Inhibition of estrus and corpora lutea function with Norgestomet

Forty-five nonpregnant, nonlactating, Angus and Brangus cows were utilized to determine how long a Norgestomet ear implant would inhibit estrus when administered at various stages of an estrous cycle. All cows completed a nontreated estrous cycle to ensure normal cyclicity. At the second observed estrus (estrus = Day 1), cows were randomly allotted to be treated at metestrus (Day 3 or Day 4, n = 15); at diestrus (Day 9 or Day 10, n = 14); or at proestrus (Day 15 or Day 16, n = 16). All cows received a 2-ml intramuscular injection of 3 mg of Norgestomet accompanied by a 6-mg Norgestomet ear implant, which remained in situ for 21 days, or until individual cows were observed in estrus. Estrus was inhibited for a mean (+/- SEM) of 18.7 +/- 0.7, 19.9 +/- 0.8, and 17.0 +/- 0.8 days, respectively, when cows were treated at metestrus, diestrus, and proestrus (metestrus and diestrus vs proestrus; P < 0.05). Estrus was inhibited for an entire 21-day implantation period in 27, 50, and 38% of cows treated at metestrus, diestrus, and proestrus, respectively (P > 0.10). Norgestomet inhibited estrus in all cows for 11, 17, and 11 days after implantation when treatment was initiated at metestrus, diestrus, and proestrus, respectively (P > 0.10). These data indicate that a 6-mg Norgestomet ear implant effectively inhibits estrus in all cows for a maximum of 11 days, with some cows exhibiting estrus by Day 12 with the Norgestomet implant in situ.     

Inhibition of sperm transport and fertilization in superovulating ewes

In Experiment 1, all ewes were treated with follicle stimulating hormone (FSH-P) to induce superovulation. Ewes came into natural estrus or were treated with prostaglandin F(2)alpha (PGF(2)alpha) or 6-methyl-17-acetoxyprogesterone (MAP) to regulate the time of estrus. The ewes were mated during estrus and necropsied 3 h after mating. Regulation of estrus with either compound reduced the number of sperm recovered from the cervix, uterus, and oviducts and increased the proportions of sperm recovered from the cervix and uterine body that were immotile, dead, or had disrupted membranes. In Experiment 2, all ewes were in natural estrus. They either ovulated naturally or were superovulated, and ewes in each group were necropsied at 3 or 23 h after mating. Superovulation reduced the number of sperm in oviducts, uterus, and anterior segments of the cervix at both time intervals and increased the proportions of sperm that were immotile, dead, or had disrupted membranes. In Experiment 3, of 3x2 design, ewes were in either natural estrus or estrus regulated with PGF(2)alpha or with MAP; they ovulated naturally or were superovulated. Ewes were necropsied 3 d after mating and ova were examined. Both regulation of estrus and superovulation reduced the proportion of ova that were fertilized and reduced the number of accessory sperm attached to fertilized ova.     

Comparison of two progestogens during out-of-season breeding in a commercial ewe flock

A comparison was made of the relative effectiveness of subcutaneous ear implants containing 2 mg Norgestomet or vagnial pessaries containing 60 mg medroxyprogesterone acetate (MAP) to induce estrus and conception in dry anestrous ewes. Groups of ewes were treated with one of the two progestogens for 14 d, and 500 IU pregnant mare serum gonadotropin (PMSG) was administered intramuscularly at the time of progestogen withdrawal. No significant differences in estrus induction, pregnancy rate or number of lambs born per ewe lambing were observed. Ewes treated with Norgestomet had 96% estrus, 60% pregnancy rate and 1.4 lambs per ewe lambing. Comparably, ewes treated with MAP had 94% estrus, 65% pregnancy rate and 1.7 lambs per ewe lambing. Norgestomet implants compared favorably with MAP pessaries for estrus induction and breeding of commercial, dry anestrous ewes.     

Investigations on the detrimental effect of prostaglandin F2α-regulated estrus on the number and condition of sperm in the reproductive tract of the ewe

Ewes in the luteal phase of the estrous cycle were treated with prostaglandin F₂α (PGF), mated to rams at the ensuing estrus 2 days later, and necropsied at 2 or 23 hr after mating. At 2 hr after mating, ewes in PGF-regulated estrus had significantly fewer sperm in the middle and anterior one-thirds of the cervix and in the uterus than did ewes mated during natural estrus. At 23 hr, soon after ovulation, significantly fewer ewes in PGF-regulated estrus had sperm in the oviducts than did ewes in natural estrus.In Experiment 2, ewes in PGF-regulated or natural estrus were laparotomized, inseminated by deposition of semen in the uterine lumen, and necropsied 2 or 23 hr later. Intrauterine insemination prevented most of the reduction in sperm numbers in the reproductive tract at PGF-regulated estrus.In Experiment 3, ewes in PGF-regulated or natural estrus were either mated to rams or inseminated in the uterine lumen and necropsied 2 hr later. Sperm were recovered from three segments of the cervix and were counted and evaluated for motility, response to live-dead staining, and acrosomal morphology. Intrauterine insemination again reduced the detrimental effect of PGF-regulated estrus on sperm numbers. However, the percentages of sperm recovered from the cervix that were motile, live, and had normal acrosomes were much lower in ewes in PGF-regulated estrus than in ewes in natural estrus. Compared with natural mating, intrauterine insemination reduced but did not eliminate the detrimental effects of PGF-regulated estrus on the viability and morphology of sperm. Regulating estrus with PGF resulted in damage to sperm in the cervix regardless of whether sperm reached the cervix from the vagina or from the uterus.     

Investigations on spermicidal activity in the sheep vagina.

This study was conducted to elucidate some of the effects of a synthetic progestagen and natural ovarian hormones on spermicidal activity in the sheep vagina. In the first experiment, parous ewes were treated for 17 days either intravaginally with medroxyprogesterone acetate (MAP) or subcutaneously with progesterone. They were inseminated artificially either on the last day of progestagen treatment or during estrus after progestagen withdrawal. Their vulvovaginal junctions were ligated to prevent the loss of sperm cells by drainage to the exterior. Untreated control ewes were inseminated during either estrus or the luteal phase of the estrous cycle. The ewes were killed 22 hr. after insemination, their vaginas flushed, and intact sperm cells and tailless sperm heads counted. In the second and third experiments, some of the ewes were bilaterally ovariectomized and inseminated several weeks later. Other ewes were ovariectomized and given subcutaneous injections of estradiol, progesterone, or both hormones.In the first experiment, most sperm cells were recovered intact from estrous or luteal phase control ewes. The intravaginal administration of MAP increased both the breakage of sperm cells into heads and tails and the disappearance of sperm cells. The spermicidal effects of MAP were just as great in ewes inseminated on the last day of treatment. as in those inseminated during the ensuing estrus; these results indicated that the peak estrogen secretion that occurs near the beginning of estrus was not necessary for the intensification of spermicidal activity.In the second experiment, ovariectomized ewes were compared to estrous and luteal phase ewes in regard to vaginal spermicidal activity. Sperm breakage and disappearance occurred least in estrous ewes, to a somewhat greater degree in luteal phase ewes, and to the greatest extent in ovariectomized ewes. The results suggested that endogenous ovarian hormones, particularly those in estrous ewes, suppress spermicidal mechanisms in the vagina.In the third experiment, the administration of estradiol and progesterone to ovariectomized ewes prevented the increase in sperm cell disappearance. Neither hormone alone prevented the increase.     

Effects of hormonal manipulation on the resumption of postpartum reproductive activity in Texel ewes

Three experiments were conducted on Texel ewes to study the influence of prostaglandin F(2alpha) (PGF(2alpha)), prolactin (PRL), estradiol (E(2)), and gonadotrophin releasing hormone (GnRH) on postpartum reproductive activity. In Experiment 1, oral administration of indomethacin (25 to 50 mg/day/ewe) from Day 3 post partum to the first detected estrus inhibited plasma 13, 14-dihydro-15-keto, PGF(2alpha) (PGFM) concentrations (P < 0.0001). This treatment resulted in an earlier rise in the frequency and amplitude of luteinizing hormone (LH) pulses and a resumption of estrous behavior (P < 0.05), while ovarian activity estimated by progesterone (P(4)) concentrations resumed to the same extent in treated ewes and controls. Bromocriptine treatment (2.5 mg/day/ewe) reduced plasma PRL levels (P < 0.0001) but had no effect on ovarian activity as evidenced by P(4) and resumption of estrus or on either the frequency or amplitude of the LH pulse. In Experiment 2, a single injection of GnRH agonist (42 mcg of buserelin/ewe) on Day 16 post partum resulted in an abrupt elevation of plasma LH concentrations; mean LH values were 18 to 27 times higher when compared with those of the control ewes. Two days after this treatment, ovulations occurred in 5 of the treated ewes and in 2 of the control ewes. This induced ovarian activity was not associated with estrous behavior; however, after an adequate subsequent luteal phase all the treated ewes displayed estrus, the resumption of estrus thus being earlier in treated than in control ewes (P < 0.01). In Experiment 3, E(2) supplementation from Day 16 to Day 28 post partum increased the number of LH pulses per 6 hours in suckling ewes (P < 0.05) and induced earlier resumption of estrus in dry ewes but not in suckling ewes (P < 0.01). Luteal function was detected about 5 and 8 days after the insertion of E(2) implants in 4 dry ewes and in 2 suckling ewes, respectively.     

Induction of estrus and superovulation in seasonally anestrous ewes

The induction of estrus in 17 previously cycling nulliparous ewes, 9 to 10 months of age, was attempted with Medroxyprogesterone acetate (MAP) pessaries during the early anestrous period (March-April). Ewes were verified to be anestrous by the lack of estrous behavior in the presence of a vasectomized ram and by a radioimmunoassay for serum progesterone in two samples taken 7 days apart showing less than 1 ng/ml serum progesterone. Superovulation was attempted with injections of either FSH or FSH + LH. MAP vaginal pessaries remained in place for a period of 12 days and FSH was administered to all ewes (IM) at 12 hr intervals over a 3 day period; 5 mg was injected twice on day 11 after pessary insertion, followed by 4 and 3 mg injections twice daily on each succeeding day, for a total of 24 mg per ewe. Nine ewes were given 25 mg LH (IV) within 8 hrs after the onset of behavioral estrus in addition to FSH. Ewes were hand-mated to several rams at 12 hr intervals throughout the estrus period. Ovulation and fertilization rates were recorded for each ewe following midline laparotomy and embryo collection. All ewes were in estrus between 36 and 48 hrs after removal of the MAP pessaries. In ewes injected with FSH only, 8 of 8 ovulated with a mean ovulation rate of 6.0 +/- 4.4 and a fertilization rate of 70%. Nine of 9 ewes receiving both FSH + LH ovulated with a mean ovulation rate of 13.9 +/- 13.1 and a fertilization rate of 72%. Statistical analysis by Students t-test resulted in differences in number of ova recovered (P<.05) between FSH only and FSH + LH treated ewes and a trend towards increased ovulation rate in FSH + LH treated ewes. These results show that early seasonally anestrous ewes can be successfully induced and synchronized for estrus with MAP pessaries and the number of ova recovered is increased with the inclusion of LH in the superovulation regime.     

Effect of low dose of FSH given at the beginning of the estrous cycle and subsequent superovulatory response in Holstein cows

A total of 47 superovulations were conducted on forty non-lactating cows to evaluate two different schemes using follicle stimulating hormone (FSH) for superovulating cattle. Cows randomly assigned to treatment A (26 collections) were superovulated beginning on days 9 to 13 of the estrous cycle by giving FSH at decreasing doses of 6, 6, 5, 5, 3, 3, and 2, 2 mg for 4 consecutive days at 12-h intervals while those in treatment B (21 collections) also received 2.5 mg of FSH on days 3 and 4 of the estrous cycle. Animals in both treatments were each given 12.5 mg of prostaglandin F(2alpha) (PGF(2alpha)) at 60 and 72 h after the initiation of superovulatory treatment. Cows were artificially inseminated at 0, 12, and 24 h after the onset of estrus. Embryos were recovered nonsurgically on d 6 and morphologically evaluated. Ovaries of the cows were palpated at the end of flushings to assess the number of corpora lutea (CL). The mean interval from PGF(2alpha) to the onset of estrus was not different (P>0.05) for treatments A (56.6 h) and B (50.0 h). Also, mean duration of standing estrus was not different for either treatment (13.4 h vs 12.8 h). The mean number of CL palpated (7.3 vs 12.9) and ova recovered (5.5 vs 14.2) were significantly greater (P<0.05) for treatment B. The mean number of excellent and good embryos recovered was lower for treatment A animals, but not significant (P>0.05). Therefore, low doses of FSH given at the beginning of the cycle increased ovulation rate and embryo recovery in non-lactating cows.     

Prostaglandin F2alpha-induced estrus in ewes exhibiting estrous cycles of different duration

Effects of prostaglandin F(2alpha) (PGF(2alpha)), administered during the mid-luteal phase of the estrous cycle, were examined in ewes exhibiting estrous cycles classified as short (< or =16.5 days, short-cycle ewes, n = 10) or long (> or =18 days, long-cycle ewes, n = 9) based on the durations of two estrous cycles (cycles -2 and -1) before treatment. The ewes received (i.m.) 20mg of PGF(2alpha) on day 10 of the third estrous cycle (cycle 0) followed, 36 h later, by 25 microg of gonadotropin releasing hormone (GnRH) to time the events of ovulation. Duration of subsequent estrous cycles +1 and +2 were recorded, and then the ewes were treated with the same combination of PGF(2alpha) and GnRH beginning on day 10 of estrous cycle +3. Ovaries were recovered 6h after GnRH administration to assess development of pre-ovulatory follicles. The proportion of ewes that exhibited estrus after PGF(2alpha) and GnRH treatment on cycle 0 was not different (P > 0.05) between short- and long-cycle ewes. Onset of estrus occurred sooner (P < 0.05) after PGF(2alpha) injection in short-cycle ewes than in long-cycle ewes (1.9 +/- 0.1 days and 2.3 +/- 0.1 days, duration of cycle 0 was 11.9 and 12.3 days, respectively). Duration of estrous cycle +1 was 1.2 days longer (P < 0.01) than cycle -1 in short-cycle ewes. However, duration of estrous cycle +1 did not change (P > 0.05) after PGF(2alpha) and GnRH administration in ewes having long cycles. Pre-ovulatory follicles did not differ (P > 0.05) in numbers, diameter, layers of granulosa cells nor concentrations of progesterone and estradiol-17beta in follicular fluid between short- and long-cycle ewes after PGF(2alpha) and GnRH treatment. In conclusion, ewes having short or long estrous cycles responded differently to PGF(2alpha) and GnRH treatment with respect to the interval to onset of estrus and duration of the subsequent estrous cycle.     

Estrus synchronization and pregnancy rates in cyclic and noncyclic beef cows and heifers treated with syncro-mate B or Norgestomet and Alfaprostol

Postpartum lactating cows (N=118) and virgin heifers (N=60) were treated with subcutaneous Norgestomet implants for nine days and received either an intramuscular injection (im) of 5 mg estradiol valerate and 3 mg Norgestomet at the time of implant insertion or an im injection of 5 mg Alfaprostol 24 hr before implant removal. Animals were artificially inseminated 12 hr after detection of estrus. Of the cows and heifers, 78% and 88%, respectively, were in estrus within five days after implant removal (P<0.09). There was no difference between treatments in the proportion of animals in estrus or in the timing of estrus (P<0.85). Estrus was detected in a greater (P<0.05) proportion of animals that were cyclic prior to treatment (88%) than among those that were anestrous prior to treatment (77%). Pregnancy rates after five days were similar between heifers that were cyclic (42%) or anestrous (47%) prior to treatment; however, the five-day pregnancy rate in cows that were anestrous prior to treatment was 38% lower than that in cows that were cyclic prior to treatment (17 vs 55%, P<0.01). Although the treatments synchronized or induced estrus in both cyclic and anestrous animals, marked variability in estrous response and fertility among previously cyclic or anestrous postpartum cows limited the effectiveness of the treatments.     

Response of anestrous ewes to norgestomet and PMSG

A 10-day treatment regime with a subcutaneous ear implant containing 3 mg of norgestomet, accompanied by an intramuscular injection of 1.5 mg norgestomet and 0.5 mg estradiol valerate (EV) on day 1 and 750 I. U. pregnant mares serum gonadotropin (PMSG) given intravenously on day 10, proved effective in eliciting estrus in 72% of 110 anestrous ewes within 5 days of treatment. Ewes which were treated in months closer in proximity to the normal breeding scason responded with significatly increased induction of estrus, with 71, 37, 59, 74, and 97% in estrus for ewes which were treated in February through June, respectively. Comparable estrous response in nontreated, control ewes was 0, 13, 0, 10, and 24% during February through June, respectively. (Treated vs controls, P<.01). Pregnancy rate to first service of ewes in estruc was 51% in treated and 30% in control ewes (P>.10). Overall pregnancy rate for all ewes in both groups was 36% in treated and 3% in control ewes during 5 or 16 days of breeding, respectively (P<.01).     

Effect of dose and time of injection of prostaglandin F(2alpha) in cycling ewes

A study was done to evaluate the efficacy of graded doses of prostaglandin F(2alpha) (PGF(2alpha)) to induce regression of the corpus luteum and hence estrus, in cycling ewes when given on various days of the estrous cycle. One hundred cycling cross-bred ewes were observed twice daily (08:00 and 20:00 h) for marking by raddled vasectomized rams. After estrus was confirmed in marked ewes by assay of plasma progesterone concentration, the ewes were treated in pairs with 0, 5, 10, 15 or 20 mg PGF(2alpha) on day 2, 3, 4, 7, 8, 9, 12, 13, 14 or 15 of an estrous cycle and then exposed to a raddled ram of known libido and fertility. Plasma progesterone levels were determined on the day of, and on the day following PGF(2alpha)-treatment to monitor luteal function. Ewes marked between one and five days after treatment and having a decrease in plasma progesterone were considered to have responded to the treatment. The percentages of ewes responding were 10, 35, 60, 70 and 95 to doses of 0, 5, 10, 15 and 20 mg PGF(2alpha) respectively. Differences due to dose were significant (P < 0.01) with the two higher doses being more effective. There were differences due to the day of injection, with treatments on days 2 and 3 being less effective.     

Relationship between doses of prostaglandin F2alpha and stages of the breeding season for synchronization of estrus and ovulation in ewes

Two experiments were conducted to compare estrous response to three doses (8, 16 and 24 mg) of prostaglandin F(2alpha) (PGF(2alpha)) administered by intramuscular injection to ewes between day 6 and 12 of the estrous cycle (Experiment I) and to ewes on unknown days of the estrous cycle during four different stages of the breeding season (Experiment II). In experiment I, a total of 41 ewes were treated with PGF(2alpha). The injection of 24 mg PGF(2alpha) resulted in a higher proportion of ewes exhibiting estrus (13 14 , 92.9%) within 5 days after treatment as compared to the other two doses (2 12 and 10 15 , for 8 and 16 mg PGF(2alpha), respectively). However, there was no significant difference for the proportion between 16 mg and 24 mg PGF(2alpha). In experiment II, PGF(2alpha) was given to ewes on the 3rd of February (early breeding season), the 28th of February (mid-early breeding season), the 10th of April (mid breeding season) and the 27th of May (late breeding season). These was a significant difference for the proportion of ewes exhibiting estrus between the early breeding season and the other three seasons (P < 0.05) but not for ewes ovulating. Throughout the breeding season, 16 mg PGF(2alpha) appeared to be slightly better than the other two doses (8 and 24 mg) although there was no overall difference in the estrous responses to treatment among the three doses. However, a significant difference in the proportion of ewes ovulating was found among the three doses of PGF(2alpha) (P < 0.05). Especially, 16 mg PGF(2alpha) was significantly superior to 8 mg (P < 0.01) and 24 mg (P < 0.05). It was considered that there was a complicated relationship between the doses of PGF(2alpha) and the stages of the breeding season for induction of estrus and ovulation in the ewe.     

Reducing the incidence of short estrous cycles in beef cows with norgestomet

Twenty-nine anestrous cows suckling calves 27 to 67 days old were allotted to 3 treatment groups according to calving date. Calves were weaned from all cows; 9 cows received no further treatment, while 10 were implanted with 6 mg of norgestomet 9 days before calves were weaned and 10 were implanted when calves were weaned. All implants were removed after 9 days. Twenty-two cows exhibited estrus within 10 days after treatment, and all exhibited estrus within 25 days. In the cows exhibiting estrus in 10 days, norgestomet reduced the incidence of 8 to 12-day cycles from 83.3 percent in the control group to 30 percent when implanted before weaning and to zero when implanted at weaning. Conception rates at first service were increased from zero for cows which were not implanted to 33.3 and 80 percent for those implanted before and at weaning, respectively. These data demonstrate that the presence of a progestogen before the first postpartum estrus increases conception rates and reduces the percentage of previously anestrous cows exhibiting short estrous cycles after their calves are weaned.     

Effect of systemic or intrauterine injections of indomethacin on plasma oxytocin-neurophysin concentrations in ewes over the time of normal corpus luteum regression

This study was undertaken to investigate the effect of systemic or intrauterine injections of indomethacin, a known prostaglandin (PG) synthetase inhibitor, on peripheral plasma oxytocin-associated neurophysin (OT-N) concentrations in ewes over the time of expected luteolysis. In the first experiment, 9 ewes were given i.m. injections of indomethacin (4 mg/kg live weight, n = 4) or vehicle (n = 5) 3 times/day over Days 13-15 of the estrous cycle. Blood samples were collected at hourly intervals from 0700 h on Day 13 to 1800 h on Day 15 post-estrus. In the second experiment, indomethacin (20 mg, n = 5) or the injection vehicle (n = 4) was given twice daily into the uterine horn over Days 12-14 post-estrus. Blood samples were collected at hourly intervals from Day 12 to 14. In the third experiment, 4 additional ewes were bled at 5-min intervals from 1200 to 1600 h on Day 13 of the estrous cycle. Plasma samples were analyzed for OT-N and 13,14-dihydro-15-keto-prostaglandin F2 alpha (PGFM) to provide an indirect index for ovarian oxytocin and uterine prostaglandin F2 alpha release, respectively. Results from the first experiment indicated that surges in plasma OT-N concentrations occurred in the vehicle-treated ewes but were suppressed in ewes given systemic injections of indomethacin. Intrauterine indomethacin injections did not cause a significant reduction in the maximum peak height or number of peaks when compared with the control ewes. In the third experiment, there was a marked increase in plasma OT-N concentrations, but no significant rise in plasma PGFM concentrations in one ewe.(ABSTRACT TRUNCATED AT 250 WORDS)     

Ovine uterine gland knock-out model: effects of gland ablation on the estrous cycle

Ovine endometrial gland development is a postnatal event that can be inhibited epigenetically by chronic exposure of ewe lambs to a synthetic progestin from birth to puberty. As adults, these neonatally progestin-treated ewes lack endometrial glands and display a uterine gland knockout (UGKO) phenotype that is useful as a model for study of endometrial function. Here, objectives were to determine: 1) length of progestin exposure necessary from birth to produce the UGKO phenotype in ewes; 2) if UGKO ewes display normal estrous cycles; and 3) if UGKO ewes could establish and/or maintain pregnancy. Ewe lambs (n = 22) received a Norgestomet (Nor) implant at birth and every two weeks thereafter for 8 (Group I), 16 (Group II), or 32 (Groups III and IV) weeks. Control ewe lambs (n = 13) received no Nor treatment (Groups V and VI). Ewes in Groups I, II, III, and VI were hemihysterectomized (Hhx) at 16 weeks of age. After puberty, the remaining uterine horn in Hhx ewes was removed on either Day 9 or 15 of the estrous cycle (Day 0 = estrus). Histological analyses of uteri indicated that progestin exposure for 8, 16, or 32 weeks prevented endometrial adenogenesis and produced the UGKO phenotype in adult ewes. Three endometrial phenotypes were consistently observed in Nor-treated ewes: 1) no glands, 2) slight glandular invaginations into the stroma, and 3) limited numbers of cyst- or gland-like structures in the stroma. Overall patterns of uterine progesterone, estrogen, and oxytocin receptor expression were not different in uteri from adult cyclic control and UGKO ewes. However, receptor expression was variegated in the ruffled luminal epithelium of uteri from UGKO ewes. Intact UGKO ewes displayed altered estrous cycles with interestrous intervals of 17 to 43 days, and they responded to exogenous prostaglandin F(2 approximately ) (PGF) with luteolysis and behavioral estrus. During the estrous cycle, plasma concentrations of progesterone in intact control and UGKO ewes were not different during metestrus and diestrus, but levels did not decline in many UGKO ewes during late diestrus. Peak peripheral plasma concentrations of PGF metabolite, in response to an oxytocin challenge on Day 15, were threefold lower in UGKO compared to control ewes. Intact UGKO ewes bred repeatedly to intact rams did not display evidence of pregnancy based on results of ultrasound. Collectively, results indicate that 1) transient, progestin-induced disruption of ovine uterine development from birth alters both structural and functional integrity of the adult endometrium; 2) normal adult endometrial integrity, including uterine glands, is required to insure a luteolytic pattern of PGF production; and 3) the UGKO phenotype, characterized by the absence of endometrial glands and a compact, disorganized endometrial stroma, limits or inhibits the capacity of uterine tissues to support the establishment and/or maintenance of pregnancy.     

Cervical versus intrauterine insemination of ewes using fresh or frozen semen diluted with aloe vera gel

This study was conducted at Belen de Escobar, Argentina, in March and April 1987. Experimental work on synchronization of estrus, deep-freeze conservation of ram semen and small fertility trials involving cervical and intrauterine (i.u.) insemination methods was undertaken. A total of 80 Corriedale ewes were used in seven insemination trials. Insemination trials were grouped into two experimental groups for comparison of 1) frozen semen diluted with an experimental extender and a control diluent inseminated cervically or i.u. in synchronized/superovulated ewes and 2) cervical insemination of fresh diluted or frozen semen in ewes inseminated at natural estrus or in ewes that were synchronized/superovulated. An overall ovulation rate of 8.7 +/- 0.5 was obtained by using a superovulatory regimen consisting of 3 mg Norgestomet implants and a total dose of 18 mg follicle stimulating hormone-pituitary (FSH-P). Numbers of ova recovered per ewe following superovulation ranged from 4.3 to 5.4. In experimental Group I, fertilization rates improved when laparoscopic intrauterine AI was used compared with cervical insemination (P<0.05). Fertility rates of i.u. and cervical insemination of frozen semen diluted with the experimental extender showed satisfactory fertilizing capacity. In experimental Group II, a lower number of fertilized ova were recovered from ewes inseminated with frozen semen (P<0.02), irrespective of their estrus manipulation.     

Use of fluorogestone acetate after breeding to reduce the effect of premature luteal regression in dairy goats when superovulation is induced with FSH

The aim of the present study was to determine the effect of fluorogestone acetate (FGA) administered after mating, on embryo production in the dairy goat subjected to conventional superovulatory and embryo recovery protocols. Adult does, most of them of the French Alpine breed, were randomly assigned after a FSH-superovulatory estrus and fertile matings to a control group (n=20) or to a treated group (n=20) in which intravaginal sponges impregnated with FGA were inserted after mating and remove before embryo collection (day 6). Blood samples were collected every 12h from days 1 to 7 post-estrus and serum progesterone concentrations were determined. The FGA-group had a lesser percentage of does with normal corpora lutea (CL) and a greater percentage of animals with CL in regression or mixed (normal and in regression) when compared with the control group (13.3 and 64.7%, 53.3 and 23.5%, and 33.3 and 11.8%, respectively; P<0.05). Mean number of normal CL per doe was less and mean number of regressed CL greater in FGA as compared with the control group (4.2 compared with 10.7 and 8.5 compared with 3.6, respectively; P<0.05). There were no differences (P>0.05) in recovery rate, total number of CL, total recovered structures, oocytes and transferable and non-transferable embryos between groups. Serum progesterone concentrations from day 5 to 7 post-estrus were lower (P<0.05) in FGA as compared with the control group. Percentage of does with luteal failure on day 6 post-estrus was greater in FGA as compared with the control group (86.6 compared with 33.3%; P<0.01). When considering only does with luteal failure on day 6 post-estrus, mean total recovered structures, transferable embryos and percentage of does rendering > or =3 transferable embryos were greater in the FGA compared with the control group (6.3 and 1.3 structures, 4.5 and 1.2 embryos, 67 and 17%, respectively; P<0.05). In does not having luteal failure, FGA administration did not appear to affect embryo production or embryo survival. These results indicate that FGA administration after mating improves embryo recovery in dairy goats with luteal failure after superovulatory treatment. However, it also increases the incidence of luteal regression when administered early in the estrous cycle.     

Role of progesterone in regulating uteroovarian venous concentrations of PGF2 alpha and PGE2 during the estrous cycle and early pregnancy in ewes

The role of progesterone in regulation of uteroovarian venous concentrations of prostaglandins F2 alpha(PGF2 alpha) and E2 (PGE2) during days 13 to 16 of the ovine estrous cycle or early pregnancy was examined. At estrus, ewes were either mated to a fertile ram or unmated. On day 12 postestrus, ewes were laparotomized and a catheter was inserted into a uteroovarian vein. Six mated and 7 unmated ewes received no further treatment. Fifteen mated and 13 unmated ewes were ovariectomized on day 12 and of these, 7 mated and 5 unmated ewes were given 10 mg progesterone sc and an intravaginal pessary containing 30 mg of progesterone. Uteroovarian venous samples were collected every 15 min for 3 h on days 13 to 16 postestrus. Mating resulted in higher mean daily concentrations of PGE2 in the uteroovarian vein than in unmated ewes. Ovariectomy prevented the rise in PGE2 with day in mated ewes but had no effect in unmated ewes. Progesterone treatment restored PGE2 in ovariectomized, mated ewes with intact embryos. Mating had no effect on mean daily concentrations of PGE2 alpha or the patterns of the natural logarithm (1n) of the variance of PGF2 alpha. Ovariectomy resulted in higher mean concentrations and 1n variances of PGF2 alpha on day 13 and lower mean concentrations and 1n variances of PGF2 alpha on days 15 and 16. Replacement with progesterone prevented these changes in patterns of mean concentrations and 1n variances of PGF2 alpha following ovariectomy. It is concluded that progesterone regulates the release of PGF2 alpha from the uterus, maintaining high concentrations while also preventing the occurrence of the final peaks of PGF2 alpha which are seen with falling concentrations of progesterone. This occurs in both pregnant and non-pregnant ewes. Progesterone is also needed to maintain increasing concentrations of PGE2 in mated ewes.     

Corpus luteum function in the ewe: Effect of PGF2α and prostaglandin synthetase inhibitors

A series of experiments were conducted to evaluate the effects of mode and frequency of administration and estrous cycle stage on the response of the cycling ewe to PGF_2α. The effects of dexamethasone, arachadonic acid and prostaglandin synthetase inhibitors on estrous cycle length and plasma progesterone levels were also determined.Intramuscular administration of 5 or 10 mg of PGF_2α, on days 8 and 9 after estrus (5 ewes/group), significantly (p<.01) shortened the mean length of the estrous cycle and the interval from the end of treatment to estrus. Mean plasma progesterone levels, 24 hours after initial injection, were significantly (p<.01) lowered. When administered on day 8 only, these doses were considerably less effective in shortening estrous cycle length or lowering plasma progesterone levels. Intravaginal administration of PGF_2α, by polyurethane tampon, was also largely ineffective.Treatment of ewes with 10 mg of PGF_2α i.m., on days 3 and 4 of the estrous cycle, resulted in a return to estrus in 2 days in 25% of the treated animals. Plasma progesterone levels of PGF_2α-treated ewes were significantly lower than controls on the second, third and fourth days after the start of dosing. It would appear that PGF_2α exerts a retarding effect on developing CL functionality.The prostaglandin synthetase inhibitors, aspirin, flufenamic acid and 1-p-chlorobenzylidene-2-methyl-5-methoxy-3-indenylacetic acid, were administered orally or parenterally for 16 days beginning on day 8 of the estrous cycle. These compounds failed to prolong estrous cycle length. Parenteral administration of dexamethasone did not result in PGF_2α release in the cycling ewe, at least not in quantities sufficient to induce luteolysis. The prostaglandin precursor, arachadonic acid, also was not luteolytic when given parenterally to cycling ewes.