Progesterone promotes oocyte maturation, but not ovulation, in nonhuman primate follicles without a gonadotropin surge

During the periovulatory interval, intrafollicular progesterone (P) prevents follicular atresia and promotes ovulation. Whether P influences oocyte quality or maturation and follicle rupture independent of the midcycle gonadotropin surge was examined. Rhesus monkeys underwent controlled ovarian stimulation with recombinant human gonadotropins followed by a) experiment 1: an ovulatory bolus of hCG alone or with a steroid synthesis inhibitor (trilostane, TRL), or TRL + the progestin R5020; or b) no hCG, but rather sesame oil (vehicle), R5020, or dihydrotestosterone (DHT). In experiment 1, the majority of oocytes remained immature (65% +/- 20%) by 12 h post-hCG. However, the percentage of degenerating oocytes increased (P < 0.05) with TRL (42% +/- 22% vs. 0% controls), but was reduced (P < 0.05) by progestin replacement (15% +/- 7%). By 36 h post-hCG, the majority of oocytes in all three groups reached metaphase II (MI). In experiment 2, no evidence of follicle rupture was observed in the vehicle, R5020, or DHT groups. Despite the absence of hCG, a significant (P < 0.05) percentage of oocytes resumed meiosis to metaphase I in R5020- (41 +/- 9) and DHT- (36 +/- 15) but not vehicle- (4 +/- 4) treated animals. Only oocytes from R5020-treated animals continued meiosis in vivo to MII. More (P < 0.05) oocytes fertilized in vitro with R5020 (40%) than with vehicle (20%) or DHT (22%). Thus, P is unable to elicit ovulation in the absence of an ovulatory gonadotropin surge; however, P and/or androgens may prevent oocyte atresia and promote oocyte nuclear maturation in primate follicles.     

Aspiration of equine oocytes from immature follicles after treatment with equine pituitary extract (EPE) alone or in combination with hCG

This study examined the effect of treating mares with equine pituitary extract (EPE) alone or in combination with hCG on the recovery rate of immature follicles by transvaginal follicular aspiration (ovum pick-up; OPU). Ten normally cycling crossbred mares aged 3-15 years and weighing 350-400 kg were subjected to each of three treatments in a random sequence with each exposure to a new treatment separated by a rest cycle during which a spontaneous ovulation occurred. The treatments were (1) superovulated with 25mg EPE and treated with 2500 IU hCG, (2) superovulation with 25mg EPE, and (3) control (no exogenous treatment). Treatments 7 days after spontaneous ovulation; and all the follicles >10mm were aspirated 24h after the largest follicle achieved a diameter of 27-30 mm for control group, and most follicles reached 22-27 mm for the EPE alone treatment. To the group EPE+hCG, when the follicles reached 22-27 mm, hCG was administered, 24h before OPU. Superovulation increased the number of follicles available for aspiration. The total number of follicles available for aspiration was 61 in the EPE/hCG group, 63 in the EPE group and 42 in the control. The proportion of follicles aspirated varied from 63.5% to 73.8%. Oocyte recovery rate ranged from 15.0% to 16.7% and the proportion of mares that yielded at least one oocyte was 70% (7/10) in the EPE/hCG, 60% (6/10) in the EPE alone and 50% (5/10) in control group. The EPE/hCG treatment had a higher proportion of follicles with expanded granulose cells (64.4%) than the control (3.3%; p<0.05) and the EPE treatment (25.0%). The intervals from spontaneous ovulation to aspiration were similar for all treatments (11-12 days). However, superovulatory treatment significantly increased the aspiration to ovulation interval from 15+/-4 days for control to 27+/-15 days for EPE (p<0.05) and to 23+/-13 days for EPE/hCG treatment with commensurate increases in the time between spontaneous ovulations.     

Exogenous growth hormone improves the number of transferable embryos in superovulated ewes.

The application of pGH (porcine Growth Hormone) to superovulated ewes was studied with the aim of improving the embryo yield. Thirty-seven ewes were superovulated with pFSH for 3 d and 18 of them were cotreated the third day with 0.50 mg of pGH. Embryos were surgically recovered on Day 7 after sponge withdrawal. Then, 102 morphologically healthy embryos were immediately transferred in pairs to 51 synchronized recipient ewes. The GH treatment did not significantly affect the percentage of ewes in estrus, the time of estrus onset or the ovulation rate. However, it improved synchronization by grouping estrus in a narrower range (12 h) in comparison to the control group (24 h); (16 to 28 h after sponge withdrawal vs 12 to 36 h; P < 0.05). The total amount of LH released during the preovulatory surge was lower in the GH than in the control group (P < 0.05). No differences were found between groups for other LH-related parameters such as basal levels, peak values or peak time from sponge removal. The proportions of unfertilized oocytes and degenerate embryos recovered were lower in the GH cotreated group (P < 0.05 and P < 0.01, respectively). This resulted in higher rates of transferable embryos and lambs born per donor ewe in the GH than in the untreated group (3.9 vs 1.7 and 2.28 vs 0.84, respectively; both, P < 0.05). These beneficial effects of GH would likely be due either to a direct action on oocyte maturation or to an indirect action on the oviductal environment.     

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.     

Early cycle FSH-p priming as a prelude to superovulating gonadotropin administration in ewes and heifers

The effect of an exogenous FSH treatment in the periovulatory, post-LH surge period on superovulatory response in the subsequent cycle of ewes and heifers was investigated. Thirty-five ewes were synchronized with progestagen pessaries and pregnant mares serum gonadotropin. The day following the onset of estrus (Day 1) 17 ewes received one intramuscular injection of 5 mg follicle stimulating hormone of porcine origin (FSH-p). All 35 ewes received another progestagen pessary on Day 1 and were superovulated with horse anterior pituitary extract (HAP). The ewes were bred and embryos collected 6 days following the onset of estrus. Early cycle FSH-p administration did not increase the subsequent ovulation rate (6.5 vs. 8.4 for controls, n.s.). Recovery rate for the FSH-p treated animals was higher (78.5% vs. 49.3%; P<0.05) as was fertilization rate (100% vs. 62.4%; P<0.05). The final result was a mean of 4.4 transferable embryos per ewe treated among the FSH-p boosted ewes and 2.6 transferable embryos per ewe treated among the control ewes.Twenty-nine heifers were brought into estrus with one 500-μg injection of prostaglandin F_2α (PG). Twelve of the 29 heifers were given one intramuscular injection of 10 mg FSH-p on either Day 2 or 3 (Day 1 is the day following the onset of estrus). All heifers were superovulated starting on Day 11–16, over a 4-day period using a decreasing dosage of FSH-p. Prostaglandin was administered at the time of the fifth superovulatory FSH-p injection and the heifers were bred by artificial insemination. Ova were recovered between 2 and 4.5 days following the onset of estrus. There was no effect on ovulation rate due to the interval from FSH-p priming to the day of superovulatory FSH-p initiation. The proportion of heifers that ovulated when given a FSH-p injection early in the cycle was higher than in the control group (94% vs. 68%; P<0.05). The primed heifers had a higher number of ovulations than did the control heifers (16.3 vs. 6.2; P<0.01). The effect of higher ovulation rate carried through all parameters measured, so that the FSH-p primed heifers also had a higher number of fertilized ova than the controls (10.7 vs. 3.9; P<0.05), indicating that there was no significant deterioration in ovum quality due to the FSH-p priming. The results show that FSH-p improved superovulatory efficiency in both sheep and cattle.     

Developmental competence of bovine embryos derived from oocytes collected at various stages of the estrous cycle

The developmental competence of bovine oocytes collected from donors at various stages of the estrous cycle and fertilized in vitro was investigated by comparing the yields of embryos obtained from oocytes isolated from the ovaries of cows slaughtered on estrous cycle Days 7 and 14, 8 and 15, 9 and 16 and on Days 19, 20 and 2. The percentages of oocytes that developed into blastocysts at Day 8 after exposure to spermatozoa were: 11.9 vs 20.0; 13.2 vs 30.5; 20.8 vs 29.8; and 11.7, 4.4 and 16.9, respectively. A significantly higher proportion of oocytes developed into blastocysts following isolation on cycle Days 14 to 16 (24.3 %) than following recovery on Days 7 to 9 (13.0 %; P < 0.05), Days 19 to 20 (6.6 %; P < 0.05) or Day 2 (16.9 %; P < 0.05). Embryo development was also faster in oocytes isolated at the end of the luteal phase (Days 14 to 16). These results demonstrate that the stage of the estrous cycle may influence the developmental potential of oocytes and in vitro embryo production.     

Protocol for the recovery of in vivo matured canine oocytes based on once daily measurement of serum progesterone

The collection of in vivo matured canine oocytes relies on the accurate prediction of ovulation. The present study was designed to develop a protocol for the recovery of in vivo matured canine oocytes based on once daily measurements of serum progesterone (P(4)) concentrations. Blood samples (2 mL) were collected every day at 0900 h, and P(4) concentrations were analyzed using a DSL-3900 ACTIVE((R)) Progesterone Coated-Tube Radioimmunoassay Kit. The average number of oocytes at the metaphase II (M II) stage was significantly higher at or after 72 h (6.7 to 7.5) compared to 56 h (1.7) following ovulation. The highest numbers of corpora lutea, and therefore the highest numbers of oocytes, were recovered from bitches with initial ovulatory P(4) concentrations ranging from 6.0 to 8.0 ng/ mL (12.2 and 11.4, respectively) compared to from 4.0 to 4.9 ng/ mL (9.6 and 8.8, respectively; p < 0.05). The average number of M II oocytes recovered at 84 h from bitches with initial ovulatory P(4) levels of 5.0 to 5.9 ng/mL (7.7) was higher compared to bitches with P(4) levels of 4.0 to 4.9 ng/ mL (3.5) and 6.0 to 8.0 ng/ mL (4.8; p < 0.05). When oocyte recovery time was adjusted for initial ovulatory P(4) concentration, no significant difference in recovery rates or oocyte quality were observed. In conclusion, once daily measurements of P(4) can be used to predict ovulation in bitches, and oocyte recovery time should be adjusted for initial ovulatory serum P(4) concentrations.     

Pentoxifylline improves in vitro fertilization and subsequent development of bovine oocytes

The purpose of this study was to examine whether pentoxifylline improves in vitro fertilization and developmental rates of bovine oocytes. In the first experiment, we examined the effects on the fertilization rate of various concentrations of pentoxifylline (0-7.5 mM) combined with heparin (10 IU/mL). In the second experiment, we examined fertilization cleavage and blastocyst rates after frozen-thawed spermatozoa, obtained from four different bulls, were incubated with heparin (10 IU/mL) with or without caffeine (5 mM) or pentoxifylline (5 mM). In the first experiment, a significantly higher fertilization rate was obtained in heparin containing 5 mM pentoxifylline compared to that in heparin alone or in heparin containing 7.5 mM pentoxifylline (86% vs 60% vs 64%, respectively). The percentage of monospermy in 5 mM pentoxifylline (81%) was significantly higher than in heparin alone (57%). In the second experiment, the interactions among Bulls A, B, C, and D; between treatments (pentoxifylline-with-heparin, caffeine-with-heparin and heparin alone), and between bulls and treatments were analyzed for the number of oocytes penetrated, monospermic oocytes, cleaved oocytes and blastocysts. Among bulls, there was a significant difference in the number of oocytes penetrated (P < 0.01), monospermic oocytes (P < 0.05), cleaved oocytes (P < 0.001), and blastocysts (P < 0.001). Between treatments, there was a significant difference in the number of oocytes penetrated (P < 0.001), monospermic oocytes (P < 0.01) and cleaved oocytes (P < 0.001). Interaction between bulls and treatments was observed for the number of oocytes penetrated (P < 0.05). Individually, for Bulls A, C and D, the numbers of oocytes penetrated and monospermic oocytes in pentoxifylline-with-heparin were significantly higher than in heparin alone. For Bull D, significantly higher results were obtained for the number of oocytes penetrated, monospermic oocytes, cleaved oocytes and blastocysts in pentoxifylline-with-heparin compared to caffeine-with-heparin and heparin alone (P < 0.05). These results suggest that treating sperm with 5 mM pentoxifylline in combination with heparin is effective for bovine in vitro fertilization and it that this treatment is effective even for bulls that produce low fertilization and blastocysts after sperm treatment with caffeine-with-heparin or heparin alone.     

Fertilization rates in superovulated and spontaneously ovulating mares

Embryo recovery per ovulation has been shown to be lower in superovulated mares than in untreated controls. The objectives of this study were to 1) determine whether follicles stimulated with superovulatory treatment ovulate or luteinize without ovulation, 2) determine fertilization rates of oocytes in oviducts of superovulated and control mares, and 3) evaluate viability of early stage embryos from superovulated and control mares when cultured in equine oviductal cell-conditioned medium. Cyclic mares were randomly assigned to 1 of 2 groups (n=14 per group) on the day of ovulation (Day 0): Group 1 received 40 mg of equine pituitary extract (EPE; i.m.) daily beginning on Day 5 after ovulation; mares assigned to Group 2 served as untreated controls. All mares were given 10 mg PGF(2alpha) on Day 5 and Day 6, and 3,300 IU of human chorionic gonadotropin (hCG) were administered intravenously once mares developed 2 follicles >/=35 mm in diameter (Group 1) or 1 follicle >/=35 mm in diameter (Group 2). Mares in estrus were inseminated daily with 1 x 10(9) progressively motile spermatozoa once a >/=35 mm follicle was obtained. Two days after the last ovulation the ovaries and oviducts were removed. Ovaries were examined for ovulatory tracts to confirm ovulation, while the oviducts were trimmed and flushed with Dulbeccos PBS + 10% FCS to recover fertilized oocytes. All fertilized oocytes (embryos) recovered were cultured in vitro for 5 d using TCM-199 conditioned with equine oviductal cells. Ninety-two percent of the CL's from EPE mares resulted from ovulations compared with 94% for mares in the control group (P>0.05). The percentages of ovulations resulting in embryos were 57.1 and 62.5% for EPE-treated and control mares, respectively (P>0.05). Eighty-eight (Group 1) and 91% (Group 2) of the freshly ovulated oocytes recovered were fertilized (P>0.05). After 5 d of culture, 46.4 and 40.0% of the embryos from EPE-treated and control mares developed to the morula or early blastocyst stage (P>0.05). In summary, the CL's formed in superovulated mares were from ovulations not luteinizations. Although embryo recovery was less than expected, fertilization rates and embryo development were similar (P>0.05) between superovulated and control mares.     

Modification of follicular dynamics by exogenous FSH and progesterone, and the induction of ovulation using hCG in postpartum beef cows

Follicular growth and ovulation in response to FSH, progesterone and hCG were evaluated in postpartum beef cows. In Experiment 1, on Day 21 post partum, cows received an injection of either saline (control; n = 6), FSH (200 mg; n = 6), or a PRID (n = 5) for 10 d. Both FSH and PRID prolonged maintenance of a dominant follicle (15.5 +/- 1.16 and 14.4 +/- 1.29 d, respectively, vs 8.4 +/- 1.22 d in control; P < 0.01), and increased the maximum diameter of the dominant follicle (14.0 +/- 0.91 and 16.4 +/- 1.01 mm, respectively, vs 10.9 +/- 0.95 mm in control; P < 0.05). The PRID-maintained dominant follicle ovulated in 60% of cows, followed by normal estrous cycles (vs 0% in control; P = 0.01), whereas the dominant follicle ovulated in 33% of FSH-treated cows (P = 0.08). The PRID regimen shortened the interval to first ovulation preceding a normal cycle and continued cyclicity (44 +/- 4.1 vs 60 +/- 4.4 d in control; P = 0.02). In Experiment 2, on Day 21 post partum, cows received either saline (control), saline + PRID, or FSH + PRID (n = 16/group). Sixty hours after PRID withdrawal, cows received either saline or hCG (1,500 IU, n = 8/treatment). The FSH + PRID regimen increased the number of large (> 10 mm in diameter) follicles (3.6 +/- 0.43 vs 1.9 +/- 0.39 in control; P = 0.005). Both PRID and FSH + PRID prolonged maintenance of the largest follicle (11.0 +/- 0.82 and 11.2 +/- 0.91 d, respectively, vs 8.7 +/- 0.81 d in control; P < 0.05). The PRID-maintained dominant follicle ovulated in 50% of cows, followed by normal estrous cycles. The FSH + PRID-maintained largest follicle had become atretic at PRID withdrawal and was anovulatory. The FSH + PRID + hCG regimen increased the incidence of ovulation preceding a cycle of normal duration and continued cyclicity (100 vs 50% in PRID; P = 0.03), and reduced the interval to first ovulation preceding a cycle of normal duration and continued cyclicity (38 +/- 6.5 vs 58 +/- 6.3 d in control; P = 0.04). The area under the progesterone curve during the induced cycle was reduced after (PRID +/- FSH) + hCG than after PRID +/- FSH (P = 0.002). These results indicate that PRID alone or with FSH/hCG has the potential to modify the dominant follicle and initiate cyclicity in postpartum beef cows.     

The impact of dose of FSH (Folltropin) containing LH (Lutropin) on follicular development, estrus and ovulation responses in prepubertal gilts

FSH is favored over chorionic gonadotropins for induction of estrus in various species, yet little data are available for its effects on follicle development and fertility for use in pigs. For Experiment 1, prepubertal gilts (n = 36) received saline, 100 mg FSH, or FSH with 0.5 mg LH. Treatments were divided into six injections given every 8 h on Days 0 and 1. Proportions of gilts developing medium follicles were increased for FSH and FSH-LH (P < 0.05) compared to saline, but follicles were not sustained and fewer hormone-treated gilts developed large follicles (P < 0.05). No gilts expressed estrus and few ovulated. Experiment 2 tested FSH preparations with greater LH content. Prepubertal gilts (n = 56) received saline, FSH-hCG (100 mg FSH with 200 IU hCG), FSH-LH5 (FSH with 5 mg LH), FSH-LH10 (FSH with 10 mg LH), or FSH-LH20 (FSH with 20 mg LH). FSH-LH was administered as previously described, while 100 IU of hCG was given at 0 h and 24 h. Hormone treated gilts showed increased (P < 0.05) medium and large follicle development, estrus (>70%), ovulation (100%), and ovulation rate (>30 CL) compared to saline. There was an increase (P < 0.05) in the proportion of hormone-treated gilts with follicular cysts at Day 5, but these did not persist to Day 22. These gilts also showed an increase in poorly formed CL (P < 0.05). FSH alone or with small amounts of LH can induce medium follicle growth but greater amounts of LH at the same time is needed to sustain medium follicles, stimulate development of large follicles and induce estrus and ovulation in prepubertal gilts.     

Ovarian response in ewes following horse anterior pituitary extract and progestagen treatment

Sixty adult ewes were treated intravaginally for 12 days with one of three progestagen treatments: (1) 500 mg progesterone pessary, (2) 30 mg flurogestone acetate pessary, (3) 12% (w/w) progesterone in a Controlled Internal Drug Release (CIDR) device. On days 10, 11 and 12 of progestagen treatment ewes received either 60, 45 and 30 mg; 45, 45 and 45 mg or 30, 45 and 60 mg of horse anterior pituitary extract (HAP), respectively. Progestagen treatment was terminated on day 12 at the time of the last HAP treatment. Ewes were bred by artificial insemination at 8- and 16-h intervals during oestrus, which was checked by using vasectomized rams. Ovarian response and fertility were determined at laparotomy 8 days after progestagen withdrawal. Progestagen treatment significantly increased (P<0.05) ovulation rate, with a mean of 9.1, 12.0 and 6.6 ovulations from treatments (1), (2) and (3), respectively. The method of HAP administration had no significant effect on ovulation rate, with a mean of 9.8, 10.0 and 7.8 after either decreasing, constant or increasing levels during treatment. There was no difference in the fertilization rate following flurogestone acetate (45.7%) or CIDR (47.0%), but a lower rate resulted after the progesterone pessary (30.0%) (P<0.025). More eggs were recovered following local than following general anaesthesia (P<0.05). Results indicate that cervical insemination does not give a satisfactory yield of fertilized eggs following hormonal inductions of superovulation.     

Efficacy of exogenous gonadotrophic hormones to induce estrus in anestrous gilts

The objective of this study was to examine the response of anestrous gilts to injections of pregnant mare's serum gonadotrophin (PMSG) alone or in combination with human chorionic gonadotrophin (hCG). One hundred and eighty gilts which had failed to exhibit estrus by about 33 wk of age were given one of the following treatments: no injection, 500 IU PMSG, 1000 IU PMSG or 400 IU PMSG + 200 IU hCG. A greater number of gilts injected with 1000 IU PMSG exhibited estrus within nine days of treatment than control gilts (21/37 vs 13/41, X(2) = 5.0, P<0.05). In addition, gilts injected with 1000 IU PMSG exhibited oestrus significantly earlier than gilts receiving the other treatments. In comparisons of the proportion of gilts ovulating within 9 d of treatment and the treatment-to-ovulation interval, there were no significant differences between the three exogenous hormone treatments. There was also no significant effect of treatment on farrowing rate or subsequent litter size. The results of our study indicate that treatment of anestrous gilts with 1000 IU PMSG effectively induces ovulation and fertile estrus. Inadequate expression of estrus often accompanied the ovulation induced by the lower dosages of PMSG used with and without hCG in this experiment.     

Effects of a GnRH agonist on oocyte number and maturation in mice superovulated with eCG and hCG

The objective was to investigate the effects of a gonadotropin-releasing hormone agonist (GnRH) on ovulation rate and the number and maturation of oocytes in mice superovulated with equine chorionic gonadotropin (eCG) and human chorionic gonadotropin (hCG). Thirty 3-month-old BALB/C female mice (weight: 25-30 g) were assigned to three experimental groups: control, superovulated, and superovulated with GnRH pretreatment (n=10 per group). Control mice received an i.p. injection of 0.1 ml physiological saline solution. Superovulation was induced with 5 IU eCG (i.p.) and 5 IU hCG 48 h later. Mice in the superovulated with GnRH pretreatment group were given GnRH (20 mg/kg Fertirelin, i.m.), 24 h before superovulation. Thirteen hours after hCG administration, mice were sacrificed by cervical dislocation and blood samples were collected to determine serum progesterone concentration (by radioimmunoassay). Ovaries and oviducts were also harvested to enumerate corpora lutea and cumulus-enclosed oocytes. Progesterone concentrations were not significantly different among groups. The oocyte number and the maturation, ovulation rate, and the number of corpora lutea were higher in GnRH-treated mice than both controls and superovulated mice. In conclusion, GnRH given 24 h before superovulation with eCG-hCG increased the number and maturation of oocytes and the rate of ovulation in mice.     

Pregnancies and live birth from in vitro fertilization of calf oocytes collected by laparoscopic follicular aspiration

Oocytes were recovered by laparoscopic aspiration from 3- to 8-week-old calves treated with follicle-stimulating hormone (FSH) followed by human chorionic gonadotropin (hCG) to induce follicular growth and oocyte maturation in vivo. Most of the recovered oocytes either had resumed meiotic maturation at the time of aspiration or were competent to undergo maturation during subsequent culture in vitro. Oocytes matured in vivo following FSH and hCG treatment underwent in vitro fertilization (70%) at rates not significantly different from those of control oocytes recovered from adult cow ovaries at abattoirs and matured in vitro (75%). Calf oocytes that were immature at aspiration exhibited lower fertilization rates after in vitro maturation (36%) but their rate of development to morulae and blastocysts did not differ from that of mature oocytes at aspiration. A total of 91% of the zygotes produced from calf oocytes developed to morula and 27% to blastocyst stages during 6 days of culture. The proportion developing to morulae was significantly higher (P<0.05) than that observed for zygotes resulting from in vitro maturation and fertilization of oocytes recovered from cow ovaries obtained at an abattoir and processed concomitantly (59% to morulae and 18% to blastocysts). Morulae or blastocysts developed from oocytes from 5 to 6-week-old calves, when transferred to synchronized recipient heifers, resulted in 2 confirmed pregnancies, one of which produced a single full-term live calf. The ability to produce embryos from oocytes recovered from newborn or prepubertal calves offers the potential for markedly reducing the generation interval in cattle, thereby substantially accelerating the rate of genetic gain that can be achieved through embryo transfer.     

不同激素和注射方式对家猫超排效果的比较

比较了PMSG hCG和FSH hCG两种方案以及PMSG的不同剂量和注射方式对家猫的超排效果的影响。用 1 0 0IU的PMSG超排家猫所得到的排卵点数及平均每只猫获得的卵数显著低于 2 0 0IU处理组或 30 0IU处理组 (P <0 0 5 ) ,但 2 0 0IU处理组与 30 0IU处理组之间的超排效果也无显著差异 (P >0 0 5 ) ;用皮下注射 2 0 0IU的PMSG或用肌肉注射 2 0 0IU的PMSG对超排效果无差异 (P >0 0 5 ) ;用 2 0 0IUPMSG 2 0 0IUhCG和 1 5mgFSH 2 0 0IUhCG两种方案对家猫超排 ,发现不论是每只猫的排卵点数、卵子获得数 ,还是卵子的第一极体排放率都没有显著差异 (P >0 0 5 )。实验说明 ,PMSG的注射方式不影响对家猫的超排效果 ,用 2 0 0IU的PMSG超排家猫是较适合的剂量 ,FSH和PMSG都可用于家猫的超排 ,但PMSG使用更为方便。     

Premature elevation of progesterone shortens duration of ovulation in PMSG/hCG-treated prepuberal gilts

A surge of LH during the follicular phase triggers multiple pathways, including progesterone and prostaglandin synthesis before culminating in ovulation. Progesterone has been shown to be involved in the ovulatory process in many species. In prepuberal gilts treated with PMSG/hCG the follicular progesterone level has been shown to increase sharply before ovulation. This study was conducted to investigate whether premature elevation of progesterone can accelerate the ovulatory process in Large White PMSG/hCG-treated prepuberal gilts. Fifty-four Large White gilts were treated with 1000 IU, i.m. PMSG to stimulate follicular growth, followed 72 h later by 500 IU, i.m. hCG to induce ovulation. Gilts in the treatment group (n = 27) were given progesterone intermuscularly at 24 and 36 h after hCG. Ovaries were exteriorized to observe ovulation points during laparotomy under general anesthesia at 38 to 50 h after hCG. Ovulation in both groups commenced by 40.05 h after hCG and was completed by 47.71 h in the control group and by 42.87 h after hCG in the treated group. Progesterone shortened (P < 0.01) ovulation time by 4.84 h and the time required (P < 0.01) for the median proportion of follicles to ovulate (40.7 vs 43.5 h after hCG). Progesterone also increased (P < 0.01) the plasma progesterone concentration without altering follicular progesterone concentration.     

Bovine blastocyst development from oocytes injected with freeze-dried spermatozoa

Pronuclear formation, and the chromosomal constitution and developmental capacity of bovine zygotes formed by intracytoplasmic sperm injection with freeze-dried (lyophilized) spermatozoa were evaluated. Frozen-thawed spermatozoa were selected, freeze-dried, and stored at 4 degrees C until use. After 22-24 h of in vitro maturation oocytes were denuded and injected singly with a lyophilized spermatozoon. Injected oocytes were activated by treatment with 10 microM ionomycin (5 min) alone and in combination with 1.9 mM 6-dimethylaminopurine (DMAP) for 4 h. Ionomycin plus DMAP activation treatment resulted in a significantly higher proportion of sperm-injected oocytes with two pronuclei than was found after activation with ionomycin alone (74% vs. 56%; P < 0.03). The rates of cleavage, morula, and blastocyst development of sperm-injected oocytes treated with ionomycin plus DMAP were higher than after activation with ionomycin alone (63.3%, 34.2%, and 29.6% vs. 44.7%, 18.7%, and 10.6%, respectively; P < 0.05). Seventy-three percent of blastocysts produced with lyophilized sperm were diploid. These results demonstrate that in vitro-matured bovine oocytes can be fertilized with freeze-dried sperm cells, and that resultant zygotes can develop into karyotypically normal blastocysts.     

The relationship of follicle atresia to follicle size, oocyte recovery rate on aspiration, and oocyte morphology in the mare

Oocytes were collected by aspiration of follicles from horse ovaries obtained at surgery or post-mortem. The oocytes were classified according to morphology of the ooplasm and cumulus. The size of the corresponding follicles was measured, and sections of the follicles were fixed and examined histologically to determine the stage of viability or atresia. In Part 1, 11 pairs of ovaries were examined and all follicles were sectioned; in Part 2, 9 pairs of ovaries were examined and only those follicles from which oocytes were recovered were sectioned. The number of follicles examined per pair of ovaries in Part 1 (average +/- SD) was 12.9 +/- 4.1. The proportion of follicles that were viable increased with increasing follicular size (P < 0.01); the percentage of viable follicles was 21, 42 and 83% for follicles < 10 mm, 10 to 19 mm, and >/= 20 mm in diameter, respectively. The overall oocyte recovery rate on aspiration of follicles was 46%. There was no significant difference in the oocyte recovery rate between viable and atretic follicles. A significantly higher proportion of oocytes recovered from viable follicles had granular ooplasm (64 vs 39%; (P < 0.05); whereas significantly more oocytes from atretic follicles had a misshapen or dense ooplasm (23 vs 6%; P < 0.05), or an expanded or pyknotic cumulus (24 vs 6%; P < 0.05). The most common cumulus morphology (63% of oocytes from viable follicles and 48% of oocytes from atretic follicles) was presence of only the corona radiata. Only 11% of oocytes from viable follicles and 9% of oocytes from atretic follicles had a complete cumulus present.