Effects of oxygen tension and supplements to the culture medium on activation and development of bovine follicles in vitro

Our laboratory developed a method for culturing small pieces of bovine and baboon ovarian cortex, rich in primordial follicles, that supports the initiation of follicle growth and development to the primary stage. However, only a few follicles progressed to the secondary stage. The purpose of the current experiments was to determine if changes in culture conditions, specifically oxygen concentration and supplements to the culture medium, would facilitate the primary to secondary follicle transition. In Experiment 1, ovarian cortical pieces from late-gestation bovine fetuses were cultured with 2, 5, 20, or 60% oxygen in Waymouth's medium plus ITS+ (insulin, transferrin, selenium plus linoleic acid and BSA). Although the three lower concentrations of oxygen were generally equivalent in promoting follicle activation and growth, the highest concentration (60%) had deleterious effects on follicle survival after 7 days in culture, reducing the number of healthy follicles to about 35% of the number observed with 20% oxygen (P<0.05). In Experiment 2, bovine ovarian cortical pieces were cultured in the standard gas mixture (5% CO(2) in air) with graded doses of fetal bovine serum (FBS, 2.5, 5, or 10%) in the presence or absence of 0.5 or 1x ITS+. All concentrations of FBS alone were much less effective at maintaining follicular health and supporting the initiation and progression of follicular growth than was ITS+. However, 5 and 10% FBS alone increased the percentage of healthy primordial and primary follicles by about twofold (P<0.05) in the absence of ITS+ and in the presence of 0.5x ITS+, they enhanced the primary to secondary follicle transition by 10- and 9-fold, respectively. Thus, of the culture conditions evaluated, 20% oxygen and medium containing 0.5x ITS+ plus 5% or 10% FBS were the most effective for promoting follicular health and development.     

The capacity of primordial follicles in fetal bovine ovaries to initiate growth in vitro develops during mid-gestation and is associated with meiotic arrest of oocytes

In cattle and other species in which the pool of resting, primordial follicles is formed during fetal life, little is known about the regulation of the early stages of ovarian follicular development. We used histological morphometry and a combination of observations in vivo and experiments in vitro to study the timing and regulation of follicle formation and the acquisition of the capacity of primordial follicles to initiate growth in cattle. In vivo, primordial, primary, and secondary follicles were first observed around Days 90, 140, and 210 of gestation, respectively. The long interval between the first appearance of primordial and primary follicles suggests that primordial follicles are not capable of activating when they are first formed, or they are inhibited from activating. This hypothesis was confirmed by the finding that most primordial follicles in pieces of ovarian cortex obtained from fetal ovaries older than 140 days activated (i.e., initiated growth) after 2 days in vitro, whereas follicles in cortical pieces from 90- to 140-day-old fetal ovaries did not. We tested the hypothesis that the oocytes of newly formed primordial follicles are not in meiotic arrest and found that before Day 141, most oocytes ( approximately 73%) were in prediplotene stages of prophase I, whereas after Day 140, the majority of oocytes ( approximately 85%) had arrested at the diplotene stage. This observation was further confirmed by the finding that levels of mRNA for YBX2, a protein associated with meiotic arrest, were 2.3 times higher in ovarian cortical pieces isolated after versus before Day 141. Primordial follicles in cortical pieces from 90- to 140-day-old fetal ovaries did activate during a longer, 10-day culture, but activation could be inhibited by adding estradiol or progesterone, but not dihydrotestosterone (all at 10(-6) M). Fetal ovaries secreted estradiol in vitro, and secretion by ovaries from 83 to 140-day-old fetuses declined precipitously ( approximately 30-fold) with age, consistent with the hypothesis that estradiol inhibits activation of newly formed primordial follicles in vivo. In summary, the results show that newly formed primordial follicles do not activate in vivo or within 2 days in vitro and that capacity to activate is correlated with achievement of meiotic arrest by the oocyte and can be inhibited by estradiol, which fetal ovaries actively produce around the time of follicle formation.     

Activation of bovine and baboon primordial follicles in vitro

Mammalian ovaries contain a large pool of non-growing, primordial follicles. The ability to initiate growth of this pool of resting follicles in vitro and to maintain follicular growth to a stage when the oocyte could be matured and fertilized would increase the reproductive potential of valuable domestic animals, endangered species and infertile women. This paper summarizes our progress to date in activating primordial follicles of cattle and baboons. Pieces of ovarian cortex, rich in primordial follicles, were obtained from fetal bovine and baboon ovaries during late gestation. Pieces were maintained in organ culture in serum-free medium containing ITS+ (insulin-transferrin-selenium-linoleic acid-BSA) for up to 20 days and at various times during culture some pieces were fixed for histological morphometry. As early as 2 days of culture, the number of primordial follicles had decreased by 88% or 55%, whereas the number of primary follicles had increased 2.5- or 5-fold, compared to tissue freshly isolated from bovine or baboon ovaries, respectively (P < 0.01). In baboon cortical pieces a small number of secondary follicles developed during a 20-day culture period. The development of primary and secondary follicles was accompanied by an increase in diameter of both the granulosa cell layer and the oocyte. The addition of FSH (1, 10, or 100 ng/ml) had no effect on the development of follicles in bovine cortical pieces after 7 or 14 days of culture, relative to control cultures without FSH. These results show that a high percentage of primordial follicles from cattle and baboons can be activated to grow in serum-free medium in the absence of gonadotropins. Conditions that will support further growth in vitro of follicles from these species remain to be elucidated. The culture system we have developed could be used to develop such conditions and to explore factors that regulate the movement of primordial follicles into the pool of growing follicles.     

Effect of growth factors and co-culture with ovarian medulla on the activation of primordial follicles in explants of bovine ovarian cortex

It has been proposed that the ovarian medulla exerts an intra-ovarian inhibitory effect on primordial follicle activation in cattle. We tested this hypothesis using cortical ovarian explants and determined whether growth factors could alter follicle activation or primary follicle health. Ovaries were obtained from bovine fetuses, and cortical slices were cultured on Millicell culture inserts for up to 8 days. Within 2 d of culture, the proportion of primordial follicles decreased from 70.1 +/- 3.5 to 6.4 +/- 3.4% (P<0.05), and the proportion of primary follicles increased from 23.8 +/- 3.3 to 79.7 +/- 5.5% (P<0.05). The proportion of secondary follicles was relatively stable (6 to 13%). Morphological examination indicated that 91.9 +/- 3.7, 76.7 +/- 8.8, and 71.8 +/- 10.4% of primordial, primary, and secondary follicles, respectively, were considered to be healthy in slices of fresh tissue; these proportions were not altered by up to 8 d of culture (P>0.05). The proportion of all classes of follicles and their morphological health were not affected by the addition of medullary slices to the culture well, nor by the culture of corticomedullary slices (P>0.05). The addition of FSH, insulin-like growth factor-I, epidermal growth factor, basic fibroblast growth factor, or transforming growth factor-beta did not alter primordial follicle activation or the morphological health of primary or secondary follicles. The addition of transforming growth factor-alpha (TGFalpha) decreased the proportion of primary follicles that were healthy from 67.6 +/- 5.1 to 36.8 +/- 4.7% (P<0.05). In conclusion, these data do not support the existence of a medullary inhibitor of primary follicle activation but suggest a role for TGFalpha in the regulation of primary follicle development.     

The early stages of follicular development: activation of primordial follicles and growth of preantral follicles

Although enormous progress has been made in understanding the events and regulation of the later stages of ovarian follicular development, the early stages of development, to a large extent and particularly in large mammals, remain a mystery. Mechanisms that regulate the initiation of follicular growth (follicle activation) and the ensuing growth and differentiation of preantral follicles are of considerable interest, since their elucidation is a prerequisite to use of the primordial pool to enhance reproductive efficiency in domestic animals, humans, and endangered species. This review is an attempt to summarize the approaches that have been taken to further this goal and the results thus far of these efforts. Preantral follicular development can be divided into three stages: activation of primordial follicles, the primary to secondary follicle transition, and the development of secondary follicles to the periantral stage. The activation of primordial follicles in vitro has been achieved thus far in rodents, cattle, and primates, where it occurs spontaneously without the addition of growth factors or hormones. The ovaries of rodents are small enough to be cultured intact and, in that experimental situation, some follicles activate, while many remain in the resting pool, and the addition of specific factors can increase or decrease the number of follicles that leave the resting pool in vitro. In contrast, follicular activation in cattle and primates has been studied by culturing small pieces of the ovarian cortex, rich in primordial follicles, and the great majority of the primordial follicles activate in that situation, suggesting the importance of inhibitory factors to the normal, gradual exit of follicles from the resting pool. In cultured rodent ovaries, follicles appear to pass easily and spontaneously from the primary to the secondary stage, whereas few of the activated follicles in cultured cortical pieces from cattle or primates progress from the primary to the secondary stage. Understanding the requirements for the primary to secondary transition is critical for growing follicles activated in vitro to the late preantral and antral stages. In contrast, the requirements for the continued growth of larger preantral follicles, which can be isolated for in vitro studies, have been extensively explored in rodents and to a lesser extent in domestic species. A number of hormones and factors have been implicated and will be discussed. Taken together, the results highlight the need for a better understanding of the earliest stages of follicular development in domestic ruminants, particularly follicle activation and the primary to secondary follicle transition.     

Evidence for a role for anti-Mullerian hormone in the suppression of follicle activation in mouse ovaries and bovine ovarian cortex grafted beneath the chick chorioallantoic membrane

The first critical transition in follicular development, the activation of primordial follicles to leave the pool of resting follicles and begin growth, is poorly understood, but it appears that the balance between inhibitory and stimulatory factors is important in regulating the exodus of follicles from the resting pool. There is evidence that anti-Mullerian hormone (AMH; also known as MIS) inhibits follicle activation in mice, but whether it plays a similar role in non rodent species is not known. When pieces of bovine ovarian cortex, rich in primordial follicles, are cultured in serum-free medium, most follicles initiate growth, but when cortical pieces are grafted beneath the chorioallantoic membrane (CAM) of chick embryos, follicle activation does not occur. Since embryonic chick gonads of both sexes produce and secrete high levels of AMH, the hypothesis that the AMH in the chick circulation inhibits follicle activation was tested. In Experiment 1, whole newborn mouse ovaries were grafted beneath the CAM (placed "in ovo") or cultured in vitro for 8 days. In vitro (or after 8 days in vivo) follicles activated and proceeded to the primary or secondary stage, but activation was suppressed in ovo. This inhibition was reversed if ovaries were removed from beneath the CAM and cultured in vitro. In contrast, when ovaries from mice null mutant for the AMH type II receptor were CAM-grafted in Experiment 2, follicle activation occurred in a similar fashion to activation in vitro. This finding strongly implicates AMH as the inhibitor of follicle activation in ovo. Since chick embryonic gonads are the source of circulating AMH, chicks were gonadectomized in Experiment 3, prior to grafting of pieces of bovine ovarian cortex beneath their CAMs. Bovine primordial follicles activated in the gonadectomized chicks, similar to the results for mice lacking the AMH type II receptor. Taken together these experiments provide strong evidence that AMH is the inhibitor of mouse follicle activation present in the circulation of embryonic chicks and provide indirect, and hence more tentative, evidence for AMH as an inhibitor of bovine follicle activation.     

Ultrastructure and melatonin 1a receptor distribution in the ovaries of African ostrich chicks

Healthy 90-day-old ostrich chicks were used in the present study. The ultrastructure and melatonin 1a receptor (MT1) distribution in the ovaries of ostrich chicks was observed by transmission electron microscope and light microscope. The results showed that the ostrich chick ovary contained primordial follicles, primary follicles and secondary follicles, but no mature follicles. There are some unique ultrastructural characteristics observed in the secondary follicle, such as the cortical granule, which was located in cytoplasm beside the nucleus and appeared first in the oocyte. The zona radiata appeared in the secondary follicle, and there was an obvious vitelline membrane. There were intraovarian rete, connecting rete, and extraovarian rete in the ovaries of ostrich chicks. This is the first study that provides immunohistochemical evidence for the localization of the melatonin MT1 in the ostrich chick ovary. The germinal epithelium, follicular cell layer of every grade of follicle, cytoplasm of the oocyte and interstitial cells all expressed MT1. The expression of positive immunoreactivity materials was the strongest in the follicular cell layer of the primordial follicle and germinal epithelium, was weaker in the follicular cell layer of the primary follicle and secondary follicle, and was weakest in the oocytes of all grades of follicle. In addition, the extraovarian rete displayed strong positive expression of MT1, while there was no positive expression in the intraovarian rete or connecting rete. The positive expression of MT1 immunoreactivity in the ovary was very strong, implying that the ovary is an important organ for synthesizing MT1.     

Differential expression of ZPC in the bovine ovary,oocyte, and embryo

Using nonradioactive in situ hybridization (ISH), the mRNA encoding the zona glycoprotein bZPC was localized in bovine ovaries, oocytes, and embryos. In the ovary, the distribution of the mRNA was correlated with the developmental stage of the follicle. Whereas in primordial and primary follicles the mRNA was predominantly seen in the oocyte, it was found in both the oocyte and the follicle cells of secondary and tertiary follicles. In 2-day-old embryos produced by in vitro fertilization (IVF), no mRNA encoding ZPC could be demonstrated. Immunoblotting using monospecific polyclonal antibodies against porcine ZPC revealed a distinct band at a molecular weight of 47 kD in the ovarian cortex of cows, calves, and fetuses as well as in bovine follicle cells. Immunohistochemistry using the ZPC antibody displayed a strong signal in the zona pellucida of bovine oocytes and 2- to 6-day-old embryos as well as in the follicle cells. Our results show that during follicular development bovine ZPC is synthesized by the oocyte of the primary follicle and by both the oocyte and the follicle cells of the secondary and tertiary follicle. After fertilization, the synthesis of the zona protein is finished. Mol. Reprod. Dev. 49:435–443, 1998. © 1998 Wiley-Liss, Inc.     

褪黑激素对休情期银黑狐腔前卵泡卵母细胞超微结构的影响

为了研究褪黑激素(Melatonin,MLT)对休情期银黑狐腔前卵泡卵母细胞超微结构的影响。本研究选取健康7月龄埋植和未埋植MLT的银黑狐各5只,取其左侧卵巢共计10枚,制备超薄切片后利用透射电镜分别观察每枚卵巢的各级腔前卵泡各1-5个,并进行拍照。结果埋植和未埋植MLT的银黑狐原始卵泡卵母细胞内均有少量线粒体和高尔基体,而未埋植MLT的银黑狐卵母细胞中还可见少量滑面内质网;初级卵泡卵母细胞内,均开始形成不完整透明带,线粒体及内质网数量均有所增加,沿透明带出现少量皮质颗粒;次级卵泡阶段,未埋植MLT银黑狐卵母细胞微绒毛数量较埋植MLT的多,其余细胞器未见差异。结果表明,MLT对休情期银黑狐卵巢腔前卵泡卵母细胞的线粒体、脂滴、高尔基体、皮质颗粒等细胞器的发育没有影响,仅对初级卵泡阶段内质网的发育有抑制作用。     

Estrogen actions on follicle formation and early follicle development

Estradiol-17beta (E(2)) affects late follicular development, whereas primordial follicle differentiation and early activation are believed to be independent of E(2). To test this hypothesis we compared numbers of primordial and primary follicles in wild-type and E(2)-deficient, aromatase knockout (ArKO) mice, and the immunohistochemical staining or mRNA expression of Mullerian inhibiting substance (MIS), Wilms tumor 1 (WT-1), and growth differentiation factor (GDF9), which are known to effect early follicular differentiation. Proliferating cell nuclear antigen (PCNA) staining was a marker of proliferative index. The effects of E(2) replacement for 3 wk in 7-wk-old ArKO and wild-type mice on these parameters were also tested. ArKO mice had reduced numbers of primordial and primary follicles compared with wild-type mice (63%, P < 0.001 and 60%, P = 0.062, respectively). This reduction was not corrected by E(2) treatment, suggesting that E(2) affects the initial formation or activation of primordial follicles. There was a significant increase in the diameters of the oocytes in primordial follicles of ArKO mice compared with mice of the wild type. There were no differences in the immunostaining of MIS, WT-1, and PCNA in primordial and primary follicles between wild-type and ArKO mice. The only difference was as a consequence of Sertoli and Leydig cells that develop in ovaries of ArKO mice. GDF9 mRNA expression was markedly increased in ArKO ovaries. E(2) treatment restored the ovarian follicular morphology in ArKO mice, and consequently the immunostaining patterns, but had no effect on early follicle numbers. In conclusion, E(2) has a role in controlling the size of the oocyte and primordial follicle pool in mice.     

Androgens promote oocyte insulin-like growth factor I expression and initiation of follicle development in the primate ovary.

In the study reported here, we investigated the effect of androgens on recruitment of resting, primordial follicles into the actively growing pool. Healthy, random-cycling female rhesus monkeys were treated with testosterone, dihydrotestosterone (DHT), or vehicle for 3-10 days, after which ovaries were collected for histological analysis. The first stage of follicle growth is the formation of the primary follicle, consisting of an oocyte surrounded by a single layer of cuboidal granulosa cells. The number of primary follicles was significantly increased over time in testosterone-treated animals. In situ hybridization showed that androgen treatment resulted in an increase to 3-fold in insulin-like growth factor I (IGF-I) and to 5-fold in IGF-I receptor mRNA in primordial follicle oocytes. DHT effects were comparable to those of testosterone, showing that these are androgen receptor-mediated phenomena. These data show that androgens promote initiation of primordial follicle growth and implicate oocyte-derived IGF-I in this activation process.     

Growth differentiation factor-9 and stem cell factor promote primordial follicle formation in the hamster: modulation by follicle-stimulating hormone

Growth differentiation factor-9 (GDF-9) and stem cell factor (SCF) influence follicle formation beyond the primary stage; however, factors influencing the formation of primordial follicles remain elusive. To determine whether GDF-9 and SCF promoted primordial follicle formation during ovarian morphogenesis in the hamster, and whether FSH had any modulatory influence, fetal ovaries were collected on Gestation Day 15 from pregnant hamsters treated with or without an FSH antiserum on Gestation Day 12 and cultured in vitro up to Day 9 with SCF, GDF-9, or FSH. The percentages and diameters of primordial, primary, and secondary follicles and their oocytes were determined by morphometric evaluation, and the expression of GDF-9 was detected by immunolocalization. SCF, GDF-9, and FSH promoted primordial and primary follicle formation, but GDF-9 was more efficient. The diameters of the follicles developed under GDF-9 or FSH, but not SCF, compared well with those developed in vivo. FSH- and GDF-9-induced folliculogenesis was attenuated by the SCF antibody. Similarly, in vitro formation of primordial follicles decreased markedly in ovaries exposed to the FSH antiserum in utero, which was reversed by SCF, GDF-9, or FSH; however, GDF-9 had a profound effect on follicular development. GDF-9 protein appeared exclusively in the oocytes on Postnatal Day 4; however, it appeared in vitro by 48 h, and the expression was upregulated by FSH. These results suggest that although SCF-induced primordial follicle formation constitutes primarily somatic cell development, GDF-9 influences both the oocyte and its companion somatic cells. FSH plays an important role in primordial folliculogenesis in the hamster via GDF-9 and SCF.     

Steady‐state level of kit ligand mRNA in goat ovaries and the role of kit ligand in preantral follicle survival and growth in vitro

The aims of this study were to investigate steady‐state level of Kit Ligand (KL) mRNA and its effects on in vitro survival and growth of caprine preantral follicles. RT‐PCR was used to analyze caprine steady‐state level of KL mRNA in primordial, primary, and secondary follicles, and in small (1–3 mm) and large (3–6 mm) antral follicles. Furthermore, ovarian fragments were cultured for 1 or 7 days in Minimal Essential Medium (MEM⁺) supplemented with KL (0, 1, 10, 50, 100, or 200 ng/ml). Noncultured (control) and cultured fragments were processed for histology and transmission electron microscopy (TEM). RT‐PCR demonstrated an increase in steady‐state level of KL mRNA during the transition from primary to secondary follicles. Small antral follicles had higher steady‐state levels of KL mRNA in granulosa and theca cells than large follicles. After 7 days, only 50 ng/ml of KL had maintained the percentage of normal follicles similar to control. After 1 day, all KL concentrations reduced the percentage of primordial follicles and increased the percentage of growing follicles. KL at 10, 50, 100, or 200 ng/ml increased primary follicles, compared to MEM⁺ after 7 days. An increase in oocyte and follicular diameter was observed at 50 ng/ml of KL. TEM confirmed ultrastructural integrity of follicles after 7 days at 50 ng/ml of KL. In conclusion, the KL mRNAs were detected in all follicular categories. Furthermore, 50 ng/ml of KL maintained the integrity of caprine preantral follicle cultured for 7 days and stimulated primordial follicle activation and follicle growth. Mol. Reprod. Dev. 77: 231–240, 2010. © 2009 Wiley‐Liss, Inc.     

Development of primordial and prenatal follicles from undifferentiated somatic cells and oocytes in the hamster prenatal ovary in vitro: effect of insulin

Fetal hamster ovaries were cultured for up to 16 days in the presence or absence of various dosages of insulin to evaluate the induction of folliculogenesis in vitro. In the absence of insulin, a few primordial follicle-like structures appeared by the 4th day, and distinct primary follicles (stage 1) appeared by the 12th day of culture. The organelles in the oocytes and adjacent granulosa cells developed along with follicular growth. Moreover, gap junctions between the oocyte and somatic cell plasma membrane also developed as early as 8 days in culture. In the presence of 0.2 microg/ml insulin, primary follicles developed after 8 days, and approximately 4% secondary follicles with 2-3 layers of granulosa cells appeared after 16 days of culture. However, higher dosages (> 0.2 microg/ml) of insulin retarded primary follicle formation and induced the formation of primordial follicles with larger oocytes. An increased number of larger oocytes with a few granulosa cells accumulated at the periphery of the ovary. The results indicate that although primordial and primary follicles can develop after 12 days in vitro in the absence of exogenous insulin, the latter is required for timely progression of follicular development through primary and secondary stages.     

Immunolocalization of GnRHRI,gonadotropin receptors,PGR, and PGRMCI during follicular development in the rabbit ovary

The aim of this study was to investigate the presence and localization of gonadotropin-releasing hormone receptor-I (GnRHRI), gonadotropin receptors (FSHR, LHR), progesterone receptor (PGR), and progesterone receptor membrane-binding component-I (PGRMCI) in the different developmental stages of the rabbit follicle. The ovaries were collected from four healthy New Zealand white rabbits, and the mRNA expression and protein levels of GnRHRI, FSHR, LHR, PGR, and PGRMCI were examined with real-time PCR and immunohistochemistry. The results showed that GnRHRI, FSHR, LHR, PGR, and PGRMCI mRNA was expressed in the ovary; furthermore, we show cell-type specific and follicular development stage-specific expression of these receptors at the protein level. Specifically, all of the receptors were detected in the oocytes from the primordial to the tertiary follicles and in the granulosa and theca cells from the secondary and tertiary follicles. In the mature follicles, all receptors were primarily localized in the granulosa and theca cells. In addition, LHR was also localized in the granulosa cells from the primordial and primary follicles. With follicular development, the expression level of all of the receptors, except GnRHRI, in the follicles showed a tendency to decrease because the area of the follicle increased sharply. The expression level of GnRHRI, FSHR, and PGR in the granulosa and theca cells showed an increasing trend with ongoing follicular development. Interestingly, the expression level of FSHR in the oocytes obviously decreased from the primary to the tertiary follicles, whereas LHR in the oocytes increased from the secondary to tertiary follicles. In conclusion, the expression of GnRHRI, the gonadotropin receptors, PGR, and PGRMCI decreased from the preantral follicles (primordial, primary, and secondary follicles) to the tertiary follicles. The expression of GnRHRI and LHR in the oocytes increased from the secondary to the tertiary follicles, whereas FSHR decreased from the primary to the tertiary follicles. The expression of GnRHRI and PGR in the granulosa and theca cells increased from the secondary to the mature follicles. These observations suggest that these receptors play roles in follicular development and participate in the regulation of follicular development.     

Kaempferol promotes primordial follicle activation through the phosphatidylinositol 3‐kinase/protein kinase B signaling pathway and reduces DNA fragmentation of sheep preantral follicles cultured in vitro

The aim of this study was to evaluate the effects of kaempferol on the morphology, follicular activation, growth, and DNA fragmentation of ovine preantral follicles cultured in situ, and the effects of a phosphatidylinositol 3 kinase (PI3K) inhibitor and the expression of phosphorylated protein kinase B (pAKT) after culture. Ovine ovarian fragments were fixed for histological and terminal deoxynucleotidyl transferase‐mediated dUTP nick‐end labeling (TUNEL) analyses (fresh control) or cultured in α‐MEM+ alone (control) or with different concentrations of kaempferol (0.1, 1, 10, or 100 μM) for 7 days. Follicles were classified as normal or atretic, primordial or growing, and the oocyte and follicle diameters were measured. Proliferating cells were analyzed and DNA fragmentation was evaluated by the TUNEL assay. Inhibition of PI3K activity was performed through pretreatment in media added with 50 µM LY294002 for 1 hr and pAKT immunohistochemistry was performed after culture in the absence or presence of LY294002. After culture, the percentage of normal follicles was similar among the treatments (p > 0.05), except for 100 µM kaempferol, which had less normal follicles (p < 0.05). Moreover, kaempferol at 10 μM showed a higher percentage of follicular activation and cell proliferation than the other treatments (p < 0.05) and a percentage of TUNEL‐positive cells similar to that in the fresh control and lower than other treatments (p < 0.05). LY294002 significantly inhibited primordial follicle activation stimulated by α‐MEM+ and 10 μM kaempferol and reduced pAKT expression in those follicles. In conclusion, 10 μM kaempferol promotes primordial follicle activation and cell proliferation through the PI3K/AKT pathway and reduces DNA fragmentation of ovine preantral follicles cultured in vitro.     

Developmental programming: impact of prenatal testosterone excess on ovarian cell proliferation and apoptotic factors in sheep

Prenatal testosterone (T) excess leads to reproductive dysfunctions in sheep, which include increased ovarian follicular recruitment and persistence. To test the hypothesis that follicular disruptions in T sheep stem from changes in the developmental ontogeny of ovarian proliferation and apoptotic factors, pregnant Suffolk sheep were injected twice weekly with T propionate or dihydrotestosterone propionate (DHT; a nonaromatizable androgen) from Days 30 to 90 of gestation. Changes in developmental expression of proliferating cell nuclear antigen (PCNA), BCL2, BAX, activated CASP3, and FAS/FASLG were determined at Fetal Days 90 and 140, 22 wk, 10 mo, and 21 mo of age by immunocytochemisty. Prenatal T treatment induced changes in expression of proliferative and apoptotic markers in a follicle-, age-, and steroid-specific manner. Changes in BAX were evident only during fetal life and PCNA, BCL2, and CASP3 only postnatally. Prenatal T and not DHT increased PCNA and decreased BCL2 in granulosa/theca cells of antral follicles at 10 and 21 mo but decreased CASP3 in granulosa/theca cells of antral follicles at 22 wk (prepubertal) and 10 and 21 mo. Both treatments decreased BAX immunostaining in granulosa cells of Fetal Day 90 primordial/primary follicles. Neither treatment affected FAS expression at any developmental time point in any follicular compartment. Effects on BAX appear to be programmed by androgenic actions and PCNA, BCL2, and CASP3 by estrogenic actions of T. Overall, the findings demonstrate that fetal exposure to excess T disrupts the ovarian proliferation/apoptosis balance, thus providing a basis for the follicular disruptions evidenced in these females.     

Differential steroid and gonadotropin response by individual tertiary porcine follicles in vitro. Possible physiologic role of atretic follicles

Since atretic follicles contain significant amounts of androgen and/or progesterone in their follicular fluid, we examined whether they also contribute to ovarian steroid secretion. Steroid secretion by atretic porcine follicles and their responsiveness to FSH was assessed by a perifusion system that allows for separate dynamic incubation of whole follicles in vitro. Identically treated nonatretic follicles of comparable size served as a reference group. The extent of granulosal pyknosis, on which the staging of atresia was based, was inversely related to follicular estradiol (E2) secretion and its responsiveness to FSH. Both basal and FSH-stimulated secretion of testosterone (T), androstenedione (A), and progesterone (P) were maintained by follicles in all stages of atresia. Secretion of A by late atretic follicles was greater than that in earlier stages or by nonatretic follicles. Atretic follicles may therefore release comparable or larger amounts of androgen and P into their intraovarian environment than do nonatretic follicles. We examined whether steroids secreted by atretic follicles in vitro could be utilized by nonatretic follicles. A static incubation system was used that allows for simultaneous incubation of a number of individual follicles. When nonatretic follicles were exposed to A, T, or P in physiologic concentrations (10(-7)-10(-5) M), their secretion of E2 increased 2-8-fold. Doses of FSH or LH that stimulated follicular steroid in vitro had no additional stimulatory effect when combined with A or P treatment, respectively. In conclusion, atretic follicles may contribute significantly to intraovarian levels of androgen and P.(ABSTRACT TRUNCATED AT 250 WORDS)