Par‐aPKC‐dependent and ‐independent mechanisms cooperatively control cell polarity,Hippo signaling,and cell positioning in 16‐cell stage mouse embryos

In preimplantation mouse embryos, the Hippo signaling pathway plays a central role in regulating the fates of the trophectoderm (TE) and the inner cell mass (ICM). In early blastocysts with more than 32 cells, the Par‐aPKC system controls polarization of the outer cells along the apicobasal axis, and cell polarity suppresses Hippo signaling. Inactivation of Hippo signaling promotes nuclear accumulation of a coactivator protein, Yap, leading to induction of TE‐specific genes. However, whether similar mechanisms operate at earlier stages is not known. Here, we show that slightly different mechanisms operate in 16‐cell stage embryos. Similar to 32‐cell stage embryos, disruption of the Par‐aPKC system activated Hippo signaling and suppressed nuclear Yap and Cdx2 expression in the outer cells. However, unlike 32‐cell stage embryos, 16‐cell stage embryos with a disrupted Par‐aPKC system maintained apical localization of phosphorylated Ezrin/Radixin/Moesin (p‐ERM), and the effects on Yap and Cdx2 were weak. Furthermore, normal 16‐cell stage embryos often contained apolar cells in the outer position. In these cells, the Hippo pathway was strongly activated and Yap was excluded from the nuclei, thus resembling inner cells. Dissociated blastomeres of 8‐cell stage embryos form polar–apolar couplets, which exhibit different levels of nuclear Yap, and the polar cell engulfed the apolar cell. These results suggest that cell polarization at the 16‐cell stage is regulated by both Par‐aPKC‐dependent and ‐independent mechanisms. Asymmetric cell division is involved in cell polarity control, and cell polarity regulates cell positioning and most likely controls Hippo signaling.     

Normal specification of the extraembryonic lineage after somatic nuclear transfer

To examine the establishment and maintenance of trophectoderm (TE) lineage in somatic cloned blastocysts, the expression of Cdx2, a key molecule for specification of TE fate, was immunohistochemically examined simultaneously with Oct4 expression. Cloned mouse embryos were made by nuclear transfer using cumulus cells, tail-tip fibroblasts, and embryonic stem cells. After 96 h of culture, the rates of Oct4-expressing blastocysts were as low as 50% and 60% for cumulus and fibroblast clones, respectively. However, regardless of Oct4 expression, the majority of those cloned blastocysts (> 90%) normally expressed Cdx2. Thus, even though somatic cloned embryos have reduced potential to produce the inner cell mass lineage, the TE lineage can be established and maintained.     

Delay of polarization event increases the number of Cdx2-positive blastomeres in mouse embryo

During preimplantation mouse embryo development expression of Cdx2 is induced in outer cells, which are the trophectoderm (TE) precursors. The mechanism of Cdx2 upregulation in these cells remains unclear. However, it has been suggested that the cell position and polarization may play a crucial role in this process. In order to elucidate the role of these two parameters in the formation of TE we analyzed the expression pattern of Cdx2 in the embryos in which either the position of cells and the time of polarization or only the position of cells was experimentally disrupted. Such embryos developed from the blastomeres that were isolated from 8-cell embryos either before or after the compaction, i.e. before or after the cell polarization took place. We found that in the embryos developed from polar blastomeres originated from the 8-cell compacted embryo, the experimentally imposed outer position was not sufficient to induce the Cdx2 in these blastomeres which in the intact embryo would form the inner cells. However, when the polarization at the 8-cell stage was disrupted, the embryos developed from such an unpolarized blastomeres showed the increased number of cells expressing Cdx2. We found that in such experimentally obtained embryos the polarization was delayed until the 16-cell stage. These results suggest that the main factor responsible for upregulation of Cdx2 expression in outer blastomeres, i.e. TE precursors, is their polarity.     

CDX2 in the formation of the trophectoderm lineage in primate embryos

The first lineage decision during mammalian development is the establishment of the trophectoderm (TE) and the inner cell mass (ICM). The caudal-type homeodomain protein Cdx2 is implicated in the formation and maintenance of the TE in the mouse. However, the role of CDX2 during early embryonic development in primates is unknown. Here, we demonstrated that CDX2 mRNA levels were detectable in rhesus monkey oocytes, significantly upregulated in pronuclear stage zygotes, diminished in early cleaving embryos but restored again in compact morula and blastocyst stages. CDX2 protein was localized to the nucleus of TE cells but absent altogether in the ICM. Knockdown of CDX2 in monkey oocytes resulted in formation of early blastocyst-like embryos that failed to expand and ceased development. However, the ICM lineage of CDX2-deficient embryos supported the isolation of functional embryonic stem cells. These results provide evidence that CDX2 plays an essential role in functional TE formation during primate embryonic development.     

Cdx1::Cre allele for gene analysis in the extraembryonic ectoderm and the three germ layers of mice at mid‐gastrulation

Transgenic mice with a defined cell‐ or tissues‐specific expression of Cre‐recombinase are essential tools to study gene function. Here we report the generation and analysis of a transgenic mouse line (Cdx1::Cre) with restricted Cre‐expression from Cdx1 regulatory elements. The expression of Cre‐recombinase mimicked the endogenous expression pattern of Cdx1 at midgastrulation (from E7.5 to early headfold stage) inducing recombination in the three germlayers of the primitive streak region throughout the posterior embryo and caudal to the heart. This enables gene modifications to investigate patterning of the caudal embryo during and after gastrulation. Interestingly, we identified Cdx1 expression in the trophectoderm (TE) of blastocyst stage embryos. Concordantly, we detected extensive Cre‐mediated recombination in the polar TE and, although to lesser extent, in the mural TE. In E7.5 postimplantation embryos, almost all cells of the extraembryonic ectoderm (ExE), which are derived from the polar TE, are recombined although the ExE itself is negative for Cdx1 and Cre at this stage. These results indicate that Cdx1::Cre mice are also a valuable tool to study gene function in tissues essential for placental development. genesis 47:204–209, 2009. © 2009 Wiley‐Liss, Inc.     

Trophectoderm lineage determination in cattle

The trophectoderm (TE) and inner cell mass (ICM) are committed and marked by reciprocal expression of Cdx2 and Oct4 in mouse late blastocysts. We find that the TE is not committed at equivalent stages in cattle, and that bovine Cdx2 is required later, for TE maintenance, but does not repress Oct4 expression. A mouse Oct4 (mOct4) reporter, repressed in mouse TE, remained active in the cattle TE; bovine Oct4 constructs were not repressed in the mouse TE. mOct4 has acquired Tcfap2 binding sites mediating Cdx2-independent repression-cattle, humans, and rabbits do not contain these sites and maintain high Oct4 levels in the TE. Our data suggest that the regulatory circuitry determining ICM/TE identity has been rewired in mice, to allow rapid TE differentiation and early blastocyst implantation. These findings thus emphasize ways in which mice may not be representative of the earliest stages of mammalian development and stem cell biology.     

Ability of outside cells from preimplantation mouse embryos to form inner cell mass derivatives

Previous studies have shown that inside cells in the preimplantation mouse embryo do not become committed to the formation of inner cell mass until after blastocyst formation. However, it is not yet clear whether outside cells are also labile late in preimplantation development or whether they become restricted to trophectoderm development at an earlier stage. The present study investigates the potency of outside cells isolated from late morulae just prior to blastocyst formation and shows that some, if not all, outside cells retain the potential to form inner cell mass derivatives in vitro and in vivo. This suggests that trophectoderm cells are not restricted in potential earlier than ICM cells and that all cells of the early embryo may be labile at least until blastulation.