Developmental morphology of the neonatal alligator (Alligator mississippiensis) ovary

American alligator (Alligator mississippiensis) ovary development is incomplete at hatching. During the months following hatching, the cortical processes of oogenesis started in ovo continues and folliculogenesis is initiated. Additionally, the medullary region of the gonad undergoes dramatic restructuring. We describe alligator ovarian histology at hatching, 1 week, 1 month, and 3 months of age in order to characterize the timing of morphological development and compare these findings to chicken ovary development. At hatching, the ovarian cortex presents a germinal epithelium containing oogonia and a few primary oocytes irregularly scattered between somatic epithelial cells. The hatchling medulla shows fragmentation indicative of the formation of lacunae. By 1 week of age, oocytes form growing nests and show increased interactions with somatic cells, indicative of the initiation of folliculogenesis. Medullary lacunae increase in diameter and contain secretory material in their lumen. At 1 month, nest sizes and lacunar diameters continue to enlarge. Pachytene oocytes surrounded by somatic cells are more frequent. Trabeculae composed of dense irregular connective tissue divide cortical nests. Three months after hatching oocytes in meiotic stages of prophase I up to diplotene are present. The ovary displays many enlarged follicles with oocytes in diplotene arrest, thecal layers, lampbrush chromosomes, and complete layers of follicular cells. The medulla is an elaborated complex of vascularized lacunae underlying the cortex and often containing discrete lymphoid aggregates. While the general morphology of the alligator ovary is similar to that of the chicken ovary, the progression of oogenesis and folliculogenesis around hatching is notably slower in alligators. Diplotene oocytes are observed at hatching in chickens, but not until 3 months in alligators. Folliculogenesis is completed at 3 weeks in chickens whereas it is still progressing at 3 months in alligators.     

Immunohistochemical detection of estrogen receptor alpha in the growing and regressing ovaries of newly hatched chicks

The aim of this study was to detect the presence of estrogen receptor alpha in different cell subpopulations of the growing left and regressing right ovaries from newly hatched chicks, by immunohistochemical methods, using an indirect immunoperoxidase technique. Newly hatched chicks were killed by decapitation and the growing left and regressing right ovaries were removed and processed for histological and immunohistochemical studies. The percentage of estrogen receptor alpha (ER) immunostained cells and the staining intensity were determined. Histological results demonstrated that the right ovary lacks cortex and is constituted by the medullary region, whereas the left ovary is composed by cortical and medullary compartments. The medullary region is similar in both ovaries and presents the same elements. Immunohistochemical analysis revealed ER-positive cells in the left ovary, located in the nucleus of all cell subpopulations; in contrast, in the right ovary, only epithelial cells of the lacunar channels depicted estrogen receptors. The present findings indicate a cell-specific localization of ER in left and right ovaries of newly hatched chick.     

Immunohistochemical detection of insulin-like growth factor-I, transforming growth factor-beta2, basic fibroblast growth factor and epidermal growth factor-receptor expression in developing rat ovary

The aim of this study was to determine the immunohistochemical expression and localization of insulin-like growth factor-I (IGF-I), transforming growth factor-β2 (TGF-β2), basic fibroblast growth factor (bFGF) and epidermal growth factor-receptor (EGF-R) in developing rat ovaries.Eighteen female Wistar rats were enrolled in this study; newborn (n = 6), one-month-old (n = 6) and adult (n = 6) rats. Formalin-fixed and parafin-embedded ovarian tissues were stained with antibodies against IGF-I, TGF-β2, bFGF and EGF-R, immunohistochemically. The ovarian cells were evaluated by semi-quantitative scoring system under light microscope.The staining of IGF-I, TGF-β2, bFGF and EGF-R were most intense in the oocytes and were heavily at one-month-old rats. A moderate immunostaining in theca cells and corpus luteii reacted with IGF-I in adult rats. Furthermore the staining intensity for IGF-I was moderate in granulosa cells of newborn rat ovaries. We detected also a moderate staining for TGF-β2 in corpus luteii of adult rats. In addition, we found a bFGF immunostaining mainly in oocytes of follicles of young and adult rats. Immunostaining for EGF-R was moderate in granulosa cells of one-month-old rats.In conclusion, this study suggests that growth factors play a pivotal role in ovarian function, especially in follicular development. The role of growth factor in controlling degeneration or growth (or both) of ovary follicles remain as explained.     

Differentiation and function of the ovarian somatic cells in the pseudoscorpion,Chelifer cancroides (Linnaeus, 1761) (Chelicerata: Arachnida: Pseudoscorpionida)

Pseudoscorpion females carry fertilized eggs and embryos in specialized brood sacs, where embryos are fed with a nutritive fluid produced and secreted by somatic ovarian cells. We used various microscopic techniques to analyze the organization of the somatic cells in the ovary of a pseudoscorpion, Chelifer cancroides. In young specimens, the ovary is a cylindrical mass of internally located germline cells (oogonia and early previtellogenic oocytes) and two types of somatic cells: the epithelial cells of the ovarian wall and the internal interstitial cells. In subsequent stages of the ovary development, the oocytes grow and protrude from the ovary into the hemocoel (opisthosomal cavity). At the same time the interstitial cells differentiate into the follicular cells that directly cover the oocyte surface, whereas some epithelial cells of the ovarian wall form the oocyte stalks – tubular structures that connect the oocytes with the ovarian tube. The follicular cells do not seem to participate in oogenesis. In contrast, the cells of the stalk presumably have a dual function. During ovulation the stalk cells appear to contribute to the formation of the external egg envelope (chorion), while in the post-ovulatory phase of ovary function they cooperate with the other cells of the ovarian wall in the production of the nutritive fluid for the developing embryos.     

Origin and differentiation of the endocrine cells of the ovary

A large proportion of the somatic cells of the developing ovaries of mouse, human and rabbit stems from the mesonephric tissue. In the immature mouse ovary and in the 19-day-old fetal rabbit ovary, the first steroid-producing cells differentiate among the mesonephric-derived cells within the ovary. In the fetal human ovary, the first steroid-producing cells arise in the inner part of the cortex and differentiate concomitantly with the formation of small follicles. The origin of the early steroid-producing cells in the human ovary is still uncertain. During early ovarian development, formation and further differentiation of the steroid-producing interstitial cells seem to continue only in areas devoid of free viable germ cells.     

Transforming growth factor beta inhibits proliferation of somatic cells without influencing germ cell number in the chicken embryonic ovary

The gonadal development of chicken embryo is regulated by hormones and growth factors. Transforming growth factor beta (TGF-β) isoforms may play a critical role in the regulation of growth in chicken gonads. We have investigated the effect of the TGF-β isoforms on the number of germ and somatic cells in the ovary of the chicken embryo. Ovaries were obtained from chicken embryos at 9 days of incubation. They were organ-cultured for 72 h in groups treated with TGF-β1, TGF-β2, soluble betaglycan, TGF-β1 plus soluble betaglycan, or TGF-β2 plus soluble betaglycan, and untreated (control). TGF-β1 and TGF-β2 diminished the somatic cell number in the ovary of the chicken embryo at this age by inhibiting the proliferation of the somatic cells without increasing apoptosis. On the other hand, TGF-β1 and TGF-β2 did not affect the number of germ cells in the cultured ovary. The capacity of TGF-β1 and TGF-β2 to diminish the number of somatic cells in the ovary was blocked with soluble betaglycan, a natural TGF-β antagonist. However, changes in the location of germ cells within the ovary suggested that TGF-β promoted the migration of the germ cells from the ovarian cortex to the medulla. Thus, TGF-β affects germ and somatic cells in the ovary of the 9-day-old chicken embryo and inhibits the proliferation of somatic cells.This work was supported by DGAPA-UNAM (IN214403) and CONACYT (45030).     

Estradiol secretion by the ovary of 19-day-old hypophysectomized and sham-operated chick embryos

The amounts of estradiol released into culture media by ovaries from 19-day-old hypophysectomized (decapitated) and sham-operated chick embryos were determined by RIA. Per single ovary, ovaries from decapitated embryos secreted slightly less estradiol than ovaries from sham-operated ones during a 4-h culture period (837 +/- 413 vs 935 +/- 378 pg), but this difference was not significant. On an ovarian weight basis, ovaries from decapitated embryos secreted slightly more estradiol than ovaries from sham-operated ones (1.15 vs 0.91 ng), but this difference was not significant either. It is concluded from these results that the hypophysis does not control estradiol secretion by the ovary in the 19-day-old chick embryo.     

Expression of endogenous avian myeloblastosis virus information in different chicken cells.

Uninfected chicken cells were found to contain endogenous avian myeloblastosis virus (AMV)-specific information. Different tissues from chicken embryos and chickens expressed different amounts of the AMV-specific information. The endogenous AMV-related RNA was most abundant in bone marrow cells, which contained about 20 copies per cell. About 5 to 10 copies of AMV endogenous RNA per cell were found in embryonic yolk sac cells and bursa cells. The spleen, muscle, liver, and kidney cells of chickens and the fibroblasts of chicken embryos contained about two copies per cell. The amounts of AMV endogenous RNA in bone marrow, yolk sac, and bursa varied with age. From 19-day-old embryos to 2-week-old chickens, the bone marrow contained 20 copies of AMV RNA per cell. Bone marrow cells from 2-year-old chickens contained five copies per cell. Yolk sac cells of 10-day-old embryos and 1-day-old chickens were found to contain two copies per cell, whereas in 15- to 17-day-old embryos, these cells contained 5 to 10 copies. These results indicate that the level of endogenous AMV expression correlates with the development of granulopoiesis of the chicken hemopoietic system. The results of experiments on the thermostability of RNA-DNA hybrids indicated that the endogenous AMV RNA is closely related to viral AMV RNA. The expression of endogenous AMV information is independent of the activity of the chick helper factor. This endogenous AMV information is expressed as 20 to 21S RNA in both bone marrow and yolk sac cells.     

Ovarian morphology and folliculogenesis and ovulation process in the flat-faced fruit-eating bat Artibeus planirostris and the Argentine brown bat Eptesicus furinalis: A comparative analysis

The Neotropical bat species Artibeus planirostris and Eptesicus furinalis present a different morphology of the female reproductive organs: the first presents a simplex uterus, while the second presents a bicornuate uterus, but there is no information about their ovaries. Our aim was to compare the general ovary morphology and the folliculogenesis process in these species to increase the knowledge about the reproductive diversity of tropical bats. We observed a morphological distinction between the ovaries of both species: A. planirostris presents the primordial follicles located in a cranial portion of the ovary and the interstitial gland cells are not distinctive, while in E. furinalis, the primordial follicles are located throughout the cortex, and there is an abundance of interstitial gland cells. Both species present binovular or triovular follicles. Artibeus planirostris is a monovular species, with a preferential ovulation in the left side. Some females of E. furinalis exhibited two corpora lutea in the same ovary, and others presented a corpus luteum in both right and left ovaries at the same time; thus, E. furinalis is a polyovular species. Our results express the variation between two Neotropical species, reflecting the great variation in the reproductive aspects in Chiroptera.     

Ontogenesis of the ovary in a moth midge,Tinearia alternata Say (Diptera: Psychodidae)

In a psychodid, Tinearia alternata, the initial differentiation of the polytrophic ovary occurs during the early larval stages. Early in development, each ovary anlage is a solid organ subdivided into three distinct zones: the cortex houses germ cells and somatic interstitial tissue, while two other somatic regions will give rise to the oviduct calyx and anterior part of the lateral oviduct. Germ cell cluster formation precedes the development of ovarioles. Each ovariole houses only one functional egg chamber. All ovarioles within paired ovaries are developmentally synchronized. In the larval ovaries, the newly formed egg chambers and then the ovarioles are intermingeled with and surrounded by the somatic interstitial tissue of the ovary cortex. The interstitial cells give rise to all the somatic elements of the ovarioles. In the pupal ovaries, the remaining interstitial tissue degenerates; thus, the ovarioles protrude into the body cavity. The ovaries in psychodids develop relatively large and swollen oviduct calyxes that are equivalent to receptaculum seminis (spermatheca). The morphological differentiation of germ cells within the egg chambers starts during late larval/early pupal stages. Nurse cell nuclei contain prominent nucleoli and polytene chromosomes. Oocyte growth results from accumulation of yolk and then, in the final stages of oogenesis, from an inflow of cytoplasm from the nurse cells. J. Morphol. 236:167–177, 1998. © 1998 Wiley-Liss, Inc.     

Adaptations for matrotrophy in the female reproductive system in the pseudoscorpion Chelifer cancroides (Chelicerata: Pseudoscorpiones,Cheliferidae)

Pseudoscorpiones (pseudoscorpions, false scorpions) is an order of small terrestrial chelicerates. While most chelicerates are lecithotrophic, that is, embryos develop due to nutrients (mostly yolk) deposited in the oocyte cytoplasm, pseudoscorpions are matrotrophic, that is, embryos are nourished by the female. Pseudoscorpion oocytes contain only a small amount of yolk. The embryos develop within a brood sac carried on the abdominal site of the female and absorb nutrients by a pumping organ. It is believed that in pseudoscorpions nutrients for developing embryos are produced in the ovary during a postovulatory (secretory) phase of the ovarian cycle. The goal of our study was to analyze the structure of the female reproductive system during the secretory phase in the pseudoscorpion Chelifer cancroides, a representative of the family Cheliferidae, considered to be one of the most advanced pseudoscorpion taxa. We use diverse microscopic techniques to document that the nutritive fluid is produced not only in the ovaries but also by the epithelial cells in the oviducts. The secretory active epithelial cells are hypertrophic and polyploid and release their content by fragmentation of apical parts. Our observations also indicate that fertilization occurs in the oviducts. Moreover, in contrast to previous findings, we show that secretion of the nutritive material starts when the fertilized oocytes reach the brood sac and thus precedes formation of the pumping organ. Summing up, we show that C. cancroides exhibits traits of advanced adaptations for matrotrophy due to coordinated secretion of the nutritive fluid by the ovarian and oviductal epithelial cells, which substantially increases the efficiency of nutritive fluid formation. Since the secretion of nutrients starts before formation of the pumping organ, we suggest that the embryos are able to absorb the nutritive fluid also in the early embryonic stages.     

A new route of prostaglandin F-2α transfer from the uterus into the ovary in swine

On day 14 of the oestrous cycle in swine, laparotomy under general anaesthesia was performed and both ovaries with their ovarian pedicles and with part of the uterine horns were isolated using ligatures and excised as two independent units which were called A and B. They were placed in separate aluminium paper boxes on a heated surface (40°C). Preparation A was supplied with autologous arterial blood through the uterine artery and through the ovarian artery. The mesosalpinx of this preparation covered the ovary of preparation B from which the mesosalpinx was excised. Preparation B was also supplied with autologous blood through the ovarian artery. Tritiated prostaglandin F-2α (³H-PGF-2α) was injected into the musculature of the uterine horn of preparation A and then both preparations were perfused with blood of the same animal for 30 min. ³H-PGF-2α was found in the ovarian venous blood, interstitial fluid, and ovarian and pedicle tissue of preparation B. The data indicate an extravascular penetration of ³H-PGF-2α into the ovary through the mesosalpinx.     

Genome-Wide Linkage Analysis Identifies Loci for Testicle and Ovary Traits in Chickens

Development of testes or ovaries is critical to chicken breeders. Understanding the genetic mechanisms influencing the development of the testes and ovaries could enhance selection efforts which target reproductive traits. The linkage analysis was conducted within an F2 population derived from Beijing-You chickens and a commercial broiler line. The results have identified one quantitative trait loci (QTL, designated T1) for bilateral testicular weight (TW) and the percentage of TW to carcass weight, and five QTLs (designated O1–O5) for ovary weight (follicle-free, OW) and the percentage of OW to carcass weight. For the testes traits, QTL T1 is located between 6.55 and 8.56 Mb on GGA13. Especially, the gene gamma-amino butyric acid A receptor, alpha 1 (GABRA1) located near the T1 peak. For ovarian traits, QTL O2 was located at 29.31 Mb on GGA7. G protein-coupled receptor 39 (GPR39) present at the O2 peak was expressed at higher levels within the reproductive tract. It is also involved in the regulation of several reproductive functions. Other QTL peaks and the genes’ function in the ovary and testes need to be evaluated. The QTLs and the genes identified in this study could provide valuable information for establishing reproductive traits in chickens, and need further investigation.     

Immunocytochemical studies of relaxin in ovaries of pregnant and cycling mice

Immunocytochemical staining for relaxin in ovarian sections of pregnant mice from day 11 through day 18 of gestation revealed that only corpora lutea (CL) of pregnancy are stained. Evaluation of serial sections of ovaries from a day 16 pregnant mouse revealed that the only luteal structures present are CL of pregnancy. The number of CL present in each ovary equaled the number of implantation sites in each related horn (7 on the right side and 8 on the left side). These large CL varied in shape, being round in some profiles to very elongate in others. All CL were immunochemically stained for relaxin using the peroxidase-antiperoxidase method of L. Sternberger (Immunocytochemistry, 2nd ed. Wiley, New York, 1979). The intensity of the strain varied from cell to cell within each CL. Small luteal structures that were observed to be immunochemically stained for relaxin were demonstrated to represent the periphery of CL of pregnancy. No luteinized follicles were observed and interstitial cells and follicles were not immunochemically stained in any of the day 16 serial ovarian sections or in any of the ovarian sections from pregnant mice on the other days of gestation studied. CL of previous cycles were not observed to be present in the ovaries at days 15, 16, or 18 of gestation. However on day 14 and before, CL of previous cycles were observed and they did not exhibit any relaxin immunostaining. Immunocytochemical studies using the biotin-avidin system revealed that no relaxin immunostaining could be demonstrated in the ovaries of cycling mice at any stage of the estrous cycle. In conclusion, this study revealed that the only ovarian structures demonstrating relaxin immunocytochemical staining in the mouse were CL of pregnancy.     

Ghrelin ovarian cell expression in patients with polycystic ovary syndrome: an immunohistochemical evaluation.

INTRODUCTION: The influence of ghrelin on different organs has been studied recently, e.g. in the regulation of pituitary hormone release, regulation of energy homeostasis, glucose metabolism and insulin secretion, cell proliferation, and reproductive function. However, the etiology of polycystic ovary syndrome has not been fully explained. The aim of our study was to estimate the presence of ghrelin in polycystic ovaries cells and evaluation of the relationship between ghrelin occurrence and cells proliferation. METHODS: In the present work we have compared ten polycystic ovaries with ovaries without pathology as the control group. We used immunohistochemical method to detect ghrelin. The cells proliferation was evaluated by Ki 67 proliferation index. RESULTS: Ghrelin immunostaining was demonstrated in cytoplasm of ovarian secondary interstitial cells and in atretic corpus luteum. The cell nuclei were ghrelin positive in granulosa, theca layers of follicular cyst in both groups as well as in luteal cells of young corpus luteum in healthy ovaries. Ki 67 immunostaining was observed in granulosa and theca layers of follicular cyst in polycystic and healthy ovaries. CONCLUSIONS: It is possible that local ghrelin expression plays an important role in the direct control of ovarian development and function and ghrelin may participate in patomechanism of PCOS.     

Effects of follicle-stimulating hormone and 17beta-estradiol on proliferation of chicken embryonic ovarian germ cells in culture

The effects of follicle-stimulating hormone (FSH) and 17beta-estradiol (E2) on chicken ovarian germ cell proliferation were evaluated through a germ-somatic cell coculture model. Ovarian cells from the left ovaries of 18-day-old chicken embryos were cultured in serum-free McCoy's 5A medium at 39 degrees C and challenged with FSH (0.25-1.0 IU/mL) or E2 (10(-8)-10(-5) M) alone and in combination for 48 h. The number of germ cells was counted, and the proliferating cells were immunolocalized by a specific antibody against proliferating cell nuclear antigen (PCNA). The labeling index (LI) was determined for germ cells. Results revealed that germ cells could survive and kept proliferating under support of somatic cells. Germ cells were localized by expression of a specific antibody for stem cell factor receptor c-kit. Both FSH (0.25-1.0 IU/mL) and E2 (10(-7)-10(-5) M) alone induced a marked increase in germ cell number (P<0.05), and PCNA-LI of germ cells was greater in FSH-treated groups (0.25-1.0 IU/mL) and E2-treated groups (10(-8)-10(-5) M), compared with vehicle-treated group (P<0.05). Furthermore, FSH manifested a synergistic effect with E2 (10(-6)-10(-5) M) in stimulating germ cell proliferation. These results indicate that FSH might interact with estrogen to promote ovarian germ cell proliferation in embryonic chickens near hatching.     

Effects of follicle-stimulating hormone and 17β-estradiol on proliferation of chicken embryonic ovarian germ cells in culture

The effects of follicle-stimulating hormone (FSH) and 17beta-estradiol (E2) on chicken ovarian germ cell proliferation were evaluated through a germ-somatic cell coculture model. Ovarian cells from the left ovaries of 18-day-old chicken embryos were cultured in serum-free McCoy's 5A medium at 39 degrees C and challenged with FSH (0.25-1.0 IU/mL) or E2 (10(-8)-10(-5) M) alone and in combination for 48 h. The number of germ cells was counted, and the proliferating cells were immunolocalized by a specific antibody against proliferating cell nuclear antigen (PCNA). The labeling index (LI) was determined for germ cells. Results revealed that germ cells could survive and kept proliferating under support of somatic cells. Germ cells were localized by expression of a specific antibody for stem cell factor receptor c-kit. Both FSH (0.25-1.0 IU/mL) and E2 (10(-7)-10(-5) M) alone induced a marked increase in germ cell number (P<0.05), and PCNA-LI of germ cells was greater in FSH-treated groups (0.25-1.0 IU/mL) and E2-treated groups (10(-8)-10(-5) M), compared with vehicle-treated group (P<0.05). Furthermore, FSH manifested a synergistic effect with E2 (10(-6)-10(-5) M) in stimulating germ cell proliferation. These results indicate that FSH might interact with estrogen to promote ovarian germ cell proliferation in embryonic chickens near hatching.     

Hypophysis and estradiol secretion in the chick embryo

Ovaries from 10- to 18-day-old chick embryos hypophysectomized by partial decapitation were cultured in vitro and their estradiol secretion was compared to that of ovaries from control embryos. The production of estradiol was not less in the decapitated than in the control embryos at 15-18 days, neither per ovary nor on the basis of ovarian weight. However, the difference was significant at 10-11 days. These results suggest that the hypophysis controls estradiol secretion by the chick embryo ovary in the early stages, but not in the later ones.     

The Capacity of Ovarian Cells of the Postnatal Rat to Reorganize into Histiotypic Structures

Cell-reorganization experiments in vitro were performed with dissociated rat ovaries at different ages of postnatal development, namely newborn, 8–10, 15–22, and 90-day-old. Ovarian cells consistently aggregated into follicularlike structures. Follicular organization in vitro is comparable to the ovarian histology of the respective age. The histogenic properties conserved by ovarian cells are considered to be related with the morphogenetic processes steadily occurring in the ovary.