Cytodifferentiation and tissue phenotype change during transformation of embryonic lens epithelium to mesenchyme-like cells in vitro

A number of adult and embryonic epithelia, when suspended within native type I collagen gels, give rise to elongate bipolar cells that migrate freely within the three-dimensional matrix. The morphology of these newly formed mesenchyme-like cells is indistinguishable from "true" mesenchymal cells at the light and ultrastructural level. In this report, we extend previous observations on the transformation of embryonic avian lens epithelium to mesenchyme-like cells. Lens epithelia, dissected from 12-day chick embryos, were cultured either within a collagen matrix or on a two-dimensional surface. Cells derived from explants on the surface of type I collagen express the epithelial phenotype. The cells form new basal lamina, continue to express delta-crystallin protein and secrete both type IV collagen and laminin. In contrast, epithelia suspended within collagen gels lose epithelial morphology, phenotype, and cytodifferentiation. The newly formed mesenchyme-like cells lack the ability to synthesize lens-specific delta-crystallin protein, type IV collagen, and laminin. They do, however, express type I collagen de novo, a characteristic of mesenchymal cells. The changes in cytodifferentiation and tissue phenotype which occur during the transformation are stable under the conditions studied here. When mesenchyme-like cells are removed from the gel and replated onto two-dimensional surfaces, they remain bipolar, will invade collagen matrices, and are unable to synthesize delta-crystallin protein.     

Type I collagen gel induces Madin-Darby canine kidney cells to become fusiform in shape and lose apical-basal polarity

In the embryo, epithelia give rise to mesenchyme at specific times and places. Recently, it has been reported (Greenburg, G., and E. D. Hay. 1986. Dev. Biol. 115:363-379; Greenberg, G., and E. D. Hay. 1988. Development (Camb.). 102:605-622) that definitive epithelia can give rise to fibroblast-like cells when suspended within type I collagen gels. We wanted to know whether Madin-Darby canine kidney (MDCK) cells, an epithelial line, can form mesenchyme under similar conditions. Small explants of MDCK cells on basement membrane were suspended within or placed on top of extracellular matrix gels. MDCK cells on basement membrane gel are tall, columnar in shape, and ultrastructurally resemble epithelia transporting fluid and ions. MDCK explants cultured on type I collagen gel give rise to isolated fusiform-shaped cells that migrate over the gel surface. The fusiform cells extend pseudopodia and filopodia, lose cell membrane specializations, and develop an actin cortex around the entire cell. Unlike true mesenchymal cells, which express vimentin and type I collagen, fusiform cells produce both keratin and vimentin, continue to express laminin, and do not turn on type I collagen. Fusiform cells are not apically-basally polarized, but show mesenchymal cell polarity. Influenza hemagglutinin and virus budding localize to the front end or entire cell surface. Na,K-ATPase occurs intracellularly and also symmetrically distributes on the cell surface. Fodrin becomes diffusely distributed along the plasma membrane, ZO-1 cannot be detected, and desmoplakins distribute randomly in the cytoplasm. The loss of epithelial polarity and acquisition of mesenchymal cell polarity and shape by fusiform MDCK cells on type I collagen gel was previously unsuspected. The phenomenon may offer new opportunities for studying cytoplasmic and nuclear mechanisms regulating cell shape and polarity.     

Factors affecting morphogenesis of rabbit gallbladder epithelial cells cultured in collagen gels

Although peptide growth factors play an important role in the morphogenesis of gallbladder, little is known about how they effect the morphogenesis of gallbladder epithelial cells. Rabbit gallbladder epithelial cells (RGEC) were isolated and cultured in monolayer or collagen gels. Epidermal growth factor (EGF), hepatocyte growth factor (HGF), epimorphin, transforming growth factor-beta 1 (TGF-beta 1), and fibroblast-conditioned medium (FCM) were added to the cultured cells to clarify the effects of these peptides and FCM on morphogenesis of RGEC. RGEC suspended in collagen gels form spherical cysts with morphologic polarity. EGF, HGF, epimorphin, and FCM promoted cyst maturation by accelerating the proliferation and aggregation of clear, polarized vesicles. In contrast, TGF-beta 1 markedly inhibited DNA synthesis in both monolayer and collagen gel cultures and promoted formation of branching structures in collagen gels. Furthermore, in the presence of EGF, TGF-beta 1 induced a drastic change in morphogenesis, with the formation of branching networks that showed cell-cell contact only at sites where branches touched. RGEC-forming multicellular cysts did not express vimentin but expressed significant amounts of cytokeratin and regained junctional complexes. In contrast, TGF-beta 1-treated cells strongly expressed vimentin along with branching structures and showed decreases in cytokeratin expression and junctional complexes. Thus, TGF-beta 1 induces a mesenchyme-like cell shape accompanied by cytoskeletal molecular changes, with loss of both epithelial polarization and junctional complexes. These results suggest that the morphogenetic program of RGEC is likely to be determined by the interaction of these peptides and the timing of their presence.     

Epithelia suspended in collagen gels can lose polarity and express characteristics of migrating mesenchymal cells

This study of epithelial-mesenchymal transformation and epithelial cell polarity in vitro reveals that environmental conditions can have a profound effect on the epithelial phenotype, cell shape, and polarity as expressed by the presence of apical and basal surfaces. A number of different adult and embryonic epithelia were suspended within native collagen gels. Under these conditions, cells elongate, detach from the explants, and migrate as individual cells within the three-dimensional lattice, a previously unknown property of well-differentiated epithelia. Epithelial cells from adult and embryonic anterior lens were studied in detail. Elongated cells derived from the apical surface develop pseudopodia and filopodia characteristic of migratory cells and acquire a morphology and ultrastructure virtually indistinguishable from that of mesenchymal cells in vivo. It is concluded from these experiments that the three-dimensional collagen gel can promote dissociation, migration, and acquisition of secretory organelles by differentiated epithelial cells, and can abolish the apical-basal cell polarity characteristic of the original epithelium.     

Neural crest migration in 3D extracellular matrix utilizes laminin, fibronectin, or collagen

The trunk neural crest originates by transformation of dorsal neuroepithelial cells into mesenchymal cells that migrate into embryonic interstices. Fibronectin (FN) is thought to be essential for the process, although other extracellular matrix (ECM) molecules are potentially important. We have examined the ability of three dimensional (3D) ECM to promote crest formation in vitro. Neural tubes from stage 12 chick embryos were suspended within gelling solutions of either basement membrane (BM) components or rat tail collagen, and the extent of crest outgrowth was measured after 22 hr. Fetal calf serum inhibits outgrowth in both gels and was not used unless specified. Neither BM gel nor collagen gel contains fibronectin. Extensive crest migration occurs into the BM gel, whereas outgrowth is less in rat tail collagen. Addition of fibronectin or embryo extract (EE), which is rich in fibronectin, does not increase the extent of neural crest outgrowth in BM, which is already maximal, but does stimulate migration into collagen gel. Removal of FN from EE with gelatin-Sepharose does not remove the ability of EE to stimulate migration. Endogenous FN is localized by immunofluorescence to the basal surface of cultured neural tubes, but is not seen in the proximity of migrating neural crest cells. Addition of the FN cell-binding hexapeptide GRGDSP does not affect migration into either the BM gel or the collagen gel with EE, although it does block spreading on FN-coated plastic. Thus, although crest cells appear to use exogenous fibronectin to migrate on planar substrata in vitro, they can interact with 3D collagenous matrices in the absence of exogenous or endogenous fibronectin. In BM gels, the laminin cell-binding peptide, YIGSR, completely inhibits migration of crest away from the neural tube, suggesting that laminin is the migratory substratum. Indeed, laminin as well as collagen and fibronectin is present in the embryonic ECM. Thus, it is possible that ECM molecules in addition to or instead of fibronectin may serve as migratory substrata for neural crest in vivo.     

Degradation of type IV collagen by matrix metalloproteinases is an important step in the epithelial-mesenchymal transformation of the endocardial cushions

Morphogenesis of some tissues and organs in the developing embryo requires the transformation of epithelial cells into mesenchyme followed by cell motility and invasion of surrounding connective tissues. Details of the mechanisms involved in this important process are beginning to be elucidated. The epithelial-mesenchymal transformation (EMT) process involves many steps, one of which is the upregulation and activation of specific extracellular proteinases including members of the matrix metalloproteinase (MMP) family. Here we analyze the role of MMPs in the initiation of the mesenchymal cell phenotype in the developing heart, and find that they are necessary for the invasion of mesenchymal cells into the extracellular matrix of the endocardial cushion tissues. An important requirement in the formation of this mesenchyme is the turnover of type IV collagen along the basal surface of endocardial cells. In vitro experiments suggest that type IV collagen does not provide a suitable migratory substrate for endocardial cushion cells unless MMP-2 and MT-MMP are active. Relevant MMPs were found to be upregulated by factors known to be involved in the induction of the EMT such as TGFbeta3. These results provide evidence of an important role for MMPs during a specific stage of the epithelial mesenchymal transformation in the embryonic heart, and suggest that specific cell-matrix interactions which facilitate cell migration only occur when the composition of the surrounding extracellular matrix is proteolytically altered.     

Epithelial and mesenchymal cell differentiation in the fetal rat genital ducts: changes in the expression of cytokeratin and vimentin type of intermediate filaments and desmosomal plaque proteins

Mesonephric and paramesonephric ducts develop in different ways in male and female fetuses. We have analyzed the changes in the expression of cytokeratin and vimentin type of intermediate filaments and desmosomal plaque proteins in progressing and regressing genital ducts of rat fetuses. The concomitant changes in the basement membranes were detected by laminin antibody. Epithelial cells of the indifferent (Day 15) male and female mesonephric and paramesonephric ducts contained faint vimentin positivity which, however, later disappeared. Indifferent mesonephric duct epithelium stained strongly for cytokeratin, whereas in the corresponding paramesonephric duct only a weak and spotty positivity was seen. Immunocytochemical localization of cytokeratin filaments and desmosomal plaque proteins correlated with the ultrastructural differences in the apical junctional complexes of the mesonephric and paramesonephric ducts. Regardless of the ongoing regression of the male paramesonephric duct, cytokeratin positivity increased in the disorganizing epithelium; the most weak and a granular immunoreaction was seen in the cells found in the intensively vimentin-positive periductal mesenchyme. In the regressing female mesonephric duct cytokeratin positivity was lost before the final dissolution of the basement membrane. Immunoblotting analysis of cytokeratin and vimentin polypeptides of the individual genital ducts were in agreement with the immunocytochemical results obtained in 15- and 16-day-old fetuses. The results suggest that the expression of vimentin type intermediate filaments is an indication of the mesothelial origin of the genital ducts. The increase in cytokeratin positivity of the regressing paramesonephric duct epithelium suggests that the degenerative changes are initiated by the mesenchyme. Cytokeratin-positive cells found in the periductal mesenchyme of the male paramesonephric duct may be epithelial cells transforming into mesenchyme. The results emphasize a close relationship between the changes of the intermediate filament system and extracellular matrix upon differentiation of the fetal genital ducts.     

Matrix-cytoskeletal interactions in the developing eye

The embryonic avian corneal epithelium in vitro responds to extracellular matrix (ECM) molecules in either soluble or polymerized form by flattening its basal surface, organizing the basal cortical actin cytoskeleton, and stepping up its production of corneal stroma twofold. Embryonic corneal epithelia, like hepatocytes and mammary gland cells, seem to contain heparan sulfate proteoglycan (HSPG) in their plasmalemma, which may interact with actin on the one hand or underlying collagen on the other. Work on the corneal epithelium suggests that, in addition to HSPG, specific glycoprotein receptors for laminin and collagen exist in the basal plasmalemma and play the critical role in actually organizing the basal epithelial cytoskeleton. As yet, uncharacterized proteins may link such receptors to actin. We suggest that ECM-dependent organization of the cytoskeleton is responsible for ECM enhancement of corneal epithelial differentiation. Cell shape and exogenous ECM also affect mesenchymal cell differentiation. In the case of the corneal fibroblast migrating in collagen gels, an actin cortex present around the elongate cell seems to interact with myosin in the cytosol to bring about pseudopodial extension. Both microtubules and actin microfilaments are involved in fibroblast elongation in collagen gels. It follows from the rules presented in this review that the mesenchymal cell surface is quite different from the epithelial cell surface in its organization. Nevertheless, epithelial cell surface-ECM interaction can be modified in the embryo at particular times to permit predesignated epithelial-mesenchymal transformations, as for example at the primitive streak. Though basal surfaces of definitive, nonmalignant epithelia adhere rather strictly to the rules of epithelium-ECM interaction and do not invade underlying ECM, the environment can be manipulated in vitro to cause these epithelia to send out pseudopodia and give rise aberrantly to mesenchymal cells in collagen gels. Further study of this phenomenon should cast light on the manner in which epithelial and mesenchymal cells organize receptors for matrix molecules on their cell surfaces and develop appropriate cytoskeletal responses to the extracellular matrix.     

In vitro stimulation of cartilage in embryonic chick neural crest cells by products of rentinal pigmented epithelium.

The retinal pigmented epithelium of the chick embryo influences head neural crest mesenchymal cells to form the scleral cartilage of the eye. The possible role of extracellular matrix in this interaction was studied. Extracellular matrix was deposited on Millipore filters in vitro by pigmented epithelial cells which were then killed by distilled water lysis. When grown on the Millipore filters which had carried pigmented epithelium, clonal neural crest and periocular mesenchyme “target” cells formed cartilage in 61 of 155 experiments. Cartilage was not formed when the cells were grown on naked filters nor did gels of purified Type I and Type II collagen promote chondrogenesis. It is concluded that extracellular matrix deposited by the pigmented epithelium in vitro is a potent stimulus for the induction of chondrogenesis in competent mesenchyme, and that living pigmented epithelial cells need not be present for such induction.     

Control of corneal differentiation by extracellular materials. Collagen as a promoter and stabilizer of epithelial stroma production

The primary stroma of the cornea of the chick embryo consists of orthogonally arranged collagen fibrils embedded in glycosaminoglycan (GAG) produced by the epithelium under the early inductive influence of the lens. The experiments reported here were designed to test whether or not the collagen of the lens basement lamina is capable of stimulating corneal epithelium to produce primary stroma. Enzymatically isolated 5-day-old corneal epithelia were grown for 24 hr in vitro in the presence of ³⁵SO₄ or proline-³H on various substrata. Epithelia cultured on lens capsule synthesized 2.5 times as much GAG (as measured by incorporation of label into CPC precipitable material) and almost 3 times as much collagen (assayed by hot TCA extraction or collagenase sensitivity) as when cultured on Millipore filter or other noncollagenous substrata. A similar stimulatory response was observed when epithelium was combined with chemically pure chondrosarcoma collagen, NaOH-extracted lens capsule, vitreous humor, frozen-killed corneal stroma or cartilage, or tendon collagen gels; in the latter case, the magnitude of the effect can be shown to be related to concentration of the collagen in the gel. All of the collagenous substrata stimulate not only extracellular matrix production, but also polymerization of corneal-type matrix, as judged by ultrastructural criteria and by the association of more radioactivity with the tissue than the medium. Since purified chondrosarcoma collagen is as effective as lens capsule, the stimulatory effect on collagen and GAG synthesis by corneal epithelium is not specific for basal lamina (lens capsule) collagen.     

Different substrates influence the expression of intermediate filaments and the deposition of basement membrane proteins

Summary A primary culture of serous cystadenocarcinoma of the ovary was used to study the expression of intermediate filament proteins and the deposition of basal lamina proteins. It was found that cells grown on type I and IV collagens or in collagen gels failed to express vimentin, which was readily demonstrable in cultures of the same cells grown on plastic or glass. Furthermore cells grown in collagen gels formed colonies demonstrating a cystic architecture Unlike what is commonly observed on glass or plastic where laminin and fibronectin are deposited as disorganized fibrils in the extracellular space, in or on collagen these proteins appear solely at the interface between the epithelial cells and matrix. The results suggest that the extracellular matrix influences the cytoskeletal organization of the intermediate filaments and determines cell polarity. They confirm that collagen substrates permit epithelial cell cultures to progress toward a more differentiated state. Supported by grants from the Italian Assciation for Cancer Research (AIRC).     

Effects of extracellular matrix components on the differentiation of chick embryo tail bud mesenchyme in culture

The mesenchymal cells of the chick tail bud comprise the remains of Hensen's node and the primitive streak after gastrulation. This mass of cells, situated at the caudal limit of the chick embryo, is morphologically homogeneous but pluripotent, with the ability to differentiate into a variety of tissues that are both ectoderm- and mesoderm-derived elsewhere in the embryo. These tissues include neuroectoderm, neurons, myoblasts and chondrocytes. As the factors regulating the differentiation of tail bud mesenchyme into so many cell types are unclear, and because the extracellular matrix (ECM) is known to have a profound effect on cellular differentiation in many embryonic systems, we studied the differentiation of tail bud mesenchyme explanted onto a variety of different ECM components as substrata. We report that the histogenetic potential of isolated tail buds in culture compares favourably with that in situ. Using various antibody markers, we have demonstrated that tail bud mesenchyme cultured upon different ECM components as substrata is able to differentiate into neurons, neuroepithelium, melanocytes, muscle and cartilage. Laminin and laminin-containing substrata (Matrigel) were found to promote the differentiation of neural crest derivatives (neurons and melanocytes) and neuroepithelial cells; type I collagen promoted both myogenesis and chondrogenesis; while type IV collagen promoted myogenesis only. We have therefore demonstrated that differentiation of tail bud mesenchyme in vitro is substratum-dependent.     

Culture on basement membrane does not reverse the phenotype of lens derived mesenchyme-like cells

Definitive epithelia suspended within type I collagen gel give rise to individual, freely migrating cells that express the mesenchymal phenotype. They become elongate in shape, invade collagenous matrices and develop abundant RER. We investigated whether mesenchyme-like cells that derive from lens epithelia retain the mesenchymal phenotype or revert to epithelial phenotype when cultured on basement membrane (BM). Mesenchyme-like cells placed on top of BM gel or lens capsule BM retain the elongate, bipolar morphology of mesenchymal cells. They migrate individually along and into the BM matrix. Mesenchyme-like cells on or in BM ultrastructurally resemble true mesenchymal cells. They extend pseudopodia and filopodia, exhibit a circumferential actin cortex, and contain well developed RER. Mesenchymal products, such as type I collagen, continue to be expressed. We conclude that the phenotype of mesenchyme-like cells derived from definitive epithelia is stable even in or on matrix known to promote the epithelial genetic program. Their behavior, thus, is similar to that of true (secondary) mesenchymal cells in the embryo.     

Collagenous substrata regulate the nature and distribution of glycosaminoglycans produced by differentiated cultures of mouse mammary epithelial cells

We have investigated the influence of culture substrata upon glycosaminoglycans produced in primary cultures of mouse mammary epithelial cells isolated from the glands of late pregnant mice. Three substrata have been used for experiments: tissue culture plastic, collagen (type I) gels attached to culture dishes, and collagen (type I) gels that have been floated in the culture medium after cell attachment. These latter gels contract significantly. Cells cultured on all three substrata produce hyaluronic acid, heparan sulfate, chondroitin sulfates and dermatan sulfate but the relative quantities accumulated and their distribution among cellular and extracellular compartments differ according to the nature of the culture substratum. Notably most of the glycosaminoglycans accumulated by cells on plastic are secreted into the culture medium, while cells on floating gels incorporate almost all their glycosaminoglycans into an extracellular matrix fraction. Cells on attached collagen gels secrete approx. 30% of their glycosaminoglycans and assemble most of the remainder into an extracellular matrix. Hyaluronic acid is produced in significant quantities by cells on plastic and attached gels but in relatively reduced quantity by cells on floating gels. In contrast, iduronyl-rich dermatan sulfate is accumulated by cells on floating gels, where it is primarily associated with the extracellular matrix fraction, but is proportionally reduced in cells on plastic and attached gels. The results are discussed in terms of polarized assembly of a morphologically distinct basal lamina, a process that occurs primarily when cells are on floating gels. In addition, as these cultures secrete certain milk proteins only when cultured on floating gels, we discuss the possibility that cell synthesized glycosaminoglycans and proteoglycans may play a role in the maintenance of a differentiated phenotype.     

Syndecan and tenascin expression is induced by epithelial-mesenchymal interactions in embryonic tooth mesenchyme

Morphogenesis of embryonic organs is regulated by epithelial-mesenchymal interactions associating with changes in the extracellular matrix (ECM). The response of the cells to the changes in the ECM must involve integral cell surface molecules that recognize their matrix ligand and initiate transmission of signal intracellularly. We have studied the expression of the cell surface proteoglycan, syndecan, which is a matrix receptor for epithelial cells (Saunders, S., M. Jalkanen, S. O'Farrell, and M. Bernfield. J. Cell Biol. In press.), and the matrix glycoprotein, tenascin, which has been proposed to be involved in epithelial-mesenchymal interactions (Chiquet-Ehrismann, R., E. J. Mackie, C. A. Pearson, and T. Sakakura. 1986. Cell. 47:131-139) in experimental tissue recombinations of dental epithelium and mesenchyme. Our earlier studies have shown that in mouse embryos both syndecan and tenascin are intensely expressed in the condensing dental mesenchyme surrounding the epithelial bud (Thesleff, I., M. Jalkanen, S. Vainio, and M. Bernfield. 1988. Dev. Biol. 129:565-572; Thesleff, I., E. Mackie, S. Vainio, and R. Chiquet-Ehrismann. 1987. Development. 101:289-296). Analysis of rat-mouse tissue recombinants by a monoclonal antibody against the murine syndecan showed that the presumptive dental epithelium induces the expression of syndecan in the underlying mesenchyme. The expression of tenascin was induced in the dental mesenchyme in the same area as syndecan. The syndecan and tenascin positive areas increased with time of epithelial-mesenchymal contact. Other ECM molecules, laminin, type III collagen, and fibronectin, did not show a staining pattern similar to that of syndecan and tenascin. Oral epithelium from older embryos had lost its ability to induce syndecan expression but the presumptive dental epithelium induced syndecan expression even in oral mesenchyme of older embryos. Our results indicate that the expression of syndecan and tenascin in the tooth mesenchyme is regulated by epithelial-mesenchymal interactions. Because of their early appearance, syndecan and tenascin may be used to study the molecular regulation of this interaction. The similar distribution patterns of syndecan and tenascin in vivo and in vitro and their early appearance as a result of epithelial-mesenchymal interaction suggest that these molecules may be involved in the condensation and differentiation of dental mesenchymal cells.     

Fibronectin accelerates the growth and differentiation of ameloblast lineage cells in vitro.

During tooth development, the growth and differentiation of ameloblast lineage (AL) cells are regulated by epithelial-mesenchymal interactions. To examine the dynamic effects of components of the basement membrane, which is the extracellular matrix (ECM) lying between the epithelium and mesenchyme, we prepared AL cells from the epithelial layer sheet of mandibular incisors of postnatal day 7 rats and cultured them on plates coated with type IV collagen, laminin-1, or fibronectin. The growth of AL cells was supported by type IV collagen and fibronectin but not by laminin-1 in comparison with that on type I collagen as a reference. Clustering and differentiation of AL cells were observed on all matrices examined. AL cells showed normal growth and differentiation at low cell density on fibronectin but not on type I collagen. Furthermore, the population of cytokeratin 14-positive cells on fibronectin was lower than that on other ECM components, suggesting that fibronectin may be a modulator to accelerate the differentiation of AL cells. After the cells had been cultured for 9 days on fibronectin, crystal-like structures were observed. These structures overlaid the cell clusters and were positive for von Kossa staining. These findings indicate that each matrix component has a regulative role in the proliferation and differentiation of AL cells and that fibronectin causes the greatest acceleration of AL cell differentiation.     

An SEM analysis of the epithelial--mesenchymal interface in the mandible of the embryonic chick

In this paper the ultrastructural features of the epithelial-mesenchymal interface in mandibular processes of embryonic chicks have been examined using scanning electron microscopy. Mandibular epithelium is required for the mesenchyme to differentiate as osteoblasts and to deposit the membrane bones of the mandible. The surface morphology of the epithelium changes from the lateral to the medial face of the mandible from rounded cells, each with a central cilium to flattened cells with numerous microvilli. Treatment with trypsin and pancreatin was used to digest the basal lamina so as to separate epithelium from mesenchyme. This exposed a thick, fibrillar basement membrane (reticular lamina), which was thicker underlying the caudal epithelium than under the cephalad epithelium. Addition of collagenase to the trypsin/pancreatin solution degraded some of the basement lamella, especially that underlying epithelium on the caudal portion of each mandibular process. Selective degradation of basement lamella is postulated as one means of regulating inductive epithelial-mesenchymal interactions. EDTA was used to isolate basal laminae on mandibular mesenchyme. SEM was used to confirm the integrity of the basal lamina, its structure, and its association with overlying epithelial cells and underlying basement lamella.     

Early mouse molar root development: Cellular changes and distribution of fibronectin, laminin and type-IV collagen

We analysed epithelial-mesenchymal interactions that occur during the early stages of the formation of mouse molar roots using light and electron microscopy. Morphological changes observed in the cells of Hertwig's epithelial sheath, the pulp and the follicular mesenchyme are described. The Hertwig's epithelial cells lose their cuboidal form and become flattened, apparently intermixing with the cells of the follicular mesenchyme. At the light- and electron-microscope levels, immunoperoxidase techniques were used to localize fibronectin, laminin and type-IV collagen. These appear to be closely associated with cell differentiation and matrix deposition in developing tooth roots. In addition, at the ultrastructural level, intracellular immunoreactivity was detected. The rough endoplasmic reticulum and nuclear envelope of some cells of the periodontal ligament facing the acellular cementum exhibited specific reactivity with laminin and type-IV collagen. Moreover, these periodontal ligament cells express keratin, but not vimentin, filaments. Our results demonstrate that Hertwig's epithelial cells maintain their capacity to synthesize laminin and type-IV collagen, as well as to express keratin filaments, despite basement membrane fragmentation and the disorganization of Hertwig's epithelial sheath. Thus, some Hertwig's epithelial cells remain in the periodontal ligament intermixed with follicular mesenchyme cells.     

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.     

Influence of collagen gel on the orientation of epithelial cell polarity: follicle formation from isolated thyroid cells and from preformed monolayers

The influence of collagen gels on the orientation of the polarity of epithelial thyroid cells in culture was studied under four different conditions. (a) Isolated cells cultured on the surface of a collagen gel formed a monolayer. The apical pole was in contact with the culture medium and the basal membrane was attached to the substratum. (b) Isolated cells embedded inside the gel organized within 8 into follicles. The basal pole was in contact with collagen and the apical pole was oriented towards the interior of the follicular lumen. (c) Cells were first organized into floating vesicles, structures in which the apical surface is in contact with the culture medium, and the vesicles were embedded inside the collagen gel. After 3 d, cell polarity was inverted, the apical pole being oriented towards the cavity encompassed by cells. Vesicles had been transformed into follicles. (d) Monolayers formed on collagen gels as in a were overlaid with a second layer of collagen, which was polymerized in contact with the apical cell surface. A disorganization of the continuous pavement occurred within 24 h; cells attached to the upper layer of collagen and reorganized into follicles in the collagen sandwich within 4-8 d. A similar process occurred when the monolayer was grown on plastic and overlaid with collagen, or grown on collagen and covered with small pieces of glass cover slips. No reorganization was observed between two glass surfaces. In conclusion, first, a basal pole was always formed in the area of contact between the cell membrane and an adhesive surface and, second, the interaction of a preformed apical pole with an adhesive surface was not compatible with the stability of this domain of the plasma membrane. The interaction of the cell membrane with extracellular components having adhesive properties appears to be a determinant factor in the orientation and stabilization of epithelial cell polarity.