Evidence for selection against tetraploid cells in tetraploid<-->diploid mouse chimaeras before the late blastocyst stage

Tetraploid (4n) cells do not contribute equally to all tissues of midgestation mouse chimaeras and mosaics. Our previous studies of early blastocysts showed that 4n cells are preferentially allocated to the mural trophectoderm of the early blastocyst and this may contribute to the restricted distribution pattern seen at later stages. In this study of later-stage blastocysts we found evidence for selection against 4n cells. The contribution of 4n cells to 4n<-->2n chimaeric blastocysts decreased between E3.5 and E4.5 days, whereas the composition of 2n<-->2n controls changed little over this period. These results suggest that, prior to implantation, blastocysts have already lost some tetraploid cells from their embryonic and extra-embryonic lineages due to a combination of preferential allocation of 4n cells to the mural trophectoderm and selection against 4n cells throughout the embryo.     

The effects of cell size and ploidy on cell allocation in mouse chimaeric blastocysts

In a previous study of mouse tetraploid<-->diploid chimaeric blastocysts, tetraploid cells were found to be more abundant in the trophectoderm than the inner cell mass (ICM) and more abundant in the mural trophectoderm than the polar trophectoderm. This non-random allocation of tetraploid cells to different regions of the chimaeric blastocyst may contribute to the restricted tissue distribution seen in post-implantation stage tetraploid<-->diploid chimaeras. However, the tetraploid and diploid embryos that were aggregated together differed in several respects: the tetraploid embryos had fewer cells and these cells were bigger and differed in ploidy. Each of these factors might underlie a non-random allocation of tetraploid cells to the chimaeric blastocyst. A combination of micromanipulation and electrofusion was used to produce two series of chimaeras that distinguished between the effects of cell size and ploidy on the allocation of cells to different tissues in chimaeric blastocysts. When aggregated cells differed in cell size but not ploidy, the derivatives of the larger cell contributed significantly more to the mural trophectoderm and polar trophectoderm than the ICM. When aggregated cells differed in ploidy but not cell size, the tetraploid cells contributed significantly more to the mural trophectoderm than the ICM. In both experiments the contributions to the polar trophectoderm tended to be intermediate between those of the mural trophectoderm and ICM. These experiments show that both the larger size and increased ploidy of tetraploid cells could have contributed to the non-random cell distribution that was observed in a previous study of tetraploid<-->diploid chimaeric blastocysts.     

Generation and Developmental Characteristics of Porcine Tetraploid Embryos and Tetraploid]diploid Chimeric Embryos

The aim of this study was to optimize electrofusion conditions for generating porcine tetraploid(4n)embryos and produce tetraploid/diploid(4n/2n)chimeric embryos.Different electric feld intensities were tested and 2 direct current(DC)pulses of 0.9 kV/cm for 30 ls was selected as the optimum condition for electrofusion of 2-cell embryos to produce 4n embryos.The fusion rate of 2-cell embryos and the development rate to blastocyst of presumably 4n embryos,reached85.4%and 28.5%,respectively.68.18%of the fused embryos were found to be 4n as demonstrated by fluorescent in situ hybridization(FISH).Although the number of blastomeres in 4n blastocysts was signifcantly lower than in 2n blastocysts(P<0.05),there was no signifcant difference in developmental rates of blastocysts between 2n and 4n embryos(P>0.05),suggesting that the blastocyst forming capacity in 4n embryos is similar to those in 2n embryos.Moreover,4n/2n chimeric embryos were obtained by aggregation of 4n and 2n embryos.We found that the developmental rate and cell number of blastocysts of 4-cell(4n)/4-cell(2n)chimeric embryos were signifcantly higher than those of 2-cell(4n)/4-cell(2n),4-cell(4n)/8-cell(2n),4-cell(4n)/2-cell(2n)chimeric embryos(P<0.05).Consistent with mouse chimeras,the majority of 4n cells contribute to the trophectoderm(TE),while the 2n cells are mainly present in the inner cell mass(ICM)of porcine4n/2n chimeric embryos.Our study established a feasible and effcient approach to produce porcine4n embryos and 4n/2n chimeric embryos.     

Completely ES Cell-Derived Mice Produced by Tetraploid Complementation Using Inner Cell Mass (ICM) Deficient Blastocysts

Tetraploid complementation is often used to produce mice from embryonic stem cells (ESCs) by injection of diploid (2n) ESCs into tetraploid (4n) blastocysts (ESC-derived mice). This method has also been adapted to mouse cloning and the derivation of mice from induced pluripotent stem (iPS) cells. However, the underlying mechanism(s) of the tetraploid complementation remains largely unclear. Whether this approach can give rise to completely ES cell-derived mice is an open question, and has not yet been unambiguously proven. Here, we show that mouse tetraploid blastocysts can be classified into two groups, according to the presence or absence of an inner cell mass (ICM). We designate these as type a (presence of ICM at blastocyst stage) or type b (absence of ICM). ESC lines were readily derived from type a blastocysts, suggesting that these embryos retain a pluripotent epiblast compartment; whereas the type b blastocysts possessed very low potential to give rise to ESC lines, suggesting that they had lost the pluripotent epiblast. When the type a blastocysts were used for tetraploid complementation, some of the resulting mice were found to be 2n/4n chimeric; whereas when type b blastocysts were used as hosts, the resulting mice are all completely ES cell-derived, with the newborn pups displaying a high frequency of abdominal hernias. Our results demonstrate that completely ES cell-derived mice can be produced using ICM-deficient 4n blastocysts, and provide evidence that the exclusion of tetraploid cells from the fetus in 2n/4n chimeras can largely be attributed to the formation of ICM-deficient blastocysts.     

In vitro development and cell allocation following aggregation of split embryos with tetraploid or developmentally asynchronous blastomeres in rhesus monkeys

Production of genetically identical pairs of monkeys would have tremendous implications for biomedical research, particularly immunological studies and vaccine trials. Specific aims of this study were to (1) determine whether aggregation of embryos split into halves or quarters with equal numbers of either developmentally asynchronous or tetraploid blastomeres would enhance their developmental potential in vitro and increase total cell numbers in resulting blastocysts, and (2) determine the allocation of tetraploid and developmentally asynchronous blastomeres in resulting blastocysts. Results demonstrated that development into blastocysts was greater (p < 0.05) for embryos split into pairs (39.8%) than for those split into quadruplet sets (17.4%) and similar (p > 0.05) to that of nonmanipulated controls (59.6%). Creation of chimeras from aggregation of a single 4-cell and four 16-cell stage blastomeres resulted in blastocyst formation (69.2%) similar to that of nonmanipulated control embryos (66.9%). However, neither development nor total cell numbers in resulting blastocysts differed between aggregate chimeras and those split into quadruplet sets at the 16-cell stage. Blastocysts resulting from the aggregate chimeras were derived strictly from the 16-cell stage blastomeres, with complete exclusion of the 4-cell stage blastomeres. Aggregation of split embryos with equal numbers of tetraploid blastomeres doubled (p < 0.05) both the proportion developing into blastocysts and the total cell numbers in resulting blastocysts. Tetraploid blastomeres were allocated to both the inner cell mass and trophectoderm of resulting blastocysts. In conclusion, due to exclusion of the less advanced cells, aggregation of developmentally asynchronous blastomeres did not improve the developmental competence or cell numbers of split rhesus embryos. Reconstitution of split embryos with equal numbers of tetraploid blastomeres enhanced their developmental potential and cell numbers in resulting blastocysts. However, tetraploid blastomeres were allocated to both the inner cell mass and trophectoderm.     

The roles of FGF and MAP kinase signaling in the segregation of the epiblast and hypoblast cell lineages in bovine and human embryos

At the blastocyst stage of mammalian pre-implantation development, three distinct cell lineages have formed: trophectoderm, hypoblast (primitive endoderm) and epiblast. The inability to derive embryonic stem (ES) cell lines in a variety of species suggests divergence between species in the cell signaling pathways involved in early lineage specification. In mouse, segregation of the primitive endoderm lineage from the pluripotent epiblast lineage depends on FGF/MAP kinase signaling, but it is unknown whether this is conserved between species. Here we examined segregation of the hypoblast and epiblast lineages in bovine and human embryos through modulation of FGF/MAP kinase signaling pathways in cultured embryos. Bovine embryos stimulated with FGF4 and heparin form inner cell masses (ICMs) composed entirely of hypoblast cells and no epiblast cells. Inhibition of MEK in bovine embryos results in ICMs with increased epiblast precursors and decreased hypoblast precursors. The hypoblast precursor population was not fully ablated upon MEK inhibition, indicating that other factors are involved in hypoblast differentiation. Surprisingly, inhibition of FGF signaling upstream of MEK had no effects on epiblast and hypoblast precursor numbers in bovine development, suggesting that GATA6 expression is not dependent on FGF signaling. By contrast, in human embryos, inhibition of MEK did not significantly alter epiblast or hypoblast precursor numbers despite the ability of the MEK inhibitor to potently inhibit ERK phosphorylation in human ES cells. These findings demonstrate intrinsic differences in early mammalian development in the role of the FGF/MAP kinase signaling pathways in governing hypoblast versus epiblast lineage choices.     

Chimeras between parthenogenetic or androgenetic blastomeres and normal embryos: allocation to the inner cell mass and trophectoderm

A series of chimeras was generated by injecting single normal, parthenogenetic, or androgenetic blastomeres carrying transgenic markers under the zona pellucida of nontransgenic eight-cell embryos. These chimeras were cultured to the blastocyst stage and sectioned, and the transgenic component was detected by in situ hybridization. No statistically significant difference was found among the normal, parthenogenetic, and androgenetic chimeras in the number of chimeric blastocysts with a transgenic contribution to the inner cell mass (ICM), the trophectoderm, or both the ICM and trophectoderm. Since androgenetic and parthenogenetic cells were present in chimeras at a high frequency in both the ICM and trophectoderm at the blastocyst stage, but not in similar chimeras at late gastrulation, these cells must not respond normally to developmental signals subsequent to blastocyst formation and prior to late gastrulation.     

Individual blastomeres of 16- and 32-cell mouse embryos are able to develop into foetuses and mice

Cell and developmental studies have clarified how, by the time of implantation, the mouse embryo forms three primary cell lineages: epiblast (EPI), primitive endoderm (PE), and trophectoderm (TE). However, it still remains unknown when cells allocated to these three lineages become determined in their developmental fate. To address this question, we studied the developmental potential of single blastomeres derived from 16- and 32-cell stage embryos and supported by carrier, tetraploid blastomeres. We were able to generate singletons, identical twins, triplets, and quadruplets from individual inner and outer cells of 16-cell embryos and, sporadically, foetuses from single cells of 32-cell embryos. The use of embryos constitutively expressing GFP as the donors of single diploid blastomeres enabled us to identify their cell progeny in the constructed 2n↔4n blastocysts. We showed that the descendants of donor blastomeres were able to locate themselves in all three first cell lineages, i.e., epiblast, primitive endoderm, and trophectoderm. In addition, the application of Cdx2 and Gata4 markers for trophectoderm and primitive endoderm, respectively, showed that the expression of these two genes in the descendants of donor blastomeres was either down- or up-regulated, depending on the cell lineage they happened to occupy. Thus, our results demonstrate that up to the early blastocysts stage, the destiny of at least some blastomeres, although they have begun to express markers of different lineage, is still labile.     

Ultrastructural and karyotypic examination of in vitro produced bovine embryos developed in the sheep uterus

This study examined whether development of bovine in vitro produced (IVP) blastocysts in the sheep uterus resulted in morphologically and karyotypically normal elongation stage bovine blastocysts. Seven day IVP bovine blastocysts, resulting from either in vitro maturation and fertilization, nuclear transfer (NT), or parthenogenic activation, were surgically transferred at the blastocyst stage into sheep uteri. Sheep were sacrificed after 7-9 days, and blastocysts were flushed from their uteri. One of each kind of IVP bovine blastocyst was recovered from sheep uteri for analysis by transmission electron microscopy, and nine NT blastocysts were used to establish cell cultures that were analysed for chromosome complement. TEM analysis of in vivo-derived elongation stage bovine and ovine blastocysts was done for comparative purposes. Most ultrastructural features of the 13-19 day blastocysts were similar to earlier stage blastocysts except that distinct alternative mitochondrial morphologies were found between epiblast and trophectoderm cells. Monociliated cells, presumably nodal cells, were observed in the bovine epiblast and hypoblast, and retrovirus-like particles were elaborated by cells in these same areas. Development in the sheep uterus of IVP bovine blastocysts resulted in the presence of crystalloid bodies in the trophectoderm cells, and apoptotic and necrotic cells were observed in the epiblast tissue. Thus, in vivo incubation in the sheep uterus allowed nearly normal development to the elongated blastocyst stage and may be useful for assessment of NT bovine blastocyst developmental competence. Cell cultures derived from the NT blastocysts had normal chromosome complements suggesting that activation by ionomycin and 6-dimethyl-aminopurine did not cause detrimental changes in ploidy in those blastocysts that developed.     

Cell fate in the polar trophectoderm of mouse blastocysts as studied by microinjection of cell lineage tracers

Horseradish peroxidase (HRP), together with Fast Green or rhodamine-conjugated dextran (RDX), was used as an intracellular lineage tracer to determine cell fate in the polar trophectoderm of 3.5-day-old mouse embryos. In HRP-injected midstage (approximately 39-cell) and expanded (approximately 65-cell) blastocysts incubated for 24 hr, the central polar trophectoderm cell was displaced from the embryonic pole an average of 20 micron (5% of blastocyst circumference) and 29 micron (6% of blastocyst circumference), respectively. Expanded blastocysts injected with HRP + Fast Green and incubated for 24 hr or with HRP + RDX and incubated for 48 hr showed a displacement of 24 micron (4% of blastocyst circumference) and 88 micron (14% of blastocyst circumference), respectively. Up to 10 HRP-positive trophectoderm cells were observed among embryos incubated for 48 hr, indicating that in those cases, the labeled progenitor cells had divided at least three times. Our observations show that the central polar trophectoderm cell divides in the plane of the trophectoderm in expanded blastocysts and, along with its descendants, is displaced toward the mural trophectoderm. The systematic tandem displacement of labeled cells and their descendants toward the abembryonic pole suggests the presence of a proliferative area at the embryonic pole of the blastocyst. Large shifts in inner cell mass (ICM) position in relation to the trophectoderm do not occur during blastocyst expansion. Furthermore, random movements within the polar trophectoderm population do not account for the replacement of labeled cells by unlabeled polar trophectoderm cells. Rather, we propose the hypothesis that the ICM contributes these replacement cells to the polar trophectoderm during blastocyst expansion.     

Epigenetic regulation of gene expression in porcine epiblast, hypoblast, trophectoderm and epiblast-derived neural progenitor cells

After fertilization, lineage specification is governed by a complicated molecular network in which permissiveness and repression of expression of pluripotency- and differentiation-associated genes are regulated by epigenetic modifications. DNA methylation operates as a very stable repressive mark in this process. In this study, we investigated the relationship between DNA methylation and expression of pluripotency-associated genes (OCT4, NANOG and SOX2), a trophectoderm (TE)-specific gene (ELF5), and genes associated with neural differentiation (SOX2 and VIMENTIN) in porcine Day 10 (E10) epiblast, hypoblast, and TE as well as in epiblast-derived neural progenitor cells (NPCs). We found that OCT4, NANOG, and SOX2 were highly expressed in the epiblast and hypoblast, while VIMENTIN was only highly expressed in the epiblast. Moreover, low expression of OCT4, NANOG, SOX2 and VIMENTIN was noted in the TE. Most CpG sites of OCT4, NANOG, SOX2 and VIMENTIN displayed low methylation levels in the epiblast and hypoblast and, strikingly, also in the TE. Hence, the expression patterns of these genes were not directly related to levels of DNA methylation in the TE in contrast to the situation in the mouse. In contrast, ELF5 was exclusively expressed in the TE and was correspondingly hypomethylated in this tissue. In NPCs, we observed down-regulation of NANOG and OCT4 expression, which correlated with hypermethylation of their promoters, whereas VIMENTIN displayed up-regulation in accordance with hypomethylation of its promoter. In conclusion, DNA methylation is an inconsistently operating epigenetic mechanism in porcine E10 blastocysts, whereas in porcine epiblast-derived NPCs, expression of pluripotency-associated and differentiation genes appear to be regulated by this modification.     

Cell lineage specific distribution of H3K27 trimethylation accumulation in an in vitro model for human implantation

Female mammals inactivate one of their two X-chromosomes to compensate for the difference in gene-dosage with males that have just one X-chromosome. X-chromosome inactivation is initiated by the expression of the non-coding RNA Xist, which coats the X-chromosome in cis and triggers gene silencing. In early mouse development the paternal X-chromosome is initially inactivated in all cells of cleavage stage embryos (imprinted X-inactivation) followed by reactivation of the inactivated paternal X-chromosome exclusively in the epiblast precursors of blastocysts, resulting temporarily in the presence of two active X-chromosomes in this specific lineage. Shortly thereafter, epiblast cells randomly inactivate either the maternal or the paternal X-chromosome. XCI is accompanied by the accumulation of histone 3 lysine 27 trimethylation (H3K27me3) marks on the condensed X-chromosome. It is still poorly understood how XCI is regulated during early human development. Here we have investigated lineage development and the distribution of H3K27me3 foci in human embryos derived from an in-vitro model for human implantation. In this system, embryos are co-cultured on decidualized endometrial stromal cells up to day 8, which allows the culture period to be extended for an additional two days. We demonstrate that after the co-culture period, the inner cell masses have relatively high cell numbers and that the GATA4-positive hypoblast lineage and OCT4-positive epiblast cell lineage in these embryos have segregated. H3K27me3 foci were observed in ～25% of the trophectoderm cells and in ～7.5% of the hypoblast cells, but not in epiblast cells. In contrast with day 8 embryos derived from the co-cultures, foci of H3K27me3 were not observed in embryos at day 5 of development derived from regular IVF-cultures. These findings indicate that the dynamics of H3K27me3 accumulation on the X-chromosome in human development is regulated in a lineage specific fashion.     

Differential expression of ezrin/radixin/moesin (ERM) and ERM-associated adhesion molecules in the blastocyst and uterus suggests their functions during implantation

Development of the blastocyst to implantation competency, differentiation of the uterus to the receptive state, and a cross talk between the implantation-competent blastocyst and the uterine luminal epithelium are all essential to the process of implantation. In the present investigation, we examined the possibility for a potential cross talk between the blastocyst and uterus involving the ezrin/radixin/moesin (ERM) proteins and ERM-associated cytoskeletal cross-linker proteins CD43, CD44, ICAM-1, and ICAM-2. In normal Day 4 blastocysts and after rendering dormant blastocysts to implantation-competent by estrogen in vivo (activated), the outer surface of mural trophectoderm cells showed much higher levels of radixin as compared to those in the polar trophectoderm cells, inner cell mass (ICM), and primitive endoderm. In contrast, ezrin was present on both the mural and the polar trophectoderm cell surfaces of normal Day 4 and activated blastocysts at higher intensity than dormant blastocysts. A distinct localization was noted in the primitive endoderm of dormant blastocysts that was not apparent in activated or normal Day 4 blastocysts. The expression of moesin was modestly higher at the mural trophectoderm of implantation-competent blastocysts, while the localization appeared to be present primarily on the polar trophectoderm cell surface of Day 4 blastocysts. The localization of ERM-associated adhesion molecules CD43, CD44, and ICAM-2 was more intense in the implantation-competent blastocysts compared with the dormant blastocysts. However, while CD44 was present both in the trophectoderm and in ICM, CD43 and ICAM-2 were localized primarily to the trophectoderm. The signal for ICAM-1 was very intense in the ICM but was modest in the trophectoderm. No significant changes in fluorescence intensity were noted between activated and dormant blastocysts. In the receptive uterus on Day 4 of pregnancy, ERM proteins were localized to the uterine epithelium, while on Day 5 the localization, especially of radixin and moesin, extended to the stroma surrounding the implantation chamber. With respect to ERM-associated adhesion molecules, while CD44 and ICAM-1 were exclusively localized in the stroma on Day 4, CD43 and ICAM-2 were localized to the epithelium. On Day 5, the localization of CD44 and ICAM-1 became highly concentrated in the antimesometrial stroma of the implantation chamber. The localization of CD43 and ICAM-2 remained mostly epithelial, although some stromal localization of CD43 was noted on Day 5. These results suggest that differential expression and distribution of ERM proteins and ERM-associated adhesion molecules are involved in the construction of the cellular architecture necessary for blastocyst activation and uterine receptivity leading to successful implantation.     

Trophectoderm cell subpopulations in the periimplantation mouse blastocyst

Trophectoderm of the preimplantation mouse blastocyst is composed of two cell subpopulations relative to their proximity to the inner cell mass. The polar trophectoderm overlying the inner cell mass proliferates to form the ectoplacental cone, and the mural trophectoderm endoreplicates and gives rise to giant cells. We examined specific differences in the two trophectoderm cell populations using a lectin (Dolichos biflorus) to detect cell surface characteristics and a simple sugar (D-Gal) to detect differences in incorporation. During the first day of delayed implantation, the mural trophectoderm presented twice as many lectin binding sites as did the polar trophectoderm. The mural trophectoderm of both nondelaying and delayed implantation blastocysts showed a greater rate of incorporation of the tritiated sugar by presenting more reduced silver grains in radioautograms. These results indicate that the mural trophectoderm and polar trophectoderm are two distinct cell types in the periimplantation blastocyst.     

Sex differentiation and germ cell production in chimeric pigs produced by inner cell mass injection into blastocysts

This study aimed at collecting background knowledge for chimeric pig production. We analyzed the genetic sex of the chimeric pigs in relation to phenotypic sex as well as to functional germ cell formation. Chimeric pigs were produced by injecting Day 6 or Day 7 inner cell mass (ICM) cells into Day 6 blastocysts. Approximately 20% of the piglets born from the injected blastocysts showed overt coat color chimerism regardless of the embryonic stage of donor cells. The male:female sex ratio was 7:2 and 6:1 in the chimeras derived from Day 6 and Day 7 ICM cells, respectively, showing an obvious bias toward males. When XX donor cells were injected into XY blastocysts at the same embryonic stage, the phenotypic sex of the resulting chimera was male with no germ-line cells formed from the donor cell lineage. On the other hand, when the donor was XY and the recipient blastocyst was XX, the phenotypic sex of the chimera was male, and germ-line cells were derived only from the donor cells. The combination of XY donor cells and XY blastocysts produced some chimeras in which the donor cell lineage did not contribute to germ-line formation even when it appeared in coat color. When the embryonic stage of the donor was advanced by 1 day in the XY-XY combination, 100% of the germ-line cells of the chimeras were derived from the donor cell lineage. These data showed that characteristics of sex differentiation and germ cell formation in chimeric pigs are similar to those in chimeric mice.     

Comparison of male chimeric mice generated from microinjection of JM8.N4 embryonic stem cells into C57BL/6J and C57BL/6NTac blastocysts

To identify ways to improve the efficiency of generating chimeric mice via microinjection of blastocysts with ES cells, we compared production and performance of ES-cell derived chimeric mice using blastocysts from two closely related and commonly used sub-strains of C57BL/6. Chimeras were produced by injection of the same JM8.N4 (C57BL/6NTac) derived ES cell line into blastocysts of mixed sex from either C57BL/6J (B6J) or C57BL/6NTac (B6NTac) mice. Similar efficiency of production and sex-conversion of chimeric animals was observed with each strain of blastocyst. However, B6J chimeric males had fewer developmental abnormalities involving urogenital and reproductive tissues (1/12, 8?%) compared with B6NTac chimeric males (7/9, 78?%). The low sample size did not permit determination of statistical significance for many parameters. However, in each category analyzed the B6J-derived chimeric males performed as well, or better, than their B6NTac counterparts. Twelve of 14 (86?%) B6J male chimeras were fertile compared with 6 of 11 (55?%) B6NTac male chimeras. Ten of 12 (83?%) B6J chimeric males sired more than 1 litter compared with only 3 of 6 (50?%) B6NTac chimeras. B6J male chimeras produced more litters per productive mating (3.42?±?1.73, n?=?12) compared to B6NTac chimeras (2.17?±?1.33, n?=?6). Finally, a greater ratio of germline transmitting chimeric males was obtained using B6J blastocysts (9/14; 64?%) compared with chimeras produced using B6NTac blastocysts (4/11; 36?%). Use of B6J host blastocysts for microinjection of ES cells may offer improvements over blastocysts from B6NTac and possibly other sub-strains of C57BL/6 mice.     

Epiblast isolation by a new four stage method (peeling) from whole bovine cloned blastocysts

We have established a new 4 stage epiblast isolation method from whole bovine cloned blastocysts without using immunosurgery. The new “peeling” method consists of dissolution of the zona pellucida (first stage), elimination of mural trophoblast (second stage), isolation of primitive endoderm and epiblast from polar trophoblast (third stage), and isolation of epiblast from primitive endoderm (fourth stage). The bovine cloned blastocyst consists of 4 different types of cells showing abundant alkaline phosphatase activity. The epiblast origin of isolated cells was confirmed by in vitro differentiation of isolated cells to tubulin β3-positive neurons and by embryoid body formation. The bovine cloned blastocyst origin of isolated epiblasts was confirmed by microsatellite analysis and mitochondrial DNA sequencing analysis. This new method might accelerate establishment of somatic cell nuclear transfer derived embryonic stem cell lines from bovine and other mammals.