affecting the final fertilizing potential of sperm cells. The oxidative environment in testicular tissue of patients with DM2 may result in cellular damage, including lipid peroxidation, formation of carbonyl groups, and DNA damage which causes sperm abnormalities. In fact, this negative condition contributes to a reduction in the sperm motility and viability followed by an

increased percentage of abnormalities in the sperm cells of rats [28].

**Figure 7** points out the levels of DNA fragmentation between the experimental

*Production of superoxide among the observed groups. W, Wistar rats, control group; ZDN, nonobese ZDF rats with diabetes mellitus type 2; ZDF, ZDF rats with obesity and diabetes mellitus type 2. \*\*(P < 0.01); \*(P < 0.5).* 

*W, compared to the Wistar group; ZDN, compared to the ZDN group.*

groups and the control. After evaluation of our results, we found statistically significant differences between the DNA fragmentation following the presence of diabetes mellitus type 2 and obesity. Statistically significant differences (P < 0.001) were observed when we compared the experimental ZDF group with the ZDN group and the control W group and also when we compared the experimental ZDN group with the control W group. As seen from our results, a continuous increase in

**100**

**Figure 6.**

*Levels of DNA fragmentation among the observed groups. W, Wistar rats, control group; ZDN, nonobese ZDF rats with diabetes mellitus type 2; ZDF, ZDF rats with obesity and diabetes mellitus type 2. \*\*\* (P < 0.001). W, compared to the Wistar group; ZDN, compared to the ZDN group.*

DNA fragmentation was present, depending on the presence of diabetes mellitus type 2, obesity, or both. Abbasihormozi et al. [29] found the link between leptin receptor mutation and higher levels of DNA fragmentation as a consequence of a higher production of reactive oxygen species. Leptin is an adipose tissue-derived hormone which has an important role in the metabolism and energy homeostasis and ensures a proper function of the neuroendocrine and reproductive system. A direct administration of leptin could affect male infertility by ROS overproduction or hormone profile modulation, but the exact mechanism of the effect of leptin on spermatogenesis is still not understood.

As with the evaluation of the superoxide radical production, we found statistically significant differences (P < 0.001) in the case of the concentration of malondialdehyde (**Figure 8**) among both experimental groups (ZDN and ZDF) with the control group (W) and also when comparing the experimental group ZDF with the second experimental group ZDN. Like us, Simas et al. [21] evaluated that there was an increase in the MDA concentration in diabetic rats when compared to all other groups. They also recorded a direct correlation between the superoxide radical production values and MDA concentration. Vignera et al. [30] found a link between

#### **Figure 8.**

*Concentration of malondialdehyde (MDA) among the observed groups. W, Wistar rats, control group; ZDN, nonobese ZDF rats with diabetes mellitus type 2; ZDF, ZDF rats with obesity and diabetes mellitus type 2. \*\*\*(P < 0.001); \*(P < 0.5). W, compared to the Wistar group; ZDN, compared to the ZDN group.*

production of MDA and regression of enzymatic activity. The activity of malondialdehyde and caspase-3 were significantly higher, whereas the enzymatic activities of superoxide dismutase and glutathione peroxidase were significantly lower in the diabetic rats than in the control group of healthy rats. Supportive antioxidant treatment could help to increase the antioxidant enzymatic activity and to decrease the activity of malondialdehyde and caspase-3. This treatment also could reduce the apoptosis of germ cells. These facts support the theory about testicular oxidative damage caused by diabetes and subsequent protective effects of antioxidant treatment.

In our opinion the decrease of rat sperm vitality was associated with high levels of body fat because adipose tissue works as an individual endocrine system affecting spermatogenesis and steroidogenesis. On the other hand, diabetes mellitus type 2 affected correct mechanisms of spermatogenesis as carbohydrates are the main source of energy in spermatozoa.
