Outer root sheath (ORS) cells organize into epidermoid cyst-like spheroids when cultured inside Matrigel: a light-microscopic and immunohistological comparison between human ORS cells and interfollicular keratinocytes

In organotypic cultures, outer root sheath (ORS) cells of the human hair follicle develop into a stratified epithelium largely reminiscent of the epidermis; this apparently reflects their importance during wound healing. In the present study, ORS cells were grown inside a three-dimensional network of extracellular matrix proteins (Matrigel), together with different mesenchymal cells, in an attempt to mimic their follicular environment. Thus, inside Matrigel, ORS cells formed spheroids differentiating toward the center and showing all the markers of epidermal keratinization. Under identical conditions, normal epidermal keratinocytes developed similar spheroids, but of a significantly smaller size. Human dermal fibroblasts and dermal papilla cells, cocultured in the matrix, had a positive influence on both the proliferation and differentiation within both types of spheroids. Epidermal differentiation markers, such as suprabasal keratins, involucrin, filaggrin, gp80 and pemphigoid antigen, were readily expressed in ORS spheroids, whereas hard (hair) keratins were not detectable by immunostaining. Cells positive for an epithelial membrane antigen, strongly expressed in sebaceous glands, were seen in numerous spheroids. In contrast to organotypic “surface” epithelia, the expression and location of different integrin chains was normalized in ORS spheroids, indicating an enhanced mesenchymal influence in this in vitro system.     

Epithelial-mesenchymal interactions control basement membrane production and differentiation in cultured and transplanted mouse keratinocytes

Summary The effects of mesenchyme and substratum on epidermal differentiation and formation of a basement membrane (BM) were analyzed in vitro and in vivo. Primary epidermal cell cultures (PEC) from neonatal mice were grown: (1) on plastic culture dishes; (2) on lifted collagen gels, either alone or (3) in recombination with mesenchyme; (4) after reimplantation in vivo either directly on mesenchyme or (5) on collagen interposed between keratinocytes and mesenchyme. Differentiation of the epithelium and formation of a BM were examined by electron microscopy, and expression of BM constituents (type IV collagen, laminin, fibronectin, bullous pemphigoid antigen, and heparan sulfate proteoglycan) by indirect immunofluorescence. PEC on plastic or on collagen gels showed poor differentiation, a structured BM was not visible, and the expression and deposition of BM constituents was incomplete. Upon reimplantation in vivo, differentiation was normalized, expression of BM components complete and a structured BM reformed. This effect does not depend on immediate contact of epidermal cells with mesenchyme. When PEC on collagen gel were similarly associated with dermal mesenchyme in vitro, epidermal differentiation and expression of BM components were almost normalized, but a structured BM was absent. These findings demonstrate that formation of the BM in epidermis is a function of keratinocytes and, like differentiation is subject to mesenchymal control. A structural BM is not a prerequisite but rather an additional criterion of normal epidermal differentiation. Send offprint requests to: Norbert E. Fusenig, M.D., Division of Differentiation and Carcinogenesis in vitro, Institute of Biochemistry, German Cancer Research Center (DKFZ), Im Neuenheimer Feld 280, D-6900 Heidelberg, Federal Republic of GermanyPart of the work was performed when I.C. Mackenzie was guest scientist at the DKFZSupported by the Deutsche Forschungsgemeinschaft (Fu 91/2)     

Outer root sheath (ORS) cells organize into epidermoid cyst-like spheroids when cultured inside Matrigel: a light-microscopic and immunohistological comparison between human ORS cells and interfollicular keratinocytes

In organotypic cultures, outer root sheath (ORS) cells of the human hair follicle develop into a stratified epithelium largely reminiscent of the epidermis; this apparently reflects their importance during wound healing. In the present study, ORS cells were grown inside a three-dimensional network of extracellular matrix proteins (Matrigel), together with different mesenchymal cells, in an attempt to mimic their follicular environment. Thus, inside Matrigel, ORS cells formed spheroids differentiating toward the center and showing all the markers of epidermal keratinization. Under identical conditions, normal epidermal keratinocytes developed similar spheroids, but of a significantly smaller size. Human dermal fibroblasts and dermal papilla cells, cocultured in the matrix, had a positive influence on both the proliferation and differentiation within both types of spheroids. Epidermal differentiation markers, such as suprabasal keratins, involucrin, filaggrin, gp80 and pemphigoid antigen, were readily expressed in ORS spheroids, whereas hard (hair) keratins were not detectable by immunostaining. Cells positive for an epithelial membrane antigen, strongly expressed in sebaceous glands, were seen in numerous spheroids. In contrast to organotypic surface epithelia, the expression and location of different integrin chains was normalized in ORS spheroids, indicating an enhanced mesenchymal influence in this in vitro system.     

Morphological appearance of epidermal cells cultured on fibroblast-reorganized collagen gels

Summary Human foreskin fibroblasts were used to reorganize hydrated collagen gels into a dermal-like matrix, after which freshly isolated keratinocytes isolated from rabbit ear skin were placed on the surfaces of the matrices and cultured for up to 12 days. Transmission electron microscopy revealed 8–12 cell layers of epidermal cells organized in three distinct strata. The basal stratum consisted of cuboidal to columnar cells with typical complement of organelles, oval nuclei, and prominent tonofilaments inserting into desmosomes. Mitotic cells often were found at this level. There was no well-defined basement membrane region; rather, many of the cells appeared to be in close contact with collagen fibrils. The intermediate stratum of suprabasal cells consisted of elongated cells that had reduced organelles, but still were connected to each other by desmosomes. Finally, the superficial stratum of suprabasal cells contained cells that were completely flattened and often appeared to be sloughing off the apical surfaces of the cultures. Indirect immunofluorescence studies carried out on frozen sections revealed bullous pemphigoid antigen associated with basal epidermal cells; pemphigus vulgaris antigen around the epidermal cells of all strata, and keratin present in the epidermal cells of all strata. Filaggrin was observed in punctate and fibrillar arrangements in suprabasal cells. Fibronectin was found in a linear deposit at the dermal-epidermal junction and around the fibroblasts in the reorganized collagen gels. Type-IV collagen and laminin, however, were not detected.     

Mucin synthesis and secretion by cultured tracheal cells: effects of collagen gel substratum thickness

Summary We previously demonstrated that human tracheobronchial epithelial (TBE) cells synthesize mucin and form mucous granules in culture when they are maintained on a collagen gel (CG) substratum, but not on a plastic tissue culture surface or a thin collagen-coated surface (Wu et al., Am. J. Respir. Cell Mol. Biol., 3:467–478; 1990). This observation led us to examine the effects of CG thickness on cell growth and differentiation in primary human/monkey TBE cell cultures. Using the same CG preparation, culture dishes with different thicknesses of CG substratum were prepared. In general, equivalent degrees of cell attachment and proliferation were observed in all cultures maintained on a collagen gel, independent of the thicknesses of CG substratum. However, a greater degree of mucin synthesis and secretion by the cells was observed as the thickness of the CG substratum was increased. Cultures maintained on a thick collagen gel (1 mm) exhibited greater apical membrane complexity, more pseudostratification, and more mucous granules than did cultures maintained on a thin CG substratum. The optimal culture surface for airway mucous cell differentiation contains more than 1-mm thickness of collagen gel substratum.     

A novel artificial substrate for cell culture: Effects of substrate flexibility/malleability on cell growth and morphology

Summary Gels of glyoxyl agarose (GA) are evaluated as a novel flexible substrate for cell culture with physical properties comparable to extracellular matrix (ECM) gels. We show here that cells adhere well to pure GA gels; in addition, specific interactions involving matrix receptors can be studied when individual matrix molecules are bound to the gel covalently. When cells are grown on such substrates, morphology is comparable to that observed on “natural” matrix gels (reconstituted gels of collagen type I or of Matrigel): rather than being flattened as in monolayer cultures on tissue culture plastic the cells assume a rounded morphology and tend to form tissue-like aggregates. The effects of the artificial matrix gels are discussed in the context of previous publications on cell interactions with the extracellular matrix, suggesting that in addition to specific recognition of matrix molecules the physical properties of ECM by themselves can be decisive for cell differentiation. We conclude that gels of glycoxyl agarose a) provide a useful model to mimic the physical properties of matrix gels without the presence of specific adhesion factors; b) may be useful as a general, non-specific ECM allowing cells to be cultured in vitro under conditions favorable for differentiation; and c) allow to design a variety of “synthetic” ECM models composed of a chemically defined gel matrix, which can be supplemented with covalently bound molecules to be recognized by cell surface receptors.     

Evidence for a role of the monoclonal antibody E48 defined antigen in cell-cell adhesion in squamous epithelia and head and neck squamous cell carcinoma

Monoclonal antibody (MAb) E48 recognizes a 20- to 22-kDa antigen expressed by human squamous and transitional epithelia and their neoplastic counterparts. Histochemical examination of these tissues revealed distinct surface labeling with MAb E48. To investigate the subcellular localization of the E48 antigen we have performed electron microscopical analysis. In cells of normal oral mucosa, the E48 antigen was expressed on the plasmalemma, particularly associated with desmosomes, suggesting involvement of the E48 antigen in intercellular adhesion. Furthermore, the level of expression of the E48 antigen appeared to be influenced by the cellular organization. In squamous cell carcinoma (SCC) cell lines grown in vitro as subconfluent monolayer cultures, the E48 antigen expression was low. However, E48 antigen expression increased when SCC cells were grown to confluency. E48 antigen expression was similarly high when SCC cell lines were cultured under conditions promoting three-dimensional growth either as colonies within floating collagen gels or as xenograft in tumor-bearing nude mice. Further evidence for the involvement of the E48 antigen in cell-cell adhesion was found when SCC cells were grown within collagen gels in the presence of MAb E48: no spherical colonies were formed, but cells grew out to colonies composed of single cells. Moreover, in this culture system the percentage of SCC cells growing out to colonies was decreased by the presence of MAb E48. These findings indicate that the E48 antigen is involved in the structural organization of squamous tissue and might have a role in intercellular adhesion.     

Epidermal growth factor and transforming growth factor alpha regulate extracellular matrix production by embryonic mouse palatal mesenchymal cells cultured on a variety of substrata

Mouse embryonic palatal mesenchymal (MEPM) cells were cultured either on plastic tissue culture dishes or on the surface of three-dimensional collagen gels or within collagen gel matrices in DMEM/F12 medium containing 2.5% donor calf serum. MEPM cells proliferated exponentially when cultured on collagen or on plastic. Cells cultured within collagen gels did not proliferate but remained viable. Addition of 10 ng/ml epidermal growth factor (EGF) or transforming growth factor alpha (TGF) stimulated the proliferation of those cells cultured on plastic or on collagen but not those cultured within collagen gels. Immunocytochemical analysis revealed that MEPM cells synthesise collagen types I, III, IV, V, VI and IX; fibronectin, heparan sulphate proteoglycan, laminin and tenascin in vitro. These molecules are all present in the developing palate in vivo. EGF and TGF produced a generalised stimulation of extracellular matrix (ECM) synthesis by MEPM cells in vitro. Biochemical analysis indicated that cells cultured within collagen gels had the highest intrinsic rate of protein synthesis. On all substrata neither EGF nor TGF markedly altered the types of ECM molecules synthesised but rather caused a general increase in the total amount produced. This stimulation was most marked where the cells were cultured within collagen gels. The lack of stimulation of proliferation of MEPM cells cultured within collagen gels (i.e. in a physiologically-relevant environment) by EGF or TGF together with the marked stimulation of ECM synthesis suggests that these factors may act as differentiation signals via their effects on ECM production. Correspondence to: M.J. Dixon     

The influence of type I collagen on the growth and differentiation of the human colonic adenocarcinoma cell line HT-29 in vitro

HT-29 Human colonic adenocarcinoma cells when grown on a plastic substratum were anaplastic in appearance and failed to express any morphological or biochemical features that were characteristic of intestinal differentiation. Growth of HT-29 cells subcutaneously in the flank of immune deprived mice gave rise to morphologically heterogeneous tumors which were poorly differentiated but contained approximately 11% of cells with an intestinal phenotype: these showed features typical of cell polarization with well-developed microvilli, tight junctional complexes and desmosomes between adjacent cells. The transfer of cells from plastic onto either a fixed (designated 'non-released') or floating (designated 'released') type I collagen gel induced some morphological features typical of intestinal differentiation; for example goblet-like cells were observed after 9 days, but biochemical markers of differentiation were expressed only modestly. The continued subculture of HT-29 cells on collagen type I gels, which were either attached to the plastic or floating in the medium, induced some morphological features of intestinal differentiation and changes in the activity of brush border-associated enzymes. Alkaline phosphatase activity was enhanced from 1.3 x 10(-3) mumoles/mg/min for cells cultured on plastic substrata to 2.1 x 10(-3) mumoles/mg/min when gels were non-released, and 2.9 x 10(-3) mumoles/mg/min when gels were released after 12 days of culture. This was confirmed by electron microscopical visualization of alkaline phosphatase activity. Elevated levels of aminopeptidase activity were also observed on day 12 (plastic = 26 milliunits/mg; non-released gel = 41 milliunits/mg; released gel = 36 milliunits/mg). Similarly, changes occurred in the secretion of carcinoembryonic antigen from 0.96 x 10(-2) micrograms/mg/48 hours by cells cultured on plastic to 2.3 x 10(-2) micrograms/mg/48 hours by cells cultured on floating collagen gels. The effects of permitting HT-29 cells to undergo polarization were tested by culture on inert filter inserts: morphological features of intestinal differentiation were observed although this did not occur until after 21 days. These studies show that optimization of the growth conditions of anaplastic cells in vitro may provide cultures more representative of the tumor in vivo. This model system may be useful for cell biological and pharmacological studies of colon carcinoma.     

Characterization of human mammary cell types in primary culture: Immunofluorescent and immunocytochemical indicators of cellular heterogeneity

Summary Parenchymal organoidal structures that were obtained from collagenase digestion of reduction mammoplasty specimens of apparently normal human breasts have been grown in short-term primary cultures, either on plastic or on floating gels of polymerized rat-tail collagen. Three morphologically distinct major cell types are readily observed in both systems: cuboidal cells, which occupy apical positions on collagen gels; larger, epithelioid, or basal cells on gels; and elongated cells which penetrate into the gel. In addition, a fourth cell type, that of a large, flat cell, is observed less readily by phase contrast microscopy on the surface of cultures grown on plastic. Immunofluorescent and immunocytochemical staining of cultures on plastic or histologic sections of cultures on gels have been undertaken with antisera and other histochemical reagents that stain the different parenchymal cell types in vivo. Thus antisera to epithelial membrane antigen(s), monoclonal antibodies (MABs) to the defatted mammary milk fat globule membrane, peanut lectin, and keratin MAB LE61, which preferentially stain the epithelial cells of ducts in vivo, also stain the cuboidal/apical cells in vitro. The large, flat cells are stained intensely by the first three reagents but not by the last one. Antisera to collagen IV, laminin, fibronectin, actin, keratin MAB LP34, MABs to the common acute lymphoblastic leukemia antigen, and MAB LICR-LON-23.10, which showed enhanced staining for the ductal myoepithelial cells in vivo, also stain the epithelioid/elongated cells in vitro. However, the effect of the last four reagents is reduced considerably in most elongated cells, and MAB LP34 stains the large, flat cells intensely. Heterogeneous cells of intermediate morphologies and staining patterns between the cuboidal/flat cells and large epithelioid cells have also been identified. The results suggest that the cuboidal cells and large, flat cells are related to mammary epithelial cells, whereas the large epithelioid/elongated cells have some characteristics of myoepithelial cells, and that intermediate forms may exist in culture between the two parenchymal cell types. This work was supported in part by the Ludwig Institute for Cancer Research and the Cancer and Polio Research Fund. Dr. M. J. Warburton is supported by the Cancer Research Campaign.     

NIMA-related kinases 6, 4, and 5 interact with each other to regulate microtubule organization during epidermal cell expansion in Arabidopsis thaliana

NimA-related kinase 6 (NEK6) has been implicated in microtubule regulation to suppress the ectopic outgrowth of epidermal cells; however, its molecular functions remain to be elucidated. Here, we analyze the function of NEK6 and other members of the NEK family with regard to epidermal cell expansion and cortical microtubule organization. The functional NEK6-green fluorescent protein fusion localizes to cortical microtubules, predominantly in particles that exhibit dynamic movement along microtubules. The kinase-dead mutant of NEK6 (ibo1-1) exhibits a disturbance of the cortical microtubule array at the site of ectopic protrusions in epidermal cells. Pharmacological studies with microtubule inhibitors and quantitative analysis of microtubule dynamics indicate excessive stabilization of cortical microtubules in ibo1/nek6 mutants. In addition, NEK6 directly binds to microtubules in vitro and phosphorylates β-tubulin. NEK6 interacts and co-localizes with NEK4 and NEK5 in a transient expression assay. The ibo1-3 mutation markedly reduces the interaction between NEK6 and NEK4 and increases the interaction between NEK6 and NEK5. NEK4 and NEK5 are required for the ibo1/nek6 ectopic outgrowth phenotype in epidermal cells. These results demonstrate that NEK6 homodimerizes and forms heterodimers with NEK4 and NEK5 to regulate cortical microtubule organization possibly through the phosphorylation of β-tubulins.     

Fractionation of functional lymphocytes sensitized to basic encephalitogen on derivatized collagen and gelatin gels.

The lymph node cells of basic encephalitogen (BE)-sensitized guinea pigs were fractionated on derivatized collagen and gelatin gels. The population of cells specifically reactive to this antigen can be isolated from derivatized gelatin gels and retain their viability and functionality as assayed in vitro. The specific binding of BE-sensitized cells to BE-derivatized gels comprised between 1 and 2% of the cells applied per plate. The ratio of sensitized cells bound to non-sensitized cells bound ranged between 4 and 6. The viability and functionality of adherent cells detached from collagen gels after enzymatic degradation were impaired. In contrast, the responses obtained with the adherent cell population released from the gelatin gels, by melting at 37 degrees C, were equal or greater than those of the original unfractionated lymph node cell cultures. Furthermore, it was possible to obtain a nonadherent cell population which was virtually completely depleted of the capacity to respond to the sensitizing antigen.     

Signaling via fibroblast growth factor receptor-1 is dependent on extracellular matrix in capillary endothelial cell differentiation

Differentiation of endothelial cells, i.e., formation of a vessel lumen, is a prerequisite for angiogenesis. The underlying molecular mechanisms are ill defined. We have studied a brain capillary endothelial cell line (IBEC) established from H-2Kb-tsA58 transgenic mice. These cells form hollow tubes in three-dimensional type I collagen gels in response to fibroblast growth factor-2 (FGF-2). Culture of IBEC on collagen gels in the presence of FGF-2 protected cells from apoptosis and allowed tube formation (i.e., differentiation) but not growth of the cells. FGF-induced differentiation, but not cell survival, was inhibited by treatment of the cells with an anti-beta1-integrin IgG. Changes in integrin expression in the collagen-gel cultures could not be detected. Rather, cell-matrix interactions critical for endothelial cell differentiation were created during the culture, as indicated by the gradual increase in tyrosine phosphorylation of focal adhesion kinase in the collagen-gel cultures. Inclusion of laminin in the collagen gels led to FGF-2-independent formation of tube structures, but cells were not protected from apoptosis. These data indicate that FGF receptor-1 signal transduction in this cell model results in cell survival. Through mechanisms dependent on cell-matrix interactions, possibly involving the alpha3beta1-integrin and laminin produced by the collagen-cultured IBE cells, FGF stimulation also leads to differentiation of the cells.     

Depletion of 43-kD growth-associated protein in primary sensory neurons leads to diminished formation and spreading of growth cones

Epithelial-mesenchymal interactions control epidermal growth and differentiation, but little is known about the mechanisms of this interaction. We have examined the effects of human dermal microvascular endothelial cells (DMEC) and fibroblasts on keratinocytes in conventional (feeder layer) and organotypic cocultures (lifted collagen gels) and demonstrated the induction of paracrine growth factor gene expression. Clonal keratinocyte growth was similarly stimulated in cocultures with irradiated DMEC and fibroblasts as feeder cells. This effect is most probably caused by induction of growth factor expression in cocultured dermal cells. Keratinocytes stimulated mRNA levels for KGF and IL-6 in both mesenchymal cell types and GM-CSF in fibroblasts. The feeder effect could not be replaced by conditioned media or addition of isolated growth factors. In organotypic cocultures with keratinocytes growing on collagen gels (repopulated with dermal cells), a virtually normal epidermis was formed within 7 to 10 d. Keratinocyte proliferation was drastically stimulated by dermal cells (histone 3 mRNA expression and BrdU labeling) which continued to proliferate as well in the gel. Expression of all typical differentiation markers was provoked in the reconstituted epithelium, though with different localization as compared to normal epidermis. Keratins K1 and K10 appeared coexpressed but delayed, reflecting conditions in epidermal hyperplasia. Keratin localization and proliferation were normalized under in vivo conditions, i.e., in surface transplants on nude mice. From these data it is concluded that epidermal homeostasis is in part controlled by complex reciprocally induced paracrine acting factors in concert with cell-cell interactions and extracellular matrix influences.     

Proliferation of human embryonic and fetal epidermal cells in organ culture

The morphology of human embryonic and fetal skin growth in organ culture at the air-medium interface was examined, and the labeling indices of the epidermal cells in such cultures were determined. The two-layered epidermis of embryonic specimens increased to five or six cell layers after 21 days in culture, and the periderm in such cultures changed from a flat cell type to one with many blebs. The organelles in the epidermal cells remained unchanged. Fetal epidermis, however, differentiated when grown in this organ culture system from three layers (basal, intermediate, and periderm) to an adult-type epidermis with basal, spinous, granular, and cornified cell layers. Keratohyalin granules, lamellar granules, and bundles of keratin filaments, organelles associated with epidermal cell differentiation, were observed in the suprabasal cells of such cultures. The periderm in these fetal cultures formed blebs early but was sloughed with the stratum corneum in older cultures. The rate of differentiation of the fetal epidermis in organ culture was related to the initial age of the specimen cultured, with the older specimens differentiating at a faster rate than the younger specimens. Labeling indices (LIs) of embryonic and fetal epidermis and periderm were determined. The LI for embryonic basal cells was 8.5% and for periderm was 8%. The fetal LIs were 7% for basal cells, 1% for intermediate cells, and 3% for periderm. The ability to maintain viable pieces of skin in organ culture affords a model for studying normal and abnormal human epidermal differentiation from fetal biopsies and for investigating proliferative diseases.     

Mouse submandibular salivary epithelial cell growth and differentiation in long-term culture: Influence of the extracellular matrix

Summary The adult mouse submandibular salivary gland provides a good model system to study gene regulation during normal and abnormal cell behavior because it synthesizes functionally distinct products ranging from growth factors and digestive enzymes to factors of relevance to homeostatic mechanisms. The present study describes the long-term growth and differentiation of submandibular salivary epithelial cells from adult male mice as a function of the culture substratum. Using a two-step partial dissociation procedure, it was possible to enrich for ductal cells of the granular convoluted tubules, the site of epidermal growth factor synthesis. Long-term cell growth over a period of 2 to 3 mo. with at least 3 serial passages was obtained only within three-dimensional collagen gels. Cells grew as ductal-type structures, many of which generated lumens with time in culture. Electron microscopic analysis in reference to the submandibular gland in vivo revealed enrichment for and maintenance of morphologic features of granular convoluted tubule cells. Reactivity with a keratin-specific monoclonal antibody established the epithelial nature of the cells that grew within collagen. Maintenance of cell differentiation, using immunoreactivity for epidermal growth factor as criterion, was determined by both cytochemical and biochemical approaches and was found to be dependent on the collagen matrix and hormones. Greater than 50% of the cells in primary collagen cultures contained epidermal growth factor only in the presence of testosterone and triiodothyronine. In contrast, cells initially seeded on plastic or cycled to plastic from collagen gels were virtually negative for epidermal growth factor. Biochemical analysis confirmed the presence of a protein with an apparent molecular weight of 6000 which comigrated with purified mouse epidermal growth factor. Epidermal growth factor was also present in detectable levels in Passage 1 cells. This culture system should permit assessment of whether modulation of submandibular gland ductal cell growth can be exerted via a mechanism that in itself includes epidermal growth factor and its receptor and signal transduction pathway. This work was supported by Public Health Service grant DE07766 from the National Institute of Dental Research, National Institutes of Health, Bethesda, MD.     

Factors affecting the differentiation of epithelial transport and responsiveness to hormones

Under standard culture conditions, epithelial cells grow with their basal surface attached to the culture dish and their apical surface facing the medium. Morphological and functional markers are located in the appropriate plasma membrane, and transepithelial transport occurs in a variety of cultured epithelia. As a result of the polarity of the cells and the presence of tight junctions between cells, on standard tissue culture dishes there is restricted access of growth medium to the basolateral surface of the epithelium, which is the surface at which nutrient exchange normally occurs. Greater differentiation of epithelial cultures can be achieved by growing primary cultures or continuous cell lines on permeable surfaces such as porous bottom cultures dishes in which the porous bottom is formed by a filter or membrane of collagen, or on floating collagen gels. In many cultures, differentiation varies with the time after the culture was seeded. Certain chemicals that accelerate differentiation in nonepithelial cells also accelerate the differentiation of epithelial cultures. Ultimately, defined media and specific substrates for cell attachment should lead to further differentiation of epithelia in culture.     

Growth and Differentiation of Primary Cultures of Mouse Mammary Epithelium Embedded in Collagen Gel

Mammary glands from BALB/cfC3H midpregnant (9–11 days) mice were dissociated with collagenase and pronase, separated on a Percoll gradient, and the epithelial cells were cultured inside collagen gel. The cell number increased three-to five-fold when cultured for 6–8 days in DME/F12 (1: 1) medium containing 3% swine serum, insulin (10 μg/ml), cortisol (1.0 μg/ml), prolactin (10 μg/ml), transferrin (10 μg/ml), and epidermal growth factor (0.01 μg/ml). The casein level, as determined by radioimmunoassay, at the end of this growth phase, was much lower than that present in freshly dissociated cells. In order to stimulate casein production, the gels were released from the sides of the plastic dish and allowed to float for eight days in Waymouth's medium, containing insulin (10 μg/ml), cortisol (5 μg/ml), prolactin (10 μg/ml), and 0.25% bovine serum albumin. The casein level at the end of this differentiation phase was found to be comparable to that seen in the original freshly dissociated cells. Cells grown in DME/F12 (1: 1) medium containing 3% swine serum, insulin (10 μg/ml), and transferrin (10 μg/ml) were still capable of undergoing casein production, indicating that the presence of exogenous lactogenic hormones such as cortisol and prolactin, as well as exogenous growth factors such as epidermal growth factor, is not necessary during the growth phase for subsequent casein production during the differentiation phase. Two factors that seemed more important for subsequent casein stimulation were: (1) releasing collagen gels at the beginning of the differentiation phase, and (2) switching to'differentiation' medium. This present two-step protocol has allowed primary cultures of dissociated midpregnant mouse mammary epithelial cells to undergo several rounds of division inside a collagen gel matrix and to be subsequently stimulated to produce the mammary-specific protein, casein.     

The influence of cell shape on the induction of functional differentiation in mouse mammary cells in vitro

Summary To define more clearly the in vitro conditions permissive for hormonal induction of functional differentiation, we cultured dissociated normal mammary cells from prelactating mice in or on a variety of substrates. Cultivation of an enriched epithelial cell population in association with living adult mammary stroma in the presence of lactogenic hormones resulted in both morphological and biochemical differentiation. This differentiation, however, was not enhanced over that seen when the cells were associated with killed stroma, provided that the killed stroma had a flexibility similar to that of the living stroma. Cells cultured in inflexible killed stroma usually did not differentiate. Cells cultured within the flexible environment of a collagen gel, but removed from the gas-medium interface, differentiated in a manner similar to those cultured in flexible stroma. Cells cultured on the surface of an attached collagen gel were squamous, and their basolateral surfaces were sequestered from the medium; they did not differentiate. Cells cultured on floating collagen gels were cuboidal-columnar, with basolateral surfaces exposed to the medium, and showed good functional differentiation. Cells cultured on inflexible floating collagen gels were extremely flattened and had exposed basolateral surfaces, and showed no evidence of functional differentiation. We infer that assumption of cuboidal to columnar shapes similar to those of mammary cells in vivo may be important to the induction of functional differentiation in vitro. The additional requirement of basolateral cell surface exposure also is important. This work was supported by U.S. Public Health Service Grants CA-05045 and CA-09041 from the National Cancer Institute, Bethesda, MD.     

Modulation of KB and A431 cell adhesion by epidermal growth inhibitory pentapeptide.

A pentapaptide, pyroGlu-Glu-Asp-Ser-GlyOH (EPP), isolated from mouse epidermis, inhibits mitoses and enhances differentiation in primary cultures and in transformed mouse epidermal cells in vitro (Elgjo et al. 1986 b). The present work demonstrates that EPP also modulates the adhesiveness of two human tumour cell lines (KB and A431) of epidermal origin to uncoated plastic and to plastic coated with fibrinogen or collagen type 1. The adhesion modulatory effect of EPP was observed over a broad range of concentrations (10(-12)-10(-6) M), and depended on the substrate the cells were growing on. Thus, when cells were seeded on plastic or collagen, the attachment to the substrate was suppressed at the highest concentrations of EPP, and stimulated at the lowest ones. The opposite concentration-response pattern was observed when fibrinogen was used as substrate.