Chromosomal abnormalities: a potential quality issue for cloned cattle embryos

Nuclear transfer in cattle is associated with high levels of embryonic mortality and often with congenital malformation. Chromosomal abnormalities are a well-known cause of pregnancy failure and congenital malformation in humans, but their relative contribution to pregnancy failure and congenital malformation in cloned embryos and calves is largely unknown. This paper reviews existing literature on the chromosomal constitution of bovine embryos produced by fertilization in vivo and in vitro, parthenogenetic activation, and nuclear transfer. The published data suggest that chromosomally abnormal cells are common in embryos; however, the frequency reported varies with the method of embryo production. The most frequently observed deviation from the diploid karyotype was mixoploidy resulting from aberrant cell division causing polyploidy in a variable proportion of the embryo's cells.     

Structural and viral association comparisons of bovine zonae pellucidae from follicular oocytes, Day-7 embryos and Day-7 degenerated ova

Bovine zonae pellucidae (ZP) from follicular oocytes and from embryos and degenerated ova collected on Day 7 from superovulated cows were examined by scanning electron microscopy, by dimensional measurement, and by total protein determination. The number of plaque-forming units (PFU) of infectious bovine rhinotracheitis virus (IBRV) that were associated with ZP-intact embryos/ova from each of the 3 sources after in vitro exposure was also determined.

Scanning electron microscopy revealed that the surfaces of Day-7 embryos and degenerated ova were smoother than those of follicular oocytes. Mean dimensional measurements of the diameter/thickness of the ZP from follicular oocytes, Day-7 embryos, and degenerated Day-7 ova were 156.7 μm/12.3μm, 161.3μm/12.6μm, and 158.9μm/12.8μm, respectively. The mean total protein per ZP of follicular oocytes, embryos, and degenerated ova was 0.331 μg, 0.349 μg, and 0.254 μg, respectively. Considerable variability existed within groups, but significantly greater quantities of IBRV were associated with follicular oocytes (mean PFU/oocyte = 68.1) than with Day-7 embryos (mean PFU/embryo = 43.0; P<0.05) or with Day-7 ova (mean PFU/ovum = 31.9; P<0.01).

The reliability of using an assay for IBRV associated with nontransferable ova/embryos as an indicator of the presence or absence of the virus in transferable embryos from the same collection (Day 7) was supported. Although structural differences between the ZPs of follicular oocytes and Day-7 embryos were observed in this study, further investigation is needed to determine if there are differences in the protective function of the respective ZPs.     

Production of piglets from in vitro-produced embryos following non-surgical transfer

The objective of this study was to enhance procedures for producing piglets derived from in vitro-produced (IVP) pig embryos by non-surgical embryo transfer (ET). The effects of insertion length for the catheter, asynchrony between the age of donor IVP blastocysts and the recipient estrous cycle, and volume of transfer medium were investigated. The IVP blastocysts at 5 days after in vitro fertilization were placed into porcine zygote medium (PZM)-5 supplemented with 10% (v/v) fetal bovine serum (PZM+FBS) in a 0.25 mL plastic straw (21-40 blastocysts per straw) and then transferred into one uterine horn of recipients using the Takumi(?) catheter for deep intrauterine insertion. Successful production of piglets derived from IVP embryos was achieved following non-surgical ET when the catheter was inserted at more than 30 cm anterior to the spiral guide spirette. The efficiency of piglet production (percentage number of piglet(s) born based on the number of embryos transferred) was greater (P<0.05) in recipients whose estrous cycle was asynchronous to that of donors with a 1-day delay (8.3%) than in those with a 2-day (1.5%) or 3-day (0.9%) delay, while pregnancy and farrowing rates (10-40%) did not differ among treatments. When blastocysts were transferred into recipients with 1.0 or 2.5 mL PZM+FBS, there were no significant differences in farrowing rate (30-40%) or average litter size (4.5-6.7) between treatments. The results of the present study indicate that the insertion length of the deep intrauterine catheter and the degree of asynchrony between donor embryos and recipient estrous cycle influenced on pregnancy and birth outcome following non-surgical transfer of IVP blastocysts.     

Exposure of in vitro-produced bovine embryos to foot-and-mouth disease virus

The aim of this study was to investigate whether foot and mouth disease virus (FMDV) interacts with in vitro produced (IVP) bovine embryos. One milliliter of a suspension of FMDV (2 x 10(7) TCID50/mL) was added to several batches of these embryos 7 d after in vitro fertilization, by which time they had either developed to the morula/blastocyst stage (n = 256) or degenerated (n = 260). Six experiments were performed in which developed or degenerated batches of embryos were incubated with FMDV for periods of 1 h (3), 2 h (2) or 4h (1). After this, the embryos were washed 10 times according to the International Embryo Transfer Society (IETS), then pooled and ground up to form a suspension, and assayed on cell cultures for FMDV. The cell cultures were observed daily for cytopathic effects for 3 d post exposure. In addition to the cell culture method, the polymerase chain reaction (PCR) technique was used to assay for the presence of the virus in the washing fluids. Assays for FMDV were also conducted on the first and second wash and on the pooled sample constituting the eight, ninth and tenth wash. With the exception of the second wash from a batch of embryos exposed to FMDV for 2 h, all samples of the first and second wash produced FMDV cytopathic effects, but none occurred with the pooled samples of the 8th, 9th and 10th wash. FMDV was also isolated from all but 1 of the batches of embryos after 1 h of incubation, from 1 of 4 batches after 2 h of incubation and from all batches after 4 h incubation. By contrast, the presence of virus could not be demonstrated by PCR based on the technique used here. These results show that 7 d old IVP bovine embryos can retain FMDV after washing, unlike in vivo-derived embryos, which do not appear to carry risks of FMDV transmission when washed according to IETS recommendations. Stricter controls are, therefore, necessary when using IVP embryos from cattle in a non-FMD-free zone in domestic or international trade.     

Chromosomal abnormalities in hypoprolific boars

Four new chromosomal rearrangements are reported in the domestic pig: 3 reciprocal translocations, rcp(4;12)(p13;q13) in a crossbred boar, rcp(1;7)(q17;q26) in a Large White purebred boar, rcp(1;6)(q17;q35) in a purebred synthetic paternal line boar, and a pericentric inversion inv(2)(p13q11) in a crossbred boar. The 1/7 reciprocal translocation and the pericentric inversion were detected in animals that had sired small litters. The effect of the 1/7 translocation was accurately determined: -4.5 piglets born per litter, i.e. -36%. Both the 1/6 and 1/7 reciprocal translocations were of maternal origin. All the chromosomal rearrangements were highlighted using GTG and/or RBG banding techniques. Chromosome painting experiments were also carried out to confirm the proposed hypotheses for the three reciprocal translocations.     

Intercellular communication in in vivo- and in vitro-produced bovine embryos.

In vivo bovine embryos were obtained by nonsurgical flushing of uterine horns of cows submitted to superovulatory treatment, while in vitro embryos were generated from oocytes collected from slaughtered donors. Lucifer Yellow injected into single blastomeres did not diffuse into neighboring cells until the morula stage in in vivo embryos and the blastocyst stage in in vitro embryos. In both cases diffusion was limited to a few cells. In contrast, diffusion was extensive in microsurgically isolated inner cell mass (ICM) but absent in the trophectoderm (TE). At the blastocyst stage, diffusion was always more extensive in in vivo than in in vitro embryos. Ultrastructural analyses confirmed these functional observations, and gap junction-like structures were observed at the blastocyst stage. These structures were diffuse in the ICM of in vivo embryos, scarce in the ICM of in vitro embryos and in the TE of in vivo embryos, and not observed in the TE of in vitro embryos. Blastomeres at all stages of development from the 2-cell stage to the blastocyst stage in in vitro embryos and at the morula and blastocyst stage in in vivo embryos were electrically coupled, and the junctional conductance (Gj) decreased in in vitro embryos from 4.18 +/- 1.70 nS (2-cell stage) to 0.37 +/- 0.12 nS (blastocyst stage). At each developmental stage, in vivo embryos showed a significantly (P < 0. 05) higher Gj than in vitro-produced embryos. Moreover, a significantly (P < 0.01) higher Gj was found in isolated ICM than in the respective blastocyst in both in vivo- and in vitro-produced embryos (3.5 +/- 1.4 vs. 0.7 +/- 0.3 and 2.6 +/- 1.6 vs. 0.37 +/- 0. 12 nS, respectively). The electrical coupling in absence of dye coupling in the early bovine embryo agrees with observations for embryos from other phyla. The late and reduced expression of intercellular communicative devices in in vitro-produced embryos may be one of the factors explaining their developmental low efficiency.     

In vitro-produced bovine embryos: dealing with the warts

Bovine in vitro embryo production is an inefficient process; while maturation and fertilization proceed apparently normally, the proportion of embryos reaching the transferable (blastocyst) stage is rarely over 40% and those that do reach this stage are often compromised in quality and competence. There is considerable evidence of a significant influence of follicular origin on oocyte developmental potential and it appears that once the oocyte is removed from the follicle its developmental capacity is capped. Evidence suggests that while culture conditions during bovine in vitro embryo production can impact somewhat the developmental potential of the early embryo, the intrinsic quality of the oocyte is the key factor determining the proportion of oocytes developing to the blastocyst stage. This paper highlights some of the problems associated with in vitro production of embryos and discusses some of the ways of overcoming these problems.     

Birth of piglets from in vitro-produced, zona-intact porcine embryos vitrified in a closed system

As the importance of swine models in biomedical research increases, it is essential to develop low-cost, high-throughput systems to cryopreserve swine germplasm for maintenance of these models. However, porcine embryos are exceedingly sensitive to low temperature and successful cryopreservation is generally limited to the use of vitrification in open systems that allow direct contact of the embryos with liquid nitrogen (LN₂). This creates a high risk of pathogen transmission. Therefore, cryopreservation of porcine embryos in a “closed” system is of very high importance. In this study, in vitro-produced (IVP) porcine embryos were used to investigate cryosurvival and developmental potential of embryos cryopreserved in a closed system. Optimal centrifugal forces to completely disassociate intracellular lipids from blastomeres were investigated using Day-4 embryos. Cryosurvival of delipidated embryos was investigated by vitrifying the embryos immediately after centrifugation, or after development to blastocysts. In this study, centrifugation for 30 min at 13,000 g was adequate to completely delipidate the embryos; furthermore, these embryos were able to survive cryopreservation at a rate comparable to those centrifuged for only 12 min. When delipidated embryos were vitrified at the blastocyst stage, there was no difference in survival between embryos vitrified using OPS and 0.25 mL straws. Some embryos vitrified by each method developed to term. These experiments demonstrated that porcine embryos can be cryopreserved in a closed system after externalizing their intracellular lipids. This has important implications for banking swine models of human health and disease.     

The ovine uterus as a host for in vitro-produced bovine embryos

A series of experiments were conducted to determine whether bovine blastocysts would develop beyond the blastocyst stage in the ovine uterine environment. In Experiment 1, in vitro matured, fertilized and cultured (IVM/IVF/IVC) expanded bovine blastocysts were transferred into uteri of ewes on Day 7 or 9 of the estrous cycle and collected on Day 14 or 15 to determine if the bovine blastocysts would elongate and form an embryonic disk. Springtime trials with ewes that were synchronized with a medroxyprogesterone acetate (MAP) sponge resulted in a 78% blastocyst recovery rate, and 68% of the recovered spherical or elongated embryos had embryonic disks. In Experiment 2, transfer of 4-cell bovine embryos to the oviducts of ewes at Day 3 resulted in a lower recovery (47 vs 80%) than the transfer of blastocysts at Day 7 when embryos were recovered at Day 14. However, the percentage of embryos containing embryonic disks was higher for embryos transferred at the 4-cell stage (71%) than for embryos transferred as blastocysts (50%). In Experiment 3, IVF embryos from super-ovulated cows or Day 8 in vitro produced embryos transferred to cows were collected at Day 14 and were found to be similar in size to those produced by transfer to ewes in Experiment 2. In Experiment 4, the transfer of bovine blastocysts to ewes did not prolong the ovine estrous cycle. In Experiment 5, extension of the ovine estrous cycle by administration of a MAP releasing intravaginal device allowed bovine embryos to elongate extensively and to become filamentous. In Experiment 6, uterine flushings on Day 14 or Day 16 contained elevated levels of interferon-tau when bovine blastocyst were transferred on Day 7. Transfer of bovine embryos to the reproductive tract of a ewe allows some embryos to develop normally to advanced perimplantation stages and may be a useful tool for studying critical stages of embryo development and the developmental capacity of experimental embryos.     

Errors in development of fetuses and placentas from in vitro-produced bovine embryos

In vitro systems for oocyte maturation, fertilization and embryo culture [in vitro production (IVP)] have the potential for more wide-spread use in creative breeding programs for dairy and beef cattle. However, one negative consequence of both IVP and somatic cell nuclear transfer (SCNT) in cattle and other species is that embryos, fetuses, placentas, and offspring can differ significantly in morphology and developmental competence compared with those from embryos produced in vivo. Fetuses and placentas derived from IVP and SCNT embryos may fall within the normal range of development, may have obvious abnormalities such as increased fetal and placental weights, or may have subtle abnormalities such as aberrant development of fetal skeletal muscle, placental blood vessels, and altered metabolism. Failures in physiologic and/or genetic mechanisms essential for proper fetal growth and survival outside of the uterus contribute significantly to pregnancy and neonatal losses. Oversized fetuses are at increased risk of death during parturition and the adverse consequences of severe dystocia may compromise the dam. Collectively, these abnormalities have been referred to as 'large offspring syndrome' or 'large calf syndrome'. Abnormal phenotypes resulting from IVP and SCNT embryos are stochastic in occurrence and they have not been consistently linked to aberrant expression of single genes or specific pathophysiology. Thus, reliable methods of early diagnosis of the condition are not yet available. The objective of this paper is to examine abnormal development of fetuses and placentas resulting from embryos produced using in vitro systems. The term 'abnormal offspring syndrome (AOS)' is introduced and a classification system of developmental outcomes is proposed to facilitate research efforts on the mechanisms of the various abnormal phenotypes. We also discuss potential genetic and physiologic mechanisms that may contribute to abnormal phenotypes following transfer of IVP and SCNT embryos.     

Closed pulled straw vitrification of in vitro-produced and in vivo-produced bovine embryos

The objective of this study was to evaluate the efficiency of the closed pulled straw (CPS) method for cryopreserving in vitro-produced and in vivo-produced bovine (Bos taurus) embryos. Based on the open pulled straw (OPS) protocol, the top end of a CPS was closed by tweezers (heated in a flame) to prevent the cryoprotectant medium containing embryos from contacting the liquid nitrogen. Bovine in vitro or in vivo morulae and early blastocyst embryos were frozen by slow cryopreservation, OPS vitrification, or CPS vitrification. Morphology of postthawed embryos was evaluated, and normal embryos were used for successive culture for 72 h. There were no significant differences between OPS and CPS freezing groups in postthawed in vitro-produced embryos with respect to rates of morphologically normal embryos (mean ± SD, 87.9 ± 5.2% vs. 85.4 ± 4.9%), survival at 24 h (58.0 ± 6.8% vs. 56.3 ± 4.4%), and survival at 72 h (35.2 ± 6.0% vs. 34.9 ± 6.7%). However, both OPS and CPS vitrification resulted in higher postthaw rates of morphologically normal embryo and survival at 24 and 72 h than those of the slow-freezing method (P < 0.05). Similar results were obtained for in vivo-derived embryos. We concluded that CPS vitrification was a feasible method to cryopreserve both in vitro-derived and in vivo-derived bovine embryos. This method not only eliminated the risk of embryo contamination by preventing contact with liquid nitrogen but also retained the advantages of the OPS vitrification method.     

Induction of parturition in Zebu-cross recipients carrying in vitro-produced Bos indicus embryos

Induction of parturition has been used as a management tool in cattle in several countries, but not commonly in Zebu breeds in tropical production systems. When timed according to the stage of gestation, most induction protocols employing a combination of PGF2alpha and a potent, short-acting corticosteroid, resulted in a predictable interval from induction to calving, with no detrimental effects on calf viability; however, the incidence of placental retention was usually elevated. Pretreatment with a long-acting corticosteroid induced placental maturation and greatly reduced the incidence of placental retention following induction with PGF2alpha and a short-acting corticosteroid. Recently, Brazilian cattle breeders have faced a new challenge with a large number of in vitro-produced embryos. Without a reliable method of cryopreservation, large numbers of embryos have been transferred fresh, creating a new demand for protocols for synchronizing recipients and managing their calving. A parturition-induction protocol, efficacious in Bos taurus cattle, was modified for use in Bos indicus cattle (which generally have a longer gestation than B. taurus cattle). Zebu-cross recipients carrying Nelore in vitro-produced embryos were pretreated with 1 mg/60 kg triamcinolone acetonide on Day 280 of gestation, followed by treatment with 500 microg of cloprostenol and 25 mg of dexamethasone on Day 287. The interval from treatment to calving was predictable and the incidence of retained placenta was low, similar to that described previously for B. taurus cattle, demonstrating that this treatment protocol could be used for induction of parturition in Zebu cattle in Brazil.     

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.     

Chromosomal abnormalities and developmental kinetics in in vivo-developed cattle embryos at days 2 to 5 after ovulation.

The frequency of chromosome abnormalities was investigated in cattle embryos (n = 256) derived from superovulated heifers (n = 35) on Days 2, 3, 4, and 5 postovulation (PO). Interphase nuclei (n = 4358) were analyzed for chromosome abnormalities using fluorescent in situ hybridization with chromosome 6- and chromosome 7-specific probes and the developmental rate was described by scoring cell numbers. We found that 93%, 85%, 84%, and 69% of the embryos from Days 2, 3, 4, and 5 PO, respectively, displayed a normal diploid chromosome number in all cells. Of the embryos containing abnormal cells, mixoploidy was significantly more frequent than polyploidy. The percentage of mixoploidy at Days 2, 3, 4, and 5 PO was 5%, 13%, 16%, and 31%, respectively, whereas the percentages of polyploidy were 2%, 2%, 0%, and 0%, respectively. The mean number of cells per embryo was 4.7, 8, 11.5, and 48.3, respectively, at Days 2, 3, 4, and 5 PO. Thus, in vivo-developed embryos were significantly more advanced than the in vitro-produced (IVP) embryos except for Day 2. In conclusion, a significantly lower frequency of chromosomally abnormal embryos, in particular displaying polyploidy early after fertilization, was seen in in vivo versus IVP embryos, and these chromosomal abnormalities may be inherent to the process of IVP in cattle.     

Improving delivery and offspring viability of in vitro-produced and cloned sheep embryos

Recently developed, assisted reproductive technologies (e.g., in vitro embryo production and nuclear transfer) have encountered perinatal morbidity/mortality of the offspring produced, which are likely to hinder the application of these techniques. Consequently we have sought to develop a system of hormonal stimulation that will ensure the delivery of offspring more prepared for extrauterine life. Here we examine deliveries outcome in sheep carrying in vitro-produced and nuclear transfer (NT) embryos in comparison to artificially inseminated and naturally mated control ewes. All groups (excluding NT, which received one treatment) were subjected to one of two hormonal treatments for induction of delivery, whereas the third part of each group was left without any treatment. The first (commonly used for naturally mated ewes) dexamethasone treatment did not solve a majority of parturition disturbances, and actually the number of deliveries necessitating assistance was reduced (P < 0.05) by this treatment in the control group. On the other hand, combined estradiol plus betamethasone stimulation (E + B) solved a majority of complications regarding delivery performance such as lack of the preparation of the mammary gland, low myometrial contractility, insufficient cervical ripening, and impaired maternal behavior. Moreover, substantial reduction of neonatal mortality was observed following the combined treatment. In conclusion, the E + B induction of delivery overcame the majority of physiological and behavioral intrapartum failures of sheep foster mothers and increased the survival of offspring, and thus can be recommended as a safe method for inducing delivery in foster mothers carrying in vitro-generated embryos.     

Chromosome aberrations in in vitro-produced bovine embryos at days 2-5 post-insemination

Availability of embryos of high quality is required to obtain satisfactory embryonic developmental rates and normal calves following transfer of in vitro-produced (IVP) bovine embryos. One relevant quality parameter is the frequency of chromosome aberrations, which can be evaluated using multicolor fluorescent in situ hybridization (FISH) with chromosome 6- and chromosome 7-specific probes in cattle. In this study, interphase nuclei (n = 3805) were analyzed from 426 bovine IVP embryos. We found that 73%, 72%, 81%, and 58% of the embryos from Days 2, 3, 4, and 5 post-insemination (pi), respectively, displayed a normal diploid chromosome number in all cells. When looking at the types of chromosome aberrations, the percentages of mixoploidy at Days 2, 3, 4, and 5 pi were 22%, 15%, 16%, and 42%, respectively, whereas the percentages of polyploidy (i.e., all nuclei in an embryo were analyzed and were polyploid) were 5%, 13%, 3%, and 0%, respectively. In conclusion, numerical chromosome aberrations were detected as early as Day 2 pi. The development of polyploid embryos is slow and is apparently arrested during the third cell cycle, whereas the mixoploid embryos seem to continue development.