Expression of cytokeratin polypeptides in mouse oocytes and preimplantation embryos

The presence and distribution of intermediate filament proteins in mouse oocytes and preimplantation embryos was studied. In immunoblotting analysis of electrophoretically separated polypeptides, a distinct doublet of polypeptides with Mr of 54K and 57K, reactive with cytokeratin antibodies, was detected in oocytes and in cleavage-stage embryos. A similar doublet of polypeptides, reactive with cytokeratin antibodies, was also detected in late morula-and blastocyst-stage embryos, and in a mouse embryo epithelial cell line (MMC-E). A third polypeptide with Mr of 50K, present in oocytes only as a minor component, was additionally detected in the blastocyst-stage embryos. No cytokeratin polypeptides could be detected in granulosa cells. Immunoblotting with vimentin antibodies gave negative results in both cleavage-stage and blastocyst-stage embryos. In electron microscopy, scattered filaments, 10-11 nm in diameter, were seen in detergent-extracted cleavage-stage embryos. Abundant 10-nm filaments were present in the blastocyst outgrowth cells. In indirect immunofluorescence microscopy (IIF) of oocytes and cleavage-stage embryos, diffuse cytoplasmic staining was seen with antibodies to cytokeratin polypeptides but not with antibodies to vimentin, glial fibrillary acidic protein, or neurofilament protein. Similarly, the inner cell mass (ICM) cells in blastocyst outgrowths showed diffuse cytokeratin-specific fluorescence. We could not detect any significant fibrillar staining in cleavage-stage cells or ICM cells by the IIF method. The first outgrowing trophectoderm cells already had a strong fibrillar cytokeratin organization. These immunoblotting and -fluorescence results suggest that cytokeratin-like polypeptides are present in mouse oocytes and preimplantation-stage embryos, and the electron microscopy observations show that these early stages also contain detergent-resistant 10- to 11-nm filaments. The relative scarcity of these filaments, as compared to the high intensity in the immunoblotting and immunofluorescence stainings, speaks in favor of a nonfilamentous pool of cytokeratin in oocytes and cleavage-stage embryos.     

Localization of nonerythroid spectrin and actin in mouse oocytes and preimplantation embryos

Mouse oocytes, cleavage-stage embryos, and blastocyst-stage embryos were studied to show the distribution of both an immunoanalog to nonerythroid spectrin (p 230) and F-actin. Using antibodies to nonerythroid spectrin, diffuse, positive cytoplasmic fluorescence was regularly seen in oocytes and embryo cells. The presence of nonerythroid spectrin in oocytes was confirmed by immunoblotting. Oocytes usually exhibited an inconspicuous submembranous layer of nonerythroid spectrin, which was more pronounced in the area of the polar body. Oocytes regularly exhibited a peripheral concentration of actin. Throughout the cleavage and blastocyst stages, a cortical layer of nonerythroid spectrin and actin was usually observed in embryo cells. These submembranous layers on the outer surface of the embryo were relatively thin as compared to those in areas of intercellular contact. The contact areas regularly showed distinct positive staining, including a concentration of label at the most peripheral region of each contact area. This resulted in the presence of ring-like fluorescence around each blastomere. Nonerythroid spectrin and actin showed concentration to the contact area between the oocyte and the polar body. Although the general localization patterns of nonerythroid spectrin and actin were similar, double-staining experiments revealed that slightly different planes of focus were necessary to obtain sharp definition of the fluorescence of these components in areas of intercellular contact: the ring-like concentration of nonerythroid spectrin appeared to be localized more peripherally than that of actin. The cells of preimplantation embryos show motile features that include actual cell movements and striking changes in cell shape (e.g., during compaction). The submembraneous layers of nonerythroid spectrin and actin may contribute to the regulation of the deformability and thus the shape of embryo cells.(ABSTRACT TRUNCATED AT 250 WORDS)     

RNAi in mouse oocytes and preimplantation embryos: effectiveness of hairpin dsRNA

Wolbachia are intracellular symbionts mainly found in arthropods, causing various sexual alterations on their hosts by unknown mechanisms. Here we report the results that strongly suggest that Wolbachia have virus-like particles of phage WO, which was previously identified as a prophage-like element in the Wolbachia genome. Wolbachia (strain wTai) infection in an insect was detected with the antibody against Wsp, an outer surface protein of Wolbachia, by fluorescence microscopy and immunoelectron-microscopy for the first time. Virus-like particles in Wolbachia were observed by electron-microscopy. The 0.22-microm filtrate of insect ovary contained DAPI-positive particles, and PCR analysis demonstrated that a phage WO DNA passed through the filter while Wolbachia DNA were eliminated, suggesting that the DAPI-positive particles were phage WO.     

Modification of cell division by phorbol ester in preimplantation mouse embryos

2-cell mouse embryos were treated in vitro with a 2 h pulse of phorbol myristate acetate (PMA) at 32nd, 38th and 50th h after hCG, then chased in culture for up to 46 h. Embryos were fixed at various time intervals of chasing, then stained and inspected. Some embryos were carefully inspected with a video recording system, every 1.44s and the cell divisions (cytokinesis) as well as formation of large, single blastomeres, each from two smaller ones, were recorded. PMA pulse let to the suppression of cell divisions. The rate of the suppression was time dependent: with a delay of 0-1, 12 and 18 h between the PMA pulse and time of scheduled cell division about 99, 87 and 44% of 2-cell embryos remained at this stage of development, for at least 10 h, respectively, and 90, 58 and 12% of their blastomeres revealed binuclearity. Since we found that PMA-mediated formation of binuclearity was not the effect of cell fusions, it was assumed that the inhibition of cytokinesis preceded by karyokinesis was responsible for binuclearity. PMA effect on cell divisions was reversible. PMA-treated embryos revealed formation of large, single blastomeres, each from two smaller ones. If cell division appeared after PMA pulse, in about 52% of 3- to 6-cell embryos, the large blastomere formation was recorded in the course of the subsequent 38 h. Large blastomere formation was concluded to be the result of either cell fusion or reversion of incompleted cytokinesis brought about by PMA.     

Quantification of basigin mRNA in mouse oocytes and preimplantation embryos by competitive RT-PCR

Basigin is a member of the immunoglobulin superfamily and a key molecule related to mouse blastocyst implantation. Whether preimplantation mouse embryos express basigin mRNA is still unknown. The aim of this study was to use a quantitative competitive polymerase chain reaction to assess quantitatively the levels of basigin mRNA in mouse oocyte and preimplantation embryos. Basigin mRNA was detected in the oocyte and all the stages of preimplantation embryos. The levels of basigin mRNA were 0.0606 +/- 0.0282 in the oocyte, 0.0102 +/- 0.0036 in the zygote, 0.0007 +/- 0.0003 in the 2-cell embryo, 0.0031 +/- 0.0017 in the 4-cell embryo, 0.0084 +/- 0.0024 in the 8-cell embryo, 0.0537 +/- 0.0121 in the morula and 0.0392 +/- 0.0161 attomoles in the blastocyst, respectively. The levels of basigin mRNA in the oocyte, morula and blastocyst were significantly higher than those in the zygote and embryos at the 2-cell, 4-cell and 8-cell stages. The high level of basigin expression in the blastocyst may play a role during embryo implantation.     

Spatio-temporal localization of membrane lipid rafts in mouse oocytes and cleaving preimplantation embryos

We report for the first time the detection of membrane lipid rafts in mouse oocytes and cleaving preimplantation embryos. Cholera toxin β (CTβ), which binds to the raft-enriched ganglioside GM1, was selected to label rafts. In a novel application a Qdot reagent was used to detect CTβ labeling. This is the first reported use of nanocrystals in mammalian embryo imaging. Comparative membrane labeling with CTβ and lipophilic membrane dyes containing saturated or unsaturated aliphatic tails showed that the detection of GM1 in mouse oocytes and embryo membranes was consistent with the identification of cholesterol- and sphingolipid-enriched rafts in the cell membrane. Distribution of the GM1 was compared with the known distribution of non-raft membrane components, and disruption of membrane rafts with detergents confirmed the cholesterol dependence of GM1 on lipid raft labeling. Complementary functional studies showed that cholesterol depletion using methyl-β-cyclodextrin inhibited preimplantation development in culture. Our results show that the membranes of the mouse oocyte and zygote are rich in lipid rafts, with heterogeneous and stage-dependent distribution. In dividing embryos, the rafts were clearly associated with the cleavage furrow. At the morula stage, rafts were also apically enriched in each blastomere. In blastocysts, rafts were detectable in the trophectoderm layer, but could not be detected in the inner cell mass without prior fixation and permeabilization of the embryo. Lipid rafts and their associated proteins are, therefore, spatio-temporally positioned to a play a critical role in preimplantation developmental events.     

An unusual subcellular localization of GLUT1 and link with metabolism in oocytes and preimplantation mouse embryos

Although mouse oocytes and cleavage-stage embryos prefer pyruvate and lactate for metabolic fuels, they do take up and metabolize glucose. Indeed, presentation of glucose during the cleavage stages is required for subsequent blastocyst formation, which normally relies on uptake and metabolism of large amounts of glucose. Expression of the facilitative glucose transporter GLUT1 was examined using immunohistochemistry and Western blotting, and in polyspermic oocytes, metabolism of glucose was measured and compared with that of pyruvate and glutamine. GLUT1 was observed in all oocytes and embryos, and membrane and vesicular staining was present. Additionally, however, in polyspermic oocytes, the most intense staining was in the pronuclei, and this nuclear staining persisted in cleaving normal embryos. Furthermore, GLUT1 expression appeared to be up-regulated both in nuclei and plasma membranes following culture of oocytes in the absence of glucose. In polyspermic oocytes, the metabolism of glucose, but not of pyruvate or glutamine, was directly proportional to the number of pronuclei formed. After compaction, nuclear staining diminished, and GLUT1 localized to basolateral membranes of the outer cells and trophectoderm. In blastocysts, a weak but uniform staining of inner-cell-mass plasma membranes was apparent. The results are discussed in terms of potential roles for GLUT1 in pronuclei of oocytes and zygotes, nuclei of cleavage-stage embryos, and a transepithelial transport function for GLUT1, probably coupled with GLUT3, in compacted embryos and blastocysts.     

Efficient delivery of dsRNA into zona-enclosed mouse oocytes and preimplantation embryos by electroporation

Conditions for the electroporation of mouse oocytes and preimplantation embryos have been optimised by following the incorporation of rhodamine labeled dextran. This procedure includes a step to weaken but not remove the zona pellucida that helps achieve good survival. This approach has been applied to introduce double-stranded RNA for c-mos into oocytes and green fluorescent protein (GFP) into transgenic GFP-expressing embryos at the 1- and 4-cell stages. In both cases we were able to observe sequence-specific interference with the expression of the target gene--a failure of oocytes to arrest at metaphase II and a loss in the green fluorescence of embryos by the morula or blastocyst stages. These effects could be observed in multiple oocytes or embryos allowed to develop together following electroporation.     

14-3-3beta binds to big mitogen-activated protein kinase 1 (BMK1/ERK5) and regulates BMK1 function

Big mitogen-activated kinase 1 (BMK1/ERK5) is a member of the MAPK family activated by growth factors that mediates cell growth and survival. Previous data show that BMK1 can be activated by steady laminar flow and is atheroprotective by preventing endothelial cells from undergoing apoptosis. The primary structure of BMK1 is distinct from other MAPK members by virtue of a unique long C-tail, suggesting specific mechanisms of regulation. To characterize regulatory mechanisms for BMK1 function, we identified binding proteins by yeast two-hybrid analysis. Among these proteins, the scaffolding protein 14-3-3 was identified. BMK1 bound to 14-3-3beta in vitro and in vivo as demonstrated by glutathione S-transferase (GST)-14-3-3beta fusion protein pull-down assays and coimmunoprecipitation. Phosphorylation of BMK1 was most likely required for this interaction. GST-14-3-3beta pull-down assays using truncated constructs of BMK1 and site-directed BMK1 mutants demonstrated that the interaction requires serine 486 within the C terminus of BMK1. BMK1 bound to 14-3-3beta basally, and the interaction was greatly abrogated when BMK1 was activated. The interaction of 14-3-3beta and BMK1 inhibited kinase activities stimulated by constitutively active (CA)-MEK5 and epidermal growth factor. Mutation of serine 486 (BMK1-S486A) prevented the interaction with 14-3-3beta and enhanced BMK1 activity upon epidermal growth factor stimulation. These data demonstrate an inhibitory function for 14-3-3beta binding to BMK1 and show that serine 486 phosphorylation represents a novel regulatory mechanism for BMK1.     

NLRP5 mediates mitochondrial function in mouse oocytes and embryos

Unraveling molecular pathways responsible for regulation of early embryonic development is crucial for our understanding of female infertility. Maternal determinants that control the transition from oocyte to embryo are crucial molecules that govern developmental competence of the newly conceived zygote. We describe a series of defects that are triggered by a disruption of maternal lethal effect gene, Nlrp5. Previous studies have shown that Nlrp5 hypomorph embryos fail to develop beyond the two-cell stage. Despite its importance in preimplantation development, the mechanism by which the embryo arrest occurs remains unclear. We confirmed that Nlrp5 mutant and wild-type females possess comparable ovarian germ pool and follicular recruitment rates. However, ovulated oocytes lacking Nlrp5 have abnormal mitochondrial localization and increased activity in order to sustain physiological ATP content. This results in an accumulation of reactive oxygen species and increased cellular stress causing mitochondrial depletion. Compromised cellular state is also accompanied by increased expression of cell death inducer Bax and depletion of cytochrome c. However, neither genetic deletion (Bax/Nlrp5 double knockout) nor mimetic interference (BH4 domain or Bax inhibitory peptide) were sufficient to alleviate embryo demise caused by depletion of Nlrp5. We therefore conclude that lack of Nlrp5 in oocytes triggers premature activation of the mitochondrial pool, causing mitochondrial damage that cannot be rescued by inactivation of Bax.     

Microelectrophoretic analysis of changes in protein expression patterns in mouse oocytes and preimplantation embryos.

One- and two-dimensional polyacrylamide microslab gel electrophoresis followed by silver staining was devised to visualize picogram to nanogram levels of proteins and was applied to the analysis of 1-20 mouse oocytes and embryos (approximately 16.5-330 ng of protein) during preimplantation development. Compared with values in embryos, more bands in the higher molecular weight range were found only for unfertilized oocytes in one-dimensional microelectrophoresis. A marked decrease in the number of protein spots occurred after fertilization in two-dimensional microelectrophoresis. Both findings indicate a decrease in maternal proteins caused by fertilization. Silver-staining densities were almost invariable for 8 major spots, but increased, decreased, or varied for 32 minor spots in developing embryos from the 1-cell to the morula stage, signifying spot-specific changes in the expression of zygotic proteins during development. The protein patterns in cumulus cells and blastocysts were different from those in oocytes and embryos. Even in a single 1-cell embryo, major spots and some minor spots were detectable by our two-dimensional microelectrophoretic technique, but many more minor spots were visualized in five 1-cell embryos, exemplifying the limit of our microelectrophoretic technique. As a preliminary result, a two-dimensional immunoblot pattern is shown for glucose transporter 1 expressed in morulae.