Steroid-independent effect of gonadotropins on prostaglandin synthesis in rat Graafian follicles in vitro

The content of prostaglandins of the E-group (PGE) or F-group (PGF) was determined by radioimmunoassay in rat ovaries and in homogenates of cultured Graafian follicles. Intraperitoneal administration of luteinizing hormone (NIH-LH-S18; 10 μg/rat) at 9.00 h on any day of the estrous cycle caused an increase in ovarian PGE content within 5 h. The response was greatest on the day of proestrus (940% rise), i.e. when the ovary contains large follicles, and least at metestrus (80%). Follicles explanted from proestrous rats before the preovulatory gonadotropin surge responded to addition of LH (1–5 μg/ml) to the culture medium with a 10 to 30-fold increase in PGE and a 5-fold increase in PGF accumulation over a 5-h-period. Follicle stimulating hormone (NIH-FSH-S9; 10 μg/ml) caused a similar rise in follicular PGE accumulation, even after treatment of the FSH preparation with excess of an antiserum to the β-subunit of LH. Stimulation of follicular PG accumulation was unimpaired during suppression of progesterone and estrogen synthesis by aminoglutethimide. It is concluded that these steroids play no part in the mediation of the LH-effect on follicular prostaglandin formation.     

Steroid-independent effect of gonadotropins on prostaglandin synthesis in rat Graafian follicles

The content of prostaglandins of the E-group (PGE) or F-group (PGF) was determined by radioimmunoassay in rat ovaries and in homogenates of cultured Graafian follicles. Intraperitoneal administration of luteinizing hormone (NIH-LH-S18; 10 μg/rat) at 9.00 h on any day of the estrous cycle caused an increase in ovarian PGE content within 5 h. The response was greatest on the day of proestrus (940% rise), i.e. when the ovary contains large follicles, and least at metestrus (80%). Follicles explanted from proestrous rats before the preovulatory gonadotropin surge responded to addition of LH (1–5 μg/ml) to the culture medium with a 10 to 30-fold increase in PGE and a 5-fold increase in PGF accumulation over a 5-h-period. Follicle stimulating hormone (NIH-FSH-S9; 10 μg/ml) caused a similar rise in follicular PGE accumulation, even after treatment of the FSH preparation with excess of an antiserum to the β-subunit of LH. Stimulation of follicular PG accumulation was unimpaired during suppression of progesterone and estrogen synthesis by aminoglutethimide. It is concluded that these steroids play no part in the mediation of the LH-effect on follicular prostaglandin formation.     

Exogenous progesterone reduces follicular prostaglandin E and 6-keto prostaglandin F-1 alpha in the cyclic hamster

In cyclic hamsters, exogenous progesterone (100 micrograms) administered s.c. at 09:00 h on the day of dioestrus II reduced prostaglandin (PG) E and 6-keto PGF-1 alpha but not PGF concentrations in preovulatory follicles measured at 09:00 h of pro-oestrus. The injection of 10 micrograms ovine LH (NIADDK-oLH-25) concurrently with 100 micrograms progesterone on dioestrus II prevented the decline in follicular PGE and 6-keto PGF-1 alpha values. Administration of LH alone did not significantly alter follicular PG concentrations. Inhibition of follicular PGE accumulation by progesterone was due to a decline in granulosa PGE concentration and not thecal PGE. Progesterone administration also reduced follicular oestradiol concentrations. Administration of oestradiol-17-cyclopentanepropionate (ECP) (10 micrograms) with progesterone did not prevent the decline in follicular PGE and 6-keto PGF-1 alpha but did increase follicular PGF concentrations. However, ECP given alone on dioestrus II reduced follicular PGE and increased PGF concentrations in preovulatory follicles on pro-oestrus. It is concluded that exogenous progesterone administered on dioestrus II inhibits granulosa PGE and 6-keto PGF-1 alpha accumulation in preovulatory follicles, probably by reducing serum LH concentrations, and that the granulosa cells, which are LH-dependent, are a major source of follicular PGE.     

Pre-ovulatory changes in cyclic AMP and prostaglandin concentrations in follicular fluid of gilts

The concentrations of cyclic adenosine 3′,5′-monophosphate (cyclic AMP) and prostaglandins E and F (PGE and PGF) were determined in follicular fluid collected from follicles of prepubertal gilts at various times after treatment with pregnant mare serum gonadotropin (PMSG) and human chorionic gonadotropin (hCG) to induce ovulation. The concentrations of cyclic AMP, PGE and PGF in the follicular fluid after PMSG treatment but prior to hCG injection were about 1 pmol/ml, 1 ng/ml and 0.2 ng/ml, respectively. After hCG administration, the follicular fluid levels of cyclic AMP increased markedly, reaching a peak (400-fold increase) about 4 h after injection and then declined gradually to pre-hCG levels. A second rise (2.5- to 5-fold increase) occurred about 30 h after hCG with the levels being sustained up to the expected time of ovulation. In contrast, the levels of PGE and PGF remained relatively constant until 28–30 h after hCG treatment. Thereafter, the concentrations of both prostaglandins began to rise with the increases becoming more pronounced and reaching maximal values as the expected time of ovulation approached. These data provide further evidence for a physiological role of follicular prostaglandins in the process of ovulation but do not support an obligatory role for prostaglandins in the acute gonadotropin stimulation of cyclic AMP formation.     

Pre-ovulatory changes in cyclic AMP and prostaglandin concentrations in follicular fluid of gilts.

The concentrations of cyclic adenosine 3', 5'-monophosphate (cyclic AMP) and prostaglandins E and F (PGE and PGF) were determined in follicular fluid collected from follicles of prepubertal gilts at various times after treatment with pregnant mare serum gonadotropin (PMSG) and human chorionic gonadotropin (hCG) to induced ovulation. The concentrations of cyclic AMP, PGE and PGF in the follicular fluid after PMSG treatment but prior to hCG injection were about 1 pmol/ml, 1 ng/ml and 0.2 ng/ml, respectively. After hCG administration, the follicular fluid levels of cyclic AMP increased markedly, reaching a peak (400-fold increase) about 4 h after injection and then declined gradually to pre-hCG levels. A second rise (2.5- to 5-fold increase) occurred about 30 h after hCG with the levels being sustained up to the expected time of ovulation. In contrast, the levels of PGE and PGF remained relatively constant until 28-30 h after hCG treatment. Thereafter, the concentrations of both prostaglandins began to rise with the increases becoming more pronounced and reaching maximal values as the expected time of ovulation approached. These data provide further evidence for a physiological role of follicular prostaglandins in the process of ovulation but do not support an obligatory role for prostaglandins in the acute gonadotropin stimulation of cyclic AMP formation.     

Interactive roles of progesterone, prostaglandins, and collagenase in the ovulatory mechanism of the ewe

Interrelationships between production of progesterone (P4), prostaglandin (PG) E2 and PGF2 alpha, and collagenase by periovulatory ovine follicles and their possible involvements in the ovulatory process were investigated. Follicles were isolated from ovaries at intervals (0 to 24 h) after the initiation of the preovulatory surge of luteinizing hormone (LH). Progesterone and PGs within follicles were determined by radioimmunoassay. Digestion of radioactive collagen during coincubation with tissue homogenates was used to assess the production of a bioactive follicular collagenase(s). Follicular accumulation of PGs and P4 increased at 12 and 16 h, respectively, after the onset of the surge of LH; PGE2 then decreased at 20 h. Collagenolytic activity of follicular tissue increased at 20 h and was maximal at 24 h (during the time of follicular rupture). An inhibitor of synthesis of P4 (isoxazol) or PGs (indomethacin) was injected into the follicular antrum at 8 h. Isoxazol did not prevent the initial rise in PGs, but inhibited synthesis of PGF2 alpha at 16 h and therafter. Isoxazol negated the decline in PGE2 and increase in collagenolysis. Indomethacin did not influence synthesis of P4; however, it suppressed collagenolytic activity of follicular tissue. Ovaries with treated follicles were left in situ and observed for an ovulation point at 30 h. Isoxazol or indomethacin was a potent inhibitor of ovulation. The blockade of ovulation by isoxazol was reversed by systemic administration of P4 or PGF2 alpha, but not by PGE2. Reversal of the blockade by indomethacin was accomplished with PGE2 or PGF2 alpha. Collagenolytic activity of follicular tissue was likewise restored by such treatments.(ABSTRACT TRUNCATED AT 250 WORDS)     

Periovulatory changes in ovarian prostaglandin formation and their hormonal control in the rat

The concentration of prostaglandins of the E-group (PGE) and F-group (PGF) and the activity of prostaglandin-synthetase in rat ovaries increased on the evening of the day of proestrus and reached a peak at 5.00 h on the following morning, i.e. about the time of ovulation. Enzyme activity and PG concentrations receded to basal levels by 10.00 h on the day of estrus. These changes were prevented when the proestrous gonadotropin surge was blocked by administration of nembutal, and could be restored by administration of either LH or of FSH freed of LH contamination. The spontaneous preovulatory rise in prostaglandin concentration was about 6-fold for PGF and 30-fold for PGE, compared with values observed during the remainder of the cycle, whereas the rise in prostaglandin synthetase activity was only about 1.7-fold. The LH effect on PG accumulation had a latency of 2–4 h, which argues for enzyme synthesis rather than activation of preformed enzyme as the mechanism responsible. The small magnitude of the change in enzymic activity suggests that LH may, in addition, augment the availability of PG precursors. The results are compatible with the concept that prostaglandins play a physiological role in the gonadotropin-induced process of follicular rupture.     

Formation of cyclic adenosine monophosphate (cAMP) in the preovulatory rabbit follicle: role of prostaglandins and steroids

The preovulatory increase in follicular prostaglandins (PG) stimulated by luteinizing hormone (LH) is dependent upon 3'-5'-cyclic adenosine monophosphate (cAMP) and is essential for ovulation. It has been proposed that follicular PG stimulate a second rise in cAMP, independent of LH. This study examined the temporal relationships among PGE2, PGF2 alpha 6-keto-PGF1 alpha, estradiol-17 beta, progesterone, testosterone, androstenedione and the biphasic increases of cAMP in follicles of rabbits. Does received indomethacin (IN, 20 mg/kg, i.v.; n = 30) or phosphate buffer (C; n = 30), 0.5 h before 50 ug of LH. At laparotomy at 0, 0.5, 1, 2, 4 or 8 h after LH, blood was collected from each ovarian vein and two follicles per ovary were aspirated of fluid and excised. Plasma and follicular tissue and fluid were assayed for PG and steroids. Tissue and fluid were assayed for cAMP. In C does, cAMP (pmol/follicle) in tissue increased from 11.3 at 0 h to 14.2 at 0.5 h, decreased at 1 h (5.4) and increased linearly through 8 h to 14.5. In IN-treated does, cAMP remained high from 0.5 (13.2) to 2 h (16.3), decreased at 4 h (7.9) then increased again by 8 h (15.5). Indomethacin decreased all PG in follicular tissue but 6-keto-PGF1 alpha rose after 2 h, whereas PGE2 and PGF2 alpha did not. Estradiol-17 beta, progesterone, and androstenedione did not vary with treatment; testosterone was increased (P less than .05) by IN. PGE2 or PGF2 alpha may terminate the first phase of cAMP production, rather than initiate the second phase.     

Prostaglandin levels in preovulatory follicles from rabbit ovaries perfused in vitro

Prostaglandin (PG) levels in follicular fluid from preovulatory follicles of rabbit ovaries perfused in vitro were measured in order to compare PG changes in this model system with those that occur in vivo and in isolated, LH-treated follicles in vitro. One ovary from each rabbit was perfused without further treatment (control). The other ovary was exposed to LH (0.1 or 1 microgram/ml) beginning 1 hour (h) after initiation of perfusion. Samples of perfusion medium were taken at frequent intervals for measurement of PGE, PGF, progesterone and estradiol 17 beta. The perfusions were terminated when the first ovulation occurred or appeared imminent as judged by changes in the size and shape of the follicles. Follicular fluid was then rapidly aspirated from all large follicles on both ovaries for PGE and PGF measurement. Ovulations occurred only in the LH-treated ovaries. Progesterone and estradiol levels were significantly elevated in the perfusion medium within 1 h of LH treatment in comparison to controls. PG levels in perfusion medium from the control and LH-treated ovaries were not different throughout perfusion and increased in both groups. In contrast, PG levels measured in follicular fluid from LH-treated ovaries were 4- to 5-fold greater than in fluid from control ovaries. It is concluded that ovulation induced by LH in this experimental model is accompanied by an increase in follicular PG levels similar to that seen in other in vivo and in vitro models. This difference in follicular PG levels between the LH-treated and control ovaries is, however, not reflected in the perfusion medium.     

Prostaglandin levels in preovulatory follicles from rabbit ovaries perfused

Prostaglandin (PG) levels in follicular fluid from preovulatory follicles of rabbit ovaries perfused were measured in order to compare PG changes in this model system with those that occur and in isolated, LH-treated follicles . One ovary from each rabbit was perfused without further treatment (control). The other ovary was exposed to LH (0.1 or 1 ug/ml) beginning 1 hour (h) after initiation of perfusion. Samples of perfusion medium were taken at frequent intervals for measurement of PGE, PGF, progesterone and estradiol 17β. The perfusions were terminated when the first ovulation occurred or appeared imminent as judged by changes in the size and shape of the follicles. Follicular fluid was then rapidly aspirated from all large follicles on both ovaries for PGE and PGF measurement.Ovulations occurred only in the LH-treated ovaries. Progesterone and estradiol levels were significantly elevated in the perfusion medium within 1 h of LH treatment in comparison to controls. PG levels in perfusion medium from the control and LH-treated ovaries were not different throughout perfusion and increased in both groups. In contrast, PG levels measured in follicular fluid from LH-treated ovaries were 4- to 5-fold greater than in fluid from control ovaries. It is concluded that ovulation induced by LH in this experimental model is accompanied by an increase in follicular PG levels similar to that seen in other and models. This difference in follicular PG levels between the LH-treated and control ovaries is, however, not reflected in the perfusion medium.     

Activity of phospholipase C in ovine luteal tissue in response to PGF2 alpha, PGE2 and luteinizing hormone.

Four ewes were utilized to determine the effects of prostaglandin (PG) F2 alpha, PGE2 and luteinizing hormone (LH) on activity of phospholipase C (PLC) in ovine luteal tissue. Corpora lutea were collected on d 10 post-estrus and six slices from one corpus luteum from each ewe were pre-incubated with [3H]-inositol prior to incubation with one of 6 treatments. Treatments were 1) control, 2) PGF2 alpha (100 ng/ml), 3) PGE2 (10 ng/ml), 4) LH (10 ng/ml), 5) PGF2 alpha + PGE2 and 6) PGF2 alpha + LH. Phospholipase C was determined indirectly by measuring the accumulation of [3H]-inositol mono-, bis- and tris-phosphates (IP, IP2, IP3). Effects of PGF2 alpha (0 vs. PGF2 alpha) and luteotropic treatment (0 vs. PGE2 vs. LH) and their interactions were determined by analysis of variance. There was a significant main effect of PGF2 alpha (P less than 0.01) as concentrations of IP, IP2, IP3 and total [3H]-inositol phosphates were greater in tissue slices treated with PGF2 alpha, regardless of luteotropic treatment. Within groups receiving no PGF2 alpha (1,3,4), no effect of luteotropic treatment was observed. Within groups receiving PGF2 alpha (2,5,6), LH caused a significant (P less than .05) increase in the accumulation of total [3H]-inositol phosphates. Thus, PGF2 alpha can stimulate the activity of PLC in ovine luteal tissue and LH can potentiate this effect.     

Regulation of prostaglandin biosynthesis by luteinizing hormone and bradykinin in rat preovulatory follicles in vitro.

Luteinizing hormone (LH) stimulates prostaglandin biosynthesis and steroidogenesis in preovulatory (PO) follicles prior to ovulation. Since the ovulatory process shares many similarities with an inflammatory reaction, mediators of the inflammatory response, such as bradykinin (BK) have been suggested to modulate the effects of LH. In the present study the effect of BK (5 microM) on: 1) prostaglandin biosynthesis (PGE2, PGF2 alpha and 6-keto-PGF1 alpha), 2) the levels of two enzymes in the cyclo-oxygenase pathway, prostaglandin endoperoxide synthase (PGS) and prostacyclin synthase (PCS), and 3) cyclic adenosine 3'5'-monophosphate (cAMP) and progesterone response of PO follicles incubated in vitro were examined. LH (0.1 microgram/ml) stimulated the accumulation of cAMP and progesterone in the medium, while BK had no effect on these parameters. BK exerted a slight stimulatory effect on PGE2, and PGF2 alpha, (p less than or equal to 0.01) but not on 6-keto-PGF1 alpha synthesis, but no changes in PGS or PCS levels could be detected. The effect of LH on prostaglandin biosynthesis was much more pronounced, with an increase of PGE2, PGF2 alpha and 6-keto-PGF1 alpha. LH also induced PGS. The combination of LH and BK did not alter these responses compared to that of LH alone. This study demonstrates that BK stimulates prostaglandin biosynthesis in PO follicles. In contrast to LH, this effect of BK does not seem to involve the adenylate cyclase system, since BK did not stimulate cAMP production. BK did not affect the levels of PGS or PCS, and the stimulatory effect of BK is suggested to involve an increase in the availability of substrate for the cyclo-oxygenase pathway.     

Effect of prostaglandins on luteal function during early pregnancy in pigs.

Luteal cells were obtained by digestion of luteal tissue of cyclic (day 12) and early pregnant (days 12, 20 and 30) pigs. Suspensions of the dispersed luteal cells (5 x 10(4) cells ml-1) were incubated for 2 h in minimum essential medium (MEM) alone (control) and MEM with different concentrations of prostaglandin F2 alpha (PGF2 alpha) and PGE2 (0.01, 0.1, 1, 10, 100 and 1000 ng ml-1) and luteinizing hormone (LH) 100 and 1000 ng ml-1, or with combinations of LH + PGF2 alpha and LH + PGE2. Net progesterone production was measured in the incubation media by direct radioimmunoassay. The overall response pattern of the luteal cells to exogenous hormones on day 12 of the oestrous cycle and pregnancy differed (P < 0.05) from treatment on day 20 and 30 of pregnancy. In general progesterone production was higher (P < 0.05) and the response to PGF2 alpha and PGE2 treatment was most obvious on day 12 of the oestrous cycle and pregnancy. Overall, PGF2 alpha stimulated progesterone production in a dose-dependent manner (P < 0.05). The response to PGE2 was of a quadratic nature (P < 0.05) in which the lowest and the highest doses of PGE2 were associated with a greater production of progesterone than were the intermediate doses. Treatment of luteal cells with PGF2 alpha + LH or PGE2 + LH caused overall inhibition (P < 0.05) of progesterone production compared with treatment with each hormone alone. This interaction was not affected by the dose of LH used. These findings indicate that PGF2 alpha and PGE2 are involved in the autocrine control of corpus luteum function.     

Synthesis of prostaglandin F2 alpha, E2 and prostacyclin in isolated corpora lutea of adult pseudopregnant rats throughout the luteal life-span.

The ability of de novo biosynthesis of prostaglandins (PGs) in individual whole corpora lutea (CL) obtained from sterile-mated adult pseudopregnant rats on different days of the luteal phase and the post-luteolytic period was evaluated. Production of PGs, progesterone and 20 alpha-dihydroprogesterone were determined after in vitro incubation of CL extirpated from Day 2 to Day 19 after mating. A time-relationship with increased accumulation of PGs in the medium was demonstrated from 18 s to 5 h, with large increments during the first 30 min. Basal accumulation of PGs in the incubation medium was highest for 6-keto-PGF1 alpha (the stable metabolite of prostacyclin) greater than PGE2 greater than PGF2 alpha greater than thromboxane B2 (TXB2) and basal accumulation of PGF2 alpha and PGE2 measured in the medium was maximal on Day 10-11 of pseudopregnancy, concomitantly with a decline in secretion of progesterone. Addition of arachidonic acid (AA) dose-dependently increased synthesis of PGs, with absolute amounts of PGE2 greater than 6-keto-PGF1 alpha greater than PGF2 alpha greater than TXB2 and addition of 14 microM indomethacin markedly inhibited accumulation of all PGs measured. Luteinizing hormone (LH, 10 micrograms/ml) stimulated progesterone secretion on all days during pseudopregnancy, but not on the post-luteolytic Day 19. LH increased PGF2 alpha, PGE2 and 6-keto-PGF1 alpha secretion on Day 13 of pseudopregnancy by 76%, 91% and 28%, respectively, but not on the other days tested. Furthermore, stimulation of PG-synthesis by addition of AA abrogated the LH-induced progesterone accumulation markedly, but only on Day 13 of pseudopregnancy. Epinephrine (5 micrograms/ml) increased production of progesterone and also PGs, but only on Day 2 of pseudopregnancy, whereas oxytocin (100 mIU/ml) was found to be without effect on progesterone as well as PG secretion on all days tested. The results of the present study demonstrates the independent ability of the rat CL to synthesize PGG/PGH2-derived prostaglandins, including the putative luteolysin PGF2 alpha. Secondly, we demonstrate that LH and AA-induced increases in PGF2 alpha and PGE2 production during the luteolytic period, may be an autocrine or paracrine mechanism involved in luteolysis.     

Gonadotropic regulation of prostaglandin production by ovarian follicular cells of the pig

Prepubertal gilts were treated with 750 IU pregnant mare's serum gonadotropin (PMSG) and 72 h later with 500 IU human chorionic gonadotropin (hCG) to induce follicular growth and ovulation. Dispersed granulosa cells (GC) and theca interna cells (TC) from follicles of gilts 72 h (GC-72 and TC-72, respectively) and 108 h (GC-108 and TC-108 h, respectively) after PMSG treatment were cultured for 0, 12, 24, and 36 h in medium with or without luteinizing hormone (LH), dibutyryl cyclic adenosine 3',5'-monophosphate [Bu)2cAMP), calcium ionophore (A23187), and/or arachidonic acid (AA), and the production of prostaglandin E2 (PGE) and prostaglandin F2 alpha (PGF) was measured by radioimmunoassay. TC-72 was the principal source of PGs 72 h after PMSG. At 108 h, the production of PGE and PGF by GC was increased 10- and 30-fold, respectively, whereas corresponding increases by TC were 2-fold. LH and A23187 significantly stimulated PGE and PGF production by both GC-72 and TC-72, but only thecal PG production was stimulated by (Bu)2cAMP. LH had minimal or no effect on PG production by GC-108 and TC-108, but A23187 (GC-108, TC-108) and (Bu)2cAMP (TC-108) were stimulatory. Basal PG production by GC-72, GC-108, and TC-108 was stimulated by AA. However, production by GC and TC cultured in medium containing AA and LH, A23187, or (Bu)2cAMP was not different from that produced by AA alone. These findings suggested that GC and TC can synthesize PGs in vitro, but AA availability is rate-limiting in GC. After exposure to hCG in vivo, the capacity of both cell types to produce PGs is increased but is limited by AA availability.(ABSTRACT TRUNCATED AT 250 WORDS)     

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.     

Involvement of prostaglandins in LH-induced superovulation in the cyclic hamster

Osmotic minipumps containing 400 micrograms ovine LH were inserted subcutaneously (sc) on day 1 (estrus) at 09:00-10:00h of the cycle in the hamster. This treatment induced increased ovarian blood flow by day 3 and superovulation of 30.0 +/- 1.4 ova at the next estrus compared to controls (16.5 +/- 0.8 ova). The continuous infusion of LH throughout the cycle increased prostaglandin F (PGF) and decreased prostaglandin E (PGE) in the growing follicles destined to ovulate and suppressed a day 3 increase in PGF concentrations in the nonluteal ovarian remnant devoid of the larger follicles. Indomethacin, a cyclooxygenase inhibitor, given sc (2 or 4 mg regimens) at 12:00-14:00h on days 1 and 2, at 09:00h and 17:00h on day 3 and at 09:00h on day 4 of the cycle to LH-infused and saline treated animals suppressed ovarian prostaglandin levels, prevented the superovulation and prevented the increased ovarian blood flow. Exogenous PGF2 alpha or PGE2 restored the superovulatory effect of LH infusion in the presence of indomethacin. The results suggest that the superovulation in response to continuous LH infusion may be mediated in part by prostaglandins via altered ovarian blood flow.     

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.     

Production of prostaglandins by porcine preovulatory follicular tissues and their roles in intrafollicular function

Prostaglandin production in vitro by theca and granulosa cells isolated from prepubertal pig ovaries was quantified in order to investigate the role of prostaglandins in intrafollicular function. Prepubertal gilts were slaughtered without treatment (O h, control) or treated with 1000 IU pregnant mare's serum gonadotropin (PMSG) and slaughtered at 36 or 72 h, or at 75 h following treatment with 500 IU of hCG at 72 h. Theca and granulosa cells were isolated from preovulatory follicles and cultured for 24 h alone or with follicle-stimulating hormone (FSH) or luteinizing hormone (LH). In vitro accumulation of 6-keto-prostaglandin F1 alpha (6-keto-PGF1 alpha), prostaglandin E2 (PGE2) and prostaglandin F2 alpha (PGF2 alpha) was measured by radioimmunoassay. On a per follicle basis theca produced more of each prostaglandin (approx. 10-fold) than granulosa at each stage of follicular development; production by each tissue type increased with development of the follicle, responding to administration of gonadotropin (PMSG) in vivo. Neither tissue type was generally responsive to further gonadotropin stimulation in vitro. However, production of PGE2 by granulosa cells was increased by addition of gonadotropin, particularly LH, in vitro, with the greatest response observed in tissue obtained at 36 and 72 h after PMSG. There were no functional correlates between prostaglandin production and steroidogenesis by either tissue type and we conclude that prostaglandins do not have an obligatory role in follicular steroidogenesis. However, these data provide additional circumstantial evidence for a role of PGE2 in granulosa cell luteinization, and possibly in ovulation. The data also indicate that prostaglandins derived from thecal tissue in relatively large quantities may play an important role in ovulation.     

Detection of regional ischemia in perfused beating hearts by phosphorus nuclear magnetic resonance.

Rat Graafian follicles isolated intact responded to 8-Br-cyclic GMP (0.3 and 1.0 mM) with increased prostaglandin E (PGE) production (4-fold and 8-fold, respectively) during a 6 h incubation. The effect of 8-Br-cyclic GMP was noted after a lag period of 2–4 h. 8-Br-cyclic AMP (1.0 mM) also stimulated PGE production (4-fold increase), while 8-Br-cyclic IMP, 8-Br-5′GMP and 8-Br-5′AMP were inactive in this respect. Actinomycin D (10 μg/ml) and cycloheximide (10 μg/ml) given simultaneously with 8-Br-cyclic GMP prevented the stimulatory effect of the cyclic nucleotide. The results suggest that cyclic GMP induces de novo synthesis of a macromolecular component of the ovarian prostaglandin synthetase system, and that this cyclic nucleotide, along with cyclic AMP, may play a role in the known stimulatory action of luteinizing hormone on follicular prostaglandin production.