Microsoft Word - Biol041017-finalproof.doc 5043- SQU Journal For Science, 10 (2005) © 2005 Sultan Qaboos University 43 Circulating Hormone Levels in Hatchlings of Green Turtle, Chelonia mydas, from Ras Al-Hadd Reserve, Oman A. Y. A. AlKindi Department of Biology, College of Science, Sultan Qaboos University, P.O. Box 36, Al-Khod 123, Sultanate of Oman, Email:aakindy@squ.edu.om مستويات الهرمونات البالزمية في السالحف الخضراء الفاقسة للتو باستخدام حاضنة مخبرية للبيض الذي جلب من محمية رأس الحد بسلطنة عمان عبدالعزيز بن يحيى الكندي تمت دراسة معدالت الهرمونات البالزمية المتمثلـة فـي هرمونـات التكـاثر مـن األسـترادايول و :خالصة ن و الجونادوتروبين في السالحف الخضراء التي فقست للتو و التي تم جمعها بطريقة عشوائية من التستوسيرو 16و قد تمت حضانة البيض باستخدام حاضنة معملية بعد ، خمسة أعشاش من منطقة راس الحد بسلطنة عمان -30نتاج الذكور و مئوية إل 27º-26ساعة من جمع البيض من األعشاش، و قد كانت درجة حرارة الحاضنة 31º و قد وجـد أن . مئوية إلنتاج اإلناث وتم التعرف على نوع الجنس بالفحص المباشر ألنسجة أعضاء التكاثر إال أن معامل (P<0.001)الفروق اإلحصائية بين درجة الحرارة و التستوسيرون ذات داللة إحصائية موجبة كان سالبا، وكان معامل االرتباط بين مستويات هرمـون ، يول االرتباط بين درجة الحرارة و هرمون األسترادا LH وفيما يخص اإلناث فانه لم يوجد معامل ارتباط بين درجة . ودرجة الحرارة ضعيفا، هذا فيما يخص الذكور لم يكن ممكنا قياسه في كل من الجنسين، و سيتم نقاش FSHكما أن هرمون. الحرارة و أي من تلك الهرمونات .تائج وأهميتها في هذا البحثهذه الن ABSTRACT: Post-hatching levels of plasma estradiol (E2), Progesterone (Pro), testosterone (T), Luteinizing Hormone (LH), Follicle-Stimulating Hormone (FSH) and thyroxine (T4) were monitored in hatchlings of Green Turtle, Chelonia mydas immediately after emergence. Eggs were collected at random from 5 nests. The eggs were placed in incubators 16 hr after oviposition set at 26-27oC for male producing hatchlings and at 30-31oC for female producing hatchlings. Blood was collected after sacrifice. Chemiluminescence immunoassay was used for determination of plasma hormone levels, using Beckman Coulter Access-2-immunoassay and reagents (Beckman Coulter, Inc.). Sex was determined from histological examination of gonads. In males, plasma T levels were positively correlated with temperature (rho = 0.67, P<0.001). A.Y.A. ALKINDI 44 However, plasma E2 levels were negatively correlated but not strongly with temperature (rho = -0.396, P<0.05) and there was a weak correlation between plasma LH levels and temperatures (rho = 0.38, P<0.05). Also in the males, there was no correlation between temperature and either plasma Pro or T4 levels. In females, there was no correlation between temperature and any of the hormones. In addition, there was no significant difference in plasma concentrations of T, Pro, LH or T4 between sexes. However, plasma E2 concentration was significantly higher in males (P<0.05). FSH was undetectable in plasma from both sexes. The significance of these findings will be discussed. KEYWORDS: Circulating hormone, hatchilings, green turtle. 1. Introduction n many reptiles including turtles, sex determination depends on incubation temperature. In chelonian embryos with temperature–dependent sex determination (TSD), the thermosensitive period (TSP) takes place in the middle third period of incubation (Yntema and Mrosovsky, 1982; Wibbels et al. 1991, a, b; Desvages et al. 1993). In the Olive ridley (Lepidochelys olivacea) TSP was about 7 days (day 20-27 of the incubation period) at a male or female promoting temperature (Merchant-Larios et al. 1997). The rate of gonadal growth was faster at female promoting temperature than at male promoting temperature. During the critical stages of TSP, there is a rapid differentiation in the steroidogenic tissues as well as differential expression of steroidogenic enzymes (Thomas et al. 1992; Fleming et al. 1999; Rhen et al. 1999). Moreover, sex steroid hormones and particularly estrogens are essential in controlling sex determination (Crews et al. 1994; Crews, 1996; Lance, 1997; Wibbels et al. 1998). Administration of exogenous estrogens to the red-eared slider turtle (Trachemys scripta) was capable of changing males to females during TSP despite the temperature effect (Crews et al. 1991). Administration of exogenous aromatase inhibitor, the enzyme that is responsible for estrogen biosynthesis, can override the female–promoting incubation temperature that resulted in male hatchlings (Crews et al. 1994; Wibbels and Crews, 1994). Rhen et al. (1999) reported that incubation temperature could influence sex steroid levels 6 weeks after hatching in the red-eared slider turtle. Temperature may be transduced into steroid signals for controlling gonadal differentiation. Steroidogenic factor 1 (SF-1) regulated steroidogenic enzymes expressed during TSP in red-eared slider turtle (Fleming et al. 1999; Fleming and Crews, 2001). This report represents a preliminary investigation on monitoring plasma sex steroids, gonadotropins and thyroxine in the green turtle hatchlings immediately after emergence. Such findings are valuable in understanding the physiological and hormonal status in the green turtles, and provide important preliminary information for future conservation programs of these animals at Ras Al-Hadd Reserve, Oman. 2. Methods 2.1 Study Area Ras Al-Hadd Reserve (between 22o 32 N and 59o 45 E and 22o 14 N and 59o 48 E) is a 45 km coastal strip on the Gulf of Oman and the Arabian Sea with over 20 major sandy beaches that extend from Al-Jarama Bay to Ras Ar Ruays. The first 4 km in the northern section of the Reserve is located on the Gulf of Oman while the rest (approx. 41 km.) is located on the Arabian Sea. I CIRCULATING HORMONE LEVELS IN HATCHINGS OF GREEN TURTLE 45 2.2 Egg Collection Eggs were collected randomly within 1 km area from 5 different nests immediately after oviposition from Ras Al Hadd Reserve-Oman in January and May 2003. Each nest was excavated and eggs were taken out. The eggs were then transported in plastic buckets with damp sand from Ras Al- Hadd to the Department of Biology at Sultan Qaboos University (SQU) and placed in the incubators about 16 hr after oviposition. 2.3 Method of Incubation Each egg was incubated singly in 600 ml plastic container according to the method of Mrosovsky (1988), with some modifications. Each container had a plastic cover 10 cm in diameter. The upper part of the container was punched (eight holes in each container, 2.5 mm in diameter). Each egg was placed at the center of the container on top of sponge foam surrounded by vermiculite. In each container, 65 ml of distilled water was added to moisten the foam. Additional 65ml of distilled water was added to the vermiculite on day 20 of incubation. The eggs were placed in Precision Scientific incubators (Thermo Forma, Marietta, OH, USA) adjusted to run at different temperatures. Eggs incubated at 30-31oC produced females while eggs incubated at 26-27oC produced males. Uncovered containers containing distilled water were placed at the bottom of the incubators in order to provide humidity for the eggs. Two mercury thermometers with 0.1°C graduation were placed inside the incubators at the center of each shelf to ascertain temperature accuracy. Daily temperature readings were quickly taken when the incubator was opened. On the outside of the incubator a temperature gauge was checked to make sure that there was no significant fluctuation between daily temperature readings. 2.4 Fixation and Tissue Processing Hatchlings were sacrificed and the gonads were dissected along with the adjacent kidneys. They were fixed in 10% buffer formaline and then processed for light microscope according to the method of Mrosovsky, (1988). 2.5 Blood Collection Blood samples were collected from the hatchlings approximately 24h after hatching. The hatchlings were sacrificed and plasma was obtained from the blood samples. 2.6 Determination of Plasma Steroid Concentrations Chemiluminescence immunoassay was used for the determination of plasma steroids, FSH, LH and T4 levels using a Beckman Coulter Access 2 immunoassay system and reagents. (Beckman Coulter, Inc., USA). The technique detects the emission of light due to the occurrence of a chemical reaction. It involves the release of energy in the form of photons as the electrons move from the excited state to the ground state. 2.7 Statistical Methods The non-parametric Mann-Whitney U test was used to compare the differences of hormone levels between the sexes while Spearman correlation was used to test the correlation between the hormones values. (P< 0.05) was considered significant. A.Y.A. ALKINDI 46 MALE (n=32) FEMALE (n=12) T E S T O S T E R O N E ( nm ol /L ) 4.5 4.0 3.5 3.0 2.5 Figure 1. Box plots of plasma testosterone levels in hatchlings of the green turtles Chelonia mydas incubated in laboratory under constant temperature. Boxes represent the middle 50% of the observations. Horizontal lines inside the boxes represent the median. Observations beyond the vertical lines are outliers. Table 1. Plasma hormone levels and the incubation temperature of hatchlings – green turtles, Chelonia mydas. (*Significant at P< 0.05) Hormone values Sex and number Mean ±SEM Incubation temperature oC Testosterone (nmol/L) F = 12 M = 32 3.57 ± 0.081 3.41 ± 0.069 F = 16 30 15 ± 0.28 M = 39 27 19 ± 0.18 Estradiol (nmol/L) F = 11 M = 36 0.18 ± 0.03 0.27 ± 0.02* “ Progesterone (nmol/L) F = 12 M = 34 11.16 ± 1.77 10.08 ± 0.88 “ Luteinizing hormone (IU/L) F = 11 M = 30 0.15 ± 0.04 0.27 ± 0.05 “ Thyroxine (pmol/L) F = 9 M = 16 45.20 ± 3.16 52.90 ± 4.27 “ 3. Results P, T, LH and T4 plasma values were not significantly different between sexes (Figs. 1-5). However, E2 levels were significantly higher in males over females (P<0.05) (Fig. 2). FSH levels were undetectable in both sexes. Hormone values are reported in Table 1. CIRCULATING HORMONE LEVELS IN HATCHINGS OF GREEN TURTLE 47 MALE (n=36) FEMALE (n=11) E ST R A D IO L (n m ol /L ) .7 .6 .5 .4 .3 .2 .1 0.0 44 5 15 13 Figure 2. Box plots of plasma estradiol levels in hatchlings of the green turtles Chelonia mydas incubated in laboratory under constant temperature. See Fig 1 for explanation. MALE (n=16) FEMALE (n=9) T H Y R O X IN E (p m ol /L ) 100 80 60 40 20 0 Figure 3. Boxplots of plasma thyroxine levels in hatchlings of the green turtles Chelonia mydas incubated in laboratory under constant temperature. See Fig 1 for explanation. In the female hatchlings, there was no correlation between plasma levels of E2, Pro, T, LH and T4, and the incubation temperature. There was also no correlation between the hormone levels. In male hatchlings, incubation temperature was positively correlated with plasma T levels (rho= 0.67, P=<0.01) but there was a weak negative correlation with plasma E2 levels (rho= -0.4, P=<0.05). As the incubation temperature increased there was a decrease in plasma E2 levels. Also, there was a weak A.Y.A. ALKINDI 48 MALE (n=34) FEMALE (n=12) PR O G E ST E R O N E (n m ol /L ) 30 20 10 0 26 53 Figure 4. Boxplots of plasma progesterone levels in hatchlings of the green turtles Chelonia mydas incubated in laboratory under constant temperature. See Fig 1 for explanation. correlation between incubation temperature and plasma LH concentration (rho = 0.380, P<0.05). There was no correlation between incubation temperature and plasma P, and T4 levels. Light microscopic studies indicated that in the female the gonadal medulla was degenerative while the cortex was well developed with the appearance of the primary follicles. MALE (n=30) FEMALE (n=11) L H (I U /L ) .8 .6 .4 .2 0.0 17 29 Figure 5. Boxplots of plasma LH levels in hatchlings of the green turtles Chelonia mydas incubated in laboratory under constant temperature. See Fig 1 for explanation. CIRCULATING HORMONE LEVELS IN HATCHINGS OF GREEN TURTLE 49 4. Discussion Plasma levels of steroids (E2, Pro and T) gonadotropins (FSH and LH) and thyroxine (T4) were analyzed shortly after hatching in relation to the incubation temperature in the green turtles collected from Ras Al-Hadd, Oman. The results indicate that there is no clear pattern in the hormonal levels of the male and female hatchlings 24 hr after emergence. The lack of specific differences in hormone values may indicate that these hatchlings are still in their transitional stage of gonadal development and may take sometime before any conclusive difference in hormonal levels can take place. On the other hand, the histological sex differences clearly show that in the males, the gonadal tissue cortex is degenerative while the medulla is well developed with distinct appearance of the seminiferous tubules. In the female gonadal tissue the medulla is degenerative while the cortex is well developed with the appearance of the primary follicles. The values of plasma hormone levels in the females did not show any correlation with the incubation temperature. However, in males the incubation temperature was positively correlated with T and LH levels but negatively correlated with E2. Also, Pro, T4 levels were not correlated with the incubation temperature. FSH levels were not detected in both sexes. There was no significant difference in hormone levels between the sexes except E2 levels, which were higher in males over the females. These results indicate that there was no conclusive evidence that the incubation temperature had any lasting influence on steroidogenesis immediately after emergence in the green turtles. Rhen et al. (1999) reported that the incubation temperature in the red-eared slider turtles Trachemys scripta, a species with TSD, had lasting effects on the sex–steroid levels even six weeks after hatching. Plasma thyroxine levels did not show any correlation with the incubation temperature and there was no significant difference between the sexes. In the snapping turtle (Chelydra serpentina) plasma T4 levels from hatchlings emerging from eggs incubated at 21.5oC average 220% that of turtles emerging from eggs incubated at 30.5oC (O’Steen and Janzen, 1999). However, O’Steen and Janzen, (1999) added triiodothyronine to the eggs during mid-incubation and that may have altered the natural values of T4 in the embryo. In the present study carried out in both sexes, T4 levels did not show any correlation with the incubation temperature. A comprehensive investigation on the relationship between stages of TSP and the steroidogenic pathways must be investigated before drawing any conclusion on the effects of incubation temperature on the hormone levels in the hatchlings of a TSD species like the green turtles. 5. 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