Balanced Notch-Wnt signaling interplay is required for mouse embryo and fetal development

This study investigated the role of Notch and Wnt cell signaling interplay in the mouse early embryo, and its effects on fetal development. Developmental kinetics was evaluated in embryos in vitro cultured from the 8-16-cell to the hatched blastocyst stage in the presence of signaling inhibitors of Notch (DAPT) and/or Wnt (DKK1). An embryo subset was evaluated for differential cell count and gene transcription of Notch (receptors Notch1-4, ligands Dll1, Dll4, Jagged1-2, effectors Hes1-2) and Wnt (Wnt3a, Lrp6, Gsk3β, C-myc, Tcf4, β-catenin) components, E-cadherin and pluripotency and differentiation markers (Sox2, Oct4, Klf4, Cdx2), whereas a second subset was evaluated for implantation ability and development to term following transfer into recipients. Notch and Wnt blockades had significant opposing effects on developmental kinetics – Notch blockade retarded while Wnt blockade fastened development. This evidences that Notch and Wnt regulate the pace of embryo kinetics by respectively speeding and braking development. Blockades significantly changed the transcription profile of Sox2, Oct4, Klf4 and Cdx2, and Notch and double blockades significantly changed embryonic cell numbers and cell ratio. The double blockade induced more severe phenotypes than those expected from the cumulative effects of single blockades. Implantation ability was unaffected, but Notch and double blockades significantly decreased fetal development to term. Compared to control embryos, Notch blockade and Wnt blockade embryos originated, respectively, significantly lighter and heavier fetuses. In conclusion, Notch and Wnt signaling interplay in the regulation of the pace of early embryo kinetics, and their actions at this stage have significant carry-over effects on later fetal development to term.

HIPPO signaling resolves embryonic cell fate conflicts during establishment of pluripotency in vivo

During mammalian development, the challenge for the embryo is to override intrinsic cellular plasticity to drive cells to distinct fates. Here, we unveil novel roles for the HIPPO signaling pathway in controlling cell positioning and expression of Sox2, the first marker of pluripotency in the mouse early embryo. We show that maternal and zygotic YAP1 and WWTR1 repress Sox2 while promoting expression of the trophectoderm gene Cdx2 in parallel. Yet, Sox2 is more sensitive than Cdx2 to Yap1/Wwtr1 dosage, leading cells to a state of conflicted cell fate when YAP1/WWTR1 activity is moderate. Remarkably, HIPPO signaling activity resolves conflicted cell fate by repositioning cells to the interior of the embryo, independent of its role in regulating Sox2 expression. Rather, HIPPO antagonizes apical localization of Par complex components PARD6B and aPKC. Thus, negative feedback between HIPPO and Par complex components ensure robust lineage segregation.

HIPPO signaling resolves embryonic cell fate conflicts during establishment of pluripotency in vivo

During mammalian development, the challenge for the embryo is to override intrinsic cellular plasticity to drive cells to distinct fates. Here, we unveil novel roles for the HIPPO signaling pathway segregates pluripotent and extraembryonic fates by controlling cell positioning as well as expression of Sox2, the first marker of pluripotency in the mouse early embryo. We show that maternal and zygotic YAP1 and WWTR1 repress Sox2 while promoting expression of the trophectoderm gene Cdx2 in parallel. Yet, Sox2 is more sensitive than Cdx2 to Yap1/Wwtr1 dosage, leading cells to a state of conflicted cell fate when YAP1/WWTR1 activity is moderate. Remarkably, HIPPO signaling activity resolves conflicted cell fate by repositioning cells to the interior of the embryo, independent of its role in regulating Sox2 expression. Rather, HIPPO antagonizes apical localization of Par complex components PARD6B and aPKC. Thus, negative feedback between HIPPO and Par complex components ensure robust lineage segregation.

Collaborations between CpG sites in DNA methylation

DNA methylation patterns have profound impacts on genome stability, gene expression and development. The molecular base of DNA methylation patterns has long been focused at single CpG sites level. Here, we construct a kinetic model of DNA methylation with collaborations between CpG sites, from which a correlation function was established based on experimental data. The function consists of three parts that suggest three possible sources of the correlation: movement of enzymes along DNA, collaboration between DNA methylation and nucleosome modification, and global enzyme concentrations within a cell. Moreover, the collaboration strength between DNA methylation and nucleosome modification is universal for mouse early embryo cells. The obtained correlation function provides insightful understanding for the mechanisms of inheritance of DNA methylation patterns.

Collaborations between CpG sites in DNA methylation

DNA methylation patterns have profound impacts on genome stability, gene expression, and development. The molecular base of DNA methylation patterns has long been focused at single CpG sites level. Here, we construct a kinetic model of DNA methylation with collaborations between CpG sites, from which a correlation function was established based on experimental data. The function consists of three parts that suggest three possible sources of the correlation: movement of enzymes along DNA, collaboration between DNA methylation and nucleosome modification, and global enzyme concentrations within a cell. Moreover, the collaboration strength between DNA methylation and nucleosome modification is universal for mouse early embryo cells. The obtained correlation function provide insightful understanding for the mechanisms of inheritance of DNA methylation patterns.