Definitive endoderm of the mouse embryo: formation, cell fates, and morphogenetic function

Regionalisation of the endoderm progenitors and morphogenesis of the gut portals of the mouse embryo

This fate-mapping study reveals that the progenitors of all major parts of the embryonic gut are already present in endoderm of the early-head-fold to early-somite stage (1-9 somites) mouse embryo. The anterior endoderm contributes primarily to the anterior intestinal portal of the early-organogenesis stage (16-19 somites) embryo. Endoderm cells around and lateral to the node are allocated to the open "midgut" region of the embryonic gut. The posterior (post-nodal) endoderm contributes not only to the posterior intestinal portal but also the open "midgut". Descendants of the posterior endoderm span a length of the gut from the level of the 3rd-5th somites to the posterior end of the embryonic gut. The formation of the anterior and posterior intestinal portals is accompanied by similar repertoires of morphogenetic tissue movement. We also discovered that cells on contralateral sides of the anterior endoderm are distributed asymmetrically to the dorsal and ventral sides of the anterior intestinal portal, heralding the acquisition of laterality by the embryonic foregut.

Translational embryology: using embryonic principles to generate pancreatic endocrine cells from embryonic stem cells

Diseases that affect endodermally derived organs such as the lungs, liver, and pancreas include cystic fibrosis, chronic hepatitis, and diabetes, respectively. Despite the prevalence of these diseases, cures remain elusive. While several promising transplantation-based therapies exist for some diseases such as Type 1 diabetes, they are currently limited by the availability of donor-derived tissues. Embryonic stem cells are a promising and renewable source of tissue for transplantation; however, directing their differentiation into specific, adult cell lineages remains a significant challenge. In this review, we will focus on one endodermally derived organ, the pancreas, and discuss how studies of embryonic pancreas development have been used as the basis for the directed, step-wise differentiation of mouse and human embryonic stem cells into pancreatic endocrine cells that are capable of rescuing Type 1 diabetes in animal models.

The Gata5 target, TGIF2, defines the pancreatic region by modulating BMP signals within the endoderm

Mechanisms underlying regional specification of distinct organ precursors within the endoderm, including the liver and pancreas, are still poorly understood. This is particularly true for stages between endoderm formation and the initiation of organogenesis. In this report, we have investigated these intermediate steps downstream of the early endodermal factor Gata5, which progressively lead to the induction of pancreatic fate. We have identified TGIF2 as a novel Gata5 target and demonstrate its function in the establishment of the pancreatic region within dorsal endoderm in Xenopus. TGIF2 acts primarily by restricting BMP signaling in the endoderm to allow pancreatic formation. Consistently, we found that blocking BMP signaling by independent means also perturbs the establishment of pancreatic identity in the endoderm. Previous findings demonstrated a crucial role for BMP signaling in determining dorsal/ventral fates in ectoderm and mesoderm. Our results now extend this trend to the endoderm and identify TGIF2 as the molecular link between dorsoventral patterning of the endoderm and pancreatic specification.

A systematic screen for genes expressed in definitive endoderm by Serial Analysis of Gene Expression (SAGE)

Background

The embryonic definitive endoderm (DE) gives rise to organs of the gastrointestinal and respiratory tract including the liver, pancreas and epithelia of the lung and colon. Understanding how DE progenitor cells generate these tissues is critical to understanding the cause of visceral organ disorders and cancers, and will ultimately lead to novel therapies including tissue and organ regeneration. However, investigation into the molecular mechanisms of DE differentiation has been hindered by the lack of early DE-specific markers.

Results

We describe the identification of novel as well as known genes that are expressed in DE using Serial Analysis of Gene Expression (SAGE). We generated and analyzed three longSAGE libraries from early DE of murine embryos: early whole definitive endoderm (0–6 somite stage), foregut (8–12 somite stage), and hindgut (8–12 somite stage). A list of candidate genes enriched for expression in endoderm was compiled through comparisons within these three endoderm libraries and against 133 mouse longSAGE libraries generated by the Mouse Atlas of Gene Expression Project encompassing multiple embryonic tissues and stages. Using whole mount in situ hybridization, we confirmed that 22/32 (69%) genes showed previously uncharacterized expression in the DE. Importantly, two genes identified, Pyy and 5730521E12Rik, showed exclusive DE expression at early stages of endoderm patterning.

Conclusion

The high efficiency of this endoderm screen indicates that our approach can be successfully used to analyze and validate the vast amount of data obtained by the Mouse Atlas of Gene Expression Project. Importantly, these novel early endoderm-expressing genes will be valuable for further investigation into the molecular mechanisms that regulate endoderm development.

Directed Differentiation of Human Embryonic Stem Cells into the Pancreatic Endocrine Lineage

Human embryonic stem (hES) cells represent a potentially unlimited source of transplantable beta-cells for the treatment of diabetes. Here we describe a differentiation strategy that reproducibly directs HES3, an National Institutes of Health (NIH)-registered hES cell line, into cells of the pancreatic endocrine lineage. HES3 cells are removed from their feeder layer and cultured as embryoid bodies in a three-dimensional matrix in the presence of Activin A and Bmp4 to induce definitive endoderm. Next, growth factors known to promote the proliferation and differentiation of pancreatic ductal epithelial cells to glucose-sensing, insulin-secreting beta-cells are added. Pdx1 expression, which identifies pancreatic progenitors, is detected as early as day 12 of differentiation. By day 34, Pdx1+ cells comprise between 5% and 20% of the total cell population and Insulin gene expression is up-regulated, with release of C-peptide into the culture medium. Unlike another recent report of the induction of insulin+ cells in differentiated hES cell populations, we are unable to detect the expression of other pancreatic hormones in insulin+ cells. When transplanted into severe combined immunodeficiency (SCID) mice, differentiated cell populations retain their endocrine identity and synthesize insulin.

Dissecting the molecular hierarchy for mesendoderm differentiation through a combination of embryonic stem cell culture and RNA interference

Although there is a criticism that embryonic stem (ES) cell differentiation does not always reflect the differentiation process involved in mouse development, it is a suitable model system to dissect the specific differentiation pathway. We established the culture conditions that selectively differentiated mouse ES cells into three germ layers containing mesendoderm, definitive endoderm (DE), visceral endoderm (VE), mesoderm, and neuroectoderm. However, the molecular mechanisms of differentiation under each specific condition still remain unclear. Here, in combination with the RNA interference-mediated gene knockdown (KD) method, we show that Eomesodermin (Eomes), Mixl1, Brachyury (T), and GATA6 are major molecular determinants in the differentiation of mesendoderm, DE, VE, and mesoderm. Eomes plays a pivotal role in an early stage of mesendoderm differentiation, whereas Mixl1 does the same in the later stage where mesendoderm differentiates into DE. Further analyses of quantitative reverse transcription polymerase chain reaction and overexpression of Mixl1 demonstrated that Mixl1 is genetically a downstream molecule of Eomes. In addition, both Eomes and Mixl1 act as negative regulators of T expression. This strategy also reveals that Eomes and T play cell-autonomous roles in platelet-derived growth factor receptor alpha (PDGFRalpha)+ vascular endothelial growth factor receptor 2 (VEGFR2)+ and PDGFRalpha+ mesoderm generations, respectively. Our results obtained from this study are fully consistent with previous knockout studies of those genes. The present study, therefore, demonstrates that the major molecular mechanism underlying in vitro ES cell differentiation largely recapitulates that in actual embryogenesis, and the combination of our culture system and RNAi-mediated gene KD is an useful tool to elucidate the molecular hierarchy in in vitro ES cell differentiation. Disclosure of potential conflicts of interest is found at the end of this article.

Gene function in mouse embryogenesis: get set for gastrulation

During early mouse embryogenesis, temporal and spatial regulation of gene expression and cell signalling influences lineage specification, embryonic polarity, the patterning of tissue progenitors and the morphogenetic movement of cells and tissues. Uniquely in mammals, the extraembryonic tissues are the source of signals for lineage specification and tissue patterning. Here we discuss recent discoveries about the lead up to gastrulation, including early manifestations of asymmetry, coordination of cell and tissue movements and the interactions of transcription factors and signalling activity for lineage allocation and germ-layer specification.

Intestinal morphogenesis

PURPOSE OF REVIEW

The molecular basis of endoderm differentiation and interaction with mesoderm to generate the mature intestine has been the focus of intensive investigation. Signaling pathways relevant to organogenesis may be recapitulated during oncogenesis. This review highlights recent studies of endoderm specification, differentiation and formation of the gut tube, the ontogeny of regional differentiation along the anterior-posterior and crypt-villus axes, and mechanisms of epithelial differentiation and epithelial-mesenchymal interactions during gut morphogenesis.

RECENT FINDINGS

Model organisms include zebrafish, Xenopus, Drosophila and the mouse. Fibroblast growth factors play critical roles in early endoderm differentiation and anterior-posterior patterning, and retinoids regulate left-right asymmetry and gut looping/rotation. Embryoid bodies derived from embryonic stem cells recapitulate many aspects of gut epithelial morphogenesis. Novel regulators of epithelial cell differentiation and epithelial-mesenchymal interactions have been identified (e.g. Mtgr1), and several known genes modulate these processes (e.g. PPARbeta/delta, Ptk6, GATA4). The role of Bmp, Hh and wnt signaling in morphogenesis continues to be elucidated.

SUMMARY

The complex process of intestinal morphogenesis involves interactions among multiple signaling pathways. Studies of morphogenesis are critical for elucidating the molecular basis of congenital gut defects and provide novel insight into intestinal oncogenic processes.

Nodal signaling: developmental roles and regulation

Nodal-related ligands of the transforming growth factor-beta (TGFbeta) superfamily play central roles in patterning the early embryo during the induction of mesoderm and endoderm and the specification of left-right asymmetry. Additional roles for this pathway in the maintenance of embryonic stem cell pluripotency and in carcinogenesis have been uncovered more recently. Consistent with its crucial developmental functions, Nodal signaling is tightly regulated by diverse mechanisms including the control of ligand processing, utilization of co-receptors, expression of soluble antagonists, as well as positive- and negative-feedback activities.

Nutritional endoderm in a direct developing frog: A potential parallel to the evolution of the amniote egg

The egg of the direct-developing frog, Eleutherodactylus coqui, has 20 x the volume as that of the model amphibian, Xenopus laevis. Increased egg size led to the origin of nutritional endoderm, a novel cell type that provides nutrition but does not differentiate into digestive tract tissues. As the E. coqui endoderm develops, a distinct boundary exists between differentiating intestinal cells and large yolky cells, which persists even when yolk platelets are depleted. The yolky cells do not become tissues of the digestive tract and are lost, as shown by histology and lineage tracing. EcSox17, an endodermal transcriptional factor, did not distinguish these two cell types, however. When cleavage of the yolky cells was inhibited, embryogenesis continued, indicating that some degree of incomplete cleavage can be tolerated. The presence of cellularized nutritional endoderm in E. coqui may parallel changes that occurred in the evolution of the amniote egg 360 million years ago.

Targeted disruption of cubilin reveals essential developmental roles in the structure and function of endoderm and in somite formation

Background

Cubilin is a peripheral membrane protein that interacts with the integral membrane proteins megalin and amnionless to mediate ligand endocytosis by absorptive epithelia such as the extraembryonic visceral endoderm (VE).

Results

Here we report the effects of the genetic deletion of cubilin on mouse embryonic development. Cubilin gene deletion is homozygous embryonic lethal with death occurring between 7.5–13.5 days post coitum (dpc). Cubilin-deficient embryos display developmental retardation and do not advance morphologically beyond the gross appearance of wild-type 8–8.5 dpc embryos. While mesodermal structures such as the allantois and the heart are formed in cubilin mutants, other mesoderm-derived tissues are anomalous or absent. Yolk sac blood islands are formed in cubilin mutants but are unusually large, and the yolk sac blood vessels fail to undergo remodeling. Furthermore, somite formation does not occur in cubilin mutants. Morphological abnormalities of endoderm occur in cubilin mutants and include a stratified epithelium in place of the normally simple columnar VE epithelium and a stratified cuboidal epithelium in place of the normally simple squamous epithelium of the definitive endoderm. Cubilin-deficient VE is also functionally defective, unable to mediate uptake of maternally derived high-density lipoprotein (HDL).

Conclusion

In summary, cubilin is required for embryonic development and is essential for the formation of somites, definitive endoderm and VE and for the absorptive function of VE including the process of maternal-embryo transport of HDL.