Cytogenesis of murine mammary tumors in BALB/cfC3H and BALB/cfRIII strains

Biological and morphological differences in the mammary tumors of BALB/cfC3H and BALB/cfRIII mice are due to differences in the causative viruses. The C3H and RIII variants of the murine mammary tumor virus (MuMTV) might give origin to different mammary tumors by transforming different types of cell, i.e. epithelial or myoepithelial cells. The nature (epithelial or myoepithelial) of the neoplastic cells has been investigated by demonstrating their plasma membrane ATPase activities. We found that in normal murine mammary gland both epithelium and myoepithelium have Mg++ dependent ATPase activity, while the myoepithelium shows in addition an Na+K+ dependent ATPase activity. It is suggested that the results obtained exclude the participation of myoepithelium to the neoplastic growth and we ascribe the differences in mammary tumors of the two strains of mice to differences in the mechanisms of action of the virus variants.     

Dual secretory and myoepithelial differentiation in the transplantable R3230AC rat mammary carcinoma

The hormone-responsive R3230AC mammary carcinoma, serially transplantable in Fisher rats, shows striking functional and morphological similarities to the normal mammary gland. We have studied its cellular composition by both light and electron microscopy, employing markers of myoepithelial and epithelial cells. We identified two cell types: the major cellular component corresponded to epithelial milk-protein secreting cells, while a second component showed immunocytochemical and ultrastructural characteristics of the myoepithelial cells. These cells were positive with a monoclonal antibody detecting alpha smooth muscle actin. The dual differentiation which normally occurs in breast ducts is therefore reproduced in a malignant experimental tumor. The coexistence of neoplastic cell populations, divergent in morphology and function, that persist in a tumor despite many transplant generations, leads to reconsideration of the relationship between cellular differentiation and malignant transformation.     

Alterations in the expression and localization of protein kinase C isoforms during mammary gland differentiation.

Protein kinase C (PKC) is involved in signaling that modulates the proliferation and differentiation of many cell types, including mammary epithelial cells. In addition, changes in PKC expression or activity have been observed during mammary carcinogenesis. In order to examine the involvement of specific PKC isoforms during normal mammary gland development, the expression and localization of PKCs alpha, delta, epsilon and zeta were examined during puberty, pregnancy, lactation, and involution. By immunoblot analysis, expression of PKC alpha, delta, epsilon and zeta proteins was increased in mammary epithelial organoids during the transition from puberty to pregnancy. In mammary gland frozen sections, PKCs alpha, delta, epsilon and zeta were stained in the luminal epithelium and myoepithelium, in varying isoform-and developmental stage-specific locations. PKC alpha was found in a punctate apical localization in the luminal epithelium during pregnancy. During lactation, PKC epsilon was present in the nucleus, and PKC zeta was concentrated in the subapical region of the luminal epithelium. Additionally, marked staining for PKCs alpha, delta, epsilon, and zeta was observed in the myoepithelial cells at the base of ducts and alveoli. This basal ductal and alveolar staining differed in intensity in a developmentally-specific fashion. During most time points (virgin, pregnant, lactating, and early involution), myoepithelial cells of the duct were more intensely stained than those lining the alveoli for PKCs alpha, delta, epsilon and zeta. During late involution (days 9-12), the preferential staining of ducts was lost or reversed, and the myoepithelial cells lining the regressing alveolar structures stained equally (PKCs epsilon and zeta) or more intensely (PKCs alpha and delta), coincident with the thickening of the myoepithelial cells surrounding the regressing alveoli. The increased PKC isoform staining at the base of alveoli during involution suggests that alveolar regression may be influenced by alterations in signaling in the alveolar myoepithelium.     

Organotypic growth and differentiation of human mammary gland in sponge-gel matrix supported histoculture

Summary Blocks of breast tissue obtained during radical mastectomies from 23 patients with mammary gland carcinomas were used for cultivation in native-state, gel-supported histocultures. We show that the human mammary gland can be successfully maintained in this system so that normal epithelial breast structures proliferate and undergo differentiation for several weeks and a well-developed system of ducts and lobules is formed. Using antibodies to individual keratins 17 and 8 we have shown for the first time that ducts and alveoles developing in vitro undergo differentiation into the lining epithelium and myoepithelium in the same way as mammary gland epithelium in vivo. Growth of epithelial structures in vitro is also accompanied by the development of continuous basal membrane.     

Characterization of breast carcinomas by two monoclonal antibodies distinguishing myoepithelial from luminal epithelial cells

Two monoclonal antibodies, KA 1 and KA 4, raised against human epidermis, were biochemically and immunologically characterized and were shown to react with specific cytokeratin polypeptides. On frozen sections of human mammary gland, these antibodies distinguish between myoepithelial and luminal epithelial cells. We present evidence that in these cells KA 1 antibody recognized cytokeratin 5 and KA 4 antibody cytokeratin 19. In normal mammary tissue, KA 4 antibody invariably reacted with the epithelial cells lining the lumina of acini, ductules, ducts, and sinus. In contrast, KA 1 antibody decorated only the myoepithelial and basal epithelial cells of acini, ducts, and sinus. In ductules, however, KA 1 also stained the luminal cells. All 73 invasive lobular and ductal carcinomas studied reacted with KA 4 antibody; five of these were also positive, apparently in the same tumor cells, with KA 1. The tumor cells of in situ carcinomas were also stained in a homogeneous pattern with KA 4 antibody; KA 1 antibody reacted only with the surrounding myoepithelium. In epithelial hyperplasias, the proliferating cells were decorated by KA 1 and KA 4 antibodies in a heterogeneous pattern. Other antibodies were used for comparison. The results are discussed with respect to epithelial differentiation and pathogenesis and to the application of such antibodies for immunohistodiagnosis of mammary lesions.     

Localization of metallothionein in female reproductive organs of rat and guinea pig

We demonstrated the localization of metallothionein (MT) in rat uterus and ovaries and in guinea pig mammary glands. During the cyclic changes from one estrous period to the next, strong MT immunostaining was found in the glandular epithelium of the endometrium and weak immunostaining was observed in the simple columnar epithelium. Interestingly, during estrus, the intensity of MT immunostaining decreased in the cytoplasm, whereas during metestrus, diestrus, and proestrus the intensity of strong and similar immunostaining was observed in both the cytoplasm and nucleus. During proestrus and estrus, the number of vaginal epithelial cells containing MT increased on the luminal side of the epithelium and inside the lumen. In rat ovary, strong immunostaining was observed in the cytoplasm and nucleus of granulosa-lutein cells of the corpus luteum and in the cytoplasm of the ovum. In mammary gland of non-pregnant guinea pig, very strong but scattered MT immunostaining was demonstrated in both cytoplasm and nucleus of some epithelial cells of the lactiferous ducts. The mammary tissue of the pregnant guinea pig showed an increase in MT staining in alveolar cells that had proliferated due to pregnancy. The presence of MT in the female reproductive organs, the tissues of which actively grow under the control of female sex hormones, indicates some as yet unknown association of MT with cell proliferation and differentiation.     

Connexins and Gap Junctions in Mammary Gland Development and Breast Cancer Progression

The development and function of the mammary gland require precise control of gap junctional intercellular communication (GJIC). Here, we review the expression and function of gap junction proteins, connexins, in the normal mouse and human mammary gland. We then discuss the possible tumor-suppressive role of Cx26 and Cx43 in primary breast tumors and through the various stages of breast cancer metastasis and consider whether connexins or GJIC may actually promote tumorigenesis at some stages. Finally, we present in vitro data on the impact of connexin expression on breast cancer cell metastasis to the bone. We observed that Cx43 expression inhibited the invasive and migratory potentials of MDA-MB-231 breast cancer cells in a bone microenvironment, provided by the MC3T3-E1 mouse osteoblastic cell line. Expression of either Cx26 or Cx43 had no effect on MDA-MB-231 growth and adhesion under the influence of osteoblasts and did not result in regulation of osteogenic gene expression in these breast cancer cells. Furthermore, connexin-expressing MDA-MB-231 cells did not have an effect on the growth or differentiation of MC3T3-E1 cells. In summary, we conclude that connexin expression and GJIC are integral to the development and differentiation of the mammary gland. In breast cancer, connexins generally act as tumor suppressors in the primary tumor; however, in advanced breast tumors, connexins appear to act as both context-dependent tumor suppressors and facilitators of disease progression.     

Differential expression of annexins I and II in normal and malignant human mammary epithelial cells

Abstract. Collagen-binding proteins ( CBPs ) of rat mammary tumors are identical to Ca²⁺-binding annexins [49]. We have now isolated a protein of 38 kDa from the human mammary tumor cell line ALAB by collagen type I affinity chromatography as well as by extraction of calcium-binding proteins. The 38-kDa band of both preparations was identified as annexin II (calpactin I) by its reaction with an annexin II-specific monoclonal antibody in Western blot analysis. Annexin I (lipocortin I) was not detectable in these cells. Two other human cell lines, the SV40-transformed cell line SV3 and cell line HBL-100, both established from normal mammary glands, were also positive for annexin II and negative for annexin I.
In vivo expression of annexins was investigated by immunohistological staining of normal and malignant human mammary tissue. The annexin II-specific mAb reacted with normal and tumor parenchyme whereas the annexin I-specific mAb reacted with acini and ductal myoepithelium of the normal mammary gland but showed no reaction with tumor tissue. Immunolocalization studies also showed annexin II expression in both normal and tumor stroma while only tumor stromal cells were found to be reactive with the antibody against annexin I. The differential expression of annexins in normal and malignant human mammary tissue suggests special functions of these proteins in the mammary gland.     

Use of peanut lectin and rat mammary stem cell lines to identify a cellular differentiation pathway for the alveolar cell in the rat mammary gland.

The presence of the carbohydrate receptor for PNL has been used to identify the previously described morphological types of epithelial cell produced as the stem cell line rat mammary 25 (Rama 25) differentiates to casein secretory alveolar-like cells in vitro. Thus when cultures of the epithelial stem cell line Rama 25 are treated with neuraminidase, fluorescently-conjugated PNL fails to stain cuboidal cells, stains weakly grey cells, and stains strongly the surface of dark cells. When superconfluent cultures of Rama 25 are treated with dimethyl sulfoxide or retinoic acid and prolactin, estradiol, hydrocortisone, and insulin to induce differentiation to alveolar cells, PNL stains strongly the untreated surfaces of droplet cells and casein-secreting vacuolated cells. PNL-staining of the derivative cell lines with truncated cellular pathways, and quantitative binding of [125I]-labeled PNL to the cultured cells are consistent with this cellular staining pattern. The presence of the carbohydrate receptor for peanut lectin (PNL) has also been used to identify specific epithelial cell types in different mammary structures of the developing rat mammary gland, as they differentiate to casein secretory alveolar cells in vivo. Thus when different structures of the developing rat mammary gland are treated with neuraminidase, peroxidase-conjugated PNL fails to stain histochemically the majority of epithelial cells in ducts, stains the cytoplasm of the majority of epithelial cells in terminal end-buds (TEBs), and stains strongly the luminal surfaces of the majority of epithelial cells in alveolar buds (ABs). PNL also stains the untreated luminal surfaces of alveolar cells, whether or not the cells can be stained with a monoclonal antibody to rat beta-casein. Stimulation of mammary differentiation by an analogue of ethyl retinoate or by perphenazine causes cells in end-buds to bind PNL without the necessity for their desialylation similar to that seen in casein secretory alveoli of lactating rats. In conclusion the different interconverting cell types of Rama 25 which form a pathway to casein-secretory cells in vitro are thus equated with recognisable epithelial cell types in vivo. These results suggest that casein-secretory cells in vivo are generated by similar successive interconversions between the major epithelial cell types present in the different mammary structures in the order: ducts, TEBs, ABs, alveoli, and secretory alveoli.     

The Role of the Microenvironment in Mammary Gland Development and Cancer

The mammary gland is composed of a diverse array of cell types that form intricate interaction networks essential for its normal development and physiologic function. Abnormalities in these interactions play an important role throughout different stages of tumorigenesis. Branching ducts and alveoli are lined by an inner layer of secretory luminal epithelial cells that produce milk during lactation and are surrounded by contractile myoepithelial cells and basement membrane. The surrounding stroma comprised of extracellular matrix and various cell types including fibroblasts, endothelial cells, and infiltrating leukocytes not only provides a scaffold for the organ, but also regulates mammary epithelial cell function via paracrine, physical, and hormonal interactions. With rare exceptions breast tumors initiate in the epithelial compartment and in their initial phases are confined to the ducts but this barrier brakes down with invasive progression because of a combination of signals emitted by tumor epithelial and various stromal cells. In this article, we overview the importance of cellular interactions and microenvironmental signals in mammary gland development and cancer.The mammary gland is composed of a combination of multiple cell types that together form complex interaction networks required for the proper development and functioning of the organ. The branching milk ducts are formed by an outer myoepithelial cell layer producing the basement membrane (BM) and an inner luminal epithelial cell layer producing milk during lactation. The ducts are surrounded by the microenvironment composed of extracellular matrix (ECM) and various stromal cell types (e.g., endothelial cells, fibroblasts, myofibroblasts, and leukocytes). Large amount of data suggest that cell-cell and cell-microenvironment interactions modify the proliferation, survival, polarity, differentiation, and invasive capacity of mammary epithelial cells. However, the molecular mechanisms underlying these effects are poorly understood. The purification and comprehensive characterization of each cell type comprising normal and neoplastic human breast tissue combined with hypothesis testing in cell culture and animal models are likely to improve our understanding of the role these cells play in the normal functioning of the mammary gland and in breast tumorigenesis. In this article, we overview cellular and microenvironmental interactions that play important roles in the normal functioning of the mammary gland and their abnormalities in breast cancer.     

Ultrastructural characteristics of the parenchymatous cells in breast cancer

Electron microscopy was used to examine ultrastructure of parenchymatous cells of lobular mammary carcinoma and preservation of an ability of these cells to organ specificity. Ultrastructural characteristics of the cells of intact mammary gland lobules and parenchymatous cells of infiltrative carcinoma were studied and compared. It was shown that lobular mammary carcinoma has dissimilar cellular composition. It is represented by the cells with ultrastructural features characteristic for the three cell types occurring in the intact mammary gland (secretory epithelium, myoepithelium and cambial cells). As regards ultrastructure, parenchymatous cells of lobular mammary carcinoma, like the cells of the normal lobule, are at varying levels of differentiation and in diverse phases of the functional status.     

Expression and function of CCAAT/enhancer binding proteinbeta (C/EBPbeta) LAP and LIP isoforms in mouse mammary gland, tumors and cultured mammary epithelial cells

CCAAT/Enhancer binding proteins (C/EBPs) play important roles in the regulation of cell growth and differentiation. This study investigated the expression and function of C/EBPbeta isoforms in the mouse mammary gland, mammary tumors, and a nontransformed mouse mammary epithelial cell line (HC11). C/EBPbeta mRNA levels are 2-5-fold higher in mouse mammary tumors derived from MMTV/c-neu transgenic mice compared with lactating and involuting mouse mammary gland. The "full-length" 38 kd C/EBPbeta LAP ("Liver-enriched Activator Protein") isoform is the predominant C/EBPbeta protein isoform in mammary tumor whole cell lysates, however, the truncated 20 kd C/EBPbeta LIP ("Liver-enriched Inhibitory Protein") isoform is also present at detectable levels (mean LAP:LIP ratio 5.3:1). The mammary tumor C/EBPbeta LAP:LIP ratio decreases 70% (from 5.3:1 to 1.6:1) when lysate preparation is switched from a rapid whole cell lysis protocol to a multistep nuclear/cytoplasmic fractionation protocol. In contrast to mammary tumors, only the C/EBPbeta LAP isoform is detectable in the mammary gland whole cell and nuclear lysates; the truncated "LIP" isoform is undetectable regardless of isolation protocol. Ectopic over expression of C/EBPbeta LIP or C/EBPbeta LAP did not alter HC11 growth rates. However, C/EBPbeta LIP over expressing HC11 cells (LAP:LIP ratio of approximately 1:1) exhibited a consistent 2-4 h delay in G(0)/S phase transition. C/EBPbeta LIP overexpressing HC11 cells did not express beta-casein mRNA (mammary epithelial cell differentiation marker) in response to lactogenic hormones. This defect in beta-casein expression was not corrected by carrying out the differentiation protocol in the presence of an artificial extracellular matrix. These results demonstrate that the "full-length" C/EBPbeta LAP isoform is the predominant C/EBPbeta protein isoform expressed in mouse mammary gland in vivo and mouse mammary epithelial cell cultures in vitro. C/EBPbeta LIP detected in mammary tumor lysates may result from in vivo production or ex vivo isolation-induced proteolysis of C/EBPbeta LAP. Ectopic overexpression of C/EBPbeta LIP (LAP:LIP ratio of approximately 1:1) inhibits mammary epithelial cell differentiation (beta-casein expression).     

Cytogenesis of murine mammary tumors in BALB/cfC3H and BALB/cfRIII strains

Summary Biological and morphological differences in the mammary tumors of BALB/cfC3H and BALB/cfRIII mice are due to differences in the causative viruses. The C3H and RIII variants of the murine mammary tumor virus (MuMTV) might give origin to different mammary tumors by transforming different types of cell, i.e. epithelial or myoepithelial cells. The nature (epithelial or myoepithelial) of the neoplastic cells has been investigated by demonstrating their plasma membrane ATPase activities. We found that in normal murine mammary gland both epithelium and myoepithelium have Mg⁺⁺ dependent ATPase activity, while the myoepithelium shows in addition an Na⁺ K⁺ dependent ATPase activity. It is suggested that the results obtained exclude the participation of myoepithelium to the neoplastic growth and we ascribe the differences in mammary tumors of the two strains of mice to differences in the mechanisms of action of the virus variants.Supported by contract No. 79.00431.84 from the National Research Council, Rome, Progetto Finalizzato CNR Virus     

Noradrenergic and peptidergic innervation of the mammary gland in the immature pig

The presence and pattern of coexistence of some biologically active substances in nerve fibres supplying the mammary gland in the immature pig were studied using immunohistochemical methods. The substances studied included: protein gene product 9.5 (PGP), tyrosine hydroxylase (TH), somatostatin (SOM), neuropeptide Y (NPY), galanin (GAL), calcitonin gene-related peptide (CGRP) and substance P (SP). The mammary gland was found to be richly supplied by PGP-immunoreactive (PGP-IR) nerve fibres that surrounded blood vessels, bundles of smooth muscle cells and lactiferous ducts. The vast majority of these nerves also displayed immunoreactivity to TH. Immunoreactivity to SOM was observed in a moderate number of nerve fibres which were associated with smooth muscles of the nipple and blood vessels. Immunoreactivity to NPY occurred in many nerve fibres associated with blood vessels and in single nerves supplying smooth muscle cells. Solitary GAL-IR axons supplied mostly blood vessels. Many CGRP-IR nerve fibres were associated with both blood vessels and smooth muscles. SP-IR nerve fibres richly supplied blood vessels only. The colocalization study revealed that SOM, NPY and GAL partly colocalized with TH in nerve fibres supplying the porcine mammary gland.     

Precocious Mammary Gland Development in P-Cadherin–deficient Mice

To investigate the functions of P-cadherin in vivo, we have mutated the gene encoding this cell adhesion receptor in mice. In contrast to E- and N-cadherin– deficient mice, mice homozygous for the P-cadherin mutation are viable. Although P-cadherin is expressed at high levels in the placenta, P-cadherin–null females are fertile. P-cadherin expression is localized to the myoepithelial cells surrounding the lumenal epithelial cells of the mammary gland. The role of the myoepithelium as a contractile tissue necessary for milk secretion is clear, but its function in the nonpregnant animal is unknown. The ability of the P-cadherin mutant female to nurse and maintain her litter indicates that the contractile function of the myoepithelium is not dependent on the cell adhesion molecule P-cadherin. The virgin P-cadherin–null females display precocious differentiation of the mammary gland. The alveolar-like buds in virgins resemble the glands of an early pregnant animal morphologically and biochemically (i.e., milk protein synthesis). The P-cadherin mutant mice develop hyperplasia and dysplasia of the mammary epithelium with age. In addition, abnormal lymphocyte infiltration was observed in the mammary glands of the mutant animals. These results indicate that P-cadherin–mediated adhesion and/or signals derived from cell–cell interactions are important determinants in negative growth control in the mammary gland. Furthermore, the loss of P-cadherin from the myoepithelium has uncovered a novel function for this tissue in maintaining the undifferentiated state of the underlying secretory epithelium.     

Transforming growth factor-beta signaling helps specify tumor type in DMBA and hormone-induced mammary cancers

To determine the role of transforming growth factor-beta (TGF-beta) signaling in mammary development and tumor formation, we previously generated transgenic mice that expressed a dominant-negative form of the TGF-beta type II receptor (DNIIR) under the control of DNA regulatory elements from the metallothionein promoter (MT-DNIIR-28). In this report, we tested the hypothesis that loss of TGF-beta signaling in the mammary gland alters the development of chemically or hormonally induced tumors in mice. Four groups of mice were used in the study: wild-type and MT-DNIIR-28 mice on zinc with pituitary isograft, and wild-type and MT-DNIIR-28 mice on zinc with pituitary isograft treated with the carcinogen, 7,12-dimethylbenz[a]anthracene (DMBA). Tumor-free survival over time, tumor growth rate, and tumor pathology were measured. Statistically significant differences in tumor free survival over time or tumor growth rate were not detected in wild-type versus transgenic mice treated with DMBA. In contrast, tumor-free survival was significantly altered in transgenic mice that were treated with the pituitary isograft alone with MT-DNIIR mice developing tumors more quickly. Alterations in the types of tumors that formed in wild-type versus MT-DNIIR DMBA-treated mice were detected. In wild-type mice, tumors with squamous differentiation or bicellular adenomyoepitheliomas were most common. Adenomyoepitheliomas were not detected in transgenic mice. Furthermore, there was reduced staining for alpha smooth muscle actin and keratin 14, markers for myoepithelial cells, in the glandular portion of tumors in transgenic mice. The pathology of tumors induced by pituitary isograft alone was also markedly different in wild-type and transgenic mice. All the tumors classified from wild-type mice demonstrated some form of squamous differentiation, whereas squamous differentiation was not detected in the pituitary-induced transgenic tumors. The results suggest that TGF-beta acts as a tumor suppressor for hormone-induced cancers and that TGF-beta has a role in determining tumor pathology by regulating myoepithelial or squamous differentiation, maintenance, or transformation.     

Epithelial induction of stromal tenascin in the mouse mammary gland: from embryogenesis to carcinogenesis

The distribution of the extracellular matrix glycoprotein tenascin was studied by immunofluorescence in the developmental history of the mouse mammary gland from embryogenesis to carcinogenesis. Tenascin appeared only in the mesenchyme immediately surrounding the epithelia just starting morphogenesis, that is, in embryonic mammary glands from 13th to 16th day of gestation, in mammary endbuds which are a characteristic structure starting development during maturation of the mammary gland, and in the stroma of malignant mammary tumors. However, tenascin was absent in the elongating ducts of embryonic, adult, proliferating, and involuting mammary glands and preneoplastic hyperplastic alveolar nodules. The transplantation of embryonic submandibular mesenchyme into adult mammary glands induces the development of duct-alveolus nodules, which morphologically resemble developing endbuds. Tenascin reappeared around those nodules during the initial stages of their development. Tenascin expression could be induced experimentally in several ways. First, tenascin was detected at the site where the first mammary tumor cells GMT-L metastasized. Second, tenascin was detected in the connective tissue in the tumors derived from the injected C3H mammary tumor cell line CMT315 into Balb/c nude mouse. Cross-strain marker anti-CSA antiserum clearly showed that the tenascin-positive fibroblasts were of Balb/c origin. Third, when embryonic mammary epithelium was explanted on to embryonic mammary fat pad cultures, the mesenchymal cells condensed immediately surrounding the epithelium. Tenascin was detected in these condensed cells. From these three observations we conclude that both embryonic and neoplastic epithelium induced tenascin synthesis in their surrounding mesenchyme.     

Immunocytochemical identification of proliferating cell types in mouse mammary gland

To study cell proliferation in different cell types and segments of the mammary gland, we devised a dual staining procedure, combining nuclear labeling by 5-bromo-2'-deoxy-uridine (BrdU) uptake (revealed by a dark-brown precipitate) and an alternative (red or blue) cytoplasmic labeling by antibodies specific for the differentiation proteins of epithelial, myoepithelial, and secretory cell types. The following markers, revealed by APAAP or beta-galactosidase procedure, were selected: alpha-smooth muscle actin for the myoepithelial cells, keratin (detected by AE1 monoclonal) for the luminal epithelial cells, alpha-lactalbumin and beta-casein for the secretory cells. To follow the full process of organogenesis, the study was conducted in mouse mammary glands from virgin, primed, and lactating animals and from glands cultured in vitro under specific hormone stimulation. Cell proliferation was localized mainly in focal areas (end buds), and mostly corresponded to "null" undifferentiated cells. Estrogen and progestin stimulation induced a relative increase of proliferating differentiated cells of either epithelial or myoepithelial type, localized in ducts and alveolar structures. Prolactin stimulation induced proliferation in secretory cells.     

Establishment and initial characterization of the ovine mammary epithelial cell line nish

Summary Analysis of the molecular mechanisms involved in the differentiation and formation of the characteristic three-dimensional structures of the developing mammary gland of the major milk-producing livestock (ducts, end buds, and alveoli) requires in vitro model cell cultures. The few cell lines that have been established from dairy animals do not fully reproduce the entire program of mammary differentiation. Here we present the initial characterization of a unique mammary epithelial cell line derived spontaneously from midpregnant sheep (NISH). These cells form in vitro functional structures resembling ducts, lateral buds, and alveoli that secrete β-lactoglobulin (BLG) in an ECM (extracellular matrix)-dependent manner. Interestingly, the presence of growth hormone dramatically increased BLG secretion from NISH cells cultured on ECM. It appears that GH is required not only to establish the structural organization but also is continuously needed to maintain BLG expression. Stable transfection of NISH cells with BLG/Human Serum Albumin (HSA) hybrid gene constructs revealed that the relative level of expression was comparable to the in vivo secretion of HSA in transgenic mice carrying these gene sequences. No expression could be detected in cells transfected with hybrid genes carrying either HSA cDNA or the entire HSA gene, and HSA expression was dependent on the presence of intronic sequences. These results demonstrate that NISH cells may prove a useful tool for studying the differentiation and organogenesis of mammary epithelial cells under defined culture conditions. Furthermore, transfected NISH cells may be an alternative for the transgenic mouse model in evaluating the potential of gene constructs to be efficiently expressed in the mammary gland of transgenic farm animals.