Introduction

Prevalence of diabetes in sub-saharan Africa has been projected to rise from 7.1 million in 2000 to 18.6 million in 2030 (Saleh, Agarwal, Kandirali, & Sharma, 2002). According to reports, approximately 50% of diabetic men will suffer from reproductive dysfunction within five years of the diagnosis (Saumya & Basha, 2017). Given the alarming prevalence of type II diabetes mellitus (DM) even among youths in the last few decades now drifting towards onset ages of 25–35 years due to urbanization, sedentary life style, dietary, and other factors associated with it.

Studies in diabetic animal model have demonstrated an impairment of sperm quality and fecundity, structural defect, and significantly lower motility of sperm cells (Baccetti et al., 2002), lower ability to penetrate zona free hamster eggs, detrimental effects on endocrine control of spermatogenesis and impairment of erection and ejaculation (Beckam, Goldfire, & Gordon, 2001), progressive genotoxicity, and so on.

The gradual shift to herbal therapy with its attendant increasing acceptance, even among the elite confirm the claim that herbal remedies can provide cure for several diseases, including infertility in men. A large number of plant and animal products have been tested for possible fertility regulatory properties (Anthony, Oladipo, Adedoyin, & Tajudin, 2006).

Auricularia Polytricha (wood ear mushroom) grown in farms and death woods for culinary and medical purposes has been found to have numerous medicinal properties. It belongs to the family Auriculariacaea and has been reported to have antioxidant property (Bhatia, Sharma, Pathania, & Khauduri, 2010). Immunomodulatory activity (Mau, Chao, & Wu, 2001), anti-tumor activity (Sun, Liu, & Kennedy, 2010), anti-dementia properties (Bannett et al., 2003), and hypocholesterolemic effect (Zhao et al., 2015).

A. polytricha has been used locally by the Ejagham speaking people in Cross River State of Nigeria as an aphrodisiac agent in management and treatment of sexual dysfunction in men. This has been going on without the corresponding clinical trials and acceptable scientific experimentation to give credence to this age-long practice. The aim of this study is, therefore, to investigate the effect of graded doses of ethanolic extract of A. polytricha on some reproductive parameters (sperm quality, sex hormones levels, and histological examination of testis) in streptozotocin-induced diabetic animal model.

Materials and methods

Preparation of extract

Auricularia polytricha was be obtained from Etomi central market located in Etung Local Government Area of Cross River State and taken to the Department of Biological Sciences, University of Nigeria for identification. The mushroom was dried at room temperature, powdered and subjected to crude extraction with ethanol. Modified method was used for extraction. Two hundred grams of A. polytricha was soaked in 1000 ml of ethanol, labeled, and covered for 72 h, after which a clean filter paper (Whatman No. 1) was used to filter extracts. The filtrate was evaporated to dryness at 40 °C in a vacuum using a rotatory evaporator. The extracts was weighed and kept at 4 °C in refrigerator until further use.

Experimental animals

Twenty five (25) adult male Wistar rats with average weight of 150 g were used for this research. The rats were kept in clean cages and divided into five groups designated A, B, C, D, and E with five rats in each group. The rats were allowed to acclimatize for two weeks in animal house, Department of Anatomy, Faculty of Basic Medical Sciences, University of Nigeria, Enugu Campus, and allowed unrestricted access to commercially available chow (livestock feed) and water.

Experimental design (Table 1)

Table 1 Experimental animals grouping and treatment

Induction of hyperglycemia

After fasting for 12 h, hyperglycemia was induced by administering streptozotocin (STZ) intraperitoneally reconstituted in 0.5 M sodium citrate and administered at a dose of 65 mg/kg.bw (Ugochukwu & Babady, 2003).

Confirmation of diabetes

Diabetes was confirmed three days after administration of STZ using Accu-Check glucometer (Roche diagnostic, Germany) with blood samples obtained from tails of Wistar rats. Blood glucose levels were checked before and after induction to ascertain hyperglycemic state.

Administration of extract

Diabetes was induced and sustained for 2 weeks (14 days) after which administration of A. polytricha commenced by oral gastric intubation on the fifteenth and lasted for another 3 weeks (21 days). The experimental protocol was maintained for a total of 5 weeks (35 days).

Termination of experiment and collection of samples for analysis

At termination, the animals were sacrificed with the testes removed and plotted with filter paper. Both right and left testes were then suspended in Bouins fluid for fixation, preparatory to histological processing. The sperm was collected by mincing from caudal epididymis with anatomical scissors into a glass beaker. Nineteen drops of diluting solution was added to dilute the semen in a proportion of 1:20. A sample from this homogenate was used for semen analysis.

Determination of sperm count

Sperm count was done using improved Neubauer’s hemocytometer

Determination of sperm motility

Motility estimates was performed from three fields in each sample and the mean of the three estimates used as the final motility. Sperm motility will be determined as follows:

  1. a)

    No progressive motility (grade 1+): spermatozoa swinging the tail with no resultant movement.

  2. b)

    Sluggish motility (grade 2+): spermatozoa moving aimlessly with slow forward progression.

  3. c)

    Moderate progressive motility (grade 3+): spermatozoa moving at moderate speed with forward progression.

  4. d)

    Rapid progressive motility (grade 4+): spermatozoa moving at high speed with straight forward progression.

Examination of sperm morphology

The homogenate was smeared on a clean slide and viewed under microscope at × 400 magnification to assess sperm morphological abnormalities. (Navodita & Varma, 2014).

Hormonal assay

Blood samples for hormonal assay were collected by cardiac puncture and allowed to clot, centrifuged to obtain sera which was stored for 24 h in the refrigerator. ELISA (enzyme-linked immune sorbent assay) kit was used to evaluate levels of follicle stimulating hormone (FSH), leutinizing hormone (LH), and testosterone.

Histological examination

Tissues were sectioned at 5 μ using microtome. Routine hematoxylin and eosin technique was used for staining (Drury & Washington, 1973). Stained sections of testes were observed under light microscope (Olympus, model CX23) and photographed at × 100 and × 400 magnification.

Statistical analysis

Quantitative data from this research was recoded and tabularized. Statistical significance of the differences between the groups was determined using one way analysis of variance (ANOVA) using SPSS (Version 20) statistical analysis program. p < 0.05 will be considered significant.

Results

Diabetic control animals (group B) recorded the least values of sperm count (11.17 + 0.23 million/ml) and sperm motility (29%), and these values were significantly (p < 0.05) lower when compared to group A (sperm count 27.40 + 0.83 million/ml and motility 86 + 0.66%), but with A. polytricha treatment, no significant difference was observed in group C (Diabetic animals placed on 250 mg/kg.bw A. polytricha. However, diabetic animals placed on 500 mg/kg.bw A. polytricha (group D) and 1000 mg/kgbw A. polytricha (group E) recorded sperm count and motility that were significantly increased when compared to diabetic control. Sperm morphological defects were significantly increased in group B when compared to group A while groups D and E recorded remarkably (p < 0.05) lower value of sperm morphological defects when compared to diabetic control animals. (Figs. 1, 2, and 3)

Fig. 1
figure 1

Comparison of sperm count in the different experimental groups

Fig. 2
figure 2

Comparison of sperm motility in the different experimental groups

Fig. 3
figure 3

Comparison of total sperm morphological defect in different experimental groups

Figure 4 reveals that serum levels of FSH and LH were significantly (p < 0.05) lower in group B (diabetic control) when compared to group A (normal control). However, values recorded in groups D and E, diabetic animals placed on 500 and 1000 mg/kg.bw of A. polytricha, respectively increased remarkably (p < 0.05) when compared to diabetic control. As shown in Fig. 5, a chart comparing the testosterone levels of different experimental groups reveals a decrease in testosterone levels in the diabetic control group (8.19 + 0.61 nmol/L), and this reduction was significantly (p < 0.05) lower when compared with normal control group (18.67 + 0.49 nmol/L). Groups D (medium dose A. polytricha) and E (High dose A. polytricha) recorded values that were not significantly higher when compared with normal control.

Fig. 4
figure 4

Comparison of FSH and LH levels in the different experimental groups

Fig. 5
figure 5

Comparison of testosterone levels in the different experimental groups

Histopathological examination

Group A (normal control) revealed that testes had closely packed seminiferous tubules with an intact membrane containing proliferating spermatogonia cells at various stages of maturation. The cells are greater than four layer thick comprising of spermatogia A and B, spermatocytes, spermatids and spermatozoa. There luminal cavity contains flagellae of mature spermatozoa and the separating interstitial matrix contains prominent Leydig cells (Fig. 6a, b).

Fig. 6
figure 6

a Group A (normal control) × 100. b Group A (normal control) × 400

Sections of testes from the diabetic control group (group B) showed significant alteration in histological structural pattern in the testes. Irregular-shaped seminiferous tubules with shrunken lumen where observed. The germinal epithelium had scanty differentiating cells arranged in an irregular pattern and tubular lumen contained very few spermatozoa tails. The intervening interstitium was distorted and cells of Leydig were not prominent (Fig. 7a, b).

Fig. 7
figure 7

a Group B (diabetic control) × 100.b Group B (diabetic control) × 400

Photomicrograph of testes in group C (diabetic animals placed on 250 mg/kg.bw of A. polytricha extract) showed irregular and shrunken seminiferous tubules. Fewer spermatogenic cell population on the germinal epithelium and inconsistent cellular associations. The interstitium was irregular and contained Leydig cells (Fig. 8a, b).

Fig. 8
figure 8

a Group C (diabetes + 250 mg/kg.bw A. polytricha) × 100. b Group C (diabetes + 250 mg/kgbw A. polytricha) × 400

The group of diabetic animals treated with 500 mg/kg.bw of A. polytricha (group D) showed prominent seminiferous tubules with intact basement membranes and prominent Leydig cells in the interstitium. A regular cell series of spermatogenic cell series was observed (Fig. 9a, b).

Fig. 9
figure 9

a Group D (diabetes + 500 mg/kg.bw A. polytricha) × 100. b (Diabetes + 500 mg/kg.bw A. polytricha) × 400

The micro structure of testes in diabetic animals placed on 1000 mg/kg.bw of A. polytricha (group E) revealed prominent seminiferous tubules with intact and undistorted basement membrane. The germinal epithelium had normal and consistent cell associations and tubular lumen with numerous flagella of spermatozoa. The intervening interstitium was regular and contained prominent interstitial cells of Leydig containing blood vessels (Fig. 10a, b).

Fig. 10
figure 10

a (Diabetes + 1000 mg/kg.bw A. polytricha) × 100. b (Diabetes + 1000 mg/kg.bw A. polytricha) × 400

Discussion

Testicular dysfunction caused by hyperglycemic conditions may have been responsible for alteration in spermatogenic process, hence the significant (p < 0.05) reduction in sperm count observed in diabetic control (group B) when compared with normal control. Several experimental evidences have shown that one or more cellular associations in germinal epithelium of testes can be altered in diabetic condition resulting in reduced number of mature spermatozoa (Zhao et al., 2015).

Spermatozoa, unlike other cells, are structurally and functionally unique and are therefore very prone to damage by lipid peroxidation. It has been demonstrated that sperm cells lack the ability to restore alterations caused by increased levels of reactive oxygen specie (ROS) resulting from prolonged hyperglycemia because they do not have the cytoplasmic enzyme system that are required for such reversal. This critical feature makes spermatozoa very susceptible to oxidative insult and may have contributed to low values in sperm count observed in hyperglycemic rats. Krausz, Mills, Rogers, Tan, and Aitken (2015) has also reported so.

According to Halliwell and Gutteridge (2007), reduction in sperm motility has been linked with increase in generation of free radicals in diabetes. From this study, it has been reveals that sperm motility in rats under the influence of STZ—induced diabetes decreased remarkably when compared with normal control. The link between hyperglycemia and sperm motility has been attributed to the series of events that decreases protein phosphorylation resulting in sperm immobilization, which are related to reduced membrane fluidity required for fertilizing capabilities of spermatozoa. This is consistent with findings of Aitken and Krause (2007).

It is also reasonable to suggest that A. polytricha extract may have been responsible for restoration and remarkable improvement in sperm parameters when compared to the diabetic control group because of the antioxidant agents in phenolic and flavonoid contents as well as tocopherol and ascorbic acid as found in A. polytricha. This observation finds backing from Chen et al. (2011), who reported that A. polytricha is a good exogenous source of antioxidant that can prevent oxidative stress in testes thereby improving fertility outcomes.

Low levels of gonadotropic hormones in group B as shown in this study may have been as a result of sustained hyperglycemia. Findings from Brunning et al. (2000) revealed that diabetes is capable of disrupting activities of the Hypothalamo-pituitary-gonadal axis (H-P-G axis) resulting in low serum concentration of androgenic hormones, impaired spermatogenesis, and subsequent subfertility. Insulin receptors have been detected in the hypothalamus and play a critical function as a signaling hormone in the central nervous system. Insulin is also a potential signal to the brain on body energy homeostasis, thus lack of insulin in a diabetic condition may have signaled lack of energy supply and knocked out of brain-specific insulin receptors thereby alterations in the hypothalamo-pituitary-gonadal axis, as a consequence, lower levels of FSH and LH. Reduction in levels of plasma testosterone in diabetic control rats may have been linked to low gonadotropic hormones, especially LH because gonadotropin releasing hormone (GnRH) pulses from the hypothalamus will stimulate the pituitary gland to release FSH and LH which will in turn act on Sertoli cells and Leydig cells to stimulate spermatogenesis. The absence of stimulatory effect of insulin on Leydig cells may also have been implicated.

However, A. polytricha administration may have improved the values of circulating LH, FSH, and testosterone levels as was observed in groups C, D, and E placed on 250 mg/kg.bw, 500 mg/kg.bw, and 1000 mg/kg.bw, respectively. This significant (p < 0.05) increase when compared with the diabetic control may be attribute to the fact that A. polytricha is capable of raising levels of leptin, an important biomolecule that interacts with insulin in the homeostasis mechanism of the CNS. This finding has the support of Obici, Zhang, Karkanias, and Rossetti (2002) and German, Wisse, Thaler, Oh, and Sarruf (2010) who said that decreased levels of leptin are associated with insulin resistance in type II diabetes.

From this research, histological observation on the testes reveals that testicular histology was significantly altered in diabetic rats when compared to the normal control. Less prominent and shrunken seminiferous tubules with loose basement membrane, scanty interstitium, non-visible Leydig cells, and distorted germinal epithelium were observed in photomicrograph of group B when compared with normal control (group A). These are indicators of testicular tissue damage. Kowluru, Kanwar, and Kennedy (2007) have confirmed and reported that STZ-induced diabetes is responsible for alteration in histology of testes, reduction, and possible death of germ cells in experimental animals. This observation also finds support in a study by Ahmed (2005) who reported that free radical production during oxidative stress explains the pathophysiology and biological effect of diabetes mellitus especially regarding cellular degeneration, tissue damage, and subsequent complication. Restoration of testicular lesion was seen in groups treated with A. polytricha; it is therefore appropriate to suggest that mechanisms other than regulation of hyperglycemia were responsible for improved testicular cytoarchitecture. This improvement may be linked to the antioxidant capacity and lipoprotein lipase activity of A. polytricha polysaccharides which are natural antioxidant that could be used as an alternative in resisting oxidation process. Research has shown that the use of synthetic antioxidant may be limited as it showed potential danger in terms of adulteration (Johansen, Rychly, Harris, & Ergul, 2005). Mushroom and mushroom-derived polysaccharides have been shown to have nutritious and therapeutic properties against metabolic syndrome and may be clinically recommended in management and treatment of diabetes-related reproductive dysfunction.

Conclusion

Results from this research clearly demonstrates that microstructural alterations in testes of STZ-induced diabetic rat were regulated, reversed, and restored following administration of ethanolic extract of A. polytricha. This restoration could be attributed to essential phytochemical constituents like polyphenol and flavonoid which may be found useful in prevention and treatment of diabetes induced testicular dysfunction. Reproductive parameters like sperm quality and circulating gonadotropic hormones levels that were altered significantly by sustained hyperglycemia improved in a dose-dependent manner, following 21 days of A. polytricha administration.