Authors
1 Dept. Theriogenology Fac. Vet. Med., Assiut University.
2 Dept. of Anatomy and Histology, Fac. Vet. Med., Assiut University
Abstract
Keywords
Dept. Theriogenology
Fac. Vet. Med., Assiut University.
Morphometric and immunohistochemical variations in the camel (Camelus dromedarius) testis in relation to some endocrinological aspects during different seasons of the year
(With 2 Tables and 3 Figures)
By
D.R.I. Derar; H.A. Hussein and A.M. Saleh*
*Dept. of Anatomy and Histology, Fac. Vet. Med., Assiut University
(Received at 16/12/2004)
التغيرات في القياس الظاهري وکيمياء النسيج المناعي في خصية
الجمل وحيد السنام نسبة إلى بعض النواحي الهرمونية
خلال المواسم المختلقة من السنة
تمت دراسة التغيرات الموسمية التي تطرأ علي مستوي هرمون التستستيرون في المصل مدعومة باستکشاف التفاعل المناعي لإنزيم 3 بيتا هيدروکسي ستيرويد ديهيدروجينيز في خلايا لايدج لعدد 54 جمل وحيد السنام وناضج جنسيا وسليم ظاهريا. أظهرت النتائج أن خلايا لايدج کانت کثيرة ومنتشرة في النسيج البين خلوي مع تفاعل قوي وإيجابي لإنزيم 3 بيتا هيدروکسي ستيرويد ديهيدروجينيز أثناء أشهر ديسمبر ويناير وفبراير ومارس. تفاعل هذا الإنزيم کان خافتا وضعيفا تدريجيا أثناء الأشهر من أبريل وحتى يوليو عندها لم يکن ممکنا ملاحظة التفاعل المناعي لهذا الإنزيم. وفي ذات الوقت -ومصاحبا لهذه التغيرات-کانت هناک زيادة کبيرة في هرمون التستستيرون في المصل ابتداءًا من شهر ديسمبر وانتهاءا بشهر أبريل مع ملاحظة أن أعلي مستويات له کانت في شهر يناير. لوحظ أن مستوي هرمون الثيروکسين في المصل يمر تقريبا بنفس التغيرات من زيادة ونقصان متوازيا مع التي شهدها هرمون التستستيرون. من خلال نتائج الدراسة الحالية يمکن القول أن إنزيم 3 بيتا هيدروکسي ستيرويد ديهيدروجينيز له أهمية قصوى في تنظيم عملية تخليق هرمون التستستيرون من خلايا لايدج في ذکور الجمال وحيدة السنام وأن هرمون الثيروکسين هام جدا للنشاط التناسلي أثناء موسم التزاوج في ذکور الجمال وحيدة السنام ويمر بنفس التغيرات التي يمر بها هرمون الذکورة.
Seasonal variation in serum testosterone, thyroxin and the testicular morphology were studied in 54 sexually mature and apparently healthy one-humped camels during the different seasons of the year. The testosterone and thyroxin serum levels were measured and 3b-hydroxysteroid dehydrogenase activity of Leydig cells was assessed immunohistochemically to aid in the interpretation of results. The activity of 3b-HSD was high during cold months and severely depressed to the minimum activity in hot months. Concomitantly, serum testosterone and thyroxin levels increased during the winter and early spring and decreased thereafter. Their levels reached the peak during the months of January till April. These results suggested that 3b-HSD is a key enzyme in the regulation of the testosterone production in Leydig cells of the male dromedary. Thyroxin is a crucial hormone for the male reproductive activity during the breeding season in the dromedary and fluctuated in the same pattern as serum male androgen.
Seasonal changes in the camels could be clarified through studying morphology of the testis, histochemical observation of the testes and studies on the male accessory sex glands (Abdel-Raouf and Owaida 1974, Abdel-Raouf et al. 1975). It has been found that in seasonal breeders the mating and nonmating seasons are clearly related to different levels of testosterone in the plasma and testes (Racey, 1978). Clear correlation between testicular steroidogenesis and reproduction is well exemplified in the dromedary that is not a typical seasonal breeder. The rate of synthesis of testosterone is high during the mating season and low during the nonmating season (Friedlander et al. 1984).
Seasonality in the male is evidenced by changes in sexual behaviour, morphology and function of the genital organs, as well as changes in endocrinological profiles. In seasonal breeders, the effect of photoperiod is undeniable. In this regard, Vaughan et al. (1982) explained that chronic exposure of female Syrian hamsters (long day breeders) for 9 weeks to a short photoperiod (10L:14D) depressed the pituitary-thyroid axis as indicated by a drop in circulating titers of thyroid stimulating hormone (TSH), thyroxin (T4), triiodothyronine (T3) and the free thyroxin index (FT4) compared to animals maintained under long photoperiodic conditions. 90% of iodine circulating in the animal's blood is in the form of T4 (Wilson, 1975). Lack of iodine prevents production of both T4 and T3 (Guyton, 1991). The enzyme hydroxysteroid dehydrogenase (3b-HSD) plays a central role in the biosynthesis of steroid hormones, including androgens (Conley and Bird 1997; Penning 1997). 3b-HSD is present in the testis, ovary and placenta, adrenal gland as well as in a large number of peripheral intracrine tissues, including the prostate, breast, liver and skin (Ferre et al. 1975; Lacoste et al.1990). It catalyzes the final step in progesterone biosynthesis in the ovary and is required for testosterone production in the testis. Different 3b-HSD isoforms have been cloned from various tissues from humans, rats and mice (Simard et al. 1993 and 1995 and Penning 1997).
The purpose of the present work was to investigate the correlation between seasonal changes in serum testosterone and thyroxin hormones from one side and the 3b-HSD activity and testicular morphology on the other side.
Materials and Methods
The testes of 48 sexually mature (5-12 years old) and apparently healthy one-humped camels were obtained from Bany-Ady (Assiut governorate) and Cairo slaughterhouses. The materials were collected at regular monthly intervals over a period of twelve months. Within one hour after slaughter, the scrotum was incised, the testes were removed and the volume was taken. For the histological morphometric study, the testes were cut in slices and small cubes from the testicular parenchyma were taken and fixed in neutral buffer formalin contained 1% glutaraldehyde. Then, processed for paraffin embedding, and sections of 5µm thick were cut and stained with H&E.
Morphometric studies: The weight of testes was taken and their volume was measured by water displacement method (Willett and Ohms, 1957 and Scherle, 1970). The testicular parenchymal volume was calculated by subtraction of 11% from the testicular volume. These 11% represent the volume of tunica albuginea and rete testis (Wrobel 1990). Different histological morphometric values were carried out on H&E stained sections using Leica Q 500 MC Image analyzer.
3b-Hydroxysteroid dehydrogenase (3b-HSD):
Fixation: Immediately after slaughter, the testes were removed from their envelopes and samples of suitable size (about 1.0 x 0.5 x 0.5 cm) were taken from different regions testis every month. Immersion fixation was carried out in two steps. Fixative I (30 min) contained 4% paraformaldehyde; 15% v/v saturated picric acid; 0.1% glutaraldehyde in 0.1 M phosphate buffer, pH 7.4. Fixative II (several hours) had the same composition as fixative I but without glutaraldehyde. Following fixation, the blocks were washed in 0.1 M phosphate buffer, transferred into a graded series (10%, 20%, 30%) of saccharose-containing rinsing buffer and shipped by air to Regensburg. Here, the samples were immersed in Tissue Tek OCT compound (Miles, Elkhardt, Ind., USA) and snap-frozen in liquid nitrogen. Cryostat sections (12 µm thick) were mounted on gelatin/chrome alum-coated slides and air-dried for 2 - 3 min before further treatment.
Controls for immunohistochemistry:Controlsincluded: (a) Omission of the primary antiserum. (b) Substitution of primary antiserum by non-immune serum 1: 500 in blocking buffer. (c) Blocking of the primary antibody by preincubation with the matching antigen in excess. No immunostaining was obtained after any of these control procedures (a-c).
Statistical analysis: Statistical analysis of the collected data was carried out according to procedures of completely random design, SAS (1995).
Results
The weight, volume densities (mean ± SE) of testes and testicular parenchyma throughout the year are shown in (Table 1, Fig 1A). There was one fold difference between the highest and lowest mean testicular volume during different reproductive cycle. The testicular weight and volume showed similar peak during the breeding phases. The testes began to increase in weight and volume from quiescence (September) and attained a peak during breeding season (December, January and February). Then, testes declined in volume and weight in March and April to reach the lowest values in July.
The epithelial height and diameter of seminiferous tubules (table 1, Fig 1B) displays statistically significant annual changes. The tubular diameter showed significant increase in February and March and lowest values were recorded in July. The epithelial height showed significantly higher values during the breeding season in December and January. The Leydig cells started to increase in number in September to reach the maximum number in December and showed significant seasonal variations (table 1, Fig 1B).
Table 1: seasonal and monthly variation in testicular volume, diameter of seminiferous tubules and epithelial height of seminiferous tubules in the male dromedary (n = 48).
Mon. |
Day length (hrs) |
Testicular weight (g) |
Testicular Volume (c.c.) |
Parenchyma volume of (c.c.) |
Leydig cells number/Crosse section 250X |
Diameter of seminiferous tubules (µm) |
Epithelial height (µm) |
Jun July (Summer) Aug. |
14.15 |
64.0 ± 3.0a |
65.8 ± 3.3a |
47.1 ± 2.2a |
55 ± 4.4a |
169.4 ± 2.5a |
77.5 ± 1.6ab |
13.50 |
64.3 ± 3.5 a |
65.3 ± 3.9 a |
47.1 ± 2.6a |
40 ± 3.7a |
163.5 ± 1.6 a |
77.5 ± 1.7ab |
|
13.15 |
64.8 ± 4.0 a |
66.8 ± 4.3 a |
47.2 ± 3.2a |
40 ± 4.1a |
170.3 ± 1.7 a |
74.6 ± 2.3ab |
|
Sept. Oct. (Autumn) Nov. |
12.30 |
66.5 ± 5.1 a |
68.9 ± 5.3 a |
50.8 ± 3.2a |
90 ± 5.2ab |
187.5 ± 3.8 ab |
63.4 ± 2.6a |
11.30 |
71.0 ± 3.3 ab |
73.8 ± 3.3 ab |
58.0 ± 2.2ab |
95 ± 5.0ab |
190.5 ± 4.6 ab |
78.4 ± 1.4ab |
|
10.15 |
78.0 ± 3.4 ab |
79.3 ± 3.6 ab |
63.0 ± 3.5ab |
110 ± 6.7ab |
198.8 ± 2.8b |
86.1 ± 5.2 b |
|
Dec. Jan. (Winter) Feb. |
10.45 |
94.8 ± 4.3b |
95.8 ± 4.3b |
78.0 ± 2.1b |
182 ± 8.0b |
200.4 ±4.3 b |
90.3 ± 2.1 b |
11.0 |
96.6 ± 5.6 b |
97.6 ± 6.6 b |
79.6 ± 2.4 b |
280 ± 8.7b |
210.1 ± 4.8 bc |
91.4± 3.1b |
|
11.45 |
93.9 ± 5.3 b |
94.9 ± 4.3 b |
77.2 ± 3.6 b |
265 ± 10b |
210.4 ± 5.1 bc |
90.5 ± 4.6 b |
|
March April (Spring) May |
12.0 |
90.0 ± 5.7 b |
90.5 ± 5.7 b |
73.2 ± 4.8 b |
180 ± 9.6b |
220.6 ± 5.2 c |
90.3 ± 2.1 b |
12.50 |
71.2 ± 4.3 ab |
73.8 ± 5.3 ab |
67.1 ± 4.5 b |
160 ± 9.0b |
190.5 ± 6.1 ab |
86.4 ± 2.5 b |
|
13.50 |
60.1 ± 4.1 ab |
61.1 ± 4.2 ab |
55.5 ± 3.3a |
90 ± 4.1a |
180.7 ± 4.2 ab |
81.5 ± 1.9 ab |
Figure 1: seasonal variation in: (A) testicular weight, testicular volume and Parenchymal volume B)Leydig cells number, Tubular diameter and Epithelial height of the testicular tubule.
3b-HSD immunohistochemistry
The hormonal activity of the Leydig cell was assessed by 3b-HSD enzyme immunohistochemitry. This reaction revealed dark gray granules localized in the cytoplasm of the Leydig cells. The intensity of the reaction and the population of Leydig cells showed marked annual variations. In June, July and august, a weak reaction in and low number Leydig cells were observed. September and October, intertubular tissue showed few number of Leydig cells with strong 3b-HSD reaction. The number of the Leydig cells increased to reach their maximum population and strongest 3b-HSD reaction in December, January and February (qualitative and quantitative). In March April and May, the intertubular tissues contained abundant number of Leydig cells with relatively weak 3b-HSD reaction (Figure 2).
Figure 2: Changes in 3b-HSD immunoreactivity throughout different seasons of the year in the male camel. 250x.
In the beginning of the year, during January to April months, serum testosterone increased significantly and reached a peak level during these months As shown in table (2), Figure (3).
Table 2: Serum concentrations of testosterone and thyroxin all over the year in male camels (n = 6).
Month |
Season |
Testosterone ng/ml |
Thyroxin ng/dL |
June |
Summer |
2.58 ± 0.72c |
66.50 ± 7.81bc |
July |
1.30 ± 0.75c |
52.16 ± 9.05c |
|
August |
1.11 ± 0.56c |
50.33 ± 7.70c |
|
September |
Autumn |
2.54 ± 0.44c |
41.33 ± 16.06c |
October |
1.43 ± 0.26c |
4.42 ± 4.49cd |
|
November |
1.49 ± 0.40c |
26.50 ± 2.57d |
|
December |
Winter |
15.94 ± 3.40b |
64.50 ± 8.34bc |
January |
30.86 ± 2.96a |
75.83 ± 12.08b |
|
February |
30.37 ± 3.00a |
96.50 ± 19.20ab |
|
March |
Spring |
29.93 ± 3.88a |
91.00 ± 17.39b |
April |
30.99 ± 5.88a |
116.00 ± 18.50a |
|
May |
13.59 ± 2.23b |
87.83 ± 6.16b |
The reproductive activity of the camel builds up during September and October, and the animal is in actual rut during November, December, January and February, with a drop in March and thereafter(Abdel-Raouf and owaida, 1974, Abdel-Raouf et al., 1975 and Tingari et al, 1984). In the present study, the testes began to increase in volume from quiescence (September) and attained a peak during breeding season (December, January and February). Then, testes declined in volume in March and April to reach the lowest values in July. The present findings are coincident with those of Singh and Bharadwaj (1978) and Zayed et al. (1995).
Thornton et al. (2002) suggested that plasma androgen and/or IGF-1 levels may be important in modulating the expression of some s in the regulation of the testosterone production in Leydig cells. In this study, a steroidogenic enzymes like 3beta-HSD. These results suggest that 3beta HSD is a key enzyme strong positive relation between serum androgen and histochemistry reaction of 3b-HSD was noticed. In June and July, The Leydig cells showed low population and a very weak 3b-HSD activity. The activity of the 3b-HSD increased steadily in September and October and reached the maximum activity in December, January, February and March (qualitative and quantitative). The Leydig cells are in highest population and highest morphological differentiation and their smooth ER (SER) is highly developed (Zayed et al. 1995). In April and May, the Leydig cells decreased steadily in population and 3b-HSD activity to reach the minimum state in Jun and July. The cells were small in size, SER is reduced and many Leydig cells are degenerating (Zayed et al. 1995). These findings supported the previous results reported for camel (Yagil and Etzion, 1980), stallion (Johnson and Thompson, 1987) and Japanese black bear (Komatsu et al 1997).
Serum testosterone level was 15.94 ± 3.40 ng/ml in December, reached a plateau in April (30.99 ± 5.88 ng/ml) and decreased to 13.59 ± 2.23 ng/ml in May and dropped to its lowest level at June (2.58 ± 0.72 ng/ml) and continued at this nadir through the summer and autumn seasons. It has been previously shown that the differential testosterone synthesis between the seasons in the dromedary is not quantitative. However, during the mating season, the synthesis of testosterone synthesis is through both 4-ene and 5-ene pathways, whereas during the non mating season, the synthesis occurs mainly through the 5-ene pathway and at a lower rate than that of this pathway duringthe mating season (Bedrak et. al., 1983). Delgadillo et al. (2004) reported that Short days enhanced testosterone secretion and long days inhibited it in seasonal breeder males. During the mating season, Leydig cells were highly packed and larger than during the nonmating season (Friedlander et. al., 1984).
Abdel-Raouf et al (1975) claimed that the largest seminiferous tubule diameters and the greatest numbers of spermatogonia, spermatids and spermatozoa were found in the spring. The numbers of mature Leydig cells, compared to the numbers of pre-Leydig and immature Leydig cells, increased by the end of winter so that, during the spring, the interstitial cells were mainly of the mature type. Degenerative changes with diminished numbers of mature cells were seen in the summer and this trend continued into early and mid-autumn. In the stallion (long day breeder), Johnson and Thompson (1987) found that the volume of Smooth Endoplasmic Reticulum (SER)/g and testosterone/g tended to be higher in the breeding than non-breeding season. Leydig cell number/g, volume of SER/testis, testosterone/testis, and Leydig cell number/testis were significantly greater in the breeding than in the non-breeding season. Volume of SER/testis and testosterone/testis were related significantly to the cell number/testis, and SER/testis was related (P < 0.05) to testosterone/testis.
Our findings support the concept that thethyroid gland plays a fundamental role in seasonal reproduction in the male camel.An annual cycle of serum thyroxin wasdetected; values reached a peak in winter (late breeding season) and aminimal level in summer (late anestrus). Significant increase in serum thyroxin concentration was found during the period from December till June. Maximum level of thyroxin was found in April (116.00 ± 18.5 ng/dL). The increase in serum thyroxin concentrations was coincident with an increase in serum androgen concentration. Moreover, a simultaneous significant decline in serum thyroxin and androgen levels were found nearly in the same time during the nonmating season. Wasfi, et al. (1987) reported values of 9.33 ±1.15 ng/ml (1.43±0.18 nmol/l) for T3 concentration in normal Saudi Arabian camels. Nazifi et al., (1999) found that the concentrations of T3 and T4 were higher in the breeding season compared with the rest of the year (p< 0.05). Thyroidal hormones (T3 and T4) showed significant correlations with serum total protein and glucose.
A significant positive correlation between plasma levels of cholesterol and both serum thyroxin and testosterone in males was reported (Heller et. al 1981). Webster et al (1991), Andersonet al. (2003) and Hernandez et al (2003) mentioned that thyroid hormones did not alter onset of the breeding season but they were permissive for various species to enterseasonal anestrus. Responsivenessto T4 is lost gradually during the mid to late anestrous season and thyroid hormones can influence the timing of the breedingseason and thus may be required for the maintenance or entrainmentof the endogenous reproductive rhythm(Andersonet al, 2002 Billings et al, 2002). Viguié et al (1999) provided strong evidencethat thyroid hormones can act directly within the brain to promoteseasonal inhibition of neuroendocrine reproductive functionin the ewe. Further, the reproductiveneuroendocrine axis is not equally responsive to thyroid hormoneat all times of the year (Thrun et al, 1997). It is concluded that the decline of thyroid function, as gauged by hormone secretion in summer, aids in preservation of body water by decreasing pulmonary water loss and dropping basic metabolism(Yagil et al, 1978).
Form the present findings, it seems that, Thyroid hormones are necessary onlyduring a limited interval early in the breeding season to promoteseasonal reproductive activation in the male dromedary. There is a criticalperiod of responsiveness during which thyroid hormones mustbe present for rut to develop. In conclusion, the present findings indicated that there is a concomitant rise and fall in 3b-HSD, serum testosterone and thyroxin level in the male dromedary which is indicative and diagnostic for the onset of reproductive seasonality. Thyroxin is a key hormone for the resumption of sexual activity after the non rut period in the dromedary.
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