Micronanipulation of bovine embryos for sex determination

Transverse and vertical incisions affect the viability of in vitro-produced embryos submitted to a simplified microsurgery approach

Integrating in vitro embryo production with embryonic microsurgery facilitates the generation of monozygotic twins. However, despite their potential benefits, these methods have not been widely adopted in commercial settings because of their substantial costs. Hence, there is a need to streamline the bisection procedure while ensuring efficient production of viable demi-embryos. In this study, we investigated the impact of different orientations of microsurgical incisions in relation to inner cell mass on embryonic development, morphology, viability, and expression of cell fate protein markers using a simplified microsurgery approach. Ovaries were transported from the slaughterhouse to the laboratory and aspirated to obtain oocytes that were selected and subjected to in vitro embryo production. The selected expanded blastocysts (n = 204) underwent microsurgery. The blastocysts were immobilized to facilitate incision using an adapted microblade, yielding demi-embryos (vertical incision) and viable embryonic fragments (transverse incision). The structures were then re-cultured for 12 h. Viability was assessed by measuring the re-expansion rate after re-culture, followed by immunofluorescence analysis of proteins (CDX2 and NANOG) and apoptosis analysis using terminal deoxynucleotyl transferase dUTP nick end-labeling (TUNEL). Microsurgically derived embryos exhibited remarkable plasticity, as evidenced by a slight reduction (P < 0.05) in the re-expansion rate (transverse 64.2 % and vertical 57.2 %) compared to that of the control group (blastocysts without microsurgery) (86.7 %). They also demonstrated the ability of morphological reconstitution after culturing. Despite the anticipated decrease (P < 0.05) in the total number of cells and embryo volume, microsurgery did not result in a significant increase (P > 0.05) in the number of apoptotic cells. Furthermore, microsurgery led to higher (P < 0.05) expression of markers associated with pluripotency, indicating its efficiency in preserving regenerative capacity. Moreover, microsurgery, whether followed by immunosurgery or not, made the isolation of embryonic cells easier. In conclusion, both transverse and vertical microsurgery incisions enabled the production of identical demi-embryos and served as tools for isolating embryonic cells without compromising the resumption of development and the apoptotic index.

Looking back at five decades of embryo technology in practice

This paper covers developments from International Embryo Technology Society (IETS) meetings over the past 50years. The IETS was officially 'born' at a meeting in Denver, Colorado on Sunday 26 May 1974. There have been 51 IETS meetings (the first was in May 1974), and the first conference at which papers were presented was in 1975. The name of the IETS was changed from International Embryo Transfer Society to International Embryo Technology Society in 2016. The annual IETS conferences are held once a year in January. Embryo technology advanced from the laborious and slow techniques of surgical recovery and transfer of bovine embryos to non-surgical recovery and transfer in many species. Cryopreservation of embryos was initially a slow process that met with only moderate technical success before the development of technology that resulted in high embryo survival rates. The polymerase chain reaction was used to determine the sex of embryos following laminar flow cytology, which came into use to separate X- and Y-bearing spermatozoa. IVF has grown to become widely used, and several factors make it more useful than superovulation and embryo recovery/transfer. Perhaps the most important tool of all was the system that allowed the genetic 'mapping' of the genomic sequence of Bos taurus cattle. Charting key DNA differences by scientists, 'haplotypes' are now used routinely to identify animals with desirable traits of economic importance, discover new genetic disorders, and track carrier status of genotyped animals. Future technology is discussed.

Pre-Implantation Bovine Embryo Evaluation-From Optics to Omics and Beyond

Approximately 80% of the ~1.5 million bovine embryos transferred in 2021 were in vitro produced. However, only ~27% of the transferred IVP embryos will result in live births. The ~73% pregnancy failures are partly due to transferring poor-quality embryos, a result of erroneous stereomicroscopy-based morphological evaluation, the current method of choice for pre-transfer embryo evaluation. Numerous microscopic (e.g., differential interference contrast, electron, fluorescent, time-lapse, and artificial-intelligence-based microscopy) and non-microscopic (e.g., genomics, transcriptomics, epigenomics, proteomics, metabolomics, and nuclear magnetic resonance) methodologies have been tested to find an embryo evaluation technique that is superior to morphologic evaluation. Many of these research tools can accurately determine embryo quality/viability; however, most are invasive, expensive, laborious, technically sophisticated, and/or time-consuming, making them futile in the context of in-field embryo evaluation. However accurate they may be, using complex methods, such as RNA sequencing, SNP chips, mass spectrometry, and multiphoton microscopy, at thousands of embryo production/collection facilities is impractical. Therefore, future research is warranted to innovate field-friendly, simple benchtop tests using findings already available, particularly from omics-based research methodologies. Time-lapse monitoring and artificial-intelligence-based automated image analysis also have the potential for accurate embryo evaluation; however, further research is warranted to innovate economically feasible options for in-field applications.

Fresh Rumen Liquid Inoculant Enhances the Rumen Microbial Community Establishment in Pre-weaned Dairy Calves

The development of the functional rumen in calves involves a complex interplay between the host and host-related microbiome. Attempts to modulate rumen microbial community establishment may therefore have an impact on weaning success, calf health, and animal performance later in life. In this experiment, we aimed to elucidate how rumen liquid inoculum from an adult cow, provided to calves during the pre-weaning period, influences the establishment of rumen bacterial, archaeal, fungal, and ciliate protozoan communities in monozygotic twin calves (n = 6 pairs). The calves were divided into treatment (T-group) and control (C-group) groups, where the T-group received fresh rumen liquid as an oral inoculum during a 2-8-week period. The C-group was not inoculated. The rumen microbial community composition was determined using bacterial and archaeal 16S ribosomal RNA (rRNA) gene, protozoal 18S rRNA gene, and fungal ITS1 region amplicon sequencing. Animal weight gain and feed intake were monitored throughout the experiment. The T-group tended to have a higher concentrate intake (Treatment: p < 0.08) and had a significantly higher weekly weight gain (Treatment: p < 0.05), but no significant difference in volatile fatty acid concentrations between the groups was observed. In the T-group, the inoculum stimulated the earlier establishment of mature rumen-related bacterial taxa, affecting significant differences between the groups until 6 weeks of age. The inoculum also increased the archaeal operational taxonomic unit (OTU) diversity (Treatment: p < 0.05) but did not affect the archaeal quantity. Archaeal communities differed significantly between groups until week 4 (p = 0.02). Due to the inoculum, ciliate protozoa were detected in the T-group in week 2, while the C-group remained defaunated until 6 weeks of age. In week 8, Eremoplastron dilobum was the dominant ciliate protozoa in the C-group and Isotricha sp. in the T-group, respectively. The Shannon diversity of rumen anaerobic fungi reduced with age (Week: p < 0.01), and community establishment was influenced by a change of diet and potential interaction with other rumen microorganisms. Our results indicate that an adult cow rumen liquid inoculum enhanced the maturation of bacterial and archaeal communities in pre-weaning calves' rumen, whereas its effect on eukaryotic communities was less clear and requires further investigation.

Correlation between in vitro fertilization and artificial insemination in Holstein bulls

Objective

Owing to the lack of breeding index for efficient and quick fertility evaluations of Holstein bulls when using traditional or genome-wide detection methods, this study aimed to determine whether in vitro fertilization (IVF) could be used as an indicator of conception rate of artificial insemination (AI).

Methods

Conventional and sexed frozen semen from nine bulls were used for IVF and AI.

Results

The IVF and AI conception rates of each bull were confirmed to be positively correlated between the conventional frozen and sexed frozen semen. The correlation coefficient R values of nine bulls between IVF and AI methods were 0.73 and 0.97 for the conventional frozen and sexed frozen semen, respectively. The average conception rate of three bulls undergoing AI was 69.5% and 64.2%, 61.8% and 58.8%, and 48.2% and 46.2% in first-, second-, and third-born cows when conventional frozen and sexed frozen semen were used, respectively, which showed a positive correlation with the fertilization rate in the same parity. We propose an evaluation standard to assess the fertilization ability of bulls based on their IVF test results, which is categorized into three grades: grade one, normal fertility bull with an AI conception rate of 40% ± 5% and IVF rate of 45%-60%; grade two, higher fertility bull with an AI conception rate of 50% ± 5% and IVF rate of 61%-80%; and grade three, highest fertility bull with an AI conception rate of 60% ± 5% and IVF rate of >80%.

Conclusion

These findings reveal that IVF results can be used as a breeding index for bulls to evaluate their AI conception ability, which may shorten the time required to select bulls for breeding.

Sex Manipulation Technologies Progress in Livestock: A Review

Sex manipulation technologies allow predetermination of the sex of animal offspring by altering the normal reproductive process. In livestock production, the difference in type and gender can translate into significant economic benefits, including alleviation of severe food shortages. In livestock, however, the commercial application of sex manipulation technologies is currently available for cattle only. In this review, we described the brief history of sex manipulation, and the research progresses of common methods used in sex manipulation thus far. Information presented in this review can inform future studies on expanding the scope and use of sex manipulation technologies in livestock.

Laser assisted blastomere extrusion biopsy of in vitro produced cattle embryos-A potential high throughput, minimally invasive approach for sampling pre-morula and morula stage embryos

Whilst adoption of in vitro production (IVP) of cattle embryos and subsequent biopsy for genetic evaluation is increasing, biopsy techniques primarily used were developed to sample in vivo-produced blastocysts. This study was conducted to develop a laser-assisted blastomere extrusion approach for rapid and minimal-invasive biopsy of IVP cattle embryos at pre-morula to morula stages of development (Day 5 or 6 post-fertilisation). Embryo development into blastocysts was not compromised when ≤3 cells were collected by blastomere extrusion on Day 5 (44.4 ± 4.4 % and 34.3 ± 4.6 %) or Day 6 (58.0 ± 4.3 % and 57.5 ± 5.3 %) post-fertilisation compared with non-biopsied control embryos. Similarly, capacity to withstand cryopreservation was not different between embryos biopsied at Day 5 and 6 post-fertilisation and control-embryos (58.8 ± 6.0 %, 63.5 ± 5.6 %, and 56.0 ± 4.8 %, respectively). When more cells were collected from embryos at Day 6 post-fertilisation (≥8 compared to ≤3 cells), subsequent embryo development was not different (63.6 ± 6.1 % and 73.1 ± 6.2 %, respectively) nor was the capacity to withstand cryopreservation (67.9 ± 9.0 % and 62.5 ± 8.7 %, respectively). For biopsies on Day 6 post-fertilization, 95 % of samples produced a PCR product; however, when compared to the whole embryo PCR results, approximately 11 % of biopsy-samples classified as being from a male embryo were from female embryos (false positive), indicating DNA contamination between samples. In conclusion, results of this study indicate laser-assisted blastomere extrusion is a time efficient and minimally invasive approach to biopsy IVP morula and pre-morula cattle embryos to facilitate genetic analysis.

A 100-Year Review: Reproductive technologies in dairy science

Reproductive technology revolutionized dairy production during the past century. Artificial insemination was first successfully applied to cattle in the early 1900s. The next major developments involved semen extenders, invention of the electroejaculator, progeny testing, addition of antibiotics to semen during the 1930s and 1940s, and the major discovery of sperm cryopreservation with glycerol in 1949. The 1950s and 1960s were particularly productive with the development of protocols for the superovulation of cattle with both pregnant mare serum gonadotrophin/equine chorionic gonadotrophin and FSH, the first successful bovine embryo transfer, the discovery of sperm capacitation, the birth of rabbits after in vitro fertilization, and the development of insulated liquid nitrogen tanks. Improved semen extenders and the replacement of glass ampules with plastic semen straws followed. Some of the most noteworthy developments in the 1970s included the initial successes with in vitro culture of embryos, calves born after chromosomal sexing as embryos, embryo splitting resulting in the birth of twins, and development of computer-assisted semen analysis. The 1980s brought flow cytometric separation of X- and Y-bearing sperm, in vitro fertilization leading to the birth of live calves, clones produced by nuclear transfer from embryonic cells, and ovum pick-up via ultrasound-guided follicular aspiration. The 20th century ended with the birth of calves produced from AI with sexed semen, sheep and cattle clones produced by nuclear transfer from adult somatic cell nuclei, and the birth of transgenic cloned calves. The 21st century has seen the introduction of perhaps the most powerful biotechnology since the development of artificial insemination and cryopreservation. Quick, inexpensive genomic analysis via the use of single nucleotide polymorphism genotyping chips is revolutionizing the cattle breeding industry. Now, with the introduction of genome editing technology, the changes are becoming almost too rapid to fully digest.

The contribution of efficient production of monozygotic twins to beef cattle breeding

Production of sires with high breeding potential is indispensable for prompt and reliable breeding using their semen in the cattle industry. Currently, in Japan, we aim to further the production of Japanese black sires via a new breeding system that uses genetically homologous monozygotic twins so that better growth performance and carcass traits can be translated to the increased production of beef with higher economic value. Several studies have reported that monozygotic twins are produced by embryo bisection. On the other hand, with the evolution and stabilization of in vitro fertilization technology, it has become possible to produce multiple monozygotic twin calves from blastomeres separated from a cleavage-stage embryo. This review attempts to clarify breeding practices through revalidation of the factors that affect the production efficiency of monozygotic twin calves by embryo bisection. Furthermore, the establishment of a system for monozygotic twin embryo production via the simplified technique of blastomere separation is reviewed while showing data from our previously performed studies.

The ART of selecting the best embryo: A review of early embryonic mortality and bovine embryo viability assessment methods

Animal reproductive biotechnology is continually evolving. Significant advances have been made in our understanding of early embryonic mortality and embryo development in domestic animals, which has improved the selection and success of in vitro technologies. Yet our knowledge is still relatively limited such that identifying a single embryo with the highest chance of survival and development for transfer remains challenging. While invasive methods such as embryo biopsy can provide useful information regarding the genetic status of the embryos, morphological assessment remains the most common evaluation. A recent shift, however, favors alternative, adjunct approaches for non-invasive assessment of an embryo's viability and developmental potential. Various analytical techniques have facilitated the evaluation of cellular health through the metabolome, the assessment of end products of cellular metabolism, or by analyzing spent media for small RNAs. This review discusses the application of noninvasive approaches for ascertaining the health and viability of in vitro-produced bovine embryos. A comparative analysis of noninvasive techniques for embryo assessment currently being investigated in cattle and humans is also discussed.

Forty years of embryo transfer in cattle: a review focusing on the journal Theriogenology, the growth of the industry in North America, and personal reminisces

After the first successful transfer of mammalian embryos in 1890, it was approximately 60 years before significant progress was reported in the basic technology of embryo transfer (ET) in cattle. Starting in the early 1970s, technology had progressed sufficiently to support the founding of commercial ET programs in several countries. Today, well-established and reliable techniques involving superovulation, embryo recovery and transfer, cryopreservation, and IVF are utilized worldwide in hundreds, if not thousands, of commercial businesses located in many countries. The mean number of embryos produced via superovulation has changed little in 40 years, but there have been improvements in synchrony and hormonal protocols. Cryopreservation of in vivo-derived embryos is a reliable procedure, but improvements are needed for biopsied and in vitro-derived embryos. High pregnancy rates are achieved when good quality embryos are transferred into suitable recipients and low pregnancy rates are often owing to problems in recipient management and not technology per se. In the future, unanticipated disease outbreaks and the ever-changing economics of cattle and milk prices will continue to influence the ET industry. The issue of abnormal pregnancies involving in vitro embryos has not been satisfactorily resolved and the involvement of abnormal epigenetics associate with this technology merits continued research. Last, genomic testing of bovine embryos is likely to be available in the foreseeable future. This may markedly decrease the number of embryos that are actually transferred and stimulate the evolution of more sophisticated ET businesses.

Optimization of cryoprotectant loading into murine and human oocytes

Loading of cryoprotectants into oocytes is an important step of the cryopreservation process, in which the cells are exposed to potentially damaging osmotic stresses and chemical toxicity. Thus, we investigated the use of physics-based mathematical optimization to guide design of cryoprotectant loading methods for mouse and human oocytes. We first examined loading of 1.5 M dimethyl sulfoxide (Me(2)SO) into mouse oocytes at 23°C. Conventional one-step loading resulted in rates of fertilization (34%) and embryonic development (60%) that were significantly lower than those of untreated controls (95% and 94%, respectively). In contrast, the mathematically optimized two-step method yielded much higher rates of fertilization (85%) and development (87%). To examine the causes for oocyte damage, we performed experiments to separate the effects of cell shrinkage and Me(2)SO exposure time, revealing that neither shrinkage nor Me(2)SO exposure single-handedly impairs the fertilization and development rates. Thus, damage during one-step Me(2)SO addition appears to result from interactions between the effects of Me(2)SO toxicity and osmotic stress. We also investigated Me(2)SO loading into mouse oocytes at 30°C. At this temperature, fertilization rates were again lower after one-step loading (8%) in comparison to mathematically optimized two-step loading (86%) and untreated controls (96%). Furthermore, our computer algorithm generated an effective strategy for reducing Me(2)SO exposure time, using hypotonic diluents for cryoprotectant solutions. With this technique, 1.5 M Me(2)SO was successfully loaded in only 2.5 min, with 92% fertilizability. Based on these promising results, we propose new methods to load cryoprotectants into human oocytes, designed using our mathematical optimization approach.

Birth of correctly genotyped calves after multiplex marker detection from bovine embryo microblade biopsies

We report a method for multiplex genotyping of bovine embryo microblade biopsies. We have tested the reliability of the method and the viability of the embryos in vitro and in vivo. Two polymorphic gene markers (GHR F279Y and PRLR S18N) associated with milk production traits and one marker for sex diagnosis (ZFX/ZFY) were genotyped simultaneously with a method that combines nested PCR and allelic discrimination. To test the accuracy of genotyping, in the first experiment the genotypes of 134 biopsies from in vitro produced embryos were compared to genotypes determined from the corresponding embryos after biopsy. The method proved to be highly accurate as only in three cases (two for PRLR S18N and one for GHR F279Y) out of 395 genotypes the genotype was in disagreement between the two samples. The viability of similarly biopsied embryos was tested in parallel: after 24-hr culture 94.6% of embryos recovered in vitro. In the second experiment, a total of 150 in vivo-produced embryos were biopsied on Day 7 and genotyped. After the genotyping results were obtained on Day 8, female embryos were selected for transfer. From a total of 57 selected embryos 43 were transferred individually and 14 as pairs. After single embryo transfers, 19 recipients became pregnant and after embryo transfers in pairs one became pregnant. The success of genotyping was tested with the genotypes of donors and bulls and also from the hair samples of born calves. All calves were females and of the same genotypes determined from the biopsy.

Effect of hormonal stimulation on bovine follicular response and oocyte developmental competence in a commercial operation

The widespread use of ultrasonography and IVF over the past decade has provided new tools to evaluate how follicles and oocytes react to different superstimulatory treatments. This information may be used to redefine actual hormonal stimulations to improve results of MOET programs and/or obtain improved responses from the "so-called" poor responders. This retrospective study examined data collected over a 5-year period involving oocyte collections in a commercial embryo transfer unit to determine the stimulation protocol that was most effective in producing competent cumulus oocyte complexes, and to determine a definition of a low responder. Overall, the population of small antral follicles at the time of follicle ablation was the most important factor affecting results. This pool of small antral follicles was significantly correlated with the number of follicles at oocyte collection, and to the number of viable and transferable embryos produced. Varying the superstimulatory treatments in terms of type of FSH in association with a shorter or longer coasting period did not affect ovarian response or embryonic development rates. Low responders (less than 10% of the animals in this study) were defined as animals with a lower than average follicular response following superstimulation. Low potential animals were defined as donors producing a limited number of embryos because of the limited population of small antral follicles present in the ovaries at initiation of FSH treatment. Embryo transfer practitioners must distinguish between low responders and low potential animals as modifications to the stimulation protocol for the latter group is unlikely to result in a higher number of transferable embryos.

A bovine protocol for training professionals in preimplantation genetic diagnosis using polymerase chain reaction

OBJECTIVE

To develop a bovine protocol for training in preimplantation genetic diagnosis (PGD) using PCR.

DESIGN

Randomized study.

SETTING

Human reproduction PCR laboratory.

PATIENT(S)

Cow ovaries obtained from slaughterhouses.

INTERVENTION(S)

The ovaries were punctured and the oocytes were matured and submitted to in vitro fertilization. On the third day after fertilization, the embryos were biopsied and 1-2 blastomeres removed. A blastomere and the rest of the embryo were submitted to PCR for sex determination.

MAIN OUTCOME MEASURE(S)

Establishment of a possible training protocol.

RESULT(S)

A total of 50 embryos and 50 biopsied blastomeres were submitted to DNA amplification for sexing. Of the 50 embryos, 41 (82%) achieved successful DNA amplification and 9 (18%) did not. Of the 50 biopsies, 31 (62%) amplified and 19 (38%) did not. In 27 (65.9%) of the 41 embryos with DNA amplification, sex was identified as female and in 14 (34.1%) as male. In 40 cases (80%) amplification and sex determination were successful in both embryos and blastomeres. Sex was identical in all these cases.

CONCLUSION(S)

This training model seems to be useful in identifying mistakes and difficulties and improving the professional's performance in the various stages of preimplantation genetic diagnosis.

Nonelectrophoretic PCR-sexing of bovine embryos in a commercial environment

Techniques for sex determination of bovine embryos have evolved from karyotyping of older preimplantation embryos some 25 years ago to the current variety of widely used polymerase chain reaction (PCR) protocols. Although highly accurate, most PCR protocols for sex determination have included an electrophoresis step. The present work is a retrospective study utilizing a unique PCR protocol to sex bovine embryos without use of electrophoresis in a commercial embryo transfer program. Both in vivo and in vitro-derived embryos were produced by conventional techniques and biopsied between 7 and 8 days of age with a steel blade attached to a mechanical micromanipulator. Males constituted 49.0% of 3964 in vivo and 53.0% of 1181 in vitro-derived embryos subjected to PCR. Based on ultrasound fetal sexing and on calvings, the accuracy of sex determination was 98.7% for male embryos and 94.4% for females, with no samples producing an undetermined outcome. Pregnancy rates following transfer of biopsied Grade 1 embryos were lower than control, intact embryos as follows: 8, 6 and 16% points for in vivo, in vitro and in vivo frozen embryos, respectively. Pregnancy rates were similar for all stages of in vivo-derived embryos, whereas the pregnancy rate was significantly lower for in vitro-derived morulae compared to all stages of blastocysts. The sex ratio was significantly skewed in favor of females among in vitro-derived morulae, and in favor of males among in vitro expanded blastocysts. The sex ratio of in vivo expanded blastocysts was significantly skewed in favor of female embryos. No seasonal variation in either pregnancy rate or sex ratio was detected. There was no evidence that DNA contamination influenced the PCR assay during the duration of the study. The assay was sensitive to single blastomeres from male embryos, whereas it was not sensitive to Percoll-centrifuged or accessory sperm cells.

Splitting and biopsy for bovine embryo sexing under field conditions

Improvements on embryo micromanipulation techniques led to the use of embryo bisection technology in commercial embryo transfer programs, and made possible the direct genetic analysis of preimplantation bovine embryos by biopsy. For example, aspiration and microsection, allow bovine embryos sexing by detection of male-specific Y-chromosome in a sample of embryonic cells. We report on the application of the methodologies of splitting and biopsy of bovine embryos in field conditions, and on the results of embryo sex determination by the polymerase chain reaction (PCR). Pregnancy rates achieved with fresh bisected or biopsied embryos (50 to 60%) were similar to the fresh intact embryos (55 to 61%). The PCR protocol used for embryo sexing showed 92% to 94% of efficiency and 90 to 100% of accuracy. These results demonstrate these procedures are suitable for use in field conditions.

Sexing and multiple genotype analysis from a single cell of bovine embryo

We described a procedure for multiple genotype analysis (determination of sex and of three genetic markers) from a single cell derived from bovine preimplantation embryo. It consists of primer extension preamplification-polymerase chain reaction (PEP-PCR) and subsequent single assay or multiplex PCR. A single blastomere that was isolated by microaspiration from bovine embryos at the 16- to 32-cell stage then was lysed and was subjected to the PEP-PCR. When testing 75 embryos, efficiency of genotyping by standard PCR for kappa-casein, growth hormone (GH) and prolactin (PRL) polymorphic alleles was 91, 88 and 89%, respectively. Sexing efficiency in the multiplex PCR was 91%, based on the amplification of Y-specific locus using kappa-casein internal standard. The microaspiration of a single blastomere was shown not to be invasive for the embryos. It did not alter their development potential in vitro (P > 0.05), as was seen by obtaining a similar percentage of embryos developing further into the blastocyst stage in the group subjected to biopsy (44/75, 59%) and in the control group of embryos (30/50, 60%).

Progress on methods of gene detection in preimplantation embryos

The advent of the polymerase chain reaction (PCR) and the development of fluorescence in situ hybridization (FISH) have had a tremendous impact on preimplantation genetic diagnosis (PGD). While PCR is a powerful tool in detecting genetic diseases or molecular markers affecting quantitative trait loci, the main use of FISH is screening for chromosomal aberrations. This presentation reviews the recent progress in preimplantation genetic diagnosis with an emphasis on bovine embryos. In particular the importance of biopsy size and strategies to avoid PCR contamination are discussed. Alternative DNA amplification and detection methods as well as methods to meet the challenge of multiple locus detection for marker assisted selection are presented.

Sexing of porcine embryo by in situ hybridization using chromosome Y- and 1-specific DNA probes

This study was carried out to determine if a rapid, simultaneous detection system using chromosome Y- and 1-bearing boar spermatozoa was applicable for sexing embryos. Porcine embryos were recovered from gilts and sows 4 to 6 d after mating, and whole embryos or biopsy cells were mounted on a glass slide with a small amount of fixative (methanol: acetic acid: distilled water = 9:1:4). The samples were then stained by means of a fluorescence in situ hybridization (FISH) procedure developed specifically for the detection of Y-bearing spermatozoa. Hybridization was performed using digoxigenin (dig)-labeled chromosome Y- specific DNA, and biotin-labeled chromosome 1-specific DNA sequences were detected as a signal of FITC and Texas Red on nucleus visualized DAPI-stain. Proportions of whole embryos labeled with chromosome 1-probe were 17 and 97% at the 3 to 16 and > or = 32 cell stage, respectively. Of the 93 biopsied embryos analyzed by FISH, 85 embryos (91%) could be accurately classified as male or female. Of the 65 biopsied embryos, 60 embryos (92%) had a clear blastocoele and a inner cell mass after 48 h of culture in vitro, and these embryos were evaluated as available embryos. One out of 4 recipient gilts which received sexed embryos at transfer farrowed 12 piglets of the expected sex. The results of this study demonstrated that porcine embryos at the > or = 32 cell stage can be sexed within 2 h using the FISH method. Moreover further development of the FISH technique could make it an effective tool for the study of early porcine embryos and for the control of porcine sex.

Production of calves by transfer of nuclei from cultured somatic cells obtained from Japanese black bulls

We investigated the possibility of producing calves from transferable bovine embryos obtained by nuclear transfer using somatic cell-derived cell lines. Muscle cells obtained from 2 Japanese Black bulls were dispersed in Hank's solution supplemented with collagenase Type-I. The separated muscle cells were cultured in Dulbecco's Modified Eagle's medium (D-MEM) supplemented with 10% fetal bovine serum (FBS) at 39 degrees C in an atmosphere of 5% CO2 in air. Cells were passaged at least 4 times, and for 5 d prior to nuclear transfer they (donor cells: karyoplasts) were cultured in D-MEM supplemented with 0.5% FBS (to induce quiescence) or 10% FBS. Recipient oocytes were produced by in vitro culture of bovine oocytes that were obtained at a slaughterhouse and then enucleated in modified phosphate buffered saline supplemented with cytochalasin B. Embryos were reconstructed by 3 protocols using karyoplasts cultured in the medium with 0.5% FBS. 1) Group A: recipient oocytes (cytoplasts; n = 157) were treated with Ca ionophore A 23187, ethanol and cycloheximide, and then a karyoplast was fused to an activated cytoplast. 2) Group B: karyoplasts were transferred to cytoplasts (n = 117), and the couplets were treated with electric stimulation and then Ca ionophore A 23187 and cycloheximide. 3) Group C: cytoplasts (n = 104) were cultured for a further 12 h before fusion, and then the couplets were treated with electric stimulation and cycloheximide. 4) Group D: in addition to the above 3 groups, karyoplasts cultured in the medium with 10% FBS were transferred to recipient cytoplasts (n = 137) and treated as in Protocol 2. Reconstructed embryos were cultured in modified CR1aa for 8 d, and the development of embryos was assessed. In total 73 blastocysts were obtained, and the frequency of development to the blastocyst stage in Group A (2.5%) was lower than that of Groups B, C and D (20.5, 18.3 and 19.0%, respectively; P < 0.01). Of these the sex of 21 blastocysts was determined by rapid Y-chromosome detection assay, and all were male, suggesting that nuclear replacement had been achieved successfully. When 26 blastocysts were transferred to 20 recipient cows, 8 of them became pregnant; 4 cows subsequently aborted about 60 d after embryo transfer while the remaining 4 cows calved. These results indicate that reconstructed embryos obtained by nuclear transfer of muscle cell-derived cell lines can develop to the blastocyst stage, and some are sufficiently competent to develop to term. Particularly important was the finding that special culture protocols for somatic cells prior to nuclear transfer were not necessary in our system.

Determining the sex of bovine embryos using polymerase chain reaction results: a six-year retrospective study

Knowing the sex of embryos produced for use in an embryo transfer program can assist the dairy producer in managing his resources more effectively. A reliable procedure for accomplishing this goal is to apply PCR technology to the biopsy of an embryo. A description is provided of how the technique has been applied on a large scale in a commercial setting in western Canada between 1992 and 1997. A total of 4,183 embryos was biopsied over a 6-yr period. The sex was determined with more than 90% of the embryos. The results showed that there was a seasonal variation in the sex ratio, with more females being recorded in the period of least light (October to March), than in April to September. While both sire and embryo quality affected the sex ratio, the differences were too small to be of value in most breeding programs. Pregnancy rates with fresh sexed embryos (58 to 71%) were comparable to those with fresh unsexed embryos. The results following freezing and thawing of sexed embryos were low (37 to 66%) but sufficient to be viable commercially. When the sex assigned by PCR was verified by fetal sexing at 60 d of gestation, the error rate was 7%. This study demonstrates that sexing of embryos can be carried out on a large scale. Demand for quick, reliable determination of sex can be met in a cost effective manner. The pregnancy rates achieved with embryos after biopsy are suitable for use in a commercial setting.

In vitro embryo production in the cow: an effective alternative to the conventional embryo production approach

Development of new technology related to in vitro embryo production has allowed for the commercial use of this method of reproduction. In the present work, we evaluate the efficiency of this technology compared with conventional embryo production based on results obtained with a standard procedure, including the sexing of embryos. The donor animals were mature nonlactating dairy cows (n = 92) kept under a constant environment and feeding program in an ET center. Ultrasound guided transvaginal ovum pick-up following 48 h pre-treatment with FSH has been used for the IVF-IVC protocol. A total of 437 oocyte recovery sessions performed on 92 cows yielded 4145 oocytes, which were used in an IVF-IVC protocol. Using the conventional approach, 156 embryo collections on 49 cows yielded 1652 ova and embryos. All Quality 1 and 2 embryos were sexed by a PCR procedure, and embryos of the desired sex were transferred to synchronized recipients located at the center. The results obtained in the IVF protocol showed that 4 oocyte collections per cow performed within 60 d, yielded 38 oocytes, which resulted in 18.8 viable embryos, of which 7.05 were female. After transfer of the female embryos, an average of 3.8 recipients were pregnant at 60 d. One embryo collection under the conventional approach yielded an average of 1.2 female pregnancies, which was confirmed during the same 60-d time period. These results indicate that IVF procedures can effectively replace conventional embryo production methods when a predetermined number of pregnancies of known sex are needed within a short period of time.

Rapid detection of male-specific DNA sequence in bovine embryos using fluorescence in situ hybridization

An accurate, reliable, and quick (less than an hour) method for determining the sex of bovine embryos was developed using a fluorescence in situ hybridization (FISH), with a probe designed from a bovine Y chromosome specific DNA (BC1.2). First, to improve a protocol of FISH and evaluate an accuracy of the method, lymphocyte nuclei prepared from three bulls, two cows, and one freemartin were tested. We found that 5 min was enough for hybridization. The washing solution adequate for posthybridization was 0.5x SSC at 72 degrees C for 5 min. The whole procedure for FISH can be accomplished in less than an hour. A male-specific signal was detected, on average, as 97, 0.5, and 83%, respectively, of lymphocytes in males, females, and a freemartin. Using the rapid FISH protocol developed, 28 embryos were divided. According to the presence of the digoxigenin signal, 16 embryos (57.1%) were predicted as male, and 12 embryos (42.9%), predicted as female.

Normal calves from transfer of biopsied, sexed and vitrified IVP bovine embryos

Data on biopsied, sexed and cryopreserved in vitro produced (IVP) bovine embryos, and their in vivo developmental competence are very limited. Two preliminary studies were conducted before the primary study. In Experiment 1, post-thaw in vitro developmental competence of biopsied and vitrified IVP embryos was evaluated using re-expansion as an endpoint. In Experiment 2, the pregnancy rates of biopsied fresh, frozen or vitrified embryos following single embryo transfer were compared. Since vitrified embryos resulted in a higher pregnancy rate than frozen-thawed embryos, in the primary study (Experiment 3), all IVP embryos were vitrified following biopsy and sexing (by DNA fingerprinting). In Experiment 3, we compared pregnancy initiation and calving results of heifers in the following treatments: 1) artificial insemination (AI); 2) AI plus contralateral transfer of a single embryo (AI + SET); 3) ipsilateral transfer of single embryo (SET); or 4) bilateral transfer of two embryos (DET). Birth weights, gestation lengths and dystocia scores were recorded. In Experiment 1, post-thaw re-expansion rate of biopsied and vitrified embryos was 85% (70/82). In Experiment 2, pregnancy rates (90 d) were 44% (7/16), 23% (3/13), and 50% (7/14) for vitrified, frozen and fresh embryos, respectively (P < 0.10). In Experiment 3, pregnancy rates of AI and SET were 65% (20/31) and 40% (16/40), respectively (P < 0.05). The pregnancy rate of AI + SET was 75% (27/36) with 11 carrying twins, and the pregnancy rate of DET was 72% (26/36) with 10 carrying twins. All AI fetuses were carried to term, but only half the SET fetuses were carried to term. Similar calving rates were observed in the AI + SET and DET groups, 76 and 70%, respectively, of those pregnant at Day 40. Mean birth weight, dystocia score and gestation length of AI calves were not different from those of SET calves. Mean birth weight and dystocia score of single-born calves were greater than those of twin born calves (P < 0.05). These data demonstrate that biopsied IVP bovine embryos can be successfully cryopreserved by vitrification and following post-thaw embryo transfer, acceptable rates of offspring with normal birth weights can be obtained without major calving difficulties.

Comparison of two manipulation methods to produce in vitro fertilized, biopsied and vitrified bovine embryos

The objective of this study was to compare the overall efficiency, measured by in vitro embryonic survival, and practical value of bovine in vitro embryo production, biopsy, vitrification, and direct transfer technology using 2 different manipulation methods for biopsy. Slaughterhouse-derived oocytes were matured in vitro, fertilized (Day 0) with frozen-thawed, Percoll-separated spermatozoa and cultured on a granulosa cell monolayer. In Experiment 1, one or two blastomeres were expelled from Day 4 embryos by mechanical force through a hole made by partial zona dissection. Using a darning needle hole system for individual culture of biopsied embryos from Day 4 to Day 7.5, the blastocyst per oocyte rate was 50%, and 76% of the blastocysts survived subsequent vitrification and direct in-straw rehydration. Attempts to increase the cell number of the biopsies by further in vitro culture were unsuccessful. In Experiment 2, Day 7 and Day 8 embryos were manually biopsied before or after vitrification. When biopsy was performed before vitrification, 98% of the embryos survived manipulation, and 86% of these re-expanded after vitrification and in-straw dilution. Biopsy after vitrification was less efficient, since only 69% of the embryos survived both processes. The cumulative efficiency of embryo production, Day 7.5 biopsy and vitrification--in-straw direct rehydration was lower (P < 0.001) than that of Day 4 biopsy and Day 7.5 vitrification (29 vs 38%, respectively). However, a Day 7.5 biopsy may have the more practical application since the size of the biopsy is larger and the process is not as time-consuming as the long-term individual culture of the biopsied embryos.

Multiple genotype analysis and sexing of IVF bovine embryos

Twenty-one in vitro-fertilized bovine blastocysts were quartered, lysed and subjected to primer elongation preamplification (PEP) procedure, allowing for the analysis of up to 40 genotypes per quarter embryo. The quarter-embryos were sexed by polymerase chain reaction (PCR) using BRY.1, Bov97M and ZFX/ZFY loci, and then genotyped for k-casein, bovine leukocyte adhesion deficiency (BLAD) and microsatellite D9S1. The mitochondrial cytochrome B locus was used as an internal control with a 95% success rate. The PEP procedure amplified genomic fragments in 93% of all cases. The embryos were identified to be 11 males and 10 females. Sexing accuracy was 87% for BRY.1, 97% for ZFX/ZFY and 100% for Bov97M. False genotyping was due mostly to amplification of BRY.1 in the female embryos and to the nonamplification of the ZFY locus in the male embryos. The results indicate that the combined use of Bov97M and ZFX/ZFY loci is a highly accurate procedure for sexing bovine embryos. Genotyping for kappa-casein, D9S1 and BLAD was successful in 94, 99 and 91% of assays, respectively. Sex ratios and allele frequencies of embryos for gk-casein, BLAD and D9S1 were all close to the observed frequencies in the Israeli Holstein population. These results support the conclusion that the genotyping of embryos is as accurate as that of mature animals. Thus, marker-assisted selection can be efficiently applied at the preimplantation embryo level for loci of economic importance.

Sex selection in mammals: A review

New methods for sperm separation and embryo sexing provide the opportunity to select the gender of the offspring of domestic mammals. We review here procedures currently available for pre- and post-fertilization sex determination, including flow cytometric selection of X- and Y-chromosome bearing spermatozoa and the application of the polymerase chain reaction to biopsied embryos. Modern techniques are considered in the context of the development of the field and parallel innovations in human medicine are briefly considered.

Cryopreservation of mammalian embryos and oocytes: Recent advances

The cryopreservation of embryos of most domestic species has become a routine procedure in embryo transfer, and recently, advances have been made in the cold storage of mammalian oocytes. The ability to sustain viable oocytes and embryos from mammalian species at low temperature for prolonged periods of time has important implications to basic and applied biotechnology. Recent advances in the study of physico-chemical behaviour of different cryoprotectants, use of various macromolecule additives in cryoprotective solutions and isolation and use of proteins of plant and animal origin with antifreeze activity offers many new options for cryopreservation of oocytes and embryos of animal and human origin. At the same time rapidly developing methods of oocyte/embryo manipulation such as in vitro embryo production, embryo splitting, embryo biopsying for gene and sex determination, embryo cloning and the isolation of individual blastomers, create new challenges in cryopreservation. Very recent advances in the cryopreservation of mammalian oocytes, in vivo- and in vitro-derived embryos, and micromanipulated embryos are reviewed in this manuscript.

PCR-sexing of bovine embryos: A simplified protocol

To make bovine embryo sexing under farm conditions more feasible we developed a simplified protocol utilizing manual biopsy and detection of the Y chromosome directly from polymerase chain reaction (PCR) reaction tubes. Twenty-four embryos (morulae and blastocysts) were biopsied manually into 2 to 4 samples. One sample of each original embryo was diagnosed for sex, based on restriction fragment length polymorphism of PCR-amplified DNA of the ZFX/ZFY locus. The remaining 44 samples were diagnosed using the tube detection assay. In this assay the biopsies were pipetted into 0.5 -ml reaction tubes containing lysis mixture, incubated 10 to 60 min at 37 degrees C and inactivated 10 min at 98 degrees C. Then the PCR mixture was added containing buffer, DNA polymerase, ethidium bromide and primers designed to amplify the highly repeated btDYZ-1 region of the bovine Y chromosome. After 50 cycles of PCR, the reaction tubes were examined under UV illumination for pink fluorescence indicating the presence of Y-chromosomal DNA. All sexing results from the replicates were in agreement with the ZFX/ZFY assay, with 12 of the original embryos diagnosed as females and 12 as males. We conclude that highly efficient and accurate PCR-sexing of embryos can be accomplished without the use of micromanipulators, control primers and electrophoresis. The 2 reaction mixtures needed for sex diagnosis can be stored at -20 degrees C and -196 degrees C, respectively. The tube detection assay minimizes the risk of carryover contamination by previously amplified products as there is no need to open the tubes following PCR.

Viability of fresh and frozen-thawed biopsied bovine embryos

Bovine embryos were biopsied using a simplified splitting technique and frozen-thawed according to a standard method with glycerol as cryoprotectant. The viability of fresh and frozen-thawed biopsied and intact embryos were evaluated after in vitro culture, by means of fluorescence test or following transfer to recipients. The survival rates after in vitro culture of fresh intact and biopsied embryos and of frozen-thawed intact and zona free embryos were not significantly different (70%, 60%, 68% and 52%, respectively), but significantly reduced for biopsied frozen-thawed embryos (16%) (p < or = 0.05). The pregnancy results after transfer of biopsied frozen-thawed embryos were also significantly lower (8%) compared to fresh biopsied embryos (39%) (p < or = 0.05). Both intact and biopsied embryos fluoresced after incubation with diacetylfluorescin but with higher intensity for the intact embryos. It is suggested that the reduced survivability for the frozen-thawed biopsied embryos might be caused by combined effects of the loss of the zona pellucida and the reduction of cells as a result of the simplified biopsy technique. It is concluded that improved biopsy and/or freezing techniques must be used if biopsied embryos have to be frozen.

Polymerase chain reaction and its applications: special emphasis on its role in embryo sexing

The polymerase chain reaction (PCR) has developed into one of the most promising methods for in vitro enzymatic amplification of DNA and has found widespread application in DNA cloning, sequencing and mutagenesis related studies. This innovative technique can selectively amplify a single target DNA molecule a billion-fold in a span of a few hours. Amplification of specific DNA sequences by PCR is useful in identification of sex, novel genes, pathogens and diseases. PCR has facilitated the establishment of evolutionary relationships among species and in revealing structural intricacies of single cells. In this article we review some of the major advances and applications of PCR, especially, its role in embryo sexing.

DNA contamination of reagents used in embryo transfer and culture

Commonly used reagents in the culture and transfer of embryos are isolated from blood and tissue samples and thus have the potential for chromosomal and or mitochondrial DNA contamination. In this study, we evaluated the results obtained from PCR analysis of bovine trypsin, bovine sera, and bovine albumin precipitates. Bovine sera samples that were tested yielded minor to heavy DNA contamination signals depending on the manufacturer and specific type of sera. Bovine albumin precipitates showed very little DNA contamination or none at all. Bovine trypsin samples yielded moderate DNA contamination signals depending on the ability of the trypsin to be inactivated prior to PCR analysis.

Sex determination and milk protein genotyping of preimplantation stage bovine embryos using multiplex PCR

A method for determining the sex and milk protein genotypes (RFLPs) of preimplantation stage bovine embryos using multiplex polymerase chain reaction (PCR) is described. Day 6 to 7 embryos were micromanipulated to isolate 5 to 6 cells. These cells were then dried in reaction tubes for transport to the laboratory. Subsequently, two sets of PCRs were performed using Y chromosome, k-casein and beta-lactoglobulin gene specific primers, followed by electrophoretic analysis of the PCR products. The presence or absence of the Y chromosome was ascertained in 90 of 92 embryos. Moreover, the k-casein specific fragment was amplified and detected in all these embryos. The PCR products were digested in order to genotype the k-casein gene. In 70% of the embryos, the beta-lactoglobulin specific fragment was amplified, although together with some unspecific fragments.

Restriction fragment length polymorphism in the mitochondrial DNA of cloned cattle

The clonal origin of 4 Holstein bulls was determined by hybridization experiments with 2 different minisatellite probes, and all 4 animals showed identical genomic DNA fingerprints, hence confirming monozygosity. Extra-chromosomal differences were observed among these 4 Holstein bulls. Mitochondrial DNA restriction fragment length polymorphisms with restriction endonucleases Avall and Hhal sites were found, and these polymorphisms can be explained by the loss of a single site for each of these 2 enzymes. Since mitochondrial DNA are maternally transmitted, all 4 bulls would produce genetically equivalent spermatozoa and offspring. The combination of embryo cloning and specific cytoplasmic markers would provide an ideal system for the study of maternal cytoplasmic effects on quantitative traits.

Current status and potential of embryo transfer and reproductive technology in dairy cattle

Significant use of embryo transfer in dairy cattle commenced with the introduction of nonsurgical embryo recovery in the mid-1970s and developed with the use of nonsurgical transfers in the late 1970s. Numbers of registered Holstein calves from embryo transfer doubled yearly through 1980, after which the rate of increase slowed; the total reached nearly 19,000 calves in 1990. However, the efficacy of superovulation procedures and commercial success rates of transferred fresh embryos have not improved the past 10 to 15 yr. Fertilization rates in superovulated donors remain low. Although embryo-splitting techniques were perfected in the early 1980s, they are not used widely. A practical, commercial embryo-sexing procedure remains unavailable. Recent significant improvement is apparent in the technology of ultrasound-guided oocyte collection and in vitro oocyte maturation, fertilization, and embryo culture. In the future, this technology may be used in conjunction with sperm separated by sex with a flow cytometer. Modest numbers of embryo clones have been produced in several commercial programs via nuclear transfer techniques. However, the efficiency of gene transfer experiments involving ova of cattle and other domestic species has been low. Recently, DNA probe technology has begun to provide genotype information for cattle and will ultimately be applied to embryos.

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.