Hormonal changes associated with estrogen induced luteolysis in the pregnant hamster: a reevaluation of the luteotropic complex

Hamsters were injected sc on Day 1 of pregnancy (sperm positive) with 50 micrograms estradiol cyclopentylpropionate (ECP) or peanut oil. On Day 5, serum progesterone (P4) was 10.6 ng/ml in controls vs 3.1 ng/ml after ECP. In the ECP group, serum prolactin (PRL) and follicle stimulating hormone (FSH) did not differ from controls but serum luteinizing hormone (LH) was significantly lower than that of the controls, and usually below the sensitivity of the radioimmunoassay (RIA). After ECP, structural signs of luteolysis (weight and histology) and absence of antral follicles characterized the ovary. Injection of an anti-LH serum on Day 4 halved serum P4 levels on Day 5 in control animals but caused no further lowering of P4 in ECP-treated hamsters. Treatment on Days 1-5 with 1.0 IU hCG or 10 micrograms LH plus ECP on Day 1 restored, by the afternoon of Day 5, serum P4 to the control range (9-10 ng/ml) and antral follicles were now present. The results indicate that a large dose of ECP causes luteolysis by reducing LH levels and reinforce the concept of a luteotropic complex in the hamster with PRL and FSH constituting the minimal components and LH serving as a synergist.     

The impact of dose of FSH (Folltropin) containing LH (Lutropin) on follicular development, estrus and ovulation responses in prepubertal gilts

FSH is favored over chorionic gonadotropins for induction of estrus in various species, yet little data are available for its effects on follicle development and fertility for use in pigs. For Experiment 1, prepubertal gilts (n = 36) received saline, 100 mg FSH, or FSH with 0.5 mg LH. Treatments were divided into six injections given every 8 h on Days 0 and 1. Proportions of gilts developing medium follicles were increased for FSH and FSH-LH (P < 0.05) compared to saline, but follicles were not sustained and fewer hormone-treated gilts developed large follicles (P < 0.05). No gilts expressed estrus and few ovulated. Experiment 2 tested FSH preparations with greater LH content. Prepubertal gilts (n = 56) received saline, FSH-hCG (100 mg FSH with 200 IU hCG), FSH-LH5 (FSH with 5 mg LH), FSH-LH10 (FSH with 10 mg LH), or FSH-LH20 (FSH with 20 mg LH). FSH-LH was administered as previously described, while 100 IU of hCG was given at 0 h and 24 h. Hormone treated gilts showed increased (P < 0.05) medium and large follicle development, estrus (>70%), ovulation (100%), and ovulation rate (>30 CL) compared to saline. There was an increase (P < 0.05) in the proportion of hormone-treated gilts with follicular cysts at Day 5, but these did not persist to Day 22. These gilts also showed an increase in poorly formed CL (P < 0.05). FSH alone or with small amounts of LH can induce medium follicle growth but greater amounts of LH at the same time is needed to sustain medium follicles, stimulate development of large follicles and induce estrus and ovulation in prepubertal gilts.     

Initiation of follicular maturation during mid-pregnancy by the administration of LH in the rat

Pregnant rats were injected twice daily for 1-3 days (Days 13-16 of pregnancy) with various doses of ovine LH. Follicular maturation was determined by the ability of the follicles to ovulate in response to 10 i.u. hCG as well as by endogenous production of oestradiol-17 beta and inhibin. In control animals, no ovulation was induced by hCG given on Day 16 of pregnancy. An injection of hCG on Day 16 of pregnancy, however, induced ovulation in LH-treated animals (6.25-50.0 micrograms LH per injection, s.c. at 12-h intervals from Days 13 to 16). Concentrations of oestradiol-17 beta and inhibin activity in ovarian venous plasma increased after the administration of LH, indicating that development of ovulatory follicles had been induced. Abolishing the decline in plasma LH values therefore induced maturation of a new set of follicles or prevented the atresia of large antral follicles usually seen at this time of pregnancy. Plasma and pituitary concentrations of FSH decreased in LH-treated animals compared with those in control animals. Concentrations of progesterone, testosterone and oestradiol-17 beta in the peripheral plasma were not significantly different between the two groups. These results suggest that the increase in inhibin secretion from the ovary containing maturing follicles after LH treatment may suppress the secretion of FSH from the pituitary gland. These findings indicate that (1) the development of ovulatory follicles can be induced by the administration of exogenous LH during mid-pregnancy in the rat and (2) basal concentrations of FSH are enough to initiate follicular maturation even in the presence of active corpora lutea of pregnancy, when appropriate amounts of plasma LH are present.     

Effects of progesterone or luteinizing hormone on folliculogenesis in intact or hypophysectomized immature hamsters

Since exogenous progesterone (P4) causes superovulation in hypophysectomized (hypoxed) cyclic hamsters treated with gonadotropins, the current study was performed to evaluate the roles of P4 and luteinizing hormone (LH) as a folliculotropic complex in the immature hamster. Intact or hypoxed immature hamsters were injected daily, beginning on Day 23, with 1 mg P4 and/or 20 micrograms LH for 4 days. Treatment with P4 alone or combined with LH in intact immature hamsters increased the number of antral follicles (6.7 and 4.3, respectively, vs. 1.5 per ovary in controls), but neither treatment maintained large follicles in hypoxed animals. In contrast, in hypoxed hamsters, the number of small preantral follicles was enhanced by P4 or LH (406 and 409, respectively, compared to 302 per ovary in untreated controls), but with no additive effects by combined treatment. The stimulatory effect of P4 in intact hamsters was unrelated to serum levels of follicle-stimulating hormone, estradiol, or LH. Moreover, in the hypoxed hamster, P4 or LH acts directly to increase the numbers of small preantral follicles with 2 to 5 layers of granulosa cells, whereas equally large doses of stilbestrol or estradiol cyclopentylpropionate are ineffective. In the hypoxed or intact hamster, the effects of P4 or LH may involve either recruitment of smaller follicles into larger stages or prevention of atresia. The present experimental design can not distinguish between these possibilities.     

Autoradiographic analysis of follicle-stimulating hormone and human chorionic gonadotropin receptors in the ovary of immature rats treated with equine chorionic gonadotropin.

The gonadotropin-primed immature rat has become the most common model for the study of follicular development and ovulation. In this study, prepubertal female rats, 23 and 24 days old, were injected s. c. with 5 IU eCG, and ovaries were collected for topical autoradiography of FSH and hCG receptors at 48 or 24 h post-eCG, respectively (i.e., Day 25). In a baseline group, on Day 25 (before eCG), even the smallest preantral follicles with 1 layer of granulosa cells (GCs; primary follicles) possessed FSH receptors, but hCG receptors were found only on the theca of follicles with 2 or more layers of GCs. Human CG receptors were especially prominent in the interstitium that intimately surrounds preantral follicles without any distinction between theca and interstitial cells. There was a discrete theca surrounding antral follicles. Occasionally antral follicles had hCG receptors in the interstitium, but the adjacent theca was negative, suggesting that these follicles might be destined for atresia. By 24 h post-eCG, a now-discrete theca layer with hCG receptors surrounded all preantral follicles except for the primary follicles, which never responded to eCG. The interstitium was hypertrophied and epithelioid, as was the theca surrounding nonatretic preantral and antral follicles. Increased mitotic activity characterized the growing preantral follicle, and for the first time, FSH binding in GCs of antral follicles was greater than in the preantral population. By 48 h post-eCG, the primary follicles were still unresponsive to eCG. FSH receptors were even more pronounced in the GCs of large antral follicles, although hCG receptors were present in the GCs of only one third of the antral follicles, reflecting the small dose of eCG administered. By 48 h post-eCG, receptors in the interstitium were barely detectable. Using this model, the following study considers the functional in vitro changes in steroidogenesis in follicles from the smallest preantral follicles to the largest antral follicles.     

Cell-type-specific localization of transforming growth factor-beta 2 and transforming growth factor-beta 1 in the hamster ovary: differential regulation by follicle-stimulating hormone and luteinizing hormone.

Cell-type-specific localization and gonadotropin regulation of transforming growth factor-beta 1 (TGF-beta 1) and transforming growth factor-beta 2 (TGF-beta 2) in the hamster ovary were evaluated immunohistochemically under three conditions: (1) during the estrous cycle (Day 1 = estrus; Day 4 = proestrus); (2) after the blockade of periovulatory gonadotropin surges by phenobarbital, and (3) after FSH and/or LH treatment of long-term hypophysectomized hamsters. Ovarian TGF-beta 1 activity was primarily localized in theca and interstitial cells. The activity increased moderately but significantly after the preovulatory LH surge and reached a peak at 0900 h, Day 2 h; oocytes showed considerable activity. TGF-beta 1 immunoreactivity subsequently fell to low levels in theca-interstitial cells through 0900 h, Day 4. Significant TGF-beta 2 immunoreactivity appeared after the surge, mainly in the granulosa cells of both preantral and antral follicles; a few interstitial cells surrounding preantral follicles showed discrete staining. TGF-beta 2 immunoreactivity in granulosa cells and in interstitial cells next to preantral follicles reached a peak at 0900 h, Day 1, and persisted up to 0900 h, Day 2; oocytes showed no staining. Phenobarbital treatment blocked the appearance of TGF-beta 1 and TGF-beta 2 immunoreactivities at 1600 h, Day 4; however, a rebound in immunoreactivities was observed with the onset of the surge after a 1-day delay. Replacement of LH to long-term hypophysectomized hamsters resulted in a marked increase in TGF-beta 1 immunoreactivity in the interstitial cells, but FSH, although it induced follicular development, did not influence ovarian TGF-beta 1 activity. Treatment with FSH, however, induced a massive increase in TGF-beta 2 immunoreactivity in the granulosa cells of newly developed antral and preantral follicles but not in the interstitial cells; LH, on the other hand, had no significant effect on TGF-beta 2 activity. Treatment with FSH and LH combined resulted in a dramatic increase in TGF-beta 2 immunoreactivity in granulosa and interstitial cells and in TGF-beta 1 in theca and interstitial cells comparable to their peak activity in intact animals. Western analyses substantiated the presence of TGF-beta 1 and TGF-beta 2 in the hamster ovary and the specificity of immunolocalization. These studies, therefore, provide critical evidence that TGF-beta 1 and TGF-beta 2 in the hamster ovary are expressed in specific cell types and that their expression is differentially regulated by LH and FSH, respectively.     

Quantitative analysis of in-vitro incorporation of [3H]thymidine into hamster follicles during the oestrous cycle

Follicles were isolated from hamster ovaries at 09:00 h and 15:00 h on each of the 4 days of the oestrous cycle (Day 1 = oestrus; Day 4 = pro-oestrus) by microdissection and by a mixture of enzymes and classified into 10 stages with pre-calibrated pipettes (stage 1 = preantral follicles with 1 layer of granulosa cells; stage 10 = preovulatory antral follicles). The follicles at each stage were incubated for 4 h with [3H]thymidine with incorporation expressed per microgram follicular DNA or per follicle. A significant increase in thymidine per follicle occurred at 15:00 h on Days 1 and 3 of the cycle from stage 2 (bilaminar follicle) to stage 6 (7-8 layers granulosa cells plus theca). When expressed as thymidine per follicle or microgram DNA, there was a significant increase in incorporation for stages 1-4 (4 layers granulosa cells) on Day 4 at 15:00 h compared to 09:00 h, presumably as a consequence of the preovulatory increase in gonadotrophins. Follicles in stages 5 to 8 (preantral follicles with 5 or more layers of granulosa cells to small antral follicles), from which the next set of ovulatory follicles will be selected, did not show a significant peak in incorporation per microgram DNA until Day 1 at 09:00 and 15:00 h when the second increase in FSH is in progress. DNA synthesis was similarly sustained throughout Day 1 for stage 1-4 follicles. These results suggest that periovulatory changes in FSH and LH, directly or indirectly, are not only responsible for ovulation and the recruitment of the next set of follicles destined to ovulate but also stimulate DNA replication in smaller follicles which develop over the course of several cycles before they ovulate or become atretic.     

Elevated peripheral concentrations of LH block ovulation and increase thecal and serum progesterone in the hamster

Insertion of osmotic minipumps containing 1 mg ovine LH on Day 1 (oestrus) elevated circulating serum concentrations of LH, progesterone and androstenedione when compared with values at pro-oestrus. Ovulation was blocked for at least 2 days at which time there were twice the normal numbers of preovulatory follicles. Follicular and thecal progesterone production in vitro was elevated when compared with that in pro-oestrous controls. Follicular and thecal androstenedione production in vitro was lower than in controls even though serum concentrations of androstenedione were elevated; the higher androstenedione values may be due to the increase in number of preovulatory follicles when compared with pro-oestrous controls. Follicles from LH-treated hamsters aromatized androstenedione to oestradiol and follicular production of oestradiol was similar to that in pro-oestrous follicles despite low follicular androstenedione production in the LH-treated group. Treatment with 20 i.u. hCG on Days 4 or 6 after insertion of an LH osmotic minipump on Day 1 induced ovulation of approximately 30 ova, indicating that the blockade of ovulation was not due to atresia of the preovulatory follicles. Serum progesterone concentrations on Days 2, 4 and 6 in LH-treated hamsters were greater than 17 nmol/l, suggesting that the blockade of ovulation might have been due to prevention of the LH surge by high serum progesterone concentrations.     

The peripubertal golden hamster and the transition between daily and estrous cycle hormone rhythms

Transitional patterns of LH, FSH, and progesterone (P4) in the circulation were studied in peripubertal female golden hamsters. A daily rhythm, with afternoon surges of these hormones, is typical of the immature female, whereas 4-day rhythms characterize the estrous cycle of the adult. Blood samples were collected repeatedly from maturing individuals at either 1400 or 1700 h. Each animal was examined daily for the appearance of regular vaginal estrous cycles as indicated by a mucous exudate on the morning of ovulation. Between Days -10 and -5 relative to first vaginal estrus (FVE), afternoon surges of LH, FSH, and P4 were often observed. From Days -5 to -1 relative to FVE, afternoon surges of LH and FSH were less frequent, but P4 retained the daily rhythmicity until Day -2. A 4-day pattern of LH secretion, but not of FSH or P4, was established prior to FVE. To determine whether or not ovulations were occurring prior to the appearance of external vaginal estrous cycles, reproductive tracts were collected from 26-34 days of age and examined for evidence of ovulation. Of 124 females, concordance between the record of daily vaginal examinations and the examinations of the ovaries and oviducts was found in 103 cases (83%). The development of ovarian follicles was correlated with FVE in peripubertal hamsters by unilateral ovariectomy. Antral follicles were found only in the last 3 days prior to vaginal estrus.     

Effects of a luteinizing hormone-releasing hormone antagonist in late-juvenile female rats: blockade of follicle growth and delay of first ovulation following suppression of gonadotropin concentrations

Subcutaneous injections of an antagonist against luteinizing hormone-releasing hormone (LHRH-A, Org, 30276) were administered to late-juvenile female rats. The effects on timing of vaginal opening and first ovulation on serum gonadotropin concentrations and on follicle growth were studied. The dose of 100 micrograms LHRH-A/100 g body wt, given on Days 28, 31, and 34, did not influence timing of first ovulation. After administration of 500 micrograms LHRH-A/100 g body wt, ovulation was retarded by 4.7 days if injections were given on Days 28 and 31; by 6.7 days if given on Days 28, 31, and 34; and by 11.5 days if given on Days 28, 31, 34, and 37. Serum LH and FSH concentrations 3 days after the first, second, and third injections of 500 micrograms LHRH-A were significantly (p less than 0.01) lower than in saline-treated controls. Ovarian follicle counts showed decreased numbers of (antral) Class 2, 3, and 4 follicles 3 days after injection of 500 micrograms LHRH-A/100 g body wt on Day 28; a significantly higher number of Class 1 follicles and a further decrease in Class 2, 3, and 4 follicles 3 days after the second LHRH-A injection; and total absence of Class 3, 4, and 5 follicles 3 days after the third LHRH-A injection. Six days after the third LHRH-A injection, Class 3 and 4 follicles reappeared in the ovaries.(ABSTRACT TRUNCATED AT 250 WORDS)     

Pituitary and ovarian hormone secretion and ovulation in gilts injected with gonadotropins during and after oral administration of progesterone agonist (Altrenogest)

We determined changes in plasma hormone concentrations in gilts after treatment with a progesterone agonist, Altrenogest (AT), and determined the effect of exogenous gonadotropins on ovulation and plasma hormone concentrations during AT treatment. Twenty-nine cyclic gilts were fed 20 mg of AT/(day X gilt) once daily for 15 days starting on Days 10 to 14 of their estrous cycle. The 16th day after starting AT was designated Day 1. In Experiment 1, the preovulatory luteinizing hormone (LH) surge occurred 5.6 days after cessation of AT feeding. Plasma follicle-stimulating hormone (FSH) increased simultaneously with the LH surge and then increased further to a maximum 2 to 3 days later. In Experiment 2, each of 23 gilts was assigned to one of the following treatment groups: 1) no additional AT or injections, n = 4; 2) no additional AT, 1200 IU of pregnant mare's serum gonadotropin (PMSG) on Day 1, n = 4); 3) AT continued through Day 10 and PMSG on Day 1, n = 5, 4) AT continued through Day 10, PMSG on Day 1, and 500 IU of human chorionic gonadotropin (hCG) on Day 5, n = 5; or 5) AT continued through Day 10 and no injections, n = 5. Gilts were bled once daily on Days 1-3 and 9-11, bled twice daily on Days 4-8, and killed on Day 11 to recover ovaries. Termination of AT feeding or injection of PMSG increased plasma estrogen and decreased plasma FSH between Day 1 and Day 4; plasma estrogen profiles did not differ significantly among groups after injection of PMSG (Groups 2-4). Feeding AT blocked estrus, the LH surge, and ovulation after injection of PMSG (Group 3); hCG on Day 5 following PMSG on Day 1 caused ovulation (Group 4). Although AT did not block the action of PMSG and hCG at the ovary, AT did block the mechanisms by which estrogen triggers the preovulatory LH surge and estrus.     

Compensatory responses after unilateral ovariectomy in rabbits

Compensatory ovarian and gonadotropic responses to unilateral ovariectomy (ULO) were examined in the rabbit doe, an induced ovulator. On Days 2, 4, 5, 6, 8, 10, 15 and 20 after ULO, ovaries from 3 hemiovariectomized does and 1 sham-hemiovariectomized doe were examined macro- and microscopically for number, size and signs of atresia of follicles. The number of surface follicles increased initially to 7 or 8 follicles 2 days after ULO, followed by an increase to 10 or more follicles by Day 15 (control ovaries had 5.7 +/- 0.4 follicles). Total numbers of antral follicles and the proportion of follicles which were atretic did not vary relative to day after ULO. However, distributions of antral follicles in classes of 0.2-mm increments were significantly different between sham-ovariectomized and hemiovariectomized does after Day 2 due to shifts of follicles into larger size classes. Peripheral serum concentrations of follicle-stimulating hormone (FSH), but not luteinizing hormone (LH), increased temporarily during the 48 h after ULO. Follicular compensation after ULO in the doe entailed nonlinear increases in numbers of preovulatory follicles, due to increased growth within the antral population of follicles, probably the result of an acute surge of FSH. A period of more than 10 days was necessary to restore the number of preovulatory follicles after ULO. Exogenous human chorionic gonadotropin (hCG) induced ovulation of recruited follicles.     

A species difference between hamster and rat in the effect of oestrogens on growth of large preantral follicles

Intact or hypophysectomized 23-day-old hamsters and rats were injected s.c. with 2 mg diethylstilboestrol (DES) or 1 mg oestradiol cyclopentylpropionate (OECP) on Days 23-25 and killed on Day 26. Although serum oestradiol was elevated to the same high levels by OECP, ovarian and uterine weights were increased in the rat by OECP or DES whereas only the uterus responded in the hamster. This correlated with the ability of the oestrogens to increase significantly the number of large preantral and antral follicles in the intact rat but only the number of follicles with 2-3 layers of granulosa cells in the immature hamster. Qualitative study revealed that DES and OECP increased the number of large preantral follicles in the adult hypophysectomized rat but were ineffective in the adult hamster. It is concluded that for the immature and adult hamster oestrogens do not play a major role in the recruitment of large preantral follicles.     

Ovarian follicular populations and preovulatory enlargement in Booroola and control Merino ewes

To investigate the factors contributing to the different ovulation rates observed in two strains of sheep (Booroola 5.2, Merino 1.2), in-vivo monitoring of follicular kinetics followed by histological examination of both ovaries was performed during the late luteal and follicular phases. Ewes of both strains were either ovariectomized at Day 13, or had the 3 largest follicles of each ovary ink-labelled at Day 13 and were ovariectomized at Day 15, or had the 3 largest follicles of each ovary ink-labelled at Days 13 and 15 and were ovariectomized 16 h after the beginning of oestrus (N = 6 per time per strain). In another experiment, the age effects on the follicular populations of these two strains were also studied. There were 2-4 times more primordial follicles and 1.5-2 times more preantral follicles in the ovaries of Booroola than in control Merino ewes, although the number of antral follicles was the same. The percentage of normal follicles in this population was higher in Merino than Booroola ovaries. In Booroola ewes, there was no correlation between the number of antral follicles per ovary and the ovulation rate at the previous cycle (r = 0.22). This suggests that follicle numbers do not play a key role in the high ovulation rate of the Booroola strain. The number of follicles initiating growth from the primordial pool, the number of growing follicles disappearing at the preantral stage, the pattern of antrum development, granulosa cell multiplication and appearance of atresia differed between strains. The reasons for the high ovulation rate of the Booroola strain became clear when preovulatory enlargement was followed by ink labelling. An extended period of time during which recruitment of ovulatory follicles takes place, together with a low incidence of selection and the ability of the follicles to wait for ovulation are the features involved in this high ovulation rate.     

Effects of luteinizing hormone on superovulatory and steroidogenic responses of rat ovaries to infusion with follicle-stimulating hormone

Immature female rats were infused s.c. continuously over a 60-h period with a partially purified porcine pituitary follicle-stimulating hormone (FSH) preparation having FSH activity 4.2 x NIH-FSH-S1 and luteinizing hormone (LH) activity 0.022 x NIH-LH-S1. High rates of superovulation were observed in rats receiving 1 U FSH/day, with 69 +/- 11 oocytes/rat recovered as cumulus-enclosed oocytes from oviducts on Day 1 (equivalent to the day of estrus). Addition of LH to the FSH, at dosages equivalent to 2.5-100 micrograms/day NIH-LH-S1 equivalents (2.5-100 mU) resulted in a dose-related inhibition of superovulation, reaching a nadir of 15 +/- 7 oocytes recovered from rats receiving 50 mU LH/day together with 1 U FSH/day. At the two highest LH doses, 50 and 100 mU/day, ovulation was advanced so that 12 +/- 3 and 15 +/- 4 oocytes, respectively, were recovered from oviducts of these rats flushed on the morning of Day 0, compared to none in rats infused with FSH alone. Ovarian steroid concentrations (ng/mg) observed on the morning of Day 0 in rats infused with FSH alone were progesterone, 0.50 +/- 0.13; testosterone, 0.16 +/- 0.08; androstenedione, 0.06; and estradiol, 0.23 +/- 0.05. On the morning of Day 1, ovarian progesterone concentrations in rats infused with FSH alone had risen to 3.30 +/- 0.33 ng/mg, whereas concentrations of testosterone, androstenedione, and estradiol, had fallen to essentially undetectable levels. Addition of LH to the FSH infusion resulted in dose-related increases, on Day 0, of all four steroids up to a dosage of 25 mU LH/day. At higher LH dosages, Day 0 ovarian concentrations of androgens and estradiol fell markedly, while progesterone concentrations continued to increase. Histological examination of ovaries revealed increases in the extent of luteinization of granulosa cells in follicles with retained oocytes on both Days 0 and 1 in rats infused with 25 and 50 mU LH/day together with 1 U FSH/day, compared to those observed in rats receiving FSH alone. These findings indicate that the elevated progesterone levels on Day 0 and inhibition of ovulation observed at these LH doses were due to premature luteinization of follicles, thus preventing ovulation. At lower LH doses, no sign (based on histologic or steroidogenic criteria) of premature luteinization was evident, suggesting that the decreased superovulation in these rats was due to decreased follicular maturation and/or increased atresia rather than to luteinization of follicles without ovulation.(ABSTRACT TRUNCATED AT 400 WORDS)     

Changes in follicle-stimulating hormone and follicle populations during the ovarian cycle of the common marmoset

The common marmoset (Callithrix jacchus) belongs to the family Callitrichidae, the only anthropoid primates with a high and variable number of ovulations (one to four). An understanding of folliculogenesis in this species may provide some insight into factors regulating multiple follicular growth in primates. The aims of this study were to characterize in detail changes in the antral follicle population at different stages of the ovarian cycle, to characterize the marmoset FSH profile, and to relate cyclic changes in FSH to changes in follicle sizes and circulating estradiol concentrations. Fifty-five pairs of ovaries were collected (32 of which were at five distinct stages of the cycle) from adult marmosets, and antral follicles were manually excised and separated into four size groups. Daily urinary FSH and plasma estradiol and progesterone concentrations from Day 0 of the follicular phase to 2 days postovulation were measured in 22 marmosets using enzyme immunoassays. The FSH profile revealed two distinct peaks, on Days 2 and 6, during the 10-day follicular phase, with a marginal periovulatory increase on Days 9 and 10. Estradiol levels rose significantly (P: < 0.05) above baseline (Days 1-4) on Day 5 and continuously increased to a peak on the day preceding ovulation (Days 8 and 9). Follicle dissection revealed a high (mean = 68) and variable (range, 14-158) total number of antral follicles >0.6 mm. The number of antral follicles significantly declined (P: < 0.001) with age. The number of preovulatory follicles (>2 mm) was positively correlated with the number of antral follicles (P: < 0. 001) and tended to be negatively related to age (P: = 0.06). The number of antral follicles did not vary significantly with stage of the ovarian cycle, although the follicle size distribution was cycle-stage dependent (P: < 0.05). Follicles >1.0 mm appeared only in the follicular phase, and preovulatory follicles (>2.0 mm) appeared only at the end of the follicular phase (Days 7-9). The Day 2 FSH peak corresponded to emergence of a population of medium-size antral follicles, and the Day 6 peak was consistent with rising estradiol levels and appearance of the preovulatory follicles. These results suggest that some aspects of marmoset folliculogenesis are comparable to those in Old World primates, including the absence of multiple follicular waves and the appearance of an identifiable dominant follicle in the midfollicular phase. However, the midphase FSH peak, multiple dominant follicles, and abundance of nonovulatory antral follicles differ strongly from the pattern in Old World primates and humans. The findings are discussed in relation to the regulation of growth of multiple ovulatory follicles and provide the basis for further studies on factors influencing the dynamics of follicular growth and development in this species.     

Follicle-stimulating hormone plays a role in the induction of ovarian follicular cysts in hypophysectomized rats.

Unabated stimulation by low doses of LH-like activity produces ovarian follicular cysts in both progesterone-synchronized immature rats and pregnant rats. Serum FSH is maintained in both of these models at values similar to those observed on diestrus. To determine whether unabated stimulation by basal serum FSH affects the ability of LH-like activity to induce cystic ovaries, immature hypophysectomized (HYPOXD) rats were given either no hormone (control); 2 micrograms ovine FSH (oFSH) once daily for 14 days beginning on Day 27; 0.5 IU hCG twice daily for 13 days beginning on Day 28 of age; or both oFSH and hCG (FSH + hCG) beginning on Day 27 and Day 28, respectively. By the end of the in vivo treatments (Day 40 of age), the largest follicles in the ovaries of control and hCG-treated HYPOXD rats were at the preantral stage of development, whereas the largest follicles present in ovaries from FSH-treated animals were atretic and at the small antral stage of development. In contrast, ovaries from rats treated with FSH + hCG displayed large follicular cysts by Day 37 of age. Of the serum steroids analyzed, only estradiol and androstenedione concentrations for animals treated with FSH + hCG were consistently elevated above values observed for control HYPOXD rats. Serum testosterone and dihydrotestosterone values were similar for hCG-treated and control HYPOXD rats throughout the in vivo treatments. In contrast, these steroids were elevated between Days 3 and 5 of FSH treatment (+/- hCG treatment). Serum progesterone and estrone values for all in vivo gonadotropin treatment groups were similar to those of controls. Serum insulin concentrations were not affected by any in vivo treatment. Incubates of follicles/cysts from FSH + hCG-treated HYPOXD rats contained more progesterone, androstenedione, and estradiol than incubates of follicles from any other in vivo treatment group. Follicles from all in vivo treatment groups responded to 8-bromo cAMP (cAMP) with increased in vitro progesterone accumulation. However, only follicles from FSH-treated and FSH + hCG-treated rats responded to cAMP with increased androstenedione and estradiol accumulation in vitro. Inclusion of 400 ng of either androstenedione or testosterone in the incubation medium enhanced progesterone accumulation in follicular incubates from control, hCG-treated, and FSH-treated HYPOXD rats, but did not enhance progesterone accumulation in follicular incubates from FSH + hCG-treated animals. Both androstenedione and estradiol production increased markedly under these conditions for follicles from all in vivo treatment groups.(ABSTRACT TRUNCATED AT 400 WORDS)     

Comparison of the total ovarian follicular populations at day 140 of pregnancy and at day 5 postpartum in ewes

The total ovarian follicular populations were determined in ewes at Day 140 of pregnancy and at Day 5 postpartum. The right and left ovaries of five pregnant and five non-suckling ewes of the Préalpes-du-Sud breed were used in this study. All the ovaries were serially sectioned at a thickness of 7 μm, and every section was examined microscopically.The mean numbers of preantral follicles per ovary increased (P<0.005) at Day 5 postapartum as compared to Day 140 of pregnancy. The distribution of preantral non-atretic follicles into different size classes clearly showed a sharp increase in the mean number of follicles per size class at Day 5 postpartum, especially those leaving the reserve of primordial follicles.No difference was detected between both groups of ewes in the mean number of antral follicles. The diameter of the largest antral follicle at Day 140 of pregnancy does not exceed 1.5 mm. However, at Day 5 postpartum, a population of large follicles ≥ 1.5 mm was observed, reaching 2–4 mm in diameter.We conclude that although the pattern of normal follicular development is inhibited during late pregnancy, the ovary at this time is not quiescent, and ovarian follicular development starts well before parturition. The increasing number of preantral follicles, as well as the enlargement of antral follicle diameter observed at Day 5 postpartum, may be correlated with increasing secretion of FSH after lambing.     

Effects of gonadotrophins, growth hormone, and activin A on enzymatically isolated follicle growth, oocyte chromatin organization, and steroid secretion

So far, standard follicle culture systems can produce blastocyst from less than 40% of the in vitro matured oocytes compared to over 70% in the in vivo counterpart. Because the capacity for embryonic development is strictly associated with the terminal stage of oocyte growth, the nuclear maturity status of the in vitro grown oocyte was the subject of this study. Mouse early preantral follicles (100-130 microm) and early antral follicles (170-200 microm) isolated enzymatically were cultured for 12 and 4 days, respectively, in a collagen-free dish. The serum-based media were supplemented with either 100 mIU/ml FSH (FSH only); 100 mIU/ml FSH + 10 mIU/ml LH (FSH-LH); 100 mIU/ml FSH + 1 mIU/ml GH (FSH-GH) or 100 mIU/ml FSH + 100 ng/ml activin A (FSH-AA). Follicle survival was highest in follicle stimulating hormone (FSH)-AA group in both cultured preantral (91.8%) and antral follicles (82.7%). Survival rates in the other groups ranged between 48% (FSH only, preantral follicle culture) and 78.7% (FSH only, antral follicle culture). Estradiol and progesterone were undetectable in medium lacking gonadotrophins while AA supplementation in synergy with FSH caused increased estradiol secretion and a simultaneously lowered progesterone secretion. Chromatin configuration of oocytes from surviving follicles at the end of culture revealed that there were twice more developmentally incompetent non-surrounded nucleolus (NSN) oocytes (>65%) than the competent surrounded nucleolus (SN) oocytes (<34%). We conclude that the present standard follicle culture system does not produce optimum proportion of developmentally competent oocytes.