Compact Morula Research Articles

Some Factors Affecting the Rate of Pregnancy after Embryo Transfer Derived from the Brazilian Jumper Horse Breed

This study aimed to evaluate the effects of certain embryo transfer parameters on the pregnancy rate after equine embryo transfer of the Brazilian Jumper Horse breed. The size, embryonic development stage, embryo quality, and synchronization of ovulation between the donor (n = 120) and recipient (n = 420) were evaluated in 396 embryos. Embryo recovery was performed on Day 6-9 after ovulation (Day 0 = day of ovulation). The recipient mares were chosen on the day of embryo recovery, and the transfers were performed that same day. The embryo size (diameter including envelopes; n = 396) ranged from 150 to 3000 μm; 67.1% measured between 400 and 1199 μm. The embryo size (400-1199 μm vs. ≤399 μm); stage of development (n = 396; blastocyst and expanded blastocyst versus compact morula and early blastocyst); quality (n = 396; grade 1 [excellent]), 2 [good], or 3 [poor]); and synchronization of ovulation between the donor and recipient (0, 1, 2, 3, and 4 days versus −1, 5, and 6 days, respectively) all affected pregnancy rate (P < .05). The pregnancy rate did not differ significantly among transfers performed on Days 0, 1, 2, 3, and 4. In conclusion, embryos measuring 400-1199 μm produced higher pregnancy rates in recipients than embryos measuring 150-399 μm, and blastocysts and expanded blastocysts produced pregnancy more efficiently than morulae and early blastocysts. The embryo quality also affected the pregnancy rate. Synchronization of donor and recipient ovulation to Days 0-4 improved the efficiency of embryo transplant.

130 EFFECT OF HYALURONIC ACID SUPPLEMENTATION ON OVINE EMBRYO DEVELOPMENT IN VITRO AND ON SURVIVAL AFTER VITRIFICATION

Studies have shown that supplementation with hyaluronic acid (HA), a glycosaminoglycan found in mammalian follicular, oviduct, and uterine fluids, improves in vitro development and post-thaw survival of bovine embryos. In this study, we examined the effect of HA supplementation on ovine embryo development and on survival after vitrification using the minimum volume cooling (MVC) cryotop method. Abattoir sourced ovine oocytes were in vitro matured and fertilized as per routine procedures (Walker et al. 1996 Biol. Reprod. 55, 703–708). In Experiment 1 (5 replicates), presumptive zygotes were randomly allocated to IVC medium supplemented with 0.8 mg mL–1 BSA, amino acids, and 0, 0.5, 1.0, 1.5 or 2.0 mg mL–1 HA. Cleavage rates were recorded and blastocyst development evaluated on Day 7 (Day 0 = day of IVF). In Experiment 2 (3 replicates), presumptive zygotes were placed in in vitro culture (IVC) medium with or without 1.0 mg mL–1 HA. Embryos were vitrified using the MVC cryotop method (Kelly et al. 2004 Reprod. Fert. Dev. 16, 172) on either Day 5 (morula–blastocyst stages), Day 6 (compact morula–hatching blastocyst stages), or Day 7 (blastocyst–hatching blastocyst stages). Vitrified embryos were thawed 7 days later and placed into IVC medium. Embryo survival (assessed by blastocoele re-expansion) and hatching rates were recorded on Day 8. Variables were assessed using procedure CATMOD in SAS (SAS Institute Inc., Cary, NC, USA). In Experiment 1, the addition of HA did not affect cleavage or blastocyst formation rates but hatching rates were significantly (P &lt; 0.05) improved at concentrations of 0.5 to 1.5 mg mL–1 (Table 1). In Experiment 2, HA supplementation (1.0 mg mL–1) compared with control medium did not affect cleavage (96.8 and 97.1%, respectively) or blastocyst formation rates (68.6 and 70.2%, respectively). HA significantly (P &lt; 0.05) improved survival after thawing of embryos vitrified on Day 5 (100 v. 85.6%, n = 85 and 90). However no effect was observed when embryos were vitrified on either Day 6 (97.8 v. 97.8%, n = 91 and 92) or Day 7 (96.7 v. 97.9%, n = 92 and 94). Within day, HA supplementation did not affect hatching rate compared with control medium (Day 5, 54.1 v. 53.2%; Day 6, 62.9 v. 65.6%; Day 7, 71.9 v. 62.0%, respectively). These results demonstrate that HA supplementation of IVC medium significantly improves hatching rate of ovine embryos and we speculate that this improvement may correlate with comparable improvements in pregnancy rates after transfer. Hyaluronic acid binds to CD44, a glycoprotein expressed on the surface of preimplantation ovine embryos and shown to play a role on embryo development (Luz et al. 2012 Genet. Mol. Res. 11, 799–809). Hyaluronic acid plays a role in cell migration and we suggest that, in the early blastocyst, it affords an advantage to the trophectoderm cells. Table 1.Effect of hyaluronic acid (HA) supplementation in IVC medium on cleavage, blastocyst, and hatching rates

144 EFFECTS OF CO-CULTURE WITH FIBROBLASTS AND OVIDUCT CELLS ON IN VITRO PRODUCTION OF PORCINE EMBRYOS

Cell co-culture during in vitro maturation or embryo culture has been reported as a method to improve the efficiency of maturation or embryo development (Kidson et al. 2003 Theriogenology 59, 1889; Romar et al. 2005 Anim. Reprod. Sci. 85, 287). Here, we present the impact of different methods of co-culture with mouse embryonic fibroblasts or oviduct epithelial cells on in vitro embryo production in pigs. Cumulus–oocyte complexes (COC) were collected from follicles with diameter larger than 3 mm and used for in vitro embryo production based on the method of Kikuchi et al. 2002 (Biol. Reprod. 66, 1033) with minor modifications. There were 8 groups; group 1: maturation and embryo culture without cell co-culture (control group); group 2: maturation in the presence of fibroblasts; group 3: embryo culture in the presence of fibroblasts; group 4: both maturation and embryo culture in the presence of fibroblasts; group 5: maturation in the presence of oviduct cells; group 6: embryo culture in the presence of oviduct cells; group 7: both maturation and embryo culture in the presence of oviduct cells; group 8: both maturation and embryo culture in the presence of both fibroblast and oviduct cells. In vitro maturation (IVM) was carried out at 39oC under 5% CO2 in air for 44 h using NCSU-37 as basic medium. Matured oocytes were inseminated using epididymal frozen semen in IVF medium modified Pig-FM supplemented with 2 mM caffeine and 5 mg mL–1 bovine serum albumin (Kikuchi et al. 2002). The percentage of cleaved embryos and percentage of cleaved embryos which developed to the compact morula and early blastocyst stage were recorded. Results were analysed by one-way ANOVA followed by Dunnett’s test. To investigate the effects of co-culture with mouse embryonic fibroblasts and oviduct epithelial cells on oocyte maturation, some COCs cultured in groups 1, 2, 5, and 8 were fixed to assess their nuclear maturation to the metaphase II stage. The rate of matured oocytes in the groups 2, 5, and 8 was 76.85 ± 3.39% (n = 102), 79.11 ± 3.75% (n = 64), and 81.84 ± 3.93% (n = 66), respectively; these rates were increased significantly compared to the group 1 (55.87 ± 1.88%, n = 94; P &lt; 0.05). The effect of co-culture on the fertilization and embryo development is shown in Table 1. Our results indicate that co-culture increases the rates of embryonic cleavage in all groups by comparison with the control group. However, a significant increase in the rate of morula-blastocyst was only observed when embryos were co-cultured with fibroblasts or when both maturation and culture were performed in co-culture with either fibroblasts or oviduct cells (groups 3, 4, 7, and 8). The most important increase in morula-blastocyst rate was recorded for the group of embryos co-cultured with fibroblasts (group 3). In conclusion, the co-culture with fibroblast or oviduct cells during maturation can improve oocyte maturation and cleavage rate, while co-culturing the embryos with fibroblasts seems sufficient to improve both the cleavage and the morula-blastocyst rates. Table 1.Effect of co-culture on the fertilization and embryo development in pig Supported by a grant from the NAFOSTED VN.

318 EFFECT OF BREED AND FOLLICULAR STATUS ON RESPONSE TO SUPEROVULATION IN SOUTH AFRICAN GOATS

This study evaluated the effect of breed and follicular status on quantity and quality of embryos recovered following superovulation in South African goats. Mature, nonlactating Boer (n = 10) and unimproved indigenous (n = 10) goats were used in this trial. Oestrous cycles of does were synchronised with controlled internal drug release (CIDR®; Pfizer Animal Health, New York, NY, USA) dispensers inserted for 9 days and injected with prostaglandin at CIDR insertion. All does were superovulated with pFSH, administered in 7 dosages, at 12 h intervals, starting from 48 h before CIDR removal. Ultrasonographic scans were performed at initiation of the superovulation treatment. Does were cervically inseminated with fresh undiluted semen at 36 and 48 h following CIDR withdrawal. Embryos were surgically collected at Day 6 following AI. The total number of recovered structures (unfertilised ova and embryos) was evaluated microscopically for the stage of development and quality, using morphological criteria. The structures were classified as unfertilised ova (if there was no cleavage), degenerate embryos (embryos at 8-cell stage and earlier stage), or as transferable grade 1, 2, and 3 embryos (morphologically intact compacted morulae, early blastocysts, and expanded blastocysts). All data were analysed using the ANOVA procedures of SAS (SAS Institute Inc., Cary, NC, USA). The time from CIDR removal to onset of oestrus did not differ significantly between breeds. Breed had no effect on the total number of corpora lutea, structures (unfertilised ova and embryos), unfertilised ova, embryos, degenerated embryos, and transferable embryos. The total number of follicles at the onset of pFSH treatment was positively correlated with the number of structures (unfertilised ova plus embryos) recovered. Similarly, the total number of embryos recovered was positively correlated with the number of follicles 2 to 3 mm and 4 to 5 mm, and the total number of follicles. The number of follicles 4 to 5 mm and the total number of follicles at the onset of pFSH treatment were positively correlated with total number of the transferrable embryos at the beginning of a superovulation treatment. The total number of transferable embryos was negatively correlated with the presence of follicles with a diameter &gt;6 mm at the beginning of the superovulation treatment. In conclusion, breed had no effect on response to superovulation. The total number of follicles and follicle diameters 2 to 3 mm and 4 to 5 mm were positively correlated with embryo yield. The presence of follicles &gt;6 mm at the beginning of superovulation negatively affected the quality of embryos. The results of this study indicate that breed has no effect on response to superovulation. However, the number and size of follicles at the beginning of a superovulation treatment affect both embryo yield and quality.

Metabolism of energy substrates of in vitro and in vivo derived embryos from ewes synchronized and super ovulated with norgestomet and porcine follicle stimulating hormone.

The synchronization and ovulatory responses of Sangsari cross bred ewes and metabolism of energy substrates in 8-cell stage embryos to hatched blastocysts stage produced in vitro or in vivo were investigated. Ewes were assigned randomly to receive 37.5 IU of porcine follicle stimulating hormone (FSH-P) daily for the 3 days preceding implant removal (Day 0). Synchronization of estrus was carried out using a 1.5 mg norgestomet (Crestar) ear implant for 12 days. Ewes in estrus were mated two to three times with rams of proven fertility. At the time of first mating each ewe was administered 1000 IU of human chorionic gonadotrophin (hCG) to induce ovulation. Surgical embryo recovery was performed on Days 4 and 6 after onset of estrus (Day 0) and recovered embryos were subjected to comparative metabolism studies with in vitro derived embryos at the same stage of development. The number of corpora lutea (CL), unovulated follicles and overall ovarian activity were recorded for each ewe during the breeding and non-breeding seasons. While the pattern of oxidation was similar among in vitro and in vivo derived embryos, a low pyruvate to lactate ratio was the preferred substrate of embryos derived in vitro. A high level of production of CO2 and lactate resulted from a stress response to the suboptimal culture environment. The first marked increase in the metabolism of glucose by ovine embryos was detected in compact morula stage, but there was no significant increase in the oxidation of glucose after the morula stage. Two different concentrations of glucose were compared, but this did not affect metabolism. However, the rate of incorporation and metabolism of glucose tended to be higher at the 0.56 mmol/L glucose dosage.

Analysis of factors contributing to the efficiency of the in vitro production of transgenic goat embryos (Capra hircus) by handmade cloning (HMC)

Cloning by Somatic Cell Nuclear Transfer (SCNT) still is challenging and inefficient. Recently, the handmade cloning (HMC) procedures have been successfully applied to livestock species. The aim of this study was to compare the effect of distinct oocyte sources (in vivo vs. post-mortem) and the final cytoplasmic embryo volume (∼85% or 2×50%) on fusion rates and on the developmental potential of Day-1 or Day-7 cloned transgenic goat embryos produced by HMC procedures. Cloned embryos were reconstructed by HMC using skin fibroblast donor cells established from a transgenic goat. Oocytes were obtained in vivo by laparoscopic oocyte recovery (LOR) from hormonally stimulated females or post-mortem from slaughterhouse ovaries from nonstimulated goats, resulting in no differences in the number of aspirated follicles, cumulus-oocyte complexes (COCs), and viable COCs per goat. However, the COC recovery rate was higher for slaughterhouse ovaries (86.0%) than for LOR (73.0%). Also, cytoplasmic volume (∼85% vs. 2×50%) had no effect on fusion rates after embryo reconstruction. Using slaughterhouse ovaries for cloning, a total of 18.0% (27/150) and 12.7% (19/150) of the in vitro-cultured embryos developed to the compact morula and blastocyst stages on Day 7. However, no recipients became pregnant on Day 30 following the transfer of Day-1 or Day-7 embryos. In conclusion, the use of slaughterhouse ovaries was as valuable to supply oocytes for the production of cloned goat embryos by HMC as the in vivo approach. The HMC was proven a simple alternative for the production of cloned transgenic goat embryos.

Exogenous induction of ovarian activity and ovulation and transfer of fresh embryos of domestic cat (Felis catus)

The objective of the present study was the exogenous stimulation of ovarian activity and definition of embryo collection, and transfer protocols, in the domestic cat for potential application in non-domestic endangered species. Sixteen adult queens and two adult male reproducers kept in the experimental cat house at the Morphology sector at the Veterinary Department (DVT), UFV, were used in this study. All the queens received a single application of 150 IU Equine Chorionic Gonadotropin (eCG) in the post estrus to induce ovarian activity and 80 to 84 hours later, received a single application of 100 UI Human Chorionic Gonadotropin (hCG) to induce ovulation. After hCG application, only the donor queens were naturally mated. The receptor queens received extra stimulus for induction of ovulation through manipulation of an intravaginal swab. Five to six days after hCG application, the donor queens were subjected to a laparotomy for embryo collection that was performed by trans-horn uterine washing. On average, six embryos were surgically inovulated. They were classified as type I and III compact morula and blastocysts in four receptor queens. Three animals presented pregnancy confirmed by ultrasound at day 36 and two of these animals gave birth to litters of two and four offsprings, respectively, at 66 and 63 days after induction of ovulation. Except for one still birth, all the offspring developed normally.

Dynamic profiles of Oct-4, Cdx-2 and acetylated H4K5 in in-vivo-derived rabbit embryos

This study documents the spatial and temporal distribution of Oct-4, Cdx-2 and acetylated H4K5 (H4K5ac) by immunocytochemistry staining using in-vivo-derived rabbit embryos at different stages: day-3 compact morulae, day-4 early blastocysts, day-4 expanded blastocysts, day-5 blastocysts, day-6 blastocysts and day-7 blastocysts. The Oct-4 signal was stronger in the inner cell mass (ICM)/epiblast cells than in the trophectoderm (TE) cells in all blastocyst stages except day-4 expanded blastocysts, where the signal was similarly weak in both the ICM and TE cells. The Cdx-2 signal was first detected in a small number of TE cells of day-4 early blastocysts, and became evident in the TE cells exclusively afterwards. A consistently strong H4K5ac signal was observed in the TE cells in all blastocyst stages examined. In particular, this signal was stronger in the TE than in the ICM cells in day-4 early blastocysts, day-4 expanded blastocysts and day-5 blastocysts. Double staining of H4K5ac with either Oct-4 or Cdx-2 on embryos at different blastocyst stages confirmed these findings. This work suggests that day 4 is a critical timing for lineage formation in rabbit embryos. A combination of Oct-4, Cdx-2 and H4K5ac can be used as biomarkers to identify different lineage cells in rabbit blastocysts.There are very limited studies on key transcription factors and epigenetic programming events in preimplantation-stage rabbit embryos. Previously we reported the spatial and temporal distribution of Oct-4 and acetylated H4K5 (H4K5ac) in-vitro-cultured rabbit embryos. In the present study, we report the similar distribution patterns of Oct-4 and H4K5ac using in-vivo-derived rabbit embryos at different stages: day-3 compact morulae, day-4 early blastocysts, day-4 expanded blastocysts, day-5 blastocysts, day-6 blastocysts and day-7 blastocysts. The Oct-4 signal was stronger in the inner cell mass (ICM)/epiblast cells than in the trophectoderm (TE) cells in all blastocyst stages except day-4 expanded blastocysts, where such signal was similarly weak in both the ICM and the TE cells. A consistent strong H4K5ac signal was observed in the TE cells in all stages examined. In particular, this signal was stronger in the TE than in the ICM cells in day-4 early blastocysts, day-4 expanded blastocysts and day-5 blastocysts. Importantly, we also report, as far as is known for the first time, the distribution pattern of Cdx-2 in rabbit embryos. The Cdx-2 signal was first detected in a small number of TE cells of day-4 early blastocysts. It became evident in the TE cells exclusively afterwards. The present study provides novel information on key transcription factors and epigenetic events during rabbit embryo development, and demonstrates that a combination of Oct-4, Cdx-2 and H4K5ac could be used as biomarkers to identify different lineage cells in rabbit blastocysts.

Co-localization of NANOG and OCT4 in human pre-implantation embryos and in human embryonic stem cells

NANOG and OCT4 are required for the maintenance of pluripotency in embryonic stem cells (ESCs). These proteins are also expressed in the inner cell mass (ICM) of the mouse pre-implantation embryo. Immunohistochemistry was used to show the presence of NANOG and OCT4 protein, and in situ hybridization was used to localize NANOG mRNA in human embryos from two-cell to blastocyst stage, and in human ESCs (hESCs). Nanog and Oct4 were co-localized in human embryos from morula and blastocyst stages. NANOG mRNA was detected in a group of cells in the morula, in cells of the ICM of blastocysts, and evenly in hESCs. All non-differentiated hESCs expressed NANOG and OCT4 protein. Pluripotent cells expressing NANOG and Oct4 were eccentrically localized, probably in polarized cells in a human compacted morula, which appears to be different from expression in murine embryos. In this study, we demonstrate that whole mount in situ hybridization is amenable to localization of mRNAs in human development, as in other species.

The cleavage stage embryo

A precise embryo quality evaluation is of paramount importance to sustain a successful in vitro fertilization (IVF) program. In most IVF clinics around the world, this quality assessment relies mainly on the morphological evaluation of cleavage stage embryos. Embryologists should be able to correlate the features observed at the optical microscope with the implantation potential of each particular embryo (Alikani et al., 2000; Ebner et al., 2003; Alpha Scientists in Reproductive Medicine and ESHRE Special Interest Group of Embryology, 2011). To achieve this goal, many scoring systems based on the morphological features of the dividing embryo have been developed (Giorgetti et al., 1995; Veeck, 1999; Fisch et al., 2001; de Placido et al., 2002; Baczkowski et al., 2004; reviewed by Rienzi et al., 2005; Torello et al., 2005; Holte et al., 2007). These embryo classification systems are based on the evaluation of the number of blastomeres, the degree of fragmentation, the symmetry of the blastomeres, the presence of multinucleation and the compaction status. It is very important that the features related to implantation potential are assessed accurately and similarly. The purpose of this chapter is to illustrate morphological aspects useful for the evaluation of the implantation potential of the embryos. Cleavage stage embryos range from the 2-cell stage to the compacted morula composed of 8–16 cells. The number of blastomeres is used as the main characteristic with the highest predictive value (Van Royen et al., 1999; Alikani et al., 2000; Fisch et al., 2001). Good quality embryos must exhibit appropriate kinetics and synchrony of division. In normal-developing embryos, cell division occurs every 18–20 h. Embryos dividing either too slow or too fast may have metabolic and/or chromosomal defects (Edwards et al., 1980; Giorgetti et al., 1995; Ziebe et al., 1997; Van Royen et al., 1999; Leese, 2002; Munne, 2006; Magli et al., 2007). Recent time-lapse studies indicate that not only the timing of cleavage, but also the time between each cell division is of importance. If all blastomeres divide in exact synchrony, only 2-, 4or 8-cell embryos would be observed. However, it is frequent to observe 3-, 5-, 6-, 7or 9-cell embryos, which is an indication of asynchronous development (Scott et al., 2007; Lemmen et al., 2008; Wong et al., 2010; Meseguer et al., 2011; reviewed by Kirkegaard et al., 2012). Time of scoring with respect to the insemination event has to be precisely established for a correct evaluation of the kinetics of cell division (Scott et al., 2007). However, it is also important to keep in mind that the environment in the specific laboratory, such as culture media and temperature, influences the kinetics of development. Very frequently, the mitosis of embryos leads to externalization of parts of the cell cytoplasm, resulting in the presence of anuclear fragments surrounded by a plasma membrane (Antczak and van Blerkom, 1999). The size and distribution of fragments inside the space surrounded by the zona pellucida (ZP) are variable (Alikani et al., 1999). The amount of fragments is widely used to predict the implantation potential of the embryos and fragmentation has been related to aneuploidy (Ebner et al., 2001; Ziebe et al., 2003; Munne, 2006). If fragmentation does not reach 10% of the total embryo volume it is agreed that it does not have an impact on the embryo’s developmental potential (Van Royen et al., 2001; Holte et al., 2007). Mitosis in blastomeres should produce two equally sized daughter cells. When the division is asymmetric, one of the blastomeres of the next generation will inherit less than half the amount of cytoplasm from the parent blastomere, leading to a defective lineage in the embryo. For example, 4and 8-cell embryos with equal cell sizes have been shown to have lower multinucleation and aneuploidy rates and increased implantation rates (Hardarson et al., 2001; Van Royen et al., 2001; Hnida et al., 2004; Scott et al., 2007). After two cleavages, the zygote becomes a 4-cell embryo. The four cells of the embryo are normally arranged in a tetrahedron in the spherical space provided by the ZP. However, in some cases, the blastomeres are located close to a single, spatial plane produced by an incorrect orientation of the division axes. This can be associated with altered embryo polarity (Edwards and Hansis, 2005). Each embryo blastomere should have a single nucleus. Multinucleation has been described to be associated with genetic disorders of the embryo (Kligman et al., 1996; Hardarson et al., 2001). It impairs cleavage rates and the implantation potential of human embryos

In vivo oocyte IGF-1 priming increases inner cell mass proliferation of in vitro-formed bovine blastocysts

Studies addressing the effects of supraphysiological levels of IGF-1 on oocyte developmental competence are relevant for unravelling conditions resulting in high bioavailability of IGF-1, such as the polycystic ovary syndrome (PCOS). This study investigated the effects of supraphysiological levels of IGF-1 during in vivo folliculogenesis on the morula-blastocyst transition in bovine embryos. Compacted morulae were non-surgically collected and frozen for subsequent mRNA expression analysis (IGF1R, IGBP3, TP53, AKT1, SLC2A1, SLC2A3, and SLC2A8), or underwent confocal microscopy analysis for protein localization (IGF1R and TP53), or were cultured in vitro for 24 h. In vitro-formed blastocysts were subjected to differential cell staining. The mRNA expression of SLC2A8 was higher in morulae collected from cows treated with IGF-1. Both IGF1R and TP53 protein were present in the plasma membrane and cytoplasm. IGF-1 treatment did not affect protein localization of both IGF1R and TP53. In vitro-formed blastocysts derived from morulae recovered from IGF-1-treated cows displayed a higher number of cells in the inner cell mass (ICM). Total cell number (TCN) of in vitro-formed blastocysts was not affected. A higher mean ICM/TCN proportion was observed in in vitro-formed blastocysts derived from morulae collected from cows treated with IGF-1. The percentage of in vitro-formed blastocysts displaying a low ICM/TCN proportion was decreased by IGF-1 treatment. In vitro-formed blastocysts with a high ICM/TCN proportion were only detected in IGF-1 treated cows. Results show that even a short in vivo exposure of oocytes to a supraphysiological IGF-1 microenvironment can increase ICM cell proliferation in vitro during the morula to blastocyst transition.

Viability of Vitrified Biopsied Bovine Embryos After In-Straw Dilution

The objective of the present study was to evaluate the viability of vitrified biopsied bovine embryos. Bovine embryos ranging from the compacted morula to blastocyst stage on day 7 (day 0=day of estrus) were collected from donor females, biopsied for sexing, and vitrified with ethylene glycol (EG) 25% (v/v), dimethylsulfoxide (DMSO) 25% (v/v) and 0.3% (w/v) bovine serum albumin dissolved in PBS using 0.25-ml straws. We assessed the concentrations of cryoprotectants in the straw after in-straw dilution, and the percentages (v/v) were 6.9–7.7% for EG and 2.8–3.3% for DMSO. The pregnancy rate of vitrified-warmed embryos in the in-straw dilution group (ISD group) was 57.9% when embryos were expelled from the straws after diluting the cryoprotectant in the straws, and that the survival of vitrified-warmed embryos were observed before transfer. In contrast, the pregnancy rate in the directly transfer group (DIR group) was 62.5% when embryos were transferred directly to recipients without expelling embryos from the straws. There were no differences among the pregnancy rates of the ISD group, the DIR group and the non-vitrified biopsied embryos (NV group) (56.3%). These results suggest that it was possible to warm the vitrified-biopsied bovine embryos on farms and to transfer them immediately to recipients, yielding a practical pregnancy rate.

A successful subsequent pregnancy after fetal reduction of one of the monozygotic twins: A case report

A 34-year-old woman attended our consultation clinic for primary infertility. The couple had complained of infertility for 10 years with no apparent reason. They were arranged with IVF-ET program. After 10 days of r-hFSH (Gonal-f,Serono, Switzerland, 225 U/d) injection, 8 oocytes were collected and 6 were fertilized by intracytoplasmic sperm injection (ICSI). On day 3 after oocyte retrieval, two embryos were transferred into the uterus that had eight even, regular, spherical blastomeres and no or very few fragments. The embryos were not assisted hatched before transfer. Two weeks later, she was confirmed pregnant for the serum hCG level reached 1172 mIU/ml. Ultrasound scan was performed at 7 gestational weeks, which showed two intrauterine gestational sacs, one sac with a fetal pole and fetal heart and the other sac with two separate fetal poles and fetal hearts (Fig. 1). She was diagnosed with a triplet pregnancy containing a monochorionic pair of twins. Fig. 1 Ultrasound appearance of triplet pregnancy containing a monochorionic pair of twins at 7 weeks gestation before fetal reduction. All the three fetal poles were detected heartbeat positive The couple were fully informed about the alternative fetal reduction protocol and insisted to reduce one the monozygotic twins. Selective fetal reduction was performed on day 47 of pregnancy. Under the guidance of vaginal ultrasound, alongside the transducer a 20-gauge needle (Wallace) was inserted into the uterine cavity and fetal thorax. Stirring the pole till the fetal heart beating vanished. The other fetus in the same sac, along with the solitary fetus was intact, and both of the fetal hearts remained (Fig. 2). The next day, examination revealed that both remaining feti were normal. Fig. 2 Ultrasound appearance of triplet pregnancy containing a monochorionic pair of twins after fetal reduction of one of the monochorionic twins. The “reduced” fetal pole’s heartbeat vanished (green arrow). The other fetus in the same ... Two live male infants were delivered by cesarean section at 33+5 week’s gestation, with birth weights of 1735 g and 1965 g respectively. Patients who undergo IVF-ET procedures are more likely to deliver multiple-birth infants than women who conceive naturally [7]. Multiple pregnancy has important medical and social implications that require consideration [2]. The anomalies that are more frequent among twins at birth include all of the most common major malformations, plus premature delivery and low birth weight, plus fetal, perinatal and infant mortality. Enzygotic twins are special twins, when the twinning event occurs after a single trophoblast has differentiated to form a membrane around the inner cells of the compacted morula, then cells within the single contiguous cell mass must establish two systems of body-symmetry axes inside the single trophoblast. Those twins will be monochorionic, among which, risk of congenital malformations is greater than dizygotic twins, such as conjoined malformation and twin transfusion syndrome. Common knowledge has it that these anomalies and complications that are associated in excess with twin births are due more or less exclusively to monozygotic twins as results of the disrupted embryogenesis (‘splitting’) required for the initiation of monozygotic twin development. Fetal reduction is a widely accepted procedure. It is useful in reducing the morbidity and mortality of multiple gestations [5]. Triplet pregnancy can be reduced to twins or monocyesis. Reduction of the monochorionic pair is frequently offered because gestational length is prolonged [1,3]. Skiadas et al. reported that pregnancies that underwent selective reduction delivered, on average, 52 days later than those not having selective reduction, and when triplet pregnancies containing a monochorionic pair were reduced to singletons, the main gestational age at delivery was 39.2 weeks compared with 34.3 weeks when the pregnancy was reduced to twins [6]. In summary, reduction of monochorionic twins contained in multiple pregnancies appears to be a safe option, since pregnancy complications are rare and obstetrical outcome is favorable in most of these cases [4]. Our successful reduction of one of the monozygotic twins provides a choice for reproductive medicine workers and patients. Long-term follow-up of infants must be conducted, but at present there is no great reason to be concerned.

EFFECT OF FETAL SERUM AND FOLLICULAR LIQUOR SUPPLEMENTATION ON THE IN VITRO PRODUCTION OF BOVINE EMBRYOS

To optimize In Vitro Fertilization (IVF) results in bovines by lowering costs, comparing the efficiency of Fetal Calf Serum (FCS) (high cost) with respect to bovine Follicular Fluid (bFF) (low cost) and by quantifying embryo production. Cumulus-Oocyte-Complexes (COC) obtained from a slaughter house, transported at 37°C in saline solution, were classified according to their quality in A, B, C and D. A and B oocytes were washed with modified Phosphate-Buffered Saline (m-PBS) and three groups were randomly formed (GC; G1; G2) cultured in drops of the respective media (10 COC/drop of 100 µL), covered with mineral oil and placed in an incubator (38,5°C, 5% CO2 y 95% humidity). Maturation was done in Tissue Culture Medium (TCM-199) and antibiotics, for 22h and developed in CR1aa medium and antibiotics. The Control Group (CG) was supplemented during both maturation and development stages with 5% FCS and 10% bFF; G1 with 5% FCS during maturation and development and G2 with 10% bFF during maturation and development. We obtained bFF from follicles larger than 15 mm, it was centrifuged (800G) inactivating it. At fertilization Bracket and Oliphant (BO) medium was used. Zygotes were evaluated every 48 h for 8 days since insemination, counting the Division Rate (DR) and the Embryo Development (ED) of compacted morulae. χ2 Test was applied. For RD, G2 differs from G1 and CG (p<0.05), CG and G1 do not differ significantly (p>0.05). During development no significant differences were found between groups (p>0.05). Results show that when using FCS, bFF or a combination of both, development results are similar. It is assumed that it is possible to substitute FCS with bFF.

Spatial and temporal distribution of Oct-4 and acetylated H4K5 in rabbit embryos

Rabbit is a unique species to study human embryology; however, there are limited reports on the key transcription factors and epigenetic events of rabbit embryos. This study examined the Oct-4 and acetylated H4K5 (H4K5ac) patterns in rabbit embryos using immunochemistry staining. The average intensity of the Oct-4 signal in the nuclei of the whole embryo spiked upon fertilization, then decreased until the 8-cell stage and increased afterwards until the compact morula (CM) stage. It decreased thereafter from the CM stage to the early blastocyst (EB) stage, with a minimum at the expanded blastocyst (EXPB) stage and came back to a level similar to that of the CM-stage embryos in the hatching blastocysts (HB). The Oct-4 signal was observed in both the inner cell mass (ICM) and the trophectoderm (TE) cells of blastocysts. The average H4K5ac signal intensity of the whole embryo increased upon fertilization, started to decrease at the 4-cell stage, reached a minimum at the 8-cell stage, increased again at the EXPB stage and peaked at the HB stage. While TE cells maintained similar levels of H4K5ac throughout the blastocyst stages, ICM cells of HB showed higher levels of H4K5ac than those of EB and EXPB.Understanding key genetic and epigenetic events during early embryo development will help to identify factors contributing to embryo losses and consequently improve embryo survival rates. As a preferred laboratory species for many human disease studies such as atherosclerosis, rabbit is also a pioneer species in the development of several embryo biotechnologies, such as IVF, transgenesis, animal cloning, embryo cryopreservation and embryonic stem cells. However, there are limited reports on key transcription factors and epigenetic events of rabbit embryos. In the present study, we documented the temporal and spatial distribution of Oct-4 protein and H4K5 acetylation during early embryo development using the immunostaining approach. We also compared the patterns of these two important biomarkers between the inner cell mass (ICM) and the trophectoderm (TE) cells in blastocyst-stage embryos. Our findings suggest that a combination of Oct-4, H4K5ac and possibly other biomarkers such as Cdx-2 is needed to accurately identify different lineages of cells in morula and blastocyst stage rabbit embryos. Importantly, we revealed a novel wave of Oct-4 intensity change in the ICM cells of rabbit blastocysts. The signal was high at the early blastocyst stage, reached a minimum at the expanded blastocyst stage and returned to a high level at the hatching blastocyst stage. We hypothesize that the signal may have reflected the regulation of Oct-4 through enhancer switching and therefore may be related to cell lineage formation in rabbit embryos. These findings enrich our understanding on key genetic and epigenetic programming events during early embryo development in rabbits.

Importance of Methionine Metabolism in Morula-to-blastocyst Transition in Bovine Preimplantation Embryos

The roles of methionine metabolism in bovine preimplantation embryo development were investigated by using ethionine, an antimetabolite of methionine. In vitro produced bovine embryos that had developed to the 5-cell stage or more at 72 h after the commencement of in vitro fertilization (IVF) were then cultured until day 8 (IVF = day 0) in medium supplemented with 0 (control), 1, 5 and 10 mM ethionine. Compared with the blastocyst development in the control (40.0%), ethionine at 10 mM almost completely blocked blastocyst development (1.1%, P<0.001), and this concentration was used in the following experiments. Methionine added at the same concentration (10 mM, a concentration control of ethionine) did not cause such an intense developmental inhibition. Development to the compacted morula stage on day 6 was not affected by 10 mM ethionine treatment. S-adenosylmethionine (SAM) added to the ethionine treatment partly restored the blastocyst development. Semiquantitative reverse transcription-polymerase chain reaction analysis of cell lineage-related transcription factors in day 6 compacted morulae showed that the expressions of NANOG and TEAD4 were increased by ethionine treatment relative to the control (P<0.01). Furthermore, immunofluorescence analysis of 5-methylcytosine revealed that DNA was hypomethylated in the ethionine-treated day 6 morulae compared with the control (P<0.001). These results demonstrate that the disruption of methionine metabolism causes impairment of the morula-to-blastocyst transition during bovine preimplantation development in part via SAM deficiency, indicating the indispensable roles of methionine during this period. The disruption of methionine metabolism may cause hypomethylation of DNA and consequently lead to the altered expression of developmentally important genes, which then results in the impairment of blastocyst development.

110 PREGNANCY RATES OF BOVINE EMBRYOS AND HEMI-EMBRYOS TRANSFERENCE

Embryo transfer (ET) in cattle speeds up genetic gains, but its use is limited by cost-benefit analysis. In addition other techniques can be developed, such as sexing and bipartition of embryos. An alternative to improve the economic viability of ET in cattle would be to bipartition embryos in order to increase the yield of the technique. The aim of this study was to investigate the operational viability of embryo bipartition technique in an ET program in cattle and to study aspects related to the viability and development of bovine hemi-embryos (HE) compared with intact ones. The embryos were collected by nonsurgical technique 7 days after the onset of oestrus. Viable structures (130) from 49 embryo collections from 25 Aberdeen and Simmental donor cows and heifers were used. Only embryos in compact morula, early blastocyst and blastocyst stage, with a morphological range from excellent to good grade (IETS Grade 1), were split. The embryos, split (78) or not (52), were transferred into the uterine horn ipsilateral to the corpus luteum of the recipients 7 days after oestrus. The treatment groups evaluated were T1 (intact embryo, n = 52), T2 (1 HE, n = 27) and T3 (2 HE, n = 51). Crossbred heifers were used as recipients and pregnancy diagnosis was done at 60 to 80 days of gestation. The embryos of T1, T2 and T3 were classified morphologically as excellent or good and by developmental stage as morula, early blastocyst, or blastocyst, distributed as follows: T1: 30, 22 and 16, 17 and 19; T2: 15, 12 and 7, 9 and 11; and T3: 29, 22 and 15, 15 and 21, respectively. The birth rate per original embryos was greater for T2 than for T1 and T3 (Table 1). The pregnancy rates for excellent and good embryos and morulae, early blastocysts and blastocysts were not different (P &gt; 0.05). The T1, T2 and T3 twin births were 0, 1 and 5, respectively. It is concluded that embryo bipartition technique applied in a commercial ET program is a viable operational technique. Table 1.Pregnancy at 60 to 80 days and birth rate per original embryos used Supported by CAPES, CNPq, FAPEMIG and BIOTRAN.

6 PRODUCTION OF GONADOTROPIN-RELEASING HORMONE II RECEPTOR KNOCKDOWN SWINE

The second mammalian isoform of GnRH (GnRH-II) is highly conserved from bony fish to humans. However, coding sequence for the receptor specific to this ligand contains reading errors in many species, suggesting the inability to produce a functional receptor. In contrast, the porcine GnRH-II receptor gene contains the appropriate sequence to produce functional protein. The objective of this study was to develop swine with reduced levels of endogenous GnRH-II receptors. Two potential target small hairpin RNA (shRNA1 and shRNA2) sequences specific to the porcine GnRH-II receptor were identified and subcloned into the lentiviral-based, pLVX-shRNA2 vector (Clontech) that provides both shRNA and fluorescent ZsGreen1 coexpression. Lentiviral particles were produced from each shRNA vector as well as a control vector using the Lenti-X HTX Packaging System (Clontech). The ability of shRNA1 and shRNA2 lentiviral particles to reduce porcine GnRH-II receptor mRNA levels was tested in a swine testis-derived (ST) cell line. The day before transduction, ST cells (2 × 106) were plated in 100-mm plates containing high-glucose DMEM supplemented with 10% FBS, 2 mM glutamine, 100 U mL–1 of penicillin and 100 mg mL–1 of streptomycin sulfate. Next, cells were transduced with 1.44 × 107 viral particles per plate for 48 h. The cells were harvested, RNA was extracted and converted to cDNA and quantitative PCR was performed to determine relative levels of GnRH-II receptor mRNA. Values were normalized using the expression levels of 18s rRNA and compared with GnRH-II receptor mRNA levels in ST cells transduced with control lentiviral particles. Lentiviral particles containing either shRNA1 or shRNA2 sequences significantly reduced GnRH-II receptor mRNA levels (95 and 99%, respectively) compared with control particles (P &lt; 0.05). Next, lentiviral particles containing the shRNA2 sequence (1.15 × 109 infectious units mL–1) were microinjected within the perivitelline space of in vivo-derived pronuclear zygotes (n = 15) using a Nikon diaphot inverted microscrope equipped with Eppendorf micromanipulators and an Eppendorf FemtoJet injection system. Microinjected zygotes were subsequently cultured in 50-μL drops of NCSU-23 under mineral oil in a humidified 5% CO2 in air environment. Following 120 h of culture, 93% of the zygotes developed to the compact morula stage, whereas 73% formed blastocysts at 168 h. By 192 h, 80% of the microinjected embryos developed to the blastocyst or expanded blastocyst stages. Fluorescent microscopy revealed that all blastocysts expressed ZsGreen1, indicating a 100% transduction efficiency of shRNA2 lentiviral particles. Finally, embryos were surgically collected from white crossbred donor sows and transduced as described above. A total of 40, 33 and 23 microinjected zygotes were immediately transferred into 3 synchronized recipient females that will be allowed to gestate to term. The animals produced from this study will represent the first animal model to examine the physiological implications of reduced GnRH-II receptor levels.

Symmetrical division of mouse oocytes during meiotic maturation can lead to the development of twin embryos that amalgamate to form a chimeric hermaphrodite

Gentle compression of mouse oocytes during meiosis-1 prevented the usual extrusion of a small polar body and resulted in the symmetrical division of the ooplasm into two cells of similar size within the zona pellucida. The purpose of our study was to determine whether such cells, equivalent to two small oocytes, were capable of embryonic development and would result in birth following transfer to the uterus. IVF of the 2-celled oocytes was performed and the twin intra-zonal embryos were observed. In each case, the two embryos that originated from fertilized cells with two pronuclei were observed to amalgamate and form a single morula and subsequent blastocyst that was transferred to the uterus of a recipient of a different mouse strain. FISH analysis was performed on sectioned paraffin-embedded tissue of the offspring. In symmetrically divided oocytes each cell contained a metaphase II spindle. Both cells were fertilizable and cleaved to form twin embryos within the same zona pellucida. Most twin embryos amalgamated to form a single compacted morula, which progressed to hatched blastocysts that contained a single inner cell mass. In total, 104 of these blastocysts were transferred to 19 mice, two of which became pregnant, resulting in the birth of three offspring. FISH analysis showed that one newborn contained both XX and XY cells. We found that two small oocytes fertilized within the same zona pellucida to form twin embryos that amalgamate to establish a single chimeric embryo. This may be one mechanism that leads to the formation of a chimeric hermaphrodite when an embryo containing XX cells mixes with its intra-zonal twin containing XY cells.

Role of PTEN in mouse pre-implantation development

The PI3K/Akt signal transduction pathway plays an important role in pre-implantation embryonic development. The tumor suppressor gene PTEN negatively regulates the PI3K/Akt pathway. Although PI3K is constitutively activated during pre-implantation embryonic development, currently no evidence shows the presence and possible involvement of PTEN in early embryo development. We investigated the expression of PTEN protein in germinal vesicle (GV) stage oocytes as well as in pre-implantation embryos. The activated form of PTEN was distributed in the peripheral of GV oocytes and compact morula. Treatment of GV oocytes with PTEN inhibitor bpV(pic) did not affect the maturation of the oocyte, but significantly impaired embryonic development. Thus, our study suggests the necessary role of PTEN in pre-implantation embryonic development.