In
mammalian embryogenesis, differentiation and segregation of cells composing the inner cell mass of the blastocyst yields two distinct layers—the epiblast ("primitive ectoderm") and the
hypoblast ("primitive endoderm"). While the
cuboidal hypoblast cells delaminate ventrally, away from the embryonic pole, to line the
blastocoele, the remaining cells of the inner cell mass, situated between the hypoblast and the polar
trophoblast, become the epiblast and comprise
columnar cells. In the mouse, primordial
germ cells are specified from epiblast cells. This specification is accompanied by extensive
epigenetic reprogramming that involves global
DNA demethylation,
chromatin reorganization and imprint erasure leading to
totipotency. Upon commencement of
gastrulation, the
primitive streak, a visible, morphological linear band of cells, appears on the posterior epiblast and orients along the anterior-posterior embryo axis. Initiated by signals from the underlying hypoblast, formation of the primitive streak is predicated on epiblast cell migration, mediated by
Nodal, from the lateral-posterior regions of the epiblast to the center midline. The
primitive node is situated at the anterior end of the primitive streak and serves as the organizer for gastrulation, determining epiblast cell fate by inducing the differentiation of migrating epiblast cells during gastrulation. During gastrulation, migrating epiblast cells undergo
epithelial-mesenchymal transition in order to lose cell-cell adhesion (
E-cadherin), delaminate from the epiblast layer and migrate over the dorsal surface of the epiblast then down through the primitive streak. The first wave of epiblast cells to invaginate through the primitive streak invades and displaces the hypoblast to become the embryonic endoderm. The mesoderm layer is established next as migrating epiblast cells move through the primitive streak then spread out within the space between the endoderm and remaining epiblast, which once the mesoderm layer has formed ultimately becomes the definitive ectoderm. The process of gastrulation results in a
trilaminar germ disc, consisting of the ectoderm, mesoderm and endoderm layers.
Epiblast diversity Epiblasts exhibit diverse structure across species as a result of early embryo morphogenesis. The human epiblast assumes a disc shape, conforming to the embryonic disc morphology; whereas, the mouse epiblast develops in a cup shape within the cylindrical embryo. During
implantation of the blastocyst, both the human and mouse epiblasts form a rosette shape in a process called polarization. Polarization results from the interaction between the mammalian blastocyst and β1-integrin from the
extracellular matrix, produced from the extra-embryonic tissues. At this stage, both human and mouse epiblasts consist of a
pseudostratified columnar epithelium. Shortly after, the human epiblast will assume a disc shape while the amniotic cavity forms. The epiblast cells adjacent to the trophoblast are specified to become
amnion cells. The mouse epiblast transitions from a rosette structure to a cup. A pro-amniotic cavity forms, surrounded by the epiblast cup fused to extraembryonic ectoderm. Mouse epiblast cells are not specified to amnion cell fate. ==Birds==