Retention of epithelial basal lamina allows isolated mandibular mesenchyme to form bone

The initiation of bone formation in the avian mandible requires that neural crest-derived cells undergo an inductive interaction with mandibular epithelium. To examine the role of the epithelial basal lamina in that interaction, mandibles were separated into their epithelial and mesenchymal components following exposure to the chelating agent, EDTA. Transmission and scanning electron microscopy was used to show that the basal lamina was retained as a continuous layer over the mesenchyme. Osteogenesis was initiated when such EDTA-isolated mesenchyme was grafted to the chorioallantoic membranes of host embryos. In contrast, mesenchyme isolated using trypsin and pancreatin failed to form bone. It is concluded that the property of mandibular epithelium which permits osteogenesis resides within the basal lamina.     

An ultrastructural analysis of cell and matrix differentiation during early limb development in Xenopus laevis

Early development of the hind limb of Xenopus (stages 44–48) has been analyzed at the level of ultrastructure with emphasis on differentiation of extracellular matrix components and intercellular contacts. By stages 44–45, mesenchyme is separated from prospective bud epithelium by numerous adepidermal granules in a subepithelial compartment (the lamina lucida), a continuous basal lamina and several layers of collagen (the basement lamella). Tricomplex stabilization of amphoteric phospholipid demonstrates that each adepidermal granule consists of several membranelike layers (electron-lucent band 25–30 Å; electron-dense band 20–40 Å), which are usually parallel to the basal surface of adjacent epithelial cells. Collagen fibrils are interconnected by filaments (35 Å in diameter) which stain with ruthenium red. Epithelial cells possess junctional complexes at their superficial borders, numerous desmosomes at apposing cell membranes and hemidesmosomes at their basal surface. Mesenchymal cells predominantly exhibit close contacts (100–150 Å separation) with few focal tight junctions at various areas of their surface. By stages 47–48, adepidermal granules are absent beneath bud epithelium and layers of collagen in the basement lamella lose filamentous cross-linking elements. Filopodia of mesenchymal cells penetrate the disorganized matrix and abut the basal lamina. Hemidesmosomes disappear at the basal surface of the epidermis and mesenchymal cells immediately subjacent to epithelium exhibit focal tight junctions and gap junctions at their lateral borders. These structural changes may be instrumental in the epitheliomesenchymal interactions of early limb development. Degradation of oriented collagenous lamellae permits direct association of mesenchymal cell surfaces (filopodia) with surface-associated products of epithelial cells (organized into the basal lamina). Development of structural pathways for intercellular ion and metabolite transport in mesenchyme may coordinate events specific to limb morphogenesis.     

Differential response of embryonic cells to culture on tissue matrices.

Cell responses to different natural substrates have been followed by scanning microscopy in order to evaluate the role of these substrates in morphogenesis. Matrix has been isolated then repopulated with suspensions of embryonic cells from chick skin, spinal ganglia, duodenal epithelium and heart. In some cases outgrowth from amphibian embryonic tissue was used. Basal lamina of the Xenopus tail may be exposed by freezing and thawing the tissue, or by EDTA treatment. The underlying lamella of orthogonally oriented collagen fibers may be exposed by use of trypsin or hyaluronidase. Trypsin causes more clumping of collagen fibers and a coarser texture of the matrix. On trypsin isolated basement lamella, nerve cell processes grow out on the surface and show no strong tendency to penetrate the lamella while skin mesenchymal cells commonly burrow among the collagen plies. Epithelial cells remain on the surface. On the basal lamina mesenchymal cells ruffle in early stages of culture, then flatten. Epithelial cells flatten rapidly on the lamina. These differences in cell response are in some cases closely related to cell behavior in vivo and suggest that cells show a selective response to the chemical composition of the substrate as well as to its physical conformation.     

Response of epithelial and mesenchymal cells to culture on basement lamella observed by scanning microscopy

The basement lamella of Xenopus tadpole skin has been viewed in situ by scanning microscopy, then isolated by trypsin treatment and used as a substrate for cell culture. The basal lamina may also be viewed after EDTA treatment. Responses of epithelial and mesenchymal cells to the lamella have been compared. Mesenchymal cells from chick skin and heart ventricle flatten and attach between the plies of the lamella, then infiltrate it. Myoblasts appear to move less readily within the lamella. Embryonic Xenopus skin epithelium spreads over the surface. Isolated chick skin epithelial cells first begin to spread, then round up and eventually attach to each other in clusters which form a flat basal surface above the lamella. Thus epithelial and mesenchymal cells cultured on this isolated extracellular material mimic aspects of normal tissue organization.     

Association of mesenchyme with attenuated basement membranes during morphogenetic stages of newt limb regeneration

The interface between epithelium and mesenchyme may be involved in inductive interactions which occur during development. This interface within the growth bud, or blastema, of a regenerating limb has been examined to determine whether changes in basement-membrane structures are visible in regions of putative epithelial-mesenchymal inductive interaction. Regenerating forelimbs of adult newts were fixed by perfusion with osmotically balanced aldehydes. Late-bulb to early-digit stage regenerates were collected and processed either for light and transmission electron microscopy or for scanning electron microscopy. Light microscopy confirmed that regions characterized by increased numbers of subepithelial mesenchymal cells were covered by a diffusely stained basement membrane. Transmission electron microscopy of these regions revealed two structural components of the basement membrane. The thin basal lamina was continuous in all regions of all stages examined, but it was attenuated apically in areas of mesenchymal cell accumulation. The thicker underlying reticular lamina was markedly attenuated in these regions near the blastemal apex. Scanning electron microscopy of de-epithelialized blastemas revealed that, apically, the reticular lamina formed only a delicate lacelike network. On the base of the blastema, it formed a dense fibrillar meshwork which was further organized into a geometric pattern in the adjacent stump skin. Cumulatively, these observations suggest that physical contact between epithelial and mesenchymal cells is not essential at these stages, but that regions of putative epithelial-mesenchymal interaction are characterized by a distinctly diminished reticular lamina. Structural changes in basement-membrane components may be related to termination of local inductive events.     

Epithelial-Directed Mesenchyme Differentiation in vitro

To assess the requirement for specific or possibly non-specific epithelial instructions for mesenchymal cell differentiation, we designed studies to evaluate and compare homotypic with heterotypic tissue recombinations across vertebrate species. These studies further tested the hypothesis that determined dental papilla mesenchyme requires epithelial-derived instructions to differentiate into functional odontoblast cells using a serumless, chemically-defined medium. Theiler stage 25 C57BL/6 or Swiss Webster cap stage mandibular first molar tooth organs or trypsin-dissociated, homotypic epithelial-mesenchymal tissue recombinants resulted in the differentiation of odontoblasts within 3 days. Epithelial differentiation into functional ameloblasts was observed within 7 days. Trypsin-dissociated and isolated mesenchyme did not differentiate into odontoblasts under these experimental conditions. Heterotypic recombinants between quail Hamburger-Hamilton stages 22–26 mandibular epithelium and Theiler stage 25 dental papilla mesenchyme routinely resulted in odontoblast differentiation within 3 days in vitro. Odontoblast differentiation and the production of dentine extracellular matrix continued throughout the 10 days in organ culture. Ultrastructural observations of the interface between quail and mouse tissues indicated the reconstitution of the basal lamina as well as the maintenance of an intact basal lamina during 10 days in vitro. Quail epithelial cells did not differentiate into ameloblasts and no enamel extracellular matrix was observed. These results show that quail mandibular epithelium can provide the required developmental instructions for odontoblast differentiation in the absence of serum or other exogenous humoral factors in a chemically-defined medium. They also suggest the importance of reciprocal epithelial-mesenchymal interactions during epidermal organogenesis.     

Structure of the epithelial - mesenchymal interface during early morphogenesis of the chick duodenum.

During the period of early morphogenetic folding of the intestinal epithelium, changes in the epithelial-mesenchymal interface were observed by light microscopy, scanning and transmission electron microscopy. The epithelium in cross-section, appears first as a circle, then an ellipse and finally by a triangle prior to the formation of the first three previllous ridges. The bases of all epithelial cells are flat at the circular stage. At the ellipse and triangle stages the bases of the epithelial cells occupying the sides possess lobopodia that do not penetrate the basal lamina. The immediate mesenchymal cells subjacent to those epithelial cells on the sides of the ellipse and triangle alter their orientation to being rounded-up or perpendicular to the plane of the basal lamina. Large numbers of fine mesenchymal pseudopodia in addition to many extracellular fibrils are revealed by transmission and scanning electron microscopy at the epithelial-mesenchymal interface. The fine mesenchymal pseudopodia come into close contact but do not penetrate the ruthenium red-staining basal lamina. The possible roles of close contact between epithelium and mesenchyme, the alteration in orientation of mesenchyme cells, and of the basal lamina in tissue interaction are discussed.     

Cytoskeleton and thyroglobulin expression change during transformation of thyroid epithelium to mesenchyme-like cells

In considering the mechanism of transformation of epithelium to mesenchyme in the embryo, it is generally assumed that the ability to give rise to fibroblast-like cells is lost as epithelia mature. We reported previously that a definitive embryonic epithelium, that of the anterior lens, gives rise to freely migrating mesenchyme-like cells when suspended in type I collagen matrices. Here, we show that a highly differentiated epithelium that expresses cytokeratin changes to a vimentin cytoskeleton and loses thyroglobulin during epithelial-mesenchymal transformation induced by suspension in collagen gel. Using dispase and collagenase, we isolated adult thyroid follicles devoid of basal lamina and mesenchyme, and we suspended the follicles in 3D collagen gels. Cells bordering the follicle lumen retain epithelial polarity and thyroid phenotype, but basal cell surface organization is soon modified as a result of tissue multilayering and elongation of basal cells into the collagenous matrix. Cytodifferentiation, determined by thyroglobulin immunoreactivity, is lost as the basal epithelial cells move into the matrix after 3-4 days in collagen. By TEM, it can be seen that the elongating cells acquire pseudopodia, filopodia and mesenchyme-like nuclei and RER. Immunofluorescence examination of intermediate filaments showed that freshly isolated follicles and follicles cultured on planar substrata react only with anticytokeratin. However, all of the mesenchyme-like cells express vimentin and they gradually lose cytokeratin. These results suggest that vimentin may be necessary for cell functions associated with migration within a 3D matrix. The mesenchymal cells do not revert to epithelium when grown on planar substrata and the transformation of epithelium to mesenchyme-like cells does not occur within basement membrane gels. The results are relevant to our understanding of the initiation of epithelial-mesenchymal transformation in the embryo and the genetic mechanisms controlling cell shape, polarity and cytoskeletal phenotype.     

The ultrastructure of the blood vessels of Branchiostoma lanceolatum (Pallas) (Cephalochordata)

Summary The ultrastructure of the blood vessels in the caudal region of Branchiostoma is described in specimens injected with indian ink. None of the vessels have endothelial cells delimiting the luminal surface. The vessels are delimited either by dense connective tissue or by the characteristic basement lamella underneath the basal lamina of the myocoelic epithelium. It is proposed that the main blood flow in the caudal region follows different pathways depending on the activity of the animal. During swimming the muscle activity of the caudal muscles may have the effect that more blood flows from the aorta to the myoseptal plexi and is drained to the caudal vessel. In the resting animal it is possible that the blood flow through the myosepta is insignificant, and that the caudal blood flow is more or less restricted to the direct connections between the aorta and the caudal vessel: the dorsoventral anastomosis and the segmental connecting vessels.Supported by a grant from the Danish Natural Science Research Council     

Morphogenetic determination of the dermoepidermal interface during tail regeneration in Rana catesbeiana.

During regeneration of the amputated tadpole tail, reconstruction of the epithelial basal lamina and basement lamella occurs only after the other major morphogenetic processes are well established. At 4 days after tail transection of the bullfrog tadpole, electron microscopy of the internal surface of the basal cell layer of the blastemal epithelium reveals it to be relatively free of extracellular matrix. By 11 days a basal lamina of distinct regularity has formed, and the first rodlets and fibers signaling the replacement of the collagenous basement lamella are identified. At 15 days the basal cells of the epithelium start to exhibit specialization of their internal cell surfaces: Hemidesmosomes and associated tonofilaments appear, and the adepidermal globular layer is formed. Orthogonal packing of collagen plies begins by 19 days after transection, the number of layers exceeding 22 in the latter stages of regeneration.     

Effects of mesenchyme of the embryonic urogenital sinus and neonatal seminal vesicle on the cytodifferentiation of the Dunning tumor: ultrastructural study.

The aim of the present study was to examine the effects of mesenchyme on the cytodifferentiation of the Dunning tumor (DT, R3327), a transplantable rat prostatic adenocarcinoma developed spontaneously from the dorsolateral prostate of a Copenhagen rat. Small pieces of DT were combined with mesenchyme of the rat urogenital sinus (18-day fetal, UGM) or seminal vesicle (0-day neonatal, SVM). Both types of combinations were grown under the kidney capsule of male athymic nude mice for 4 weeks. At harvest, the tissue recombinants were fixed and processed for electron microscopy. Grafts of parental DT were similarly processed for electron microscopy. The tumor was characterized by tubules lined by 2-3 layers of undifferentiated cells lacking secretory granules. The basal lamina was reduplicated, and epithelioid cells traversing gaps in the basal lamina were frequently observed. The stroma was composed of a mixture of fibroblastic and large epithelioid cells derived from the ductal lining epithelium through a process of micrometastasis. In UGM or SVM+DT combinations the mesenchyme influenced the differentiation and secretory activity of the DT epithelium. The induced DT epithelial cells exhibited a well-developed granular endoplasmic reticulum, a large Golgi apparatus and prominent secretory granules which were never observed in the parental DT. The basal lamina returned to normal, while the incidence of micrometastasis was decreased. The collagen content of the stroma was increased with a concurrent appearance of smooth muscle cells surrounding those tubules where secretory cytodifferentiation had occurred. While the mechanism involved in the mesenchyme-induced change in cytodifferentiation remains unknown, it is evident that the DT epithelial cells when associated with normal embryonic or neonatal mesenchyme can express a more normal cytodifferentiation and function. It is concluded (a) that the DT cells can be induced by mesenchyme to express more highly differentiated ultrastructural patterns and secretory cytodifferentiation, (b) that the induced secretory cytodifferentiation is associated with a reduction in invasiveness (micrometastasis) and a more normal-appearing basal lamina and (c) that the increased abundance of collagen fibers and the differentiation of smooth muscle in the stromal compartment are associated with secretory cytodifferentiation suggesting that reciprocal epithelial-mesenchymal interactions are involved in the regulation of the pathobiology of the DT.     

The epithelial origin of lymphocytes in the palatine tonsil of rabbits

Lymphopoiesis was studied by electron microscopy in the palatine tonsil of the rabbit from 18 days gestation to 5 days after birth. At 18 days tonsils formed as mounds of mesenchyma covered with epithelium. At 19 days the basal epithelial cells started to increase in number, eventually forming 'buds' which projected into the mesenchyme. Simultaneously, lymphocytes appeared nearthe epithelium or buds. There was marked resemblance between the basal epithelial cells and the lymphocytes. Budding slowed down after the 25th day, but individual basal cells continued to migrate into the mesenchyme and lymphocytes increased in number. Ultrastructure wassimilar in both types of cells, and differentfrom mesenchymal cells. At 29 days lymphocytes were found in the basal epithelial layer behind an intact basement membrane. The evidence indicated that lymphocytes were derived from epithelium.     

Palatogenesis in hamster. II. Ultrastructural observations on the closure of palate

Formation of secondary palate in hamster was studied with electron microscopy. Prior to assuming horizontal position, the palatal shelves were covered by a two to three cell layer thick epithelium which was separated from the underlying mesenchyme by an intact basal lamina. Epithelial cells were attached to each other by desmosomes. Early hemidesmosomes could be identified as thickenings of the cytoplasmic membrane opposing the basal lamina. Epithelial cells, like other embryonic cells, contained only few organelles but were rich in polyribosomes. As the horizontal shelves approached each other towards the midline, lysosomes and tonofilaments appeared in the superficial and basal cells of the epithelia. Superficial cells showed degeneration and eventual lysis. Fusion of the opposing epithelia occurred between the deeper cells by means of newly formed desmosomes. The epithelial seam resulting from fusion of the epithelia was limited on each side by a continuous basal lamina. Its subsequent thining and eventual fragmentation resulted from the loss of cells by autophagy. There was no evidence of mesenchymal invasion of the epithelial seam. Mesenchymal macrophages appeared in the later stage of palatogenesis and were responsible for phagocytosis of cellular debris. Formation of the soft palate was basically similar to that of the secondary hard palate and occurred by fusion of the opposing shelves. Similarly, anterior closure of the palate occurred by fusion of the lower end of the nasal septum to the primary and secondary palates. Hyperplasia of the opposing epithelia, prior to their fusion, was often seen. It is suggested that formation of the palate occurs in predictable and coordinated fashion and that timely appearance of lysosomes causing lysis of intervening epithelia is of great significance in normal palatogenesis.     

Patterns of cell polarity in the developing mouse limb

Most cells have a morphological polarity with the centrioles and Golgi apparatus occupying one pole of the cell and the nucleus the other. This structural polarity often correlates with functional polarity as in secretory epithelia where the Golgi apparatus moves to the pole of the cell from which secretory materials are exreted. In limb development an interaction of unknown mechanism occurs between the epithelium and mesenchyme. We have evaluated the pattern of cell polarity using silver impregnation of the Golgi apparatus in limb epithelium and mesenchyme of mouse embryos from day 9.5, when limbs are first visible, to day 15, when cartilage formation is complete. Cells in the epithelium almost always have the Golgi apparatus in the apex of the cell, i.e., oriented away from the basement membrane. The layer of mesenchyme cells just beneath the basement membrane initially has only 16 to 25% of the cells oriented toward the basement membrane. A marked shift in orientation occurs between days 12 and 13 so that from days 13 to 15 up to 53% of the mesenchyme cells are oriented toward the basement membrane. This shift in orientation occurs more slowly in the mesenchyme at a depth of four cells below the basement membrane. This changing pattern of mesenchymal cell polarity occurs at a time when there is an apparent increase in the amount of extracellular matrix, especially in the region just below the basement membrane.     

Mesenchyme-dependent BMP signaling directs the timing of mandibular osteogenesis

To identify molecular and cellular mechanisms that determine when bone forms, and to elucidate the role played by osteogenic mesenchyme, we employed an avian chimeric system that draws upon the divergent embryonic maturation rates of quail and duck. Pre-migratory neural crest mesenchyme destined to form bone in the mandible was transplanted from quail to duck. In resulting chimeras, quail donor mesenchyme established significantly faster molecular and histological programs for osteogenesis within the relatively slower-progressing duck host environment. To understand this phenotype, we assayed for changes in the timing of epithelial-mesenchymal interactions required for bone formation and found that such interactions were accelerated in chimeras. In situ hybridization analyses uncovered donor-dependent changes in the spatiotemporal expression of genes, including the osteo-inductive growth factor Bmp4. Mesenchymal expression of Bmp4 correlated with an ability of quail donor cells to form bone precociously without duck host epithelium, and also relied upon epithelial interactions until mesenchyme could form bone independently. Treating control mandibles with exogenous BMP4 recapitulated the capacity of chimeras to express molecular mediators of osteogenesis prematurely and led to the early differentiation of bone. Inhibiting BMP signaling delayed bone formation in a stage-dependent manner that was accelerated in chimeras. Thus, mandibular mesenchyme dictates when bone forms by temporally regulating its interactions with epithelium and its own expression of Bmp4. Our findings offer a developmental mechanism to explain how neural crest-derived mesenchyme and BMP signaling underlie the evolution of species-specific skeletal morphology.     

Thinning of the basement Membrane and Localized Cell Proliferation during Gland Formation of the Chick Proventriculus

The early processes of proventricular gland formation in the chick embryo were investigated. The glands appeared as intra-epithelial invaginations of the proventricular endoderm on day 6 of incubation. By day 6.5 they began to protrude into the mesenchyme and elongated without branching until day 9. Before elongation of the glands, the immunofluorescence of laminin and the ultrastructure of the basal lamina were consistently observed in the intra-epithelial invaginations as well as in other regions, and the mitotic activity in the gland rudiments was not different from that in other regions. However, at the tips of the elongating glands, little laminin was detected and the basal lamina were thin and discontinuous. The mitotic activity at the tip of the glands was higher than that in non-glandular epithelium or in the stalk of the glands. These results suggest causal relationships between thinning of the basement membrane and localized epithelial cell proliferation at the tip of the elongating glands.     

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.     

Death is the major fate of medial edge epithelial cells and the cause of basal lamina degradation during palatogenesis

During mammalian development, a pair of shelves fuses to form the secondary palate, a process that requires the adhesion of the medial edge epithelial tissue (MEE) of each shelf and the degeneration of the resulting medial epithelial seam (MES). It has been reported that epithelial-mesenchymal transformation (EMT) occurs during shelf fusion and is considered a fundamental process for MES degeneration. We recently found that cell death is a necessary process for shelf fusion. These findings uncovered the relevance of cell death in MES degeneration; however, they do not discard the participation of other processes. In the present work, we focus on the evaluation of the processes that could contribute to palate shelf fusion. We tested EMT by traditional labeling of MEE cells with a dye, by infection of MEE with an adenovirus carrying the lacZ gene, and by fusing wild-type shelves with the ones from EGFP-expressing mouse embryos. Fate of MEE labeled cells was followed by culturing whole palates, or by a novel slice culture system that allows individual cells to be followed during the fusion process. Very few labeled cells were found in the mesenchyme compartment, and almost all were undergoing cell death. Inhibition of metalloproteinases prevented basal lamina degradation without affecting MES degeneration and MEE cell death. Remarkably, independently of shelf fusion, activation of cell death promoted the degradation of the basal lamina underlying the MEE ('cataptosis'). Finally, by specific labeling of periderm cells (i.e. the superficial cells that cover the basal epithelium), we observed that epithelial triangles at oral and nasal ends of the epithelial seam do not appear to result from MEE cell migration but rather from periderm cell migration. Inhibition of migration or removal of these periderm cells suggests that they have a transient function controlling MEE cell adhesion and survival, and ultimately die within the epithelial triangles. We conclude that MES degeneration occurs almost uniquely by cell death, and for the first time we show that this process can activate basal lamina degradation during a developmental process.     

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.     

Molecular and morphologic changes during the epithelial-mesenchymal transformation of palatal shelf medial edge epithelium in vitro.

The fate of the medial edge epithelial (MEE) cells during palatal fusion has been proposed to be either programmed cell death or epithelial-mesenchymal transformation. Vital cell labeling techniques were used to mark the MEE and observe their fate during palatal fusion in vitro. Fetal mouse palatal shelves were labeled with Dil and allowed to proceed through fusion while maintained in an organ culture system. The tissues were examined at several stages of palatal fusion for the distribution of Dil, presence of specific antigens and ultrastructural appearance of the cells. The MEE labeled with Dil occupied a midline position at all stages of palatal fusion. Initially the cells had keratin intermediate filaments and were separated from the underlying mesenchyme by an intact basement membrane. During the process of fusion the basement membrane was degraded and the Dil-labeled MEE were in contact with the mesenchymal-derived extracellular matrix. In the late stages of fusion the Dil-labeled MEE altered their cellular morphology, had vimentin intermediate filaments, and were not associated with an identifiable basement membrane. Dil-labeled cells, without an epithelial phenotype, remained present in the midline of the completely fused palate. The data indicate that the MEE did not die but underwent a phenotypic transformation to viable mesenchymal cell types, which were retained in the palatal mesenchyme.