Ovulations in rat ovaries perfused in vitro with follicle-stimulating hormone

Using the model of the isolated perfused rat ovary, we have found that highly purified ovine follicle-stimulating hormone (FSH) preparations cause ovulation and that this effect is not due to luteinizing hormone (LH) contamination. Ovine FSH-13 at a concentration of 1.5 mU/ml induced ovulations in all perfused ovaries (8.8 +/- 2.3 ovulations/ovary), as did a more purified preparation, ovine FSH-211B, at concentrations of 0.5 mU/ml (15.0 +/- 6.4 ovulations/ovary) and 5 mU/ml (11.3 +/- 2.6 ovulations/ovary). This ovulation-inducing effect of FSH is accompanied by a marked stimulation of estradiol levels in the perfusion medium without stimulation of progesterone levels. Furthermore, a purified rat FSH preparation (15 mU/ml) also induced ovulation in all ovaries (13.8 +/- 2.2 ovulations/ovary) as well as a stimulation of both estradiol and progesterone in the medium. These data clearly confirm the direct ovulatory effect of FSH on the ovary.     

Cyclic adenosine 3',5'-monophosphate-induced ovulation in the perfused rat ovary and its mediation by prostaglandins

The role and mechanism of action of cyclic adenosine 3',5'-monophosphate (cAMP) in the ovulatory process was investigated by using the in vitro-perfused rat ovary model. Ovaries of pregnant mare's serum gonadotropin (PMSG, 20 IU)-primed rats were perfused for 21 h beginning in the morning of induced proestrus. In vitro stimulation with luteinizing hormone (LH; 0.1 micrograms/ml) resulted in 2.4 +/- 0.7 ovulations per treated ovary. Ovulations could also be induced by the addition of forskolin (30 microM) or dibutyryl cAMP (dbcAMP, 1 mM) with isobutylmethylxanthine (IBMX, 0.2 mM), with 11.8 +/- 1.9 and 18.6 +/- 4.4 ovulations per treated ovary, respectively. Indomethacin (5 micrograms/ml) significantly decreased the number of ovulations in the forskolin and dbcAMP + IBMX groups. The addition of prostaglandin E2 (PGE2; 1 micrograms/ml three times during the perfusion) to the forskolin + indomethacin group reversed the inhibition of ovulation (21.6 +/- 5.4 ovulations per treated ovary). Ovarian PGE tissue levels were significantly higher 10 h after stimulation with either LH, forskolin, or dbcAMP + IBMX compared to the unstimulated control group. Ovulated oocytes in the LH and forskolin groups resumed meiosis but oocytes in the dbcAMP + IBMX groups remained immature. This study shows that an increase in ovarian cAMP, even if not induced by LH, is sufficient to cause ovulation of preovulatory rat follicles, supporting the involvement of cAMP in the normal ovulatory process of the PMSG-treated rat. Furthermore, prostaglandin involvement in cAMP-induced ovulations is demonstrated.     

Inhibition of follicle-stimulating hormone-induced ovulation by indomethacin in the perfused rat ovary

In isolated, perfused ovaries of rats treated with pregnant mare's serum gonadotropin (PMSG), purified preparations of ovine follicle-stimulating hormone (FSH) (oFSH-211B) and rat FSH (rFSH-I-6), 100 ng/ml, were found to induce ovulations (4.8 +/- 0.9, n = 4, and 6.4 +/- 2.0, n = 5, ovulations per ovary, respectively). Indomethacin (5 micrograms/ml) added to the perfusate inhibited this ovulatory effect and exogenous prostaglandin F2 alpha (PGF2 alpha) (1 microgram/ml), or prostaglandin E2 (PGE2) (0.5 microgram/ml), reversed the blockade. Ovine FSH and rFSH had only a weak stimulatory effect on estradiol release, and only rFSH caused a significant increase in progesterone accumulation. Indomethacin reduced the stimulatory effect of rFSH on progesterone release, and this effect was reversed by PGE2 but not by PGF2 alpha. In a 6-h incubation experiment with preovulatory rat follicles, we tested the biological activity of gonadotropins used to induce oocyte maturation. The concentration of FSH used in the perfusion experiments induced oocyte maturation in more than 88% of the oocytes studied. The data confirm earlier findings that FSH can induce ovulations and show that prostaglandins are involved in this process. The data also indicate that prostaglandins might be involved in the FSH-induced increase of progesterone levels.     

Effects of inhibitors of protein synthesis on the ovulatory process of the perfused rat ovary

The effects of two different protein synthesis inhibitors (cycloheximide and puromycin) on the ovulatory process were examined in vitro using a perfused rat ovary model. Ovaries of PMSG (20 i.u.)-primed rats were perfused for 21 h. Release of cyclic adenosine 3',5'-monophosphate (cAMP) and steroids (progesterone, testosterone, and oestradiol) was measured and the number of ovulations was estimated by counting released oocytes. Unstimulated control ovaries did not ovulate whereas addition of LH (0.1 microgram/ml) plus 3-isobutyl-1-methylxanthine (IBMX; 0.2 mM) resulted in 16.7 +/- 3.5 ovulations per treated ovary. Cycloheximide (5 micrograms/ml) totally inhibited the ovulatory effect of LH + IBMX when present from the beginning of the perfusions and also when added 8 h after LH + IBMX. No inhibition was seen when cycloheximide was added 10 h after LH + IBMX (1-1.5 h before the first ovulation; 15.2 +/- 4.4 ovulations per treated ovary). Puromycin (200 micrograms/ml) completely blocked ovulation when present from the beginning of the perfusions and the inhibition was congruent to 60% (6.5 +/- 2.2 ovulations per treated ovary) when the compound was added 8 h after LH + IBMX. Both inhibitors increased LH + IBMX-stimulated cAMP release substantially, but decreased the release of progesterone, testosterone and oestradiol. These results indicate that de-novo protein synthesis is important late in the ovulatory process for follicular rupture to occur.     

Ovarian and endocrine responses to prostaglandin F2alpha (PGF2alpha) given at the expected time of the endogenous FSH peak at mid-cycle in ewes

In the ewe, a rise in circulating concentrations of FSH preceding follicular wave emergence begins in the presence of growing follicles from a previous wave. We hypothesized that prostaglandin F(2alpha) (PGF(2alpha)) given at the time of an endogenous FSH peak in cyclic ewes would result in synchronous ovulation of follicles from two consecutive waves, increasing ovulation rate. Twelve Western White Face (WWF) ewes received a single i.m. injection of PGF(2alpha) (15 mg/ewe) at the expected time of a peak in FSH secretion, from Days 9 to 12 after ovulation. The mean ovulation rate after PGF(2alpha) treatment (2.3+/-0.3) did not differ (P>0.05) from the pre-treatment ovulation rate (1.7+/-0.1). Five ewes ovulated follicles from follicular waves emerging before and after PGF(2alpha) injection (3.0+/-0.6 ovulations/ewe) and seven ewes ovulated follicles only from a wave(s) emerging before PGF(2alpha) treatment (2.0+/-0.3 ovulations/ewe; P>0.05). The mean interval from PGF(2alpha) to emergence of the next follicular wave (1.0+/-0.4 and 4.0+/-0.0 d, respectively; P<0.001) and the interval from PGF(2alpha) treatment to the next FSH peak (0 and 3.5+/-0.4d, respectively; P<0.05) differed between the two groups. Six ewes ovulated after the onset of behavioral estrus, with a mean ovulation rate of 1.7+/-0.2, and six ewes ovulated both before and after the onset of estrus (3.0+/-0.5 ovulations/ewe; P<0.05). None of the ovulations that occurred before estrus resulted in corpora lutea (CL) with a full life span. At 24h before ovulation, follicles ovulating before or after the onset of estrus differed in size (4.1+/-0.3 or 5.5+/-0.4mm, respectively; P<0.05) and had distinctive echotextural characteristics. In conclusion, the administration of PGF(2alpha) at the expected time of an FSH peak at mid-cycle in ewes may alter the endogenous rhythm of FSH secretion and was not consistently followed by ovulation of follicles from two follicular waves. In non-prolific WWF ewes, PGF(2alpha)-induced luteolysis disrupted the normal distribution of the source of ovulatory follicles and may be associated with untimely follicular rupture and luteal inadequacy.     

Mechanism controlling ovulation rate in ewes in relation to seasonal anoestrus.

Three experiments were carried out during seasonal anoestrus in Finnish Landrace and Scottish Blackface ewes, to establish whether the differences between the breeds in ovulation rate are functional during the non-breeding season and are therefore independent of the mechanism controlling ovulation. In Expt 1, follicles greater than or equal to 2 mm in diameter were dissected from the ovaries of both breeds and incubated individually for 2 h to assess their ability to secrete oestradiol and testosterone. In both breeds, follicles producing greater than or equal to 500 pg oestrogen/ml/h (oestrogen-active) were readily identifiable from a population producing less (oestrogen-inactive). The number of oestrogen-active follicles in each breed was similar to the number of ovulations near the end of the breeding season. Oestrogen-active follicles also had more luteinizing hormone (LH) receptors and larger diameters than oestrogen-inactive follicles. There were, however, no significant differences between the two follicle types in follicular fluid or in-vitro testosterone concentrations. In Expt 2, seasonally anoestrous Scottish Blackface ewes were unilaterally ovariectomized; the second ovary was removed 7 days later. Follicles from both ovaries were processed as described for Expt 1; oestrogen-active follicles were categorized according to their ability to produce greater than 500 pg/ml/h. There were twice as many oestrogen-active follicles in the second ovary as in the first ovary; the number of oestrogen-active follicles in the second ovary was also similar to the total number of oestrogen-active follicles in both ovaries of the Scottish Blackface ewes in Expt 1.(ABSTRACT TRUNCATED AT 250 WORDS)     

Time-dependent ovulation inhibition of a selective progesterone-receptor antagonist (Org 31710) and effects on ovulatory mediators in the in vitro perfused rat ovary

Progesterone (P) is one of several local mediators in the ovulatory cascade in the rat. The precise mechanisms of action for P in ovulation and in what phase of the ovulatory process P is critical, however, need to be clarified. The present study used a selective P-receptor antagonist, Org 31710, in the in vitro perfused rat ovary model to examine the local role of P and possible effects on prostaglandin (PG) and plasminogen-activator (PA) release in ovulation. Ovaries from eCG (15 IU)-primed rats were perfused for 20 h with LH (0.2 microg/ml) and 3-isobutyl-1-methylxanthine (IBMX, 200 microM) to induce ovulation (median = 10.0, 25%-75% range = 8.5-13). Org 31710 was added at either 0, 3.5, 7, or 9 h after LH+IBMX, resulting in significant suppression of ovulation after addition at 0 and 3.5 h (1.0, 1-5.5; and 5.0, 2.5-7.75 ovulations, respectively) but no suppressive effect when added at later time points. Progesterone and estradiol levels in the perfusion media were increased after LH+IBMX but were not affected by the presence of Org 31710. Ovarian tissue levels of PGE(2), PGF(2 alpha), and PA activity were measured in ovaries that had been perfused for 10 h, a time that was 2 to 5 h before anticipated ovulation. The presence of Org 31710 significantly decreased the levels of PGE(2), PGF(2 alpha), and PA activity. These results suggest that P is essential in ovulation during the initial stages of the ovulatory process. The effect of P to facilitate ovulation seems to relate to stimulation of the PG- and PA-mediator systems.     

Hormonal dissociation of ovulation and maturation of oocytes: Ovulation of immature amphibian oocytes by prostaglandin

Prostaglandin involvement in ovulation and maturation of amphibian (Rana pipiens) ovarian follicular oocytes was investigated using in vitro-cultured ovarian follicles. Exposure of follicles to PGF₂α during culture stimulated variable but generally low levels of ovulation without concomitant induction of maturation. Addition of PGF₂α to cultured follicles markedly enhanced the incidence of ovulation in follicles exposed to progesterone or frog pituitary homogenate (FPH). Onset of the ovulatory process was further accelerated following addition of PGF₂α to FPH-treated follicles. PGE, in contrast to PGF₂α, exhibited no stimulatory effects on ovulation and consistently inhibited ovulation induction by FPH and progesterone. Cytological analysis of follicles undergoing ovulation revealed that ovulation of immature oocytes induced by PGF₂α varied markedly from that seen following FPH or progesterone stimulation of follicles in vivo or in vitro. Immature oocytes in contrast to maturing oocytes were typically ovlulated with follicle cells still attached to the vitelline membrane. The observations indicate that PGF₂α effected follicle rupture and contraction of the follicular epithelium and theca without prior separation of the follicle cells from the oocyte. Selective inhibitors of steroid synthesis (cyanoketone) and protein synthesis (cycloheximide) inhibited FPH-induced ovulation and maturation. PGF₂α reversed the inhibitory effects of cyanoketone and cycloheximide on FPH-induced ovulation but not maturation of oocytes. Neither prostaglandins alone or in combination with progesterone or FPH induced ovulation of oocytes following removal of the follicular epithelium. Ovulatory effects of PGF₂α appear to be mediated through the follicular epithelium. Results indicate that ovulation and maturation of amphibian oocytes can be induced independently of each other by separate classes of hormones. Normal synchronization of ovulation and maturation of oocytes may require the combined action of prostaglandins and steroids acting within different follicular compartments.     

Ultrasound and endocrine evaluation of the ovarian response to PGF2alpha given at different stages of the luteal phase in ewes

The purpose of this study was to evaluate the ovarian response of ewes to two treatments with PGF2alpha using transrectal ovarian ultrasonography and hormone measurements. Fifteen milligrams of PGF2alpha was given to six cyclic Western White Face (WWF) ewes early in the estrous cycle (Days 4 to 7) and to six late in the cycle (Days 10 to 12 after ovulation), and a second treatment was given 9 days after the first. Ultrasound scanning and blood sampling started 7 days prior to the first PGF2alpha treatment and ended 10 days (scanning) or 19 days (blood sampling) after the second PGF2alpha treatment, for both groups of ewes. Mean ovulation rate (2.6 +/- 0.7) did not differ significantly between the ewes first treated early or late in the cycle, or after the first or second treatments with PGF2alpha. The time from treatment to ovulation was longer in ewes first treated early (4.0 +/- 0.3 days) compared to late (2.8 +/- 0.4 days) in the cycle (P < 0.05). Both the number of ovulations (range: 0-7) and time from treatment to ovulation (range: 1-9 days) were highly variable. This variability appeared to be due to the extension of the life span of ovulating follicles that emerged prior to PGF2alpha administration and also ovulation of some follicles that emerged after treatment. When results for first and second treatments were pooled, the total number of follicles > 5 mm in diameter on the day of treatment that failed to ovulate in response to PGF2alpha was higher in ewes first treated early (0.8 +/- 0.2/ewe) compared to late (0.3 +/- 0.2/ewe) in the cycle (P < 0.05). The proportion of detected luteal structures relative to the number of ovulations was lower in ewes first treated early compared to late in the cycle (60 and 86%, respectively; P < 0.05). Disruption of ovulatory follicle dynamics and normal luteogenesis, and variability in the timing of ovulation after PGF2alpha treatments could all contribute to poor or variable fertility when prostaglandins are used for estrus synchronization.     

Pre-ovulatory changes in follicular fluid prostaglandin F levels in swine

The concentration of prostaglandin F (PGF) has been measured by radioimmunoassay in follicular fluid collected from follicles at various time intervals after treatment of prepuberal gilts with pregnant mare serum gonadotropin and human chorionic gonadotropin to induce ovulation. A high proportion of animals will ovulate 116 ± 8 hr after this treatment. Pre-ovulatory follicles can be identified on the basis of gross morphological appearance 10–12 hr before the predicted time of ovulation. The concentration of PGF in fluid from follicles judged not to be pre-ovulatory was relatively constant at about 0.45 ng per g and appeared to be independent of the time of sampling. An increase in the concentration of PGF was observed in fluid collected from follicles classified as destined to ovulate. This increase became more pronounced as the time of ovulation approached and reached a maximum at or about the time of follicle rupture.These data provide evidence in support of a role for prostaglandins in the ovulatory process in the pig.     

Pre-ovulatory changes in follicular fluid prostaglandin F levels in swine

The concentration of prostaglandin F (PGF) has been measured by radioimmunoassay in follicular fluid collected from follicles at various time intervals after treatment of prepuberal gilts with pregnant mare serum gonadotropin and human chorionic gonadotropin to induce ovulation. A high proportion of animals will ovulate 116 ± 8 hr after this treatment. Pre-ovulatory follicles can be identified on the basis of gross morphological appearance 10–12 hr before the predicted time of ovulation. The concentration of PGF in fluid from follicles judged not to be pre-ovulatory was relatively constant at about 0.45 ng per g and appeared to be independent of the time of sampling. An increase in the concentration of PGF was observed in fluid collected from follicles classified as destined to ovulate. This increase became more pronounced as the time of ovulation approached and reached a maximum at or about the time of follicle rupture.These data provide evidence in support of a role for prostaglandins in the ovulatory process in the pig.     

Efficacy of PGF(2alpha) to synchronize estrus in water buffalo cows (Bubalus bubalis) is dependent upon plasma progesterone concentration,corpus luteum size and ovarian follicular status before treatment

This study was conducted to identify factors affecting PGF(2alpha) efficacy to synchronize estrus in water buffalo cows. After detection of a corpus luteum (CL) by rectal palpation, cows were treated (im) with dinoprost (12.5, 25 or 50mg) or D(+) cloprostenol (75, 150 or 300 microg) in a total of 66 treatments. Blood samples were collected 0, 24 and 48 h after treatment and ultrasound examinations and observations for estrus were performed daily to the day of ovulation or to 6 days after treatment. No PGF(2alpha) dose-response pattern was observed and overall rates of luteal regression (progesterone <1.0 ng/ml at 48 h), estrus, no detected behavioral estrus with ovulation occurring, and ovulation were 71.2, 36.4, 19.7 and 54.5%, respectively. To analyze plasma progesterone concentrations and ovarian dynamics, cows were divided in three groups according to their response to treatment. Cows that failed to have ovulations from a follicle after treatment (Group A, n = 30) had (P < 0.05) a lower plasma progesterone concentration (2.98 ng/ml) and smaller CL area (CLA; 187.3 mm(2)) before treatment as compared with cows that had an ovulation from a follicle (4.43 ng/ml and 223.7 mm(2), respectively; Groups B and C, n = 36). In cows that failed to ovulate, plasma progesterone concentration decreased in the first 24 h, but did not decline further and was >1.0 ng/ml 48 h after treatment. Moreover, no significant change in CLA after treatment was detected, indicating that treatment induced only partial luteolysis. In cows that ovulated, plasma progesterone concentration and CLA decreased continuously from treatment to ovulation (consistent with complete luteolysis). Threshold values of 2.8 ng/ml for plasma progesterone concentration and 189 mm(2) for CLA were identified as the best predictors of ovulation before treatment (83.3 and 80.6% sensitivity and 58.6 and 65.5% specificity, respectively, with positive and negative predictive values around 71%). When the origin of the ovulatory follicle was investigated, the interval from treatment to ovulation was shorter (91.9 versus 113.3 h; P < 0.05), and the ovulatory follicle had a slower growth rate (1.02 versus 1.55 mm per day; P < 0.005), a lesser increase in diameter from treatment to ovulation (4.7 versus 8.0 mm; P < 0.001), and a greater maximum diameter (13.2 versus 12.1 mm; P < 0.05) in cows that ovulated from the largest follicle present in the ovary before treatment (Group B, n = 27) compared with cows that ovulated from the second largest follicle present in the ovary before treatment (Group C, n = 9). In summary, the efficacy of PGF(2alpha) for causing luteolysis and synchronizing estrus and ovulation in buffalo cows was dependent upon plasma progesterone concentration, CL size and ovarian follicular status before treatment.     

Comparison of the effect of nonsteroidal and steroidal antiinflammatory agents on prostaglandin production during ovulation in the rabbit

The antiinflammatory agents diclofenac, fenoprofen and aspirin were tested to determine how well they inhibit the pre-ovulatory elevation in prostaglandin (PG) production in rabbit follicles in comparison to indomethacin. In addition, the antiinflammatory agent dexamethasone and the antipyretic agent acetaminophen were tested. The agents were administered 8 h after the ovulatory process was stimulated by hCG (50 I.U./kg). At 10 h after hCG (i.e., at the expected time of ovulation) control follicles had PGF and PGE levels of 370.0 and 582.6 pg/mg of follicle, respectively. Diclofenac inhibited PG production the most-reducing PGF and PGE to 22.8 and 53.6 pg/mg, respectively. Indomethacin reduced the PGF and PGE levels to 27.4 and 76.6 pg/mg, respectively. Fenoprofen was less effective, reducing the PGF and PGE to 77.8 and 222.4 pg/mg, respectively. Aspirin reduced the PGF and PGE to 123.4 and 174.6 pg/mg, respectively. Dexamethasone and acetaminophen did not inhibit PG production. Ovulation was completely inhibited by diclofenac and indomethacin, partially inhibited by fenoprofen, and unaffected by aspirin, acetaminophen, or dexamethasone. The results suggest that any potent antiinflammatory agent can inhibit ovulation provided it adequately reduces PG production; whereas antiinflammatory agents are ineffective. The anti-inflammatory agent must completely abolish the preovulatory elevation in PGs in mature follicles in order to totally inhibit ovultion.     

Luteolysis, estrus and ovulation, and blood prostaglandin F after intramuscular administration of 15, 30 or 60 mg prostaglandin F2α

During diestrus in three consecutive estrous cycles, each of six heifers was given (im) 30 mg, 15 mg (twice at 6-hr intervals) and 60 mg prostaglandin F_2α (PGF_2α) tham salt. Neither the decline in blood progesterone, the increase in blood estradiol, the duration or the peak of the LH surge, the interval to onset of estrus, nor the interval to ovulation was affected significantly by dose of PGF_2α. Thus, relative to that after 30 mg PGF_2α im, two injections of 15 mg at 6-hr intervals or 60 mg PGF_2α did not hasten luteolysis. Thirty mg was an ample im dose of PGF_2α to cause luteolysis. Regardless of im dose of PGF_2α, blood PGF peaked at about 6.0 ng/ml within 10 minutes and returned to basal values (<1.0 ng/ml) within 90 minutes. In another trial, after a single iv injection of 5 mg PGF_2α, blood PGF peaked (25 ng/ml) within 5 minutes and returned to basal values within 15 minutes. During a 30-minute infusion (0.5 mg/minute) of PGF_2α, blood PGF plateaued at 29.5 ng/ml with a metabolic clearance rate of 17.0 liters per minute.     

Pre-ovulatory changes in follicular fluid prostaglandin F levels in swine.

The concentration of prostaglandin F (PGF) has been measured by radioimmunoassay in follicular fluid collected from follicles at various time intervals after treatment of prepuberal gilts with pregnant mare serum gonadotropin and human chorionic gonadotropin to induce ovulation. A high proportion of animals will ovulate 116 +/- 8 hr after treatment. Pre-ovulatory follicles can be identified on the basis of gross morphological apperance 10-12 hr before the predicted time of ovulation. The concentration of PGF in fluid from follicles judged not to be pre-ovulatory was relatively constant at about 0.45 ng per g and appeared to be independent of the time of sampling. An increase in the concentration of PGF was observed in fluid collected from follicles classified as destined to ovulate. This increase became more pronounced as the time of ovulation approached and reached a maximum at or about the time of follicle rupture. These data provide evidence in support of a role for prostaglandins in the ovulatory process in the pib.     

Interrelationships between prostaglandins, cyclic AMP and steroids in ovulation.

Ovulation is a complex phenomenon, involving a series of biochemical events within the ovary, leading to the rupture of the follicle. This paper summarizes recent studies in our laboratory of some of these biochemical changes using the rabbit as an experimental model. It has been shown in our laboratory that isolated Graafian follicles obtained from oestrous rabbits synthesize steroids and cyclic AMP when incubated in vitro. Luteinizing hormone added to the incubation medium increased steroidogenesis and cyclic AMP synthesis many fold. When follicles were isolated from rabbits at different times following the ovulatory stimulus (mating or HCG injection) it was found that the in vitro response to LH in terms of steroidogenesis and cylcic AMP synthesis was lost as ovulation approached. In contrast, when prostaglandins (PGF and PGE) were measured in rabbit Graafian follicles it was found that the PGF and PGE levels increased as ovulation approached. From these data and from reports in the literature, we have developed a hypothetical model for ovulation in the rabbit which may help in a better understanding of the ovulatory process.     

Effectiveness of prostagland in F2α in restoration of HMG-HCG induced ovulation in indomethacin-treated rhesus monkeys

Six mature female rhesus monkeys were treated with HMG-HCG in control cycles at doses adjusted to induce ovulation while avoiding superovulation. Occurrence of ovulation was determined by observation of fresh ovulation points at laparotomy 48 to 120 hours following HCG. In subsequent cycles animals were treated with indomethacin (treatment days 4 through 10) together with the established dose of HMG-HCG. In 8 cycles indomethacin 5 mg/kg was given i.m. once daily; in 9 cycles 10 mg/kg i.m. was administered in 2 divided doses. Following this, PGF₂α (3 mg t.i.d. s.c.) was administered for 3 days together with indomethacin 10 mg/kg and HMG-HCG, beginning on the day prior to HCG. Determinations of progesterone were performed by RIA on treatment days 4, 7, 10, and 11. Eleven of the 13 control cycles were ovulatory. With indomethacin 5 mg/kg/day, 5 of 8 cycles were ovulatory but ovulation was delayed in 2 instances. Of 9 cycles using indomethacin 10 mg/kg/day only 1 was ovulatory. When PGF₂α was administered in subsequent cycles along with indomethacin (10 mg/kg) and HMG-HCG, ovulation occurred in 13 of 19 cycles. These data suggest that local ovarian PGF₂α may be essential in the mechanics of follicle rupture in gonadotropin-treated rhesus monkeys.     

Prostaglandin F2α-induced stimulation of estrone and estradiol-17β secretion in cattle

Four of 5 Holstein heifers given intra-ovarian injections of 300 μg of prostaglandin F_2α (PGF_2α) showed transient, but statistically significant, depressions in plasma progesterone levels which returned to near normal levels within 24 hr. The same 4 animals also exhibited significant elevations in plasma estrone and estradiol-17β levels during the initial 24 hr. period following treatment, although no animals were observed in estrus during this time. Plasma levels of progesterone, estrone, estradiol-17β and PGF showed little change in control heifers receiving intra-ovarian injections of the buffer solution used as a vehicle for PGF_2α. It is concluded that PGF_2α stimulates estrogen secretion, presumably by follicular elements of the ovary.     

Plasma endotoxin and concentrations of stable metabolites of prostacyclin, thromboxane A2, and prostaglandin E2 in postpartum dairy cows

The presence of endotoxin in plasma and patterns of stable metabolites of prostacyclin (PC), thromoxane A₂ (TXA₂) and prostaglandin E₂ (PGE₂) were determined during the first postpartum estrous cycles in sixteen dairy cows. These included 8 cows with uterine infections which exhibited shortened luteal phases (SC) and 8 cows which had normal luteal phases (NC) after the first post partum ovulations. Endotoxin was consistently detected in all SC cows during the abbreviated estrous cycles while plasma samples of NC cows were free of endotoxin. Plasma concentrations of TXA₂ metabolite was higher in SC cows (p<0.05) (1785–3452 pg/ml) compared to NC cows (723–1240 pg/ml). Similarly, plasma concentrations of PC metabolite was higher in SC cows (p<0.07) (423–1847 pg/ml) compared to NC cows (159–325 pg/ml). In contrast, plasma concentrations of PGE₂ metabolite was higher in NC cows (p<0.05) (850–2219 pg/ml) compared to SC cows (455–628 pg/ml). The results of this study suggest that postpartum uterine infections mediate the release of prostaglandins from the uteri by means of the endotoxin and endotoxin appears to stimulate selectively the production of PC and TXA₂ favoring early demise of corpora lutea formed after first postpartum ovulations in dairy cows.     

Corpus luteum function following single and double ovulation during estrous cycle in Sanjabi ewes

This study compared the effect of double and single ovulation on serum progesterone concentrations and luteal characteristics in Sanjabi ewes at different days of the estrous cycle. The estrous cycles of 197 Sanjabi ewes were synchronized by a 12-day treatment with intravaginal sponges (Chronogest^®). Estrus was detected in 144 ewes 27–39 h after sponge removal. Daily blood samples were taken every morning and analyzed for serum progesterone (P4). Ewes were then transported to a local abattoir, where nine ewes were slaughtered on each experimental day (days 1–16 after estrus) for ovary collection. The ovarian follicles were measured and categorized by size (very small <2 mm; small 2–3.5 mm; medium 3.5–5 mm; large >5 mm). On each slaughter day, the number of corpora lutea per ewe was classified as single and double ovulation. The results show that the effect of dominant follicles was less during the mid-luteal phase. Ovulation rate of right, left and both ovaries were (54.9%), (23.6%) and (21.5%), respectively. The incidence of double ovulations was 40.2%. In the case of ewes exhibiting double ovulation, 46.6% occurred unilateral (ewes exhibited both ovulations on the right ovary); whereas 53.4% occurred bilateral (ewes exhibited ovulations on the right and left ovaries). Unilateral double ovulation was not observed in the left ovary. The right ovary appeared to play a significantly greater role in ewes showing single and double ovulations than the left ovary (P < 0.05). Serum progesterone concentration showed minimum and maximum levels of 0.29 ± 0.15 and 5.51 ± 0.75 ng/ml on days 16 and 11 post-estrous, respectively (P < 0.001). The mean volume of individual corpus lutea in ewes with single ovulations was significantly higher than in ewes with double ovulations (P < 0.01). However, the total volume of corpus lutea in ewes with single ovulation was significantly lower than in ewes with double ovulations in some days of estrous cycle (P < 0.01). The serum progesterone concentration was significantly higher in double than single ovulating animals on days 1–16 of the estrous cycle (P < 0.001). These results indicated a relatively high incidence of double ovulation in ewes associated with increasing total luteal volume and high circulating concentrations of progesterone.