Fertilizability of Superovulated Eggs by Estrous Stage-independent PMSG/hCG Treatment in Adult Wistar-Imamichi Rats

We investigated the fertilization and developmental ability of superovulated eggs obtained from adult Wistar-Imamichi (WI) rats, by using pregnant mare serum gonadotropin (PMSG) and human chorionic gonadotropin (hCG) treatment. Female WI rats, 11–13 weeks of age, were divided into four groups by estrous stage (metestrus [ME], diestrus [DE], proestrus [PE], or estrus [E]). PMSG (150 IU/kg) and hCG (75 IU/kg) were injected at an interval of 48 or 55 h and the female rats were mated with mature male rats. The ovulated eggs were collected 20, 24, and 27 h after hCG injection. Regardless of the estrous stage at the time of PMSG injection, the treated rats mated and ovulated similar to the untreated spontaneously ovulated rats (S group). Although the proportion of fertilized eggs in the E- and PE-treated groups was less than the S group 20 h after hCG injection, the proportion was not different among all treated and S groups 24 h after hCG injection. The proportion of fertilized eggs using in vitro fertilization and the proportion of offspring obtained from 2-cell stage embryo transfer did not differ among the treated and S groups. In comparison with PMSG/hCG-treated immature rats, mating and ovulation rate of adult rats were significantly higher. The proportion of fertilized eggs obtained from mated rats did not differ between immature and adult rats. These results demonstrate that adult WI rats are good egg donors for reproductive biotechnological studies using unfertilized or fertilized eggs.     

Use of purified porcine follicle-stimulating hormone for ovarian stimulation of macaque monkeys

At present, in nonhuman primates, ovarian stimulation with heterologous gonadotropin preparations is the only reliable way to produce substantial numbers of competent ova for in vitro fertilization and embryo development studies. Preparations such as equine chorionic gonadotropin (eCG) and human menopausal gonadotropins (hMG or hFSH) have been used successfully, but eCG is crude and contains variable amounts of LH activity, while hMG/hFSH is very expensive and the supply is not stable. This study examined the use of a purified porcine FSH preparation (Folltropin V) for ovarian stimulation in rhesus monkeys. Twice-daily intramuscular injections of this preparation resulted in good follicular development, and was followed by a single intramuscular injection of hCG. Ova were collected laparoscopically 30 h post hCG, fertilized in vitro and then cultured until development ceased. Stimulation of 9 monkeys with Folltropin V yielded a mean of 20 ova per animal, of which 71% reached metaphase II and were inseminated; of these, 92% were fertilized in vitro and 48% developed into blastocysts in vitro. These results are similar to those reported by us and by others using eCG, hMG or an hFSH/hMG combination for ovarian stimulation of macaque monkeys. We conclude that Folltropin V is a suitable alternative preparation for ovarian stimulation in nonhuman primates and one that also has the advantages of being readily available and much less expensive than human gonadotropin preparations.     

Causes for decreased fertility in out-of-season mated ewes

The interval from onset of estrus to preovulatory luteinizing hormone (LH) release, conception and fertilization rates, and number of accessory spermatozoa per ovum at 48 hr postmating in untreated cyclic ewes and in progestogen-pregnant mare serum gonadotropin (PMSG) treated, anestrous ewes were compared in efforts to identify sources of lowered fertility for matings induced in anestrous ewes with exogenous hormones. Blood samples for LH determination were collected at 0, 2, 4, 6, 8, 10, 12, and 24 hr after the onset of estrus. Conception and fertilization failure rates were determined at 48 hr, 12 days, or parturition. The progestogen-PMSG treated ewes had a shorter interval from onset of estrus to preovulatory LH release, lower conception rates, and fewer accessory spermatozoa than cyclic ewes had. Conception failure, rather than embryonic mortality, was the major cause of reduced fertility for the out-of-season mated ewes and apparently resulted from insufficient viable spermatozoa in the oviducts to fertilize the ova.     

Comparison between PMSG- and FSH-induced superovulation for the generation of transgenic rats

Superovulation protocols using single injections of pregnant mare's serum gonadotropin (PMSG) or minipumps with follicle-stimulating hormone (FSH) were compared in immature Sprague-Dawley (SD) rats. We used the following criteria: total number of ova, rate of fertilization, in vitro embryo development, sensitivity of zygotes to the microinjection of foreign DNA into the pronucleus, and their in-vivo development after transplantation into the oviduct of a recipient. Female SD rats were stimulated with 15 IU PMSG or 10 mg FSH followed by the injection of human chorionic gonadotropin (hCG) at doses of 20 and 30 IU per female. After hCG administration, they were mated with males of the same strain and sacrificed on day 1 of pregnancy. The percentage of mated animals and the fertilization rate was similar in all groups. In rats given PMSG, the number of ovulated zygotes was hCG dose-dependent. In contrast, the dose of hCG did not influence the efficiency of superovulation in rats given FSH, which was equal to PMSG-treated rats at the optimal dose of hCG. The rates of in vitro blastocyst development (31.4 and 23.3%) and the resistance to microinjection into the pronucleus did also not differ significantly between zygotes of both studied groups. The proportion of offspring developing from microinjected zygotes after oviduct transfer (26.2 and 26.8%, respectively) and the rate of transgene integration per newborns (7.3 and 4.9%, respectively) was similar in both experimental groups. The results of this study demonstrate that superovulation of immature SD rats by PMSG is equally effective as FSH treatment and, thus, preferable for transgenic rat technology due to the lower costs and easier handling.     

Developmental competence of domestic cat follicular oocytes after fertilization in vitro

Empirical evaluation of variables affecting oocyte collection, in vitro fertilization, and embryo transfer resulted in establishing a successful procedure for the artificial production of offspring in the domestic cat. Female cats were treated with pregnant mare's serum gonadotropin (PMSG, 150 IU) followed 72 or 80 h later with 100 or 200 IU human chorionic gonadotropin (hCG). After laparoscopic collection, follicular oocytes were inseminated in vitro with ejaculated, processed spermatozoa, cultured (37 degrees C, 5% CO2), and then examined for evidence of fertilization. Two- to 4-cell stage embryos were transferred to the oviducts of oocyte donors. Oocyte donor cats and naturally mated controls also were subjected to sequential laparoscopic examinations and blood sampling to assess corpora lutea (CL) function. At 24-30 h of culture, fewer (p less than 0.001) degenerate oocytes were observed in cats receiving 100 IU hCG (8.2%) compared to those receiving 200 IU (20.6%), regardless of the PMSG-hCG interval. Overall fertilization (48.1%) and cleavage (45.2%, at 30 h post-insemination) rates were greatest following an 80-h PMSG-hCG interval combined with the 100 IU hCG dose. Five of the 6 cats receiving 6 to 18 embryos became pregnant and produced from 1 to 4 kittens/litter. Gonadotropin-treated females subjected to follicular aspiration produced morphologically normal CL and circulating progesterone patterns that were qualitatively similar (p greater than 0.05) to control cats. These data indicate that domestic cat follicular oocytes are capable of fertilization in vitro, but success is dependent on both the timing and dose of the hCG stimulus. Follicles subjected to aspiration appear capable of forming normal, functional CL and the birth of live young after embryo transfer unequivocally demonstrates, for the first time, the developmental competence of in vitro-fertilized carnivore oocytes.     

Ovulation, fertilization and pronucleus development in superovulated gilts

Estrus was synchronized in 45 gilts by ingestion of Zinc-Methallibur in the feed for 15 d. On Day 16 each gilts was treated with PMSG (1200 IU i.m.) followed in 72 h by hCG (500 IU i.m.). Gilts were inseminated 24 and 36 h after the onset of estrus followed by slaughter of groups (n = 4 or 5) at 40 h, 44 h, 48 h, 52 h, 56 h, 60 h and 64 h after hCG injection. Ovaries were evaluated macroscopically and oocytes/embryos were recovered by flushing the oviducts. The ovulation rate increased from 38% to 87% from 40 to 45 h and remained constant thereafter. At 40 h, 36% of oocytes were penetrated by a single spermatozoon. The rate of fertilization increased from 36% (40 h) to 59% (44 h), to 65% (48 h), to 73% (52 h), to 76% (56 h), 80% (60 h) and to 64% (64 h). At 40 h all fertilized ova contained a decondensed sperm head. After another 4 to 8 h early pronuclei were common, and 52 h after hCG treatment opposed pronuclei were predominant. The first cleavages were recorded 64 h after hCG injection.     

Development of in vivo-matured porcine oocytes following intracytoplasmic sperm injection

The objective of this study was to assess the development of porcine ova fertilized by intracytoplasmic sperm injection (ICSI). Allyl trenbolone (Regumate) was used to synchronize estrus in 13 postpuberal gilts. Gilts were superovulated with pregnant mare serum gonadotropin and hCG. Ova were aspirated from 5- to 8-mm follicles at 36 h after hCG. Cumulus cells were removed by blunt dissection and pipetting in Beltsville embryo culture medium (BECM) supplemented with 0.1% hyaluronidase. Sperm were washed and resuspended in BECM + 8% polyvinylpyrrolidone. Ova (n = 237) that exhibited a polar body were centrifuged at 15 000 x g for 6 min and injected with a single spermatozoon. One hundred fifty-four ova were cultured in NCSU-23 medium in a 5% CO(2) in air environment for 168 h. Ova were fixed in acetic acid/ethanol and stained with 1% orcein. Sixty-nine ICSI ova were cultured for 24 h and transferred (mean = 23) to three recipients. Eighty-one ova (69%) that survived ICSI cleaved within 48 h. Thirty-eight percent (31/81) of these ova became blastocysts (mean +/- SEM = 24.7 +/- 1.1 cells). One recipient gave birth to three pigs. These results demonstrate that porcine embryos derived from ICSI can develop into live pigs.     

Ultrastructure of in-vivo fertilization in superovulated cattle

Heifers were induced to superovulate by treatment with PMSG or FSH. Subsequently, oestrus was induced with prostaglandins and artificial insemination was performed. Ova were collected from the oviducts and their ultrastructural features were related to an estimated time of ovulation based on the time of the LH peak. With the insemination schedule used, the estimated time of ovulation defined the time at which fertilization was expected to occur. The ova were characterized as unfertilized, fertilized or possibly fertilized, and a sequence of nuclear and cytoplasmic changes associated with fertilization was revealed. Within 4 h after the estimated time of ovulation formation of the female and male pronucleus was initiated, and at 5-7 h swelling of the pronuclei occurred. At 19 h the pronuclei were closely apposed and synkaryosis was seen, and at 23 h the first two-cell stage was obtained. Within 2-3 h after the estimated time of ovulation cortical granule release, development of conspicuous Golgi complexes, and transformation of the smooth endoplasmic reticulum occurred. At approximately 7 h parallel arrays of annulate lamellae appeared. In one third of the unfertilized ova deviant oocyte maturation was noticed.     

Fertilization of rabbit ova and the role of ovum investments in the block to polyspermy

The rabbit ovum seldom becomes polyspermic despite the presence of supernumerary sperm with easy access to the ovum plasma membrane. The purpose of this study was to characterize the role of ovum investments in blocking polyspermy. Ova were inseminated with capacitated sperm in vitro and were fertilized. Early stages of development were normal. The incidence of polyspermy was determined by cytological examination of fixed ova. The incidence of polyspermy increased following removal of both the zona pellucida and corona radiata but not following removal of only the corona radiata. These results suggest that the failure of supernumerary sperm to penetrate the ovum plasma membrane is at least in part due to the presence of the zona pellucida.     

The use of synthetic gonadotropin releasing hormone treatment in the collection of sheep embryos

Gonadotropin releasing hormone (GnRH) treatment was examined as a means of improving the efficacy of embryo collection in the sheep following intrauterine insemination of frozen-thawed semen. In summary, treatment consistently improved fertilization rates and the number of fertilized ova collected per ewe was enhanced compared with untreated ewes. The yield of fertilized ova in ewes treated with follicle stimulating hormone (FSH) was maximized by administering GnRH 36 h after progestagen treatment; 24 h was the preferred time in ewes treated with pregnant mare serum gonadotropin (PMSG). There was a significant (P < 0.001) increase in the percentage of unfertilized ova in the former treatment when GnRH was given at 24 h. An examination of the time of insemination (0, 6, 12 and 18 h before the median time of ovulation) indicated that fertilization rates were highest when insemination occurred at 6 h in both GnRH-treated ewes and in untreated ewes. In GnRH-treated ewes, the recovery of ova was lowest when insemination occurred at the time of ovulation. The number of motile frozen-thawed spermatozoa required for fertilization following treatment was estimated to be approximately 20 x 10(6) per uterine horn. GnRH-treatment also improved the yield of fertilized ova in sheep that were naturally mated, although this yield was lower than that obtained with intrauterine insemination of frozen-thawed semen. It is concluded that fertilization failure, a major problem in sheep embryo collection, can be eliminated through judicious use of GnRH treatment and properly timed intrauterine insemination.     

Cytogenetic analysis of Day-4 embryos from PMSG/hCG-treated prepuberal gilts

Prepuberal gilts were treated with pregnant mare serum gonadotropin (PMSG) to study the effects of its dosage on ovulation rate, fertilization rate after artificial insemination, embryo viability, and rate of development and incidence of chromosome abnormalities in Day-4 embryos. Gilts received 750 IU, 1250 IU or 1500 IU of PMSG, followed 72 h later by 500 IU human chorionic gonadotropin (hCG). Gilts were inseminated 28 to 30 h following the hCG injection, and resulting embryos were collected on Day 4 post ovulation. Ovulation rate was higher in the 1250 IU group than in the 1500 IU group or the 750 IU group. The 1500 IU dose caused excessive stimulation of the ovary, resulting in the occurrence of large (>10mm diameter) unovulated follicles, reduced fertilization rate and low embryo recovery rate. There was no difference in the incidence of chromosome abnormalities among the three groups, although the 1500 IU group had higher embryonic mortality than the two lower dose groups. A dose of 1250 IU PMSG increased ovulation rate above that achieved by 750 IU and, therefore, increased the number of oocytes or embryos available for transfer or for other studies, without sacrificing embryo viability or increasing the incidence of chromosome abnormalities.     

In vitro fertilization of gonadotropin-stimulated leopard cat (Felis bengalensis) follicular oocytes

Based on techniques developed for the domestic cat, in vitro fertilization (IVF) studies were conducted in the taxonomically related leopard cat (Felis bengalensis). Adult females received pregnant mares' serum gonadotropin (PMSG) followed 80 or 84 h later by human chorionic gonadotropin (hCG) on two to four occasions over a 40-day to 27-month interval. Oocytes were collected laparoscopically from ovarian follicles 25-27 h after hCG and co-cultured with processed, homologous spermatozoa (37 degrees C, 5% CO2 in air, humidified atmosphere) for 30-36 h. There was no apparent ovarian refractoriness to repeated treatments with exogenous gonadotropins. Overall, the mean number of mature follicles present and the total number of oocytes and proportion of immature oocytes collected did not differ (P greater than 0.05) between the 80 h (4.9 +/- 0.9; 4.7 +/- 1.2; 14.9%, respectively) and 84 h (5.6 +/- 1.4; 5.4 +/- 1.7; 22.2%, respectively) gonadotropin interval groups. However, the proportion of mature leopard cat oocytes fertilized in vitro, as determined by embryonic cleavage, was increased (P less than 0.005) by extending the interval between PMSG and hCG from 80 (17.5%) to 84 (52.4%) h. These data 1) demonstrate that, compared to the domestic cat, the ovaries of the leopard cat are less responsive to a given PMSG/hCG treatment; 2) indicate that leopard cat follicular oocytes can be recovered readily by laparoscopy and are capable of becoming fertilized in vitro; and 3) suggest that IVF may be a viable approach for producing embryos and perhaps enhancing captive propagation of rare Felidae.     

In vitro fertilization in mice: Strain differences in response to superovulation protocols and effect of cumulus cell removal

Strain differences have proven to be crucial components in mouse in vitro fertilization (IVF) and superovulatory protocols. To maximize the yield of IVF-derived mouse eggs, a series of experiments was conducted using different injection timing intervals for administration of pregnant mare serum gonadotropin (PMSG) and hCG to induce follicular development and ovulation. Strains were chosen that were representative of those commonly used in genetic engineering experimentation. These strains included ICR outbred, C57BL/6 inbred, and B6SJLF1 hybrid (C57BL/6J x SJL/J F1) mice. Females were superovulated using 4 PMSG/hCG/IVF timing regimens (group), with sperm obtained from males of the same strain. Group designations were based on the following PMSG/hCG and hCG/oocyte collection intervals, respectively: Group 1, 55 and 21.5 h; Group 2, 60 and 14.5 h; Group 3, 55 and 14.5 h; Group 4, 48 and 14.5 h. After overnight culture of ova, fertilization rates (development to the 2-cell stage) were assessed. A logistic regression was performed using indicator variables for both strain and group. There was a significant strain influence on ova fertilization rate, based on the coefficients of mouse strain (ICR, beta = -1.1067, P = 8E-17 and C57BL/6, beta = -0.5172, P = 8E-06). Additionally, group affected the proportion of fertilized ova obtained (coefficient of Group 1, beta = -1.3152, P = 0.00 and Group 3, beta = 0.9531, P = 3E-12). From the coefficients for the interaction terms, the effect of groups varies across mouse strain. Therefore, the treatment that produces the highest fertilization rate is related to and contingent upon the strain of mouse. In the second study, the Group 3 protocol was used to evaluate fertilization differences between cumulus-intact and cumulus-free oocytes. Again, there was a significant strain influence on ova fertilization rate based on the coefficients of mouse strain (ICR, beta = -2.6639, P = 0.00; C57BL/6, beta = -2.5114, P = 0.00). However, there was no difference between Cumulus and No Cumulus groups (cumulus coefficient, beta = 0.1640, P = 0.59872), indicating that there was no affect of cumulus presence on fertilization rate. In summary, responses to standardized mouse IVF protocols vary significantly. The efficiency of IVF procedures can be optimized between and within specific mouse strains by the timing of superovulatory regimens. However, absence of cumulus cells during the IVF procedure does not adversely affect fertilization rate.     

Oocyte recovery, maturation and fertilization in vitro in the puma (Felis concolor)

Eight female pumas were treated i.m. with 1000 (N = 5) or 2000 (N = 3) i.u. PMSG followed 84 h later by 800 i.u. hCG. Eggs were recovered 24-26 h after hCG from ovarian follicles by using laparoscopy and transabdominal aspiration. Mature eggs were inseminated in vitro 4-6 h later whereas immature eggs were cultured for 24 h and then inseminated. Electroejaculates from 3 pumas were diluted with mKRB before insemination to evaluate the influence of sperm concentration on fertilization. Seven of 8 pumas responded with follicle development, and 140 eggs were recovered from 145 follicles (96.6%; 77 mature, 43 immature, 20 degenerate eggs; mean +/- s.e.m., 20.0 +/- 5.9 eggs/female). Overall fertilization rate was 43.5% (total eggs fertilized = 40) despite using inseminates containing 82-99% pleiomorphic spermatozoa. Of the 36 immature oocytes matured in vitro and inseminated, 12 were fertilized even though 50% of the inseminating spermatozoa contained an acrosomal defect. Fertilization rate of mature oocytes collected from follicles appeared unrelated (P greater than 0.05) to PMSG dose or number of spermatozoa/inseminate. This study demonstrates that a high proportion of follicular eggs can be recovered laparoscopically from adult pumas treated with PMSG and hCG. These gametes are capable of being fertilized in vitro (immediately or after maturation in vitro) even with low quality semen with a high incidence of sperm pleiomorphisms.     

In vitro fertilization of Siberian hamster oocytes

Siberian hamsters were superovulated and various media were tested in an effort to fertilize the recovered oocytes in vitro. The highest percentage of fertilized ova was achieved by using a modified Tyrode's medium, designated MT (Bavister, J. Reprod. Fertil., 18:544-545, '69), previously formulated to fertilize Syrian hamster ova in vitro. Spermatozoa incubated in this medium in a concentrated state overnight (14 hr) and then diluted (1 hr) fertilized 39% of the ova. Similar results (40%) were obtained with this medium by adding 20% human follicular fluid to fresh concentrated sperm for 30 min and then diluting the sperm for 2-3 hr prior to the addition of ova. Ova fertilized in vitro cleaved to the two-cell stage but failed to develop any further in culture. Two-cell embryos recovered from mated hamsters and cultured did not undergo additional cleavage. Four-cell embryos collected from mated females and cultured cleaved to the six- to eight-cell stage and stopped. Techniques and media used for fertilizing large numbers of Syrian and Chinese hamster ova in vitro will have to be modified to achieve the same degree of success in the Siberian hamster.     

Increased mortality during early embryonic development after in-vitro fertilization of rat oocytes

Immature female rats (60-65 g) were injected with 4 i.u. PMSG on Day -2, and allocated to 3 groups. For Groups I and II, unmated donors were killed 67-69 h after PMSG injection, shortly after the expected time of ovulation. Oocytes were recovered from the oviducts and transferred immediately into the oviduct of mated recipients (Group I) whose ipsilateral ovary had been exposed by peeling back the bursa, preventing endogenous oocytes from entering the oviduct, or were fertilized in vitro (Group II) and were transferred 16-18 h later. Rats in Group III were allowed to mate and half were killed 6 h after mating. The fertilized oocytes were then incubated for 10-12 h until transfer. The remaining rats in Group III were killed 16-18 h after mating and fertilized oocytes were collected and transferred immediately. Recipient rats were killed on Days 2, 5, 8 and 20. Zygotes resulting from in-vitro fertilization (Group II) were as able as those fertilized in donors (Group III) or recipients (Group I) to develop to the 2-cell stage, but underwent significantly greater embryonic loss beyond this stage of development. There was a slower rate of development of such oocytes to the blastocyst stage (Day 5) and a lower mean weight of implantation sites (Day 8). Transfer of zygotes after in-vitro fertilization resulted in a loss of 35% of the embryos at the time of implantation. These results suggest that in-vitro fertilization of rat oocytes leads to defects in the embryos causing a delay in early embryo development and a large number of implantation losses.     

A comparison of 1- and 2-cell ova production by F2 50% Meishan versus F1 White line gilts

The objective of this study was to compare recovery of pronuclear and 2-cell ova from F2 50% Meishan (MX) gilts versus F1 White line (L42) gilts. Sexually mature MX and L42 gilts were allocated across 2 treatments: Super (MX:n=9; L42:n=10) and Control (MX:n=6; L42:n=5) in a 2 x 2 factorial experiment. Allyl trenbolone (AT) was used to synchronize estrus in all gilts. Super gilts were given pregnant mare serum gonadotropin (PMSG: 1250 IU) at 24 h after AT withdrawal. Eighty-five hours after PMSG administration, all Super gilts received 750 IU of human chorionic gonadotropin (hCG). Super gilts which exhibited estrus within 24 h of hCG administration (MX-Super: n=6; L42-Super: n=5) and all Control gilts were bred naturally to Line 3 boars at 12 and 24 hours after the onset of estrus. Ova were recovered from Super gilts between 60 and 64 h after hCG and Control gilts at 48 h after the onset of estrus. All 1- and 2-cell ova were centrifuged at 15000 x g and observed using differential interference contrast microscopy. The mean ovulation rate was greater (P<0.05) for both MX-Super and L42-Super gilts in comparison to their respective Control groups. No differences were detected in the mean ovulation rate (P>0.38) or the mean number of 1- and 2-cell ova recovered (P>0.50) between MX-Super and L42-Super gilts. The proportion of 1- and 2-cell ova which exhibited visible pronuclei or nuclei was also similar among MX-SUPER and L42-SUPER gilts. This study demonstrates that MX gilts respond/perform comparably to L42 gilts with respect to estrus synchronization, superovulation, ova yield, and the ease of visibility of pronuclei or nuclei in the ova.     

Variations in rabbit oviduct microvascular architecture after ovulation induced by hCG

Rabbits were induced to ovulate by injection with hCG and vascular corrosion casts of the oviducts were examined by scanning electron microscopy after 24 and 48 h, when the ova would be expected to be at the ampullary-isthmic junction, and traversing the isthmus respectively. At 24 h there was dilatation of the isthmic subserosal venous plexus. It is suggested that venous distension in the isthmic subserosal venous plexus, due to raised venous pressure or to reduced venous wall tone, may occlude the isthmic lumen to ova, and thus explain the known pre-isthmic delay in ovum transport. By 48 h after hCG, distension was no longer evident, consistent with the possibility of ovum transport.     

The effect of ovarian steroidogenesis on ovulation and fertilizability in the in vitro perfused rabbit ovary

The effects of aminoglutethimide phosphate (AGP) on ovulation, ovum maturation, fertilizability, and steroid production were studied with the use of an isolated perfused rabbit ovary preparation. AGP (10(-3) or 10(-4) M) was added to the perfusate of one ovary. The contralateral control ovary was perfused in medium alone. Thirty minutes later human chorionic gonadotropin (hCG) (50 IU) was added to the perfusate of all ovaries. No difference was observed in time of ovulation or ovulatory efficiency between controls and AGP-treated ovaries. The degree of ovum maturity and degeneration was also comparable in the two groups. Progesterone and estradiol production were significantly reduced by AGP treatment. A second experiment examined fertilizability of ova ovulated in vitro after perfusion with 10(-3) M AGP. AGP significantly reduced the rate of normal fertilization as observed 12 h after insemination. The percentage of inseminated ova with evidence of degeneration was greater in ova from AGP-treated ovaries than in those from controls, however, this difference was not significant. The study indicates that AGP affects neither hCG-induced ovulation nor meiotic resumption; however, fertilizability of ova from ovaries treated with AGP is impaired. These data suggest that the intrafollicular steroid environment may participate in cytoplasmic maturation of ovulated ova.     

Superovulation in immature and mature Chinese hamsters

Mature female Chinese hamsters ovulate an average of 8.8 ± 1.0 (mean ± SD) eggs per female in each estrous cycle. Superovulation can be induced in both immature and mature females by subcutaneous or intraperitoneal injections of pregnant mare serum gonadotropin (PMSG) and either human chorionic gonadotropin (hCG) or pituitary luteinizing hormone (PLH). The best superovulation in immature females was induced by the administration of 15 IU of PMSG followed 72 hr later by injection of 15 IU of hCG (about 25 eggs per female) or 0.2 mg (200 IU) PLH (about 46 eggs per female). Ovulation started about 13–15 hr after administration of hCG (or PLH) and was completed during the next 5–6 hr. Superovulation in mature females could be induced by injecting PMSG any day of the estrous cycle, but the best superovulation (about 39 eggs per female) was induced by injecting 15 IU of PMSG on day 1 (day of ovulation) followed by the injection of 0.4 mg of PLH 72 hr later. When immature females treated with the best superovulatory protocol were mated on the evening of PLH injection, only 5% of the eggs were found fertilized 50 hr after PLH administration. On the other hand, about 60% of the eggs were found fertilized in mature females mated following treatment with the best superovulatory protocol. The majority (83–85%) of superovulated eggs obtained from both immature and mature females were normally fertilized in vitro.