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.     

Effects of subepithelial fibroblasts on epithelial differentiation in human skin and oral mucosa: heterotypically recombined organotypic culture model

The stratified squamous epithelia differ regionally in their patterns of morphogenesis and differentiation. Although some reports suggested that the adult epithelial phenotype is an intrinsic property of the epithelium, there is increasing evidence that subepithelial connective tissue can modify the phenotypic expression of the epithelium. The aim of this study was to elucidate whether the differentiation of cutaneous and oral epithelia is influenced by underlying mesenchymal tissues. Three normal skin samples and three normal buccal mucosa samples were used for the experiments. Skin equivalents were constructed in four ways, depending on the combinations of keratinocytes (cutaneous or mucosal keratinocytes) and fibroblasts (dermal or mucosal fibroblasts), and the effects of subepithelial fibroblasts on the differentiation of oral and cutaneous keratinocytes were studied with histological examinations and immunohistochemical analyses with anti-cytokeratin (keratins 10 and 13) antibodies. For each experiment, three paired skin equivalents were constructed by using single parent keratinocyte and fibroblast sources for each group; consequently, nine (3 x 3) organotypic cultures per group were constructed and studied. The oral and cutaneous epithelial cells maintained their intrinsic keratin expression. The keratin expression patterns in oral and cutaneous epithelia of skin equivalents were generally similar to their original patterns but were partly modified exogenously by the topologically different fibroblasts. The mucosal keratinocytes were more differentiated and expressed keratin 10 when cocultured with dermal fibroblasts, and the expression patterns of keratin 13 in cutaneous keratinocytes cocultured with mucosal fibroblasts were different from those in keratinocytes cocultured with cutaneous fibroblasts. The results suggested that the epithelial phenotype and keratin expression could be extrinsically modified by mesenchymal fibroblasts. In epithelial differentiation, however, the intrinsic control by epithelial cells may still be stronger than extrinsic regulation by mesenchymal fibroblasts.     

Differentiation of proventricular epithelium in xenoplastic associations with mesenchymal or fibroblastic cells

Summary Proventricular epithelium (PV epithelium) from 6-day chicken embryos was associated with cultured cells, derived from fetal rat small intestine, or with fetal rat or human skin fibroblasts. The cytodifferentiation of PV epithelium was investigated using antibodies to chicken pepsinogen, a marker protein of PV epithelium, and to chicken sucrase, a marker enzyme of the small-intestinal brush-border membrane. PV epithelium formed complex glands and produced pepsinogen in association with cultured gut mesenchymal cells and skin fibroblasts. Its development was comparable to that achieved under the influence of PV mesenchyme. PV epithelial development was severely inhibited, however, under the influence of intact chicken or rat intestinal mesenchyme. The data are consistent with the idea that during the first step of epithelial-mesenchymal interactions, the epithelium and not the mesenchyme may be responsible for the determination of the developmental fate.     

Electron microscopic study of in vitro differentiation of the small intestinal endoderm in young bird embryo in the presence or absence of mesenchyme

Electron microscopical studies demonstrated that the small intestinal endoderm of young avian embryos cultures in vitro in the presence or absence of mesenchyme can differentiate into an absorptive epithelium with the brush border, and that, in the absence of mesenchyme the brush border develops much earlier than in the presence of mesenchyme, but goblet cells do not appear and morphogenesis of villi does not occur. These results show that the intestinal mesenchyme controls the endodermal differentiation, though the undifferentiated endoderm possesses self-differentiation potency.     

Fetal gut mesenchyme induces differentiation of cultured intestinal endodermal and crypt cells

An experimental model was designed to analyze the effect of fetal gut mesenchyme on the cytodifferentiation of crypt cells and of embryonic progenitor cells. The cells used were the rat intestinal crypt cell line, IEC-17, and primary cell cultures prepared form isolated 14-day-old fetal intestinal endoderm (EC). Both cultures prepared from isolated 14-day-old fetal rat intestinal endoderm (EC). Both types of cells were associated with 14-day-old fetal rat gut mesenchyme (Rm) and grafted under the kidney capsule of adult rats. Seventy percent of the Rm/EC and ten percent of the Rm/IEC recombinants, recovered after 9 days, exhibited well-vascularized structures in which the mesenchyme had induced morphogenesis of the cells into a villus epithelium. The four main intestinal epithelial cell types, absorptive, goblet, endocrine, and Paneth cells, were identified using electron microscopy. Biochemical determinations of enzyme activities associated with brush border membranes revealed that alkaline phosphatase, lactase, sucrase, and maltase were expressed in both types of associations. These results were confirmed by immunofluorescence staining using monoclonal antibodies to brush border enzymes. Both enzyme assays and immunocytochemistry showed that the amount of enzymes present in the brush border membrane of Rm/IEC grafts was in general lower than that of the Rm/EC recombinants. The results indicate that fetal rat gut mesenchyme enables morphogenesis and cytodifferentiation of both crypt and embryonic progenitor cells.     

Fetal endoderm primarily holds the temporal and positional information required for mammalian intestinal development

In rodents, the intestinal tract progressively acquires a functional regionalization during postnatal development. Using lactase-phlorizin hydrolase as a marker, we have analyzed in a xenograft model the ontogenic potencies of fetal rat intestinal segments taken prior to endoderm cytodifferentiation. Segments from the presumptive proximal jejunum and distal ileum grafted in nude mice developed correct spatial and temporal patterns of lactase protein and mRNA expression, which reproduced the normal pre- and post-weaning conditions. Segments from the fetal colon showed a faint lactase immunostaining 8-10 d after transplantation in chick embryos but not in mice; it is consistent with the transient expression of this enzyme in the colon of rat neonates. Heterotopic cross-associations comprising endoderm and mesenchyme from the presumptive proximal jejunum and distal ileum developed as xenografts in nude mice, and they exhibited lactase mRNA and protein expression patterns that were typical of the origin of the endodermal moiety. Endoderm from the distal ileum also expressed a normal lactase pattern when it was associated to fetal skin fibroblasts, while the fibroblasts differentiated into muscle layers containing alpha-smooth- muscle actin. Noteworthy, associations comprising colon endoderm and small intestinal mesenchyme showed a typical small intestinal morphology and expressed the digestive enzyme sucrase-isomaltase normally absent in the colon. However, in heterologous associations comprising lung or stomach endoderm and small intestinal mesenchyme, the epithelial compartment expressed markers in accordance to their tissue of origin but neither intestinal lactase nor sucrase-isomaltase. A thick intestinal muscle coat in which cells expressed alpha-smooth- muscle actin surrounded the grafts. The results demonstrate that: (a) the temporal and positional information needed for intestinal ontogeny up to the post-weaning stage results from an intrinsic program that is fixed in mammalian fetuses prior to endoderm cytodifferentiation; (b) this temporal and positional information is primarily carried by the endodermal moiety which is also able to change the fate of heterologous mesodermal cells to form intestinal mesenchyme; and (c) the small intestinal mesenchyme in turn may deliver instructive information as shown in association with colonic endoderm; yet this effect is not obvious with nonintestinal endoderms.     

Inductive properties of fibroblastic cell cultures derived from rat intestinal mucosa on epithelial differentiation

The present study represents a first attempt to elucidate the regulatory properties displayed by the non-epithelial portion of the intestinal mucosa, growing as fibroblasts in monolayer cultures. Thus, we compared the inductive action of 6-day suckling rat duodenal fibroblasts with that displayed by chick embryonic intestinal mesenchyme on the heterotypic cytodifferentiation of 5 1/2-day chick embryonic gizzard endoderm. The latter, isolated by 0.03% collagenase, was surrounded by intestinal intramucosal fibroblastic cell sheets. As control experiments, fibroblastic cells derived from the intestinal muscle or from 20-day fetal rat skin and lung were used. Every type of association was grafted into the coelomic cavity of 3-day chick embryos for 11 to 12 days, a system providing their vascularization and growth. The results clearly demonstrate that the mucosal fibroblastic cells of rat intestine were as potent as embryonic intestinal mesenchyme in inducing brush-border enzymes like sucrase and maltase, in conformity with an induced intestinal morphology. In contrast, the control fibroblastic cells were completely ineffective.     

Endodermal Hedgehog signals modulate Notch pathway activity in the developing digestive tract mesenchyme

The digestive tract epithelium and its adjoining mesenchyme undergo coordinated patterning and growth during development. The signals they exchange in the process are not fully characterized but include ligands of the Hedgehog (Hh) family, which originate in the epithelium and are necessary for mesenchymal cells to expand in number and drive elongation of the developing gut tube. The Notch signaling pathway has known requirements in fetal and adult intestinal epithelial progenitors. We detected Notch pathway activity in the embryonic gut mesenchyme and used conditional knockout mice to study its function. Selective disruption of the Notch effector gene RBP-Jκ (Rbpj) in the mesenchyme caused progressive loss of subepithelial fibroblasts and abbreviated gut length, revealing an unexpected requirement in this compartment. Surprisingly, constitutive Notch activity also induced rapid mesenchymal cell loss and impaired organogenesis, probably resulting from increased cell death and suggesting the need for a delicate balance in Notch signaling. Because digestive tract anomalies in mouse embryos with excess Notch activity phenocopy the absence of Hh signaling, we postulated that endodermal Hh restrains mesenchymal Notch pathway activity. Indeed, Hh-deficient embryos showed Notch overactivity in their defective gut mesenchyme and exposure to recombinant sonic hedgehog could override Notch-induced death of cultured fetal gut mesenchymal cells. These results reveal unexpected interactions between prominent signals in gastrointestinal development and provide a coherent explanation for Hh requirements in mesenchymal cell survival and organ growth.     

Demonstration of sucrase immunoreactivity of the brush border induced by duodenal mesenchyme in chick stomach endoderm

Summary When stomach endoderm of chick embryos was recombined and cultured with duodenal mesenchyme, the endoderm developed a brush border structure over a large area and also differentiated into mucous cells in a small area according to its own developmental fate. In the present investigation, we examined whether the induced brush border structure expressed sucrase antigen by immunoelectron microscopy using the antiserum raised against chicken sucrase. Sucrase immunoreactivity could be detected as ferritin particles in the region where the brush border was induced, whereas it was never detected on microvilli of endodermal cells which differentiated into the mucous cells. Thus, almost all of the endodermal cells could be identified as either small intestine-type cells possessing the sucrase antigen or stomach-type cells possessing mucous granules but not the sucrase antigen. The results indicate that stomach endodermal cells of chick embryos can differentiate not only morphologically but also functionally into typical intestinal epithelial cells under the inductive influence of the duodenal mesenchyme.     

Enzymatic response to glucocorticoids of the chick intestinal endoderm associated with various mesenchymal cell types

The aim of the present study was to test the morphological and functional maturation of recombinants composed of chick intestinal endoderms associated to different mesenchymal supports and their enzymatic response to glucocorticoids. For this purpose 5.5-day chick embryonic intestinal endoderm has been associated to 14-day fetal rat gut mesenchyme, to rat intestinal fibroblasts (6-day neonatal rat intramucosal fibroblasts) or to rat control fibroblasts, originating from 20-day fetal rat skin and lung and from 6-day neonatal rat intestinal muscle. The recombinants were grown as intracoelomic grafts either for 12 days or for 10 days plus 2 days in organ culture in the presence of dexamethasone. The data show that heterospecific recombinants achieve subnormal morphogenesis and enzymatic maturation. The organ culture experiments further reveal that sucrase activity is insensitive to dexamethasone in all types of recombinants whereas, alkaline phosphatase is highly stimulated over the levels present in the intestine developed in situ whatever the stromal support, except when this support is provided by rat gut mesenchyme. These results support the view that in the intestine the hormonal response is mediated by epithelial-mesenchymal interactions.     

Effects of human fetal gastroenteric mesenchymal cells on some developmental aspects of animal gut endoderm

Human intestinal and gastric mesenchymal cells were associated with chick and rat intestinal endoderm in order to test their species-specific capacity on epithelial differentiation. Primary cell cultures were established from human intestinal and gastric mesenchyme. Animal intestinal endoderms were associated with both cell types, grafted in ovo and allowed to develop for 12 days. The morphologic and enzymatic differentiation of the recombinants demonstrated two types of inductive properties exerted by human fetal intestinal and gastric mesenchymal cells, respectively. Firstly, human intestinal mesenchymal cells triggered intrinsic developmental capacities in chick and rat endoderm, i.e. enhanced structural brush-border maturation in both species and precocious sucrase induction in rat endoderm. Secondly, human gastric mesenchymal cells provoked the partial conversion of chick intestinal endoderm into gastric structures. Such properties were not found in homologous animal mesenchymes.     

Development of fetal rat intestine in organ and monolayer culture

Maturation and differentiation of intestinal epithelial cells was demonstrated in segments of fetal rat small intestine, maintained for more than a month in suspension organ culture, by ultrastructural, biochemical, and immunological criteria. Over a 5-7 d period, fragments of fetal intestine evolved into globular structures covered with a single columnar epithelium ultrastructurally similar to suckling villus cells. Loose mesenchymal cells, cellular debris, and collagen were present inside the structures. After 6 d in culture, goblet cells, not present in the fetal intestine at day 18, were numerous and well developed. Intestinal endocrine cells were also observed. Immunofluorescence studies employing monoclonal antibodies specific for villus and crypt cells in vivo, and various enzyme assays, have demonstrated a level of differentiation and maturation of the cultured epithelial cells similar but not identical to that of suckling intestinal mucosa in vivo. Crypts and crypt cell markers were not observed in the the cultures. Addition of glucocorticoids to the culture medium resulted in the induction of sucrase-isomaltase but failed to promote most of the functional changes characteristic of the intestinal epithelium at weaning in vivo. Epithelial cells were identified in explants derived from the organ cultures by their specific expression of intestinal cytokeratin. Differentiation-specific markers, present in the epithelial cells in primary cultures, were lost upon selection and subculturing of pure epithelial cell populations. These results suggest a requirement for mesenchymal and/or extracellular matrix components in the maintenance of the differentiated state of the epithelial cells. The fetal intestinal organ cultures described here present significant advantages over traditional organ and monolayer culture techniques for the study of the cellular and molecular interactions involved in the development and differentiation of the intestinal epithelium.     

Induction of cytokeratin expression in human mesenchymal cells

We studied the phenotypic features of some typical human mesenchymal cells, including decidual stromal cells and adult and fetal fibroblasts under different cell culture conditions by using antibodies to intermediate filament proteins and desmoplakins. In cell culture, the decidual stromal cells rapidly acquired typical fibroblastoid appearance with abundant arrays of vimentin filaments while the cytokeratin-positive epithelial cells, occasionally found in typical epithelioid colonies, lacked vimentin positivity and showed desmoplakin positivity. Within a few days, many of the stromal cells started to present cytokeratin positivity when cultured either in Condimed or in Chang medium. The cytokeratin positivity was first detected in small, scattered cytoplasmic dotted fibrils or in perinuclear dotlike aggregates with fibrillar projections. Later, denser cytokeratin-positive fibrillar arrays could also be seen in stromal cells, which lacked desmoplakin positivity as judged by two monoclonal antibodies. Decidual stromal cells were also cloned and in five out of ten clones some of the cells acquired a similar cytokeratin positivity when transferred into Chang or Condimed medium. Immunoblotting results indicated that cytokeratins 8, 18, and 19 can be found in these cultures. Similar cytokeratin positivity could also be seen in the same culture conditions in cultured fetal fibroblasts from skin, chorionic villi, and lung but not in young or adult skin fibroblast cultures. The present results suggest that decidual stromal cells as well as some embryonal mesenchymal cells can acquire epithelial differentiation in vitro as judged by the emergence of cytokeratin proteins. This ability appears to be lost in the corresponding adult cell. The results furthermore suggest that cytokeratin fibrils can be organized in the cytoplasm without an apparent organization center and that neither the appearance of desmoplakins nor the formation of cell-to-cell contacts are required for cytokeratin filament assembly.     

Epithelial-mesenchymal interactions in the production of basement membrane components in the gut

The production and deposition of extracellular matrix proteins and the cellular origin of type-IV collagen have been analysed immunocytochemically in cocultured or transplanted intestinal epithelial-mesenchymal cell associations. In the first experimental model, rat intestinal endodermal cells were cultured on top of confluent mono-layers of rat intestinal or skin fibroblastic cells. Under these conditions, interstitial matrix and basement membrane proteins were deposited within the fibroblastic layer over the whole culture period; interactions between the epithelial cells and the fibroblastic cell population, whatever their organ of origin, were required for the production of the basement membrane. In addition, its formation was progressive as assessed by the shift of a spot-like labelling to a continuous linear pattern at the epithelial-mesenchymal interface, and paralleled epithelial cell differentiation. In the second experimental model, chick-rat epithelial-mesenchymal recombinants developed as intracoelomic grafts were used, and the immunocytochemical detection of a basement membrane protein, type-IV collagen, was performed with species-specific antibodies. The major role of the mesenchyme in the deposition of type-IV collagen is supported by the fact that anti-chick but not anti-mammalian antibodies stained this antigen in chick mesenchyme-rat endoderm recombinants. These observations emphasize the role of tissue interactions in the formation of a basement membrane and show that the mesenchymal compartment is the principal endogenous source of type-IV collagen.     

Identification and partial characterization of mesenchyme-derived growth factor that stimulates proliferation and inhibits functional differentiation of mouse mammary epithelium in culture

The effect of mesenchyme on both proliferation and differentiation of mammary epithelial cells was investigated in a primary cell culture system. Mammary cells cultured on collagen gel for 4 days produced casein in response to the synergistic action of insulin, cortisol, and prolactin. When mammary epithelial cells were co-cultured with fibroblasts derived from three different kinds of fetal mesenchymal tissues, casein production was suppressed. The addition of conditioned media obtained from cultures of these mesenchymal cells stimulated DNA synthesis and reduced casein synthesis in a dose-dependent fashion in the cultured mammary cells. Although such biological actions are similar to those of epidermal growth factor (EGF), the capability to compete with EGF for EGF receptor was not found in this conditioned medium. Sephadex G-200 column chromatography revealed that molecular weight of the peak which has these biological activities was around 100,000. These results indicate that fetal mesenchymal cells secrete a substance(s) which has a stimulatory effect on proliferation and an inhibitory effect on differentiation of mammary epithelial cells.     

Contractile capacity of fibroblasts from different sources in the model of living skin equivalent

Human fibroblasts contract collagen gel in vitro and produce a connective tissue-like structure termed the living skin equivalent. In this study, the contractile capacity of postnatal dermal fibroblasts, bone marrow mesenchymal cells and mesenchymal cells derived from the fat tissue has been compared to that of fetal dermal fibroblasts in the model of living skin equivalent. The results show that fetal fibroblasts contract the collagen gel approximately six times stronger than do all other fibroblast cell types, with the numbers of all these cells being equal. A deeper insight into the behavior of fibroblasts differing in their origin will help to develop new approaches to the treatment and regulation of wound healing and fibrosis formation.     

Regulation of Human (Caco-2) Intestinal Epithelial Cell Differentiation by Extracellular Matrix Proteins

Extracellular matrix regulation of intestinal epithelial differentiation may affect development, differentiation during migration to villus tips, healing, inflammatory bowel disease, and malignant transformation. Cell culture studies of intestinal epithelial biology may also depend on the matrix substrate used. We evaluated matrix effects on differentiation and proliferation in human intestinal Caco-2 epithelial cells, a model for intestinal epithelial differentiation. Proliferation, brush border enzyme specific activity, and spreading were compared in cells cultured on tissue culture plastic with interstitial collagen I and the basement membrane constituents collagen IV and laminin. Each matrix significantly increased alkaline phosphatase, dipeptidyl peptidase, lactase, sucrase-isomaltase, and cell spreading in comparison to plastic. However, the basement membrane proteins collagen IV and laminin further promoted all four brush border enzymes but inhibited spreading compared to collagen I. Proliferation was most rapid on type I collagen and slowest on laminin and tissue culture plastic. Basement membrane matrix proteins may promote intestinal epithelial differentiation and inhibit proliferation compared with interstitial collagen I.     

Behavior of fetal intestinal organ culture explanted onto a collagen substratum

A model of organ culture of 18 day old fetal rat intestine (Quaroni, 1985) was modified and characterized in the present work with the purpose of developing an in vitro model for the study of intestinal epithelial cell behaviour. Fragments of this intestine were kept in suspension culture for 7 days and then explanted onto collagen (type I) matrix. Within a day, the fragments became anchored to the substratum and a circular monolayer grew out to about 1 cm diameter. In the fragments, an outer layer of absorptive epithelial cells came to enclose a stroma, which was polarized into a loose (mesenchymal) and a dense portion. The dense portion contained a mixture of smooth muscle cells and primitive stem-type epithelial cells ('p-cells'). After explantation, at the contact point with the matrix, the epithelium broke up and the mesenchyme grew into the matrix and anchored the fragment. The epithelial edges now became continuous with the developing monolayer. Radioautography with tritiated thymidine indicated a constant cell renewal in epithelium and monolayer apparently from foci of p-cells, a reserve population of which was seen to be sequestered among the smooth muscle cells. Activated stem cells could differentiate into three mature epithelial phenotypes, each differentiation pathway apparently being determined by the type of underlying stroma. Immunohistochemistry using gold- and fluorescein-labeled monoclonal antibodies indicated that adult differentiation-specific markers (e.g. brush border enzymes) were present in the fragment epithelium but not in the monolayer cells. On the other hand, the monolayer cells could be induced to express some of these markers by contact with mesenchymal cells or by co-culturing with fibroblastic cell lines. Matrigel substratum mixed with collagen (type I) supported the appearance in monolayer of strands positive for amino-peptidase and lactase. The model thus appears to be suitable for the in vitro study of epithelial renewal and differentiation, and it has already provided some results in this respect.