Nutrition, synchronization, and management of beef embryo transfer recipients

A commercially viable cattle embryo transfer industry was established during the early 1970s. Initially, techniques for transferring cattle embryos were exclusively surgical. However, by the early 1980s, most embryos were transferred nonsurgically. For an embryo transfer program to be effective, numerous factors need to be in place to ensure success. Nutrition, estrous cycle control, and recipient management are all responsible for the success or failure in fertility for a given herd. Utilization of body condition scores is a practical method to determine nutritional status of the recipient herd. Prepartum nutrition is critical to ensure that cows calve in adequate body condition to reinitiate postpartum estrous cycles early enough to respond to synchronization protocols. Estrus synchronization for embryo transfer after detected estrus or for fixed-time embryo transfer without estrus detection are effective methods to increase the number of calves produced by embryo transfer. In addition, resynchronization of nonpregnant recipients effectively ensures that a high percentage of recipients will return to estrus during a 72 h interval and are eligible for subsequent embryo transfers. Numerous additional factors need to be assessed to ensure that the recipient herd achieves its reproductive potential. These factors include assessing the merits of nulliparous, primiparous, or multiparous cows, ensuring that facilities allow for minimal stress, and that the herd health program is well-defined and followed. Numerous short- and long-term factors contribute to recipients conceiving to a transferred embryo, maintaining the embryo/fetus to term, delivering the calf without assistance and raising and weaning a healthy calf.     

A history of farm animal embryo transfer and some associated techniques

Events over the last 125 years that have been particularly important to the development of embryo transfer in farm animals are reviewed, arguing that an appreciation of the history of a discipline helps shape its future. Special attention is paid to how the motivations of the scientists involved have changed over time, and how these changes have influenced the practical application of embryo transfer to animal breeding.     

Reproductive biotechnology and "big" biological questions

In recent decades, scientists have learned to manipulate that cardinal characteristic of life, reproduction, with powerful techniques like artificial insemination, contraception, embryo transfer, cryopreservation, and cloning by nuclear transfer. While these technologies often are used for practical applications and basic research, they have another profound intrinsic quality, which is to engender deep-seated thinking about important biological questions. Examples that stimulate such thinking include a goat's giving birth to her identical twin sister via splitting embryos, cryopreservation, and embryo transfer; that a parthenogenetic embryo can never become an animal but can become a genetic mother via an aggregation chimera; or that a somatic cell can become the sole genetic parent of a calf via cloning. In this paper, I illustrate this thought-stimulating quality by considering contributions of reproductive technologies to understanding, if not completely answering, several important biological questions.     

Micromanipulation of mammalian embryos: Principles, progress and future possibilities

Numerous advances in development of techniques for manipulating mammalian embryos outside the maternal environment have been made over the past decade. Some techniques were developed primarily for use in research; others were developed in response to problems of practical livestock production but have proven useful in research as well. Embryo micromanipulation procedures are used often in conjunction with embryo transfer, and interest in these procedures was stimulated by growth of the embryo transfer industry. Included in this review are discussions of procedures for manipulation of gametes and embryos, including sperm injection into oocytes, pronuclear and nuclear transfer, embryo biopsy and splitting, experimental chimera production and isolation of embryonic stem cells.     

The influence of variation in embryo stage and maternal hormone profiles on embryo survival in farm animals

The physiological mechanisms that lead to the requirement for synchronous embryo transfer have been defined in some species, particularly the sheep. In mated animals, variation in hormone profile and embryo stage have been shown to be sufficient to cause some embryo loss, perhaps by generating an asynchronous relationship. During procedures of embryo transfer, there may be additional divergence between hormone profile and embryo stage. It may be beneficial to supply hormones to recipients and to transfer embryos at a particular stage of development at a precise interval after initiation of this treatment.     

Historical perspectives and recent research on superovulation in cattle

Superovulation protocols have evolved greatly over the past 40 to 50 years. The development of commercial pituitary extracts and prostaglandins in the 1970s, and partially purified pituitary extracts and progesterone-releasing devices in the 1980s and 1990s have provided for the development of many of the protocols that we use today. Furthermore, the knowledge of follicular wave dynamics through the use of real-time ultrasonography and the development of the means by which follicular wave emergence can be controlled have provided new practical approaches. Although some embryo transfer practitioners still initiate superstimulatory treatments during mid-cycle in donor cows, the elective control of follicular wave emergence and ovulation has had a great effect on the application of on-farm embryo transfer, especially when large groups of donors need to be superstimulated at the same time. The most common treatment for the synchronization of follicular wave emergence for many years has been estradiol and progestins. In countries where estradiol cannot be used, practitioners have turned to alternative treatments for the synchronization of follicle wave emergence, such as mechanical follicle ablation or the administration of GnRH to induce ovulation. An approach that has shown promise is to initiate FSH treatments at the time of the emergence of the new follicular wave after GnRH-induced ovulation of an induced persistent follicle. Alternatively, it has been suggested recently that it might be possible to ignore follicular wave status, and by extending the treatment protocol, induce small antral follicles to grow and superovulate. Recently, the mixing of FSH with sustained release polymers or the development of long-acting recombinant FSH products have permitted superstimulation with a single or alternatively, two gonadotropin treatments 48 hours apart, reducing the need for animal handling during superstimulation. Although the number of transferable embryos per donor cow superstimulated has not increased, the protocols that are used today have increased the numbers of transferable embryos recovered per unit time and have facilitated the application of on-farm embryo transfer programs. They are practical, easy to administer by farm personnel, and more importantly, they eliminate the need for detecting estrus.     

Nuclear transplantation as a method of producing genetically identical livestock

Abstract

Genetic variation is a problem faced by both researchers and producers. One method to reduce genetic variation is to clone embryos by nuclear transfer. Implementation, involves transferring nuclei from a morula stage embryo to unfertilized oocytes from which the metaphase II chromosomes have been removed. Since each of the nuclei from the original morula stage embryo are genetically identical, each of the embryos that are a result of nuclear transfer have identical nuclear genetics. The original morula stage embryo, relatively speaking, is more differentiated than a one‐cell stage embryo. Thus for the resulting nuclear transfer embryo to continue in development the transferred nuclei must be remodeled to resemble nuclei of a one‐cell stage embryo and be reprogrammed in their developmental cascade of events to behave as nuclei of a one‐cell stage embryo. The potential applications of producing genetically identical individuals range from reducing the number of animals needed for experimentation to providing a more uniform product in the freezer at the grocery store. Unfortunately, the procedures for producing cloned animals by nuclear transfer are still relatively inefficient. There is a need for more basic research to be conducted in understanding mammalian embryogenesis for the application of this and other biotechnologies.     

Effect of transporting donor or recipient does and their embryos on the outcome of fresh embryo transfer in Boer goats

Between-farm embryo transfer of livestock animals can potentially increase the spread of quality genetic material. However, the transporting of donor or recipient animals or their embryos has become a practical problem. The objective of this study was to compare the effect of transporting donor and recipient does and their embryos between various farms on inter-farm fresh embryo transfer in Boer goats. Results indicate the transportation of donor does within 4 h before embryo collection not to have a significant effect on embryo recovery number, embryo survival rate and the subsequent pregnancy in recipient does. Also, the transportation of embryos at 36.5–38 °C within 2 h before embryo transfer did not significantly affect the embryo survival rate and subsequent pregnancy rate, but the transportation of embryos at 20 °C resulted in a significant (P < 0.05) lower survival rate (41.7%) and pregnancy rate (42.0%). The transportation of recipient does resulted in a significantly lower pregnancy rate (42.0%) and embryo survival rate (32.1%) than the transportation of donor does and embryos. Results suggest the transportation of donor does to be the best method for embryo transfer programs on the farm. Alternatively, the supply of fresh embryos kept at body temperature (36.5 °C) was also preferred for short or long distances between farms.     

Non-surgical transfer of deep-frozen bovine embryos

Preservation of cattle embryos by methods of deep-freezing has recently been established (1, 11, 12) and provides a valuable addition to the possibilities of controlled breeding by embryo transfer in cattle.Already long distance transport of frozen embryos has been demonstrated (2, 6) and adopted by some commercial interests. However, in all publications to date, embryos have been transferred to recipients by surgical methods, even though non-surgical methods of embryo recovery and transfer would be preferred for commercial embryo transfer.The purpose of the present experiments was to utilize non-surgical methods of embryo recovery and transfer of deep-frozen cattle embryos to demonstrate the feasibility of the procedure for a farm service to interested breeders. The particular advantage of non-surgical embryo transfer methods is that neither the donor nor recipient need to leave the farm. Embryo preservation by freezing obviates the necessity for synchronization of recipients for immediate transfer from the donor and allows considerable freedom in the choice of the recipients and the timing of embryo transfers.     

Pregnancy rates, prenatal and postnatal survival of offspring, and litter sizes after reciprocal embryo transfer in DBA/2JHd, C3H/HeNCrl and NMRI mice

Success of embryo transfer is often a limiting factor in transgenic procedures and rederivation efforts, and depends on the genetic background of the donor and recipient strains used. Here we show that embryo transfer to DBA/2J females is possible, and present data on pre- and postnatal success rates after reciprocal embryo transfer using the inbred DBA/2J and C3H/HeN, and outbred NMRI strains. The highest embryo yield was achieved in outbred NMRI females, but embryo yields were similar in DBA/2J and C3H/HeN mice following superovulation despite poor estrus cycle synchronization in DBA/2J females. In-strain transfer of DBA/2J blastocysts (transfer of embryos to recipients from the same strain) resulted in pregnancy rates (57.1%) similar to those obtained following in-strain transfer of C3H/HeN (60.0%) and NMRI mice (83.3%), although the prenatal survival rate of blastocysts was low. Moreover, from the pups born only half survived the postnatal period after transfer of DBA/2J and C3H/HeN blastocysts to DBA/2J recipients. These problems were not observed when transferring NMRI-blastocysts to C3H/HeN and DBA/2J mothers. The number of blastocysts transferred also had a positive effect on the success of embryo transfer. In conclusion, C3H/HeN and DBA/2J females can be used as recipients for embryo transfer procedures for certain donor strains like NMRI, as one major determinant seems to be the genetic background of the embryos transferred. We also recommend to increase the number of DBA/2J blastocysts transferred, and to foster the DBA/2J pups to other DBA/2J mothers postnatally for in-strain transfer of DBA/2J mice.     

Genetic aspects of embryo transfer

Use of embryo transfer can lead to increases in rates of genetic improvement from selection programs from as little as 5% to a maximum of near 100%, depending on species, trait, and extent of use of other tools such as A.I. In general, embryo transfer will have much less impact on rates of genetic improvement than A.I., and in a dairy cattle program where A.I. is used effectively, embryo transfer is likely to add less than 10% to rate of genetic improvement. The potential for increasing rate of genetic improvement appears to be greater in beef cattle. In any species with low reproductive rate, embryo transfer offers a potential means of rapidly increasing numbers of animals of a breed, strain, mutant genotype or group exceeding a stringent threshold; such use may be of considerable value to a specific genetic research or multiplication program. Maximizing selection intensity through combined use of A.I. and embryo transfer can lead to a rapid increase in inbreeding, and steps should be taken to avoid this in any population which it is desired to maintain in the long term. Embryo transfer offers an effective tool for research on maternal-fetal and fetal-fetal interactions, and in this way can make important indirect contributions to more efficient breeding programs. With improved embryo storage capability, embryo transfer has the potential for useful contributions in the areas of transfer of germ plasm between countries, preservation of rare breeds, and provision of genetically stable control populations.     

Creating genetically modified pigs by using nuclear transfer

Nuclear transfer (NT) is a procedure by which genetically identical individuals can be created. The technology of pig somatic NT, including in vitro maturation of oocytes, isolation and treatment of donor cells, artificial activation of reconstructed oocytes, embryo culture and embryo transfer, has been intensively studied in recent years, resulting in birth of cloned pigs in many labs. While it provides an efficient method for producing transgenic pigs, more importantly, it is the only way to produce gene-targeted pigs. So far pig cloning has been successfully used to produce transgenic pigs expressing the green fluorescence protein, expand transgenic pig groups and create gene targeted pigs which are deficient of alpha-1,3-galactosyltransferase. The production of pigs with genetic modification by NT is now in the transition from investigation to practical use. Although the efficiency of somatic cell NT in pig, when measured as development to term as a proportion of oocytes used, is not high, it is anticipated that the ability of making specific modifications to the swine genome will result in this technology having a large impact not only on medicine but also on agriculture.     

克隆猪技术及其在转基因猪研究中的应用

哺乳动物核移植技术是一种可以获得基因组遗传信息完全相同的后代的生物技术。猪体细胞核移植技术包括以下几个环节：卵母细胞的体外成熟、供体细胞的分离和处理、体细胞的核转移、重构胚胎的人工激活、胚胎体外培养和胚胎移植。由于该技术在最近几年的迅速发展,很多实验室已通过该技术成功获得了克隆猪后代。核移植克隆猪技术的出现为生产转基因猪提供了一种有效的方法,并且是目前生产基因打靶猪的惟一方法。至今利用克隆猪技术已经成功获得了一系列的转基因猪和基因敲除猪。以核移植技术产生基因修饰猪目前正处于从基础研究走向应用的过渡阶段。尽管猪体细胞核移植克隆的效率（出生克隆猪数占所用卵数的比例）还不高,但是由于通过该技术能够对猪基因组进行特定的修饰,确保生产的克隆动物100％为转基因动物,从而大大提高了转基因猪的制作效率,可以预料猪核移植技术将会对医药业和农业产生重大的影响。     

Piglets produced from cloned blastocysts cultured in vitro with GM‐CSF

In general, pig embryos established by somatic cell nuclear transfer (SCNT) are transferred at the one‐cell stage because of suboptimal embryo culture conditions. Improvements in embryo culture can increase the practical application of late embryo transfer. The goal of this study was to evaluate embryos cultured with granulocyte‐macrophage colony‐stimulating factor (GM‐CSF) in vitro, and to track the in vivo developmental competency of SCNT‐derived blastocysts from these GM‐CSF embryos. The receptor for GM‐CSF was up‐regulated in in vitro‐produced embryos when compared to in vivo‐produced cohorts, but the level decreased when GM‐CSF was present. In vitro fertilized (IVF) embryos, supplemented with GM‐CSF (2 or 10 ng/ml), showed a higher frequency of development to the blastocyst stage compared to controls. The total cell numbers of the blastocysts also increased with supplementation of GM‐CSF. Molecular analysis demonstrates that IVF‐derived blastocysts cultured with GM‐CSF exhibit less apoptotic activity. Similarly, an increase in development to the blastocyst stage and an increase in the average total‐cell number in the blastocysts were observed when SCNT‐derived embryos were cultured with either concentration of GM‐CSF (2 or 10 ng/ml). When SCNT‐derived embryos, cultured with 10 ng/ml GM‐CSF, were transferred into six surrogates at Day 6, five of the surrogates became pregnant and delivered healthy piglets. Our findings suggest that supplementation of GM‐CSF can provide better culture conditions for IVF‐ and SCNT‐derived embryos, and pig SCNT‐derived embryos cultured with GM‐CSF in vitro can successfully produce piglets when transferred into surrogates at the blastocyst stage. Thus, it may be practical to begin performing SCNT‐derived embryo transfer at the blastocyst stage. Mol. Reprod. Dev. © 2013 Wiley Periodicals, Inc.     

Single embryo transfer in IVF to prevent multiple pregnancies.

As the success rates of IVF clinics improve, one of the adverse consequences is the increased incidence of twins, due largely to the number of embryos transferred. Even if the number of embryos transferred is restricted to two, the twinning rate can exceed 40% of the pregnancies. An obvious way to reduce this high twin rate would be to transfer only one embryo. This would require that cryopreservation of the supernumerary embryos be efficacious enough so that the chance of achieving an ongoing pregnancy is not diminished by transferring a single embryo in the stimulated cycle. Previous studies utilising embryos on day 2 and 3 of development have shown that the pregnancy rates can be acceptable (about 40%) and that the cumulative rate can be up to 60%. Most of these studies, however, do not include a comparison with the cumulative pregnancy rate with two embryos transferred in the stimulated cycle. Therefore, the efficacy has not been proven. We present clinical data from the past few years to illustrate the increase in success rates and the concomitant increase in twinning rates. The increased success in the cryopreservation program has enabled us to trial a single embryo transfer program and compare the results to the transfer of two embryos. The results strongly suggest that the transfer of a single embryo is the better clinical option.     

一种非手术性小鼠胚胎移植技术

为了提高非手术性小鼠胚胎移植技术的成功率,利用塑料移植导管模拟非手术胚胎移植过程,通过观察染料在子宫角的分布而评估胚胎移植效果,并在此基础上将自然妊娠3.5 d的小鼠囊胚经子宫颈移植受体小鼠。结果表明:将CD-1小鼠囊胚移植假孕2.5 d小鼠单侧子宫角,平均70.9%的胚胎能够发育至成活新生仔鼠,建立了高效非手术性小鼠胚胎移植技术。该方法简便快捷、不易污染、费用低,无需专业的手术器械,且符合实验动物伦理原则,完全可以取代手术法胚胎移植技术,更重要的是,它为人类和其他大动物的胚胎移植提供了研究模型。     

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.     

Use of tissue culture to bypass wheat hybrid necrosis

Summary Hybrid necrosis in wheat is a barrier to gene transfer in wheat breeding practice. It is based on two complementary genes, Ne1 and Ne2. Recovery mutants (Re1, Re2 and Re3) which can grow to maturity were recovered from immature embryo cultures of necrotic hybrids between T. aestivum and T. durum. Cytological observation demonstrated that Re1 had 34 chromosomes instead of 35. This indicated that one of the chromosomes carrying the Ne genes was lost. Genetic study suggested that for Re1, the lost chromosome was chromosome 5B of the durum parental line. Re mutants are male sterile but can be maintained through a young ear culture method. Re mutants could be successfully pollinated by either parental line and the BC1 progeny is partially fertile. Re mutants were repeatedly induced in about 1% of the regenerated plants from immature embryo culture. This technique provides a practical way to bypass hybrid necrosis.     

体细胞核移植诱导的表观遗传学变化

体细胞核移植技术是指将一个分化的体细胞核置入去核的卵母细胞中,并发育产生与供体细胞遗传背景一致的克隆后代的技术。目前,世界上通过体细胞核移植技术已经产生了许多的克隆动物。但克隆过程中还存在着很多问题,比如,克隆效率太低、克隆个体常伴有表型异常和早亡等,从而使该技术应有的应用潜力不能得到充分的发挥。体细胞表观遗传学重编程的不完全或紊乱是造成核移植诸多问题的主要原因。近十多年来,人们对体细胞核移植后的重编程进行了广泛的研究,其核心内容包括核及核外结构的重塑、DNA甲基化模式的重建、基因印迹和x染色体失活、组蛋白乙酰化模式的重建、端粒长度恢复等,以期能够对其重编程加以人为干预,从而提高动物克隆效率。本文拟对体细胞核移植诱导的重编程研究进展加以综述,希望对体细胞重编程机制的阐明有所启发。     

Utero-tubal Embryo Transfer and Vasectomy in the Mouse Model

The transfer of preimplantation embryos to a surrogate female is a required step for the production of genetically modified mice or to study the effects of epigenetic alterations originated during preimplantation development on subsequent fetal development and adult health. The use of an effective and consistent embryo transfer technique is crucial to enhance the generation of genetically modified animals and to determine the effect of different treatments on implantation rates and survival to term. Embryos at the blastocyst stage are usually transferred by uterine transfer, performing a puncture in the uterine wall to introduce the embryo manipulation pipette. The orifice performed in the uterus does not close after the pipette has been withdrawn, and the embryos can outflow to the abdominal cavity due to the positive pressure of the uterus. The puncture can also produce a hemorrhage that impairs implantation, blocks the transfer pipette and may affect embryo development, especially when embryos without zona are transferred. Consequently, this technique often results in very variable and overall low embryo survival rates. Avoiding these negative effects, utero-tubal embryo transfer take advantage of the utero-tubal junction as a natural barrier that impedes embryo outflow and avoid the puncture of the uterine wall. Vasectomized males are required for obtaining pseudopregnant recipients. A technique to perform vasectomy is described as a complement to the utero-tubal embryo transfer.