Haploid mouse blastocysts developed from bisected zygotes

Allelic reprogramming of chromatin states in human early embryos

The reprogramming of parental epigenomes in human early embryos remains elusive. To what extent the characteristics of parental epigenomes are conserved between humans and mice is currently unknown. Here, we mapped parental haploid epigenomes using human parthenogenetic and androgenetic embryos. Human embryos have a larger portion of genome with parentally specific epigenetic states than mouse embryos. The allelic patterns of epigenetic states for orthologous regions are not conserved between humans and mice. Nevertheless, it is conserved that maternal DNA methylation and paternal H3K27me3 are associated with the repression of two alleles in humans and mice. In addition, for DNA-methylation-dependent imprinting, we report 19 novel imprinted genes and their associated germline differentially methylated regions. Unlike in mice, H3K27me3-dependent imprinting is not observed in human early embryos. Collectively, allele-specific epigenomic reprogramming is different in humans and mice.

Human zygotic genome activation is initiated from paternal genome

Although parental genomes undergo extensive epigenetic reprogramming to be equalized after fertilization, whether they play different roles in human zygotic genome activation (ZGA) remains unknown. Here, we mapped parental transcriptomes by using human parthenogenetic (PG) and androgenetic (AG) embryos during ZGA. Our data show that human ZGA is launched at the 8-cell stage in AG and bi-parental embryos, but at the morula stage in PG embryos. In contrast, mouse ZGA occurs at the same stage in PG and AG embryos. Mechanistically, primate-specific ZNF675 with AG-specific expression plays a role in human ZGA initiated from paternal genome at the 8-cell stage. AG-specifically expressed LSM1 is also critical for human maternal RNA degradation (MRD) and ZGA. The allelic expressions of ZNF675 and LSM1 are associated with their allelically epigenetic states. Notably, the paternally specific expressions of ZNF675 and LSM1 are also observed in diploid embryos. Collectively, human ZGA is initiated from paternal genome.

Dysregulated Gene Expression of Imprinted and X-Linked Genes: A Link to Poor Development of Bovine Haploid Androgenetic Embryos

Mammalian uniparental embryos are efficient models for genome imprinting research and allow studies on the contribution of the paternal and maternal genomes to early embryonic development. In this study, we analyzed different methods for production of bovine haploid androgenetic embryos (hAE) to elucidate the causes behind their poor developmental potential. Results indicate that hAE can be efficiently generated by using intracytoplasmic sperm injection and oocyte enucleation at telophase II. Although androgenetic haploidy does not disturb early development up to around the 8-cell stage, androgenetic development is disturbed after the time of zygote genome activation and hAE that reach the morula stage are less capable to reach the blastocyst stage of development. Karyotypic comparisons to parthenogenetic- and ICSI-derived embryos excluded chromosomal segregation errors as causes of the developmental constraints of hAE. However, analysis of gene expression indicated abnormal levels of transcripts for key long non-coding RNAs involved in X chromosome inactivation and genomic imprinting of the KCNQ1 locus, suggesting an association with X chromosome and some imprinted loci. Moreover, transcript levels of methyltransferase 3B were significantly downregulated, suggesting potential anomalies in hAE establishing de novo methylation. Finally, the methylation status of imprinted control regions for XIST and KCNQ1OT1 genes remained hypomethylated in hAE at the morula and blastocyst stages, confirming their origin from spermatozoa. Thus, our results exclude micromanipulation and chromosomal abnormalities as major factors disturbing the normal development of bovine haploid androgenotes. In addition, although the cause of the arrest remains unclear, we have shown that the inefficient development of haploid androgenetic bovine embryos to develop to the blastocyst stage is associated with abnormal expression of key factors involved in X chromosome activity and genomic imprinting.

The milestone of genetic screening: Mammalian haploid cells

Mammalian haploid cells provide insights into multiple genetics approaches as have been proved by advances in homozygous phenotypes and function as gametes. Recent achievements make ploidy of mammalian haploid cells stable and improve the developmental efficiency of embryos derived from mammalian haploid cells intracytoplasmic microinjection, which promise great potentials for using mammalian haploid cells in forward and reverse genetic screening. In this review, we introduce breakthroughs of mammalian haploid cells involving in mechanisms of self-diploidization, forward genetics for various targeting genes and imprinted genes related development.

Haploid pluripotent stem cells: twofold benefits with half the effort in genetic screening and reproduction

Haploid pluripotent stem cells, which are capable of self-renewal and differentiation into other cell types with only one set of chromosomes, have been established in several species from haploid embryos. Compared with diploid embryonic stem cells (ESCs), haploid embryonic stem cells (haESCs) are smaller in size, have a prolonged metaphase, and undergo self-doubling during culture. The monoallelic expression of haESCs provides great convenience for recessive inheritance research. Genetically modified haESCs also provide benefits in replacement of the gamete genomes, which not only facilitates the study of the function of imprinted genes but also potentially removes barriers to same-sex reproduction. In this review, we focus on strategies for obtaining haESCs and their potential applications in genetic screening, genomic imprinting, and unisexual reproduction.

Technical advances contribute to the study of genomic imprinting

Genomic imprinting in mammals was discovered over 30 years ago through elegant embryological and genetic experiments in mice. Imprinted genes show a monoallelic and parent of origin-specific expression pattern; the development of techniques that can distinguish between expression from maternal and paternal chromosomes in mice, combined with high-throughput strategies, has allowed for identification of many more imprinted genes, most of which are conserved in humans. Undoubtedly, technical progress has greatly promoted progress in the field of genomic imprinting. Here, we summarize the techniques used to discover imprinted genes, identify new imprinted genes, define imprinting regulation mechanisms, and study imprinting functions.

Current advances in haploid stem cells

Diploidy is the typical genomic mode in all mammals. Haploid stem cells are artificial cell lines experimentally derived in vitro in the form of different types of stem cells, which combine the characteristics of haploidy with a broad developmental potential and open the possibility to uncover biological mysteries at a genomic scale. To date, a multitude of haploid stem cell types from mouse, rat, monkey and humans have been derived, as more are in development. They have been applied in high-throughput genetic screens and mammalian assisted reproduction. Here, we review the generation, unique properties and broad applications of these remarkable cells.

Self-diploidization of human haploid parthenogenetic embryos through the Rho pathway regulates endomitosis and failed cytokinesis

A diploid genome is necessary for normal mammalian development, thus haploid parthenogenetic embryos undergo frequent self-diploidization during preimplantation development; however, the underlying mechanism is unclear. In this study, time-lapse recording revealed that human haploid parthenotes (HPs) undergo self-diploidization via failed cytokinesis (FC) and endomitosis (EM). The frequencies of FC/EM were significantly higher in HPs than in normal fertilized embryos (26.3% vs. 1.6%, P < 0.01; 19.7% vs. 0, P < 0.01), and above 90% of FC/EM occurred at the first cell cycle in HPs. Fluorescent in situ hybridization of chromosome 16,18 and X in HPs identified diploid recovery after the appearance of FC/EM, and FC/EM HPs showed improved blastocyst formation compared with non-FC/EM HPs (18.8% and 40.0% vs. 15.4%, P > 0.05). In 66.7% of the 1-cell stage HPs, furrow ingression was not observed during the time for normal cleavage, and both immunostaining and gene expression analysis of 1-cell stage HPs revealed the absence or down-regulation of several key genes of the Rho pathway, which regulates cytomitosis. Our results suggested that the major mechanism for self-diploidization is Rho pathway inhibition leading to FC/EM in the first cell cycle, and fine-tuning of this signalling pathway may help to generate stable haploid embryos for stem cell biology studies.

Generation and application of mammalian haploid embryonic stem cells

Haploid cells contain one set of chromosomes and are amenable for genetic analyses. In mammals, haploidy exists only in gametes. An intriguing question is whether haploid cells can be derived from gametes. Recently, by application of haploid cell enrichment using fluorescence-activated cell sorting, stable haploid embryonic stem cells (haESCs) have been successfully derived from oocyte-derived parthenogenetic and sperm-derived androgenetic embryos from several species. Whilst both parthenogenetic and androgenetic (AG)-haESCs enable whole-genome genetic screening at the cellular level, such as screening of drug resistance or disease-related genes, AG-haESCs, after intracytoplasmic injection into oocytes, can also be used to produce alive semi-cloned mice. Nevertheless, one major drawback associated with wild-type AG-haESCs is the very low birth rate of healthy semi-cloned mice. Of interest, after inhibiting the expression of two paternally imprinted genes (H19 and Gtl2) in AG-haESCs by removal of their differentially DNA methylated regions, double-knockout AG-haESCs can efficiently and stably support the generation of healthy semi-cloned pups. Importantly, double-knockout AG-haESCs are feasible for multiple genetic manipulations, followed by efficient generation of semi-cloned mice carrying multiple genetic traits; thus they could be used to validate candidate loci that have been identified in genome-wide association studies of multigenic diseases by generation of mouse models carrying multiple alterations. Of note, by combining a CRISPR-Cas9 library and double-knockout AG-haESCs, semi-cloned mice carrying different mutant genes can be efficiently generated in one step, enabling functional mutagenic screening in mice. HaESCs, therefore, provide a powerful tool for genetic analyses in mammals at both the cellular and organismal levels.

Androgenetic development of X- and Y-chromosome bearing haploid rainbow trout embryos

Haploid fish embryos are important in studies regarding role of the recessive traits during early ontogeny. In fish species with the male heterogamety, androgenetic haploid embryos might be also useful tool in studies concerning role of the sex chromosomes during an embryonic development. Morphologically differentiated X and Y chromosomes have been found in a limited number of fish species including rainbow trout (Oncorhynchus mykiss Walbaum 1792). To evaluate role of the sex chromosomes during rainbow trout embryonic development, survival of the androgenetic haploids in the presence of X or Y sex chromosomes has been examined. Androgenetic haploid rainbow trout were produced by fertilization of X-irradiated eggs with spermatozoa derived from the normal males (XY) and neomales, that is, sex-reversed females (XX) to produce X- and Y-bearing haploids, and all X-bearing haploids, respectively. Survival rates of the androgenetic progenies of normal males and neomales examined during embryogenesis and at hatching did not differ significantly. However, all haploids died within next few days after hatching. Cytogenetic analysis of the androgenetic embryos confirmed their haploid status. Moreover, apart from the intact paternal chromosomes, residues of the irradiated maternal chromosomes observed as chromosome fragments were identified in some of the haploids. Provided results suggested that rainbow trout X and Y chromosomes despite morphological and genetic differences are at the early stage of differentiation and still share genetic information responsible for the proper embryonic development.

Genome Editing Using Mammalian Haploid Cells

Haploid cells are useful for studying gene functions because disruption of a single allele can cause loss-of-function phenotypes. Recent success in generating haploid embryonic stem cells (ESCs) in mice, rats, and monkeys provides a new platform for simple genetic manipulation of the mammalian genome. Use of haploid ESCs enhances the genome-editing potential of the CRISPR/Cas system. For example, CRISPR/Cas was used in haploid ESCs to generate multiple knockouts and large deletions at high efficiency. In addition, genome-wide screening is facilitated by haploid cell lines containing gene knockout libraries.

Haploid mouse embryonic stem cells: rapid genetic screening and germline transmission

Most animal genomes are diploid, and mammalian development depends on specific adaptations that have evolved secondary to diploidy. Genomic imprinting and dosage compensation restrict haploid development to early embryos. Recently, haploid mammalian development has been reinvestigated since the establishment of haploid embryonic stem cells (ESCs) from mouse embryos. Haploid cells possess one copy of each gene, facilitating the generation of loss-of-function mutations in a single step. Recessive mutations can then be assessed in forward genetic screens. Applications of haploid mammalian cell systems in screens have been illustrated in several recent publications. Haploid ESCs are characterized by a wide developmental potential and can contribute to chimeric embryos and mice. Different strategies for introducing genetic modifications from haploid ESCs into the mouse germline have been further developed. Haploid ESCs therefore introduce new possibilities in mammalian genetics and could offer an unprecedented tool for genome exploration in the future.

Development and imprinted gene expression in uniparental preimplantation mouse embryos in vitro

Increasing numbers of reports show that imprinted genes play a crucial role in fetal development, and uniparental embryos, which possess two paternally or two maternally derived pronuclei, are excellent tools for investigating the biological significance of imprinted genes. In the present study, to examine the in vitro developmental ability and expression pattern of eight imprinted genes in uniparental embryos, we produced androgenones, gynogenones, and parthenogenones using enucleation. Our data confirmed the previously observed restriction in haploid androgenetic development potential and first indicated that diploid androgenetic embryos were arrested in the 3/4-cell stage. Some imprinted genes were expressed in androgenetic, gynogenetic, and parthenogenetic blastocysts, suggesting that they were unable to maintain their imprinted expression status in uniparental embryos and that both paternal and maternal alleles are required for the specific expression of some imprinted genes.

Karyotype characterization of in vivo- and in vitro-derived porcine parthenogenetic cell lines

Mammalian haploid cell lines provide useful tools for both genetic studies and transgenic animal production. To derive porcine haploid cells, three sets of experiments were conducted. First, genomes of blastomeres from 8-cell to 16-cell porcine parthenogenetically activated (PA) embryos were examined by chromosome spread analysis. An intact haploid genome was maintained by 48.15% of blastomeres. Based on this result, two major approaches for amplifying the haploid cell population were tested. First, embryonic stem-like (ES-like) cells were cultured from PA blastocyst stage embryos, and second, fetal fibroblasts from implanted day 30 PA fetuses were cultured. A total of six ES-like cell lines were derived from PA blastocysts. No chromosome spread with exactly 19 chromosomes (the normal haploid complement) was found. Four cell lines showed a tendency to develop to polyploidy (more than 38 chromosomes). The karyotypes of the fetal fibroblasts showed different abnormalities. Cells with 19–38 chromosomes were the predominant karyotype (59.48–60.91%). The diploid cells were the second most observed karyotype (16.17%–22.73%). Although a low percentage (3.45–8.33%) of cells with 19 chromosomes were detected in 18.52% of the fetus-derived cell lines, these cells were not authentic haploid cells since they exhibited random losses or gains of some chromosomes. The haploid fibroblasts were not efficiently enriched via flow cytometry sorting. On the contrary, the diploid cells were efficiently enriched. The enriched parthenogenetic diploid cells showed normal karyotypes and expressed paternally imprinted genes at extremely low levels. We concluded that only a limited number of authentic haploid cells could be obtained from porcine cleavage-stage parthenogenetic embryos. Unlike mouse, the karyotype of porcine PA embryo-derived haploid cells is not stable, long-term culture of parthenogenetic embryos, either in vivo or in vitro, resulted in abnormal karyotypes. The porcine PA embryo-derived diploid fibroblasts enriched from sorting might be candidate cells for paternally imprinted gene research.

Haploid animal cells

Haploid genetics holds great promise for understanding genome evolution and function. Much of the work on haploid genetics has previously been limited to microbes, but possibilities now extend to animal species, including mammals. Whereas haploid animals were described decades ago, only very recent advances in culture techniques have facilitated haploid embryonic stem cell derivation in mammals. This article examines the potential use of haploid cells and puts haploid animal cells into a historical and biological context. Application of haploid cells in genetic screening holds promise for advancing the genetic exploration of mammalian genomes.

Haploid embryonic stem cells serve as a new tool for mammalian genetic study

In mammals, all somatic cells carry two sets of chromosomes while haploids are restricted only to gametes and are occasionally found in tumors with genome instability. Mammalian haploid embryonic stem (ES) cells have recently been established successfully in mice and monkeys, from either parthenogenetic or androgenetic haploid embryos. These haploid ES cells maintain haploidy and stable growth during extensive in vitro culture, express pluripotent markers, and possess the ability to differentiate into all three germ layers in vitro and in vivo. The mouse haploid ES cells can also contribute to germlines of chimeras. Moreover, the mouse androgenetic haploid ES cells can produce fertile progenies after intracytoplasmic injection into mature oocytes, and the mouse parthenogenetic haploid ES cells can also achieve this by substitution of the maternal genome, albeit at a lower efficiency. These distinct features of mammalian haploid ES cells empower themselves not only as a valuable tool for genetic screening at a cellular level, but also as a new tool for genome-modified animal production and genetic studies at the animal level. Here we review the current progress on mammalian haploid ES cell research, describe in detail their characteristics, and discuss their potential applications. These achievements may provide a new but powerful tool for mammalian genetic studies, and may also shed light on the some interesting questions regarding genome ploidy maintenance and genomic imprinting.

Analysis of imprinted gene expression and implantation in haploid androgenetic mouse embryos

The successful development of mammalian embryos requires both parental genomes. Nuclear transfer techniques have been adapted to generate uniparental embryos, which possess two sets of paternal or maternal genomes. These embryos fail to develop to term because of abnormal imprinted gene expression, which is not regulated by Mendelian inheritance. Uniparental embryos provide us with an important model to investigate imprinted gene function and ontogenesis. To evaluate the pre- and post-developmental ability of haploid androgenetic mouse embryos, and to analyse the expression of imprinted genes Igf2r, Asb4 and Mest in haploid androgenetic/gynogenetic blastocysts, we produced the haploid mouse embryos using the enucleation technique, examined their development at 6.5 dpc and quantified gene expression by quantitative real-time PCR. The results demonstrated that the developmental potential of haploid embryos was severely impaired and revealed that the haploid androgenones could induce the deciduas reaction, but failed to retain a live foetus at 6.5 dpc. Expression of imprinted genes Igf2r and Asb4 was unregulated in haploid androgenetic/gynogenetic blastocysts.

Haploid genomes illustrate epigenetic constraints and gene dosage effects in mammals

Sequencing projects have revealed the information of many animal genomes and thereby enabled the exploration of genome evolution. Insights into how genomes have been repeatedly modified provide a basis for understanding evolutionary innovation and the ever increasing complexity of animal developmental programs. Animal genomes are diploid in most cases, suggesting that redundant information in two copies of the genome increases evolutionary fitness. Genomes are well adapted to a diploid state. Changes of ploidy can be accommodated early in development but they rarely permit successful development into adulthood. In mammals, epigenetic mechanisms including imprinting and X inactivation restrict haploid development. These restrictions are relaxed in an early phase of development suggesting that dosage regulation appears less critical. Here we review the recent literature on haploid genomes and dosage effects and try to embed recent findings in an evolutionary perspective.

Cloned sheep blastocysts derived from oocytes enucleated manually using a pulled pasteur pipette

The potential applications of a simplified method of somatic cell nuclear transfer (SCNT) that is improved in both efficiency and throughput is considerable. Technically, a major step of SCNT is to produce large pools of enucleated oocytes (cytoplasts) efficiently, a process that requires considerable micromanipulation skill and expensive equipment. Here, we have developed an efficient and high-throughput method of manual oocyte enucleation using a simple device, a pulled Pasteur pipette, that can be connected to standard zona-free method of embryo reconstitution. Common Pasteur pipettes were pulled on a flame to produce finely drawn pipettes with inner diameters approximately less than half the oocyte diameter (∼50-60 μm), and slightly larger than cytoplasmic protrusion (∼20-30 μm) that was induced after demecolcine treatment of MII-stage oocytes. Oocyte manipulation was performed under a stereomicroscope by either bisecting the oocyte into two approximately equal demioocytes (blind manual enucleation), or by positioning the oocytes so that the cytoplasmic extrusion that contains the MII chromosome mass is removed with the minimum amount of cytoplasm (oriented manual enucleation). The survival rate of the manually enucleated oocytes was 81.4-91.5%, comparable to standard zona-free method of oocyte enucleation (>95%). A total of 80-120 oocytes could be enucleated in 10 min, which was considerably higher than standard zona-free enucleation method. In vitro development rates of cloned embryos derived from manually enucleated cytoplasts with varying cytoplasmic volumes (50%, 95%, and 100%) was comparable, and embryonic developmental rates of the two latter groups were at least as good as standard zona-free method. The manual method of oocyte enucleation described here can be learned and mastered for simple, fast, and cheap production of cloned embryos with comparable efficiency to other available methods.

Free-hand bisection of mouse oocytes and embryos

Mouse oocytes and zygotes are semitransparent and large cells approximately 80 μm in diameter. Bisection is one of the easiest ways for performing micromanipulations on such cells. It allows living sister halves or smaller fragments to be obtained, which can be cultured and observed for long periods of time. Bisection can be used for different kinds of experiments such as analysis of nucleo-cytoplasmic interactions, the relationship between different cellular structures or between different parts of embryos, eventually for analyzing the developmental potential of embryonic fragments. Oocyte or embryo halves can be examined by immunostaining, by measuring different cellular functions and by Western blot and genetic analysis (e.g., RT-PCR). Here we describe a detailed protocol for the free-hand bisection of mouse zona pellucida-free oocytes and embryos on an agar layer using a glass needle.

Fusion and development rates of single blastomere pairs of mouse two- and four-cell embryos using the electrofusion method

The present study was undertaken to find suitable conditions for blastomere fusion of mouse two- and four-cell embryos using the electrofusion method to simplify the nuclear transfer procedure. Single blastomeres of ICR and F1 (C57BL/6J x CBA/N) two-cell embryos or ICR four-cell embryos and F1 two-cell embryos were paired and treated with electric stimulus under different fusion conditions. Two hours after electrofusion treatment, the fused blastomere pairs were encapsulated in alginate gel and cultured for 96 hours to observe their developmental potential. When the single blastomere pairs of two-cell embryos were exposed to electric pulses of 1.0, 1.5 and 2.0 kV/cm for 30, 60 and 90 mu sec, high fusion rates were obtained (84.6 to 100%). However, when two-cell blastomere were paired with four-cell blastomere and then treated under the same conditions, the fusion rates (27.5 to 87.5%) were lower than that of single blastomere pairs of two-cell embryos regardless of the duration and strength of the d.c. pulses. The blastocyst developmental rate after in vitro culture of the fused blastomere pairs of two-cell embryos using the above electrofusion conditions was high (81.8 to 100%). Lower blastocyst developmental rates were obtained on the fused blastomere pairs of two- and four-cell embryos (46.4 to 76.2%). Based on the results of this study, a pulse duration of 60 mu sec and a pulse strength of 1.0kV/cm were the most suitable conditions for single blastomere pair fusion of two-cell or two- and four-cell embryos. The study further showed that alginate gel is a good substitute for zonae pellucidae for encapsulating zona-free embryos.

Generation of genetically modified mice by oocyte injection of androgenetic haploid embryonic stem cells

Haploid cells are amenable for genetic analysis. Recent success in the derivation of mouse haploid embryonic stem cells (haESCs) via parthenogenesis has enabled genetic screening in mammalian cells. However, successful generation of live animals from these haESCs, which is needed to extend the genetic analysis to the organism level, has not been achieved. Here, we report the derivation of haESCs from androgenetic blastocysts. These cells, designated as AG-haESCs, partially maintain paternal imprints, express classical ESC pluripotency markers, and contribute to various tissues, including the germline, upon injection into diploid blastocysts. Strikingly, live mice can be obtained upon injection of AG-haESCs into MII oocytes, and these mice bear haESC-carried genetic traits and develop into fertile adults. Furthermore, gene targeting via homologous recombination is feasible in the AG-haESCs. Our results demonstrate that AG-haESCs can be used as a genetically tractable fertilization agent for the production of live animals via injection into oocytes.

Developmental competence of porcine parthenogenetic embryos relative to embryonic chromosomal abnormalities

Parthenogenetically activated (PA) embryos exhibit delayed development, a lower blastocyst rate, and less successful development in vitro compared to in vitro fertilized (IVF) embryos. To investigate the possible mechanisms for unsuccessful parthenogenetic development, this study analyzed the chromosome abnormalities and developmental potential of porcine PA embryos. Mature oocytes were electrically activated and cultured in Porcine Zygote Medium-3 (PZM3) supplemented with 3 mg/ml BSA for 6, 7, or 8 days. The percentage of PA blastocysts was lower than that of IVF embryos on days 6 and 7 (16.4 +/- 7.4 vs. 28.7 +/- 3.7; 10.9 +/- 2.8 vs. 21.5 +/- 4.7, P < 0.05; respectively), and the PA blastocysts had significantly fewer nuclei than IVF blastocysts (23.2 +/- 1.8 vs. 29.7 +/- 0.8; 29.7 +/- 3.3 vs. 32.0 +/- 2.4, P < 0.05). The percentage of abnormal PA embryos (including embryos with condensed nuclei, arrested embryos and fragmented embryos) was higher than that of IVF embryos (PA: 52.9 +/- 12.8 vs. 16.4 +/- 7.4 on day 6), and increased with culture time (71.9 +/- 12.1 vs. 10.9 +/- 2.8. on day 7,and 75.0 +/- 22.6 vs. 12.1 +/- 2.3 on day 8, P < 0.05). The Day-6 PA blastocysts (n = 147) were divided into three classes according to the total number of nuclei (<20, 20-39, >40) and into three groups according to the morphological diameter (<150, 150-180, >180 microm). Of the haploid blastocysts, 56.1% had less than 20 nuclei, and 71.5% were less than 150 microm in diameter. Of all (114) blastocysts suitable for analysis, 55.5% displayed chromosomal abnormalities. Among chromosomal abnormalities in PA blastocysts, haploid blastocysts were most prevalent (43.6%), while polyploidy (4.4%) and mixoploidy (7.7%) embryos were less prevalent. Chromosomal abnormalities of porcine PA embryos might contribute to a higher rate of abnormal embryonic development. We suggest that a careful consideration should be given when using the blastocysts with smaller size, and establishing the optimum culture condition for PA embryos development in vitro.

Blastocyst formation, karyotype, and mitochondrial DNA of interspecies embryos derived from nuclear transfer of human cord fibroblasts into enucleated bovine oocytes

OBJECTIVE

To establish an interspecies somatic cell nuclear transfer (iSCNT) technique for deriving blastocysts having human chromosome complements without sacrificing human oocytes.

DESIGN

Prospective, randomized study undertaken in vitro.

SETTING

University-affiliated hospital and laboratory, Seoul National University.

PATIENT(S)

Postpartum women with natural spontaneous vaginal delivery.

INTERVENTION(S)

Human cord fibroblasts were retrieved from five postpartum women from whom informed consent was obtained. After subculture and cryopreservation, serum-starved cells were transferred into enucleated bovine oocytes.

MAIN OUTCOME MEASURE(S)

Embryo development, karyotype, and the presence of mitochondrial DNA (mtDNA).

RESULT(S)

A total 1,742 oocytes were provided for iSCNT and results showed that both fibroblast batch and reconstruction method significantly affected iSCNT outcome. An iSCNT using a single DC pulse of 1.9-2.1 kV/cm for 20 microseconds yielded better rates of fusion (30%-56%) and cleavage (36%) than the other iSCNT protocols. Four to 9% interspecies embryos produced with the optimized method developed to morulae or blastocysts after cultured in a serum-free medium. Results from karyotyping demonstrated that 56% of interspecies embryos evaluated had human chromosome complements. In polymerase chain reaction (PCR) analysis of a single embryo, both human and bovine mtDNAs were detected until the 16-cell stage, whereas only the bovine mtDNA was found beyond the morula stage.

CONCLUSION(S)

An iSCNT using human cord fibroblasts and bovine oocytes can yield blastocysts and the results of karyotyping and mtDNA analysis confirmed the feasibility of the iSCNT technique.

Comparison of gene expression during preimplantation development between diploid and haploid mouse embryos

Haploid development is a normal part of the life cycle for some animals, but it has not been observed in mammals. Studies in mice have revealed that the preimplantation developmental potential of haploid embryos is significantly impaired relative to diploid embryos. The reasons for the severely limited developmental potential of haploid embryos in mammals have not been discerned. To examine the effects of haploid development on gene expression, and in particular on X-linked gene expression, and to evaluate to what degree newer techniques of producing and culturing such embryos might affect developmental potential, haploid and diploid parthenogenetic and androgenetic embryos were produced and reevaluated for developmental potential, genomic integrity, and relative expression levels of specific autosomal and X-linked gene transcripts. Our data confirm the previously observed restriction in haploid developmental potential, eliminate chromosomal abnormalities as a major factor in this restriction, and reveal subtle alterations in gene expression. Haploid parthenogenones display only very subtle alterations in the expression of most mRNAs but a consistent elevation in X-linked Bex1 mRNA expression. Haploid androgenones seem to lack repression of the Pgk1 gene that is seen in diploid androgenones, but this may reflect ongoing loss of those haploid androgenones that experience X chromosome inactivation. The significance and possible explanations for these differences are discussed.

Animal and vegetal poles of the mouse egg predict the polarity of the embryonic axis, yet are nonessential for development

Recent studies suggest early (preimplantation) events might be important in the development of polarity in mammalian embryos. We report here lineage tracing experiments with green fluorescent protein showing that cells located either near to or opposite the polar body at the 8-cell stage of the mouse embryo retain their same relative positions in the blastocyst. Thus they come to lie on either end of an axis of symmetry of the blastocyst that has recently been shown to correlate with the anterior-posterior axis of the postimplantation embryo (see R. J. Weber, R. A. Pedersen, F. Wianny, M. J. Evans and M. Zernicka-Goetz (1999). Development 126, 5591–5598). The embryonic axes of the mouse can therefore be related to the position of the polar body at the 8-cell stage, and by implication, to the animal-vegetal axis of the zygote. However, we also show that chimeric embryos constructed from 2-cell stage blastomeres from which the animal or the vegetal poles have been removed can develop into normal blastocysts and become fertile adult mice. This is also true of chimeras composed of animal or vegetal pole cells derived through normal cleavage to the 8-cell stage. We discuss that although polarity of the postimplantation embryo can be traced back to the 8-cell stage and in turn to the organisation of the egg, it is not absolutely fixed by this time.

Early development of mouse embryos null mutant for the cyclin A2 gene occurs in the absence of maternally derived cyclin A2 gene products

Progression through the mammalian cell cycle is regulated by the sequential activation and inactivation of the cyclin-dependent kinases. In adult cells, cyclin A2-dependent kinases are required for entry into S and M phases, completion of S phase, and centrosome duplication. However, mouse embryos lacking the cyclin A2 gene nonetheless complete preimplantation development, but die soon after implantation. In this report, we investigated whether a contribution of maternal cyclin A2 mRNA and protein to early embryonic cell cycles might explain these conflicting observations. Our data show that a maternal stock of cyclin A2 mRNA is present in the oocyte and persists after fertilization until the second mitotic cell cycle, when it is degraded to undetectable levels coincident with transcriptional activation of the zygotic genome. A portion of maternally derived cyclin A2 protein is stable during the first mitosis and persists in the cytoplasm, but is completely degraded at the second mitosis. The ability of cyclin A2-null mutants to develop normally from the four-cell to the postimplantation stage in the absence of detectable cyclin A2 gene product indicates therefore that cyclin A2 is dispensable for cellular progression during the preimplantation nongrowth period of mouse embryo development.

Cytogenetic study of in vitro-derived bovine embryos

A cytogenetic study of early bovine embryos (2-16 blastomeres) produced in vitro was conducted to determine the incidence of embryos carrying chromosome anomalies. The embryos were produced from immature oocytes matured in vitro and fertilized by sperm prepared using the Percoll density gradient method. Slides were prepared according to an 'air drying' technique and the chromosomal complement of embryos was studied by Giemsa-staining. Approximately 57% of prepared embryos were suitable for analysis. The results revealed that 18% of cytogenetically analysed embryos presented chromosomal anomalies, including haploidy (8%), aneuploidy (2%) and polyploidy (8%). Our results were compared to the results of other studies in cattle and other domestic animals.

Electroactivation of rabbit oocytes in an hypotonic pulsing medium and parthenogenetic in vitro development without cytochalasin B-diploidizing pretreatment

We investigated the electroactivation frequencies, type of activation and in vitro development of rabbit oocytes. In Experiment 1, activation (8 pulses, 12 min apart, 60 microsec, 0.6 kVcm(-1)) was performed by altering osmolarity (190 vs. 320 mOsm kg(-1)) and Ca++ concentration (10, 60 or 100 microM) in mannitol pulsing media. More oocytes were activated in hypotonic pulsing medium, regardless of Ca++ concentration (96 to 100%). Both haploid and diploid parthenogenetic embryos developed to compacted morulae (57 to 92% and 63 to 100%, respectively) regardless of the activation treatment; however, the blastocyst rates were more variable (0 to 74% and 0 to 73%, respectively). In Experiment 2, the effects of pulse duration (30 or 60 microsec) and number of applied pulses (4, 8 or 12) under hypotonic conditions were studied. Activation frequencies were the lowest after four 30 microsec-pulses (58 vs. 88 to 100%, respectively). A lower haploid frequency was obtained when more than four 30 or 60 microsec-pulses were applied (from 67 to 25% and 83 to 0%, respectively). Increasing the number of 60-microsec pulses improved the compacted morula rate of haploid and diploid oocytes (47 to 83% and 57 to 96%, respectively). Overall, haploid development to morulae and blastocysts was lower than diploid development to these stages (69 and 25% vs. 74 and 44%, respectively).

Fertile offspring derived from mammalian eggs lacking either animal or vegetal poles

In all animals so far tested, removing either pole of the undivided egg prevents normal development: embryos may arrest early, lack organs, or the adults may be sterile. These experiments have shown that spatial patterning of the egg is of utmost importance for subsequent development. However, the significance of spatial patterning in mammalian eggs is still controversial. To test the importance of egg polarity in the mouse a substantial amount of material either from the animal (polar body-associated) or the vegetal (opposite) pole of the fertilised egg was removed. One pole of the egg was cut away manually with a glass needle and the eggs were allowed to develop in vitro. Both kinds of surgical operation permit the development of blastocysts, which, after transfer to the uteri of pseudo-pregnant foster mothers, can produce viable offspring. Furthermore, these develop into fertile adult mice. I conclude that mouse eggs have no essential components that are localised uniquely to the animal or the vegetal pole and, therefore, do not rely for their axial development on maternal determinants that are so localised in the fertilised egg. Thus the mammalian egg appears to be very unusual in the animal kingdom in that it establishes the embryonic axes after the zygote has begun development.

Developmental ability of mouse late 2-cell stage blastomeres fused to chemically enucleated oocytes in vitro

The effects of different concentrations of etoposide and cycloheximide (ETO-CHXM), used for chemical enucleation of mouse oocytes, on polar body extrusion and chromatin expulsion were tested. The developmental ability of blastomeres of late 2-cell stage embryos fused to chemically enucleated oocytes of different ages or cytoplasts from different sources was also examined in vitro. Metaphase I oocytes cultured in different concentrations of ETO-CHXM (10-50 micrograms/ml/each) extruded polar bodies at rates similar to those cultured without ETO-CHXM (58.5-65.9% and 64.6%, respectively). However, low percent of the oocytes (1.7-6.2%) expressed signs of meiotic perturbation, which was manifested by blebbing of the cytoplasmic membrane and extrusion of two or more polar body-like fragments. Twenty-three percent of the chemically enucleated oocytes cultured in ETO-CHXM-free medium spontaneously fused to their polar bodies. The rates of total chromatin expulsion were similar when ETO-CHXM concentrations were 36 and 50 micrograms/ml (93.5 and 98%, respectively). The results also showed that the cleavage rates of reconstituted embryos were significantly (P < 0.001) affected by the age of the chemically enucleated oocytes. Cytoplasts of bisected oocytes that matured in vivo supported the development of 31.7% of the reconstituted embryos to the blastocyst stage. However, both cytoplasts of chemically enucleated oocytes and in vitro matured oocytes did not support the development to the blastocyst stage. A high percentage (85.5%) of the reconstituted embryos with chemically enucleated recipients displayed abnormality of the metaphase plate. These results suggest that concentrations of etoposide between 36 and 50 micrograms/ml are optimum for enucleation of mouse oocytes. Furthermore, increasing the age or reducing the cytoplasmic volume of the chemically enucleated oocytes did not improve the development of the reconstituted embryos to the blastocyst stage.

Cleavage rate of haploid and diploid parthenogenetic mouse embryos during the preimplantation period

The lack of a paternal genome in parthenogenetic embryos clearly limits their postimplantation development, but apparently not their preimplantation development, since morphologically normal blastocysts can be formed. The cleavage rate of these embryos during the preimplantation period gives a better indication of the influence of their genetic constitution than blastocyst formation. Conflicting results from previous studies prompted us to use a more suitable method of following the development of haploid and diploid parthenogenetic embryos during this period. Two classes of parthenogenetic embryos were analysed following the activation of oocytes in vitro with 7% ethanol: 1) single pronuclear (haploid) embryos and 2) two pronuclear (diploid) embryos. Each group was then transferred separately during the afternoon to the oviducts of recipients on the 1st day of pseudopregnancy. Control (diploid) 1-cell fertilised embryos were isolated in the morning of finding a vaginal plug, and transferred to pseudopregnant recipients at approximately the same time of the day as the parthenogenones. Embryos were isolated at various times after the HCG injection to induce ovulation, from each of the three groups studied. Total cell counts were made of each embryo, and the log mean values were plotted against time. The gradient of the lines indicated that 1) the cell doubling time of the diploid parthenogenones was 12.25 +/- 0.34 h, and was not significantly different from the value obtained for the control group (12.74 +/- 1.17 h), and that 2) the cell doubling time of the haploid parthenogenones (15.25 +/- 0.99 h) was slower than that of the diploid parthenogenones and the control diploid group.(ABSTRACT TRUNCATED AT 250 WORDS)

Development of bovine in vitro-matured follicular oocytes activated with ethanol

Bovine follicular oocytes cultured in vitro for 30 hours were activated by ethanol and then the developmental ability of the oocytes was assessed. When the activated oocytes were treated with cytochalasin B at concentrations of 0, 1.25, 2.5, 5 and 7.5 mug/ml, the percentages of oocytes having two pronuclei were 8, 18, 54, 66 and 60%, respectively. The percentage of the activated oocytes with two pronuclei also increased with increased exposure time to cytochalasin B. When the activated oocytes were treated with cytochalasin B (5mug/ml) for 10 hours, 20% of them cleaved after 36 hours and 5% of them developed to the eight-cell stage after 60 hours of culture. These results indicated that bovine in vitro matured oocytes can be activated by ethanol and develop to the eight-cell stage following treatment with cytochalasin B.

Development of reconstituted mouse embryos produced from bisected and electrofused pronuclear-stage embryos

The present study was designed to investigate the in vitro and in vivo development potential of reconstituted mouse embryos produced by bisection and electrofusion of pronuclear stage embryos (PN-E). Pronuclear-stage ICR and F1 (C57BL x CBA) strain mouse embryos were bisected manually with a fine glass needle under the dissecting microscope to produce karyoplasts (KP) and cytoplasts (CP). The KP of ICR PN-E and CP of F1 PN-E (KP: ICR + CP:F1) or the KP of F1 PN-E and CP of F1 PN-E (KP:F1 + CP:ICR) were attached using phytohemagglutinin-P (PHA-P) and then electrofused. High fusion rates of the KP and CP of PN-E were obtained (93.5%). The fused embryos were encapsulated in alginate gel and cultured for 72 or 96 hours. The cleavage rates of reconstituted embryos were also high (98.8%). Developmental rates to the blastocyst stage in vitro for the 96-hour culture of reconstituted embryos were 68.9% (KP:ICR + CP:F1) and 78.4% (KP:F1 + CP:ICR). Furthermore, the developmental ability of reconstituted embryos in vivo was investigated, and some live young were obtained (KP:ICR + CP:F1, 7.5% and KP:F1 + CP:ICR, 10.8%). In this study, it was confirmed that reconstituted embryos produced by bisection and electrofusion of pronuclear stage embryos were able to develop into blastocysts in vitro and into live young in vivo.

In vitro survival of cells derived from isodiploid uniparental half embryos of the mouse after aggregation with normal embryos

Fertilized mouse eggs, heterozygous for two allozymes of glucose phosphate isomerase (GPI) were bisected, and the resulting half eggs were diploidized with cytochalasin B. After separate aggregation with normal embryos carrying a third allozyme of GPI, the resulting chimaeras were kept in culture up to 10 days. The majority grew out on the culture dish during this period. By GPI analysis, 7.7% of the embryos were found to be chimaeric. Both types of uniparental cells, from gynogenetic and from androgenetic half eggs, were capable of surviving in chimaeras in vitro. These results are comparable with published data obtained by using uniparental embryos generated by micromanipulation.

Microdissection of the mouse egg

A rapid and efficient method for microdissection of the mouse egg is described. The dissection is carried out in hanging drops of medium surrounded by heavy liquid paraffin oil at room temperature. Eggs are first deformed into a cylindrical shape and then dissected at a predetermined site with a glass needle on a Leitz micromanipulator. The survival rate of the dissected fragments is 75-90% and between 20 and 30 eggs can be dissected in an hour. Development of the dissected eggs is at least as good as that described after other types of manipulation. Cytoplasts and karyoplasts of various sizes can be prepared, as well as gynogenetic and androgenetic eggs with different amounts of cytoplasm. This procedure may help to examine nuclear-cytoplasmic interactions in eggs reconstituted from a variety of fragments.