Characterization of mouse A33 antigen, a definitive marker for basolateral surfaces of intestinal epithelial cells

The murine A33 antigen is emerging as a definitive marker of intestinal epithelial cells. Cloning and sequence determination of cDNAs encoding mA33 antigen predict a novel type 1 transmembrane protein of 298 amino acids, comprising an extracellular domain with two immunoglobulin-like domains, a single-span transmembrane domain, and a highly acidic cytoplasmic domain. On the basis of conservation of amino acid sequence and genomic structure, the mA33 antigen is a member of a growing subfamily within the immunoglobulin superfamily, which includes transmembrane proteins CTX/ChT1, CTM/CTH, and CAR. During embryonic development, mA33 antigen expression is first observed in the inner cell mass of blastocysts before implantation. Intestinal expression of mA33 antigen is initiated in the hindgut at E14.5 and increases steadily throughout late embryonic and postnatal life into adulthood. The protein is specifically expressed on the basolateral surfaces of intestinal epithelial cells of all lineages, independent of their position along the rostrocaudal and crypt-villus axes. Thus the mA33 antigen appears to be a novel marker for both proliferating and differentiating intestinal epithelial cells.     

Growth of intestinal epithelium in organ culture is dependent on EGF signalling

Differentiation of endoderm into intestinal epithelium is initiated at E13.5 of mouse development when there are significant changes in morphology resulting in the conversion of undifferentiated stratified epithelium into a mature epithelial monolayer. Here we demonstrate that monolayer formation is associated with the selective apoptosis of superficial cells lining the lumen while cell proliferation is progressively restricted to cells adjacent to the basement membrane. We describe an innovative embryonic gut culture system that maintains the three-dimensional architecture of gut and in which these processes are recapitulated in vitro. Explants taken from specific regions of the gut and placed into organ culture develop and express molecular markers (Cdx1, Cdx2 and A33 antigen) in the same spatial and temporal pattern observed in vivo indicating that regional specification is maintained. Inhibition of the epidermal growth factor receptor (EGFR) tyrosine kinase using the specific inhibitor AG1478 significantly reduced the proliferation and survival of cells within the epithelial cell layer of cultured gut explants. This demonstrates an essential role for the EGF signalling pathway during the early stages of intestinal development.     

Rhou maintains the epithelial architecture and facilitates differentiation of the foregut endoderm

Rhou encodes a Cdc42-related atypical Rho GTPase that influences actin organization in cultured cells. In mouse embryos at early-somite to early-organogenesis stages, Rhou is expressed in the columnar endoderm epithelium lining the lateral and ventral wall of the anterior intestinal portal. During foregut development, Rhou is downregulated in regions where the epithelium acquires a multilayered morphology heralding the budding of organ primordia. In embryos generated from Rhou knockdown embryonic stem (ES) cells, the embryonic foregut displays an abnormally flattened shape. The epithelial architecture of the endoderm is disrupted, the cells are depleted of microvilli and the phalloidin-stained F-actin content of their sub-apical cortical domain is reduced. Rhou-deficient cells in ES cell-derived embryos and embryoid bodies are less efficient in endoderm differentiation. Impaired endoderm differentiation of Rhou-deficient ES cells is accompanied by reduced expression of c-Jun/AP-1 target genes, consistent with a role for Rhou in regulating JNK activity. Downregulation of Rhou in individual endoderm cells results in a reduced ability of these cells to occupy the apical territory of the epithelium. Our findings highlight epithelial morphogenesis as a required intermediate step in the differentiation of endoderm progenitors. In vivo, Rhou activity maintains the epithelial architecture of the endoderm progenitors, and its downregulation accompanies the transition of the columnar epithelium in the embryonic foregut to a multilayered cell sheet during organ formation.     

Sonic hedgehog expression in developing chicken digestive organs is regulated by epithelial–mesenchymal interactions

Sonic hedgehog (Shh) gene encodes a secreted protein that acts as an important mediator of cell–cell interactions. A detailed analysis of Shh expression in the digestive organs of the chicken embryo was carried out. Shh expression in the endoderm begins at stage 7, when the formation of the foregut commences, and is found as narrow bands in the midgut. Shh expression around the anterior intestinal portal at stage 15 is restricted to the columnar endoderm lined by the thick splanchnic mesoderm, suggesting that the existence of thick splanchnic mesoderm might be necessary for Shh expression in the columnar endoderm. After the gut is closed, Shh expression is found universally in digestive epithelia, including the cecal epithelium. However, its expression ceases in the epithelium of the proventricular glands, the ductus choledochus and ductus pancreaticus that protrude from the main digestive duct. When the gizzard epithelium differentiated into glands under the influence of the proventricular mesenchyme, the glandular epithelium lost the ability to express Shh . These findings suggest that Shh expression in the epithelium may be regulated by surrounding mesenchyme throughout organogenesis of the digestive organs and is closely involved in epithelial–mesenchymal interactions in developing digestive organs.     

Molecular analysis of the determination of developmental fate in the small intestinal epithelium in the chicken embryo

Determination of the developmental fate in the small intestinal epithelium of the chicken embryo has not been fully analyzed up to the present. This study was carried out to analyze the determination time of the developmental fate of the small intestinal epithelium under the influence of other mesenchymes. The small intestinal epithelium reassociated and cultivated with the proventricular or gizzard mesenchyme or the dermis expressed chicken intestinal fatty acid binding protein, sucrase and CdxA as occurs during the normal development of the small intestinal epithelium. The presumptive intestinal endoderm taken from an earlier stage embryo and associated and cultivated with the proventricular or gizzard mesenchyme, showed gene expression patterns which were the same as those found in normal development. However, when the dermis was associated, the epithelium expressed sonic hedgehog, but never expressed intestinal epithelial- or stomach epithelial-markers. These results indicate that the determination of the developmental fate in the small intestinal epithelium and acquisition of autodifferentiation potency occur at the early stage of the gut development. Moreover the presumptive intestinal endoderm needs the supportive influence of the gut mesenchyme in order to differentiate fully into the intestinal epithelium.     

Early Determination of Developmental Fate in Presumptive Intestinal Endoderm of the Chicken Embryo

The endodermal epithelia of esophagus, proventriculus and gizzard of 6-day chicken embryos can form glands and express embryonic chicken pepsinogen (ECPg), when they are subjected to the influence of proventricular mesenchyme, while intestinal epithelium of the same age cannot respond to the inductive influence of proventricular mesenchyme. We attempted in this paper to know whether this regional difference of epithelia to respond to mesenchymal influence originates very early in development or it is established gradually in the course of development of digestive tract.
The young presumptive intestinal endoderm taken from embryos having 15–20 somites was associated and cultivated with 6-day proventricular mesenchyme. The presumptive intestinal endoderm never expressed ECPg although it formed gland-like structures. In the control explants composed of presumptive stomach endoderm and proventricular mesenchyme, glands were formed and gland cells expressed ECPg detected by immunocytochemistry and in situ hybridization.
These results indicate that the developmental fate of presumptive intestinal endoderm is determined rather strictly at very early developmental stage, and suggest that the segregation of at least two cell lineages occurs early in the development; one which can express ECPg under the influence of proventricular mesenchyme, and another one which cannot express ECPg and differentiates mainly into intestinal epithelium.     

Smooth muscle actin expression during rat gut development and induction in fetal skin fibroblastic cells associated with intestinal embryonic epithelium

Abstract. Cytodifferentiation of smooth muscle cells has been analyzed immunocytochemically during rat intestinal development and in chimaeric intestines by using monoclonal antibodies reacting specifically with smooth muscle actin species ( CGA7 [10] and anti-α SM-1 [40]). As development proceeds, the various intestinal muscle layers differentiate in the following order: (1) cells expressing smooth muscle actin appear within the mesenchyme of the 15-day fetal rat intestine, in the circular muscle-forming area, the differentiation of cells in the presumptive longitudinal muscle layer starting with a 48-h delay; (2) smooth muscle fibers appear within the connective tissue core of the villi shortly after birth, in parallel with a progressive formation of the muscularis mucosae, which becomes clear-cut only in the course of the 2nd week after birth; (3) a distinct cell layer in the innermost part of the circular muscle layer arises during the perinatal period. Thereafter, the fluorescence pattern remains unchanged until the adult stage. Chimaeric intestines were constructed by the association of 14-day fetal intestinal epithelium and cultured fetal rat or human skin fibroblasts. These fibroblastic cells did not express actin at the time at which they were associated. The immunocytochemical analysis of smooth muscle actin in the hybrid intestines, which had developed as intracoelomic grafts for 12 days, revealed that the skin fibroblastic cells had been induced by the intestinal epithelial cells to differentiate into smooth muscle cells. Such a result was also obtained with allantoic endoderm. It was not obvious in cocultures of intestinal epithelium with skin fibroblastic cells. However, when intestinal epithelial cells were cocultured with intestinal mesenchymal cells, actin expression was stimulated in the latter cell population.     

A novel antigen Apsi is expressed in a half population of endoderm cells in normal and LiCI-treated starfish embryos

A novel antigen, Apsi, revealed a tissue specific expression in the starfish embryo. Apsi was detected in the stomach and intestine of the bipinnaria larva by immunofluorescence microscopy, but was not detected in the esophagus or ectoderm. The expression of Apsi was zygotic and first detected at day 3 after fertilization. Using this antigen as a molecular marker, the effect of LiCI treatment on development was examined by counting the cell number of each germ layer and endoderm tissues on serial paraffin sections. At day 5 larva stage, the ratio of the cell number of ectoderm, esophagus, Apsi-expressing tissue (stomach and intestine) and mesoderm was 75:10:10:5. The corresponding ratio in LiCI-treated embryo was 68:14:14:4. LiCI treatment increased the cell number of endoderm by 40%, at the expense of a 10% decrease in the cell number of ectoderm. In intact embryos, approximately half the endoderm cells expressed Apsi antigen, while the other half did not. LiCI treatment did not change this ratio of Apsi expression in endoderm tissues. These observations indicate that LiCI treatment of early blastulae affects the commitment of ectoderm/endoderm but does not affect the differentiation of the esophagus/stomach and intestine.     

Immunofluorescent localization of a monoclonally defined carbohydrate cell surface antigen (IIC3) during mouse development

A monoclonal antibody (anti-IIC3), raised against F9 embryonal carcinoma cells, detects an antigen which is first expressed at the compacted morula stage and segregates with the trophectoderm of the mouse blastocyst. We have further examined the expression of this antigen during embryonic development. Immunofluorescence experiments on sectioned embryos demonstrate that IIC3 expression is associated with the differentiation of extra-embryonic cell types. It is expressed at the cell surface of the trophectoderm of the attaching blastocyst and differentially by the two derivatives of this layer. The primary and secondary trophoblastic giant cells label intracellularly, whereas the cells of the ectoplacental cone and labyrinth placenta label at the cell surface. IIC3 is also expressed by the primitive endoderm of the blastocyst and subsequently by the visceral endoderm. The parietal endoderm does not express IIC3. Partial characterization of the IIC3 antigen with sugar hapten inhibition and glycosidase digestion experiments, suggests that the antigen is a lactosaminoglycan-like molecule, with galactose and N-acetylgalactosamine residues representing part of the antigenic determinant. Neuraminidase and fucosidase treatment exposed additional anti-IIC3-antigenic sites on the extra-embryonic ectoderm and chorion. A possible role for IIC3 in normal embryonic-uterine interactions is discussed.     

Tissue-specific and inducible Cre-mediated recombination in the gut epithelium

We generated two complementary systems for Cre-mediated recombination of target genes in the mouse digestive epithelium and tested them with a Cre-reporter mouse strain. Cre was expressed under the control of a 9 kb regulatory region of the murine villin gene (vil-Cre). Genetic recombination was initiated at embryonic day (E) 9 in the visceral endoderm, and by E12.5 in the entire intestinal epithelium, but not in other tissues. Cre expression was maintained throughout adulthood. Furthermore, transgenic mice bearing a tamoxifen-dependent Cre recombinase (vil-Cre-ERT2) expressed under the control of the villin promoter were created to perform targeted spatiotemporally controlled somatic recombination. After tamoxifen treatment, recombination was detectable throughout the digestive epithelium. The recombined locus persisted for 60 days after tamoxifen administration, despite rapid intestinal cell renewal, indicating that epithelial progenitor cells had been targeted. The villin-Cre and villin-Cre-ERT2 mice provide valuable tools for studies of cell lineage allocation and gene function in the developing and adult intestine.     

Changing patterns of cytokeratins and vimentin in the early chick embryo

The distribution of cytokeratins and vimentin intermediate filaments in the first 48 h of chick development has been determined using immunofluorescent labelling. During formation of the germ layers, cytokeratin expression is associated with the appearance of an integral epithelium (ectoderm), whereas vimentin expression is associated with cells that detach and migrate from this epithelium to form endoderm and mesoderm. Subsequently, vimentin persists in the endoderm and mesoderm and the tissues derived therefrom, such as the somites and developing heart, throughout the period of study. The appearance of cytokeratins at later stages of development occurs in some epithelia such as the ectoderm, endoderm, lateral plate and epimyocardium but not others including the neural plate, neural tube and somites. Expression of cytokeratins in endoderm and mesenchymal tissues occurs in tandem with vimentin. In conclusion, vimentin expression is related to its distribution in the epiblast before germ layer formation. Its initial appearance may be related to the motile behaviour of cells about to ingress through the primitive streak. The appearance of cytokeratin filaments, however, does not reflect germ layer derivation but rather the need for an epithelial sheet.     

Wnt signaling specifies and patterns intestinal endoderm

Wnt signaling has been implicated in many developmental processes, but its role in early endoderm development is not well understood. Wnt signaling is active in posterior endoderm as early as E7.5. Genetic and chemical activation show that the Wnt pathway acts directly on endoderm to induce the intestinal master regulator Cdx2, shifting global gene away from anterior endoderm and toward a posterior, intestinal program. In a mouse embryonic stem cell differentiation platform that yields pure populations of definitive endoderm, Wnt signaling induces intestinal gene expression in all cells. We have identified a set of genes specific to the anterior small intestine, posterior small intestine, and large intestine during early development, and show that Wnt, through Cdx2, activates large intestinal gene expression at high doses and small intestinal gene expression at lower doses. These findings shed light on the mechanism of embryonic intestinal induction and provide a method to manipulate intestinal development from embryonic stem cells.     

A differential screen for genes expressed in the extraembryonic endodermal layer of pre-primitive streak stage chick embryos reveals expression of Apolipoprotein A1 in hypoblast, endoblast and endoderm

The lower layer of the pre-gastrulating chick embryo is an extra-embryonic tissue made up of two different cell populations, the hypoblast and the endoblast. The hypoblast is characterized by the expression of inhibitory signalling molecules (e.g. Cerberus, Dickkopf1, Crescent) and others (e.g. Otx2, goosecoid, Hex, Hesx1/RPX, FGF8). However, no genes expressed in the endoblast have yet been found. We designed a differential screen to identify markers differentially expressed in these two cell populations. This only revealed one novel gene, Apolipoprotein A1 (APO A1) with restricted endodermal layer expression. Expression of APO A1 begins very early throughout the lower layer (both hypoblast and endoblast). At later stages it is also expressed in the endoderm and its derivatives, the anterior intestinal portal endoderm and the growing liver bud.     

Gland formation induced in the allantoic and small-intestinal endoderm by the proventricular mesenchyme is not coupled with pepsinogen expression

Abstract. Allantoic and small-intestinal endoderms of chick and quail embryos were associated with the proventricular mesenchyme of chick embryos and then cultivated on chorioallantoic membrane. This resulted in the induction of complex glands, but the recombinates never produced embryo-specific pepsinogens; also, glandular cells developed a brush border, expressed sucrase antigen on their apical surface, and sometimes differentiated into goblet cells, thus indicating that both endoderms have the tendency to differentiate into an intestinal epithelium. In the recombinates composed of allantoic endoderm and proventricular mesenchyme, acid-protease activity was detected, but biochemical analysis revealed that this activity was not due topepsinogens. These results indicate that the gland formation induced in allantoic and small-intestinal endoderms by the proventricular mesenchyme is not accompanied by the expression of pepsinogens, suggesting that independent mechanisms are responsible for the morphogenesis and cyto chemical differentiation of the endoderm.