Characterisation of chondroitin/dermatan sulphate proteoglycans synthesised by rat mammary myoepithelial and fibroblastic cell lines.

Chondroitin sulphate proteoglycans were isolated from the culture medium of rat mammary gland fibroblast (Rama 27) and myoepithelial (Rama 401) cell lines which had been labelled with [35S]sulphate. Chromatography on Sepharose CL-4B indicated that the Rama 401 proteoglycan was larger than the Rama 27 proteoglycan (Kav values 0.47 and 0.56, respectively). Treatment of the proteoglycans with alkaline NaBH4 yielded chondroitin sulphate chains with average M(r) values of 37,000 (Rama 401) and 21,000 (Rama 27). Structural analysis of the glycosaminoglycan chains indicated that both were co-polymers of chondroitin and dermatan sulphate although there were differences in the amounts and distribution of the disaccharide repeating units. The M(r) values of the core proteins, determined by immunoblotting, were about 43,000 and 46,000 (Rama 27) and 44,500 (Rama 401). Using an antibody to chondroitin sulphate proteoglycan in immunofluorescence experiments, the proteoglycan was demonstrated on the surface of both cell lines. Rama 27 cells additionally possessed an extensive fibrous extracellular matrix which also stained with the antibody. Staining of sections of lactating mammary gland suggested that the proteoglycan was present in the basement membrane as well as the stromal connective tissue. The presence of chondroitin sulphate proteoglycan in the basement membrane was confirmed by ultrastructural immunolocalisation.

Role of fibronectin in the organisation of the cytoskeleton during the spreading of rat mammary epithelial cells.

The correlation between the extracellular deposition of fibronectin and the development of the actin-containing cytoskeleton was studied during the attachment and spreading of the rat mammary epithelial cell line Rama 25. During the initial phase of cell spreading, actin is localised in peripheral microfilament bundles. As cell spreading increases, the peripheral ring is displaced towards the perinuclear region. Fibronectin, deposited beneath the basal surface, co-localises with the actin-containing peripheral ring. The peripheral ring subsequently disappears and is replaced by a system of radial microfilaments that extend from the perinuclear region to the cell periphery. At this stage, there is no correlation between the distribution of fibronectin and actin. As cells form colonies, radial microfilament bundles are replaced by peripheral microfilament bundles which do not co-localise with fibronectin. Cells at the edges of colonies extend lamellae that contain microfilament stress fibres. In these structures there is co-localisation of actin, fibronectin and the a5 beta 1-integrin fibronectin receptor.

Localization of vimentin in myoepithelial cells of the rat mammary gland.

Myoepithelial 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).

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

Parenchymal 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 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 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.

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.

Loss of basement membrane deposits and development of invasive potential by virally-transformed rat mammary cells are independent of collagenase production.

The myoepithelial-type cell line, Rama 712, derived from a normal rat mammary gland, deposits an extracellular matrix containing type-IV collagen and other basement membrane proteins round its cellular periphery. After transformation with a temperature-sensitive mutant of Rous sarcoma virus (tsRSV) the cells fail to deposit an extracellular matrix at the permissive temperature (35 degrees C), but retain the capacity to do so at the non-permissive temperature (41 degrees C). The synthesis of type-IV collagen is not affected by the temperature shift. Rama 712 cells fail to form tumours in syngeneic rats. However, Rama 712-tsRSV cells form tumours that are locally invasive but fail to metastasize. In histological sections, the tumour cells stain with an antibody to type-IV collagen, but do not deposit any extracellular type-IV collagen. Cells isolated from the tumours (Rama 712T) remain temperature-sensitive for the extracellular deposition of type-IV collagen when grown in vitro. Rama 712, Rama 712-tsRSV and Rama 712T fail to produce any detectable type-I or type-IV collagenase at either 35 degrees C or 41 degrees C. These results show that in this system extracellular deposits of basement membrane proteins are lost from invasive tumours produced by myoepithelial-type cells by mechanisms other than those due to the production of collagenolytic enzymes.

Generation of cell types with myoepithelial and mesenchymal phenotypes during the conversion of rat mammary tumor epithelial stem cells into elongated cells.

Epithelial cell lines isolated from benign rat mammary tumors converted to elongated cells that showed some aspects of myoepithelial differentiation. This cellular conversion was blocked in cells isolated from malignant tumors. For investigation of the pathway of the conversion, a rat mammary epithelial cell line (Rama 25) that converted to elongated cells through a series of morphologically distinct intermediates was isolated. These intermediates formed a series in the order: Rama 25, Rama 25-I2, Rama 25-I1, Rama 25-I4, and elongated cells. These cell lines were examined for aspects of myoepithelial or mesenchymal differentiation with the use of a polyclonal antibody to type IV collagen and a keratin monoclonal antibody, LP34 (myoepithelial markers), or a polyclonal antibody to type I procollagen (mesenchymal marker) for cells grown on plastic or as tumors in nude mice. The more epithelial-like cell lines Rama 25 and Rama 25-I2 produced relatively small amounts of type IV collagen and did not stain with LP34 or anti-type I procollagen. The flatter, polygonal cell line Rama 25-I1 stained more strongly with the antibody to type IV collagen but did not stain with anti-type I procollagen. Rama 25-I1 cells, and to a lesser extent Rama 25-I4 cells in tumors, contained a network of cytoplasmic filaments that stained strongly with LP34. The elongated cells, Rama 25-I4 and Rama 25-floaters (Rama 25-FL), did not stain with LP34 in vitro but produced an extracellular matrix that stained with antibodies to both type I procollagen and type IV collagen. The results obtained with these marker proteins suggested that, in this series of morphologic intermediates, the myoepithelial phenotype was best expressed in Rama 25-I1 cells and to a lesser extent in 25-I4 cells. However, this phenotype was relatively unstable, converting to elongated cells, some of which have decreased myoepithelial and increased mesenchymal characteristics. Such a pathway may explain the mixed population of cells seen in some types of benign mammary tumor.

Dissociation of basement membrane protein deposition and cell spreading in virally transformed rat mammary myoepithelial cells.

A myoepithelial-like cell line (Rama 401), isolated from rat mammary gland, has been transformed with a temperature-sensitive mutant of Rous sarcoma virus (tsRSV). Rama 401-tsRSV cells adopt a spindle morphology and fail to deposit basement membrane proteins when grown at the permissive temperature (35 degrees C). When switched to the non-permissive temperature (41 degrees C), the cells flatten (with a 5-fold increase in area), and deposit an extracellular matrix containing basement membrane proteins. When the cells are switched from 35 degrees C to 41 degrees C in the presence of monensin (an ionophore that inhibits protein secretion), basement membrane proteins are no longer deposited extracellularly although the cells flatten, their area increasing by ninefold. Cells switched from 35 degrees C to 41 degrees C in the presence of cycloheximide still flatten and deposit basement membrane proteins, whereas the morphological change on switching from 41 degrees C to 35 degrees C is inhibited by cycloheximide. These experiments indicate that the ability of Rama 401-tsRSV cells to spread on a plastic substratum is not dependent on the de novo synthesis and deposition of basement membrane proteins.

Control of type IV collagen production in rat mammary epithelial and myoepithelial-like cells.

A rat mammary myoepithelial-like cell line (Rama 401) produces 3.5 times more type IV collagen than a mammary epithelial cell line (Rama 25), as measured by the formation of protein hydroxyproline. However, using quantitative "dot" hybridization techniques, the level of poly (A)-containing mRNA hybridizing to a type IV collagen cDNA probe is only 50% higher in Rama 401 cells than in Rama 25 cells. The total amount of hydroxyproline synthesized per cell by the two cell lines is similar. However, in the Rama 25 cells approximately 70% of the hydroxyproline is found as free hydroxyproline against 13% for Rama 401 cells. When Rama 25 cells are grown on collagen gels, they accumulate 2.5-fold more type IV collagen. However, type IV collagen mRNA levels are only 30% higher in Rama 25 cells grown on collagen. The total amount of hydroxyproline synthesized is the same as cells grown on plastic, whereas the extent of collagen degradation is reduced from 71% to 30% in cells grown on collagen gels. No degradation of type IV collagen can be detected in the culture medium of Rama 25 cells. These results indicate that the increased accumulation of type IV collagen in Rama 401 cells is not due to increased synthesis but to a decreased rate of intracellular degradation, and that for Rama 25 cells, the extracellular matrix modulates type IV collagen production by regulating the rate of intracellular collagen degradation.

Collagen processing in ras-transfected mouse mammary epithelial cells.

A mouse mammary epithelial cell line (NMuMG), after transfection with the c-rasH oncogene, forms invasive tumors in nude mice. NMuMG and NMuMG/p-rasH cells produce similar amounts of collagen (mostly type IV) when grown on plastic. NMuMG cells respond to growth on collagen gels by increasing the rate of collagen synthesis and deposition by 100%, unlike NMuMG/p-rasH cells which synthesize similar amounts of collagen whether grown on plastic or collagen gels. These results suggest that ras transformation partially inhibits the interaction between epithelial cells and the surrounding stroma that is necessary for basement membrane deposition in vivo and consequently may facilitate the invasion of the stroma by transfected cells.

Characterization of rat mammary cell types in primary culture: lectins and antisera to basement membrane and intermediate filament proteins as indicators of cellular heterogeneity.

Three morphologically distinct major cell types were observed in primary cultures obtained from the mammary parenchyma of glands from virgin rats. These cell types consisted of small cuboidal epithelial cells, larger epithelioid cells and elongated cells. We have investigated the distribution of the basement membrane proteins laminin and type IV collagen, and the intermediate filament proteins vimentin and prekeratin, in these three cell types using immunofluorescence techniques. Antisera to the basement membrane proteins stain the large epithelioid cells and the elongated cells, but do not stain the small cuboidal cells. Polyclonal antiserum to keratin stains all the small cuboidal and large epithelioid cells, but only a small subpopulation of the elongated cells. However, a monoclonal antibody to keratin, LP34, stains only the large cuboidal and a proportion of the elongated cells. Vimentin antiserum fails to stain the small cuboidal cells but stains all the large epithelioid and elongated cells. In addition, peanut lectin, which binds only to ductal lining epithelial cells in the virgin rat mammary gland in vivo after their treatment with neuraminidase, binds to the small cuboidal cells after neuraminidase treatment but not to the other cell types. However, Griffonia simplicifolia agglutinin I, which specifically stains myoepithelial cells in vivo, binds to the large epithelioid and elongated cells but not to the small cuboidal cells. These results suggest that the small cuboidal cells are related to mammary ductal epithelial cells whereas the large epithelial and elongated cells have some characteristics of myoepithelial cells.

Distribution of entactin in the basement membrane of the rat mammary gland. Evidence for a non-epithelial origin.

Entactin, a sulfated glycoprotein with a molecular weight (MW) of about 150 kD, is present in vascular basement membranes and in the interstitial connective tissue of the mammary glands of virgin rats. It does not appear to be present in the basement membrane surrounding the mammary ductal system. However, in lactating mammary glands entactin is also present in the basement membrane region surrounding the secretory alveoli. Ultrastructural localisation of entactin reveals that it is present on the basal surface of epithelial cells, with patchy staining in the lamina lucida and lamina densa. Entactin also appears to be associated with interstitial collagen fibres. Mammary fibroblastic cells in culture are able to produce entactin, whereas mammary epithelial and myoepithelial cells, which synthesise the basement membrane proteins laminin and type IV collagen, fail to synthesise entactin.

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.

Induction of differentiation in a rat mammary epithelial stem cell line by dimethyl sulphoxide and mammotrophic hormones.

Rama 25 is a clonal epithelial cell line derived from a dimethylbenzanthracene-induced rat mammary adenocarcinoma. In the presence of the mammotrophic hormones, insulin, hydrocortisone, estrogen and prolactin, Rama 25 produces small amounts of casein and forms domes at a low rate. The rates of both these processes can be greatly increased by the addition of dimethyl sulphoxide or hexamethylenebisacetamide which are also known to induce the differentiation of Friend erythroleukemia cells. Other compounds which stimulate the differentiation of Rama 25 cells include linoleic acid and 6-thioguanine. The intracellular pathways triggering changes in the two markers of differentiation are partially separable using different combinations of hormones, prolactin and hydrocortisone being the most important for the production of casein and the formation of domes respectively. The kinetics of differentiation, as judged by the appearance of these two markers, are characterised by two phases, a fixed period of 8 h (lag phase), the length of which is independent of the dimethyl sulphoxide concentration and a second phase where their rates are dependent on the concentration of dimethyl sulphoxide. Rama 25 cells do not become committed to differentiate during this lag phase but increasing numbers of cells do so after this period. We suggest that the differentiation processes occur in two stages. The first stage, involving the inducer, commits Rama 25 cells to a new differentiated state. The second stage, involving the hormones, modulates the expression of different markers of this state. Both casein production and dome formation can be blocked by inhibitors of DNA synthesis and show reciprocal changes with the rates of cellular DNA synthesis. Thus, in its hormonal and DNA synthetic requirements for differentiation, Rama 25 cells appear to resemble some of the mammary epithelial cells of mature virgin rats.