Integrin alpha6beta1-laminin interactions regulate early myotome formation in the mouse embryo

We addressed the potential role of cell-laminin interactions during epaxial myotome formation in the mouse embryo. Assembly of the myotomal laminin matrix occurs as epaxial myogenic precursor cells enter the myotome. Most Myf5-positive and myogenin-negative myogenic precursor cells localise near assembled laminin, while myogenin-expressing cells are located either away from this matrix or in areas where it is being assembled. In Myf5(nlacZ/nlacZ) (Myf5-null) embryos, laminin, collagen type IV and perlecan are present extracellularly near myogenic precursor cells, but do not form a basement membrane and cells are not contained in the myotomal compartment. Unlike wild-type myogenic precursor cells, Myf5-null cells do not express the alpha6beta1 integrin, a laminin receptor, suggesting that integrin alpha6beta1-laminin interactions are required for myotomal laminin matrix assembly. Blocking alpha6beta1-laminin binding in cultured wild-type mouse embryo explants resulted in dispersion of Myf5-positive cells, a phenotype also seen in Myf5(nlacZ/nlacZ) embryos. Furthermore, inhibition of alpha6beta1 resulted in an increase in Myf5 protein and ectopic myogenin expression in dermomyotomal cells, suggesting that alpha6beta1-laminin interactions normally repress myogenesis in the dermomyotome. We conclude that Myf5 is required for maintaining alpha6beta1 expression on myogenic precursor cells, and that alpha6beta1 is necessary for myotomal laminin matrix assembly and cell guidance into the myotome. Engagement of laminin by alpha6beta1 also plays a role in maintaining the undifferentiated state of cells in the dermomyotome prior to their entry into the myotome.     

Interferon synthesis in the early post-implantation mouse embryo

Abstract. A qualitative bioassay was adapted and used to determine the ability of the early post-implantation mouse embryo to synthesise interferon. Interferon production was not seen in any embryo tissue in the absence of an inducer and could only be detected in virus-induced tissue from the early 7th day of development. This induced interferon synthesis was initially confined to the trophoblast of the early 7th day embryo. It was then found in tissues of both trophoblast and inner cell mass origin in the early 8th day, and subsequently, in derivatives of the embryonic ectoderm in the 13th-day embryo.     

Interferon synthesis in the early post-implantation mouse embryo

A qualitative bioassay was adapted and used to determine the ability of the early post-implantation mouse embryo to synthesise interferon. Interferon production was not seen in any embryo tissue in the absence of an inducer and could only be detected in virus-induced tissue from the early 7th day of development. This induced interferon synthesis was initially confined to the trophoblast of the early 7th day embryo. It was then found in tissues of both trophoblast and inner cell mass origin in the early 8th day, and subsequently, in derivatives of the embryonic ectoderm in the 13th-day embryo.     

Steroidogenic capabilities of the early mouse embryo

Preimplantation embryos from ICR albino mice were used to determine progesterone and estradiol-17β production during incubation in BMOC-2. Following culture of 40 embryos/culture at either the morula, early blastocyst or late blastocyst stages, progesterone and estradiol-17β contents were 192±27 and 82±22 pg, 289±50 and 147±46 pg and 157±28 and 88±23 pg, respectively, for incubated samples and 306±68 and 89±40 pg, 404±63 and 125±44 pg, and 241±54 and 86±39 pg, respectively for control samples. Although, there were significant stage of development and treatments effects (P<0.05) for progesterone, production of this steroid was not evident. These data suggest that the early preimplantation mouse embryo does not produce progesterone or estradiol-17β in a defined culture system.     

Endocytosis and epithelial biogenesis in the mouse early embryo

The polarized organization of epithelial cells is expressed in many ways including the morphology of the cell surface or cytocortex, the molecular composition of membrane domains and the distribution of cytoplasmic organelles. The differentiation of mouse trophectoderm is described with particular attention given to the maturation of the endocytic system in an attempt to define how the complex assembly of an epithelium may be generated.     

RNA polymerase during early development in mouse embryo

RNA polymerase activity in mouse embryo homogenates has been measured at various stages of pre-implantation development. The amount of enzyme/embryo appears to increase in the period under consideration. On a per cell basis a decline in the level of polymerase was, however, observed from the 2-cell to the early blastocyst stages.     

Tolerance in early embryo aggregation-derived mouse chimaeras.

Epidermal cell suspensions of 90% average viability prepared from adult mouse tail skin by trypsinization and glass wool filtration were compared with leucocytes for their capacity to induce and reveal cell-mediated cytotoxicity to histocompatibility antigens in an H-2 different strain combination. As targets in short-term chromium release assays, epidermal cells incorporated ten times more ⁵¹Cr than normal lymph node cells yet released a lower proportion spontaneously. Although they were more resistant to lysis than lymph node cells, they registered high levels of cytotoxicity when particularly active attacker cells were used, even at low attacker-to-target cell ratios. In mixed cell cultures, irradiated epidermal cells were as effective as spleen cells in boosting immunity induced in vivo by skin allografts. Epidermal cells also were effective primary immunogens in vitro, but at higher responder-to-stimulator cell ratios than required for spleen cells. The specificity of epidermal cells as both targets and immunogens fully paralleled that of leucocytes from the same donors.     

ROCK inhibition prevents early mouse embryo development

ROCK is a Rho-GTPase effector that is important for actin assembly and is involved in various cellular functions, including cell contraction, migration, motility, and tumor cell invasion. In this study, we investigated ROCK expression and function during early mouse embryo development. Inhibiting ROCK by Y-27632 treatment at the zygote stage resulted in first cleavage failure, and most embryos failed to develop to the 8-cell stage. When adding Y-27632 at the 8-cell stage, embryos failed to undergo compaction and could not develop into blastocysts. In addition, fluorescence staining intensity analysis indicated that actin expression at blastomere membranes was significantly reduced. After ROCK inhibition, two or more nuclei were observed in a cell, which indicated possible cytokinesis failure. Moreover, after ROCK inhibition with Y-27632, the phosphorylation levels of LIMK1/2, a downstream molecule of ROCK, were decreased at blastomere membranes. Thus, our results showed conserved roles for ROCK in this mammalian embryo model and indicated that a ROCK-LIMK1/2-actin pathway might regulate cleavage and blastocyst formation during early mouse embryo development.     

A gene network establishing polarity in the early mouse embryo

In mammalian embryos, molecular cross-talk with extraembryonic tissues is essential to elaborate the primary body axes. Here, we review a series of reciprocal interactions that occur shortly after implantation in the uterus, and discuss how they are integrated in a complex signaling network to establish antero-posterior and dorso-ventral polarity. At the heart of this signaling network is the TGFbeta-related protein Nodal which acts on extraembryonic tissues to induce positive and negative feedback regulators at opposite poles of the egg cylinder. This likely results in an activity gradient which is instrumental to pattern the embryo proper.     

Dynamic reprogramming of DNA methylation in the early mouse embryo.

Dynamic epigenetic modification of the genome occurs during early development of the mouse. Active demethylation of the paternal genome occurs in the zygote, followed by passive demethylation during cleavage stages, and de novo methylation, which is thought to happen after implantation. We have investigated these processes by using indirect immunofluorescence with an antibody to 5-methyl cytosine. In contrast to previous work, we show that demethylation of the male pronucleus is completed within 4 h of fertilisation. This activity is intricately linked with and not separable from pronucleus formation. In conditions permissive for polyspermy, up to five male pronuclei underwent demethylation in the same oocyte. Paternal demethylation in fertilised oocytes deficient for MBD2, the only candidate demethylase, occurred normally. Passive loss of methylation occurred in a stepwise fashion up to the morulae stage without any evidence of spatial compartmentalisation. De novo methylation was observed specifically in the inner cell mass (ICM) but not in the trophectoderm of the blastocyst and hence may have an important role in early lineage specification. This is the first complete and detailed analysis of the epigenetic reprogramming cycle during preimplantation development. The three phases of methylation reprogramming may have roles in imprinting, the control of gene expression, and the establishment of nuclear totipotency.     

Cell-cell contact modulation of myosin organization in the early mouse embryo

Preimplantation mouse embryos are characterized by a polarized distribution of cortical myosin (J. S. Sobel (1983). Dev. Biol. 95, 227-231.). Myosin was present in the peripheral regions of the blastomers and was not detectable in regions of cell contact. Disaggregation of the embryos yielded blastomeres which had a continuous layer of cortical myosin. Development of new contact relations in aggregates, between daughter cells of divided blastomeres, and in chimaeras resulted in renewed polarization of cortical myosin. The results indicate that continuous cell contact interaction modulates the distribution of myosin throughout the preimplantation stages of development. The loss of detectable myosin from regions of cell contact was correlated with development of cell contacts that remained stable after Triton X-100 extraction.     

Cell fate decisions and axis determination in the early mouse embryo

The mouse embryo generates multiple cell lineages, as well as its future body axes in the early phase of its development. The early cell fate decisions lead to the generation of three lineages in the pre-implantation embryo: the epiblast, the primitive endoderm and the trophectoderm. Shortly after implantation, the anterior-posterior axis is firmly established. Recent studies have provided a better understanding of how the earliest cell fate decisions are regulated in the pre-implantation embryo, and how and when the body axes are established in the pregastrulation embryo. In this review, we address the timing of the first cell fate decisions and of the establishment of embryonic polarity, and we ask how far back one can trace their origins.     

3-D reconstruction of early preimplantation mouse embryo

Method of 3-D reconstruction approaches for early mouse embryo in preimplantation stages was modified. The developed technique is based on application of light microscopy of serial thin sections and well known soft operating. The designed method enabled us 1) to get serial sections of a single mouse embryo; 2) to create an orthogonal system independent on the sample for orientation of virtual sections. The adequacy of 3-DR protocol was checked on reconstruction of air bubbles embedded in epoxy resin as a model of sphere.     

Cellular interactions involved in the determination of the early C. elegans embryo

Classical work implied that early nematode embryogenesis is completely mosaic. This view was lately challenged by the demonstration that in C. elegans an early interaction has to occur to induce the production of muscle from a blastomere. Here, early embryonic blastomeres were inactivated by laser microsurgery. The cell lineages of irradiated embryos were compared to those of intact embryos. It is shown that one blastomere, MS, is required for the specification of mesodermal pharyngeal fates and another blastomere, P2, for the specification of hypodermal fates from the descendants of the AB blastomere, whereas the proper specification of the nervous system requires the presence of both. The irradiation of a third blastomere shows that interactions also occur within the ectoderm. I propose that the body plan of the C. elegans embryo may be established by two primary signals followed by secondary interactions. The suggested mechanisms are reminiscent of those involved in amphibian development.