Effect of treatment of estrous ewes with indomethacin on the distribution of ovarian blood to the periovulatory follicle

The level of prostaglandin (PG) F2 alpha increases within the wall of the ovine follicle pending ovulation. Coincidently, the quantity of ovarian blood distributed to the follicular wall progressively declines. A potential cause(PGF2 alpha)-and-effect (impaired follicular blood supply) relationship was considered. At an early stage of estrus, ewes were injected systemically either with vehicle or indomethacin (an inhibitor of biosynthesis of prostaglandins). Abdominal laparotomies were carried out and the ovaries examined near the expected time of ovulation. The ovary containing the largest follicle or an ovulation point was perfused with radioactive microspheres via the ovarian artery. The periovulatory follicle was isolated from the ovary and the content of radioactivity monitored with respect to that of the whole ovary. Follicular tissue was analyzed for PGF2 alpha. Treatment with the drug was associated with: 1) failure of follicular rupture; 2) follicular hyperemia and edema; and 3) suppressed synthesis of PGF2 alpha. A reduction of the supply of ovarian blood reaching the preovulatory follicle, and a mediatory task of follicular prostaglandins in this process, could be a critical determinant of ovulation.     

Effects of high and low preovulatory concentrations of progesterone on ovulation from the isolated perfused rabbit ovary

Rabbit ovaries were isolated surgically before the ovulatory gonadotrophin stimulation and perfused in vitro. Untreated, control ovaries never ovulated. Ovaries treated in vitro with ovine LH ovulated 10-14 h later and the oocytes had undergone germinal vesicle breakdown (GVB). LH induced increases in progesterone secretion from the treated ovaries. A 3 beta-hydroxysteroid dehydrogenase blocker ('Compound A') effectively reduced progesterone secretion into the perfusate and follicular fluid to very low levels but had no effect on ovulation rate or on oocyte maturation. Excessively high progesterone levels were obtained artificially in perfusates by addition of exogenous steroid; the number of ovaries ovulating was markedly reduced but there was no effect on oocyte maturation. It is concluded that the rise in progesterone that normally occurs immediately after the LH surge is not a prerequisite for ovulation in the rabbit. However, progesterone may have a modifying effect on LH-induced follicle rupture when at a pharmacologically high level.     

Follicular plasminogen and plasminogen activator and the effect of plasmin on ovarian follicle wall.

Plasminogen, plasminogen activator, protease inhibitors, and a proteolytic activity are shown to be present in bovine follicular fluid. Much of the proteolytic activity appears to be due to plasmin. In addition, plasminogen activator activity can be demonstrated in follicle wall homogenates. Evidence that plasmin decreases the tensile strength of follicle wall preparations is also reported. The potential for the involvement of these substances in ovulation is discussed.     

Optimum time for administration of indomethacin to inhibit ovulation in the rabbit

The antiinflammatory agent, indomethacin, inhibits ovulation in mammals by interfering with the synthesis of prostaglandins in preovulatory follicles. To determine the optimum time to administer this inhibitor, indomethacin was given at specific intervals from 10 h before, and up to 9 h after, the ovulatory process had been initiated by hCG (50 I.U./kg). The drug dosage ranged from 1.25 mg/kg to 40 mg/kg. The optimum time to give indomethacin was at 7–8 h after hCG (i.e., 2–3 h before expected rupture of the follicle) at which time the minimum effective dose was 2.5 mg/kg. Since a significant elevation in prostaglandin synthesis occurs as early as 3–5 h after hCG stimulation of rabbit follicles (1), these results reveal that nonsteroidal antiinflammatory agents can interrupt the ovulatory process even the follicle has begun producing substantial amounts of prostaglandins. The data suggest that prostaglandins need to be produced continuouly in the follicle up to the time of actual rupture, or else that indomethacin is interfering with some other aspect of the ovulatory process which transpires after the elevation of prostaglandins.     

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.     

Prostaglandin E(1) inhibits abnormal follicle rupture and restores ovulation in indomethacin-treated rats

In the presence of indomethacin, an inhibitor of prostaglandin (PG) synthesis, the gonadotropin surge induces abnormal follicle rupture at the basolateral follicle sides, thus preventing effective ovulation in rats. This study was undertaken to analyze whether exogenous prostaglandin administration can overcome the antiovulatory action of indomethacin. Cycling rats were treated with vehicle (olive oil) or indomethacin (1 mg/rat) on the morning of proestrus. Rats treated with indomethacin were injected with different doses (50, 250, or 500 micro g/rat) of PGE(1), PGE(2), PGF(2alpha), or vehicle (saline) at 1900 h in proestrus. The ovulatory response was analyzed on the morning of estrus by evaluating follicle rupture and the location of the oocytes in serially sectioned ovaries. The number of oocytes in the oviducts was also counted in rats treated with the highest prostaglandin doses. In indomethacin-treated rats, most newly formed corpora lutea showed abnormal follicle rupture at the basolateral sides. In addition, invasion of the ovarian stroma and blood and lymphatic vessels by granulosa cells and follicular fluid was observed. Prostaglandins of the E series, and especially PGE(1), inhibited abnormal follicle rupture and restored ovulation, although the number of oocytes in the oviducts were significantly decreased. PGF(2alpha) was only partially effective in inhibiting abnormal follicle rupture and restoring ovulation. These data suggest that prostaglandins of the E series, and particularly PGE(1), play a crucial role in ovulation by determining the targeting of follicle rupture at the apex, thus allowing release of oocytes to the periovarian space.     

Evidence for a role of the ovarian surface epithelium in the ovulatory mechanism of the sheep: secretion of urokinase-type plasminogen activator

The extent of dissolution of tissues within the apical wall of the preovulatory ovine follicle (formative site of rupture) is greater than that of the counterpart basal hemisphere. It has been hypothesized that proteolytic enzymes released from contiguous ovarian surface epithelial cells contribute to apical follicular weakening and ovulation. Ovulation occurs from the dominant ovarian follicle of proestrous ewes at approximately 24 h after administration of luteinizing hormone-releasing hormone (LHRH). Follicular rupture was inhibited in sheep in which the ovarian surface epithelium was surgically removed at 8 (but not at 16) h following LHRH. Plasminogen activator bioactivity was greater within the follicular apex compared to basal wall at 12 h; this difference was negated by prior removal of epithelium at 8 h after LHRH. A low M_r plasminogen activator of the urokinase-type (uPA) was secreted by epithelial cells recovered from the surface of preovulatory follicles (Western blot analysis). Ovarian epithelium, not associated with a preovulatory follicle, produced very little uPA. Finally, ovulation was suppressed by intrafollicular injection (8 h post-LHRH) of uPA antibodies. It is suggested that secretion of uPA by ovarian surface epithelium and consequent plasmin up-regulation within neighboring tunica albuginea and follicular theca is a contributing factor in the mechanism of ovulation.     

Evidence for Follicle Wall Involvement in Ovulation and Progesterone Production by Frog (Rana pipiens) Follicles in vitro

Involvement of different cellular investments of the amphibian ovarian follicle wall in the ovulatory process, progesterone production, and oocyte maturation was investigated. Following microdissection, to selectively remove one or more layers (surface epithelium, theca, follicle cells) of the follicle wall, dissected and undirected ovarian follicles were treated with frog pituitary homogenate (FPH) or progesterone. Intact follicles ovulated in response to pituitary homogenate and this was associated with contractions of the follicle wall. Ovulation and follicular contractions were not observed following removal of the surface epithelium without removing the thecal layer. Oocyte maturation occured in response to FPH following removal of the surface epithelium alone or together with the theca, but not in the absence of the follicle cells. Intact follicles were most responsive to FPH with respect to progesterone production, and removal of all somatic cells from oocytes obliterated FPH stimulated progesterone production. Oocytes, regardless of wether any or all follicular wall layers were removed, matured but did not ovulate following exposure to progesterone. The results suggest that the surface epithelium, but not the theca, is required for FPH-induced extrusion (ovulation) of the oocyte from ovarian follicle wall. Additionally, the somatic tissue rather than the oocyte appears to be the cells producing progesterone following FPH treatment. The results indicate that separate cellular layers (individually and/or as a result of interactions) of the follicle wall carry out different functions during follicular differentiation and mediation of ovulation. Data provide functional evidence for a role of the surface epithelium in controlling the process of ovulation and follicular contraction.     

Apparent involvement of plasmin in early-stage follicle rupture during ovulation in medaka

Until recently, the role of the proteolytic system involving serine proteases in follicle rupture during ovulation in mammalian species has been a subject of controversy. We undertook the present study to examine whether proteases play a role in follicle rupture using the teleost medaka (Oryzias latipes) model. Various serine protease inhibitors, including a specific plasmin inhibitor, drastically reduced the rate of ovulation, as assessed by an in vitro ovulation assay, which was established for the fish. Biochemical, molecular biological, and immunological analyses demonstrated that plasminogen/plasmin was present in large follicles destined to ovulate. The active protease, plasmin, was detected in follicles approximately 3-7 h before the expected time of ovulation. Specific antibodies against the medaka plasmin light chain suppressed the ovulation rate of the follicles when antibodies were added to the medium during the period in which active plasmin was generated. This finding was an indication that a plasmin-like protease similar if not identical to plasmin plays a role in follicle rupture during ovulation in the medaka. Our data also indicate that this serine protease participates in the rupture for only a few hours prior to the activation of matrix metalloproteinase (Mmp)-mediated hydrolysis at ovulation. Based on our previous and current data, we propose a follicle rupture model involving two different proteolytic enzyme systems, serine protease and Mmp, in medaka ovulation. The current study is the first to provide evidence of the indispensable role of plasmin or a plasmin-like protease in the ovulation of a nonmammalian vertebrate species.     

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.     

Changes in and partial identification of the plasminogen activator and plasminogen activator inhibitor systems during ovarian follicular maturation in the pig

Plasminogen, plasmin, and plasminogen activator (PA) activities and PA and PA inhibitor (PAI) contents were measured in granulosa (GC) and theca interna cell extracts and follicular fluid (FF) obtained from preovulatory follicles of prepubertal gilts treated with eCG and hCG to induce follicular growth and ovulation. Plasmin activity in FF increased just before the time of expected ovulation. This increase was not attributable to changes in plasminogen levels, which remained relatively constant during preovulatory follicular development. The increase in follicular plasmin levels was associated with significant (p less than 0.01) increases in PA activity and content and decreases in PAI content in GC and FF. Western blot analysis suggested that follicular PA activity was represented principally by two forms of tissue type PA (t-PA) each with a pI of 7.8 and with molecular masses of 72,000 and 78,000 daltons, respectively. Two PA-PAI complexes of 126,000 and 130,000 daltons were observed. These complexes were partially dissociated with nucleophilic agents into two t-PA-like forms and a 52,000-dalton PAI protein with a pI of 4.8. Biochemical characteristics of the PAI protein suggest that it belongs to the same class of inhibitors as bovine and human PAI-1. These data indicate that rupture of the porcine ovarian follicle is temporally associated with a net increase in PA activity and an increase in plasmin activity. The increase in PA activity appears to be regulated by changes in PA and PAI content.     

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.     

Differential effects of RU486 and indomethacin on follicle rupture during the ovulatory process in the rat

Ovulation (i.e., the release of mature oocytes from the ovary) requires spatially targeted follicle rupture at the apex. Both progesterone and prostaglandins play key roles in the ovulatory process. We have studied follicle rupture and ovulation in adult cycling rats treated with a progesterone receptor antagonist (RU486), an inhibitor of prostaglandin synthesis (indomethacin, IM), or both. All rats were treated with LHRH antagonist on the morning (0900 h) of proestrus to inhibit endogenous gonadotropins and with 10 microg of ovine LH (oLH) at 1700 h in proestrus to induce ovulation. Animals were treated from metestrus to proestrus with 2 mg/day of RU486 or vehicle (olive oil) and on the morning of proestrus (1200 h) with 1 mg of IM or vehicle (olive oil). Some rats treated with vehicle or RU486 were killed on the morning of proestrus to assess preovulatory follicle development. The remaining rats were killed on the morning of estrus to study follicle rupture and ovulation. In vehicle-treated rats, oLH induced ovulation in 98% of follicles. In IM-treated rats, spatial targeting of follicle rupture was disrupted. Most oocytes were released to the ovarian interstitium (50%) or to the periovarian space (39%), and a smaller percentage (11%) of oocytes remained trapped inside the luteinized follicle. RU486-treated rats showed, on the morning of estrus, unruptured luteinized follicles. Only occasionally (2.8%), the oocytes were released to the periovarian space. IM treatment induced follicle rupture in RU486-treated rats, and 25% of oocytes were released to the ovarian interstitium. However, the number of oocytes released to the periovarian space (i.e., ovulated) was not increased by IM treatment in rats lacking progesterone actions. Overall, these data indicate that RU486 and IM have opposite effects on follicle rupture and suggest that both progesterone and prostaglandins are necessary for the spatial targeting of follicle rupture at the apex.     

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.     

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.     

Role of the double luteinizing hormone peak, luteinizing follicles, and the secretion of inhibin for dominant follicle selection in Asian elephants (Elephas maximus)

Elephants express two luteinizing hormone (LH) peaks timed 3 wk apart during the follicular phase. This is in marked contrast with the classic mammalian estrous cycle model with its single, ovulation-inducing LH peak. It is not clear why ovulation and a rise in progesterone only occur after the second LH peak in elephants. However, by combining ovarian ultrasound and hormone measurements in five Asian elephants (Elephas maximus), we have found a novel strategy for dominant follicle selection and luteal tissue accumulation. Two distinct waves of follicles develop during the follicular phase, each of which is terminated by an LH peak. At the first (anovulatory) LH surge, the largest follicles measure between 10 and 19.0 mm. At 7 ± 2.4 days before the second (ovulatory) LH surge, luteinization of these large follicles occurs. Simultaneously with luteinized follicle (LUF) formation, immunoreactive (ir) inhibin concentrations rise and stay elevated for 41.8 ± 5.8 days after ovulation and the subsequent rise in progesterone. We have found a significant relationship between LUF diameter and serum ir-inhibin level (r(2) = 0.82, P < 0.001). The results indicate that circulating ir-inhibin concentrations are derived from the luteinized granulosa cells of LUFs. Therefore, it appears that the development of LUFs is a precondition for inhibin secretion, which in turn impacts the selection of the ovulatory follicle. Only now, a single dominant follicle may deviate from the second follicular wave and ovulate after the second LH peak. Thus, elephants have evolved a different strategy for corpus luteum formation and selection of the ovulatory follicle as compared with other mammals.     

Disruption of periovulatory FSH and LH surges during induced anovulation by an inhibitor of prostaglandin synthesis in mares

The role of passage of follicular fluid into the peritoneal cavity during ovulation in the transient disruption in the periovulatory FSH and LH surges was studied in ovulatory mares (n=7) and in mares with blockage of ovulation by treatment with an inhibitor of prostaglandin synthesis (n=8). Mares were pretreated with hCG when the largest follicle was ≥32 mm (Hour 0). Ultrasonic scanning was done at Hours 24 and 30 and every 2h thereafter until ovulation or ultrasonic signs of anovulation. Blood samples were collected at Hours 24, 30, 32, 34, 36, 38, 48, and 60. Ovulation in the ovulatory group occurred at Hours 38 (five mares), 40, and 44. Until Hour 36, diameter of the follicle and concentrations of FSH, LH, and estradiol-17β (estradiol) were similar between groups. Between Hours 34 and 36, a novel transient increase in estradiol occurred in each group, and color-Doppler signals of blood flow in the follicular wall decreased in the ovulatory group and increased in the anovulatory group. In each group, FSH and LH periovulatory surges were disrupted by a decrease or plateau between Hours 38 and 48 and an increase between Hours 48 and 60. The discharge of hormone-laden follicular fluid into the peritoneal cavity at ovulation was not an adequate sole explanation for the temporally associated transient depression in FSH and LH. Other routes from follicle to circulation for gonadotropin inhibitors played a role, based on similar depression in the ovulatory and anovulatory groups.     

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.     

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)