Expression of murine early embryonic antigens, SSEA-1 and antigenic determinant of EMA-1, in embryos and ovarian follicles of a teleost medaka (Oryzias latipes)

Stage-specific embryonic antigen-1 (SSEA-1) and the antigenic determinant of monoclonal antibody EMA-1 are expressed in a stage-specific manner in mouse early embryos. To study whether these antigens generally exist in fish, expression of the antigens was examined in embryos, ovarian follicles, and adult tissues of a teleost medaka (Oryzias latipes), using immunohistochemical techniques. In 1-cell-stage embryos, these carbohydrate antigens were found in numerous cytoplasmic granules in the blastodisc and the cortical cytoplasm. These granules gradually decreased in number as the embryos developed. In 4-cell-stage embryos, the antigens appeared on the cleavage planes and were located on the cleavage planes within the blastoderm in the following cleavage stages. In blastula-stage embryos, the expression was ubiquitously found on the cell surface of blastomeres. At the mid-gastrula stage, the antigens were restricted to the enveloping layer, yolk syncytial layer, and cortical cytoplasm, but were rarely found in deep cells that contribute to formation of the embryonic body. In later-stage embryos and adult fish, the antigens were located in various tissues. In ovarian follicles, the antigens were found in granules of oocytes and granulosa cells. These observations were basically consistent with those in mice; however, expression in 1-cell-stage embryos and ovarian follicles has not been observed in mice. This unexpected finding suggests that the antigens are produced in granulosa cells and transferred to 1-cell-stage embryos via oocytes, and that the antigens involved in the early developmental process are maternally prepared in teleosts.     

Ribonucleoprotein localization in mouse oocytes

RNA molecules rarely function alone in cells. For most RNAs, their function requires formation of various ribonucleoprotein (RNP) complexes. For example, mRNP composition can determine mRNA localization, translational repression, level of translation or mRNA stability. RNPs are usually studied by biochemical methods. However, biochemical approaches are unsuitable for some model systems, such as mammalian oocytes and early embryos, due to the small amounts that can be obtained for experimental analysis. In such cases, microscopic techniques are often used to learn about RNPs. Here, we present a review of immunostaining, fluorescence in situ hybridization with subcellular resolution and a combination of both, with emphasis on the mouse oocyte and early embryos models. Application of these techniques to whole-mount fixed oocytes and early embryos can provide information about RNP composition and localization with three-dimensional resolution.     

Evaluation of developmental competence of vitrified-warmed early cleavage stage embryos and their application for chimeric mouse production.

The developmental competence of in vitro cultured embryos vitrified-warmed at an early cleavage stage (2- or 4, 8-cell stage) was examined by both direct transfer into recipient animals and after in vitro manipulation for chimeric mice production using embryonic stem (ES) cells. Vitrified-warmed embryos transferred at the morulae and blastocyst stages showed fetus development comparable to control embryos, although blastocyst development of vitrified-warmed embryos was significantly slower than that of controls. When vitrified-warmed early cleavage stage embryos were used for chimeric mouse production using ES cells, 1 to 10% of the injected or aggregated embryos developed into chimeric neonates and germ-line chimeric mice were obtained from all ES cell lines. This study indicates that embryos developed in vitro from vitrified-warmed embryos have equivalent competence with unvitrified embryos irrespective of stage of vitrification and that these vitrified-warmed embryos maintain adequate viability even after in vitro manipulation such as aggregation and microinjection with ES cells.     

A simple DNA extraction and rapid specific identification technique for single cells and early embryos of two breeds of Bos taurus

In the process of nuclear transfer (NT), different cytoplasm from a donor cell and a recipient oocyte are mixed. However, it is unclear what effect the donor cytoplasm has upon the dedifferentiation of donor nuclei in enucleated ooplasm and upon subsequent production of live cloned offspring. Mitochondria are component parts of cytoplasm so the detection of mitochondrial DNA is helpful to reveal changes of donor cytoplasm in the NT reconstructed embryos. In this study, the experiments were designed to develop efficient DNA extraction techniques and specific primer pairs for mitochondrial DNA of Holstein and Chinese Yellow breeds in order to identify the changes of donor cytoplasm in early stage embryos. Firstly, by adding Triton X-100 and Taq DNA polymerase reaction buffer to the DNA extraction mixture, DNA was rapidly isolated from single diploid cells, single oocytes, early stage embryos and from single hairs. Secondly, two specific primer pairs for the two breeds were designed to detect the cytoplasmic DNA in a different amount of single cells and in early stage embryos. The results show that two specific fragments were successfully amplified from single somatic cells, single oocytes, parthenogenetic embryos and from NT reconstructed embryos. As a result, the techniques provide a powerful tool for studying the developmental mechanism in NT reconstructed embryos.     

In vitro exposure of the early mouse embryo to Herpes Simplex Virus-1 strain Wal

The causes of early embryonic death are not clearly understood, but one of them may be viral infection. To study the interaction between the virus and the undifierentiated cell, early mouse embryos in morula and blastocyst stages were exposed to Herpes Simplex Virus-1 WAL (HSV-1 WAL). In one group of a total of 167 embryos, 108 were exposed to HSV-1 WAL; the rest were maintained as controls. After washing in culture medium, these embryos were cultured on a murine fetal fibroblast monolayer for viral isolation. None showed cytopathic effects in the susceptible monolayer. In a second group, 140 empryos were exposed and 106 were maintained as controls. These embryos were cultured without a monolayer or washing to permit continuous viral contact. Eighty-seven of the exposed embryos and 74 control empryos developed normally 2 to 3 d post hatching with no morpnological differences between the two groups. No statistical differences were observed when the proportion of natched and degenerated embryos was compared. Our results indicated that the cells of early mouse embryos are not susceptible to HSV-1 WAL. We concluded that possibly the susceptibility of empryonic cells to viral agents partially depends on stage of differentiation.     

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.     

Successful use of oviduct epithelial cell coculture for in vitro production of viable red deer (Cervus elaphus) embryos

Techniques for in vitro production (IVP) of viable embryos have been thoroughly developed in several domestic species in view to improve breeding efficiency. When applied to wild life, these techniques may also help the maintenance of biodiversity through amplification of sparse animals offspring and facilitation of genetic material exchange. During the successive steps of IVP, i.e. oocyte in vitro maturation (IVM), fertilization (IVF) and early embryo development (IVD) to the blastocyst stage, gametes and embryos are faced with unusual environment, including oxidative stress, known to be detrimental to their survival. In the present study, starting from methods developed in domestic species, we have adapted IVP to produce viable red deer embryos. In a first experiment, cumulus cells were removed from in vitro matured oocytes either before or after IVF. The presence of cumulus cells during IVF did not affect final cleavage or development rates. In a second experiment, in vitro matured oocytes were fertilized in the presence of cumulus cells and cultured in SOFaaBSA medium alone or in the presence of ovine oviduct epithelial cell (oOEC) monolayer. Whereas, oviduct cells did not improve the cleavage rate, they significantly increased the rate of embryos reaching the blastocyst stage (from 3 to 25% of total oocytes). Ten blastocysts from oOEC coculture were transferred after freezing and thawing to five recipient hinds and gave rise to three pregnancies. The three pregnant hinds gave birth to three live and normal calves.     

Establishment of customized mouse stem cell lines by sequential nuclear transfer

Therapeutic cloning, whereby embryonic stem cells （ESCs） are derived from nuclear transfer （NT） embryos, may play a major role in the new era of regenerative medicine. In this study we established forty nuclear transfer-ESC （NTESC） lines that were derived from NT embryos of different donor cell types or passages. We found that NT-ESCs were capable of forming embryoid bodies. In addition, NT-ESCs expressed pluripotency stem cell markers in vitro and could differentiate into embryonic tissues in vivo. NT embryos from early passage RI donor cells were able to form full term developed pups, whereas those from late passage RI ES donor cells lost the potential for reprogramming that is essential for live birth. We subsequently established sequential NT-RI-ESC lines that were developed from NT blastocyst of late passage R 1 ESC donors. However, these NT-R I-ESC lines, when used as nuclear transfer donors at their early passages, failed to result in live pups. This indicates that the therapeutic cloning process using sequential NT-ESCs may not rescue the developmental deficiencies that resided in previous donor generations.     

In vitro fertilization: analysis of early post-fertilization development using cytological and molecular techniques

Methods have been developed which enable us to obtain in vitro fusion of pairs of sperm and egg cells, and sperm and central cells of angiosperms. Cultured products of such cell fusions develop progressively into zygotes, embryos and fertile plants, and endosperm, respectively. In vitro fusion of isolated gametes allows precisely timed examination of the earliest developmental processes following fertilization. When cultured, in vitro produced zygotes and primary endosperm cells organize themselves independently, and without any requirement for supporting tissues. This technology thus constitutes a unique model system for studies of early stages of zygotic embryogenesis and endosperm development. Following the adaptation of molecular techniques for use with only a few cells, it has proved possible to investigate developmental processes in these systems. This review describes the successful combination of molecular techniques with in vitro fertilization methods, and highlights results obtained with small numbers of reproductive cells isolated by microdissection.     

Cytogenetic analysis of reconstituted one-cell mouse embryos derived from nuclear transfer of fetal male germ cells.

Micromanipulation techniques were used to produce reconstituted one-cell mouse embryos after the fusion of fetal male germ cells 15.5 day post coitum with enucleated secondary oocytes. At this stage of development, male fetal germ cells are arrested at G1 of mitotic interphase. Two distinct populations of germ cells, differing in size and ploidy, were isolated from the genital ridge of a mid-term fetus. Oocytes that had received male germ cells from the population of smaller (mononuclear) germ cells developed as diploid one-cell reconstituted embryos. When the same procedures were used to produce reconstituted one-cell embryos using male fetal germ cells from a population of larger (multinucleate) cells, they exhibited ploidy of either 4x, 6x or 8x at metaphase of the first cell division. Although most reconstituted embryos (90 and 96%) developed to the two-cell stage, the proportion of embryos receiving small germ cells developed to blastocysts was much higher (62%) than that receiving large germ cells (4%). These studies indicate that not all fetal germ cells are diploid before the onset of meiosis and have identified procedures to produce reconstituted embryos from fetal germ cells that do not carry genome or chromosome anomalies.     

Early embryonic cells from in vivo-produced goat embryos transmit the caprine arthritis-encephalitis virus (CAEV)

The aim of this study was to investigate whether cells of early goat embryos isolated from in vivo-fertilized goats interact with the caprine arthritis-encephalitis virus (CAEV) in vitro and whether the embryonic zona pellucida (ZP) protects early embryo cells from CAEV infection. ZP-free and ZP-intact 8-16 cell embryos were inoculated for 2 h with CAEVat the 10(4) tissue culture infectious dose 50 (TCID50)/ml. Infected embryos were incubated for 72 h over feeder monolayer containing caprine oviduct epithelial cells (COECs) and CAEV indicator goat synovial membrane (GSM) cells. Noninoculated ZP-free and ZP-intact embryos were submitted to similar treatments and used as controls. Six days postinoculation, infectious virus assay of the wash fluids of inoculated early goat embryos showed typical CAEV-induced cytopathic effects (CPE) on indicator GSM monolayers, with fluids of the first two washes only. The mixed cell monolayer (COEC + GSM) used as feeder cells for CAEV inoculated ZP-free embryos showed CPE. In contrast, none of the feeder monolayers, used for culture of CAEV inoculated ZP-intact embryos or the noninoculated controls, developed any CPE. CAEV exposure apparently did not interfere with development of ZP-free embryos in vitro during the 72 h study period when compared with untreated controls (34.6 and 36% blastocysts, respectively, P > 0.05). From these results one can conclude that the transmission of infectious molecularly cloned CAEV-pBSCA (plasmid binding site CAEV) by embryonic cells from in vivo-produced embryos at the 8-16 cell stages is possible with ZP-free embryos. The absence of interactions between ZP-intact embryos and CAEV in vitro suggests that the ZP is an efficient protective embryo barrier.     

Ultraviolet irradiation of eggs and blastomere isolation experiments suggest that gastrulation in the direct developing ascidian, Molgula pacifica, requires localized cytoplasmic determinants in the egg and cell signaling beginning at the two-cell stage

Gastrulation in the maximum direct developing ascidian Molgula pacifica is highly modified compared with commonly studied "model" ascidians in that endoderm cells situated in the vegetal pole region do not undergo typical invagination and due to the absence of a typical blastopore the involution of mesoderm cells is highly modified. At the gastrula stage, embryos are comprised of a central cluster of large yolky cells that are surrounded by a single layer of ectoderm cells in which there is only a slight indication of an inward movement of cells at the vegetal pole. As a consequence, these embryos do not form an archenteron. In the present study, ultraviolet (UV) irradiation of fertilized eggs tested the possibility that cortical cytoplasmic factors are required for gastrulation, and blastomere isolation experiments tested the possibility that cell signaling beginning at the two-cell stage may be required for the development of the gastrula. Irradiation of unoriented fertilized eggs with UV light resulted in late cleavage stage embryos that failed to undergo gastrulation. When blastomeres were isolated from two-cell embryos, they developed into late cleavage stage embryos; however, they did not undergo gastrulation and subsequently develop into juveniles. These results suggest that cytoplasmic factors required for gastrulation are localized in the egg cortex, but in contrast to previously studied indirect developers, these factors are not exclusively localized in the vegetal pole region at the first stage of ooplasmic segregation. Furthermore, the inability of embryos derived from blastomeres isolated at the two-cell stage to undergo gastrulation and develop into juveniles suggests that important cell signaling begins as early as the two-cell stage in M. pacifica. These results are discussed in terms of the evolution of maximum direct development in ascidians.     

Differentiation capabilities of human germ cell tumors

It is well known that human germ cell tumors are an excellent model to study not only differentiation capacity of tumor cells but also human normal somatic cell differentiation. A variety of polyclonal and monoclonal antibodies were developed against cell surface antigens of murine embryos and teratocarcinomas. Accumulated data has revealed that these antigens are sequentially expressed on embryonic cells in a well-programmed manner. They have also been shown to be useful markers to investigate somatic cell differentiation in fetal and adult tissue. In humans, however, little is known about the cellular differentiation mechanism in early embryos and whether they could be studied, i.e. whether they occur in human germ cell tumors. In present review, we discussed newly established monoclonal antibodies which were raised from human embryonal carcinoma cells. We have been studying differentiation capacity of human germ cell tumor cells by using these antibodies. Some of these antibodies clearly indicates their usefulness to specify the developmental stage of normal tissue.     

Localized electroporation: a method for targeting expression of genes in avian embryos

Avian embryos are a popular model for cell and developmental biologists. However, analysis of gene function in living embryos has been hampered by difficulties in targeting the expression of exogenous genes. We have developed a method for localized electroporation that overcomes some of the limitations of current techniques. We use a double-barreled suction electrode, backfilled with a solution containing a plasmid-encoding green fluorescent protein (GFP) and a neurophysiological stimulator to electroporate small populations of cells in living embryos. As many as 600 cells express GFP 24-48 h after electroporation. The number of cells that express GFP depends on the number of trains, the pulse frequency and the voltage. Surface epithelial cells and cells deep to the point of electroporation express GFP. No deformities result from electroporations, and neurons, neural crest, head mesenchyme, lens and otic placode cells have been transfected. This method overcomes some of the disadvantages of viral techniques, lipofection and in vivo electroporation. The method will be useful to biologists interested in tracing cell lineage or making genetic mosaic avian embryos.     

Why Eberl is wrong. Reflections on the beginning of personhood

In a paper published in Bioethics, Jason Eberl has argued that early embryos are not persons and should not be granted the status possessed by them. Eberl bases this position upon the following claims: (1) The early embryo has a passive potentiality for development into a person. (2) The early embryo has not established both 'unique genetic identity' and 'ongoing ontological identity', which are necessary conditions for ensoulment. (3) The early embryo has a low probability of developing into a more developed embryo. This paper examines these claims. I argue against (1) that a plausible view is that the early embryo has an active potentiality to grow into a more developed embryo. Against (2), I argue that neither 'unique genetic identity' nor 'ongoing ontological identity' are necessary conditions for ensoulment, and that 'ongoing ontological identity' is established between early embryos and more developed embryos. Against (3), I argue that the fact that the early embryo has a low probability of developing into a more developed embryo, if true, does not warrant the conclusion that the early embryo is not a person. If Eberl is right that the human soul is that which organises the activities of a human being and that ensouled humans are persons, embryos are persons from conception.     

Identification of genes required for cytoplasmic localization in early C. elegans embryos

We have isolated and analyzed eight strict maternal effect mutations identifying four genes, par-1, par-2, par-3, and par-4, required for cytoplasmic localization in early embryos of the nematode C. elegans. Mutations in these genes lead to defects in cleavage patterns, timing of cleavages, and localization of germ line-specific P granules. Four mutations in par-1 and par-4 are fully expressed maternal effect lethal mutations; all embryos from mothers homozygous for these mutations arrest as amorphous masses of differentiated cells but are specifically lacking intestinal cells. Four mutations in par-2, par-3, and par-4 are incompletely expressed maternal effect lethal mutations and are also grandchildless; some embryos from homozygous mothers survive and grow to become infertile adults due to absence of functional germ cells. We propose that all of these defects result from the failure of a maternally encoded system for intracellular localization in early embryos.     

Drosophila segmentation genes and blastoderm cell identities

The formation of the segmentation pattern in Drosophila embryos provides an excellent model for investigating the process of pattern formation in multicellular organisms. Several genes required in an embryo for normal segmentation have been analyzed by classical and molecular genetic and morphological techniques. A detailed consideration of these results suggests that these segmentation genes are combinatorially involved in translating the positional identities of individual cells at an early stage in Drosophila development.     

Development of hamster two-cell embryos in the isolated mouse oviduct in organ culture system

Hamster early two-cell embryos developed to the expanded blastocyst stage within the isolated mouse ampulla maintained in organ culture system. Mouse ampullae isolated at different times after treating the mice with human chorionic gonadotropin (hCG) (0–72 h) or pregnant mare's serum gonadotropin (PMSG) (30–32 h) were flushed with culture medium, and hamster early two-cell embryos were introduced into these ampullae. Mouse ampullae isolated at 14–32 h after hCG injection were more favorable for the development of the embryos than those isolated at 70–72 h. When mouse ampullae were isolated 30–32 h after hCG or PMSG treatment, 39% of the cultured eggs developed, some of them to the expanded blastocyst stage after additional culture for 65–70 h. These results indicate that unknown oviductal factors stimulate the development of hamster early two-cell embryos, and these factors are under the control of hCG or PMSG. In addition, these factors are common to the mouse and hamster.     

Survival of 4-cell mouse embryos derived from in vitro fertilization after ultrarapid freezing and thawing

Four-cell mouse embryos obtained by fertilization in vitro were frozen ultrarapidly, immediately after one-step exposure to a highly concentrated solution (modified VS1) at room temperature, and later thawed in a 37 degrees C waterbath. The proportion of morphologically normal embryos on thawing was 95.7% (198/207), and 83.8% (166/198) of these embryos developed to morulas and early blastocysts after 24 hr in culture. All frozen-thawed embryos that developed to morulas and early blastocysts were transferred to the uterine horns of recipients on day 3 of pseudopregnancy and 47.0% (78/166) of transferred embryos developed to normal young.