Gamete recovery and follicular transfer (graft) using transvaginal ultrasonography in cattle

Current in vitro culture systems may not be adequate to support maturation, fertilization and embryo development of calf oocytes. Thus, we initiated a study to investigate an alternative method of assessing oocyte competence in vivo, initially using oocytes from adults. Experiment 1 was done to determine if follicle puncture would alter subsequent follicle development, ovulation and CL formation. In control (no follicle puncture, n = 3) and treated (follicle puncture, n = 3) heifers, ultrasound-guided transvaginal follicle aspiration was used to ablate all follicles > or = 5 mm at random stages of the estrous cycle to induce synchronous follicular wave emergence among heifers; PGF2 alpha was given 4 d later. Three days after PGF2 alpha, the preovulatory follicle in treated heifers was punctured with a 25-g needle between the exposed and nonexposed portions of the follicular wall, and 200 microL of PBS were infused into the antrum. There was no significant difference between control and treated heifers for mean diameter of the dominant follicle prior to ovulation, the interval to ovulation following PGF2 alpha, or first detection and diameter of the CL. Experiment 2 was designed to assess multiple embryo production following interfollicular transfer of oocytes (i.e., transfer of multiple oocytes from donor follicles to a single recipient preovulatory follicle). Follicular wave emergence was synchronized among control (no follicle puncture, n = 5), oocyte recipient (n = 7) and oocyte donor (n = 5) heifers as in Experiment 1. In control and oocyte recipient heifers, a norgestomet ear implant was placed at the time of ablation and removed 4 d later, at the second PGF2 alpha treatment. In oocyte donor heifers, FSH was given the day after ablation, and, 4 d later, oocytes were collected by transvaginal follicle aspiration, pooled and placed in holding medium. Five or 6 oocytes were loaded into the 25-g needle of the follicle infusion apparatus with < or = 200 microL of transfer medium. Puncture of the preovulatory follicle of recipient heifers was done as in Experiment 1. Immediately thereafter, LH was given to control and oocyte recipient heifers, but only the recipients were inseminated. Ovarian function was assessed by transrectal ultrasonography and control and oocyte recipient heifers were sent to the abattoir 2 or 3 d after ovulation, where excised oviducts were flushed. The interval between LH administration and ovulation (33 to 36 h) was highly synchronous within and among control and oocyte recipient heifers. Four of 5 (80%) ova were collected from controls and 16 of a potential 43 (37%) ova/embryos were recovered from oocyte recipients; 8 embryos from 3 heifers. Thus, the gamete recovery and follicular transfer procedure (GRAFT) did not alter ovulation or subsequent CL formation, and resulted in the recovery of multiple ova/embryos in which a total of 19 oocytes yielded as many as 8 early embryos, a 42% embryo production rate.     

Effects of copulation on timing of the LH surge following synchronization of estrus in the bovine

Forty-four crossbred postpubertal bovine females were used to study how mating with a bull affected estradiol-17beta (E(2)) secretion and timing of the preovulatory LH surge. Estrous cycles were synchronized with two injections of prostaglandin-F(2alpha) (PGF(2alpha)) 11 d apart. Females were either isolated from males (NE) or exposed to epididectomized bulls (BE) after the second PGF(2alpha) injection. Females exposed to bulls were allowed to mate once and then were separated from the bull. Blood samples were collected at 2-h intervals from the second PGF(2alpha) injection until 12-h post injection to monitor progesterone (P(4)) and luteinizing hormone (LH) concentrations and at hourly intervals from 12 h to 60 h post-injection to monitor LH secretion and timing of the preovulatory LH surge. Samples were also collected at 4-h intervals until 60 h post-injection to monitor estrogen (E(2)) secretion. LH surges were detected in 16 and 14 of 22 females from the BE and NE groups, respectively, during the 60-h period after PGF(2alpha) injection Mean P(4) concentrations and time of P(4) decline to <1 ng/ml were not different between the two treatment groups (P>0.30). Mean E(2) concentration during the 60-h sampling period was different (P<0.003) between BE and NE groups, and a significant treatment effect (P<0.002) occurred 48 h, 52 h and 60 h after the second PGF(2alpha) injection. However, mean LH concentration before the LH surge, duration of the LH surge and peak LH concentration during the surge were not different between the BE and NE groups (P>0.40). Mean time for the second PGF(2alpha) injection to the beginning of the LH surge was 51.6 +/- 1.5 h (X +/- S E) for the females not exposed to bulls and 48.5 +/- 1.4 h for females exposed to bulls (P>0.14). In this study, the presence of and/or mating by a bull did not affect LH secretion or timing of the preovulatory LH surge after PGF(2alpha) administration.     

Induction and inhibition of in vitro oocyte maturation and production of steroids in fish follicles by forskolin

The effects of forskolin (FK) on in vitro oocyte maturation and production of steroids were examined in Oryzias latipes. When oocytes within preovulatory follicles were preincubated in the presence of FK for 2-10 hr, they matured normally after additional incubation for 10-20 hr in plain culture medium. Naked (follicle cell-free) oocytes did not mature under these conditions. FK stimulated dose-dependent production of steroids (estradiol-17 beta, E2, and 17 alpha,20 beta-dihydroxy-4-pregnen-3-one, 17 alpha,20 beta-diOHprog) and cAMP in follicle (granulosa) cells. On the other hand, exposure to FK within 2 hr after 17 alpha,20 beta-diOH prog stimulation caused reversible inhibition of gonadotropin (PMS)- or 17 alpha,20 beta-diOH prog-induced maturation of the intrafollicular oocytes in vitro. FK also significantly inhibited the 17 alpha,20 beta-diOHprog-induced maturation of naked oocytes, suggesting the existence of adenylate cyclase in fish oocytes. These data indicate that in Oryzias latipes, FK induces oocyte maturation by stimulating follicular production of maturation-inducing steroid (MIS), probably 17 alpha,20 beta-diOH prog, via an increase in cAMP, and that it may inhibit oocyte maturation by increasing ooplasmic cAMP and some inhibitory interaction between the granulosa cells and the oocyte through intercellular communication.     

Effect of GnRH antagonist-induced prolonged follicular phase on follicular atresia and oocyte developmental competence in vitro in superovulated heifers

A GnRH antagonist (Antarelix) was used to suppress endogenous pulsatile secretion of LH and delay the preovulatory LH surge in superovulated heifers to study the effect of a prolonged follicular phase on both follicle and oocyte quality. Oestrous cycles were synchronized in 12 heifers with progestagen (norgestomet) implants for 10 days. On day 4 (day 0 = day of oestrus), heifers were stimulated with 24 mg pFSH for 4 days and luteolysis was induced at day 6 with PGF2 alpha (2 ml Estrumate). Animals in the control group (n = 4) were killed 24 h after the last FSH injection. At this time, heifers in group A36h (n = 4) and group A60h (n = 4) were treated with 1.6 mg of Antarelix every 12 h for 36 and 60 h, respectively, and then killed. After dissection of ovarian follicles, oocytes were collected for individual in vitro maturation, fertilization and culture; follicular fluid was collected for determination of steroid concentrations, and granulosa cells were smeared, fixed and stained for evaluation of pycnosis rates. Granulosa cell smears showed that 90% of follicles were healthy in the control group. In contrast, 36 and 58% of the follicles in group A36h showed signs of early or advanced atresia, respectively, while 90% of the follicles in group A60h showed signs of late atresia. Intrafollicular concentrations of oestradiol decreased (P < 0.0001) from healthy follicles (799.14 +/- 40.65 ng ml-1) to late atretic follicles (3.96 +/- 0.59 ng ml-1). Progesterone concentrations were higher (P < 0.0001) in healthy follicles compared with atretic follicles, irrespective of degree of atresia. Oestradiol:progesterone ratios decreased (P < 0.0001) from healthy (4.58 +/- 0.25) to late atretic follicles (0.07 +/- 0.009). The intrafollicular concentrations of oestradiol and progesterone were significantly higher (P < 0.0001) in the control than in the treated groups. The oestradiol:progesterone ratio was higher (P < 0.0001) in the control (4.55 +/- 0.25) than in the A36h (0.40 +/- 0.05) and A60h (0.07 +/- 0.009) groups. Unexpectedly, the cleavage rate of fertilized oocytes, blastocyst rate and number of cells per blastocyst were not significantly different among control (85%, 41% and 95 +/- 8), A36h (86%, 56% and 93 +/- 5) and A60h (88%, 58% and 79 +/- 4) groups. In addition, there were no significant differences in the blastocyst rates from oocytes derived from healthy (45%), early atretic (54%), advanced atretic (57%) and late atretic follicles (53%). In conclusion, the maintenance of the preovulatory follicles in superovulated heifers with a GnRH antagonist induced more atresia and a decrease in oestradiol and progesterone concentrations. However, the developmental potential in vitro to day 8 of the oocytes recovered from these atretic follicles was not affected.     

Prostaglandin production by the largest preovulatory follicles in the domestic hen (Gallus domesticus)

An injection of 5 micrograms of gonadotropin-releasing hormone (GnRH) into hens 8 h prior to oviposition advanced the expected time of oviposition by approximately 1 h. The plasma concentration of progesterone increased approximately 1 h earlier in GnRH-injected hens in comparison to saline-injected hens. The plasma concentration of 13,14-dihydro-15-keto-prostaglandin F2 alpha (PGFM) increased significantly (p less than 0.05) at the time of oviposition in both the GnRH- and saline-injected hens. Significantly (p less than 0.05) greater concentrations of prostaglandin F2 alpha (PGF2 alpha) were assayed in media containing the largest preovulatory follicles collected at oviposition than in media containing the second and fifth largest preovulatory follicles collected at the same time. No prostaglandin was detected in media containing small, nonhierarchial follicles. The concentration of PGF2 alpha in media containing granulosa cells from the largest preovulatory follicle was significantly greater (p less than 0.05) than in media containing 4 times as many theca cells. Ovine luteinizing hormone (oLH) alone or in combination with arachidonic acid had no effect on PGF2 alpha output from granulosa cells collected 6 h before oviposition, whereas A23187 caused a small stimulation of PGF2 alpha output. However, treating cells first with oLH and then with A23187 stimulated a 15- to 20-fold increase in PGF2 alpha. None of these stimuli enhanced the already high output of PGF2 alpha when added to incubations of granulosa cells collected within 5 min after oviposition. These data suggest that the granulosa cells of the largest preovulatory follicle are the major intraovarian source of prostaglandin and that production of PGF2 alpha is associated with the preovulatory surges of gonadotropins and steroid hormones preceding oviposition.     

Prostaglandins and preovulatory follicular maturation in mice

Experiments have been carried out in an effort to reverse the indomethacin-induced inhibition of preovulatory follicular development in immature superovulated mice utilizing prostaglandins E2 and F2 alpha. All mice were primed with 5 IU pregnant mare's serum gonadotropin followed 40 h later by 80 IU luteinizing hormone (LH). Animals were sacrificed 10 1/2 or 11 1/2-12 h post-LH, at which time ovaries were fixed and prepared for microscopic observation. Control mice receiving both indomethacin and prostaglandin (PG) vehicles averaged 92% germinal vesicle breakdown, and 82% of maturing oocytes were surrounded by an expanded cumulus oophorus. Ovarian weight increased by 29% and the apical walls of preovulatory follicles demonstrated appreciable thinning following LH administration. In mice receiving indomethacin plus PG vehicle, follicular maturation was suppressed in a dose-dependent manner; in mice receiving 10 mg/kg, less than 50% of the oocytes resumed meiosis and, of these, only 9% were accompanied by cumulus expansion. Ovarian weight gain was also inhibited, and the apical follicle wall exhibited few signs of preovulatory thinning. PGE2 and PGF2 alpha both reversed the inhibition of cumulus and oocyte maturation induced by indomethacin, though PGE2 was more effective. Only PGF2 alpha promoted apical follicular thinning, and neither PG had a significant effect on ovarian weight. We conclude that, in mice, PGs may play an integral role during preovulatory maturation of the oocyte and cumulus, as well as thinning of the apical wall.     

Remodeling of extracellular matrix at ovulation of the bovine ovarian follicle

Using immunohistochemistry and RNA analyses we examined the fate of components of a newly identified matrix that develops between granulosa cells (focimatrix, abbreviated from focal intraepithelial matrix) and of the follicular basal lamina in ovulating bovine ovarian follicles. Pre- and postovulatory follicles were generated by treatment with estradiol (Day 1), progesterone (Days 1-10), and prostaglandin analogue (Day 9) with either no further treatment (Group 1, n = 6) and or with 25 mg porcine LH (Day 11, Group 2, n = 8 or Day 10, Group 3, n = 8) and ovariectomy on Day 12 (12-14 hr post LH in Group 2, 38-40.5 hr in Group 3). In the time frame examined no loss of follicular basal lamina laminin chains beta2 and gamma1 or nidogen 1 was observed. In the follicular basal lamina collagen type IV alpha1 and perlecan were present prior to ovulation; after ovulation collagen type IV alpha1 was discontinuously distributed and perlecan was absent. Versican in the theca interna adjacent to the follicular basal lamina in preovulatory follicles was not observed post ovulation, however, the granulosa cells then showed strong cytoplasmic staining for versican. Expression of versican isoforms V0, V1, and V3 was detected at all stages. Focimatrix was observed in preovulatory follicles. It contained collagen type IV alpha1, laminins beta2 and gamma1, nidogen 1 and perlecan and underwent changes in composition similar to that of the follicular basal lamina. In conclusion focimatrix and the follicular basal lamina are degraded at ovulation. Individual components are lost at different times.     

Prostaglandin concentrations in peripheral plasma and ovarian and uterine plasma and tissue in relation to oviposition in hens

An increase in the plasma concentrations of prostaglandins (PGs) is associated with uterine contractile activity and with oviposition in the hen. In order to assess the contribution of potential sources of prostaglandins to the increase in prostaglandin levels observed at oviposition, prostaglandins E2, F2 alpha, and 13,14-dihydro-15-keto PGF2 alpha (PGFM, the stable but biologically less active metabolite of PGF2 alpha) were measured in plasma from the brachial vein, ovarian follicular vein and uterine vein, and in tissues from ovarian follicles and the uterus 12 h before and at midsequence oviposition or a terminal oviposition. These two ovipositions differ in that a midsequence oviposition is followed within 0.25-1.0 h by the next ovulation of the sequence, whereas the terminal oviposition is followed by an ovulation 14 h later. The concentration of PGFM in plasma from the brachial vein increased at midsequence oviposition, while the levels of PGE2 were unchanged. Prostaglandin E2, F2 alpha, and FM levels were each similar in the plasma from the brachial and uterine veins at the time of midsequence oviposition. In plasma from the largest preovulatory follicle, the concentration of PGF2 alpha and PGFM increased 19- and 7-fold, respectively, from 12 h before midsequence oviposition to midsequence oviposition, although no changes were observed in the concentrations of PGE2 during this interval. The levels of PGF2 alpha increased in the tissues of the two largest preovulatory follicles and the two most recently ruptured follicles during the 12-h period before a midsequence oviposition, while there was no change or a decrease in PGE2 levels in these tissues during the same interval. In contrast, the concentration of PGF2 alpha did not increase during the 12-h period preceding the terminal oviposition of the sequence in plasma from the brachial, uterine, or follicular veins.(ABSTRACT TRUNCATED AT 250 WORDS)     

Effect of a steroidal (prednisolone) and nonsteroidal (indomethacin) antiinflammatory agent on ovulation and follicular accumulation of prostaglandin F2 alpha in sheep

The antiinflammatory steroid, prednisolone, was administered to sheep during the preovulatory period. The drug did not produce a blockade of follicular rupture. However, prednisolone negated a rise in production of prostaglandin (PG) F2 alpha characteristic of preovulatory follicles. Indomethacin, a nonsteroidal antiinflammatory agent, was 100% effective in preventing ovulation. Levels of PGF2 alpha within follicular tissue were very low following treatment with indomethacin. These findings indicate that ovulation can occur in the absence of a preovulatory elevation in follicular accumulation of PGF2 alpha. Potency of antiinflammatory drugs as inhibitors of ovulation appears to hinge upon their ability to cause a marked suppression in follicular synthesis of prostaglandins.     

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)     

Effect of beta-carotene supplementation on reproductive performance of dairy heifers

Three trials were conducted to determine the effect of feeding supplemental beta-carotene on reproductive performance of Holstein heifers. In each trial, the animals were randomly assigned to either a control or treatment group. Animals in the treatment groups received 300 mg supplemental beta-carotene daily for the test periods which varied from 6 to 8 weeks in length. To facilitate sample collections and observations, estrus was synchronized with two injections of 25 mg PGF(2alpha) at 11 day intervals. The first injection was after 2 weeks of feeding supplemental beta-carotene. Blood serum beta-carotene concentrations were higher in the heifers fed supplemental beta-carotene as compared to concentrations in control heifers after 1 week of feeding and this difference increased throughout the test periods. The interval from the second injection of PGF(2alpha) to onset of estrus was shorter in the control heifers as compared to that interval in heifers supplemented with beta-carotene (trial 1,44.0 vs 56.0 hr; trial 2, 51.3 vs 70.8 hr; trial 3, 40.7 vs 62.5 hr, respectively). The intervals from PGF(2alpha) administration to the preovulatory LH peak (43.3 vs 61.5 hr) and ovulation (69.3 vs 85.9 hr) were also shorter in the control heifers in trial 3. No significant differences were found among treatments in the number of heifers that expressed estrus, the blood serum progesterone concentrations or the conception rates in any of the three trials.     

Effects of gonadotropin-releasing hormone agonists on meiotic maturation of follicle-enclosed oocytes in rabbits

The effects of GnRH agonists on in vitro maturation of rabbit follicle-enclosed oocytes were studied. Rabbit preovulatory follicles were cultured with or without hCG (10(2) ng/ml), buserelin (10(2)-10(5) ng/ml), or leuprolide (10(2)-10(5) ng/ml) for 14 hours in vitro. GnRH agonists induced the resumption of meiosis in the follicle-enclosed oocytes in a dose-dependent manner. The percentage of oocytes achieving GVBD following treatment with 10(5) ng/ml buserelin (87.9 +/- 6.3%) or 10(5) ng/ml leuprolide (86.0 +/- 4.1%) did not differ significantly from hCG-treated control (87.3 +/- 3.8%). Mature oocytes initially were detected within 2 hours of GnRH agonist exposure. Concomitant addition of a GnRH antagonist at 10(4) ng/ml significantly blocked the stimulatory effect of GnRH agonist on oocyte maturation. GnRH agonists significantly stimulated both prostaglandin (PG) E2 (PGE2) and PGF2 alpha production by preovulatory follicles (p less than 0.01), but secreted prostanoid levels did not differ significantly among different concentrations of GnRH agonists. Meiotic maturation of follicle-enclosed oocytes following GnRH agonist exposure began 2 hours earlier than production of PGs. PG production stimulated by GnRH agonists was reduced significantly by indomethacin. However, oocyte maturity in the presence of GnRH agonist plus indomethacin did not differ significantly from that of GnRH agonist alone. GnRH agonistic analogues induce the resumption of meiosis in follicle-enclosed oocytes in rabbits by a mechanism other than PG stimulation.     

Studies of the pathogenesis of bovine pestivirus-induced ovarian dysfunction in superovulated dairy cattle

Two experiments (Experiment I, n=12 Holstein-Friesian heifers; Experiment II, n=8 Jersey cows) were conducted to investigate the pathogenesis of bovine pestivirus-induced ovarian dysfunction in cattle. In both experiments the cattle were superovulated with twice daily injections of a porcine pituitary extract preparation of follicle stimulating hormone (FSH-P), for 4 days commencing on Day 10+/-2 after a presynchronised oestrus. The heifers received a total dose of 30 mg and the cows 32 mg of FSH-P. Prostaglandin F(2alpha) (PGF(2alpha)) was administered 48 h after commencement of superovulation and all cattle were artificially inseminated (AI) between 48 and 66h after PGF(2alpha) treatment. In both experiments bovine pestivirus seronegative cattle (Experiment I, n=6; Experiment II, n=4) were inoculated intranasally with an Australian strain of non-cytopathogenic bovine pestivirus (bovine viral diarrhoea virus Type 1) 9 days prior to AI. Bovine pestivirus infection was confirmed by seroconversion and/or virus isolation in all of the inoculated cattle, consistent with a viremia occurring approximately between Day 5 prior to AI and the day of AI. Ovarian function was monitored in both experiments by daily transrectal ultrasonography and strategic blood sampling to determine progesterone, oestradiol-17beta, luteinising hormone (LH) and cortisol profiles. Non-surgical ova/embryo recovery was performed on Day 7 after AI. In Experiment II half the cattle were slaughtered on Day 2 and the remainder on Day 8 after AI, and the ovaries submitted for gross and histopathological examination including immunohistochemistry to demonstrate the presence of bovine pestivirus antigen. In both studies, comparisons were made between infected and confirmed uninfected (control) animals. Overall the bovine pestivirus infected cattle had significantly lower (P<0.05) ova/embryo recovery rates compared to the control cattle. There was evidence of either an absence (partial or complete) of a preovulatory LH surge or delay in timing of the LH peak in the majority (90%) of infected heifers and cows, and histologically, there was evidence of non-suppurative oophoritis with necrosis of granulosa cells and the oocyte in follicles from the infected cows. By contrast only 20% of the control heifers and cows had evidence of absence of a pre-ovulatory LH surge. These experiments collectively demonstrate that bovine pestivirus infection during the period of final growth of preovulatory follicles may result in varying degrees of necrosis of the granulosa cells with subsequent negative effects on oestradiol-17beta secretion which in turn negatively affects the magnitude and/or timing of the preovulatory LH surge.     

GnRH improves the recovery rate and the in vitro developmental competence of oocytes obtained by transvaginal follicular aspiration from superstimulated heifers

In this study we assessed the effect of GnRH on the recovery rate, meiotic synchronization and in vitro developmental competence of oocytes recovered close to the expected time of ovulation. Twenty-three heifers were superstimulated with FSH, and luteolysis was induced by PGF(2alpha) injection 48 h after the start of treatment Twelve heifers received 200 microg GnRH at 34 h after PGF(2alpha) treatment, Blood samples were collected between 35 to 47 h after PGF(2alpha) administration to determine the time of the LH surge. Transvaginal follicular aspiration was performed at 60 h after PGF(2alpha), and the recovered oocytes were fertilized or fixed either immediately or after 24 h of maturation in vitro. GnRH-treated heifers showed an LH surge within 3 h after treatment, while only 4 of the 10 heifers in the control group exhibited an LH surge by 47 h after treatment with PGF(2alpha). The average number of large follicles (> 10 mm) was 21.3 +/- 2.3 and 19.3 +/- 2.4 for GnRH-treated and control heifers, respectively. The oocyte recovery rate was 87.7 and 63.1% (P < 0.05), respectively, and most of the cumulus-oocyte-complexes (COC) recovered from the 2 groups had an expanded cumulus (80.4 and 80.5%, respectively). Oocytes with an expanded cumulus from the GnRH group had completed meiotic maturation at higher rate than the controls (97 vs 20%;P < 0.05). In vitro development to the blastocyst stage of cumulus-expanded oocytes fertilized immediately after recovery was higher in GnRH-treated than in control heifers (60.3 vs 40.0%; P < 0.05). No difference was observed when oocytes with compact or expanded cumulus were matured in vitro for 24 h before fertilization. These results indicate that GnRH injections improve the oocyte recovery rate and that oocytes have a higher development competence than those obtained from non-GnRH-treated animals. We propose that this higher in vitro developmental competence may result from a more synchronous or further advanced meiotic maturation. However, due to the small number of oocytes in our study, we must emphasize that our findings on meiotic resumption are of preliminary nature.     

The non-luteolytic effect of prostaglandin F2α at the beginning of the bovine oestrous cycle: The role of oestrogen?

After the preovulatory gonadotrophin surge, antral follicles ovulate or become atretic; whatever their evolution, they stop secreting oestradiol. Since it was demonstrated that oestrogens were necessary for luteolysis to occur after PGF(2)alpha treatment, their absence could explain the non-luteolytic effect of PGF(2)alpha injected early in the cycle. Thus, cyclic cows received a PGF(2)alpha analogue and oestradiol valerate together on day 3. This treatment did not affect the life span of the corpus luteum. The absence of oestrogens in the blood does not explain the failure of PGF(2)alpha to cause luteolysis in young corpora lutea.     

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.     

Induction of ovulation in gilts with cloprostenol

Prepuberal gilts were treated with 750 IU pregnant mare serum gonadotropin (PMSG) followed 72 h later by 500 IU human chorionic gonadotropin (hCG) to induce follicular growth and ovulation. In this model, ovulation occurred at 42 +/- 2 h post hCG treatment. When 500 mug of cloprostenol was injected at 34 and of 36 h after hCG injection, 78% of the preovulatory follicles ovulated by 38 h compared with 0% in the control gilts. In addition, plasma progesterone concentrations were significantly higher in the cloprostenol-treated group than in the control group (P<0.01) at 38 h, indicating luteinization along with premature ovulation. These results suggest that prostaglandin F(2)alpha (PGF(2)alpha) or an analog can be used to advance, synchronize or induce ovulation in gilts.     

Prostaglandin levels in peripheral and follicular plasma, the isolated theca and granulosa layers of pre- and postovulatory follicles, and the myometrium and mucosa of the shell gland (uterus) during a midsequence-oviposition of the hen (Gallus domesticus)

Prostaglandins (PG) F and E were measured by radioimmunoassay in peripheral, uterine and follicular plasma and in the theca and granulosa layers of the five largest preovulatory and the three largest postovulatory follicles, and in the myometrium and mucosa. Plasma and tissues were collected 16, 12, 8 and 4 h before and immediately after a midsequence oviposition that was accompanied by the next ovulation. PGF concentrations in the peripheral and uterine plasma increased at oviposition with a concomitant, 16-fold increase in plasma PGF concentrations of the largest preovulatory (F1) follicle. There was a gradual increase in PGF concentrations in the theca layers during follicular maturation, with the large increases occurring 12 h before oviposition in most follicles. The highest and the second highest concentrations were observed at oviposition in the F1 and the largest postovulatory (R1) follicles. In contrast, there were no specific changes in PGF concentrations in the granulosa layers of the follicles in relation to oviposition or follicular maturation. PGE concentrations in the theca layers of the F2 and F1 follicles were greater than in other follicles, while concentrations in the granulosa layer of all the follicles remained low. PGF concentrations in the myometrium and mucosa increased 8 h before oviposition but abruptly decreased at oviposition. These results suggest that the primary source of the increase in plasma PGF at oviposition are the theca layers of the F1 and R1 follicles and that PGs may be involved in uterine contractions for oviposition and in the ovulation process.