Document Type : Original Article
Author
Department of Animal Biotechnology, Animal Production Research Institute, Dokki, Giza, Egypt
Abstract
Keywords
PROGESTERONE AND ESTROGEN SUPPLEMENTATION IN VITRO CULTURE MEDIA IMPROVE MORPHOGENESIS AND DEVELOPMENT GASTRULATION EMBRYOS RABBITS
A. M. Saeed
Department of Animal Biotechnology, Animal Production Research Institute, Dokki, Giza, Egypt. PO Box 12816. Aymansm66@gmail.com.
The objective of this study was to compare the development competence of in vitro embryo rabbit and gastrula under culture media supplemented with serum pregnancy does rabbit (SPDR). Eighty four rabbit embryos from 20 does at 6d.p.c; divided into two groups. The 1st group culture with stander media TCM 199 (control). The 2nd group culture with TCM 199 supplemented with (10% v/v) pregnancy serum rabbit does with the final concentration of progesterone 9ng/ml and 17β-estradiol 20pg/ml for three days.
Numerically viability rates were improved insignificantly according to SPDR additive to culture media. The increase rate significantly (P˂0.05) in blastocysts dimension (area 74.29%, perimeter 32.80%) and in gastrula dimension (area 82.02%, perimeter 47.24%) at 48h of culture compared with control group. In the other hand, the rate of collapsed embryos elevated in the control group compared with the serum group. Furthermore, the present results were observed that significantly increased (P˂0.05) in gastrulation stages after 8 d.p.c and 9 d.p.c, 65% and 100% of embryos treated with SPDR reached to stage 5 to 7 with strong brachyury expression along the entire primitive streak also in notochordal process .
Conclusively, overall progesterone and estrogen play an important role in the development and implantation of pre-gastrulation embryos rabbit.
Key words: Progesterone, Embryogenesis, Morphogenesis, Gastrulation, In vitro, Development, Rabbit.
Rabbit blastocysts can be exactly staged in living embryos in vivo and in vitro and are amenable to experimentation under standard culture conditions (Halacheva et al. 2011).
Gastrulation in the rabbit starts at day 6 p.c., at a stage which is easily accessible as implantation has not yet started. Seven gastrulation stages have been identified so far (Romia et al., 2010), using morphological and molecular methods (Viebahn et al.,1995; Schafer-Haas and Viebahn, 2000; Viebahn et al.,2002 and Viebahn, 2004). Early cell-lineage decision during embryonic development is another example where embryos of different mammals clearly vary between species, as recently emphasised by Rossant (2011).
Estrogen and progesterone play an important role in the development and implantation of preimplantation embryos. There is now general consensus that metabolism of steroid hormones in target tissues may play a significant part in their overall action in many types of tissues (Labrie et al., 2000). Its play key roles in the establishment and maintenance of pregnancy (Crosier et al., 2000). Elimination of these hormones from pregnant animals causes deleterious effects on the development and implantation of the embryos. It appears to be important to maintain the concentrations of estrogen and progesterone at appropriate levels relative to each other. Elevated ratios of estradiol to progesterone were shown to inhibit blastocyst metabolism and implantation (Safro et al., 1990).
Plasma concentrations of progesterone and 20α-dihydroprogesterone (Fuchs and Beling, 1974), and the rate of rise of plasma progesterone (Singh and Adams, 1978) have been reported to be higher in pregnant than in pseudopregnant rabbits during the immediate preimplantation period, Days 5-6 following mating. Crosier et al., (2000) showed that embryos treated with estrogen in vitro had significantly higher implantation rates when transferred to foster mothers receiving only progesterone, suggesting that estrogen acts directly on the embryo. This raises the question of whether the estrogens could also have a direct effect on the embryo’s development.
To our knowledge, there is no report on the effect of progesterone and estrogen in the culture medium on gastrulation rabbit in vitro development from 6d.p.c till 9d.p.c.
Therefore, this study was carried out to investigate the effect of serum pregnancy does rabbit supplementation in culture medium on in vitro development of pre-implantation rabbit embryos. In order to know the possible effects of hormonally active agents on developing animals.
MATERIALS AND METHOD
Animals:
All experimental procedures involving animals were approved by the Research Ethics Committee of the UPV and licensed by European Community Directive 86/609/EC. Rabbit does used as donors and recipients belonging to the New Zealand White line from the Instituto de Ciencia y Tecnología Animal (ICTA) at the Universidad Politécnica de Valencia (UPV).
Embryo collection and treatment
Donor does were artificially inseminated with pooled sperm from fertile males and slaughtered at 6 days of pregnancy. Eighty four embryos were recovered by perfusion of each oviduct and uterine horn with 20 mL pre-warmed Dulbecco Phosphate Buffered Saline (DPBS) supplemented with 0.2% of Bovine Serum Albumin (BSA). The blastocysts were randomly distributed in round-bottomed microwell plates (Nunc, Roskilde, Denmark) with 750 uL of two mediums. The control medium was TCM-199 with 25mM Hepes buffer and antibiotics (100 IU of G sodium penicillin and 25ug per mL of dihydrostreptomycin). The second medium contained the same components as above described, but supplemented with 10% of rabbit serum (v/v); pre-filtered in a 0.2 µm pore diameter (TCM-199+S). The microwell plates were kept under a humified atmosphere of 5% CO2 at 38°C.
Serum preparation
Whole blood was collected with the aid of a Vacutainer-heparin tube (LH/Li Heparin Tube TAPVAL®, MonLab, SL. Barcelona, Spain) from 6 day-old blastocyst donor does. Blood was centrifuged (1500 g, 10 min at 4ºC) and sera were detoxified at 56 °C for 30 minutes before frozen and stored at -80 °C. Serum levels of progesterone (steroid C21, preg-4-ene-3,20-dione) and 17β-estradiol were determined by direct enzyme immunoassay technique following the manufacturer’s instructions (Rabbit Progesterone Elisa Test, Endocrine Technologies, Inc. Newark, USA and Estradiol Elisa Ultra-Sensitive Kit, DRG International, Inc. Marburg, Germany). Sensitivities of the tests used were 0.1 ng/ml for progesterone and 1.4 pg/ml for 17β-estradiol). Estrogen and progesterone levels of serum was measured by the final concentration of 17β-estradiol 20 pg/ml and progesterone was 9 ng/ml.
Morphometry and gastrulation analysis
Embryos were morphological evaluated every 24 hours for their developmental progression during the in vitro culture, images of embryo and gastrula were recorded using stereo-zoom microscope (Nikon SMZ-1500) associated to photograph chamber (Nikon DS-U1) and software (Nikon ACT-2U). Qualitative variables such as gastrulation stage and viability were noted. Only hatched or collapsed embryos were stained with a differential vital dye (propidium iodide and SYBR-14, -Life technologies inc-), all collapsed embryos were died and all hatched were alive).
Gastrulation stages were assigned according to the cataloguing made by Viebahn (2004), Blum et al., (2007) and Hassoun et al., (2010). Gastrulation stages between 3 and 4+ were grouped together because both stages correspond with the beginning of the formation of gastrulation (early stage) and the stages 5-, 5+, 6-, 6+ and 7 were grouped as one considering them and advanced gastrulation development (late stage).
Statistical analysis
Data was statistically analyzed using the SPSS program for windows (SPSS, 2006). A Chi-Square Test was used to analyze the effect of serum does rabbit on the viability and gastrula stages development rates according to Snedcore and Cochran (1982). Independent-Samples T-Test was used to compare measurements of embryos and gastrula cultured with or without serum doe rabbits. The statistical significance was considered at P<0.05.
RESULTS AND DISCUSSION
Three days of in vitro culture to study the viability rate, measurements and stages as a key event at the start of gastrulation were chosen. The viability rates were improved according to serum pregnancy does additive to culture media but with no significant effect (Table 1). The development of embryos and fetuses is influenced by circulating levels of progesterone, particularly during the pre and pre-implantation period. The mechanism by which this occurs is unclear but probably does not involve a classic, direct effect of progesterone on the developing embryo (Farin et al., 2000).Some of progesterone is picked up by the fetal circulation and used as substrate for fetal corticosteroids. The increasing of the viability according to increase of metabolic rate and energy of embryos as a result of the ratio of steroids hormones in the serum, are agreement with (Satterfield et al. 2006 and McNeill et al., 2006) The importance of progesterone levels in the immediate post-conception period (days 4–7) depends on subsequent pregnancy maintenance. In addition, progesterone is a highly potent antagonist of the mineralocorticoid receptor (receptor for aldosterone and other mineralocorticosteroids), Rupprecht et al., (1993). Progesterone has a number of physiological effects that are amplified in the presence of estrogen. Estrogen through estrogen receptors upregulates the expression of progesterone receptors (Kastner et al., 1990). Also, progesterone prevent the apoptosis while progesterone and estrogen play as antioxidation.
The increased of the viability was associated with the increased of blastocysts and gastrula size (area and perimeter) of treated group than the control group (Table 2), but the significant increased (P˂0.05) was observed at 48h of culture for blastocysts (area 22.57µm, perimeter 16.64µm) and gastrula (area 1.62µm, perimeter 4.8µm) than the non treated group blastocysts (area 12.95 µm, perimeter 12.53 µm) and gastrula (area 0.89 µm, perimeter 3.26µm). The results indicated that a decline in the number of
Table 1: Compared between control and serum supplementation in vitro culture on the viability rate.
|
Treatment |
Initial No. |
Viability rate, % (n) |
||
|
24h |
48h |
72h |
||
|
Control |
37 |
48.6 (18) |
24.3 (9) |
10.8 (4) |
|
Serum |
47 |
66.0 (31) |
42.6 (20) |
25.5 (12) |
Control TCM199 culture, Serum: TCM199+ serum does rabbits.
Table 2: Embryos and gastrula dimension in vitro as affected by additive serum does on culture media for three days of culture (Means ± SE).
|
Culture time |
Treatment |
N |
Embryo (Means ± SE) µm |
Gastrula (Means ± SE) µm |
||
|
Area |
Perimeter |
Area |
Perimeter |
|||
|
0h |
Control |
37 |
7.44 ± 0.50 |
9.59 ± 0.40 |
0.96 ± 0.07 |
3.60 ± 0.18 |
|
Serum |
47 |
8.62 ± 0.38 |
10.18 ± 0.25 |
0.94 ± 0.06 |
3.42 ± 0.12 |
|
|
24h |
Control |
18 |
14.17 ± 1.32 |
13.16 ± 0.63 |
1.52 ± 0.19 |
4.30 ± 0.31 |
|
Serum |
31 |
16.01 ± 0.92 |
14.06 ± 0.41 |
1.49 ± 0.12 |
4.44 ± 0.18 |
|
|
48h |
Control |
9 |
12.95a ± 1.51 |
12.53a ± 0.81 |
0.89a ± 0.21 |
3.26a ± 0.37 |
|
Serum |
20 |
22.57b ± 1.86 |
16.64b ± 0.76 |
1.62b ± 0.21 |
4.80b ± 0.36 |
|
|
72h |
Control |
4 |
14.60 ±1.35 |
13.53 ±0.62 |
2.107 ±0.73 |
3.417 ±1.73 |
|
Serum |
12 |
18.04 ±9.92 |
14.62 ±4.10 |
1.767 ±0.89 |
4.307 ±1.79 |
|
Control TCM199 culture, Serum: TCM199+ serum does rabbits.
Values with different letters in the same column are significantly different (P<0.05).
culture embryos to 4 in control group and 12 in treated group at 72h. The lost of biggest embryos may be attributed to more sensitive and explosion neozona with any touch, for with insignificant differences between the two groups with stay the numerically (4 vs. 12) and dimension (14.60 vs. 18.04 µm) of control group and treated group, respectively.
Early embryonic development seems to be particularly susceptible to the effects of progesterone, administration of supplemental progesterone to bovine females between day 1 and 6 after breeding resulted in conceptuses that were significantly lengthened compared to controls (Garrett et al., 1988). Fetuses resulting from embryos exposed to exogenous progesterone between day 1 and 3 or 1 and 6 of gestation were significantly larger at midgestation than untreated controls (Kleemann et al., 1994). Progesterone treatment between day 1 and 3 of gestation was also associated with an increase in the proportion of embryos with blastomeres on day 3 of gestation (Walker et al., 1996).
The additive of serum pregnancy does to culture media increased significantly (P˂0.05) on development rate of gastrula to reached advanced stage more than the non-treated group after 48h and 72h (Table 3). After 48h of culture 64.5% of gastrula reached to stage (5-7). As a result of gastrulation the notochordal process begins to emerge from Hensen’s node along the anterior midline of the embryonic disc (Fig 1) and, in parallel, the anterior half of embryonic disc begins to elongate along the anterior-posterior axis to accommodate the neural plate as the first step of neurulation.
Table 3: Gastrula stages development as affected by additive serum pregnancy does rabbit on culture media for three days of culture.
|
Culture time |
Treatment |
N |
Gastrula stages (from 3to 7), % |
Collapsed embryos (died embryos) |
|
|
Category 3-4 |
Category 5-7 |
||||
|
24h |
Control |
37 |
100 (37) |
0 (0) |
0% (0/37) |
|
Serum |
47 |
100 (47) |
0 (0) |
0% (0/47) |
|
|
48h |
Control |
18 |
77.8a (14) |
22.2a (4) |
37.8% (14/37) |
|
Serum |
31 |
35.5b (11) |
64.5b (20) |
31.9%(15/47) |
|
|
72h |
Control |
9 |
44.4a (4) |
55.6a (5) |
54.0% (20/37) |
|
Serum |
20 |
0b (0) |
100b (20) |
48.9%(23/47) |
|
Control TCM199 culture, Serum: TCM199+ serum does rabbits.
Values with different letters in the same column are significantly different (P<0.05).
The increasing length of the notochordal process can be determined easily in dorsal views during early neurulation and is, therefore, used here to divide the beginning of neurulation into 3 stages: Stage 5 covers the period after the first and prechordal mesoderm cells leave Hensen’s node (end of stage 4) until the notochord acquires the same length as the primitive streak; during stage 6, the notochordal process elongates further and its posterior part becomes nearly twice as wide as its anterior part; this is in contrast to the posterior half of the embryonic disc which becomes narrower than its anterior half, and at stage 7, the first somites start to form on either side about equidistantly from the two extremities of the notochordal process, i.e. next to the anterior extremity of the posterior, wide part of the notochordal
(A) (B) (C) (D)
(E) (F) (G) (H)
Figure 1. Early gastrulation stages of the rabbit embryo in control and serum treated group. (A) control group, (E) serum treated group whole blastocyst at a pre-primitive streak stage (6d.p.c.); the plane of focus is on the blastocyst wall containing the embryonic disc, (B) control group, (F) serum treated group with primitive streak (s) 7 d.p.c. in the midline of the PGE. The former posterior margin is still visible (arrows). (C) Control group, (G) serum treated group in late stage 4 with node fully formed and strong Brachyury expression along the entire primitive streak at 8d.p.c. (D) Control group, (H) serum treated group 9 d.p.c Stage 5 and 6 with Brachyury expression also in notochordal process. Scale bars: 250 mm.
process (Hassoun et al 2010). After 72h of culture 100% of gastrula reached to stages (5- 7) and 65.5% reached to stages (5-7) after 48h in treated group, while only 22.2 % reached to stages (5-7) at 48h of culture and 55.6% reached to (5-7) after 72h of culture in control group. That it may be to the effect of esetroids hormone which increased the metabolic rate.
Differences in the distribution of cells to the inner cell mass vs. trophoblast in embryos may also occur as a result of progesterone treatment (Walker et al., 1996).The mechanisms through which pre-implantation concentrations of progesterone regulate embryo survival and growth are not well investigated but are thought to be mediated by secretions from the endometrium.
Conclusively, current research is focused upon understanding the importance of progesterone and estrogen levels mechanisms that enable the early embryo to initiate its normal developmental program. The effect of 17β-estradiol 20 pg/ml and progesterone 9ng/ml on morphogenesis and development gastrula rabbit in vitro culture was clear on the numerical blastocyst viability, dimension and development rate. It should help to better define the limits of the early mammalian embryo developmental autonomy and is necessary to design healthier in vitro conditions, and perhaps to the development of new strategies to modify individual phenotypes.
REFERENCES
Crosier, A.E.; Farin, P.W.; Alexander, J.E.; and Farin, C.E. (2000). Ultrastructural morphometry of bovine compact morula produced in vivo or in vitro. Biol. Reprod. , 62,1459-1465.
Blum, M.; Andre, P.; Muders, K.; Schweickert, A.; Fischer, A.; Bitzer, E.; Bogusch, S.; Beyer, T.; van Straaten, H.W.M. and Viebahn, C. (2007). Ciliation and gene expression distinguish between node and posterior notochord in the mammalian embryo. Differentiation, 75, 133–146.
Farin, C.E.; Farin, P.W.; Blondin, P. and Crosier, A.E. (2000). Function fetal development of in vitro-produced embryos: Possible association with uterine. J. ANIM. SCI., 77, 1-16.
Fuchs, A.R. and Beling, C. (1974). Evidence for early ovarian recognition of blastocysts in rabbit. Endocrinology, 95, 1054-1058.
Garrett, J.E.; Geisert, R.D.; Zavy, M.T. and Morgan, G.L. (1988). Evidence for maternal regulation of early conceptus growth and development in beef cattle. J. Reprod. Fertil., 84, 437-447.
Halacheva, V.; Fuchs, M.; Donitz, J.; Reupke, T.; Puschel, B. and Viebahn, C. (2011). Planar cell movements and oriented cell division during early primitive streak formation in the mammalian embryo. Developmental Dynamics, 240, 1905–1916.
Hamburger, V. and Hamilton, H.L. (1992). A series of normal stages in the development of the chick embryo. 1951. Developmental Dynamics, 195, 231–272.
Kastner, P.; Krust, A.; Turcotte, B.; Stropp, U.; Tora, L.; Gronemeyer, H. and Chambon, P. (1990). Two distinct estrogen-regulated promoters generate transcripts encoding the two functionally different human progesterone receptor forms A and B. EMBO Journal, 9-5, 1603–14.
Kleemann, D.O.; Walker, S.K. and Seamark, R.F. (1994). Enhanced fetal growth in sheep administered progesterone during the first three days of pregnancy. J. Reprod. Fertil. , 102, 411-417.
Labrie, F.; Luue-The, V.; Lin, S.X.; Simard, J.; Labrie, C.; El-Alfy, M.; Pelletier, G. and Belanger, A. (2000). Intracrinology: role of the family of 17b-hydroxysteroid dehydrogenases in human physiology and disease. Journal of Molecular Endocrinology, 25, 1–16.
Mc-Neill, R.E.; Sreenan, J.M.; Diskin, M.G.; Cairns, M.T.; Fitzpatrick, R.; Smith, T.J. and Morris, G. (2006). Effect of systemic progesterone concentration on the expression of progesterone-responsive genes in the bovine endometrium during the early luteal phase. Reprod Fertil Dev.; 1-85, 573-83.
Romia, H.; Bernd, P. and Christoph, V. (2010). Sox 17 Expression Patterns during Gastrulation and Early Neurulation in the Rabbit Suggest Two Sources of Endoderm Formation, Cells Tissues Organs, 191, 68–83
Rossant, J. (2011). Developmental biology: a mouse is not a cow. Nature, 471, 457–458.
Rupprecht, R.; Reul, J.M.; Trapp, T.; Van Steensel, B.; Wetzel, C., Damm, K.; Zieglgänsberger, W. and Holsboer, F. (1993). Progesterone receptor-mediated effects of neuroactive steroids. Neuron. Sep , 11- 3, 523-30.
Safro, E.; O’Neill, C. and Saunders, D.M. (1990). Elevated luteal phase estradiol: progesterone ratio in mice causes implantation failure by creating a uterine environment that suppresses embryonic metabolism. Fertility and Sterility , 54, 1150–1153.
Satterfield, M.C.1.; Bazer, F.W. and Spencer, T.E. (2006). Progesterone regulation of preimplantation conceptus growth and galectin 15 (LGALS15) in the ovine uterus. Biol Reprod. Aug., 75-2, 289-96
Schafer-Haas, A. and Viebahn, C. (2000). The term cell epitope PG-2 is expressed in primordial germ cells and in hypoblast cells of the gastrulating rabbit embryo. Anat. Embryol. (Berl). 202, 113-23.
Singh, M.M. and Adams, C.E. (1978). Luteotropic effect of the rabbit blastocyst. J. Reprod. Fert., 53, 331-333.
Snedecor, G. W. and Cochran, W. G. (1982). Statistical Methods. 6th 374 ed. Iowa State Univ. Press, Ames, U.S.A.
SPSS (2006). Command Syntax Reference. Version 15. SPSS Inc., Chicago Ill., USA.
Viebahn, C.; Mayer, B. and Miething, A. (1995). Morphology of incipient mesoderm formation in the rabbit embryo: a light- and retrospective electron-microscopic study. Acta Anat., 154, 99–110.
Viebahn, C. (2001). Hensen's node. Genesis., 29- 2, 96-103. Review.
Viebahn, C. (2004). Gastrulation in the rabbit; in Stern, C.D.S. (ed): Gastrulation. Cold Spring Harbor, Cold Spring Habor Laboratory Press, pp 263–274.
Viebahn, C.; Stortz, C.; Mitchell, S.M. and Blum, M. (2002). Low proliferative and high migratory activity in the area of Brachyury expressing mesoderm progenitor cells in the gastrulating rabbit embryo. Development ,129, 2355 – 2365.
Walker, S.K.; Hartwich, K.M. and Seamark, R.F. (1996). The production of unusually large offspring following embryo manipulation: concepts and challenges. Theriogenology, 45, 111-120.
تأثیر إضافة کلا من هرمونی البروجستیرون و الأستروجین فی بیئة الاستزراع علی تحثین jedv تالتغیرات الشکل المورفلوجی و معدلات نمو أجنة الأرانب
المحضنة معملیا فی مرحلة ما قبل تکون الجاسترولا
أیمن مصطفى سعید
قسم التکنولوجیا الحیویة، معهد بحوث الإنتاج الحیوانی، الدقى، الجیزة، مصر.
تهدف هذه الدراسة إلی مقارنة الدور الحیوی والعلاقة بین نسبة هرمونی البروجستیرون والأستروجین الموجود فی سیرم أمهات أرانب وحیویة أجنة الأرانب وما یترتب علیة من استمرار الحمل أو فقد الأجنة قبل عملیة الأنغراس. ومن هنا تم تصمیم التجربة معملیا بتحضین أجنة أرانب مجموعة قبل مرحلة الأنغراس وإضافة هرمونی البروجستیرون والأستروجین الموجود فی سیرم أمهات أرانب علی بیئة التحضین الأجنة المجمعة فی مرحلة ما قبل الجاستیرولا.
تمت الدراسة علی 48 جنین مجمعة فی عمر 6 أیام من التلقیح و تم تحضنها لمدة ثلاث أیام معملیا تحت درجة حرارة 39م ورطوبة 100% و نسبة 5% ثانی أکسید الکربون. قسمت هذه الأجنة إلی مجموعتین:
المجموعة الأولى: control بیئة الزراعة المعتادة TCM 199بدون إضافات.
المجموعة الثانیة: وبها تم إضافة سیرم الأرانب الحوامل بمعدل 10% حجم / حجم وکان الترکیز النهائی لهرمونی البروجسترون 9x10-6mg/ml والاستیروجین 20x10-9mg/ml وذلک لمدة ثلاثة أیام.
و قد أظهرت النتائج المتحصل علیها ما یلی:
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