Christine M. Hughes

Immunocytochemical identification of cell types in human mammary gland: variations in cellular markers are dependent on glandular topography and differentiation.

Antiserum to epithelial membrane antigen and three monoclonal antibodies (MAb) to milk-fat globule membranes immunocytochemically stain only epithelial cells, whereas a fourth reacts also with myoepithelial cells in inter- and intralobular ducts of human breast. Staining with peanut lectin shows a gradual increase for epithelial cells, from little or no staining in ducts through variable staining in ductules to intense staining in secretory alveoli. Antisera and MAb to vimentin, smooth-muscle actin, MAb to the common acute lymphoblastic leukemia antigen and to a glycoprotein of 135 KD stain myoepithelial cells in main ducts, but this staining is reduced in inter- and intralobular ducts and ductules. MAb to epithelial-specific keratin 18 stain a minor population of ductal epithelial cells, the major population of epithelial cells in interlobular (ILD) and extralobular terminal ducts (ETD), and epithelial cells in a minority of ductules. In lactating glands most epithelial cells in ductules are stained, but the alveolar and myoepithelial cells are unstained. Keratin MAb PKK2 and LP34 strongly stain myoepithelial cells, but only a minor population of epithelial cells in main ducts. However, these MAb stain principally the epithelial cells in ILD, ETD, and a minority of ductules. In lactating glands most epithelial cells are stained in ductules, but the myoepithelial and not the alveolar cells are stained intensely in secretory lobules. It is suggested that the unusual staining pattern of cells found principally in the ILD, ETD, and some ductules may represent regions of growth and/or subpopulation(s) of cells intermediate between epithelial and myoepithelial cells.

Synthesis of basement membrane proteins by rat mammary epithelial cells

A mammary epithelial cell line, Rama 25, growing on plastic, deposits fibronectin, type IV collagen, and laminin in punctate structures located beneath the basal surface of the cells. When grown on the surface of collagen gels, Rama 25 cells deposit these basement membrane proteins in a continuous layer between the basal surface of the cells and the surface of the collagen matrix. Rama 25 cells also penetrate the collagen matrix forming rudimentary duct-like structures. These structures are surrounded by a discontinuous layer of basement membrane proteins. The ducts of fetal and neonatal rat mammary glands contain few mature myoepithelial cells and our results suggest that some mammary epithelial cells, in contact with a collagenous stroma, are capable of synthesizing a basal lamina-like structure.

Characterization of human mammary cell types in primary culture: Immunofluorescent and immunocytochemical indicators of cellular heterogeneity

SummaryParenchymal organoidal structures that were obtained from collagenase digestion of reduction mammoplasty specimens of apparently normal human breasts have been grown in short-term primary cultures, either on plastic or on floating gels of polymerized rat-tail collagen. Three morphologically distinct major cell types are readily observed in both systems: cuboidal cells, which occupy apical positions on collagen gels; larger, epithelioid, or basal cells on gels; and elongated cells which penetrate into the gel. In addition, a fourth cell type, that of a large, flat cell, is observed less readily by phase contrast microscopy on the surface of cultures grown on plastic. Immunofluorescent and immunocytochemical staining of cultures on plastic or histologic sections of cultures on gels have been undertaken with antisera and other histochemical reagents that stain the different parenchymal cell types in vivo. Thus antisera to epithelial membrane antigen(s), monoclonal antibodies (MABs) to the defatted mammary milk fat globule membrane, peanut lectin, and keratin MAB LE61, which preferentially stain the epithelial cells of ducts in vivo, also stain the cuboidal/apical cells in vitro. The large, flat cells are stained intensely by the first three reagents but not by the last one. Antisera to collagen IV, laminin, fibronectin, actin, keratin MAB LP34, MABs to the common acute lymphoblastic leukemia antigen, and MAB LICR-LON-23.10, which showed enhanced staining for the ductal myoepithelial cells in vivo, also stain the epithelioid/elongated cells in vitro. However, the effect of the last four reagents is reduced considerably in most elongated cells, and MAB LP34 stains the large, flat cells intensely. Heterogeneous cells of intermediate morphologies and staining patterns between the cuboidal/flat cells and large epithelioid cells have also been identified. The results suggest that the cuboidal cells and large, flat cells are related to mammary epithelial cells, whereas the large epithelioid/elongated cells have some characteristics of myoepithelial cells, and that intermediate forms may exist in culture between the two parenchymal cell types.

Abnormal deposition of basement membrane and connective tissue components in dimethylbenzanthracene-induced rat mammary tumours: an immunocytochemical and ultrastructural study.

SummaryDimethylbenzanthracene-induced rat mammary tumours consist of lobules of tumours cells surrounded by connective tissue. The interstitial connective tissue proteins, collagen types I, III and V, fibronectin and elastin are largely restricted to the interlobular connective tissue. The tumour lobules are surrounded by a basement membrane that stains with antiserum to laminin. Electron microscopy reveals a greatly thickened basement membrane to which striated interstitial collagen fibres are closely juxtaposed. The lumina within the tumour lobules are of two types. In the first type, the luminal surface is characterized by the presence of microvilli and tight junctions are reacts with antiserum to rat milk fat globule membrane. In the second type, the luminal surface is flattened and lined by a thickened basement membrane that stains with antiserum to laminin and type IV collagen. These abnormal patterns of growth and differentiation may be partly a consequence of the disorganization of extracellular matrix components at the interface between the tumour epithelial cells and the surrounding stroma.

Distribution and synthesis of type V collagen in the rat mammary gland

In the 100-day-old virgin and lactating rat mammary glands, type V collagen is mainly present in the interstitial connective tissue and in association with blood vessels. It is not present in the basement membrane region surrounding the ducts in mature virgin glands but is present in this region in neonatal and lactating glands. Ultrastructural localization of type V collagen reveals that it is mainly located on the basal surface (i.e., the surface in contact with the basement membrane) of epithelial but not myoepithelial cells. In addition, type V collagen is located on some interstitial collagen fibers and on a large number of granules that are in close proximity to the basal surface of both epithelial and myoepithelial cells. Immunofluorescence and biochemical studies indicate that several clonal mammary fibroblastic cell lines synthesize type V collagen in vitro. In some cell lines, type V collagen is secreted as an extensive fibrillar meshwork on the surface of the cells, whereas in other cell lines, it is secreted beneath the cells around their periphery. A number of mammary epithelial and myoepithelial-like cells, however, do not synthesize type V collagen in vitro.

Localization of vimentin in myoepithelial cells of the rat mammary gland

SummaryMyoepithelial cells in the virgin rat mammary gland have been shown to contain vimentin, using a polyclonal antiserum to vimentin purified from hamster fibroblasts. This antiserum has been shown to be specific for vimentin by immunoblotting and ELISA techniques. Similar results were obtained with a monoclonal antibody to vimentin. In the mammary glands of pregnant rats, the staining with vimentin antibodies is much weaker in the myoepithelial cells of the developing alveolar buds than in the main ducts. Similarly, in lactating glands, the staining of myoepithelial cells is much weaker in the secretory alveoli than in lactiferous sinuses. In each case, staining with antivimentin co-localizes with staining with polyclonal antisera to callous keratin (which specifically stain myoepithelial cells in the rat mammary gland).

Appearance of myoepithelial cells in developing rat mammary glands identified with the lectins Griffonia simplicifolia-1 and pokeweed mitogen.

The histochemical binding of peroxidase-conjugated Griffonia simplicifolia-1 (GS-1) and pokeweed mitogen (PWM) to methacarn-preserved and paraffin-embedded female rat mammary glands at different developmental stages has been undertaken with a view to investigating the ontogeny of the myoepithelial cell. Conjugated GS-1 fails to stain the outer layer of ductal cells in neonatal rats up to 3 days old, but thereafter the staining increases so that all such cells are intensely stained in rats 5 days old and in mature, pregnant, and lactating rats. Conjugated GS-1 also stains most of the inner epithelial cells that line the ducts in neonatal rats up to about 5 days after birth; thereafter no such cells are stained in mature, pregnant, and lactating rats. Conjugated PWM stains both the inner and outer cell layers of ducts in neonatal rats up to 5 days old; thereafter the fraction of strongly stained cells declines rapidly in both cell layers so that in 6-day-old rats only weak staining is visible. Staining with PWM continues to decline for the inner epithelial cells of the ducts until it ceases when the rats mature; in contrast, that for the outer cell layer of the ducts increases so that all such cells are stained intensely when the rats mature. This pattern of ductal staining with PWM is maintained for pregnant and lactating rats. In terminal end buds of mammary ducts of prepubertal rats, GS-1 binds mainly to the peripheral or cap cells, the staining intensity increasing from cap cells at the distal tip to myoepithelial cells of the subtending duct. PWM binds to many more of the cortical epithelial cells and fewer of the cap cells. At the ultrastructural level, cap cells and adjacent immature myoepithelial cells both bind GS-1 and PWM to their surfaces, but basal clear cells do not. In alveolar buds and in alveoli, both conjugated lectins GS-1 and PWM bind to myoepithelial cells but not to epithelial cells of the rat mammary gland. We suggest that the appearance of carbohydrate receptors for GS-1 and PWM marks specific stages of myoepithelial cell differentiation in developing rat mammary glands.

Immunocytochemical identification of myoepithelial cells in normal and neoplastic rat mammary glands with the lectins Griffonia simplicifolia-1 and pokeweed mitogen.

Peroxidase-conjugated Griffonia simplicifolia-1 (GS-1) and pokeweed mitogen (PWM) histochemically stain only the myoepithelial cells and not the epithelial or fibroblastic cells of rat mammary glands preserved in methacarn or glutaraldehyde and embedded in paraffin. This pattern of staining occurs in other rat exocrine glands except the pancreas, but is the reverse of that seen in most lining epithelium. The histochemical binding of GS-1 and PWM to myoepithelial cells is inhibited specifically by D-galactose and by polymers of N-acetylglucosamine, respectively. GS-1 and its subcomponent, GS-1-B4, also bind to extracellular structures similar to those stained by anti-laminin serum. At the ultrastructural level, both conjugated GS-1 and PWM bind to the plasma membrane of the myoepithelial cells, as well as to the adjacent basement membrane. Non-metastasizing rat mammary tumors produced by dimethylbenz[a]anthracene, by derivative epithelial stem-cell lines, and by a transplantable tumor all contain more elongated myoepithelium-like cells as well as cuboidal epithelium-like cells; both cell types are neoplastic. The more elongated myoepithelium-like cells are stained by GS-1 and PWM, whereas the cuboidal epithelium-like cells are unstained. Moderately and strongly metastatic rat mammary tumors produced by epithelial cell lines and by transplantable tumors, respectively, contain no such neoplastic cells that bind either lectin. We suggest that the carbohydrate receptors for GS-1 and PWM are consistent markers for the presence of the myoepithelial cell in normal and tumorous rat mammary glands.

Extracellular matrix control of collagen production by rat mammary epithelial and myoepithelial-like cells in vitro

A rat mammary myoepithelial cell line (Rama 401) grown on plastic produces 5 times more collagen (largely type IV) than a mammary epithelial cell line (Rama 704) grown on the same surface. When the cells are grown on collagen gels, the amount of collagen produced by Rama 704 cells increases 3.3 times, whereas there is no increase in collagen production by Rama 401 cells. Increased production of collagen by Rama 704 cells is due to both an increased rate of synthesis and a decreased rate of degradation. These results indicate that for mammary epithelial cells, unlike myoepithelial cells, the rate of production of collagen can be regulated by the extracellular matrix.