Kinetics of v-src-induced epithelial-mesenchymal transition in developing glandular stomach.

The oncogene function in primary epithelial cells is largely unclear. Recombination organ cultures in combination with the stable and transient gene transfer techniques by retrovirus and electroporation, respectively, enable us to transfer oncogenes specifically into primary epithelial cells of the developing avian glandular stomach (proventriculus). In this system, the epithelium and mesenchyme are mutually dependent on each other for their growth and differentiation. We report here that either stable or transient expression of v-src in the epithelium causes budding and migration of epithelial cells into mesenchyme. In response to the transient expression of v-Src or a constitutive active mutant of MEK, we observed immediate downregulation of the Sonic hedgehog gene and subsequent elimination of E-cadherine expression in migrating cells, suggesting the involvement of MAP kinase signaling pathway in these processes. v-src-expressing cells that were retained in the epithelium underwent apoptosis (anoikis) and detached from the culture. Continuous expression of v-src by, for example, Rous sarcoma virus (RSV) was required for the epithelial cells to acquire the ability to express type I collagen and fibronectin genes (mesenchymal markers), and finally to establish the epithelial-mesenchymal transition. These observations would partly explain why RSV does not apparently cause carcinoma formation, but induces sarcomas exclusively.

Gene transfer into chicken embryos as an effective system of analysis in developmental biology.

Chicken embryos have been used as a model animal in developmental biology since the time of comparative and experimental embryology. Recent application of gene transfer techniques to the chicken embryo increases their value as an experimental animal. Today, gene transfer into chicken cells is performed by three major systems, lipofection, electroporation and the virus-mediated method. Each system has its own features and applicability. In this overview and the associated four minireviews, the methods and application of each system will be presented.

Application of efficient and specific gene transfer systems and organ culture techniques for the elucidation of mechanisms of epithelial-mesenchymal interaction in the developing gut.

Epithelial-mesenchymal interactions are very important in the development of the vertebrate gut. In the avian embryonic stomach (proventriculus), expression of embryonic chick pepsinogen (ECPg) gene, which is specific to developing glandular cells in stomach epithelium, is regulated by mesenchymal influence. Molecular mechanisms of tissue-specific transcriptional regulation of the ECPg gene and the molecular nature of the mesenchymal signals were analyzed using a combination of the classic organ culture system and gene transfer strategies. In the present review, three methods for the introduction of DNA into tissues are described: lipofection, electroporation and retroviral infection, and characteristics of each system are discussed.

Role for cGATA-5 in transcriptional regulation of the embryonic chicken pepsinogen gene by epithelial-mesenchymal interactions in the developing chicken stomach.

A gene encoding embryonic chicken pepsinogen (ECPg), a zymogen of the digestive enzyme pepsin, is expressed specifically in epithelial cells of glands of embryonic stage proventriculus (glandular stomach) under the influence of mesenchyme. We found four GATA and one Sox binding motifs in 1.1 kb of the 5' flanking region of the ECPg gene which are essential to the organ-specific expression of the gene. The expression of cGATA-5 and cSox2 in the proventriculus from day 6 to day 12 of incubation was therefore analyzed. cGATA-5 was more strongly expressed in glandular epithelial cells than in luminal epithelial cells, while cSox2 gene expression was weaker in glandular epithelial cells. Using heterologous recombination explants we also discovered that the expression of cGATA-5 and cSox2 in epithelial cells was affected by mesenchyme when the latter induced ECPg gene expression in epithelial cells. Introduction of expression constructs into epithelial cells by electroporation demonstrated that cGATA-5 upregulated transcription of a reporter luciferase gene via a cis element in the 5' flanking region of the ECPg gene. The gel mobility shift assay revealed that the cGATA-5 protein specifically binds to the GATA binding sites. cSox2 downregulated the activity of luciferase but it was not through the Sox binding motif. These results suggest that cGATA-5 positively regulates transcription of the ECPg gene and is involved in spatial regulation of the pepsinogen gene during development.

The concentric structure of the developing gut is regulated by Sonic hedgehog derived from endodermal epithelium.

The embryonic gut of vertebrates consists of endodermal epithelium, surrounding mesenchyme derived from splanchnic mesoderm and enteric neuronal components derived from neural crest cells. During gut organogenesis, the mesenchyme differentiates into distinct concentric layers around the endodermal epithelium forming the lamina propria, muscularis mucosae, submucosa and lamina muscularis (the smooth muscle layer). The smooth muscle layer and enteric plexus are formed at the outermost part of the gut, always some distance away from the epithelium. How this topographical organization of gut mesenchyme is established is largely unknown. Here we show the following: (1) Endodermal epithelium inhibits differentiation of smooth muscle and enteric neurons in adjacent mesenchyme. (2) Endodermal epithelium activates expression of patched and BMP4 in adjacent non-smooth muscle mesenchyme, which later differentiates into the lamina propria and submucosa. (3) Sonic hedgehog (Shh) is expressed in endodermal epithelium and disruption of Shh-signaling by cyclopamine induces differentiation of smooth muscle and a large number of neurons even in the area adjacent to epithelium. (4) Shh can mimic the effect of endodermal epithelium on the concentric stratification of the gut. Taken together, these data suggest that endoderm-derived Shh is responsible for the patterning across the radial axis of the gut through induction of inner components and inhibition of outer components, such as smooth muscle and enteric neurons.

BMPs are necessary for stomach gland formation in the chicken embryo: a study using virally induced BMP-2 and Noggin expression.

Epithelial-mesenchymal interactions are necessary for the normal development of various digestive organs. In chicken proventriculus (glandular stomach), morphogenesis and differentiation of the epithelium depend upon the inductive signals coming from underlying mesenchyme. However, the nature of such signals is still unclear despite extensive analyses carried out using experimental tissue recombinations. In this study we have examined the possible involvement of bone morphogenetic proteins (BMPs) in the formation of stomach glands in the chicken embryo. Analysis of the expression patterns of BMP-2, -4 and -7 showed that these BMPs were present in the proventricular mesenchyme prior to the initiation of the proventricular gland formation. BMP-2 expression, in particular, was restricted to the proventriculus among anterior digestive organs. Virus-mediated BMP-2 overexpression resulted in an increase in the number of glands formed. Moreover, ectopic expression of Noggin, which antagonizes the effect of BMPs, in the proventricular mesenchyme or epithelium, led to the complete inhibition of gland formation, indicating that BMP signals are necessary for the proventricular gland formation. These findings suggest that BMPs are of prime importance as mesenchymal signals for inducing proventricular glands.

Epithelial cell differentiation during stomach development.

Chicken stomach provides an extremely useful experimental system for the analysis of molecular nature of the morphogenesis and cytodifferentiation of digestive organs in vertebrates. We identified several genes of which expression is important for the normal development of the stomach. Especially, bone morphogenetic protein-2 is necessary for the mesenchymal action in inducing gland formation in the epithelium of the stomach. Some transcription factors such as cSox2 and cGATA5 are involved in the expression of embryonic chicken pepsinogen gene, a marker gene of stomach gland epithelial cells.

The mesenchymal factors regulating epithelial morphogenesis and differentiation of the chicken stomach.

It is now well established that epithelial-mesenchymal interactions are essential for the formation of many organs in the development of the animals. Chicken digestive organs provide a valuable model system for analysis of the mechanisms underlying the epithelial-mesenchymal interactions. Here we will present our recent data indicating that the mesenchymal factors necessary for the epithelial differentiation in the chicken stomach are composed of several components such as growth factors and extracellular matrices. The possible involvement of bone morphogenetic protein-2 will be discussed.

In vitro analysis of mesenchymal influences on the differentiation of stomach epithelial cells of the chicken embryo.

It is well established that epithelial-mesenchymal interactions play important roles in the differentiation of stomach epithelial cells in the chicken embryo. To analyze mesenchymal influences on the differentiation of the epithelial cells, we developed a tissue culture system for stomach (proventriculus and gizzard) epithelia of chicken embryo, and examined their differentiation in the presence or absence of mesenchyme. Stomach epithelium from 6-day chicken embryo did not express embryonic chicken pepsinogen (ECPg), a marker molecule of glandular epithelial cells of proventriculus, while it expressed marker molecules of epithelial cells of the luminal surface of stomach, when cultured alone on the Millipore filter, covered with the gel consisting of extracellular matrix components. When the epithelium was recombined with mesenchyme separated by the filter, differentiation of the epithelium was affected by the recombined mesenchyme. Proventricular and lung mesenchymes induced the expression of ECPg in epithelial cells, and the expression was extensive when the gel contained basement membrane components. Proventricular and gizzard epithelia showed different responses to the mesenchymal action. We tested the effects of some growth factors on the differentiation of epithelial cells using this culture system. Furthermore we devised a "conditioned semi-solid medium experiment" for analysis of the inductive properties of proventricular and lung mesenchymes. The results of this experiment clearly demonstrated for the first time that diffusible factors from mesenchyme induce the differentiation of glandular epithelial cells in the absence of mesenchymal cells.

Region-specific expression of chicken Sox2 in the developing gut and lung epithelium: regulation by epithelial-mesenchymal interactions.

In situ analysis of the chicken cSox2 gene, a member of the transcription factor family containing an Sry-like high-mobility group (HMG) box, demonstrated localized expression in the embryonic endoderm. Transcripts of cSox2 appeared before commencement of morphogenesis and cytodifferentiation in the rostral gut epithelium from the pharynx to the stomach. The caudal limit of cSox2 expression coincided with that of the region competent for proventricular differentiation and to the rostral limit of the domain of CdxA, a homologue of Drosophila caudal. During morphogenesis, the level of transcripts of cSox2 decreased in epithelia invaginating into surrounding mesenchyme to form glandular or tubular structures, such as the primordia of the thyroid and lung, glandular epithelium of the proventriculus, and secondary bronchus of the lung. Tissue recombination experiments demonstrated that cSox2 expression is regulated by the underlying mesenchyme as well as morphogenesis and cytodifferentiation. The results suggest that cSox2 plays pivotal roles in generating morphologically and physiologically distinct types of epithelial cells in the gut.

Tissue interaction regulates expression of a spasmolytic polypeptide gene in chicken stomach epithelium.

The primitive epithelium of embryonic chicken proventriculus (glandular stomach) differentiates, after day 6 of incubation, into luminal epithelium, which faces the lumen and abundantly secretes mucus, and glandular epithelium, which invaginates into mesenchyme and later expresses embryonic chicken pepsinogen (ECPg). So far it is not well understood how undifferentiated epithelial cells differentiate into these two distinct cell populations. Spasmolytic polypeptide (SP) is known to be expressed in surface mucous cells of mammalian stomach. In order to obtain the differentiation marker for proventricular luminal epithelial cells, we cloned a cDNA encoding chicken SP (cSP). Sequence analysis indicated that cSP has the duplicated cysteine-rich domain characteristic of SP. Examination of the spatial and temporal expression pattern of cSP gene revealed that, during embryogenesis, cSP was expressed in lumina epithelial cells of the proventriculus, gizzard, small intestine, and lung, but not the esophagus. In the proventriculus, cSP mRNA was first detected on day 8 of incubation and was localized to differentiated luminal epithelial cells. By using cSP as a molecular marker, the effects of mesenchyme on the differentiation of epithelium were analyzed in vitro. On the basis of these data, a model is presented concerning the differentiation of proventricular epithelium.

Analysis of temporal expression pattern and cis-regulatory sequences of chicken pepsinogen A and C.

Three groups of pepsinogens exist in vertebrates, namely, pepsinogen A, pepsinogen C, and prochymosin, which are produced at different developmental stages. In the chicken, prochymosin is expressed only in the embryonic stage, while pepsinogens A and C are secreted from adult chicken proventricular (glandular stomach) mucosa. In order to understand the mechanism of transcriptional regulation of these genes, we have cloned the genes encoding chicken pepsinogens A and C and analyzed the sequences possibly involved in their regulation. 5'-Upstream sequences of both genes contain putative binding motifs for transcription factors such as GATA, Sox, and HNF-3 beta, which are expressed in the chicken gut epithelium. Moreover, we found seven putative binding motifs for human MZF-1 in intron 8 of pepsinogen A gene. These transcription factors may act as regulators of expression of chicken pepsinogen genes.

cFKBP/SMAP; a novel molecule involved in the regulation of smooth muscle differentiation.

During embryogenesis, smooth muscle cells of the gut differentiate from mesenchymal cells derived from splanchnic mesoderm. We have isolated a gene involved in the differentiation of smooth muscle cells in the gut using differential display between the chicken proventriculus in which the smooth muscle layer develops poorly and the gizzard in which smooth muscles develop abundantly. The protein encoded by this gene showed highest similarity to mouse FK506 binding protein, FKBP65, and from the function of this protein it was designated chicken FKBP/smooth muscle activating protein (cFKBP/SMAP). cFKBP/SMAP was first expressed in smooth muscle precursor cells of the gut and, after smooth muscles differentiate, expression was restricted to smooth muscle cells. In organ culture of the gizzard, the differentiation of smooth muscle cells was inhibited by the addition of FK506, the inhibitor of FKBPs. Moreover, overexpression of cFKBP/SMAP in lung and gizzard mesenchymal cells induced smooth muscle differentiation. In addition, cFKBP/SMAP-induced smooth muscle differentiation was inhibited by FK506. We postulate therefore that cFKBP/SMAP plays a crucial role in smooth muscle differentiation in the gut and provides a powerful tool to study smooth muscle differentiation mechanisms, which have been poorly analyzed so far.

Differential expression of fos and jun family members in the developing chicken gastrointestinal tract.

We have analysed the expression patterns of all the known fos/jun family genes, which encode the components of the transcription factor AP-1, in the chicken embryonic digestive tract that develops into the esophagus, proventriculus, gizzard, small intestine, ceca and large intestine. From soon after formation of the tubular structure, each gene transcript was localized in distinct domains of the epithelium and mesenchyme in all of these major gastrointestinal organs, independently of the anterior-posterior axis. fra-2 was expressed predominantly in epithelium, which also expressed junD, while low-level expression of junD was also detected in smooth muscle cell precursors in mesenchyme. Expression of c-jun and c-fos was detectable in both mesenchyme and epithelium through the whole tract. In the differentiated proventriculus, the developed glandular epithelium expressed c-jun and junD, but not fra-2, while luminal epithelium expressed fra-2 and junD, but not c-jun. These results suggest that distinct Fos/Jun protein heterodimers play important roles in maintaining the epithelial-mesenchymal interactions. Similar expression patterns to those of fra-2 and junD were established from earlier stages by Sonic hedgehog gene and the Indian hedgehog gene, respectively, both of which are important in forming the inductive network between epithelium and mesenchyme of the digestive tract.

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.

Developmental changes in mucosubstances revealed by immunostaining with antimucus monoclonal antibodies and lectin staining in the epithelium lining the segment from gizzard to duodenum of the chick embryo.

The mucosubstances in the epithelium lining the segment from gizzard to duodenum during development of the chick embryo was studied histochemically using monoclonal antibodies against gizzard mucus and lectins, with attention to the regional differentiation of the epithelium in this segment. The anterior limit of epithelial CdxA mRNA expression detected by in situ hybridisation, which served as the position of the gizzard-duodenal boundary, was clearly found from d 3. Granules positive for some antibodies or lectins were found in the region ranging from the posterior part of the gizzard to the duodenum at d 3, which was followed by an increase in the number of granules and a gradual enlargement of the granule-positive area to the anterior part of the gizzard over 4-6 d. From d 4, the epithelia of the gizzard body and of the pyloric or duodenal region came to be differently stained with some antibodies or lectins. From d 10, each region showed a specific pattern of staining. The epithelia of the gizzard body and pyloric region contained abundant mucus granules with a different staining pattern. In the duodenum the number of stained granules was low except in occasional goblet cells. Thus the epithelia of the gizzard body, pyloric region and duodenum may produce different mucosubstances and the regional differentiation in these epithelia may start at rather early stages soon after the formation of digestive tube.

Early specification of intestinal epithelium in the chicken embryo: a study on the localization and regulation of CdxA expression.

CdxA, a chicken homeobox-containing gene related to caudal in Drosophila, has been implicated in the regionalization of endoderm. It is reported here that, in the development of the chicken embryo, CdxA expression appears in the endoderm at day 1.5 of development as bilateral bands on either side of the splanchnopleure which later contribute to intestinal epithelium. The CdxA-expressing area extends medially and caudally as formation of the gut tube progresses. It is also shown that the rostral limit of CdxA expression demarcates the boundary between stomach and duodenum after day 3 of development. CdxA is not expressed in digestive tract appendages which open into the intestine, such as pancreas, liver and allantois. Early restriction of CdxA expression in intestinal lineage suggests that the intestinal specification involving CdxA expression commences before the gut tube is formed. The expression of CdxA in epithelial-mesenchymal tissue recombinants suggests that mesenchymal influence regulating CdxA expression plays an important role in confirming the boundary between the stomach and intestine. Chronological change in the spatial distribution of CdxA transcripts and the results of tissue recombination experiments, together with precise fate maps of early endoderm and splanchnic mesoderm, lead to a model of mechanisms by which intestinal specification is brought about.

Chicken keratin-19: cloning of cDNA and analysis of expression in the chicken embryonic gut.

From many recent studies, it has been argued that keratins (cytokeratins) play important roles in the morphogenesis and differentiation of organ development. To learn the role of keratin in digestive tract development, a cDNA of the chicken homolog of keratin-19 (GK-19) was cloned and its expression pattern was analyzed in the digestive tract of chicken embryos. The GK-19 full-length sequence was approximately 1.6 kb and showed more than 80% similarity to human and mouse keratin-19. The result of in situ hybridization with the proventriculus (glandular stomach) of different developmental stages showed that GK-19 expression disappeared specifically in the glandular epithelium from day 6 to day 9 of incubation. Furthermore, GK-19 was localized in the notochord, floor plate, anterior lobe of the pituitary gland and mesonephros. These results suggest the possibility that GK-19 may have multiple roles in organogenesis during embryogenesis.

Spatial expression of Sonic hedgehog in the lung epithelium during branching morphogenesis.

Sonic hedgehog (Shh), a homologue of Drosophila hedgehog, was specifically expressed in lung epithelium during branching morphogenesis, but was not uniformly expressed in lung epithelium. Shh was intensely expressed in the distal tips of the bronchial tubes during branching morphogenesis, and Shh was localized on the apical side of the epithelium. On the other hand, Bmp-4, one of the target genes of Shh, was also specifically expressed in the epithelium at the branching point. These results suggest that Shh and Bmp-4 are involved in the branching morphogenesis of lung epithelium.

Analysis of mesenchymal influence on the pepsinogen gene expression in the epithelium of chicken embryonic digestive tract.

We performed tissue recombination experiments to discover the mesenchymal influences on differentiation of epithelia in chicken digestive organs. Epithelia and mesenchymes were taken from the lung, esophagus, proventriculus, gizzard, small intestine and large intestine of 6-day chicken embryos and recombined in various associations and cultivated in vitro for 6 days. Rather unexpectedly, embryonic chicken pepsinogen (ECPg) gene, a marker of the proventricular epithelium, was induced in the gizzard epithelium, which does not express ECPg in normal development, by the proventricular and lung mesenchymes. In the second half of this study, we investigated the mode of action of mesenchymal cells on ECPg expression in gizzard epithelial cells more precisely using the cell aggregate culture system, in which gizzard epithelial cells were mixed with proventricular, gizzard or lung mesenchymal cells. We found that supporting action of lung mesenchymal cells on ECPg expression was even stronger than that of proventricular mesenchymal cells, and suggest that the action of lung mesenchyme may be due partly to the enhancement of epithelial cell proliferation. According to the results of this study, together with many facts obtained so far, we will discuss a new model for restricted expression of ECPg in the proventricular epithelium in normal development.