Reversal of indomethacin blockade of ovulation in gilts by prostaglandins

Prepubertal gilts given 750 IU pregnant mares′ serum gonadotropin (PMSG) followed 72 h later by 500 IU human chorionic gonadotropin (hCG) to induce follicular growth and ovulation fail to ovulate when 10 mg/kg indomethacin (INDO) is injected 24 h after hCG administration. This study examines the effects of administration of exogenous prostaglandins F_2α and E₂ (PGF_2α and PGE₂) alone or in combination, and at various times prior to the expected time of ovulation, on the INDO blockade of ovulation in PMSG/hCG-treated gilts. Occurrence of ovulation was determined by visual observation at laparotomy 48 h after hCG. When 5 mg or 10 mg PGF_2α was injected at each of 38, 40 and 42 h after hCG injection, 63% and 79%, respectively, of preovulatory follicles ovulated. In contrast, injection of 5 mg PGE₂ or 5 mg PGE₂ plus 5 mg PGF_2α induced ovulation in 0% and 24% of preovulatory follicles, respectively. In control groups, 100% of folicles in PMSG/hCG-treated gilts ovulated whereas none did so in PMSG/hCG/INDO-treated animals. These results indicate that administration of PGF_2α can induce ovulation in the PMSG/hCG/INDO-treated prepubertal gilt and suggest that PGE₂ is ineffective and may be antagonistic to PGF_2α in overcoming the ovulation blocking effect of INDO.     

Effect of indomethacin and 7-oxa-13-prostynoic acid on luteinization of transplanted rat ovarian follicles induced by luteinizing hormone and prostaglandin E2

The ability of prostaglandin E₂ (PGE₂) to initiate luteinization was demonstrated using a system of in vitro incubation of ovarian follicles followed by transplantation. Follicles from diestrous rats were incubated with 0.05 to 50 μg/ml PGE₂, 10 μg/ml luteinizing hormone (LH), or alone in Krebs-Ringer bicarbonate buffer plus glucose for 2 hr. Then follicles were transplanted under the kidney capsules of hypophysectomized recipients, with follicles exposed to PGE₂ on one side and those exposed to LH or buffer only on the other side. As determined at autopsy 4 days later and confirmed by histological examination, follicles exposed to PGE₂ at concentrations of 0.5 μg/ml or greater, or to LH, transformed into corpora lutea, but control follicles regressed. Incubation of follicles with LH in the presence of indomethacin, an inhibitor of prostaglandin synthesis, significantly reduced the incidence of luteinization. Prostaglandin E₂ (10 μg/ml) was able to override the inhibition of luteinization by indomethacin (150 μg/ml). The prostaglandin analogue 7-oxa-13-prostynoic acid (100 μg/ml) failed to prevent luteinization in response to either 5 μg/ml LH or 1 μg/ml PGE₂. Results with PGE₂ and with indomethacin suggest a role for prostaglandins in the luteinizing action of LH.We have reported previously that in vitro exposure of diestrous rat follicles to luteinizing hormone (LH) will result in transformation of the follicles to corpora lutea following transplantation under the kidney capsules of hypophysectomized rats. Dibutyryl cyclic AMP (DBC) mimics this effect of LH, and transplants produce progesterone in measurable amounts after both LH and DBC exposure when prolactin is administered in vivo to recipients.Kuehl et al. have suggested that prostaglandins may act as obligatory intermediates in the effect of LH on the ovary, acting between LH and adenylate cyclase. Preliminary results indicated that prostaglandin E₂ (PGE₂) could induce luteinization in our system. The extent of prostaglandin involvement in luteinization was further investigated in this work, using two reported antagonists of prostaglandin action, indomethacin and 7-oxa-13-prostynoic acid. Indomethacin has been found to inhibit synthesis of prostaglandins E₂ and F_2α; 7-oxa-13-prostynoic acid, which acts as a competitive antagonist of prostaglandins, prevented the effect of LH and prostaglandins E₁ and E₂ on cyclic AMP production in mouse ovaries.     

The role of prostaglandins in the development of refractoriness to LH stimulation by graafian follicles

The possibility that prostaglandins might be responsible for the development of the pre-ovulatory refractoriness to the stimulation by LH of cyclic AMP accumulation in the Graafian follicle was examined. Isolated rabbit Graafian follicles were obtained at estrus and at 0.5, 5 and 9 hours after an ovulatory dose of LH. The follicles were incubated in the presence of [8-³H]adenine and the accumulation of [8-³H]cyclic AMP measured. Follicles from estrous animals responded to the addition of LH with a marked increase of cyclic AMP accumulation and lost this response as the time of ovulation approached. Animals pretreated with indomethacin, which inhibits the usual pre-ovulatory rise of follicular prostaglandin levels, showed essentially the same loss of responsiveness. Indomethacin alone was without effect. It is concluded that prostaglandins are not the major factor in the development of refractoriness to LH stimulation which has been observed in pre-ovulatory follicles.     

Influence of prostaglandin F autoantibodies on the estrous cycle of the guinea pig

Adult female guinea pigs were actively immunized with prostaglandin F_2α conjugated to bovine serum albumin (BSA). Control animals, immunized against BSA continued to cycle normally, while the animals immunized against prostaglandin F_2α stopped cycling after one to three normal cycles. Laparotomy at 30 days after the last estrus revealed no recently formed corpora lutea. During the remaining 70 days of observation the antibody titer increased to 1:700, accompanied by increasing total serum estrogens (136 pg/ml at day 100) and a slow decline in circulating progesterone levels (0.6 ng/ml at day 100). The ovaries at day 100 contained degenerated corpora lutea and luteinized follicles. The suppression of the estrous cycle in the present experiments was interpreted as resulting from prolongation of luteal function as well as from inhibition of ovulation.     

Development in the cyclic hamster of refractoriness to the superovulatory action of anti-LH serum

Hamsters injected s.c. on the day of ovulation (Day 1) with 100 microliters equine anti-bovine LH serum ovulated 28 eggs at the end of a 5-day cycle. When a second injection of anti-LH serum was administered 4-93 days later, the animals did not superovulate and had normal 4-day cycles. Injection of 100 microliters normal rabbit serum (NRS) on Day 1 followed 14 days later by anti-LH serum resulted in the ovulation of 32 ova whereas a priming injection of 100 microliters normal horse serum (NHS) followed by anti-LH serum resulted in the ovulation of only 18 ova. When hamsters were injected on Day 1 with anti-LH serum, NHS or NRS and then with anti-LH serum in the 4th cycle, high titres of free antibodies to LH were present on Days 2-4 only in the animals treated with NRS; these hamsters ovulated a mean of 35 ova. These experiments suggest that the hamster rapidly forms antibodies to equine immunoglobulins, thus preventing a second injection of anti-LH serum from inducing superovulation.     

Ovulation rate and serum LH levels in rats treated with indomethacin or prostaglandin E2

Serum LH levels were determined by radioimmunoassay at the normal time of the proestrous LH peak (17.30 – 18.00) and ovulatory performance was examined on the morning of estrus in rats treated with indomethacin, an inhibitor of prostaglandin synthesis. When the drug was administered at 14.30 on the day of proestrus, only 21% of the rats ovulated and the total number of ova shed was reduced to 4% of that found in the untreated control group, but there was no significant change in peak serum LH level (1122 ± 184 vs. 975 ± 240 ng/ml ± S.E., treated vs. control). Prostaglandin E₂ (PGE₂) given late on the day of proestrus (25 to 750 μ g/rat at 24.00) was effective in overcoming this antiovulatory action of indomethacin: 71–90% of the rats ovulated, though the number of eggs shed was low (24–55% of control value). Indomethacin was still effective in blocking ovulation when given at 20.00, that is after completion of the proestrous LH surge, but not at 24.00. Administration of PGE₂ (2 × 750 μ g/rat) in the early afternoon of proestrus elicited a rise in serum LH levels in rats in which the cyclic LH surge had been blocked with Nembutal (470 ± 87 vs. 106 ± 17 ng/ml ± S.E.) and induced ovulation in two-thirds of these animals.The results confirm, by direct measurement, that indomethacin does not block LH release but interferes with a late phase of the ovulatory process. PGE₂ reverses this action of indomethacin on the ovary. In addition, PGE₂ has a central effect causing LH release.     

The role of prostaglandins in the development of refractoriness to LH stimulation by Graafian follicles.

The possibility that prostaglandins might be responsible for the development of the pre-ovulatory refractoriness to the stimulation by LH of cyclic AMP accumulation in vitro in the Graafian follicle was examined. Isolated rabbit Graafian follicles were obtained at estrus and at 0.5, 5 and 9 hours after an ovulatory dose of LH. The follicles were incubated in vitro in the presence of (8-3H)adenine and the accumulation of (8-3H)cyclic AMP measured. Follicles from estrous animals responded to the in vitro addition of LH with a marked increase of cyclic AMP accumulation and lost this response as the time of ovulation approached. Animals pretreated with indomethacin, which inhibits the usual pre-ovulatory rise of follicular prostaglandin levels, showed essentially the same loss of responsiveness. Indomethacin alone was without effect. It is concluded that prostaglandins are not the major factor in the development of refractoriness to LH stimulation in vitro which has been observed in pre-ovulatory follicles.     

Male-induced short oestrous and ovarian cycles in sheep and goats: a working hypothesis

The existence of short ovulatory cycles (5-day duration) after the first male-induced ovulations in anovulatory ewes and goats, associated or not with the appearance of oestrous behaviour, is the origin of the two-peak abnormal distribution of parturitions after the "male effect". We propose here a working hypothesis to explain the presence of these short cycles. The male-effect is efficient during anoestrus, when follicles contain granulosa cells of lower quality than during the breeding season. They generate corpora lutea (CL) with a lower proportion of large luteal cells compared to small cells, which secrete less progesterone, compared to what is observed in the breeding season cycle. This is probably not sufficient to block prostaglandin synthesis in the endometrial cells of the uterus at the time when the responsiveness to prostaglandins of the new-formed CL is initiated and, in parallel, to centrally reduce LH pulsatility. This LH pulsatility stimulates a new wave of follicles secreting oestradiol which, in turn, stimulates prostaglandin synthesis and provokes luteolysis and new ovulation(s). The occurrence of a new follicular wave on days 3-4 of the first male-induced cycle and the initiation of the responsiveness to prostaglandins of the CL from day 3 of the oestrous cycle are probably the key elements which ensure such regularity in the duration of the short cycles. Exogenous progesterone injection suppresses short cycles, probably not by delaying ovulation time, but rather by blocking prostaglandin synthesis, thus impairing luteolysis. The existence, or not, of oestrous behaviour associated to these ovulatory events mainly varies with species: ewes, compared to does, require a more intense endogenous progesterone priming; only ovulations preceded by normal cycles are associated with oestrous behaviour. Thus, the precise and delicate mechanism underlying the existence of short ovulatory and oestrous cycles induced by the male effect appears to be dependent on the various levels of the hypothalamo-pituitary-ovario-uterine axis.     

Prostaglandins involvement in the formation of luteinized unrupted follicles in the cyclic female rat

The purpose of this investigation was to study the role played by prostaglandins in advanced ovulation and in the formation of luteinized unrupted follicles (LUF) in cyclic female rats. Dose related effects on ovulation were observed in rats given LH on diestrus 2 at 16.30. A significant positive correlation was observed between the number of postovulatory corpura lutea (POCL) and the increasing doses of LH. By contrast the number of LUF was negatively correlated with LH. Indomethacin treatment by 6h30 after administration of an ovulatory LH dose significantly increased the occurence of LUF at the expense of POCL. Conversely PGF_2α when admiststered by 6h30 after a subovulatory LH stimulation enhanced in a dose dependent manner the number of POCL with respect to the LH treated controls. Under a similar treatment with a subovulatory dose of LH, PGE₂ remained without ovulatory effects. The mechanisms of the formation of LUF are discussed on the basis of these results.     

Effects of systemic and intrafollicular injections of LH,prostaglandins, and indomethacin on the luteinization of rabbit Graafian follicles

The possibility that initiation of luteinization in ovarian follicles by luteinizing hormone (LH) is mediated by prostaglandins (PG's) was investigated in rabbits. Estrous rabbits, given an ovulatory dose of LH (50 μg) intravenously, were administered indomethacin (IM), an inhibitor of PG biosynthesis, by various routes. Progesterone levels in the serum and in the induced corpora lutea (CL) were subsequently measured by radioimmunoassay. Continued daily subcutaneous injections of IM from 2 days before through 2 days after LH treatment reduced the corpus luteal level, measured at 72 hours post-LH, of PGF from 208 ± 43 to 98 ± 20 pg/CL (P < 0.025) and that of PGE from 272 ± 31 to 115 ± 9 pg/CL (P < 0.005). At the same time, progesterone levels were 72 ± 12 and 93 ± 10 ng/CL (P > 0.05) in the oil-treated and IM-treated rabbits, respectively. Serum progesterone continued to rise in a linear fashion during the period from 24 to 72 hours following LH treatment, whether IM was injected or not. Intrafollicular treatment with LH (100 ng/follicle) raised the progesterone content in the treated follicles 72 hours later from 1.1 ± 0.5 to 50.1 ± 13.5 ng. (P < 0.01). This progesterone content reached 21.5 ± 15.8 ng (P < 0.05) in follicles similarly treated with PGE₂ (5 μg/follicle), but remained meagre at lower doses of PGE₂ (100 ng/follicle and 2 ng/follicle). Serum progesterone increased from 0.5 ± 0.1 to 1.2 ± 0.1 ng/ml (P < 0.005) within 72 hours in rabbits treated intrafollicularly with LH, but remained unaltered in those similarly treated with PGE₂ (P > 0.1). Intrafollicular injections with PGF_2α failed to induce changes in either level of progesterone. It is concluded that prostaglandins probably do not mediate the luteinizing action of LH in rabbit Graafian follicles, although some degree of luteinization can be induced by high levels of exogenous PGE₂.     

Prostaglandin synthesis in rabbit graafian follicles in vitro. Effect of luteinizing hormone and cyclic AMP

We have demonstrated the capacity of isolated follicles from estrous rabbits to synthesize prostaglandins in vitro and to respond to gonadotropins added to the incubation medium with an increased accumulation of these lipids. The increase in both prostaglandins became apparent only after 5 hours of incubation. The effect was specific for hormones with LH activity and the threshold dose of LH appeared to be 0.005 μg/ml. In addition, we have shown that cyclic AMP (0.02 M) added to the incubation medium also increased prostaglandin in this in vitro system and appears to be a likely mediator of this action of LH.     

Prostaglandin production by dispersed granulosa and theca interna cells from porcine preovulatory follicles

Prepubertal gilts were treated with 750 IU pregnant mares' serum gonadotropin (PMSG) and 72 h later with 500 IU human chorionic gonadotropin (hCG) to induce follicular growth and ovulation. Dispersed granulosa (GC) and theca interna (TIC) cells were prepared by microdissection and enzymatic digestion from follicles obtained 36, 72 and 108 h after PMSG treatment and incubated for up to 6 h in a chemically defined medium in the presence or absence of arachidonic acid, follicle-stimulating hormone (FSH), luteinizing hormone (LH) and indomethacin. Production of prostaglandin E2 (PGE) and prostaglandin F2 alpha (PGF) was measured by radioimmunoassay. Both GC and TIC had the capacity to produce prostaglandins, with production by each cell type increasing markedly with follicular maturation. PGE was the major prostaglandin produced by both cellular compartments. Only PGE production by GC was consistently enhanced by addition of arachidonic acid to the incubation medium. Neither cell type was responsive to FSH and LH in vitro. Indomethacin inhibited the production of PGE and PGF by both cell types. These results provide convincing evidence for an intrafollicular source of prostaglandins and indicate that both cellular compartments contribute significantly to the increased production of prostaglandins associated with follicular rupture.     

Timing of the onset and duration of ovulation in superovulated beef heifers

Thirty-two beef heifers were induced to superovulate by the administration of follicle stimulating hormone-porcine (FSH-P). All heifers received 32 mg FSH-P (total dose) which was injected twice daily in decreasing amounts for 4 d commencing on Days 8 to 10 of the estrous cycle. Cloprostenol was administered at 60 and 72 h after the first injection of FSH-P. Heifers were observed for estrus every 6 h and were slaughtered at known times between 48 to 100 h after the first cloprostenol treatment. The populations of ovulated and nonovulated follicles in the ovaries were quantified immediately after slaughter. Blood samples were taken at 2-h intervals from six heifers from 24 h after cloprostenol treatment until slaughter and the plasma was assayed for luteinizing hormone (LH) concentrations. The interval from cloprostenol injection to the onset of estrus was 41.3 +/- 1.25 h (n = 20). The interval from cloprostenol injection to the preovulatory peak of LH was 43.3 +/- 1.69 h (n = 6). No ovulations were observed in animals slaughtered prior to 64.5 h after cloprostenol (n = 12). After 64.5 h, ovulation had commenced in all animals except in one animal slaughtered at 65.5 h. The ovulation rate varied from 4 to 50 ovulations. Approximately 80% of large follicles (> 10 mm diameter) had ovulated within 12 h of the onset of ovulation. Onset of ovulation was followed by a dramatic decrease in the number of large follicles (> 10 mm) and an increase in the number of small follicles (相似文献   

Disruption of cellular associations within the granulosal compartment of periovulatory ovine follicles: Relationship to maturation of the oocyte and regulation by prostaglandins

Summary Temporal relationships were defined in sheep between the onset of the preovulatory surge of luteinizing hormone (LH; 0 h), dispersion of mural granulosal cells and cumulus oophorus, resumption of meiosis of the oocyte, and ovulation. A quantitative increase in intercellular spacing among mural granulosal and cumulus cells was detected at the light-microscopic level 12 h following the onset of the surge of LH. Evidence of breakdown of the germinal vesicle of oocytes was apparent at 16 h and thereafter. Ovulation occurred near 24 h. Systemic administration of indomethacin, an inhibitor of prostaglandin/PG biosynthesis, at 8 h subsequently prevented dissociation of mural granulosal and cumulus cells and suppressed maturation of the oocyte. The action of the drug was reversed by intrafollicular injection of PGE₂ at 12 h; PGF₂ was ineffective in this regard. Prostaglandin E₂ appears to be involved in preovulatory ovine follicles in the dissolution of cell-to-cell contacts and in maturation of the oocyte.     

Effects of inhibitors of steroid biosynthesis on prostaglandin formation in rabbit ovarian follicles

Rabbit ovarian follicles were incubated without stimulation, with LH and with LH + an inhibitor of steroid biosynthesis. Formation of prostaglandins PGE and PGF and of progesterone and estradiol was measured in these incubates. It was found that aminoglutethimide phosphate (AGP) inhibited the LH stimulated biosynthesis of both prostaglandins and steroids. However U 30870 and Metyrapone, while completely inhibiting the LH stimulated biosynthesis of progesterone and estradiol respectively, had no effect on the formation of prostaglandins. Further, the inhibition of prostaglandin formation by AGP could not be reversed by exogenous steroids. It, therefore, appears that the effect of AGP on prostaglandin biosynthesis may not be related to its effect on steroid biosynthesis. However, the response of rabbit follicles to AGP is contrary to that reported for rat follicles and indicates different control mechanisms for prostaglandin formation in the follicles of the two species.     

Effects of inhibitors of steroid biosynthesis on prostaglandin formation in rabbit ovarian follicles

Rabbit ovarian follicles were incubated without stimulation, with LH and with LH + an inhibitor or steroid biosynthesis. Formation of prostaglandins PGE and PGF and of progesterone and estradiol was measured in these incubates. It was found that aminoglutethimide phosphate (AGP) inhibited the LH stimulated biosynthesis of both prostaglandins and steroids. However U 30870 and Metyrapone, while completely inhibiting the LH stimulated biosynthesis of progesterone and estradiol respectively, had no effect on the formation of prostaglandins. Further, the inhibition of prostaglandin formation by AGP could not be reversed by exogenou steroids. It, therefore, appears that the effect of AGP on prostaglandin biosynthesis may not be related to its effect on steroid biosynthesis. However, the response of rabbit follicles to AGP is contrary to that reported for rat follicles and indicates different control mechanisms for prostaglandin formation in the follicles of the two species.     

Biosynthesis of prostaglandins in human ovarian tissues

Experiments in vitro demonstrate, that there are different patterns of PG-biosynthesis in the corpus luteum and in the follicles containing cortical substance of the human ovary. In the follicles 6-keto-F₁α. the transformation product of prostacyclin, is the main fraction; prostaglandins F₂α and E 2 being of inferior importance with regard to their amounts. The formation of the corpus luteum is in close correlation with a strongly increased prostaglandin E₂ and a diminished prostacyclin biosynthesis; prostaglandin F₂α hardly seems to be involved in this process.By means of indomethacin the formation of all three examined prostaglandins can be prevented almost completely, in the cortical substance as well as in the corpus luteum. LH (or HCG) at concentrations ranging from 2 ng to 20 μg per ml homogenate produce no stimulating effect of statistical significance on the rate of biosynthesis in both tissues.     

Pre and post ovulatory changes in the concentration of prostaglandins in rat Graafian follicles

The concentrations of prostaglandin F (PGF) and prostaglandin E (PGE) were measured by radioimmunoassay in isolated GRaafian follicles of mature female rats during the pre and post ovulatory period of the estrous cycle. The levels of these prostaglandins were low and relatively constant from 8 a.m. to 4 p.m. on the day of proestrus, but there was a marked increase at 8 p.m. of proestrus reaching an apparent maximum at midnight (PGF 18 fold, PGE 70 fold). By 4 a.m. to 8 a.m. on the morning of estrus these prostaglandins declined rapidly to levels similar to those observed between 8 a.m. and 4 p.m. on the day of proestrus. The increases in prostaglandin levels occurred after the LH peak and apparently before the time of ovulation. These data confirm the role of PGF and PGE in the local mechanism of ovulation in the normal adult of a spontaneously ovulating animal species.     

Pre and post ovulatory changes in the concentration of prostaglandins in rat graafian follicles.

The concentrations of prostaglandin F (PGF) and prostaglandin E (PGE) were measured by radioimmunoassay in isolated Graafian follicles of mature female rats during the pre and post ovulatory period of the estrous cycle. The levels of these prostaglandins were low and relatively constant from 8 a.m. to 4 p.m. on the day of proestrus, but there was a marked increase at 8 p.m. of proestrus reaching an apparent maximum at midnight (PGF 18 fold, PGE 70 fold). By 4 a.m. to 8 a.m. on the morning of estrus these prostaglandins declined rapidly to levels similar to those observed between 8 a.m. and 4 p.m. on the day of proestrus. The increases in prostaglandin levels occurred after the LH peak and apparently before the time of ovulation. These data confirm the role of PGF and PGE in the local mechanism of ovulation in the normal adult of a spontaneously ovulating animal species.     

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)