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.     

Serum-free culture conditions for the growth of normal rat mammary epithelial cells in primary culture

Summary A monolayer culture system has recently been developed for the extended growth and serial passage of normal rat mammary epithelial (RME) cells. In this system the cells undergo greater than 20 population doublings when grown on type I collagen-coated tissue culture dishes in Ham's F12 medium supplemented with insulin, hydrocortisone, epidermal growth factor, prolactin, progesterone, cholera toxin, and 5% fetal bovine serum (FBS). The purpose of the present studies was to define additional growth factors that would allow equivalent RME cell proliferation in serum-free medium. Ethanolamine (EA) was effective at reducing the FBS requirements for RME cell proliferation and at its optimum concentration did so by greater than 20-fold. Even with optimum levels of EA there was essentially no cell proliferation in the absence of FBS. However, addition of bovine serum albumin (BSA) to the hormone, growth factor, and EA-supplemented medium resulted in substantial proliferation in the absence of serum, and the further addition of transferrin (T) potentiated this effect. Thus, in this culture system, replacement of FBS with EA, BSA, and T resulted in RME cell proliferation in primary culture which was equivalent to that obtained in the 5% FBS-containing medium. This work was supported by grant RR-05529 from the Division of Research Resources, National Institutes of Health, Bethesda, MD, and by Public Health Service grant CA40064-01 from the National Cancer Institute, Bethesda, MD.     

Epidermal growth factor receptor, platelet-derived growth factor receptor, and c-erbB-2 receptor activation all promote growth but have distinctive effects upon mouse mammary epithelial cell differentiation.

Three different receptor tyrosine kinases, epidermal growth factor (EGF), c-erbB-2/neu, and platelet-derived growth factor (PDGF) receptors, have been found to be present in the mouse mammary epithelial cell line HC11. We have investigated the consequences of receptor activation on the growth and differentiation of HC11 cells. HC11 cells are normal epithelial cells which maintain differentiation-specific functions. Treatment of the cells with the lactogenic hormones glucocorticoids and prolactin leads to the expression of the milk protein beta-casein. Activation of EGF receptor has a positive effect on cell growth and causes the cells to become competent for the lactogenic hormone response. HC11 cells respond optimally to the lactogenic hormone mixture and synthesize high levels of beta-casein only if they have been kept previously in a medium containing EGF. Transfection of HC11 cells with the activated rat neuT receptor results in the acquisition of competence to respond to the lactogenic hormones even if the cells are grown in the absence of EGF. The activation of PDGF receptor, through PDGF-BB, also stimulates the growth of HC11 cells. Cells kept only in PDGF do not become competent for lactogenic hormone induction. The results show that activation of the structurally related EGF and c-erbB-2/neu receptors, but not the PDGF receptor, allows the HC11 cells to subsequently respond optimally to lactogenic hormones.     

cAMP levels in proliferating rat mammary epithelial cells in vitro and in vivo

Agents that elevate intracellular cAMP levels are required for growth of many cell types in culture including normal rat mammary epithelial (RME) cells. To determine if the intracellular levels of cAMP that result from stimulation by agents such as cholera toxin (CT) or prostaglandin E-1 (PGE-1) are within the physiological range, cAMP levels were determined in RME cells growing in primary culture and compared to levels measured in freshly isolated mammary epithelium. The results indicate that the cAMP levels of mammary epithelial organoids obtained from 45-day-old virgin rats are 4 to 6 pmol/10(6) cells. Growth of RME cells in primary culture in the presence of CT results in cAMP levels of approximately 15 to 20 pmol/10(6) cells early in culture when cells are proliferating rapidly. As cells approach confluence, cAMP concentrations decrease to levels observed in fresh organoids. CT-stimulated cAMP levels appear to be within the range of those found in pregnant mammary epithelium in vivo. Growth of RME cells in medium supplemented with PGE-1 instead of CT results in cAMP levels equivalent to those found in fresh mammary epithelial organoids and under these conditions the growth rate is approximately half that found in CT-stimulated cells. These results indicate cAMP to be a positive regulator of cell growth in vivo at levels that are within the physiological range.     

cAMP levels in proliferating rat mammary epithelial cells in vitro and in vivo

Agents that elevate intracellular cAMP levels are required for growth of many cell types in culture including normal rat mammary epithelial (RME) cells. To determine if the intracellular levels of cAMP that result from stimulation by agents such as cholera toxin (CT) or prostaglandin E-1 (PGE-1) are within the physiological range, cAMP levels were determined in RME cells growing in primary culture and compared to levels measured in freshly isolated mammary epithelium. The results indicate that the cAMP levels of mammary epithelial organoids obtained from 45-day-old virgin rats are 4 to 6 pmol/10⁶ cells. Growth of RME cells in primary culture in the presence of CT results in cAMP levels of approximately 15 to 20 pmol/10⁶ cells early in culture when cells are proliferating rapidly. As cells approach confluence, cAMP concentrations decrease to levels observed in fresh organoids. CT-stimulated cAMP levels appear to be within the range of those found in pregnant mammary epithelium in vivo. Growth of RME cells in medium supplemented with PGE-1 instead of CT results in cAMP levels equivalent to those found in fresh mammary epithelial organoids and under these conditions the growth rate is approximately half that found in CT-stimulated cells. These results indicate cAMP to be a positive regulator of cell growth in vivo at levels that are within the physiological range.     

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.     

Modulation of the mitogenic response of an epidermal growth factor-dependent keratinocyte cell line by dexamethasone, insulin, and transforming growth factor-beta

The stimulation of DNA synthesis by epidermal growth factor (EGF) has been studied for a cell line having properties useful for investigating the mechanism of action of EGF in epithelial cell populations. These studies employ a mouse keratinocyte cell line (MK), isolated by Weissman and Aaronson (1983), which is stringently dependent on exogenous EGF for growth in serum containing medium. The studies reported here characterize the compliment of EGR receptors present on the surface of MK cells and demonstrate the regulatory influence of other hormones on the capacity of EGF to stimulate DNA synthesis. Up-regulated MK cells contain approximately 22,000 EGF receptors per cell, but when the cells are grown in the presence of EGF the receptor number is reduced to about 4,000. It is estimated that only a small number of high-affinity receptors (less than 500) are required for EGF-dependent cell proliferation. In contrast to its action in fibroblastic cells, dexamethasone is a strong inhibitor of EGF-stimulated DNA synthesis of MK cells. Insulin at high concentrations, or insulin-like growth factors I or II (IGF-I, IGF-II) at physiological concentrations, synergistically enhance the EGF response. Interestingly, insulin or IGF-I or II are also able to reverse most of the dexamethasone inhibition of DNA synthesis. Transforming growth factor-beta (TGF-beta) inhibits, in reversible manner, the EGF stimulation of DNA synthesis and this inhibition is not overcome by insulin. TGF-beta receptors have been measured in MK cells and Scatchard analysis indicates approximately 20,000 receptors per cell. None of the modulatory hormones (insulin, dexamethasone, TGF-beta) significantly altered 125I-EGF binding characteristics in MK cells, suggesting a point of action distal to 125I-EGF binding.     

Growth requirements and neoplastic transformation of two types of normal human breast epithelial cells derived from reduction mammoplasty

Summary A chemically defined culture medium was developed to support the growth of two distinctly different types of normal human breast epithelial cells (HBEC) derived from reduction mammoplasty. Type I cells expressed luminal epithelial cell markers and were deficient in gap junctional intercellular communication (GJIC), whereas Type II cells expressed basal epithelial cell markers and were efficient in GJIC. In this study, we examined and compared the growth factor and hormone requirements of these two types of cells and a series of cell lines that were obtained by sequential transfection with SV40 DNA (extended lifespan, nontumorigenic), treatment with 5-bromodeoxyuridine (BrdU)/black light (immortal and weakly tumorigenic), and infection of a virus carrying the neu oncogene (highly tumorigenic). Growth of Type I cells was inhibited by withdrawing epidermal growth factor (EGF), hydrocortisone (HC), or insulin (INS) from the culture media, but was enhanced by fetal bovine serum (FBS) supplementation. Growth of Type II cells was inhibited by withdrawal of EGF, HC, or INS from the media, and was inhibited by FBS supplementation. Withdrawal of human transferrin (HT) or 17β-estradiol (E₂) from the media did not alter the growth of Type I or Type II cells. SV40 transfected Type I cell lines still required EGF, HC, or INS for optimal growth. However, the highly tumorigenic cell line did not show a growth dependence on EGF, HC, or INS but did appear to require HT and 3,3′,5-triiodo-D.L. thyronine (T₃) for optimal growth. In addition, FBS stimulated the growth of these cell lines. Thus, this study shows that Type I HBEC are distinctly different from Type II HBEC in growth response to FBS and that neoplastically transformed Type I cells could become growth factor and hormone independent.     

Serum-free mouse embryo cells: growth responses in vitro

We have derived serum-free mouse embryo (SFME) cultures in a basal nutrient medium supplemented with insulin, transferrin, epidermal growth factor (EGF), high-density lipoprotein (HDL), and fibronectin. These cells are nontumorigenic, lack gross chromosomal aberrations, and exhibit several other unique properties, including dependence on EGF for survival and growth inhibition by serum. We have examined the concentration dependence of the growth stimulatory effects of protein supplements used in the SFME medium formulation and surveyed other supplements that might act as alternative or complementary additions to the culture medium. Insulin could be replaced by insulin-like growth factor I and EGF could be replaced by transforming growth factor alpha in the same concentration range. Transferrin could be replaced by higher concentrations of lactoferrin. Deterioration of cultures in the absence of EGF began within 8 hours of the removal of the growth factor, and could be prevented by the addition of fibroblast growth factor/heparin-binding growth factor. Attachment proteins other than fibronectin were effective on SFME cells, but limited success was obtained when substituting other lipid preparations for HDL. These data introduce a precise system for exploring the unusual characteristics of SFME cells and contribute additional information that may be useful in the extension of these approaches to other cell types and species.     

Casein Accumulation by Rat Mammary Epithelial Cells Grown within a Reconstituted Basement Membrane Is Modulated by Fatty Acids in a Hormone- and Time-Dependent Manner

The mammary gland is under complex regulation involving the participation of hormones, growth factors, and stromal components, including lipids. Our laboratory has developed a unique primary culture system that allows undifferentiated mammary epithelial cells from immature virgin rats to proliferate and differentiate to an extent equivalent to the lactating mammary gland. Using this model system we have examined the effects of the unsaturated fatty acids oleate and linoleate on mammary epithelial cell proliferation as well as both morphological and functional differentiation. Neither fatty acid showed any effect on cell proliferation whether added to cells in the presence of optimal serum-free medium or under suboptimal conditions of epidermal growth factor (EGF) and prolactin. Morphological differentiation also was not affected by fatty acid addition under either optimal or suboptimal conditions, although a decrease was observed when medium depleted in EGF and prolactin was compared to optimal medium. The notable finding in this study was that both oleate and linoleate modulated functional differentiation, as assessed by casein accumulation, in a time- and hormone-dependent manner. At early times in culture, casein levels were stimulated by both oleate and linoleate; this effect was most dramatic under suboptimal conditions of prolactin and EGF. In marked contrast, however, linoleate decreased casein levels by approximately 50% in optimal medium, at all concentrations tested, after at least 7 days in culture. This decrease was also observed in suboptimal medium, although the concentration of EGF and prolactin influenced the extent of the reduction. Although the mechanism is currently unknown, it is tempting to speculate that the cellular and biochemical events that result in linoleate-induced inhibition of functional differentiation may also be involved in the tumor-enhancing properties of this fatty acid.     

Serial propagation of human ovarian surface epithelium in tissue culture

Most human ovarian cancers are thought to arise in the ovarian surface epithelium (OSE). The precise role of OSE in carcinogenesis has not been defined because no appropriate animal models for the study of this tissue exist and culture of human OSE has been limited to primary outgrowths. In this report, we describe conditions for serial cultivation of normal human OSE. Premenopausal ovarian tissue was obtained at surgery. OSE growth was compared in media MCDB 202, 199 and Waymouth's 752/1 (WM) supplemented with 5, 15, or 25% fetal bovine serum (FBS), with/without 20 ng/ml epidermal growth factor (EGF) and 0.4 micrograms/ml hydrocortisone (HC). The rate and extent of OSE outgrowths from explants in primary culture were greatest in either WM or 199/202 (1:1), supplemented with 15% FBS/EGF/HC. In early passage cultures, cell proliferation was most rapid and extensive in 199/202 with 15% FBS, EGF, and HC. In this medium, OSE cells were subcultured up to 10 times and underwent 20-25 population doublings over 5 weeks. The population doubling time during rapid growth was approximately 48 h. Seeding efficiencies of up to 53% and cloning efficiencies of up to 13% were obtained. Early passage OSE cells reversibly modulated from a slow growing, epithelial, intensely keratin-positive form in 199/202 medium lacking EGF/HC, to a rapidly proliferating, elongate, less keratin-positive form in medium with EGF/HC. OSE cells grown in WM/5-15% FBS were epithelial and near-stationary. Thus, culture conditions have been defined for ovarian carcinogen assays requiring either proliferating or stationary cell populations, and for further studies of the role of OSE in ovarian biology.     

A serum-free, chemically-defined medium for function and growth of primary neonatal rat heart cell cultures

A serum-free, chemically defined medium for supporting rhythmic contraction, maximum survival, and moderate growth of cardiac cells was achieved by using a combination of hormones and growth supplements in a mixture of equal volumes of Ham's F12 and Dulbecco's modified Eagle's medium. The hormones and growth supplements included insulin, transferrin, selenium, fetuin, bovine serum albumin, hydrocortisone (HC), L-thyroxine (T4), and epidermal growth factor (EGF). Cardiac cells were grown on fibronectin-precoated plates using the above serum-free medium. Cells grown in this medium exhibited a higher beating rate and were maintained for a longer time compared to those cells grown in serum. The effects of T4, EGF, and HC on beating rate and survival time of both cultures of mixed cell population and enriched myoblast cell population were studied. In the enriched myoblast cell cultures grown in serum-supplemented medium, the beating rate ranged from 40 to 200 beats/min, and these cultures survived for 30 d. When these enriched cell cultures were grown in serum-free hormone-supplemented medium, the beating rate ranged from 190 to 240 beats/min, and these cultures survived for more than 90 d. These results show that some hormones affect growth, whereas others affect function.     

Hormonal regulation of DNA synthesis in primary cultures of adult rat hepatocytes : Action of glucagon

Primary cultures of adult rat hepatocytes, grown in modified minimal essential medium (Eagle's) containing 10% calf serum, could be induced into DNA replication by combinations of epidermal growth factor (EGF), insulin and glucagon. The three hormones acted synergistically, and cells began entering DNA synthesis 48 h after hormone addition. The ability of the hormones to stimulate DNA synthesis was enhanced by plating cells at high cell concentrations or by conditioned medium, and was diminished by daily medium change. The contribution of glucagon to DNA synthesis was replaced by cAMP plus 1-methyl, 3-isobutyl xanthine or by adrenergic agents. Evidence is presented which suggests that all three hormones are required on the first day of culture, and that EGF and insulin are also required after the first day. This appears to be a useful system for studies on the hormonal initiation of growth in quiescent cells.     

EGF-dependent epithelial cells of the mammary cell line HC11 demonstrate a high degree of synchronized cell cycle during stimulation with epidermal growth factor

The most popular object for studying endocytosis of EGF-receptor complexes, human epidermoid carcinoma A431, was shown to answer to EGF in high concentration (100 ng/ml) by growth inhibition, being indifferent to lower (0.1-1 ng/ml) concentrations. At the same time, cells NIH 3T3, expressing human EGF receptor (HER14), and epithelial mammary cells HC11 increased 14C-thymidine incorporation into DNA after EGF addition. However, for HER14 cells stimulatory effect of EGF was twice weaker than that induced by serum, whereas the effect of EGF on 14C-thymidine incorporation in DNA of cells HC11 was approximately 5 times stronger compared to serum. Therefore, cells HC11 may be referred to as EGF-dependent. Cell cycle analysis by fluorimetry showed that more than 90% of serum-starved HER14 and HC11 were in G0/G1. Within 19-20 h after stimulation by EGF 70-90% of HC11 cells and only 30-40% of HER14 cells were in S-phase. EGF removing from culture medium earlier than 9-11 h after stimulation blocked entering of HC11 cells into S-phase, whereas such EGF-dependent period was not found for cells HER14. Thus, synchronization of progression through early stages of cell cycle, stimulated by EGF and the presence of well defined "early" (EGF-dependent) and "late" (EGF-independent) phases, make cells HC11 convenient object for studying physiological role of EGF receptor complexes endocytosis.     

The seminiferous growth factor induces proliferation of TM4 cells in serum-free medium

The seminiferous growth factor (SGF) of the mammalian testes induces DNA synthesis and cell proliferation of Balb/c 3T3 cells (Bellvé and Feig, 1984; Rec Prog Hormone Res 40:531-567). In this study, SGF was purified 80,000- to 100,000-fold from calf testes and used to examine the growth of TM4 cells in a chemically defined medium. Cells were seeded sparsely in Dulbecco's Modified Eagles/Ham's F12 medium (1:1;v:v) (DME/F12 degrees), containing epidermal growth factor (EGF; 1 ng/ml), insulin (1; 10 micrograms/ml), and transferrin (Tr; 5 micrograms/ml) (DME/F12). After 24 h, the medium was replaced with DME/F12 degrees supplemented with SGF, EGF, 1, or Tr, in two-, three- or four-way combinations. Cell numbers were quantified after another 48 h of culture. EGF, I, and Tr, alone or in two-way combinations, were not mitogenic for TM4 cells. By contrast, SGF (1 U) alone, or with any two of these factors, stimulated TM4 cell proliferation to commensurate levels, and to twofold greater numbers than occurred with the combination of EGF, I, and Tr. Synergisms or inhibitions were not measurable. Follicle-stimulating hormone, luteinizing hormone, prolactin, acidic fibroblast growth factor, or basic fibroblast growth factor was weakly or not mitogenic for TM4 cells. The effect of SGF on cell proliferation was inhibited by 1 microM - 1 nM retinoic acid, but not by retinol or retinyl acetate. SGF was mitogenic for bovine adrenal capillary endothelial cells, an effect that was potentiated by 10 micrograms heparin/ml. Thus, SGF can induce proliferation of TM4 cells and capillary endothelial cells. The former provides a sensitive, and selective, serum-free, bioassay system for SGF activity.     

Growth factor control of myoepithelial-cell differentiation in cultures of human mammary gland

The relationship between growth and cytodifferentiation was studied in cultured human mammary myoepithelial cells under serum-free culture conditions. Myoepithelial-cell differentiation was monitored by quantifying cells showing immunoreactivity to the muscle isoform of actin; to the membrane glycoprotein common acute lymphoblastic leukemia antigen (CALLA); and to type IV collagen. Growth was quantified either by measuring the actual increase in cell number, or in a more-sensitive assay using immunoreactivity to the cell-proliferation-associated nuclear antigen Ki-67 as a measurement of the number of cells leaving the G0-phase of the cell cycle. The results showed that: (a) Primary cultures of myoepithelial cells on DME-F12 supplemented with cholera toxin (CT) alone resulted in the formation of quiescent cell islets (in the G0-phase of the cell cycle) showing phenotypic traits preserved from the in vivo situation (actin- and CALLA-positive cells with little or no type-IV-collagen immunoreactivity). (b) After addition of epidermal growth factor (EGF), with an ED50 of 1-10 ng/ml, in the presence of CT, the cells entered the G1-phase of the cell cycle, without further increase in cell number. At the same ED50 of EGF, the frequency of CALLA-positive cells decreased, while the number of cells immunoreactive for type IV collagen increased with a maximal effect of EGF seen after 7-11 days. During the same period, the cells remained fully differentiated with respect to actin immunoreactivity. (c) Further addition of insulin (I) to the medium in the presence of EGF and CT resulted in the cells entering an exponential growth phase associated with simultaneous decrease in actin immunoreactivity with a maximal effect of I after 11 days of exposure. The dose-response curve to I was virtually identical for stimulating cell proliferation and for reducing the frequency of actin-immunoreactive cells (ED50 in the range of 30 ng/ml), suggesting that the two processes were controlled by the same initial I-receptor interaction. (d) Some reduction in the number of actin-positive cells was exerted by I-EGF-CT independently of the mitogenic response, but this reduction was further augmented if the cells were allowed to proliferate. (e) Time-course studies of quiescent (G0-phase) cells stimulated to exponential growth revealed that entrance of cells into the G1-phase of the cell cycle preceded the loss of muscle actin filaments. (f) Exponentially growing actin-negative epithelial cells did not resume a myoepithelial phenotype in density-arrested postconfluent cultures.(ABSTRACT TRUNCATED AT 250 WORDS)     

Proliferation of guinea-pig uterine epithelial cells in serum-free culture conditions: effect of 17 beta-estradiol, epidermal growth factor and insulin

The effects of 17 beta-estradiol (E2), epidermal growth factor (EGF) and insulin, alone or in association on guinea-pig uterine epithelial cell proliferation were examined in serum-free culture conditions. Primary cultures of epithelial cells were made quiescent by serum depletion, then incubated in a chemically defined medium. In this medium, insulin increased DNA synthesis but not in a dose-dependent manner for concentrations ranging from 0.2 to 10 micrograms/ml. A significant effect of EGF was found only for the highest concentration tested (100 ng/ml). E2 alone or in the presence of insulin (1 microgram/ml) had no effect whatsoever on the concentration tested (10(-10)-10(-5)M). Insulin (10 micrograms/ml) plus EGF (100 ng/ml) exerted on DNA synthesis and cell proliferation a significant additive effect which was identical to the growth stimulation induced by 10% fetal calf serum. The effects of insulin plus EGF were not modified by the addition of E2. These findings suggest that E2 is not directly mitogenic for uterine epithelial cells in defined culture conditions and that the mitogenic response to optimal concentration of insulin plus EGF is independent of E2.