Measurement of early pregnancy factor activity for monitoring the viability of the equine embryo

The viability of embryos before flushing from donor mares (n = 5) and after transfer to recipient mares (n = 7) was monitored in mare serum by detecting early pregnancy factor (EPF) using the rosette inhibition test (RIT). The EPF activity was measured in donor mares before and after natural mating at natural estrus; after ovulation on Days 2, 5 and 8; and after embryo flushing (Day 8) on Days 8, 9, 10 and 13 after ovulation. The collected embryos were transferred immediately after flushing. The EPF activity in recipient mares were measured on the day of transfer and after embryo transfer on Days 1, 2, 3 and 5. Pregnancy was confirmed on Day 12 to 14 after embryo transfer. The mean EPF activity of donor mares was increased to the pregnant level (> an RI titer score of 10) on Day 2 after ovulation. Two days after flushing the embryos, the EPF activity of donor mares had decreased to the nonpregnant level. Among the 7 recipient mares, 3 mares were diagnosed pregnant on Day 12 after embryo transfer with ultrasound. The EPF activity of the pregnant recipient mares was increased above the minimum level observed in pregnant mares on Days 2 to 3 after transfer. However, among the nonpregnant recipient mares after embryo transfer, the EPF activity of 3 mares remained at the pregnant level only 2 to 3 d and then declined to the nonpregnant level. In one recipient mare, EPF activity did not reach the pregnant level throughout the sample collection. The results of this study indicated that equine EPF can be detected in serum of pregnant mares as early as Day 2 after ovulation. From our observation, we conclude that the measurement of EPF activity is useful for monitoring the in vivo viability of equine embryos and early detection of embryonic death.     

Comparison of pregnancy rates from transfer of fresh versus cooled, transported equine embryos

Donor mares of mixed, light-horse breeds, maintained at Colorado State University, provided 104 embryos for immediate transfer (fresh embryos). One hundred and thirty-six additional embryos were collected on various breeding farms in the United States and were shipped to Colorado State University via commercial airlines (cooled embryos). Embryos were harvested 7 d after ovulation, graded, and either transferred into a mare immediately (<1 h) or placed in Ham's F-10 medium plus 10% fetal calf serum in an atmosphere of 5% CO(2), 5% O(2), 90% N(2) and packaged in a passive cooling unit (Equitainer) for shipment to our laboratory. All embryos were measured and graded just prior to surgical transfer via flank incision into synchronized mares. Recipients had ovulated 1 or 2 d before (+1, +2), on the same day as (0), or 1, 2 or 3 d after (-1, -2, -3) the donor mare. Pregnancy of recipients was determined by ultrasonography on 12, 35, and 50 d after ovulation of the donor. Pregnancy rates at 12, 35, and 50 d were similar for fresh (74, 64, 61%) and cooled embryos (80, 67, 66%), respectively. Overall, embryo size affected (P<0.05) pregnancy rates at 12, 35 and 50 d. Embryos of Grade 1 (excellent) or 2 resulted in more pregnancies than those of Grade 3 or 4 (poor) embryos. Embryonic losses between 12 and 35 d or between 35 and 50 d were not altered (P>0.05) by treatment (fresh or cooled) nor by age of the donor mare (P>0.05), but embryonic losses between 12 and 35 d were greater (P<0.06) for embryos stored for >12 h (25%) versus those stored for <12 h (10%). The duration needed for shipment (<12 h or >12 h) of cooled embryos did not alter pregnancy rates at 12 d (P>0.05). Age of donor mare had no effect (P>0.05) upon pregnancy rates of cooled or fresh embryos transferred nor on embryo quality. In summary, equine embryos can be cooled to 5 degrees C and maintained in storage for up to 24 h without decreased fertility, compared with those of embryos transferred in <1 hour.     

Effect of embryo age and recipient asynchrony on pregnancy rates in a commercial equine embryo transfer program

In the present study, 809 uterine flushes and 454 embryo transfers performed in mares over a 4-yr interval were examined to evaluate the effects of: (1) the day of embryo collection on recovery rates; (2) the degree of synchrony between donor and recipient mares on pregnancy rates; (3) the recipient day post ovulation on pregnancy rates; and (4) the age of the embryo at recovery on pregnancy rates at 60 days. Uterine flushes were performed on Days 6, 7, 8, 9, and 10 (Day 0 = ovulation) and embryos were transferred to recipients with degrees of synchrony varying between +1 to −6 (recipient ovulated 1 day before through 6 days after the donor). Recipient mares ranged from 2 to 8 days post ovulation. Embryo recovery rates were similar for flushes performed on Day 7 (61%), Day 8 (66%), Day 9 (59%), and Day 10 (56%), but the embryo recovery rate was lower (P < 0.03) for flushes performed on Day 6 (42%) compared with all other days. Pregnancy rates for various degrees of synchrony were as follows: +1 (71%), 0 (77%), −1 (68%), −2 (63%), −3 (66%), −4 (76%), −5 (61%), and −6 (27%). The −6 day of degree of synchrony had the lowest (P < 0.05) pregnancy rate compared with all other days, but there was no significant difference among +1 to −5 days. There was a lower (P < 0.05) pregnancy rate for embryos transferred to recipient mares on Day 2 (33%) compared with mares on Day 3 (66%), Day 4 (66%), Day 5 (62%), Day 6 (55%), Day 7 (58%), and Day 8 (56%). Pregnancy rate was higher (P < 0.05) for Day 7 (76%) embryos compared with Day 6 (50%), Day 8 (64%), and Day 9 (44%) embryos; Day 9 embryos resulted in lower (P < 0.05) pregnancy rates than Days 7 or 8 embryos. In conclusion, this study demonstrated that: (1) embryo recovery rates between Days 7 and 10 were similar and acceptable (e.g., 63% 488/771); (2) the degree of synchrony between donor and recipient mares does not need to be as restricted as previously reported in horses. Acceptable pregnancy rates (e.g., 70%, 99/142) were obtained even when recipient mares ovulated 4 to 5 days after the donors; (3) similar pregnancy rates were obtained when recipient mares received embryos within a large range of days post ovulation (Days 3 to 8); and (4) Day 7 embryos produced higher pregnancy rates when compared with Days 8 and 9 embryos. In clinical terms, the application of these new findings will be beneficial to large equine embryo transfer operations in producing more pregnancies per season.     

Observations on in vitro development of bovine morulae in Ham's F-10 and Dulbecco's phosphate buffered saline supplemented with normal steer serum

This study was conducted to compare in vitro development of bovine morulae in Ham's F-10 and Dulbecco's phosphate buffered saline (D-PBS) media supplemented with 10% (v/v) normal steer serum. Fifty-three excellent and good embryos were obtained by superovulating 15 non-lactating Holstein cows. Embryos were placed randomly in culture with Ham's F-10 or D-PBS media and development was recorded at 12-h intervals for the duration of culture. All embryos reached early blastocyst, blastocyst and expanded blastocyst stage. Nineteen of 27 embryos (70.1%) cultured in Ham's F-10 developed to hatched blastocyst stage in contrast to three out of 26 in D-PBS (11.5%). The mean developmental scores at 24, 48, 72, 96 and 120 h of culture were significantly (P<0.001) higher for embryos cultured in Ham's F-10. Also, the mean times to reach early blastocyst (25.84 +/- 6.65 vs 46.67 +/- 9.99 h), blastocyst (44.57 +/- 11.45 vs 61.89 +/- 16.62 h) and expanded blastocyst stage (65.00 +/- 13.20 vs 73.41 +/- 15.80 h) were significantly (P<0.001) shorter for embryos cultured in Ham's F-10. No difference was observed in the mean time to reach hatching (90.00 +/- 10.85 vs 84.00 +/- 16.97 h) and hatched blastocyst stage (97.26 +/- 18.71 vs 96.00 +/- 0.00 h). The results obtained support the concept that Ham's F-10 and normal steer serum provide for optimal bovine embryo development and suggest that 10% normal steer serum could be used as a protein supplement with D-PBS for short term storage and culture of bovine embryos.     

Effect of endothelial cell growth supplement and fibroblastic growth factor on early mouse embryo development in vitro

This study was conducted to examine the effect of endothelial cell growth supplement (ECGS) and fibroblastic growth factor (FGF) on early mammalian embryo development in vitro. Two hundred mouse blastocysts were placed randomly in culture wells containing one of five treatments: 1) Ham's F-10, 2) Ham's F-10 + 10 mug ECGS, 3) Ham's F-10 + 10 ng ECGS, 4) Ham's F-10 + 100 ng FGF and 5) Ham's F-10 + 10 ng FGF. In all cases, media were supplemented with 10% (v/v) normal steer serum. Embryos were cultured at 37 C with an atmosphere of 5% O(2), 5% CO(2) and 90% N and development was recorded at 12 h intervals for the duration of culture. The percentage of embryos that developed to expanded blastocyst (94.8), hatching blastocyst (74.4) and hatched blastocyst (71.8) in Ham's F-10 media were not different from embryos cultured in all other treatments except Ham's F-10 + 10 mug ECGS. A decrease in the percentage of embryos reaching expanded blastocyst (44.7), hatching blastocyst (23.7) and hatched blastocyst (18.4) was observed in Ham's F-10 + 10 mug ECGS. Also, a significant (P<0.01) decrease in development scores at 24, 48 and 72 h was observed for embryos cultured in Ham's F-10 + 10 mug ECGS. No difference was observed in the mean time to reach different developmental stages among treatments. The data suggest that ECGS and FGF at the doses tested have no beneficial effect on early mouse embryo development in vitro and 10 mug of ECGS has inhibitory effect.     

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.     

Survival of equine embryos co-cultured with equine oviductal epithelium from the four- to eight-cell to the blastocyst stage after transfer to synchronous recipient mares

In this study we examined the ability of equine oviductal epithelial cells (OEC) to support the development of four- to eight-cell equine embryos in vitro and investigated the ability of co-cultured embryos to continue normal development after transfer to synchronous recipient mares. Equine embryos obtained at Day 2 after ovulation were cultured with or without OEC for 5 days. Those OEC co-cultured embryos that reached the blastocyst stage and embryos recovered from the uterus at Day 7 were surgically transferred to synchronous recipient mares. Co-culture with OEC improved (P < 0.01) development of four- to eight-cell embryos to blastocysts compared to medium alone (11/15 vs 0/6) during 5 days in vitro. Embryos co-cultured with OEC were smaller (P < 0.05) and more delayed in development than Day-7 uterine blastocysts. There was no difference in the Day-30 survival rate of co-cultured blastocysts (3/8) or Day-7 uterine blastocysts (5/8) after transfer to recipient mares. These results indicate that co-culture with OEC can support development of four- to eight-cell equine embryos in vitro and that co-cultured embryos can continue normal development after transfer to recipient mares.     

Culture of 5-day horse embryos in microdroplets for 10 to 20 days

Embryos were recovered from the uteri of mares 5 d after ovulation. Six embryos, all morulae, were placed singly in 200-ul droplets of Ham's F-12 with 10% fetal calf serum and cultured at 37 degrees C in a 5% CO(2) atmosphere. The embryos expanded to form blastocysts by the third day of culture. The blastocysts hatched from their zona pellucida, rather than the zona thinning and flaking off, as occurs in vivo. Hatching from the zona pellucida began on the third day of culture and was complete in five of six embryos by the sixth day. The embryonic capsule, normally present in equine embryos after Day 6, was not seen in the cultured embryos. The blastocysts continued to expand until 15 to 17 d of age (10 to 12 d in culture), reaching an average diameter (+/- SD) of 2052 +/- 290 um, after which time they either collapsed or contracted. These results demonstrate that equine embryos can be maintained in long-term culture in vitro, exhibiting continued growth and expansion in the absence of the embryonic capsule.     

Effects of varying the holding temperature and interval from collection to freezing on post-thaw development of bovine embryos in vitro

The objective of this study was to evaluate the in vitro development of frozen-thawed bovine embryos held at room temperature or refrigerated for 2, 6 or 12 h prior to freezing. After recovery, embryos were randomly assigned to be placed in holding media for 2 h (n=131), 6 h (n=136) or 12h (n=133) prior to freezing. Approximately one-half of the embryos were refrigerated (5 degrees C; n=203) while the remaining half were held at room temperature (22 degrees C; n = 197) until freezing. Embryos were frozen in 10% ethylene glycol and stored in liquid nitrogen. After thawing, embryos were cultured for 72 h in Ham's F-10 media supplemented with 4% fetal bovine serum. Embryos were evaluated for quality and stage of development prior to freezing and after culture. At the end of culture, it was determined if each embryo had developed beyond the stage recorded prior to freezing and if the embryo had hatched from the zona pellucida. The percentage of embryos that developed during culture was greater (P < 0.001) for Grade 1 (81%) than for either Grade 2 (65%) or Grade 3 (48%) embryos. Likewise, a greater proportion (P < 0.001) of Grade 1 embryos developed to hatched blastocysts (60%) than either Grade 2 (40%) or Grade 3 (24%) embryos. The holding temperature from collection to freezing did not influence embryo development, regardless of the interval from embryo collection to freezing. The proportion of embryos that developed to expanded blastocysts and hatched was greater (P < 0.005) for embryos held 2 h prior to freezing (64%) than for embryos held for 12 h (33%). Hatching rate of embryos held 6 h prior to freezing (54%) tended (P < 0.08) to be lower than the hatching percentage for embryos held for 2 h. Thus, post-thaw embryonic development was impaired the longer embryos were held prior to freezing and temperature during the interval from collection to freezing did not affect post-thaw development.     

Survival of equine embryos transferred to normal and subfertile mares

To test the hypothesis that an abnormal uterine environment was a cause of early embryonic loss in subfertile mares, morphologically normal embryos were transferred to normal mares (n = 20) and subfertile mares (n = 20), and embryo survival rates were compared. Embryos were recovered nonsurgically at Days 7 to 8 postovulation and transferred surgically to normal and subfertile mares that had ovulated on the same day or within 2 d after a donor. Survival of transferred embryos was monitored by ultrasonography of the recipient mare's uterus from Day 9 through Day 28 postovulation. There were no significant differences (P > 0.5) in the embryo survival rates at Day 12 (11 20 vs 9 20 ) or Day 28 (10 20 vs 8 20 ) for normal or subfertile mares, respectively. The uterine environment of subfertile mares was apparently adequate to support the development of transferred embryos from Days 7 or 8 through Day 28 postovulation.     

Motility and fertility of equine spermatozoa in a milk extender after 12 or 24 hours at 20 degrees C

The effects of extender and storage at 20 degrees C on equine spermatozoa were evaluated in two experiments using embryo recovery as the end point. In both experiments, inseminations were every other day, starting on Day 2 or 3 of estrus or after a 35-mm follicle was detected, with 250 x 10(6) progressively motile cells (based on initial evaluation). In Experiment 1, semen from two stallions was used to compare the motility and fertility of spermatozoa maintained in a) heated skim milk extender at 37 degrees C with insemination in <1 h; b) E-Z Mixin extender at 37 degrees C with insemination in <1 h; and c) E-Z Mixin extender at 37 degrees C with cooling to 20 degrees C and insemination after storage for 12 h at 20 degrees C. The percentage of motile spermatozoa was 34% after 12 h compared to 55% at 0 h (P < 0.05). However, the percentage of mares from which an embryo was recovered 6.5 d after ovulation was 62, 56, and 50% for Treatments A, B, and C (P > 0.05). In Experiment 2, semen from three stallions was used to compare the motility and fertility of spermatozoa in a) E-Z Mixin extender at 37 degrees C with insemination in <1 h or b) E-Z Mixin extender at 37 degrees C with cooling to 20 degrees C and insemination after storage for 24 h at 20 degrees C. The percentage of motile spermatozoa was 17% after 24 h compared to 54% at 0 h (P < 0.05). There was no difference between treatments (P > 0.05) in the percentage of mares from which an embryo was recovered 6.0 d after ovulation (68 vs 62%) or among stallions. Thus, stallion semen extended in E-Z Mixin was held at 20 degrees C for 24 h without a marked decline in fertility.     

Deep freezing of horse embryos

Fourteen horse embryos recovered non-surgically on Days 6-8 after ovulation (Day 0) were cooled slowly to - 35 degrees C (7 embryos) or - 40 degrees C (7 embryos) and stored in liquid nitrogen (- 196 degrees C) for 4-98 days. Surgical transfer of the thawed embryos to unmated recipient mares that had ovulated - 2 to + 1 days with respect to the embryo donors resulted initially in the establishment of 4 conceptuses. However, only one mare maintained her pregnancy to term.     

The current status of equine embryo transfer

The use of embryo transfer in the horse has increased steadily over the past two decades. However, several unique biological features as well as technical problems have limited its widespread use in the horse as compared with that in the cattle industry. Factors that affect embryo recovery include the day of recovery, number of ovulations, age of the donor and the quality of sire's semen. Generally, embryo recoveries are performed 7 or 8 d after ovulation unless the embryos are to be frozen, in which case recovery is performed 6 d after ovulation. Most embryos are recovered from single-ovulating mares. Because there is no commercially available hormonal preparation for inducing multiple ovulation in the horse, equine pituitary extract has been used to increase the number of ovulations in treated mares, but FSH of ovine or porcine origin is relatively ineffective in inducing multiple ovulation in the mare. Factors shown to affect pregnancy rates after embryo transfer include method of transfer, synchrony of the donor and recipient, embryo quality, and management of the recipient. One of the major improvements in equine embryo transfer over the last several years is the ability to store embryos at 5 degrees C and thus ship them to a centralized station for transfer into recipient mares. Embryos are collected by practitioners on the farm, cooled to 5 degrees C in a passive cooling unit and shipped to an embryo transfer station without a major decrease in fertility. However, progress in developing techniques for freezing equine embryos has been slow. Currently, only small, Day-6 equine embryos can be frozen with reasonable success. Additional studies are needed to refine the techniques for freezing embryos collected from mares 7 or 8 d after ovulation. Demand for the development of assisted reproductive techniques in the horse has increased dramatically. Collection of equine oocytes by transvaginal, ultrasound-guided puncture and the transfer of these oocytes into recipients is now being used to produce pregnancies from donors that had previously been unable to provide embryos. In vitro fertilization, however, has been essentially unsuccessful in the horse. One alternative to in vitro fertilization that has shown promise is intracytoplasmic sperm injection. However, culture conditions for in vitro-produced embryos appear to be inadequate. The continued demand for assisted reproductive technology will likely result in the further development of techniques that are suitable for use in the horse.     

Development retardation in cultured preimplantation rabbit embryos

Day 3 to Day 5 preimplantation rabbit embryos were cultured for 24 h in chemically defined media which are widely used in early embryo culture (BSM II and Ham's F-10) supplemented with BSA or homologous serum. For the next 24 h, the embryos were left in the same culture medium, placed in freshly made medium, or cultured in medium which was supplemented with uterine flushings. In addition, 24-h cultured embryos were transferred into uteri of synchronous recipients for 1 day. After culture or transfer, development was assessed by cell proliferation evaluated by incorporation of tritiated thymidine. In comparison to non-cultured controls, thymidine incorporation demonstrated a considerably impaired cell proliferation after culture in defined media irrespective of medium, supplement, or replenishment with fresh medium. For Day 3 embryos, there was a developmental retardation amounting to about 1 day after 2 days in culture. Compared to Day 3 embryos, delay was clearly more pronounced in Day 4 and Day 5 blastocysts, i.e. in stages which had been retrieved from the uterus before culture. Supplementation with uterine flushings markedly promoted blastocyst cell proliferation (P less than 0.001). Incorporation data examined after transfer showed that impairment of cell proliferation caused by 1 day in culture had been compensated for to a large extent within 1 day in utero.     

Effects of cervical dilation and intrauterine infusions on the timing of oviductal transport of equine embryos

Equine embryos spend 5 to 6 d in the oviduct before entering the uterus as expanded blastocysts, and cannot be consistently collected nonsurgically until Day 7. Technologies such as cryopreservation and embryo splitting, which are most successful with embryos at the morula or early blastocyst stage, have not been used in mares because equine morulae and early blastocysts are located in the oviduct and cannot be recovered nonsurgically. These experiments test the hypothesis that transport of equine embryos through the oviduct can be hastened by cervical dilation or by acute, sterile endometritis induced by intrauterine oyster glycogen treatment. Cervical dilation with or without intrauterine infusion of 0.5 ml PBS on Day 4 did not appear to hasten the transport of embryos into the uterus since Day 5 uterine embryo recovery rates were not higher (P > 0.1) for mares with cervical dilation or cervical dilation plus PBS infusion vs mares receiving no treatments (0 of 5 and 0 of 5 vs 0 of 10, respectively). Intrauterine infusions of 40 ml of 1% oyster glycogen or 40 ml of PBS on Day 3 did not appear to hasten the transport of embryos into the uterus since Day 5 uterine embryo recovery rates were not higher (P > 0.1) for oyster glycogen- or PBS-treated vs untreated mares (2 of 12 and 3 of 11 vs 0 of 10, respectively). Cervical and uterine treatments on Day 3 or Day 4 and uterine lavages on Day 5 decreased (P < 0.05) Days 11 to Day 15 pregnancy rates compared with that of untreated mares. Day 11 to Day 15 pregnancy rates were 1 of 5 for mares with Day 4 cervical dilation and Day 5 uterine lavage, 1 of 5 for mares with Day 4 PBS infusion and Day 5 uterine lavage, 2 of 12 for mares with Day 3 oyster glycogen infusion and Day 5 uterine lavage, and 3 of 11 for mares with Day 3 PBS infusion and Day 5 uterine lavage vs 7 of 10 for mares that received no treatment or lavage. Cervical and uterine manipulations on Day 3 or 4 and uterine lavage on Day 5 appeared to decrease pregnancy rates by Days 11 to 15. The results of these experiments do not support the hypothesis that cervical dilation or uterine infusion hasten oviductal transport, since neither cervical manipulation nor transcervical infusion of oyster glycogen or PBS into the uterus significantly hastened the rate of embryo transport into the uterus.     

24-Hour cooled storage of equine embryos

Equine embryos were collected by transcervical uterine flush 7 d after ovulation. The flush solution was Dulbecco's phosphate buffered saline (PBS) with 1% newborn calf serum and penicillin-streptomycin. Each embryo was washed in modified Dulbecco's PBS with 1% newborn calf serum and 0.4% bovine serum albumin, and placed in 4-ml polystyrene test tube containing this same medium. Embryos were packaged in a commercial semen transport container which cooled (-0.3 degrees C/min) and maintained the embryo at 4 to 6 degrees C. After 24 h, 16 embryos were transcervically transferred into recipient mares. Of the 16 embryos, six were detected as vesicles by ultrasonography at 14 d of pregnancy, of which three were carried to term and resulted in live, normal foals. Sixteen control embryos were directly transferred without prior storage and resulted in five foals.     

In vitro-produced equine embryos: production of foals after transfer, assessment by differential staining and effect of medium calcium concentrations during culture

Viability of equine embryos produced by oocyte maturation, intracytoplasmic sperm injection and embryo culture to the blastocyst stage in vitro was evaluated after transfer of embryos to recipient mares. No pregnancies were produced after transfer of five blastocysts that had been cultured in G media. Transfer of 10 blastocysts cultured in modified DMEM/F-12 medium produced five pregnancies and three live foals; the two lost pregnancies developed only trophoblast (based on transrectal ultrasonography). To evaluate the status of the inner cell mass, equine blastocysts produced in vivo and in vitro were assessed after differential staining. A discrete inner cell mass could not be appreciated in blastocysts of either source after staining; this was attributed to the presence of a network of cells within the trophoblastic vesicle. Because increased medium calcium concentrations have been reported to decrease the incidence of trophoblast-only pregnancy after transfer of equine nuclear transfer embryos, we investigated the effect of increased calcium concentrations during oocyte maturation or during embryo culture. Increasing calcium concentration of culture medium from 2 to 5.6mM during in vitro oocyte maturation did not affect maturation rate (75 and 68%, respectively) or blastocyst development after fertilization (23 and 27%). However, increasing calcium concentration (from 1.3 to 4.9 mM) of medium used for embryo culture significantly decreased blastocyst development (27% versus 13%, respectively) and adversely affected embryo morphology. More work is needed to optimize culture systems for in vitro production of equine embryos.     

The effect of in vitro treatment of bovine embryos with IGF-1 on subsequent development in utero to Day 14 of gestation

Culture of bovine embryos with insulin-like growth factor-1 (IGF-1) can improve development to the blastocyst stage and embryo survival following transfer to heat-stressed, lactating dairy cows. Two experiments were conducted to determine whether IGF-1 could improve embryo survival and development at Day 14 after ovulation. In Experiment 1, non-lactating Holstein cows (n=58) were selected as recipients following synchronization for timed-embryo transfer. Embryos were produced in vitro and cultured with or without 100ng/mL IGF-1. At Day 7 after expected ovulation (Day 0), groups of 7-12 embryos were randomly transferred to each recipient. Embryos were recovered at Day 14. Embryo length and the presence or absence of an embryonic disc was recorded. Recovered embryos were cultured individually for 24h to determine interferon-tau (IFN-tau) secretion. There was no effect of IGF-1 on embryo recovery rate, embryo length or IFN-tau secretion. In Experiment 2, non-lactating (n=56) and lactating (n=35) Holstein cows were selected as recipients following synchronization for timed-embryo transfer. Embryos were produced as described in Experiment 1. At Day 7 after expected ovulation (Day 0), a single embryo was randomly transferred to each recipient. Embryos were recovered at Day 14. Embryo length and IFN-tau secretion were determined as in Experiment 1. Recovery rate at Day 14 tended (P=0.1) to be higher for recipients that received IGF-1 treated embryos compared to control embryos (43.2% versus 26.1%, respectively). There was no effect of IGF-1 on embryo length or IFN-tau secretion. In conclusion, results suggest that exposure to IGF-1 through Days 7-8 of development does not enhance capacity of embryos to prevent luteolysis. Results of the single embryo-transfer experiment suggested that IGF-1 treatment might affect embryo survival post-transfer as early as Day 14 after ovulation. Further experimentation is warranted to verify this finding.     

Infection of embryos following insemination of donor mares with equine arteritis virus infective semen

The objective was to evaluate the potential risks associated with embryo transfer from mares bred with equine arteritis virus (EAV) infective semen. Twenty-six mares were embryo donors, whereas 18 unvaccinated and EAV antibody seronegative mares were embryo recipients. Of the 26 donor mares, 15 were unvaccinated and seronegative for antibodies to EAV and 11 were vaccinated for the first time with a commercially available modified live virus vaccine against EVA before breeding and subsequent embryo transfer. All donor mares were bred with EAV-infective semen from a stallion persistently infected with the virus. Twenty-four embryos were recovered 7 d post-ovulation; all were subjected in sequential order to five washes in embryo flush medium, two trypsin treatments, and five additional washes in embryo flush medium (prior to transfer). Twelve and seven embryos (Grades 1 or 2) were transferred from the non-vaccinated and vaccinated donors, respectively, and pregnancy was established in 3 of 12 and 2 of 7. Perhaps trypsin reduced embryo viability and pregnancy rate. The uterine flush fluid of 11 mares (9 of 15 and 2 of 11 from non-vaccinated and vaccinated donor groups, respectively) was positive for EAV by VI (confirmed by real-time RT-PCR); the wash fluid from the embryos of nine of these mares was negative following 10 washes and two trypsin treatments. However, the embryo wash fluid from two mares was still positive for EAV after all 10 washes and the two trypsin treatments, and one embryo was positive for EAV. Two of 18 recipient mares had seroconverted to EAV 28 d after embryo transfer. Virus was not detected in any fetal tissues or fluids harvested after pregnancies were terminated (60 d). In conclusion, we inferred that the washing protocol of 10 washes and two trypsin treatments did not eliminate EAV from all embryos; due to limitations in experimental design, this requires confirmation. Furthermore, there may be a risk of EAV transmission associated with in vivo embryo transfer from a donor mare inseminated with EAV infective semen.     

Autotransfer of Day 4 embryos from oviduct to oviduct versus oviduct to uterus in the mare

Embryo autotransfer is defined as the collection of an embryo from and the transfer of this embryo into the same animal. The objectives of this study were to: 1) test the hypothesis that oviduct transport of the equine embryo from the oviduct into the uterus is not dependent on a unilateral embryo-corpus luteum interaction, 2) develop an embryo autotransfer technique for the mare and 3) compare the success rates of Day 4 embryos surgically autotransferred from the oviduct ipsilateral to ovulation to either the oviduct (n=10 mares) or the uterine horn (n=10 mares) contralateral to ovulation. Seventy percent (7 10 ) of the Day 4 embryos which were autotransferred to the oviduct contralateral to ovulation were transported through the oviduct and subsequently developed into embryonic vesicles detectable by ultrasonography between 10 and 21 days postovulation. This finding supported the hypothesis that oviductal embryo transport is not dependent upon the ipsilateral corpus luteum. Overall, sixty percent (12 20 ) of the autotransfers were successful. The success rate of uterine-transferred embryos was not significantly less (P>0.3) than that of oviductal-transferred embryos (5 10 vs 7 10 , respectively). Therefore, the Day 4 equine embryos were apparently mature enough to survive in the mare's uterus.