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.     

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.     

Localization of putative stem cells in dental epithelium and their association with Notch and FGF signaling.

The continuously growing mouse incisor is an excellent model to analyze the mechanisms for stem cell lineage. We designed an organ culture method for the apical end of the incisor and analyzed the epithelial cell lineage by 5-bromo-2'-deoxyuridine and DiI labeling. Our results indicate that stem cells reside in the cervical loop epithelium consisting of a central core of stellate reticulum cells surrounded by a layer of basal epithelial cells, and that they give rise to transit-amplifying progeny differentiating into enamel forming ameloblasts. We identified slowly dividing cells among the Notch1-expressing stellate reticulum cells in specific locations near the basal epithelial cells expressing lunatic fringe, a secretory molecule modulating Notch signaling. It is known from tissue recombination studies that in the mouse incisor the mesenchyme regulates the continuous growth of epithelium. Expression of Fgf-3 and Fgf-10 were restricted to the mesenchyme underlying the basal epithelial cells and the transit-amplifying cells expressing their receptors Fgfr1b and Fgfr2b. When FGF-10 protein was applied with beads on the cultured cervical loop epithelium it stimulated cell proliferation as well as expression of lunatic fringe. We present a model in which FGF signaling from the mesenchyme regulates the Notch pathway in dental epithelial stem cells via stimulation of lunatic fringe expression and, thereby, has a central role in coupling the mitogenesis and fate decision of stem cells.     

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.     

Lymphocyte number and distribution in the rat uterine epithelium during estrous cycle and early pregnancy

Summary The number of intraepithelial lymphocytes (IEL) in the luminal and glandular epithelium of the uterus of virgin rats was analysed in diestrus, proestrus and estrus, and in nulliparous rats on days 5, 7 and 9 of pregnancy. IEL number was calculated either with respect to the number of epithelial cells or to the length of epithelium section. It was found that in diestrus, the number of IEL was, on average, 3.7 per 100 luminal epithelial cells or 6.7 per 1 mm of epithelium section, whereas in proestrus, it decreased to 0.9 and 1.2 IEL, respectively. On day 5 of pregnancy (before implantation) the number of IEL decreased further to 0.45 per 100 luminal epithelial cells or 0.9 per 1 mm of epithelium. On days 7 and 9 of pregnancy, IEL number further decreased in implantation sites, whereas in interimplantation sites it remained at the level calculated for day 5 of pregnancy. The population of uterine IEL consisted of small (82–99%) and large (1–18%) lymphocytes. In all stages of the estrous cycle, IEL occurred with a frequency of 68–87% in the basal region, 8–20% in the middle region and 4–12% in the apical region of the luminal epithelium width.     

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.     

Histogenesis of Swiss white mouse secondary palate from nine and one-half days to fifteen and one-half days In utero. I. Epithelial-mesenchymal relationships—light and electron microscopy

Development of the secondary palate in Swiss white mouse embroyos was studied from age nine-and-one-half days in utero to the stage of mesenchymal coalescence in the secondary palate (approximately fifteen-and-one-half days). The greatest changes observed occur in the mesenchyme. At early stages, mesenchymal cells underlying oral ectoderm of the head are few and only occasionally contact the ectoderm. Electron micrographs show large intercellular spaces between the ectodermal cells. As embryogenesis continues, the mesenchymal cells become more numerous, closer to each other and closer to the epithelium. Just prior to horizontal transposition of shelves, the mesenchymal cells spread farther from each other and from the palatal epithelium and epithelium of the palatal tip becomes stretched. Ultrastructurally the intercellular spaces between epithelial cells of the palate tip have become much smaller. Some mitochondria in some epithelial cells are swollen and have clear matrices and distorted cristae. The shelves become horizontal and meet in the midpalate. Cells with degeneration bodies are seen in the epithelial seam. The seam undergoes autolysis and is replaced by mesenchyme. The morphological changes described, particularly in the mesenchyme, may play an important role in determining the effect of various teratogens at different stages of palatal development. The changes in both mesenchyme and epithelial cells in the later stages may constitute part of the process of preparing shelves for fusion as postulated by Pourtois ('66).     

The spread of herpes simplex virus type 1 from trigeminal neurons to the murine cornea: an immunoelectron microscopy study

An animal model has been developed to clarify the mechanism for spread of herpes simplex virus (HSV) from neuron to epithelial cells in herpetic epithelial keratitis. HSV was introduced into the murine trigeminal ganglion via stereotaxic guided injection. After 2 to 5 days, the animals were euthanized. Ganglia and corneas were prepared for light and electron microscopic immunocytochemistry with antisera to HSV. At 2 days, labeled axons were identified in the stromal layer. At 3 days, we could detect immunoreactive profiles of trigeminal ganglion cell axons that contained many vesicular structures. By 3 and 4 days, the infection had spread to all layers of epithelium, and the center of a region of infected epithelium appeared thinned. At 5 day, fewer basal cells appeared infected, although infection persisted in superficial cells where it had expanded laterally. Mature HSV was found in the extracellular space surrounding wing and squamous cells. Viral antigen was expressed in small pits along the apical surfaces of wing and squamous cells but not at the basal surface of these cells or on basal cells. This polarized expression of viral antigen resulted in the spread of HSV to superficial cells and limited lateral spread to neighboring basal cells. The pathogenesis of HSV infection in these mice may serve as a model of the human recurrent epithelial disease in the progression of focal sites of infection and transfer from basal to superficial cells.     

Epithelial cytodifferentiation and extracellular matrix formation in enamel-free areas of the occlusal cusp during development of mouse molars: light and electron microscopic studies

Mandibular first molars in mice ranging in age from 18 days prenatal to 5 days postnatal were used for light and electron microscopic examinations of the enamel-free area (EFA) during development of the occlusal cusp (mesiobuccal cusp). Notable morphological changes in the inner enamel epithelium and the cells of the stratum intermedium were observed. At prenatal age of 18 days, the inner enamel epithelium of the EFA (EFA epithelium) was composed of a layer of columnar cells and covered by the cells of the stratum intermedium. Two days after birth, the EFA epithelium was made up largely of preameloblasts, with mitochondria located in the proximal side of the cells toward the stratum intermedium. The cells of the stratum intermedium were irregularly shaped, with wide intercellular spaces between them. At a postnatal age of 3 days, most of the EFA epithelial cells resembled maturation-stage ameloblasts, being short and columnar in shape and having nuclei located in their proximal side. Distal cell membranes were folded, and mitochondria were scattered throughout the cytoplasm. In 4-day-old mice, the EFA epithelium was found to be formed of short columnar or cuboidal cells with distinct intercellular spaces. The cells of the stratum intermedium could no longer be detected, and cells of the EFA epithelium could not be distinguished from those of the stellate reticulum. Odontoblasts of the EFA were arranged and polarized parallel to the basal lamina, and odontoblastic processes extended toward the cusp tip. The orientation of thin and thick collagen fibers within predentin and dentin was also parallel to the basal lamina. Even after dentin mineralization, disrupted basal lamina and long, aperiodic, fine fibrils were found between the epithelium and the dentin. Following the disappearance of the basal lamina and fine fibrils, stippled material and crystals appeared on the dentin surface. The mineralized matrix, which x-ray microanalytical energy peaks identified as containing calcium and phosphorus, was continuous with enamel in the distal slope of the cusp at the cusp tip. Thus, the inner enamel epithelium of the EFA differentiated into secretory cells capable of enamel-like matrix formation.(ABSTRACT TRUNCATED AT 400 WORDS)     

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.     

The development of the guinea pig gallbladder epithelial cells. I. Light microscopical and carbohydrate-histochemical investigations (author's transl)]

The development of the guinea pig gallbladder epithelium was studied from the 19th day of intrauterine life to the 31st postnatal day by means of histological and histochemical staining reactions. At first, the epithelium is a columnar pseudostratified one. Its transformation into a simple columnar eptihelium is terminated by the 31st day of the intrauterine life. Then the epithelial cells become more columnar and their nuclei acquire a basal position. Somewhat later the epithelium invaginates the underlying mesenchyme. Up to the 57th day the epithelium contains much glycogen. Neutral and carboxylated mucosubstances are demonstrable after the 30th day. From the 48th day onwards sulphated mucosubstances can be visualized in some cells in the depth of the invaginations and from the 51st day in the epithelial cells of the gallbladder. "Light" mucoid cells appear first in the epithelium of day 58. After the 6th postnatal day the "light" cells are rarely seen in the invaginations. The development of the gallbladder epithelium is completed about the 10th postnatal day. The epithelial mucosubstances of the gallbladder of the adult animal could be classified as GC- mucins and S-mucinsA, 1.0 MgCl2.     

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.     

STRUCTURAL FEATURES OF THE EPITHELIO-MESENCHYMAL INTERFACE OF RAT DUODENAL MUCOSA DURING DEVELOPMENT

In fetal rats 5–7 days before birth, the duodenal epithelium is separated from mesenchymal cells by a well-defined basal lamina. By 3–4 days before birth, when small rudimentary villi are first seen, direct contact between epithelial and mesenchymal cells occurs by means of epithelial cell cytoplasmic processes which project through gaps in the basal lamina into the lamina propria. At contact sites, the epithelial and mesenchymal cell plasma membranes were less than 100 A apart but membrane fusion was not seen. In number and size these epithelial cell processes increase strikingly during the last 2 days of gestation, and they persist in large numbers until 7–10 days after birth. Thereafter, they decrease gradually in both number and size until 3–4 wk after birth, when the morphology of the epithelio-mesenchymal interface resembles that seen in adult rats, i.e., there are only rare epithelial cell processes which penetrate deeply into the lamina propria. The presence of a large number of epithelio-mesenchymal contact sites during the period of rapid growth and differentiation of duodenal mucosa may reflect epithelio-mesenchymal cell interactions which may facilitate the maturation of the duodenal mucosa.     

Early Development of Mouse Anterior Pituitary: Role of Mesenchyme

Epithelial-mesenchymal interaction in the early development of the anterior pituitary gland was examined by chronological observations on fetal pituitary epithelium grafted in vivo with and without its own mesenchyme. At 8.5 days of gestation, the RATHKE'S pouch began to evaginate toward the diencephalon. The mesenchymal tissue around the pouch was at first very sparsely scattered, but then condensed, on day 10 becoming visible under a dissecting microscope. When RATHKE'S pouch epithelia from 10- and 12-day fetuses were transplanted alone under the kidney capsule, they proliferated slightly to form cysts, the cells of which differentiated into ACTH-producing cells, but not into prolactin-producing cells. Pituitary morphogenesis did not occur. When these epithelia were recombined with homotypic mesenchyme and transplanted, the epithelia proliferated remarkably on one side of the wall of the pouch, resulting in formation of a pars distalis that contained both ACTH-producing cells and prolactin-producing cells. Heterotypic mesenchyme, such as lung, dermis and mammary gland mesenchyme, could induce 12-day epithelium, but not 10-day epithelium to develop into pars distalis. Thus, fetal pituitary epithelium has the capacity of autodifferentiation into ACTH-producing cells, not into prolactin-producing cells, and requires mesenchymal support for development of the pars distalis.     

兔机械性角膜上皮损伤后伤口愈合的形态学动态变化

目的观察兔机械性角膜上皮损伤后伤口愈合的形态学动态变化。方法选取新西兰大白兔12只,随机分为A、B两组,均建立机械性角膜上皮损伤模型（刮除直径为8mm的角膜中央上皮）,术后给予盐酸林可霉素滴眼液滴眼,3次/日,1滴/次。A组在建模后第0、1、4、7天共4个时间点采用前节裂隙灯照相系统进行眼表照相,并计算损伤面积。B组在建模后第1、4、7天,按随机数字表法取2只兔的实验眼角膜,行透射电镜及病理检查。结果前节裂隙灯照相系统记录了不同观察时间点损伤范围（伤口愈合面积）的动态变化。造模后第1天,角膜上皮全层缺如,损伤边缘处上皮细胞胞膜向损伤区内伸出褶皱的伪足;造模后第4天,上皮自周边向缺损区域爬行生长,覆盖整个角膜,可见2～3层细胞,主要为基底细胞和多角细胞,细胞连接松驰;造模后第7天,再生上皮分化较完全,约5～6层细胞,极向齐,连接较紧密,可见均匀分布的半桥粒结构。结论兔机械性角膜上皮损伤后伤口愈合的动态形态学变化包括上皮细胞向心性移行、增殖,以及随后的分化,连接。     

Transformed growth phenotype of mouse mammary epithelium in primary culture induced by specific fetal mesenchymes.

When mesenchyme from fetal mammary or salivary gland is implanted into adult mouse mammary gland, adjacent epithelium responds with intense hyperplasia. The hyperplastic cells are more vulnerable than are non-stimulated cells to transformation in vivo by a chemical carcinogen or by mammary tumor virus. This system provides a potentially useful model for determining how stroma contributes to mammary tumorigenesis. We have developed co-culture systems and used them to investigate in more detail the nature of the signal produced by the mesenchyme cells. Monolayers of mesenchyme cells were prepared on tissue-culture wells. The mesenchyme cells were trapped on the surface by a thin overlay of agarose. Primary mammary epithelial cells were cultured atop this barrier layer, either as organoids in collagen gels for assessment of anchorage-dependent growth, or as single-cell dispersions in soft agarose for assessment of anchorage-independent growth. Our procedures for assay of anchorage-independent growth allow us for the first time to detect and measure this transformation-defining characteristic in non-immortalized mammary epithelial cells in primary culture. Fetal mammary fat pad precursor tissue and fetal salivary mesenchyme both stimulated anchorage-dependent growth of mammary epithelium, with cell number increasing as much as fifteenfold during a 6-day culture period. These same fetal tissues also stimulated anchorage-independent growth of the mammary epithelial cells, with colony-forming efficiencies of up to 40% in co-cultures with salivary mesenchyme. No colonies formed in the absence of mesenchyme. Cells of colonies contained keratin, which indicates that the colonies grew from epithelial cells and not from a contaminant of another cell type. When co-cultured epithelial cells were subsequently re-cultured in the absence of mesenchyme, they lost their ability to grow independent of anchorage. No colonies grew in co-cultures with fetal cells from heart, kidney, or lung, which is consistent with the lack of stimulation by these tissues in the mammary gland in vivo. A tumor promoter, 12-O-tetradecanoylphorbol acetate (TPA), also caused anchorage-independent growth of the dispersed mammary epithelial cells. Culture medium conditioned by primary or early-passage salivary mesenchyme cells was capable of stimulating growth under both anchorage-dependent and anchorage-independent conditions, confirming that these effects are mediated by a paracrine factor. The results indicate that stimulatory fetal mesenchymes produce soluble molecules that act analogously to transforming growth factors.     

Gizzard epithelium of chick embryos can express embryonic pepsinogen antigen,a marker protein of proventriculus

Summary The avian stomach is composed of two distinct organs, the proventriculus and the gizzard. Pepsinogen expression in the proventricular and gizzard epithelia of chick embryos was investigated immunohistochemically with anti-embryonic chick pepsinogen (anti-ECPg) antiserum. In normal development, the ECPg antigen was expressed only in the glandular epithelial cells of the embryonic proventriculus from the 8th day of incubation onwards. However, both proventricular and gizzard epithelia of 6-day embryos expressed the ECPg antigen when recombined and cultured with the proventricular mesenchyme. Chronological studies revealed that the ECPg antigen was first detected in a few epithelial cells at 3 days of cultivation. The percentage of ECPg-positive cells among the total epithelial cells in each recombinant increased with the length of the culture period and all the glandular epithelial cells were positive at 9 days. During this process, the percentage of ECPg-positive cells in each cultured recombinant was similar in proventricular and gizzard epithelia. Moreover, both epithelia could express the ECPg antigen when recombined and cultured with the oesophageal or small-intestine mesenchyme for 9 days, though the percentage of ECPg-positive cells in each cultured recombinant was much lower than that in the cultured recombinant with the proventricular mesenchyme. These results indicate that the gizzard epithelium of 6-day chick embryos possesses a similar potential for pepsinogen expression as the proventricular epithelium of the same age.     

Persistence of responsiveness of adult mouse mammary gland to induction by embryonic mesenchyme

Persistence of the capacity for embryogenic morphogenesis in adult mammary epithelium was demonstrated by allowing it to interact with grafted embryonic mesenchyme in vivo. When 14-day embryonic mammary or salivary mesenchyme was transplanted in the mammary gland of syngeneic young adult virgin mice, organogenetic development of the mammary epithelial cells occurred responding to closely attached mesenchyme. An early change, within 2–4 days, that was observed equally in both types of the mesenchymes was proliferation of mammary epithelial cells in multiple layers resembling rudimental architecture. Subsequently, ductal branching occurred from the rudimental architecture by mesenchyme-dependent branching pattern, of mammary gland type with mammary mesenchyme and of salivary gland-like type with salivary mesenchyme. This developmental response did not require hormones secreted from ovaries since it was observed similarly in ovariectomized mice. The mammary epithelium at the lactating stage did not show such a potential to the transplanted salivary mesenchyme.     

Epithelial-mesenchymal transformation during palatal fusion: carboxyfluorescein traces cells at light and electron microscopic levels.

During the fusion of rodent embryo palatal shelves, the cells of the outer epithelial layer slough off, allowing the cells of the medial edge basal layer to form a midline seam that undergoes epithelial-mesenchymal transformation, as judged by electron microscopy and immunohistochemistry. In this study, we analyze the fate of the transformed cells using a lipid soluble dye to label the medial edge epithelium in situ. Prefusion E14 mouse palates were exposed in vitro or in vivo to a fluoresceinated lipid soluble marker, carboxydichlorofluorescein diacetate succinimidyl ester (CCFSE), which localizes in epithelia as a lipid insoluble compound that does not pass into the connective tissue compartment. The midline seam that formed after 24 hours contained labelled epithelial cells that were replaced by individually labelled mesenchymal cells where the seam transformed. By light microscopy, the labelled cells were seen to contain intensely fluorescent bodies that do not react for acid phosphatase. We were able for the first time to identify these structures by electron microscopy as CCFSE isolation bodies. The cells with isolation bodies are clearly healthy and able to participate in subsequent development of the palate. At 4 days after labelling, individual CCFSE containing cells present in the palate mesenchyme occupy both midline and lateral areas and can clearly be classified as fibroblasts by electron microscopy. CCFSE is a far more useful marker than another lipid soluble marker, DiI, for following cells, because the cells can be fixed and identified both at the light and electron microscope levels. Interestingly, if labelled palatal shelves are not allowed to fuse in vitro, the basal epithelial cells do not form mesenchyme after sloughing, indicating that formation of the epithelial midline seam is necessary to trigger its epithelial-mesenchymal transformation.