A transforming growth factor related to epidermal growth factor is expressed by fetal mouse salivary mesenchyme cells in culture

Fetal mouse salivary mesenchyme cells secrete a protein with an apparent MW of 15 Kd that is immunologically related to epidermal growth factor (EGF). Conditioned medium collected from these cells in culture stimulates the growth of primary mouse mammary epithelial cells cultured within collagen gels, competes for binding to EGF receptor sites on these mammary epithelial cells and stimulates the anchorage-independent growth of normal rat kidney fibroblast cells within soft agarose. Prior immunoprecipitation of salivary mesenchyme cell conditioned medium with anti-EGF antibodies effectively removes or attenuates all of these effects confirming that an EGF-like factor is involved in these responses.     

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.     

Morphogenesis of Mouse Mammary Epithelium In Vivo in Response to Biomatrix Prepared from a Stimulatory Fetal Mesenchyme

Insoluble "biomatrix" of mesenchyme is a stimulator of mammary cell differentiation in vitro , but its effect in the morphogenesis is unknown. Fetal salivary mesenchyme induces intense local duct formation when implanted into adult mammary gland. We have therefore tested whether biomatrix prepared from fetal salivary mesenchyme retains this abillity to stimulate duct formation in vivo . Salivary mesenchyme isolated from mouse fetuses at 13.5–14.0 days of gestation, extracted sequentially with water and with 1 M NaCl, then digested with DNAse and RNAse was implanted into mammary glands of female mice and left for periods of 1–35 days. In approximately 40% of recipients, the local epithelium either formed cyst like structures, or else "spikes" of mammary epithelium penetrated the matrix forming a simplified ductwork inside it. Similar responses were elicited by salivary mesenchyme killed by freezing and also by biomatrix prepared from fetal mammary fat pad precursor tissue, mesenchyme of fetal lung, and fetal heart, liver, and brain. However when mesenchyme was either fixed with glutaraldehyde or sonicated and embedded in polymer blocks before implantation, no epithelial response was noted. These observations suggest that the biomatrix provides a passive scaffolding that contributes to morphogenesis of mammary ducts, is insufficient to support normal morphogenesis.     

Analysis In Vitro of Capacity of Fetal Fat Pad to Support Mammary Gland Embryogenesis

Fourteen-day fetal mammary fat pad precursor tissue (FP) has the capacity to support various fetal epithelia allowing them to accomplish their characteristic development in vivo , without their own mesenchyme (1). This capacity decreases with age of fetal fat pad and is lost postnatally. To analyse the molecular mechanism of such interaction, a method for in vitro duplication of organogenesis is necessary. In the present paper, a co-culture system of fetal epithelium with prospective mammary fat pad is described. The explanted mammary epithelium started budding, then grew out forming branched mammary ducts with end buds. Ultrastructurally, the developing ductal structures exhibited the typical mammary gland morphogenesis.
³H-Thymidine incorportion assessed by autoradiography showed that the mammary gland morphogenesis in vitro was due to the proliferation of epithelial cells, not merely to a change of the shape of the epithelium. This supportive capacity of 14-day FP also decreased with aging; explanted mammary epithelium did not grow into 17-day FP. When insoluble, non-living biomatrix was used in place of living FP the epithelium grew into the matrix but the resulting structures lacked characteristic morphology of epithelium on living fetal FP. The difference of capacity between 14-day and 17-day tissues was also lost.     

EGF-receptor regulates salivary gland branching morphogenesis by supporting proliferation and maturation of epithelial cells and survival of mesenchymal cells

Epidermal growth factor receptor (EGF-R) regulates epithelial morphogenesis during development and is important for the proper branching of the lung, mammary gland, and pancreas. We analyzed the salivary gland phenotype of EGF-R-deficient mice and showed impaired growth, branching, and maturation of the epithelium. Furthermore, treatment of wild-type E13 salivary glands with gefitinib, a small molecular inhibitor of EGF-R, led to apoptosis of the mesenchyme. Interestingly, MMP2 and plasminogen activators were upregulated upon inhibition of EGF-R signaling. To summarize, we show that EGF-R is a physiological regulator of salivary gland development and its main function is to support the proliferation and maturation of the epithelium and the survival of the mesenchyme.     

Neoplastic transformation of mouse mammary epithelial cells by deregulated myc expression.

A spontaneously immortalized, nontumorigenic mouse mammary epithelial cell line (MMEC) was transfected with an activated myc construct by electroporation. Constitutive expression of myc in MMEC resulted in anchorage independence in soft agar and tumorigenicity in nude mice. The myc-expressing MMEC showed higher saturation density, faster growth rate, and partial abrogation of serum-derived growth factor(s) requirement compared with parent MMEC. Epidermal growth factor or transforming growth factor alpha stimulated the anchorage-independent growth, but not the anchorage-dependent growth, of MMEC-myc cells. Type 1 transforming growth factor beta, on the other hand, inhibited both the anchorage-independent and anchorage-dependent growth of MMEC-myc cells. These results demonstrate that deregulated expression of myc results in neoplastic transformation iin mammary epithelial cells. Accompanying the transformation is altered sensitivity to polypeptide growth factors.     

Primary culture in chemically defined medium of human fetal mammary epithelial cells within reconstituted matrix]

A serum-free primary culture system has been developed which allows for three-dimensional growth and differentiation of normal human fetal mammary epithelial cells within an extracellular matrix preparation. Human fetal mammary epithelial cells were isolated from the mammary glands of human female fetuses, 17 to 39 weeks-old. The "organoids" were embedded within a reconstituted basement membrane matrix prepared from the Engelbreth-Holm-Swarm (EHS) sarcoma according to the method of Hahm and Ip. "Organoids" were grown in either serum-free medium or in medium with fetal calf serum (FCS). The "organoid" proliferated over a 2 to 3 weeks culture period and remained viable for 1 or 2 months within the basement membrane matrix in serum free medium. Several types of colonies were observed; including alveolar-like budding clusters obtained from cultures of mammary gland from fetuses of over 20 weeks age, units with ductule-like projections and stellate-type colonies. Cell proliferation was dependent on the culture medium (with FCS no proliferation was obtained) and on the substratum (without matrix, significantly less growth and development occurred). These types of colonies are obtained when a glandular differentiation of cells budding from the malpighian epithelium is observed. Light microscopic and transmission electron microscopic studies were undertaken at the time of culture. This unique system using normal fetal mammary epithelial cells thus provides a model in which the regulation of human mammary development can be investigated.     

Milk protein expression and ductal morphogenesis in the mammary gland in vitro: hormone-dependent and -independent phases of adipocyte-mammary epithelial cell interaction

Epithelial cell differentiation frequently occurs in situ in conjunction with supporting mesenchyme or connective tissue. In embryonic development the importance of the supporting mesenchyme for cytodifferentiation and morphogenesis has been demonstrated in several epithelial tissues, but the importance of epithelial-connective tissue interactions is less well studied in adult epithelial organs. We have investigated the interaction of adult mammary epithelial cells with adipocytes, which compose the normal supporting connective tissue in the mammary gland. Mammary epithelial cells from mice in various physiological states were cultured on cellular substrates of adipocytes formed from cells of the 3T3-L1 preadipocyte cell line. We found that there were two distinct phases to the interaction of epithelial cells with adipocytes. Cytodifferentiation of the epithelial cells and milk protein production were dependent on lactogenic hormones (insulin, hydrocortisone, and prolactin), whereas ductal morphogenesis was lactogenic hormone independent. When cultured on preadipocytes or adipocytes, mammary epithelial cells from never pregnant, pregnant, lactating, and involuting mice responded to lactogenic hormones rapidly by producing and secreting large amounts of alpha-, beta-, and gamma-casein and alpha-lactalbumin. This response was seen in individual as well as in clusters of epithelial cells, but was not seen if the same cells were cultured on tissue culture dishes without adipocytes, on fibroblasts (human newborn foreskin fibroblasts) or in the presence of adipocytes but in the absence of lactogenic hormones. Continued incubation of mammary epithelial cells on adipocytes in the presence or absence of lactogenic hormones resulted in the formation of a branching ductal system. Mammary epithelial cells in ducts that formed in the absence of lactogenic hormones produced no casein, but rapidly synthesized casein when subsequently exposed to these hormones. Ultrastructural studies revealed that the formation of a basement membrane occurs only in co-cultures of mammary epithelium with adipocytes or preadipocytes. Ultrastructural changes associated with secretion occurred only in the presence of lactogenic hormones. We propose that growth and formation of a ductal system in vitro can occur in the absence of lactogenic hormones, but that certain environment-associated events must occur if the epithelium is to become responsive to lactogenic hormones and undergo the cytodifferentiation associated with lactation.     

Isolation of clones of hamster embryo cells transformed by the bovine papilloma virus

Primary hamster embryo cells infected with bovine papilloma virus (BPV) or treated with BPV DNA-calcium phosphate precipitates showed striking morphological alterations characteristic of transformed cells. Long, spindle-shaped cells grew into dense foci, eventually overgrowing monolayers of normally shaped cells. Samples of these cells were tested for anchorage-independent growth in dilute agarose medium. Cells were able to grow in agarose to form colonies which, when removed from agarose and transferred to liquid medium, established clones. Mockinfected cultures inoculated with plain medium displayed normal cell morphology and growth properties. This is the first report of BPV-transformed cells demonstrating anchorage-independent growth in agarose and the establishment of BPV transformed clones.     

Mitogenic activity of pituitary hormones on cell cultures of normal and carcinogen-induced tumor epithelium from rat mammary glands

Cell suspension containing normal or tumor epithelium were readily obtained by enzymatically digesting rat mammary glands from perphenazine-treated (prolactin-hypersecreting) cycling, female virgin animals or hormone- responsive mammary tumors from animal treated with dimethylbenzanthracene. Cell suspensions were fractioned into predominantly epithelial and predominantly stromal cells by their differential rates of attachment to culture dishes. Both normal mammary and tumor epithelial cells were characterized by the presence of specific cell-junctional complexes, desmosome-like structures, surface microvilli, and their ability to synthesize casein. Serum-dependent protease activity was greater in cultures derived from tumors, and cells from such cultures grew in agarose whereas those from the non-neoplastic gland did not. The addition of prolactin to the culture medium stimulated DNA synthesis in primary or secondary epithelial cultures from tumors, whereas additional insulin and hydrocortisone with prolactin were required for similar levels of DNA synthesis in cultures from non-neoplastic glands. The fraction of cells synthesizing DNA was, however, smaller than that with 10 percent serum measured in the same time period. Both growth hormone and epidermal growth factor stimulated DNA synthesis but to a lesser extent than did prolactin. Prolactin with hydrocortisone and insulin were relatively inactive in promoting DNA synthesis of the nonepithelial cells whereas pituitary fibroblast growth factor was more active. These mitogenic effects were obtained when the hormones were added to the medium at near physiological concentrations, and paralleled the known activities of the hormones in control of mammary gland growth and development in the rat.     

Loss of growth responsiveness to epidermal growth factor and enhanced production of alpha-transforming growth factors in ras-transformed mouse mammary epithelial cells

A mouse mammary epithelial cell line, NMuMG, exhibits a low capacity to grow in semisolid medium as colonies and it is not tumorigenic in nude mice. In contrast, NMuMG cells which have been transformed by an activated c-Harvey ras proto-oncogene, NMuMG/rasH, or by the polyoma middle T-transforming gene, NMuMG/pyt, are able to grow in soft agar and, when injected into nude mice, produce undifferentiated carcinomas. Human epidermal growth factor (EGF) or human alpha-transforming growth factor (alpha TGF) can stimulate, in a dose-dependent fashion, the anchorage-independent growth of NMuMG and NMuMG/pyt cells in soft agar but fail to enhance the anchorage-independent growth of the NMuMGrasH cells. Likewise, human EGF or human alpha TGF is also able to stimulate the anchorage-dependent growth of normal NMuMG cells and NMuMG/pyt cells in a serum-free medium supplemented with insulin, transferrin, fetuin, and laminin, or in medium containing low concentrations of serum, whereas these same growth factors under comparable culture conditions have little or no effect upon the anchorage-dependent growth of the ras-transformed NMuMG-rasH cells. The biological refractoriness of the NMuMG/rasH cells to human EGF or human alpha TGF is reflected by a reduction in the total number of cell surface receptors for EGF and by an absence of a high-affinity population of binding sites for mouse [125l]EGF on these cells as compared to the NMuMG or NMuMG/pyt cells. In addition, concentrated conditioned medium (CM) obtained from NMuMG/rasH and NMuMG/pyt cells contains a relatively higher amount of biologically active TGFs than CM obtained from comparably treated NMuMG cells as measured by the ability to induce the anchorage-independent growth of normal rat kidney cells in soft agar. The higher levels of biologically active TGFs found in the CM from the transformed cells relative to the NMuMG cells is paralleled by a corresponding increase in the CM from these cells in the amount of immunoreactive alpha TGF, by an increase in the amount of EGF receptor-competing activity, and by an increase in the levels of alpha TGF mRNA in the NMuMG/rasH cells. These results demonstrate that mammary epithelial cells which have been transformed by an activated ras proto-oncogene, but not by the polyoma middle T-transforming gene, become unresponsive to exogenous EGF or alpha TGF.(ABSTRACT TRUNCATED AT 400 WORDS)     

Ectodysplasin,Edar and TNFRSF19 are expressed in complementary and overlapping patterns during mouse embryogenesis

Ectodysplasin (Eda), a member of the tumor necrosis factor (TNF) superfamily, and its receptor Edar are necessary components of ectodermal organ development. Analysis of their expression patterns and mutant phenotypes has shown that during mouse hair and tooth development they may be involved in signalling between separate epithelial compartments. Here we have analysed ectodysplasin and Edar expression in other embryonic mouse tissues, and show that Edar mRNA is confined to the epithelium. Ectodysplasin and Edar are expressed in separate epithelial compartments in the developing brain and the lacrimal gland. In the salivary gland ectodysplasin is expressed in the mesenchyme and Edar in the epithelium. This is the first indication of ectodysplasin-Edar signalling between the epithelium and the mesenchyme. We also studied the expression pattern of a related TNF receptor, TNFRSF19, and show that it is expressed in an overlapping domain with Edar in the tooth, mammary gland, whiskers, and limb bud suggesting a potentially redundant role.     

Induction of transforming growth factor alpha expression in mouse mammary epithelial cells after transformation with a point-mutated c-Ha-ras protooncogene

NOG-8 ras cells are a normal mouse mammary epithelial cell line transfected with a plasmid containing a glucocorticoid-inducible mouse mammary tumor virus long terminal repeat linked to the activated c-Ha-ras protooncogene. After addition of dexamethasone, there is a rapid induction (within 1-3 h) of p21ras protein that is concomitant with a parallel induction of the c-Ha-ras specific mRNA. After 4-6 days of dexamethasone treatment, NOG-8 ras cells are able to grow as colonies in semisolid medium. Between 9 and 12 days of dexamethasone treatment, there is a 5- to 6-fold increase of transforming growth factor alpha (TGF alpha) activity in the conditioned medium from NOG-8 ras cells. A 60-65% reduction in epidermal growth factor cell surface receptors on NOG-8 ras cells also occurs during this time interval. A 3- to 4-fold increase of the expression of a specific TGF alpha mRNA can be detected within 2 days of dexamethasone treatment, preceding the increase in TGF alpha protein found in the conditioned medium. Exogenous TGF alpha is able to stimulate in a dose-dependent fashion the anchorage-dependent and anchorage-independent growth of NOG-8 ras cells to a level comparable to that observed in dexamethasone treated ras-transformed NOG-8 ras cells. These results suggest that the enhanced expression of TGF alpha after induction of an activated ras protooncogene may be necessary for the anchorage-independent growth and subsequent morphological changes and the enhanced growth rate observed in ras-transformed mammary epithelial cells.     

Fibronectin Fibrils and Growth Factors Stimulate Anchorage-Independent Growth of a Murine Mammary Carcinoma

Stromal cells are important regulators of mammary carcinoma growth and metastasis. We have previously shown that a 3T3-L1 adipocyte cell line secretes hepatocyte growth factor (HGF), which stimulates proliferation of a murine mammary carcinoma (SP1) in monolayer cultures (DNA Cell Biol.13, 1189–1897, 1994). We now examine the role of growth factors and the extracellular matrix protein fibronectin in stimulation of anchorage-independent growth of SP1 cells. Purified transforming growth factor-β (TGF-β) stimulated significant colony growth in soft agar cultures, whereas HGF had a lesser effect. Analysis by confocal microscopy revealed that carcinoma cell colonies contained extracellular microfibrils composed of fibronectin. Partial depletion of fibronectin from 7% FBS/agar cultures reduced the number of colonies; colony growth could be recovered by adding back exogenous fibronectin. Addition of the 70-kDa N-terminal fragment of fibronectin, which inhibits fibronectin fibril formation, reduced growth of SP1 cell colonies, but an 85-kDa fragment containing the cell binding domain did not inhibit colony growth. These findings indicate that deposition of extracellular fibronectin fibrils is necessary, but not sufficient, for anchorage-independent growth of SP1 mammary carcinoma cells; growth factors are also required. SP1 cells had less fibronectin mRNA and secreted less fibronectin protein under anchorage-independent conditions than under anchorage-dependent conditions, as determined by Northern blotting and immunoprecipitation analysis. Thus, both growth factors (HGF and TGF-β) and fibronectin may be important regulators of paracrine stimulation by stromal cells of anchorage-independent growth of mammary carcinoma cells.     

Three-dimensional epithelial and mesenchymal cell co-cultures form early tooth epithelium invagination-like structures: expression patterns of relevant molecules

Epithelium invagination is the key feature of early tooth development. In this study, we built a three-dimensional (3D) model to represent epithelium invagination-like structure by tissue engineering. Human normal oral epithelial cells (OECs) and dental pulp stem cells (DPSCs) were co-cultivated for 2-7 weeks on matrigel or collagen gel to form epithelial and mesenchymal tissues. The histological change and gene expression were analyzed by HE staining, immunostaining, and quantitative real-time RT-PCR (qRT-PCR). After 4 weeks of cultivation, OECs-formed epithelium invaginated into DPSCs-derived mesenchyme on both matrigel and collagen gel. OEC-DPSC co-cultures on matrigel showed typical invagination of epithelial cells and condensation of the underlying mesenchymal cells. Epithelial invagination-related molecules, CD44 and E-cadherin, and mesenchymal condensation involved molecules, N-cadherin and Msx1 expressed at a high level in the tissue model, suggesting the epithelial invagination is functional. However, when OECs and DPSCs were co-cultivated on collagen gel; the invaginated epithelium was transformed to several epithelial colonies inside the mesenchyme after long culture period. When DPSCs were co-cultivated with immortalized human OECs NDUSD-1, all of the above-mentioned features were not presented. Immunohistological staining and qRT-PCR analysis showed that p75, BMP2, Shh, Wnt10b, E-cadherin, N-cadherin, Msx1, and Pax9 are involved in initiating epithelium invagination and epithelial-mesenchymal interaction in the 3D OEC-DPSC co-cultures. Our results suggest that co-cultivated OECs and DPSCs on matrigel under certain conditions can build an epithelium invagination-like model. This model might be explored as a potential research tool for epithelial-mesenchymal interaction and tooth regeneration.     

Branching morphogenesis of mouse salivary epithelium in basement membrane-like substratum separated from mesenchyme by the membrane filter

Branching morphogenesis of mouse salivary gland has been studied with organ-culture system. We developed a novel transfilter culture system for analyzing branching morphogenesis of the salivary epithelium. The submandibular salivary epithelium from early 13-day mouse fetus, clotted with Matrigel and separated from the mesenchyme by membrane filter, showed extensive growth and branching morphogenesis, morphological differentiation of lobules and stalks, and a typical cleft shape. The epithelium showed little growth and no branching without Matrigel clot or without the mesenchyme. This branching morphogenesis was induced even when the pore size of the filter was reduced to 0.05 microns. Use of type I collagen gel instead of Matrigel mostly induced incomplete morphogenesis with various histological abnormalities. These results suggest that the salivary epithelium can undergo branching morphogenesis in the absence of the mechanical action of mesenchymal cells although it needs an appropriate extracellular matrix and some mesenchymal factors transmitted through the filter.     

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.     

Genetic Modification and Recombination of Salivary Gland Organ Cultures

Branching morphogenesis occurs during the development of many organs, and the embryonic mouse submandibular gland (SMG) is a classical model for the study of branching morphogenesis. In the developing SMG, this process involves iterative steps of epithelial bud and duct formation, to ultimately give rise to a complex branched network of acini and ducts, which serve to produce and modify/transport the saliva, respectively, into the oral cavity^1-3. The epithelial-associated basement membrane and aspects of the mesenchymal compartment, including the mesenchyme cells, growth factors and the extracellular matrix, produced by these cells, are critical to the branching mechanism, although how the cellular and molecular events are coordinated remains poorly understood ⁴. The study of the molecular mechanisms driving epithelial morphogenesis advances our understanding of developmental mechanisms and provides insight into possible regenerative medicine approaches. Such studies have been hampered due to the lack of effective methods for genetic manipulation of the salivary epithelium. Currently, adenoviral transduction represents the most effective method for targeting epithelial cells in adult glands in vivo⁵. However, in embryonic explants, dense mesenchyme and the basement membrane surrounding the epithelial cells impedes viral access to the epithelial cells. If the mesenchyme is removed, the epithelium can be transfected using adenoviruses, and epithelial rudiments can resume branching morphogenesis in the presence of Matrigel or laminin-111^6,7. Mesenchyme-free epithelial rudiment growth also requires additional supplementation with soluble growth factors and does not fully recapitulate branching morphogenesis as it occurs in intact glands⁸. Here we describe a technique which facilitates adenoviral transduction of epithelial cells and culture of the transfected epithelium with associated mesenchyme. Following microdissection of the embryonic SMGs, removal of the mesenchyme, and viral infection of the epithelium with a GFP-containing adenovirus, we show that the epithelium spontaneously recombines with uninfected mesenchyme, recapitulating intact SMG glandular structure and branching morphogenesis. The genetically modified epithelial cell population can be easily monitored using standard fluorescence microscopy methods, if fluorescently-tagged adenoviral constructs are used. The tissue recombination method described here is currently the most effective and accessible method for transfection of epithelial cells with a wild-type or mutant vector within a complex 3D tissue construct that does not require generation of transgenic animals.     

Growth of mouse mammary gland end buds cultured in a collagen gel matrix

End buds are the growing terminal structures of the ducts in the mammary gland. They are made up of undifferentiated epithelial cells that, under the hormonal milieu of adult and pregnant females, give rise to the ducts and alveoli of the mature gland. The end buds are of interest in understanding the developmental biology of the gland. They are also likely targets for many mammary carcinogens and, therefore, of interest in understanding the biology of mammary cancer. A method was developed for isolating end buds as a pure subpopulation from collagenase and hyaluronidase digested 4-week-old C57BL/Crgl mouse mammary glands. They were cultured within a rat tail collagen gel matrix for 3 weeks and fed with media containing various combinations of sera, hormones and growth-promoting factors. Growth in response to the different media was measured by photographing individual end bud colonies over time using dark field illumination. The growth of the individual colonies was quantitated using a computer-assisted photodensitometry method of determining the colonies' mass. The end buds showed the greatest growth response (greater than 20-fold increase in 3 weeks with a minimum doubling time of 48 h) to medium supplemented with 50% equine serum and cholera toxin or with less serum (15%) and epidermal growth factor (EGF), hormones and cholera toxin. Initially, the colonies grew logarithmically, then slowed as the colony size increased. This was due, in part, to the cessation of growth by the cells in the center. This end bud culture system differs from that of dissociated mouse mammary cells in a number of ways which are discussed.