Brain and sperm cell surface antigen (NS-4) on preimplantation mouse embryos

Antiserum prepared in rabbit against 4-day-old mouse cerebellum (anti-NS-4 serum) reacts in the complement-mediated cytotoxicity test with unfertilized and fertilized mouse eggs, cleavage stage embryos, and cells of the trophoblast and inner cell mass of the mouse blastocyst. This activity is specifically removed by absorption of antiserum with adult mouse brain and epididymal sperm but not with adult liver, spleen, kidney, and thymocytes. The antiserum reacts most strongly with cells of the trophoblast and inner cell mass and, in order of decreasing reactivity, with four- to eight-cell stage embryos, zygotes, unfertilized eggs, and two-cell stage embryos.     

Isolation of antiSLIP1-reactive boar sperm P68/62 and its binding to mammalian zona pellucida

Single-step purification of boar sperm P68/62 that is cross-reactive with a polyclonal antibody against sulfolipidimmobilizing protein 1 (SLIP1) was achieved by chromatofocusing. This method is useful for obtaining P68/62 in quantity. The two proteins, P68 and P62, were antigenically related, since the antibody generated specifically against the 68-kDa band reacted with both the 68- and 62-kDa bands. Like rat testis SLIP1, purified boar sperm P68/62 bound to sulfogalactosylglycerolipid (SGG) and inhibited sperm-egg binding in a dose-dependent manner when added exogenously to sperm-egg coincubates. This inhibitory effect occurred at the level of the zona pellucida (ZP), and further studies showed that biotinylated boar sperm P68/62 bound to the ZP of unfertilized mouse eggs. Furthermore, biotinylated boar sperm P68/62 bound to isolated ZP of unfertilized eggs from other species, including pig, rat, cat, dog, and human, as well as to ZP of intact fertilized mouse eggs and preimplantation embryos of various developmental stages, although the degree of its binding to the ZP of intact eight-cell embryos, morulae, and blastocysts was much lower than that of fertilized eggs and two-cell embryos. These results suggest that P68/62 of capacitated sperm must act together with other sperm surface proteins/molecules that regulate zona binding specificity within homologous species and in unfertilized eggs. Together with our previous findings, we suggest that rather than being a true ZP receptor, sperm P68/62 may be involved in the initial step of sperm-ZP binding that is adhesive in nature. Mol. Reprod. Dev. 49:203–216, 1998 © 1998 Wiley-Liss, Inc.     

Antibodies to sperm surface antigens and the c-myc proto-oncogene product inhibit early embryonic development in mice.

The effects of antibodies against sperm antigens and the c-myc proto-oncogene product on early embryonic development were investigated in mice. Affinity-purified Fab' antibodies against lithium diiodosalicylate (LIS)-solubilized murine sperm extract and fertilization antigen (FA-1) reduced (p less than 0.01 to p less than 0.001) blastulation rates of in vitro cultured 2-cell murine embryos primarily because of an arrest of development at the morula stage. Similarly, the c-myc monoclonal antibody (mAb) affected early embryonic development in a dose-dependent manner. These effects were specific, since immunoabsorption, with its respective peptide, completely blocked the inhibitory effect of the c-myc mAb. Anti-LIS sperm Fab' identified four protein bands (approx. 36, 29, 24.6, and 17.6 kDa) on Western blots of extracts from unfertilized and fertilized ova, one band (approx. 68 kDa) each on 4-8-cell embryo and morula extracts, and one band (approx. 53 kDa) on blastocyst extracts. Anti-FA-1 Fab' did not react with unfertilized or fertilized ova, but specifically identified two protein bands (approx. 53 and 25.7 kDa) on blots of 2-cell-embryo extract, one band (approx. 25.7 kDa) on morula extract, and one band (approx. 53 kDa) on blastocyst extract. The c-myc mAb did not react with any band corresponding to the c-myc protein on blots of extracts from unfertilized or fertilized ova, 2-cell embryos, 4-8-cell embryos, morulae, or blastocysts. These results suggest that some of the cross-reacting sperm antigens that are expressed during early cleavages, and the product of the c-myc proto-oncogene may have a role in normal early embryonic development.     

Development of single blastomeres from four- and eight-cell mouse embryos fused into the enucleated half of a two-cell embryo

Single blastomeres from four- and eight-cell mouse embryos were fused into the enucleated halves of two-cell embryos, and the ability of these reconstituted embryos to develop in vitro and in vivo was examined. The proportion of these reconstituted embryos developing to blastocysts was 74% (60/81) when four-cell embryo blastomeres were used as nuclei donors and 31% (57/182) when eight-cell embryo blastomeres were used. Eight complete sets of the quadruplet-reconstituted embryos developed to blastocysts, and five live young (9%, 5/57) were obtained after transfer; however, none of the live young were clones. Although when using blastomeres from eight-cell embryos no complete set of eight developed to blastocysts, sextuplets were obtained. The blastocysts, however, failed to produce live young after transfer. In assessing the outgrowths, it was found that 43% of those derived from reconstituted embryos using blastomeres from four-cell embryos had an inner cell mass (ICM); however, outgrowths derived from reconstituted embryos using blastomeres from eight-cell embryos lacked an ICM. These results suggest that the genomes of four- and eight-cell nuclei introduced into the enucleated halves of two-cell embryos are reversed to support the development of the reconstituted embryo.     

Protein metabolism in preimplanted mouse ova

Intracellular specific radioactivity of an amino acid (leucine) was measured in preimplantation mouse ova. The measured specific activity along with leucine incorporation rates allow calculation of the protein synthetic rate in mouse ova. Unfertilized ova, fertilized ova, two-cell ova, and blastocysts convert amino acid to protein at the rate of 8.60, 7.36, 6.92, and 56.68 × 10^?13 moles of amino acid per hour per ovum, respectively. The specific activity measurements also allowed the calculation of intracellular leucine pool size. For the unfertilized, fertilized, two-cell, and blastocyst stage, the endogenous leucine pool was 11.9, 15.9, 6.4, and 62.4 × 10^?14 moles of leucine, respectively. Most of the increase in pool size in the blastocyst probably results from the increase in total volume of cells. Protein degradation measurements indicated a marked difference between protein turnover in the two-cell and blastocyst stage. Approximately 10% of the protein at the two-cell stage turns over with a half-life of 18.3 hr and 35% of the protein at the blastocyst stage turns over with a half-life of 11.2 hr. The large remaining fraction of protein turns over much more slowly.     

In vitro fertilization of Siberian hamster oocytes

Siberian hamsters were superovulated and various media were tested in an effort to fertilize the recovered oocytes in vitro. The highest percentage of fertilized ova was achieved by using a modified Tyrode's medium, designated MT (Bavister, J. Reprod. Fertil., 18:544-545, '69), previously formulated to fertilize Syrian hamster ova in vitro. Spermatozoa incubated in this medium in a concentrated state overnight (14 hr) and then diluted (1 hr) fertilized 39% of the ova. Similar results (40%) were obtained with this medium by adding 20% human follicular fluid to fresh concentrated sperm for 30 min and then diluting the sperm for 2-3 hr prior to the addition of ova. Ova fertilized in vitro cleaved to the two-cell stage but failed to develop any further in culture. Two-cell embryos recovered from mated hamsters and cultured did not undergo additional cleavage. Four-cell embryos collected from mated females and cultured cleaved to the six- to eight-cell stage and stopped. Techniques and media used for fertilizing large numbers of Syrian and Chinese hamster ova in vitro will have to be modified to achieve the same degree of success in the Siberian hamster.     

Qualitative patterns of protein synthesis in the preimplantation mouse embryo: I. Normal pregnancy

Qualitative patterns of protein synthesis in preimplantation mouse embryos were examined by SDS-polyacrylamide-gel electrophoresis followed by autoradiography. The results demonstrate that the qualitative pattern of protein synthesis in newly fertilized eggs (day 1) is very similar to the protein pattern obtained from ovulated, unfertilized eggs. By late day 1 or early day 2, most of these “maternal” proteins are no longer being synthesized by the embryo, and many new autoradiographic bands are apparent. The most intriguing aspect of this study is the observation that all major changes in the qualitative pattern of protein synthesis take place between fertilization and the four- to eight-cell stage (day 3). From early day 3 onward, the qualitative pattern of protein synthesis remains essentially unchanged.Many of the major autoradiographic bands observed in mouse embryos from the four- to eight-cell stage and onward are also observed in protein patterns obtained from blastocyst-stage rabbit embryos. The changing patterns of protein synthesis revealed in this study occur before any gross differentiation of the embryos is evident (delineation of the inner cell mass and trophoblast) and before a marked increase in the relative rate of incorporation of l-[³⁵S]methionine takes place. However, the qualitative changes in the pattern of protein synthesis do coincide with a period of extensive fine structural differentiation.     

一种与受精有关的人精子膜蛋白（BS－17）的分离纯化

本文用盐分级分离,ＭｏｎｏＱＦＰＬＣ及ＳＤＳ－聚丙烯酰胺凝胶电泳（ＳＤＳ－ＰＡＧＥ）等方法从人精子ＣＨＡＰＳ抽提液中分离纯化出一种与不育病人血清中抗精子抗体发生特异反应的ＢＳ－１７人精子膜蛋白。该蛋白为一糖蛋白,分子量为１７．５５±２．１５ｋＤ,等电点为５．６５,中性己糖含量为１６．６７％。在人精子上主要分布于顶体区域,不同于已有报导的人精子膜蛋白。在体外实验中抗ＢＳ－１７多克隆血清可以显著影响人精子的获能（ｐ＜０．０２５）和对去透明带仓鼠卵的穿透（ｐ＜０．００５）,但不影响人精子运动性及与去透明酯酸带仓鼠卵的结合。小鼠体内被动免疫实验结果证明抗ＢＳ－１７多抗血清具有明显地抑制受精的功能（ｐ＜０．００１）。     

Aberrant methylation patterns at the two-cell stage as an indicator of early developmental failure

The fertilized mouse egg actively demethylates the paternal genome within a few hours after fertilization, whereas the maternal genome is only passively demethylated by a replication-dependent mechanism after the two-cell stage. This evolutionarily conserved assymetry in the early diploid mammalian embryo may have a role in methylation reprogramming of the two very different sets of sperm and egg chromatin for somatic development and formation of totipotent cells. Immunofluorescence staining with an antibody against 5-methylcytosine (MeC) showed that the incidence of abnormal methylation patterns differs between mouse two-cell embryos from superovulated females, nonsuperovulated matings, and in vitro fertilization (IVF). It also depends on embryo culture conditions and genetic background. In general, there was a good correlation with the number of embryos (from the same experiment) which did not develop in vitro up to the blastocyst stage. Thus, aberrant genome-wide DNA methylation in early embryos may be an important mechanism contributing to the high incidence of developmental failure in mammals. Similar to the situation in abnormally methylated embryos from nuclear transfer, it may cause a high incidence of pregnancy loss and abnormal phenotypes.     

Serological characterization of a nervous system/sperm antigen (NS-52): demonstration of its presence on murine preimplantation embryos.

Anti-NS-5 antiserum raised in C3H.SW/Sn mice against cerebellum of 4-day-old C57BL/6J mice could be shown to recognize two cell surface antigens on cerebellar cells, NS-5₁ and NS-5₂, the latter antigen being shared with mouse and rat but not rabbit sperm. An antigen operationally identical to NS-5₂ was detected using indirect immunofluorescence staining on mouse preimplantation stages of development. While the unfertilized ova did not express detectable antigen on the cell surface, the fertilized egg expressed antigen shortly before the first cleavage division. From that stage onward, the anti-NS-5 antiserum stained the blastomeres of all stages, including the trophoblast cells and inner cell mass cells of the blastocyst. No difference in staining activity was observed for preimplantation embryos of various mouse strains analyzed: C57BL/6J, BALB/c, 129/J, C3H/DiSn, CKB × BALB.K, C3H.SW/Sn, and Swiss Webster mice. The staining activity was removed when the antiserum was preabsorbed with cerebellum or sperm from any of these mouse strains or with cerebellum and sperm of rats. Lymphocytes, thymocytes, liver, kidney, and skeletal muscle from early postnatal and adult mice and heart from early postnatal mice did not absorb the staining activity and neither did rabbit sperm nor cerebellum.     

The effects of altering the position of cleavage planes on the process of localization of developmental potential in ctenophores.

During the transition from the four- to the eight-cell stage in ctenophore embryos, each blastomere produces one daughter cell with the potential to form comb plate cilia and one daughter cell that does not have this potential. If the second cleavage in a two-cell embryo is blocked, at the next cleavage these embryos frequently form four blastomeres which have the configuration of the blastomeres in a normal eight-cell embryo. At this division there is also a segregation of comb plate-forming potential. By compressing a two-cell embryo in a plane perpendicular to the first plane of cleavage it is possible to produce a four-cell blastomere configuration that is identical to that produced following the inhibition of the second cleavage. However, under these circumstances the segregation of comb plate potential does not occur. These results suggest that the appropriate plane of cleavage must take place for a given cleavage cycle, in order for localizations of developmental potential to be properly positioned within blastomeres.     

Immunocytochemical evidence for centrosomal phosphoproteins in mitotic sea urchin eggs

The change in distribution of centrosomal phosphoproteins was examined in sea urchin eggs from fertilization to the first cleavage by immunofluorescence staining with the anti-phosphoprotein antibodies, MPM-1 and MPM-2. The antibodies reacted with female pronuclei in unfertilized eggs as well as centriolar complexes located at the base of sperm flagella. After insemination, male and female pronuclei fused together to form a zygotic nucleus which was visualized by staining of fertilized eggs with the antiphosphoprotein antibodies. No major change in staining pattern was detected in extracted whole eggs until mitosis. As the fertilized eggs approached mitosis, however, the antigens started to redistribute from nuclei to the perinuclear position where the mitotic centrosomes were located. Detailed immunofluorescence observation of isolated spindles revealed that the phosphoantigens were retained in isolated structures. A major 225 kd polypeptide was recognized by the antibodies, suggesting that the 225 kd protein is a phosphocomponent of centrosomes. The area recognized by the antibody in mitotic poles enlarged with the progress of mitosis, suggesting that the antigens were apparently localized in the centrosphere. Centrospheres prepared from isolated spindles by salt extraction strongly reacted with the antibodies. One or two bright dots, which may represent centrioles, were visible in the isolated centrosphere. At the end of mitosis, the antigens again appeared in the newly formed daughter nuclei. Centriole-containing cytasters and centriole-free monasters were parthenogenetically induced in unfertilized eggs (Kuriyama and Borisy, (1983) J. Cell Sci. 61: 175-189). The antibodies stained centers of both the asters whether they contained centrioles or not, indicating that the antibodies recognizes the components of the pericentriolar material.     

The role of autophagy during the oocyte-to-embryo transition

After fertilization, the maternal proteins stored in oocytes are degraded and new proteins encoded by the zygotic genome are synthesized. Although several proteins are degraded by the ubiquitin-proteasome system, the mechanism underlying the dynamic protein turnover during this process remains largely unknown. We recently reported that autophagy plays a critical role during preimplantation embryonic development. We found that the level of autophagy was low in unfertilized oocytes; however, autophagy was activated shortly after fertilization. The function of autophagy was further analyzed using oocyte-specific Atg5 (autophagy-related 5) knockout mice. Atg5-null oocytes could develop if they were fertilized with wild-type sperm, but could not develop beyond the four- and eight-cell stages if they were fertilized with Atg5-null sperm. Furthermore, protein synthesis rates were reduced in the autophagy-deficient embryos. We have previously reported that Atg5-null oocytes derived from Atg5+/- mice, which should contain maternally inherited Atg5 protein in the oocyte, were able to produce Atg5-/- neonates, emphasizing the specific importance of autophagy during very early embryogenesis. Thus, the degradation of maternal factors by autophagy is essential for preimplantation development in mammals.

Addendum to: Tsukamoto S, Kuma A, Murakami M, Kishi C, Yamamoto A, Mizushima N. Autophagy is essential for preimplantation development of mouse embryos. Science 2008; 321:117-20.     

A cell surface antigen, TER, expressed by embryos and germ cells.

An antiserum prepared in rabbits against the C3HeB/FeJ mouse ovarian teratocarcinoma E6496 was absorbed in vivo in C3HeB/FeJ mice. This absored antiserum identified an antigen, denoted TER, that is present on sperm, ova, embryonic germ cells, and cells of the early mouse embryo. TER was absent from all adult somatic cells tested, but found on several murine tumors.     

Characterization of mouse-hamster-human cross-reacting antioocyte monoclonal antibodies produced by intrasplenic immunization of mice with 12 zona-free mouse oocytes

Several intrasplenic immunizations with batches of ～15 or ～30 zona-free, unfertilized mouse oocytes resulted in 200–300 hybrids, respectively, among which about 20 positive clones were selected from each fusion between splenic plasma cells and SP2/0 myeloma cells. When nonimmunized splenic plasma cells were used, only one antibody, showing weak immunoreaction, was obtained from ～370 hybrids collected from 2 fusions. From one immunization with a total of 12 zona-free, unfertilized mouse oocytes, 15 positive clones were selected for further study. Eleven of these 15 antibodies reacted with antigens only in unfertilized oocytes but not in fertilized, pronuclear stage oocytes. Three antibodies, which recognized antigens in paraffin-embedded oocyte sections, did not label growing ovarian oocytes, indicating that the antibodies were specific to ovulated, unfertilized oocytes. These antibodies did not detect any antigen epitopes in the panel of tissues examined. The molecular weight of one antigen, corresponding to a IgM antibody that is present both in ooplasma and zona pellucida, was ～116 kDa. Cross-reactivity to blots of unfertilized zona-free hamster oocytes was demonstrated by 6 antibodies and to unfertilized human oocytes by 7 antibodies. Three antibodies cross-reacted with both hamster and human oocytes. The study indicates that the intrasplenic immunization is an appropriate means of raising antibodies against unfertilized, zona-free mouse oocytes and that the method applied offers an easy way to select antibodies against human oocytes for functional studies. © 1994 Wiley-Liss, Inc.     

Protein synthesis in mouse embryos with experimentally produced asynchrony between chromosome replication and cell division

Summary The cleavage of fertilized mouse eggs was prevented during cytochalasin B incubation and consequently these eggs became tetraploid the following day during in vitro culture. When the eggs were cultured further in normal medium, they cleaved and gave rise to tetraploid blastocysts. Protein synthesis was analysed in these embryos at different developmental stages using two-dimensional polyacrylamide gel electrophoresis. The protein synthesis pattern of one-cell tetraploid eggs was intermediate between those of normal one- and two-cell embryos. Tetraploid two-cell embryos expressed protein sets equivalent to those of untreated four-cell embryos, and tetraploid four-cell embryos synthesized proteins similar to those of four- to eight-cell controls. At subsequent pre-implantation stages the asynchrony was no longer detectable. When fertilized eggs were cultured continuously in the presence of cytochalasin B, they became tetraploid, octoploid and more and more polyploid without cleavage occurring. The protein synthesis patterns expressed by these one-cell polyploid eggs did not resemble that of normal fertilized eggs, but were similar to those of cleaving control embryos and blastocysts of equivalent age and nuclear division. These results strongly suggest that in early mouse embryos stage-specific translation is temporally correlated with chromosome replication (karyokinesis) and independent of cell division (cytokinesis) or cell interaction.Some of these results were presented at the IX Congress of the International Society of Developmental Biologists in Basle, Switzerland, August 28–September 1, 1981     

Cell contact induces multiple types of electrical excitability from ascidian two-cell embryos that are cleavage arrested and contain all cell fate determinants

Ascidian early embryonic cells undergo cell differentiation without cell cleavage, thus enabling mixture of cell fate determinants in single cells, which will not be possible in mammalian systems. Either cell in a two-cell embryo (2C cell) has multiple fates and develops into any cell types in a tadpole. To find the condition for controlled induction of a specific cell type, cleavage-arrested cell triplets were prepared in various combinations. They were 2C cells in contact with a pair of anterior neuroectoderm cells from eight-cell embryos (2C-aa triplet), with a pair of presumptive notochordal neural cells (2C-AA triplet), with a pair of presumptive posterior epidermal cells (2C-bb triplet), and with a pair of presumptive muscle cells (2C-BB triplet). The fate of the 2C cell was electrophysiologically identified. When two-cell embryos had been fertilized 3 h later than eight-cell embryos and triplets were formed, the 2C cells became either anterior-neuronal, posterior-neuronal or muscle cells, depending on the cell type of the contacting cell pair. When two-cell embryos had been fertilized earlier than eight-cell embryos, most 2C cells became epidermal. When two- and eight-cell embryos had been simultaneously fertilized, the 2C cells became any one of three cell types described above or the epidermal cell type. Differentiation of the ascidian 2C cell into major cell types was reproducibly induced by selecting the type of contacting cell pair and the developmental time difference between the contacting cell pair and 2C cell. We discuss similarities between cleavage-arrested 2C cells and vertebrate embryonic stem cells and propose the ascidian 2C cell as a simple model for toti-potent stem cells.