The endoderm of the mouse embryo arises by dynamic widespread intercalation of embryonic and extraembryonic lineages

The cell movements underlying the morphogenesis of the embryonic endoderm, the tissue that will give rise to the respiratory and digestive tracts, are complex and not well understood. Using live imaging combined with genetic labeling, we investigated the cell behaviors and fate of the visceral endoderm during gut endoderm formation in the mouse gastrula. Contrary to the prevailing view, our data reveal no mass displacement of visceral endoderm to extraembryonic regions concomitant with the emergence of epiblast-derived definitive endoderm. Instead, we observed dispersal of the visceral endoderm epithelium and extensive mixing between cells of visceral endoderm and epiblast origin. Visceral endoderm cells remained associated with the epiblast and were incorporated into the early gut tube. Our findings suggest that the segregation of extraembryonic and embryonic tissues within the mammalian embryo is not as strict as believed and that a lineage previously defined as exclusively extraembryonic contributes cells to the embryo.     

Cell lineage analysis of the primitive and visceral endoderm of mouse embryos cultured in vitro

Cell lineages of the primitive endoderm and the visceral endoderm of mouse embryos were examined by culturing whole embryos in vitro. The primitive endoderm and visceral endoderm cells could be labelled by incubation of embryos in a medium containing horse radish peroxidase (HRP). HRP localization was chased throughout the culture period. The results show that the visceral endoderm derives from the primitive endoderm, and the visceral endoderm forms only the extra-embryonic endoderm (yolk sac endoderm) of the conceptus. The definitive endoderm which is probably derived from the head process, newly appears on the ventral surface of the embryo.     

BMP signaling induces visceral endoderm differentiation of XEN cells and parietal endoderm

The extraembryonic endoderm of mammals is essential for nutritive support of the fetus and patterning of the early embryo. Visceral and parietal endoderm are major subtypes of this lineage with the former exhibiting most, if not all, of the embryonic patterning properties. Extraembryonic endoderm (XEN) cell lines derived from the primitive endoderm of mouse blastocysts represent a cell culture model of this lineage, but are biased towards parietal endoderm in culture and in chimeras. In an effort to promote XEN cells to adopt visceral endoderm character we have mimicked different aspects of the in vivo environment. We found that BMP signaling promoted a mesenchymal-to-epithelial transition of XEN cells with up-regulation of E-cadherin and down-regulation of vimentin. Gene expression analysis showed the differentiated XEN cells most resembled extraembryonic visceral endoderm (exVE), a subtype of VE covering the extraembryonic ectoderm in the early embryo, and during gastrulation it combines with extraembryonic mesoderm to form the definitive yolk sac. We found that laminin, a major component of the extracellular matrix in the early embryo, synergised with BMP to promote highly efficient conversion of XEN cells to exVE. Inhibition of BMP signaling with the chemical inhibitor, Dorsomorphin, prevented this conversion suggesting that Smad1/5/8 activity is critical for exVE induction of XEN cells. Finally, we show that applying our new culture conditions to freshly isolated parietal endoderm (PE) from Reichert's membrane promoted VE differentiation showing that the PE is developmentally plastic and can be reprogrammed to a VE state in response to BMP. Generation of visceral endoderm from XEN cells uncovers the true potential of these blastocyst-derived cells and is a significant step towards modelling early developmental events ex vivo.     

Origin and role of distal visceral endoderm, a group of cells that determines anterior-posterior polarity of the mouse embryo

Anterior-posterior polarity of the mouse embryo has been thought to be established when distal visceral endoderm (DVE) at embryonic day (E) 5.5 migrates toward the future anterior side to form anterior visceral endoderm (AVE). Lefty1, a marker of DVE and AVE, is asymmetrically expressed in implanting mouse embryos. We now show that Lefty1 is expressed first in a subset of epiblast progenitor cells and then in a subset of primitive endoderm progenitors. Genetic fate mapping indicated that the latter cells are destined to become DVE. In contrast to the accepted notion, however, AVE is not derived from DVE but is newly formed after E5.5 from Lefty1(-) visceral endoderm cells that move to the distal tip. Concomitant with DVE migration, all visceral endoderm cells in the embryonic region undergo global movement. In embryos subjected to genetic ablation of Lefty1-expressing DVE cells, AVE was formed de novo but the visceral endoderm including the newly formed AVE failed to migrate, indicating that DVE guides the migration of AVE by initiating the global movement of visceral endoderm cells. Future anterior-posterior polarity is thus already determined by Lefty1(+) blastomeres in the implanting blastocyst.     

Distinct roles for visceral endoderm during embryonic mouse development.

The murine visceral endoderm is an extraembryonic cell layer that appears prior to gastrulation and performs critical functions during embryogenesis. The traditional role ascribed to the visceral endoderm entails nutrient uptake and transport. Besides synthesizing a number of specialized proteins that facilitate uptake, digestion, and secretion of nutrients, the extraembryonic visceral endoderm coordinates blood cell differentiation and vessel formation in the adjoining mesoderm, thereby facilitating efficient exchange of nutrients and gases between the mother and embryo. Recent studies suggest that in addition to this nutrient exchange function the visceral endoderm overlying the egg cylinder stage embryo plays an active role in guiding early development. Cells in the anterior visceral endoderm function as an early organizer. Prior to formation of the primitive streak, these cells express specific gene products that specify the fate of underlying embryonic tissues. In this review we highlight recent investigations demonstrating this dual role for visceral endoderm as a provider of both nutrients and developmental cues for the early embryo.     

The location and synthesis of transferrin in mouse embryos and teratocarcinoma cells

In early postimplantation mouse development, transferrin synthesis appears to be a marker of visceral endoderm cell types. Transferrin was identified using immunoperoxidase staining, in the proximal (visceral) endoderm of the sixth-day egg cylinder, in some tissues at later stages, and in the visceral yolk sac (VYS) at all stages examined. Since the location of a plasma protein does not necessarily indicate its site of synthesis, the incorporation of labeled amino acids into transferrin was studied. Synthesis could be detected in egg cylinders on the seventh day of gestation onwards and in the VYS at all stages. However, although endoderm was the likely tissue source, its ability to synthesize transferrin after its isolation from the embryo was either much reduced or absent. The data are suggestive of a modulating influence by mesoderm and other cell types on transferrin synthesis in visceral endoderm cells. Three types of endoderm-like cells which are produced by teratocarcinoma embryonal carcinoma (EC) cells were analyzed for transferrin synthesis to assess possible parallels with the embryo. Embryoid bodies from PSA1 EC cells contained some outer endoderm cells which stained for transferrin and others which did not. The endoderm line PSA5E but not PYS-2 synthesized transferrin. The third type of endoderm-like cell (END cells) synthesized very little (OC15S1) or no (PC13 clone 5) transferrin. The conclusion that PSA5E, OC15 END, and some differentiated PSA1 cells have visceral endoderm-like character while PYS-2 reflects parietal endoderm phenotype is in agreement with published data.     

Dynamic morphogenetic events characterize the mouse visceral endoderm

Several lines of evidence suggest that the extraembryonic endoderm of vertebrate embryos plays an important role in the development of rostral neural structures. In mice, neural inductive signals are thought to reside in an area of visceral endoderm that expresses the Hex gene. Here, we have conducted a morphological and lineage analysis of visceral endoderm cells spanning pre- and postprimitive streak stages. Our results show that Hex-expressing cells have a tall, columnar epithelial morphology, which distinguishes them from other visceral endoderm cells. This region of visceral endoderm thickening (VET) is found overlying first the distal and then one side of the epiblast at stages between 5.5 and 5.75 days post coitum (d.p.c.). In addition, we show that the epiblast has an anteroposterior-compressed appearance that is aligned with the position of the VET. Intracellular labeling of VET/Hex-expressing cells reveals an anterior and anterolateral shift from their distal epiblast position. VET/Hex-expressing cells are first localized to the anterior side of the epiblast by 5.75 d.p.c. and form a crescent on the anterior half of the embryo at the onset of gastrulation. Subsequently, VET descendants are distributed along the embryonic/extraembryonic boundary by headfold stages at 7.5 d.p.c. The morphological characteristics and position of VET/Hex-expressing cells distinguishes the future anteroposterior axis of the embryo and provide landmarks to stage mouse embryos at preprimitive streak stages. Moreover, the morphological characteristics of pregastrulation mouse embryos together with the stereotyped shift in the position of visceral endoderm cells reveal similarities among amniote embryos that suggest an evolutionary conservation of the mechanisms that pattern the rostral neurectoderm at pregastrula stages.     

High molecular weight extracellular proteins synthesized by endoderm cells derived from mouse teratocarcinoma cells and normal extraembryonic membranes

Rabbit antiserum raised against teratocarcinoma embryoid bodies reacts with two extracellular, collagenase-resistant glycoproteins, PYS A and B, with molecular weights of approximately 350,000 and 220,000 daltons. The 220,000-dalton protein is distinguishable from fibronectin. The two proteins are synthesized and secreted into the medium in large amounts by the teratocarcinoma-derived parietal endoderm line PYS-1, and by normal parietal endoderm cells from the 10.5-day embryo. There was no detectable synthesis of PYS A and B by normal visceral endoderm cells isolated from the 10.5-day embryo, and only trace amounts of PYS A were synthesized by the teratocarcinoma-derived visceral endoderm line PSA5E and by mesodermal cells isolated from the visceral yolk sac. The two proteins therefore seem to be good biochemical markers for distinguishing parietal from visceral endoderm cells. Synthesis and secretion of PYS A and B could not be detected in undifferentiated embryonal carcinoma cells or in endoderm cells derived from them in the presence of retinoic acid.     

Conversion of ES cells to columnar epithelia by hensin and to squamous epithelia by laminin

Single-layered epithelia are the first differentiated cell types to develop in the embryo, with columnar and squamous types appearing immediately after blastocyst implantation. Here, we show that mouse embryonic stem cells seeded on hensin or laminin, but not fibronectin or collagen type IV, formed hemispheric epithelial structures whose outermost layer terminally differentiated to an epithelium that resembled the visceral endoderm. Hensin induced columnar epithelia, whereas laminin formed squamous epithelia. At the egg cylinder stage, the distal visceral endoderm is columnar, and these cells begin to migrate anteriorly to create the anterior visceral endoderm, which assumes a squamous shape. Hensin expression coincided with the dynamic appearance and disappearance of columnar cells at the egg cylinder stage of the embryo. These expression patterns, and the fact that hensin null embryos (and those already reported for laminin) die at the onset of egg cylinder formation, support the view that hensin and laminin are required for terminal differentiation of columnar and squamous epithelial phenotypes during early embryogenesis.     

Regulation of extra-embryonic endoderm stem cell differentiation by Nodal and Cripto signaling

The signaling pathway for Nodal, a ligand of the TGFβ superfamily, plays a central role in regulating the differentiation and/or maintenance of stem cell types that can be derived from the peri-implantation mouse embryo. Extra-embryonic endoderm stem (XEN) cells resemble the primitive endoderm of the blastocyst, which normally gives rise to the parietal and the visceral endoderm in vivo, but XEN cells do not contribute efficiently to the visceral endoderm in chimeric embryos. We have found that XEN cells treated with Nodal or Cripto (Tdgf1), an EGF-CFC co-receptor for Nodal, display upregulation of markers for visceral endoderm as well as anterior visceral endoderm (AVE), and can contribute to visceral endoderm and AVE in chimeric embryos. In culture, XEN cells do not express Cripto, but do express the related EGF-CFC co-receptor Cryptic (Cfc1), and require Cryptic for Nodal signaling. Notably, the response to Nodal is inhibited by the Alk4/Alk5/Alk7 inhibitor SB431542, but the response to Cripto is unaffected, suggesting that the activity of Cripto is at least partially independent of type I receptor kinase activity. Gene set enrichment analysis of genome-wide expression signatures generated from XEN cells under these treatment conditions confirmed the differing responses of Nodal- and Cripto-treated XEN cells to SB431542. Our findings define distinct pathways for Nodal and Cripto in the differentiation of visceral endoderm and AVE from XEN cells and provide new insights into the specification of these cell types in vivo.     

Visceral endoderm induces specification of cardiomyocytes in mice

The endoderm plays an inductive role in the formation of cardiomyocytes in many vertebrates. Here, we provide further evidence for this in the mouse and demonstrate enhanced cardiomyogenesis in mouse embryonic stem cells cultured in the presence of native visceral endoderm. Isolated mesoderm from late-primitive streak stage mouse embryos that still have an open proamniotic canal had a reduced capacity to form cardiomyocytes after 4 days in culture compared with mesoderm isolated from later stages but prior to cardiomyogenesis. Moreover, removal of the visceral endoderm but not the primitive streak reduced the formation of beating areas in embryo explants in culture. Coculture with the END2 cell line, which has visceral endoderm-like properties, restored the formation of beating areas. Immunohistochemical analysis showed that the expected candidate signaling pathways downstream of Wnts and bone morphogenetic proteins (BMPs) were active in the embryo at the appropriate time and place to be involved. Overall, the results show that, as in other vertebrates, the (visceral) endoderm plays an important role in the early events of mouse cardiomyogenesis.     

F9 teratocarcinoma aggregates express villin upon differentiation into visceral endoderm-like cells

The visceral endoderm of the mouse embryo is a polarized epithelium which has recently been shown to express villin, a major actin binding component of absorptive epitheliums. We report here that villin is induced during differentiation of aggregates of the mouse embryonal carcinoma F9, an in vitro system widely used to study extraembryonic endoderm differentiation. Identical results were obtained with a variant of F9 which carries an immortalizing vector. Villin is coexpressed with F-actin and with alpha-foetoprotein, in most of the visceral endoderm-like cells lining the aggregates. This system is potentially useful to study (i) the induction of villin expression and (ii) the establishment of polarity in the visceral endoderm epithelium.     

Differential localization of TGF-beta 2 in mouse preimplantation and early postimplantation development

The localization of transforming growth factor type beta 2 (TGF-beta 2) has been followed during preimplantation and early postimplantation murine development using an anti-peptide antibody that specifically recognizes TGF-beta 2. The staining pattern showed that TGF-beta 2 is expressed from the four-cell stage onward and is differentially regulated as cells diverge to various lineages. High levels of staining were found in the trophectoderm of the blastocyst but no staining was observed in the inner cell mass. During postimplantation development the primitive and embryonic ectoderm also lacked detectable staining while visceral endoderm stained well. Parietal endoderm cells also showed positive staining reaction although to a lesser extent than visceral endoderm cells. These findings were confirmed in model systems of the embryo, namely, embryonal carcinoma and embryonic stem cells differentiated to to cells with either visceral or parietal endoderm characteristics. The possible regulatory role of this factor in early embryogenesis is discussed.     

Cell fate, morphogenetic movement and population kinetics of embryonic endoderm at the time of germ layer formation in the mouse

The fate of the embryonic endoderm (generally called visceral embryonic endoderm) of prestreak and early primitive streak stages of the mouse embryo was studied in vitro by microinjecting horseradish peroxidase into single axial endoderm cells of 6.7-day-old embryos and tracing the labelled descendants either through gastrulation (1 day of culture) or to early somite stages (2 days of culture). Descendants of endoderm cells from the anterior half of the axis were found at the extreme cranial end of the embryo after 1 day and in the visceral yolk sac endoderm after 2 days, i.e. they were displaced anteriorly and anterolaterally. Descendants of cells originating over and near the anterior end of the early primitive streak, i.e. posterior to the distal tip of the egg cylinder, were found after 1 day over the entire embryonic axis and after 2 days in the embryonic endoderm at the anterior intestinal portal, in the foregut, along the trunk and postnodally, as well as anteriorly and posteriorly in the visceral yolk sac. Endoderm covering the posterior half of the early primitive streak contributed to postnodal endoderm after 1 day (at the late streak stage) and mainly to posterior visceral yolk sac endoderm after 2 days. Clonal descendants of axial endoderm were located after 2 days either over the embryo or in the yolk sac; the few exceptions spanned the caudal end of the embryo and the posterior yolk sac. The clonal analysis also showed that the endoderm layer along the posterior half of the axis of prestreak- and early-streak-stage embryos is heterogeneous in its germ layer fate. Whereas the germ layer location of descendants from anterior sites did not differ after 1 day from that expected from the initial controls (approx. 90% exclusively in endoderm), only 62% of the successfully injected posterior sites resulted in labelled cells exclusively in endoderm; the remainder contributed partially or entirely to ectoderm and mesoderm. This loss from the endoderm layer was compensated by posterior-derived cells that remained in endoderm having more surviving descendants (8.4 h population doubling time) than did anterior-derived cells (10.5 h population doubling time). There was no indication of cell death at the prestreak and early streak stages; at least 93% of the cells were proliferating and more than half of the total axial population were in, or had completed, a third cell cycle after 22 h culture.(ABSTRACT TRUNCATED AT 400 WORDS)     

Evidence for the existence of an early common biochemical pathway in the differentiation of F9 cells into visceral or parietal endoderm: Modulation by cyclic AMP

The addition of dibutyryl cyclic AMP (dbcAMP) to aggregate cultures of F9 cells in medium containing retinoic acid (RA) directs the pathway of differentiation into parietal endoderm instead of visceral endoderm. We examined the levels of some of the markers that characterize the two pathways and studied the time of commitment of cells to either direction of differentiation by using immunoprecipitation and enzyme-linked immunosorbent assays (ELISA). For either pathway, the levels and patterns of laminin, type IV collagen, and fibronectin are the same on the first day of differentiation, characterized by slightly decreased levels of laminin and type IV collagen synthesis and an increased level of fibronectin synthesis. These levels reverse on the second day of culture when the pathways diverge markedly. The differentiation pathway, however, can be redirected into the alternate one; parietal endoderm cells become committed after 3 days, whereas visceral endoderm cells are able to change into parietal endoderm cells at any time. Thus, α-fetoprotein (AFP)-producing F9 embryoid bodies switched to dbcAMP-containing medium lose the capacity to synthesize AFP and start to express genes characteristic of parietal endoderm. Our results indicate that at least some visceral endoderm cells may redifferentiate into parietal endoderm cells. These phenomena thus mimic features of endoderm differentiation in the mouse embryo.     

Rac1-Dependent Collective Cell Migration Is Required for Specification of the Anterior-Posterior Body Axis of the Mouse

Cell migration and cell rearrangements are critical for establishment of the body plan of vertebrate embryos. The first step in organization of the body plan of the mouse embryo, specification of the anterior-posterior body axis, depends on migration of the anterior visceral endoderm from the distal tip of the embryo to a more proximal region overlying the future head. The anterior visceral endoderm (AVE) is a cluster of extra-embryonic cells that secretes inhibitors of the Wnt and Nodal pathways to inhibit posterior development. Because Rac proteins are crucial regulators of cell migration and mouse Rac1 mutants die early in development, we tested whether Rac1 plays a role in AVE migration. Here we show that Rac1 mutant embryos fail to specify an anterior-posterior axis and, instead, express posterior markers in a ring around the embryonic circumference. Cells that express the molecular markers of the AVE are properly specified in Rac1 mutants but remain at the distal tip of the embryo at the time when migration should take place. Using tissue specific deletions, we show that Rac1 acts autonomously within the visceral endoderm to promote cell migration. High-resolution imaging shows that the leading wild-type AVE cells extend long lamellar protrusions that span several cell diameters and are polarized in the direction of cell movement. These projections are tipped by filopodia-like structures that appear to sample the environment. Wild-type AVE cells display hallmarks of collective cell migration: they retain tight and adherens junctions as they migrate and exchange neighbors within the plane of the visceral endoderm epithelium. Analysis of mutant embryos shows that Rac1 is not required for intercellular signaling, survival, proliferation, or adhesion in the visceral endoderm but is necessary for the ability of visceral endoderm cells to extend projections, change shape, and exchange neighbors. The data show that Rac1-mediated epithelial migration of the AVE is a crucial step in the establishment of the mammalian body plan and suggest that Rac1 is essential for collective migration in mammalian tissues.     

Cell fate and cell lineage in the endoderm of the presomite mouse embryo, studied with an intracellular tracer

The fate of the embryonic endoderm (generally called visceral embryonic endoderm) of midstreak to neural plate stages of the mouse embryo was studied by microinjecting horseradish peroxidase (HRP) into single axial endoderm cells in situ, and tracing the labeled descendants to early somite stages in vitro. Axial endoderm cells along the anterior fifth of the late streak/neural plate stage embryo contributed descendants either to the yolk sac endoderm or to the anterior intestinal portal. Cells of the exposed head process contributed to the trunk endoderm and notochord; neighboring endoderm cells contributed to the dorsal foregut. Contributions to the ventral foregut came from endoderm at, and anterior to, the distal tip of the younger, midstreak embryo (in which the head process was not yet exposed). Endoderm over the primitive streak contributed to the postsomite endoderm. We argue from these results and those in the literature that during gastrulation the axial embryonic endoderm is of mixed lineage: (1) an anterior population of cells is derived from primitive endoderm and contributes to the yolk sac endoderm; (2) a population at, and anterior to, the distal tip of the midstreak embryo, extending more anteriorly at late streak/neural plate stages, is presumed to emerge from primitive ectoderm at the beginning of gastrulation and contributes to the foregut and anterior intestinal portal; (3) the axial portion of the head process that begins to incorporate into the ventral surface at the late streak stage contributes to notochord and trunk endoderm. Cells or their descendants that were destined to die within 24 hr were evident at the midstreak stage. There was a linear trend in the incidence of cell death among labeled cells at the late streak/neural plate stages, ranging from 27% caudal to the node to 57% in the anterior fifth of the embryo. The surviving axial endoderm cells divided sufficiently fast to double the population in 24 hr.     

Dual roles for the Dab2 adaptor protein in embryonic development and kidney transport

The Disabled-2 (Dab2) gene has been proposed to act as a tumor suppressor. Cell culture studies have implicated Dab2 in signal transduction by mitogens, TGFbeta and endocytosis of lipoprotein receptors. To identify in vivo functions of Dab2, targeted mutations were made in the mouse. In the absence of Dab2, embryos arrest prior to gastrulation with a phenotype reminiscent of those caused by deletion of some TGFbeta signal transduction molecules involved in Nodal signaling. Dab2 is expressed in the extra-embryonic visceral endoderm but not in the epiblast. Dab2 could be conditionally deleted from the embryo without affecting normal development, showing that Dab2 is required in the visceral endoderm but dispensable in the embryo proper. Conditionally mutant Dab2(-/-) mice are overtly normal, but have reduced clathrin-coated pits in kidney proximal tubule cells and excrete specific plasma proteins in the urine, consistent with reduced transport by a lipoprotein receptor, megalin/gp330, in the proximal tubule. This evidence indicates that Dab2 is pleiotropic and regulates both visceral endoderm function and lipoprotein receptor trafficking in vivo.     

Canonical Wnt signaling and its antagonist regulate anterior-posterior axis polarization by guiding cell migration in mouse visceral endoderm

The mouse embryonic axis is initially formed with a proximal-distal orientation followed by subsequent conversion to a prospective anterior-posterior (A-P) polarity with directional migration of visceral endoderm cells. Importantly, Otx2, a homeobox gene, is essential to this developmental process. However, the genetic regulatory mechanism governing axis conversion is poorly understood. Here, defective axis conversion due to Otx2 deficiency can be rescued by expression of Dkk1, a Wnt antagonist, or following removal of one copy of the beta-catenin gene. Misexpression of a canonical Wnt ligand can also inhibit correct A-P axis rotation. Moreover, asymmetrical distribution of beta-catenin localization is impaired in the Otx2-deficient and Wnt-misexpressing visceral endoderm. Concurrently, canonical Wnt and Dkk1 function as repulsive and attractive guidance cues, respectively, in the migration of visceral endoderm cells. We propose that Wnt/beta-catenin signaling mediates A-P axis polarization by guiding cell migration toward the prospective anterior in the pregastrula mouse embryo.