Three-dimensional growth and morphogenesis of mouse submandibular epithelial cells in serum-free primary culture

Mouse submandibular epithelial cells can be grown in primary culture using the collagen gel matrix and a chemically defined medium consisting of insulin, transferrin, cholera toxin, and BSA (or FGF). Sustained cell growth leading to a 5–10-fold increase in cell number was observed in less than 2 weeks. In the presence of these additives, clumps of cells proliferate by extending ‘star-like’ projections into the matrix, resulting in three-dimensional outgrowths. The morphology of these outgrowths can be modulated to form a ‘cyst-like’ appearance by deleting BSA and adding cortisol to the basal medium containing insulin, transferrin, cholera toxin and FGF. In brief, a serum-free medium for sustained growth has been devised and a simple manipulation of supplements can modulate the three-dimensional colony morphology in the collagen gel matrix. Finally, the resulting outgrowths can produce epidermal growth factor (EGF) in response to dihydrotestosterone.     

Different mitogenic and phenotypic responses of human breast epithelial cells grown in two versus three dimensions

Human breast epithelial cells, derived from fibroadenomas, were cultured under conditions promoting growth in two-dimensions (2D) as monolayers using the collagen-coated dishes and in three-dimensions (3D) inside the collagen gel matrix. Both epidermal growth factor (EGF) and cortisol (F) were required for maximal stimulation in 3D growth, but only cortisol was required for 2D growth. The growth stimulation of exogenously added type IV collagen was no greater than that of type I as a substrate in both the 2D and 3D growth. Immunocytochemical staining, using a polyclonal actin antibody, showed homogeneous staining in all cells in 2D monolayers, whereas more restricted distribution was observed in 3D outgrowths in the collagen gel matrix. The same cells, when cultured in 2D vs 3D, elicit different responses and the original phenotypes may be better maintained in 3D.     

Differential response of normal rat mammary epithelial cells to mammogenic hormones and EGF

A simple dissociation procedure and the collagen gel culture system have been utilized to determine the effects of mammogenic hormones and epidermal growth factor (EGF) on the proliferation of normal rat mammary epithelial (RME) cells in serum-free culture. Epithelial fragments, isolated from normal virgin F344 rat mammary glands by enzyme digestion followed by Percoll density gradient centrifugation, were embedded within a rat tail collagen matrix. A three- to four-fold increase in cell number was observed when ovine prolactin (PRL) and progesterone (P) were present in the basal medium during 7 days of culture. Mouse EGF stimulated one cell doubling during the same culture period. Isolated mammary organoids produced a 'stellate' type colony when PRL + P were present in the culture medium. These colonies were composed of small, tightly packed cuboidal cells. The addition of EGF to the basal medium produced a diffuse 'basket' type colony which was composed of large, elongate cells. When the complete hormonal and growth factor combination (PRL + P + EGF) was present, a 'mixed' type colony was observed which contained both the large and small epithelial cell types. Immunocytochemical analysis revealed that both the cuboidal and elongate cells present in the two colony types stained with antibodies to keratin indicating that these cells were epithelial in nature. The small cuboidal cells also expressed thioesterase II and alpha-lactalbumin, both specific for secretory mammary epithelial cells. The large, elongate cell type, however, was positive for actin but did not stain for either secretory epithelial specific marker. The results reported here suggest that normal rat mammary tissue may contain two epithelial populations, one which responds to PRL + P and the other which responds to EGF.     

Effect of TGF-Alpha on growth of normal human breast epithelial cells in serum-free primary culture using 3-dimensional collagen gels.

The mitogenic effect of TGF-alpha, acidic-FGF, basic-FGF and lithium on normal human breast epithelial cells was studied in a collagen gel culture system using a serum-free 1:1 mixture of Ham's F12 and DME medium containing insulin, cholera toxin and bovine serum albumin. TGF-alpha elicited a strong mitogenic response in a dose dependent manner. Addition of cortisol to TGF-alpha stimulated growth over and above that achieved with TGF-alpha alone. A consistent observation has been the effect of a combination of TGF-alpha and cortisol on growth stimulation of normal human breast epithelial cells resulting in 3-12 fold growth after 11-13 days in culture. Acidic-FGF, basic-FGF and lithium were not growth promoting.     

Effects of 1alpha,25-dihydroxycholecalciferol and cortisol on the growth and differentiation of primary cultures of mouse mammary epithelial cells in collagen gel

We examined the effects of 1alpha,25-dihydroxycholecalciferol (1,25-DHCC) and the glucocorticoid, cortisol, on primary mouse mammary epithelial cells in collagen gel cell culture systems. Physiological low concentrations (10(-11)-10(-9) M) of 1,25-DHCC stimulated growth of the cells in a collagen gel matrix culture in serum-free DMEM+Ham's F12 (1:1) medium containing BSA, EGF and cholera toxin, and the cell number reached 1.8-fold the control after 6 d in culture. In contrast, supraphysiological concentrations (10(-8)-10(-7) M) of 1,25-DHCC suppressed cell growth. Cortisol produced similar, but smaller, dose-dependent effects. The addition of serum to the culture medium masked the stimulatory effect of 1,25-DHCC and both the stimulatory and inhibitory effects of cortisol. 1,25-DHCC also affected casein synthesis by cells cultured in a serum-free floating collagen gel culture containing prolactin, insulin and cortisol, enhancing synthesis at low concentrations (10(-11)-10(-9) M) and inhibiting it above 10(-8) M. In the absence of cortisol, no detectable change in casein synthesis was induced by 1,25-DHCC. These results suggest a physiological role for 1,25-DHCC in stimulating both growth and differentiation of mouse mammary epithelial cells, though 1,25-DHCC does not substitute for glucocorticoids in the differentiation of the cells.     

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

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

Serum-free primary culture of human normal mammary epithelial cells in collagen gel matrix

Collagen gel matrix has been used successfully to promote sustained growth of human normal mammary epithelial cells in primary culture using serum-containing medium supplemented with hormones and growth factors (Nandi et al., 1932). Sustained growth can now be accomplished in a serum-free medium consisting of a 1:1 mixture of Ham's F12 and DMEM supplemented with insulin, transferrin, epidermal growth factor, cholera toxin, cortisol, and BSA. Human normal mammary epithelial cells derived from reduction mammoplasties can be routinely propagated in this serum-free medium. The extent of growth and the resulting three-dimensional outgrowths in this serum-free medium, using the collagen gel matrix system, are comparable to those seen in serum-containing medium. This is the first demonstration of sustained growth of human normal mammary epithelial cells in serum-free primary culture.     

Growth of mouse vaginal epithelial cells in culture: Effect of sera and supplemented serum-free media

Summary Normal mouse vaginal epithelial cells isolated from ovariectomized ca. 35-d-old BALB/cCrgl mice were grown in primary culture using collagen gel metrix and a serum-free medium composed of a 1∶1 mixture of Dulbecco’s modified Eagle’s medium and Ham’s F12 (D:H) medium supplemented with insulin (IN), epidermal growth factor (EGF), cholera toxin, transferrin, and bovine serum albumin V (BSA). Three-dimensional cellular outgrowths occurred inside the collagen gel matrix. The contribution of each factor to cell growth was examined by individual addition to the basic D:H medium and by individual deletion from the complete serum-free medium. When added individually, only IN promoted growth. Deletion of IN from the complete serum-free medium markedly, diminished growth; deletion of EGF or BSA slightly diminished growth. When horse, fetal bovine, or chicken serum was added to the basal D:H medium, only with increasing doses of horse serum was there enhanced cell growth. The effect of 17?-estradiol and diethylstilbestrol on the growth of cells was also tested, using a suboptimal medium of D:H supplemented with BSA and IN, or a minimal medium supplemented with IN alone. During the 8-d time period, addition of estrogen did not enhance cell growth in either medium. To date, we have been unable to demonstrate a mitogenic effect of estrogen; rather a dose-dependent inhibition of proliferation is seen. This investigation was supported by grants CA-05388 and CA-09041, awarded by the National Institutes of Health, DHHS, Bethesda, MD.     

Hepatocytic Cells Form Bile Duct-like Structures within a Three-Dimensional Collagen Gel Matrix

It has been suggested that hepatocytes have the ability to form bile ductal structures during normal development and in various pathological conditions of the liver. In the present study, we attempted to establish anin vitromodel of ductal morphogenesis of hepatocytic cells by combining an aggregate culture and a type I collagen gel culture. When spheroidal aggregates of rat or mouse primary hepatocytes were embedded within the collagen gel matrix and then cultured with a medium containing a fibroblast-conditioned medium, the aggregates extended many dendritic processes composed of a trabecular arrangement of cells. Dendritic morphogenesis was also seen in embedded aggregates of immortal liver epithelial cell lines, which spontaneously emerged during long-term cultures of mouse primary hepatocytes. A similar morphogenesis was induced by the presence of insulin in the medium. Although epidermal growth factor (EGF) and hepatocyte growth factor (HGF) showed only a small effect on the morphogenesis of most of the hepatocytic cells when used alone, these factors, especially EGF, enhanced the morphogenetic effect of insulin. Electron microscopical observations revealed luminal structures lined by microvilli within these dendritic processes, indicating ductal differentiation. Immunocytochemically, the dendritic processes were positive for cytokeratin 19, a marker for bile duct cells. On the other hand, an H-ras-transformed mouse liver epithelial cell line and rat hepatocellular carcinoma cell lines did not demonstrate the organized morphogenesis. Our results indicate that hepatocytic cells can produce bile duct-like structures in the presence of the type I collagenous matrix and soluble morphogenetic factors.     

Effect of hormones and EGF on proliferation of rat mammary epithelium enriched for alveoli : An in vitro study

Virgin rat mammary epithelium enriched for alveoli were embedded in a collagen gel matrix to study the direct effect of mammogenic hormones and epidermal growth factor (EGF) on their growth over a 12-day culture period. Serum-supplemented medium alone caused a 3- to 4-fold increase in cell number, whereas medium containing insulin, prolactin, progesterone, cholera toxin and serum caused a 15-fold increase. Cultures resulting from this substantial cell number increase consisted of large, smooth-bordered epithelial colonies with relatively few (< 1%) single cells surrounding them. An equal increase in cell number was obtained when progesterone was replaced by hydrocortisone in the above-mentioned medium, but these cultures contained predominantly single spindle-shaped cells with a few small epithelial colonies. The smooth-bordered epithelial colonies consisted solely of mammary epithelial cells, since they contained thioesterase II, an enzyme found exclusively in mammary epithelium. The identity of the single spindle-shaped cells remains to be determined. The addition of EGF to serum or serum, hormone and cholera toxin-supplemented medium did not enhance the proliferative effect of these factors on the alveolar-enriched population.     

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

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

Maintenance and induction of morphological differentiation in dissociated mammary epithelium on floating collagen membranes

Dissociated normal mammary epithelial cells from prelactating mice were plated on different substrates in various medium-serum-hormone combinations to find conditions that would permit maintenance of morphological differentiation. Cells cultured on floating collagen membranes in medium containing insulin, hydrocortisone and prolactin maintain differentiation through 1 month in culture. The surface cells form a continous epithelial pavement. Some epithelial cells below the surface layer rearrange themselves to form alveolus-like structures. Cells at both sites display surface polarization; microvilli and tight junctions are present at their medium-facing of luminal surface and a basal lamina separates the epithelial components from the gel and stromal cells. Occasional myoepithelial cells, characterized by myofilaments and plasmalemmmal vesicles, are identified at the basal surface of the secretory epithelium. In contrast, cells cultured on plastic, glass or collagen gels attached to Petri dishes form a confluent epithelial sheet showing surface polarization, but lose secretory and myoepithelial specializations. If these dedifferentiated cells are subsequently maintained on floating collagen membranes, they redifferentiate. There is little DNA synthesis in cells on collagen gels, in contrast to Petri-dish controls. Protein synthesis in cells on floating collagen membranes increases over TO values and remains constant through 7 days in culture whereas it decreases on attached gels; however, if the gels are freed to float, protein synthesis increases sharply and parallels that seen on floating membranes.     

Effects of estrogen, epidermal growth factor, and transforming growth factor-alpha on the growth of human breast epithelial cells in primary culture.

Since 17 beta-estradiol (E2)-stimulated growth in human breast cancer cell lines has been shown to be accompanied by increased production of epidermal growth factor (EGF) and transforming growth factor-alpha (TGF-alpha) and their receptor, we investigated the effects of E2 and these growth factors on the growth of human breast epithelial cells (HBEC) in primary culture. HBEC from normal, benign, and malignant tissues were cultured in serum-free medium [DME:F12(1:1), 5 mg/ml BSA, 10 ng/ml cholera toxin, 0.5 micrograms/ml cortisol, 10 micrograms/ml insulin] in the presence and absence of E2, EGF, and TGF-alpha. Tritiated-thymidine ([3H]TdR) incorporation into DNA was used as a measure of cell growth. E2 did not stimulate growth of any of the cultures at all concentrations examined (10(-9) to 10(-6) M). In contrast, EGF ranging from 1 to 100 ng/ml consistently increased the growth of cells of all three breast tissue types in a dose-dependent manner. The EGF stimulation was inhibited by MAb 528, a monoclonal antibody against the EGF receptor. TGF-alpha was equally or more effective in stimulating proliferation, although its dose-response range was different than that of EGF. E2 and EGF together acted in a synergistic manner in 50% of the samples examined. These studies suggest that E2 can exert effects on HBEC growth via modulation of the cells' response to EGF.     

Embedding in a collagen gel stabilizes the polarity of epithelial cells in thyroid follicles in suspension culture

Separated thyroid follicles are stable in suspension culture in Coon's modified Ham's F12 medium containing 0.5% calf serum. They resemble follicles in vivo except for the absence of a basal lamina. However, the epithelial cells reverse polarity and the follicles invert when the serum concentration is raised to 5%. A number of substances, especially components of extracellular matrix, were added to the medium to ascertain if they could stabilize the follicles against inversion in 5% serum. Cellular and plasma fibronectin, gelatin, heat-denatured collagen, methylcellulose and laminin did not stabilize. The addition to the medium of as little as 50 micrograms/ml of acid-soluble collagen prepared from calf skin or rat tail tendons resulted in the formation of small clouds of gel. Follicles embedded within the gel were stabilized. Follicles in the same dish but not embedded in the gel inverted. Stabilization was not specific for collagen, since follicles embedded in a plasma clot were also stabilized. A gel was not sufficient for stabilization, since embedding in an agarose gel did not stabilize. Ultrastructural studies indicate that adherence to a limited number of gelled fibers of collagen covering only a small fraction of the basal plasma membrane may be sufficient to stabilize and that a basal lamina formed in the presence of laminin but without added collagen does not stabilize.     

Maintenance and induction of morphological differentiation in dissociated mammary epithelium on floating collagen membranes

Summary Dissociated normal mammary epithelial cells from prelactating mice were plated on different substrates in various medium-serum-hormone combinations to find conditions that would permit maintenance of morphological differentiation. Cells cultured on floating collagen membranes in medium containing insulin, hydrocortisone and prolactin maintain differentiation through 1 month in culture. The surface cells form a continuous epithelial pavement. Some epithelial cells below the surface layer rearrange themselves to form alveolus-like structures. Cells at both sites display surface polarization; microvilli and tight junctions are present at their medium-facing or luminal surface and a basal lamina separates the epithelial components from the gel and stromal cells. Occasinal myoepithelial cells, characterized by myofilaments and plasmalemmal vesicles, are identified at the basal surface of the secretory epithelium. In contrast, cells cultured on plastic, glass or collagen gels attached to Petri dishes form a confluent epithelial sheet showing surface polarization, but lose secretory and myoepithelial specializations. If these dedifferentiated cells are subsequently maintained on floating collagen membranes, they redifferentiate. There is little DNA synthesis in cells on collagen gels, in contrast to Petri-dish controls. Protein synthesis in cells on floating collagen membranes increases over T₀ values and remains constant through 7 days in culture whereas it decreases on attached gels; however, if the gels are freed to float, protein synthesis increases sharply and parallels that seen on floating membranes. The work was supported by USPHS Grants CA-05388 and CA-05045 from the National Cancer Institute, DHEW.     

In vivo growth stimulation of collagen gel embedded normal human and mouse primary mammary epithelial cells

A new system for studying growth of normal human mammary epithelial cells in an in vivo environment using athymic nude mice is described. Human mammary epithelial cells dissociated from reduction mammoplasty specimens were embedded within collagen gels and subsequently transplanted subcutaneously into nude mice. Histological sections of recovered collagen gels showed epithelial cells arranged as short tubules with some branching. Proliferation of mammary epithelial cells was quantitated in vivo by 3 days' continuous infusion with 5 bromo-2′-deoxy-uridine followed by immunostaining of sections from recovered gels. Ovarian steroids administered to the host animals, resulting in blood serum levels normally found in the human female, had little or no effect on the proliferation of human mammary epithelial cells. Collagen gel embedded mouse mammary epithelial cells, mouse mammary explants, and host mammary glands all responded similarly to ovarian steroids, suggesting that the unresponsiveness of the human mammary epithelial cells under these conditions was not due to dissociation per se. However, an increased dose of 17β-estradiol or a growth factor combination containing epidermal growth factor, cholera toxin, and cortisol significantly stimulated the proliferation of human outgrowths. The growth factor response was dependent on the location of the cells, with the greatest response seen in the part of the gel proximal to the osmotic pump delivering the growth factors and the effect gradually waning in area more distal to the pump. The effect was especially striking since the mitotic figures could be easily identified and the labeling index was as high as 75%. The host mouse mammary gland also responded to growth factors, resulting in ductal hyperplasia. The proliferative and morphogenetic effects of various agents on normal human mammary epithelial cells embedded in collagen gel can be studied in vivo in nude mice. © 1995 Wiley-Liss, Inc.     

Double-layered collagen gel hemisphere for cell invasion assay: successful visualization and quantification of cell invasion activity

Although various methods for collagen gel-based cell invasion assays have been described, there continues to be a need for a simpler and more objective assay. Here, we describe an easy-to-prepare double-layered collagen gel hemisphere (DL-CGH) system that satisfies these requirements, and we demonstrate the advantages of this new system for visualizing cell movements during invasion. DL-CGH consists of a central core collagen layer surrounded by an outer cover collagen layer. A droplet of collagen I solution (containing cells to be examined) naturally forms a small hemisphere on the bottom of the culture dish. After this central core layer gels, a second droplet is placed atop the first gel, encapsulating it completely. The hemisphere is submerged in the medium and cultured. The invasive activity of cells that infiltrate from the inner to the outer layer can be evaluated optically. Using this in vitro system, we measured the inhibitory effect of E-cadherin expression on cancer cell invasion. DL-CGH also allowed visualization of interactions between invading cancer cells and the stroma. Cancer cells, which lack the proteases required for direct entrance into the three-dimensional collagen matrix, were seen to slip like amoebas through matrix gaps generated by the pericellular proteolytic activity of fibroblasts. [Supplementary materials are available for this article. Go to the publisher's online edition of Cell Communication and Adhesion for the following free supplemental resources: Movies 1-3; 4a and b].     

Mammary gland morphogenesis in vitro: Extracellular requirements for the formation of tubules in collagen gels by a cloned rat mammary epithelial cell line

Summary The mechanism of induction of tubular outgrowths in vitro on floating collagen gels and the influence of extracellular factors on this process have been investigated using the clonal rat mammary epithelial cell line, Rama 25. Growth of Rama 25 on such floating gels causes their contraction. Contraction of the gel is accompanied by a 10-fold increase in the number of cells per unit area, a change in cell shape, and a convolution of the epithelial cell sheet. Gels folded over manually show an 11-times higher incidence of tubules along the folds than on the flat surface. Tubular formation begins when cords of cells develop from local proliferations of the cell sheet and become canalized. Tubules follow wrinkles in the gel and branch to yield monopodial, dichotomous, or lobular architecture. Hydrocortisone and insulin, in the presence of serum, stimulate both narrow and thick tubular structures on folded gels, whereas extra additions of 1 ng/ml cholera toxin or 100 ng/ml epidermal growth factor preferentially stimulate thick tubular structures. Floating glutaraldehyde-fixed gels, very thick collagen gels, and collagen gels prepared on the top of rigid steel grids fail to support the formation of tubules, suggesting that flexibility and access of the medium to basal surfaces are important to their genesis. Incorporation of hyaluronic acid into the gel matrix preferentially inhibits the thick tubular outgrowths. Thus, the branching tubular structures generated by Rama 25 can be influenced in different ways by various extracellular factors in the medium and in the gel. During the course of this work E. J. Ormerod was in receipt of a Ludwig Research Studentship.     

The identification of extracellular matrix (ECM) binding sites on the basal surface of embryonic corneal epithelium and the effect of ECM binding on epithelial collagen production

Previously, we have shown that embryonic corneal epithelia can interact with, and respond to, soluble extracellular matrices (ECM) (laminin, collagen, and fibronectin). The basal surface of epithelia isolated free of the underlying ECM can be seen to be disrupted by numerous blebs that sprout from this formerly smooth surface. Laminin, collagen, or fibronectin added to the culture medium cause the epithelium to reorganize its cytoskeleton and flatten its basal surface. We show here that ECM molecules at concentrations that reorganize epithelial cytoskeletal morphology also increase the amount of collagen produced by the epithelial cells. However, molecules that do not reorganize basal epithelial morphology (concanavalin A, heparin, bovine serum albumin) have no effect on collagen production. We also report that fluorescently labeled laminin, collagen, and fibronectin, when added to the medium surrounding isolated corneal epithelia, bind to and flatten the basal epithelial cell surface. The binding site on the basal surface is protease sensitive and is specific for each ECM molecule. These results are compatible with the idea that the basal epithelial plasmalemma possesses a diverse population of binding sites for ECM that link cell surface matrix to the cytoskeleton, causing a dramatic cytoskeletal reorganization which in turn results in enhanced production of collagen by the cells.     

Separated human breast epithelial and myoepithelial cells have different growth factor requirements in vitro but can reconstitute normal breast lobuloalveolar structure

In order to investigate the specific factors controlling the growth of normal breast cell types, purified populations of human breast epithelial and myoepithelial cells from reduction mammoplasties were grown in primary culture in three defined media and their response to foetal calf serum (FCS), epidermal growth factor (EGF) and basic fibroblast growth factor (FGF2) measured using MTT growth assays. Epithelial and myoepithelial cells differed markedly in their growth requirements. Whereas epithelial cell survival was dependent on the presence of FCS, myoepithelial cell growth was dramatically inhibited by serum. EGF and FGF2 were mitogenic for epithelial cells but not myoepithelial cells, the addition of insulin being the only essential supplement required for myoepithelial cell growth. Heparin inhibited FGF2-stimulated epithelial cell growth but also basal myoepithelial cell proliferation and this inhibition could be overcome by the addition of EGF. Neutralizing antibodies to EGF also inhibited basal myoepithelial cell growth. This suggests the possibility of an autocrine role for a heparin-binding member of the EGF family in the growth of myoepithelial cells. Purified cells combined to form lobuloalveolar structures when incubated in a reconstituted basement membrane matrix (Matrigel) in the presence of EGF and FGF2. J. Cell. Physiol. 171:11–19, 1997. © 1997 Wiley-Liss, Inc.