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.     

Hormone/growth factor interactions mediating epithelial/stromal communication in mammary gland development and carcinogenesis

Epithelial/mesenchymal interactions begin during embryonic development of the mammary gland and continue throughout mammary gland development into adult life. Stromal and epithelial growth factors that may mediate interactions between these compartments of the mammary gland are reviewed. Since mammogenic hormones are the primary regulators of mammary gland development, special consideration is given to hormonal regulation of growth factors in order to explore the integration of hormones and growth factors in the regulation of mammary gland growth and neoplasia. Examination of hormonal regulation of the fibroblast growth factor (FGF)-7/FGFR2-IIIb receptor system in the mammary gland reveals that mammogenic hormones differentially regulate the synthesis of stromal growth factors and their epithelial receptors. These effects serve to optimize the action of estrogen and progesterone on mammary gland development and illustrate that the ratio of these two hormones is critical in regulating this growth factor axis. The role of stromal/epithelial mitogenic microenvironments in modulating the genotype and phenotype of preneoplastic and neoplastic lesions by chemical carcinogens is discussed. Finally, changes in growth factor expression during mammary tumor progression are described to illustrate the relative roles that stromally-derived and epithelial-derived growth factors may play during progression to hormone independent tumor growth.     

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.     

Bovine placental lactogen stimulates DNA synthesis of bovine mammary tissue maintained in athymic nude mice

Mammary tissue from five midpregnant heifers was transplanted subcutaneously into ovariectomized athymic mice (eight pieces/mouse). After a recovery period of 19 days, mice were injected daily for 5 days with buffer (50 mM NH4HCO3, pH 7.8) as control, 17 beta-estradiol (1 micrograms) plus progesterone (1 mg). Concurrently with the buffer or steroid hormone injections, mice were injected with bovine placental lactogen (0, 5, or 25 micrograms), bovine prolactin (0, 3.4, or 17.2 micrograms), or bovine growth hormone (0, 3.4, or 17.2 micrograms). All mice were injected with 2-bromo-alpha-ergocryptine (0.1 mg/day). Transplanted bovine mammary tissue was incubated for 4 hr in minimum essential medium containing 1 mu Ci/ml [3H]TdR. Two pieces were processed for autoradiography and the others were used for DNA assay and total [3H]TdR uptake. Bovine placental lactogen, prolactin, and growth hormone each increased [3H]TdR incorporation into DNA in a linear, dose-response manner. Addition of ovarian steroids to bPL resulted in a significant increase over protein hormones alone. Autoradiographic analysis indicated that the observed differences in DNA synthesis were due to hormonal effects on epithelial, rather than stromal, DNA synthesis. These results provide the first evidence of a mammogenic role of bovine placental lactogen.     

Influence of melatonin on mammary gland growth: in vivo and in vitro studies

Our objective was to determine whether melatonin influenced mammary growth in response to mammogenic hormones. Prepubertal female BALB/c mice were injected for 9 days with 1 microgram of 17 beta-estradiol and 1 mg of progesterone or 17 beta-estradiol/progesterone plus 50, 100, or 200 micrograms of melatonin. Area of the parenchyma and total DNA content of the second thoracic gland were similar between controls and melatonin-injected mice. However, micrograms of DNA/100 mg of mammary tissue were lower in animals treated with 17 beta-estradiol/progesterone plus 200 micrograms of melatonin than in controls. Triglyceride content of mammary glands from animals treated with 100 or 200 micrograms of melatonin/day increased relative to controls. In an in vitro experiment, thoracic mammary glands of 21-day-old mice were cultured for 6 days in a mammogenic milieu of hormones (17 beta-estradiol/progesterone, aldosterone, bovine prolactin, growth hormone, and insulin) with 0 (control), 10(-6), 10(-9), or 10(-12) M melatonin. Relative to controls, 10(-12) M melatonin increased and 10(-6) M melatonin decreased mammary DNA and uptake of [methyl-3H]thymidine. We conclude that high doses of melatonin reduce mammary development in normal mice and that some of this effect may be mediated directly at the mammary tissue.     

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.     

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.     

A test for hormonal responsiveness in a mammary epithelial cell line, NMuMg

The NMuMG cell line derived from normal mouse mammary epithelial cells was tested for responsiveness to hormones. The hormones studied included insulin, glucocorticoids (cortisol and dexamethasone), and prolactin. In addition to membrane bound insulin receptors and prolactin receptors, the cells had 2 X 10(4) cytoplasmic glucocorticoid receptors per cell. Morphological changes were observed in response to hormones. Clusters of cells appeared with greatly increased diameter, and the number of cells per plate was reduced. The rate of DNA synthesis, corrected by cell number, indicates that cell division, and hence cell turnover, was increased by the combination of all three hormones. Insulin greatly enhanced protein synthesis, but glucocorticoid and prolactin did not further increase the rate. The combination of three hormones produced a change in the synthesis of histones, consistent with the increase in cell turnover. There were substantial responses of enzyme activities to hormonal treatment of the cells. Insulin by itself induced a doubling of the activity of glyceraldehyde phosphate dehydrogenase and perhaps a modest increase in NADH-cytochrome c reductase. Lactose synthetase activity showed a three- to fourfold induction of both A and B subunits of the enzyme when the cells were treated with insulin, glucocorticoid, and prolactin, and the effect of the latter two hormones was shown to be additional to that of insulin.     

Regulation of glycosylation-dependent cell adhesion molecule 1 (GlyCAM-1) gene in the mouse mammary gland differs from that of casein genes

Mouse glycosylation-dependent cell adhesion molecule 1 (GlyCAM-1), also known as mC26 and homologous to bovine PP3, is a milk protein synthesized in the mammary gland. Several studies have investigated the regulation of casein, the major milk protein, gene in the mammary gland, but little is known about GlyCAM-1. Here we examined GlyCAM-1 gene expression in mouse mammary epithelial cells. First, we detected GlyCAM-1 expression in mammary epithelial cells in situ by immunohistochemistry; almost all mammary epithelial cells of the lactating mouse expressed GlyCAM-1. Second, mammary epithelial cells were digested with collagenase and cultured with insulin, prolactin and/or glucocorticoid. alpha-Casein and beta-casein genes were expressed following treatment with insulin, prolactin and glucocorticoid. In contrast, GlyCAM-1 expression could not be detected with any combination of these three hormones. We also analyzed changes in the levels of GlyCAM-1 and caseins mRNAs in cultured cells. The addition of hormones to the culture medium increased casein mRNAs, but surprisingly reduced GlyCAM-1 mRNA. Our results suggest that the mechanisms that regulate GlyCAM-1 gene in mammary cells of lactating mice are different from those involved in the regulation of casein genes.     

Regulation and functional relevance of milk fat globules and their components in the mammary gland

Mammary gland and epithelial cells are unique to mammals and are under the control of lactogenic hormones such as prolactin. Recent findings indicated that major components of milk fat globule membrane (MFGM) are under the control of lactogenic hormones, and that the major components butyrophilin and xanthine oxidoreductase are indispensable for milk fat secretion. Further, prolactin signaling is negatively controlled by two highly related protein tyrosine phosphatases, PTP1B and TC-PTP. Milk fat globule EGF factor 8 (MFG-E8) is one of the major components of MFGM and is upregulated during lactation. MFG-E8 is further upregulated in the involuting mammary gland. MFG-E8 on exosome-like membrane vesicles in the milk recovered from post-weaning but not lactating mammary glands exhibits higher binding activity to phosphatidylserine and apoptotic mammary epithelial cells, and serves as a link between apoptotic mammary epithelial cells and phagocytes. Recent reports using MFG-E8 deficient mice support the view that MFG-E8 is indispensable for eliminating apoptotic mammary epithelial cells during involution.     

Super-active forms of placental lactogen and prolactin

Both placental lactogen and prolactin can be converted into super-active forms. These super-active hormones, in combination with insulin and hydrocortisone, stimulate accumulation of α-lactalbumin and increase RNA synthesis in explants from mouse mammary glands to an extent greater than the maximal level obtained with the native hormones. Also, they are able to stimulate RNA synthesis by suspensions of mammary epithelial cells which have lost the ability to respond to native lactogen and prolactin.     

A test for hormonal responsiveness in a mammary epithelial cell line,NMuMg

Summary The NMuMG cell line derived from normal mouse mammary epithelial cells was tested for responsiveness to hormones. The hormones studied included insulin, glucocorticoids (cortisol and dexamethasone), and prolactin. In addition to membrane bound insulin receptors and prolactin receptors, the cells had 2 × 10⁴ cytoplasmic glucocorticoid receptors per cell. Morphological changes were observed in response to hormones. Clusters of cells appeared with greatly increased diameter, and the number of cells per plate was reduced. The rate of DNA synthesis, corrected by cell number, indicates that cell division, and hence cell turnover, was increased by the combination of all three hormones. Insulin greatly enhanced protein synthesis, but glucocorticoid and prolactin did not further increase the rate. The combination of the three hormones produced a change in the synthesis of histones, consistent with the increase in cell turnover. There were substantial responses of enzyme activities to hormonal treatment of the cells. Insulin by itself induced a doubling of the activity of glyceraldehyde phosphate dehydrogenase and perhaps a modest increase in NADH-cytochromec reductase. Lactose synthetase activity showed a three- to fourfold induction of both A and B subunits of the enzyme when the cells were treated with insulin, glucocorticoid, and prolactin, and the effect of the latter two hormones was shown to be additional to that of insulin. This work was supported by Contract N01-CB-43866 from the National Cancer Institute, by Grants GB-38658 from the National Science Foundation and GMS-20338 from the National Institutes of Health, and by the Agricultural Experimental Station at the University of California.     

Prolactin and progesterone receptors in pregnancy-dependent mammary tumors in GR/A mice

In this study, cellular prolactin receptors and cytosolic progesterone receptors were examined and compared in pregnancy-dependent mammary tumors (PDMT) and in normal mammary glands of pregnant GR/A mice. PDMT and normal mammary glands were examined in the same animal, thus assuring an identical hormonal environment. The PDMT cells had a larger capacity to bind prolactin or the synthetic progesterone, R5020, than did the normal mammary gland. While the dissociation constant (Kd) value for prolactin binding to normal mammary epithelial cells was similar to that of PDMT cells, PDMT cells had 2.2 times more prolactin receptors than the normal cells. Progesterone binding activity was detected only in PDMT, but not in the normal mammary cells. The receptor concentration and the Kd value for progesterone binding of PDMT were 606 fmol/mg protein and 3.53 nM, respectively. It appears, therefore, that normal regulation of these receptors may be altered within the PDMT cells. The increased growth responsiveness of PDMT to the hormones of pregnancy, especially prolactin, progesterone, and placental lactogen, may be a function of a sharp increase in the level of cellular receptors for these mammotropic hormones.     

Alveolar progenitor cells develop in mouse mammary glands independent of pregnancy and lactation

We have previously described pluripotent, parity-induced mammary epithelial cells (PI-MEC) marked by Rosa26-lacZ expression in the mammary glands of parous females. PI-MEC act as lobule-limited epithelial stem/progenitor cells. To determine whether parity is necessary to generate PI-MEC, we incubated mammary explant cultures from virgin mice in vitro with insulin alone (I), hydrocortisone alone (H), prolactin alone (Prl), or a combination of these lactogenic hormones (IHPrl). Insulin alone activated the WAP-Cre gene. Hydrocortisone and prolactin alone did not. Any combination of hormones that included insulin was effective. Only I, H and Prl together were able to induce secretory differentiation and milk protein synthesis. In addition, EGF, IGF-2 and IGF-1 added individually produced activated (lacZ(+)) PI-MEC in explant cultures. Neither estrogen nor progesterone induced WAP-Cre expression in the explants. None of these positive initiators of WAP-Cre expression in PI-MEC were effective in mammospheres or two-dimensional cultures of mammary epithelium, indicating the indispensability of epithelial-stromal interaction in PI-MEC activation. Like PI-MEC, lacZ(+) cells from virgin explants proliferated and contributed progeny to mammospheres in vitro and to epithelial outgrowths in vivo after transplantation. LacZ(+) cells induced in virgin mouse mammary explants were multipotent (like PI-MEC) in impregnated hosts producing lacZ(+) mammary alveolar structures comprised of both myoepithelial and luminal progeny. These data demonstrate PI-MEC, a mammary epithelial sub-population of lobule-limited progenitor cells, are present in nulliparous female mice before parity and, like the PI-MEC observed following parity, are capable of proliferation, self-renewal and the capacity to produce progeny of diverse epithelial cell fates.     

The study of differentiative potential of the lactating mouse mammary gland in organ culture

The organ culture of the mammary gland of lactating mice was used to examine the response of the differentiated gland to lactogenic stimuli, insulin, cortisol, and prolactin. Time course studies showed that casein synthesis in cultured tissue decreased rapidly during the first 2 d despite the presence of the three hormones, but on the 3rd d tissue cultured with either insulin and prolactin or all three hormones regained the ability to synthesize milk proteins, casein, and alpha-lactalbumin: a greater increase occurred in the three hormone system. The delayed addition of prolactin on Day 2 to the culture system containing insulin and cortisol also stimulated casein synthesis. The addition of cytarabine, which inhibited insulin-dependent cell proliferation in cultured explants, did not block the rebound of milk protein synthesis. These results indicate that in the presence of insulin, cortisol, and prolactin mammary epithelial cells in culture first lose and then regain the ability of synthesizing milk protein without requiring the formation of new daughter cells.     

Effect of various lysosomotropic agents and microtubule disrupting drugs on the lactogenic and the mammogenic action of prolactin

Various drugs added to the culture medium of rabbit mammary gland were assayed for their capacity to affect the lactogenic and the mammogenic activities of prolactin. Three lysosomotropic agents NH4Cl, chloroquine and methylamine which were previously demonstrated to inhibit the degradation of the hormone-receptor complex after its internalization (down-regulation) did not prevent the initiation of casein synthesis, of lactose synthetase activity and of DNA synthesis. Five microtubule disrupting drugs, colchicine, colcemid, vinblastin, podophyllotoxin and nocodazole inhibited the induction of casein and DNA synthesis by prolactin whereas two inactive analogues, trimethylcolchicinic acid and lumicolchicine had no effect. None of these drugs exhibited any general cytotoxic effect as judged by the capacity of the tissue to incorporate 14C aminoacids into total proteins and 3H-uridine into total RNA. The microtubule disrupting drugs did not greatly reduce the rate of casein synthesis in the cultured mammary tissue explanted from lactating rabbits. The data suggest that the down-regulation of prolactin receptor is not strictly required for the two considered prolactin activities. By contrast, the integrity of microtubules, or at least of structures in which tubulin is involved, is necessary to ensure a normal transmission of the prolactin information responsible for the initiation of milk and DNA synthesis. In addition, the fact that the lactogenic and the mammogenic activities of prolactin are affected by the same drugs suggests that these two properties of the hormone are mediated by cellular mechanisms which have at least one common step.     

Morphology and lactose synthesis in tissue culture of mammary alveoli isolated from lactating mice

Summary Mammary epithelial cells from lactating mice synthesize and secrete lactose in culture and retain many features of their in vivo morphology if mammary glands are only partially dissociated to alveoli, rather than completely dissociated to single cells. After 5 d in culture lactose synthesis by alveoli cultured on floating collagen gels is 10 to 20 times higher than in cultures of single cells on floating collagen gels. Moreover, mammary alveoli in culture retain sensitivity to lactogenic hormones; the synthesis of lactose by alveoli depends on the continued presence of insulin and either hydrocortisone or prolactin. In addition, within alveoli the original juxtaposition of constituent epithelial cells is retained, and cells are cuboidal and have many microvilli and fat droplets. In contrast, alveoli on attached gels flatten and lose their secretory morphology. These results indicate that the shape of the cells, presence of lactogenic hormones, and maintenance of epithelial:epithelial cell contacts are required for maintenance of mammary epithelial cell differentiation in culture. This research was supported by Grants CA-16392 and AG-02909 from the National Institutes of Health and Institutional Grant IN 119 from the American Cancer Society.     

Inhibition by progesterone of the lactogenic effect of prolactin in the pseudopregnant rabbit.

The effects of progesterone on lactose synthesis activity and changes in mammary gland cells were studied in pseudopregnant rabbits simultaneously treated with prolactin. The injection of progesterone alone on Days 15 and 17 of pseudopregnancy decreased the activity of lactose synthetase (LSA) and galactosyl transferase (GTA), while the administration of prolactin for 2-4 days increased their activities. Th e simultaneous administration of progesterone and prolactin decreased the increase in LSA observed with prolactin alone by 70% on the 4th day of treatment, and decreased GTA by 30%. Progesterone completely suppressed the polyribosome profile and the ratio of endoplasmic reticulum bound polyribosomes to free polyribosomes induced by prolactin. The increase in RNA content in the mammary gland induced by prolactin was also suppressed by progesterone. The results suggest that progesterone inhibits the lactogenic action of prolactin without interfe ring with its mammogenic role.     

A direct effect of prolactin and placental lactogen on mammary epithelial nuclei

Placental lactogen and prolactin stimulate the rate of RNA synthesis by nuclei isolated from mammary epithelial cells. The effect is tissue specific. It is suggested that these protein hormones may perform some of their functions within the mammary cell.