Distribution of immunoreactive transforming growth factor-alpha in non-neoplastic human salivary glands.

The distribution of immunoreactive transforming growth factor-alpha (TGF-alpha) was studied in non-neoplastic human major and minor salivary glands using an immunoperoxidase assay in conjunction with an antiserum to human TGF-alpha. The ductal cell components of all major and minor salivary glands were found to contain significant amounts of TGF-alpha immunoreactivity. In contrast, acinar and myoepithelial cells consistently lacked immune reaction product in both types of glands. Occasionally, an asynchronous pattern of TGF-alpha ductal cell immunoreactivity was observed in specific ducts within a section. Also, intraductal secretions, when present, were found to contain TGF-alpha immunoreactive material. Ductal cells and connective tissue from salivary glands samples showing significant lymphocytic infiltration and loss of acinar cells exhibited higher levels of TGF-alpha immunoreactivity than normal salivary gland samples. These observations demonstrate, for the first time, the presence of TGF-alpha immunoreactivity in specific structural components of non-neoplastic human major and minor salivary glands. It will be important in future studies to determine whether alterations in TGF-alpha expression are detectable in diverse types of salivary gland tumors.

Emergence of salivary gland cell lineage diversity suggests a role for androgen-independent epidermal growth factor receptor signaling.

Diversity of cell lineages within glandular organs is generated postnatally by differentiation of committed progenitor cells. Fundamental regulatory aspects of this process are not understood. The mouse submandibular salivary gland (SSG) served as model to assess the role of epidermal growth factor (EGF) receptor signaling during emergence of cell lineage diversity. Temporal fluctuations in EGF receptor mRNA levels coincident with crucial differentiative cell lineage transitions were revealed by RNase protection analyses. Between days 2 and 5, when proacinar cells are maturing and striated duct cells emerge, EGF receptor mRNA levels were highest and all differentiating cells exhibited EGF receptor immunoreactivity. EGF receptor mRNA levels then declined sharply and immunoreactivity became confined to ductal cells. At day 11 in male mice, and days 11 and 16 in females, a second increase in EGF receptor mRNA was detected coincident with emergence of granular convoluted tubule (GCT) cells. With completion of androgen-dependent GCT cell differentiation at the onset of puberty, EGF receptor mRNA levels and intensity of immunoreactivity decreased. Androgen effects on EGF receptor mRNA or immunoreactivity could not be detected. These temporally distinct patterns of EGF receptor expression suggest that this signaling pathway is a mechanism of potential importance in emergence of cell lineage diversity in a glandular organ.

Cell phenotypes and differentiative transitions in mouse submandibular salivary gland defined with monoclonal antibodies to mammary epithelial cells.

Recognition of distinct cell phenotypes within a given organ is important in defining cell relationships during development and in analyzing the role of cell-cell and cell-matrix interactions in growth and differentiation. Phenotypic definition of dissociated heterogeneous cell populations is also essential for studies on mechanisms regulating expression of cell lineage-specific gene products. Mouse submandibular salivary gland (SSG) cell phenotypes in the course of differentiative transitions in vivo and after enzymatic dissociation in primary culture were defined with monoclonal antibodies (MAb) to mammary epithelial cells and polyclonal antibodies to functional cell products. Proacinar cells and differentiating and mature acinar cells were uniquely recognized by an MAb designated 50B8. Ductal cell components were uniquely recognized by an MAb designated JSE3. JSE3 immunoreactivity was particularly useful for detecting the emergence of two SSG duct cell phenotypes, striated ducts and the hormone-responsive granular convoluted tubules (GCTs). JSE3-positive striated duct-like cells were visualized as early as Day 2 after birth and emergence of GCT-like structures from striated ducts was apparent between Days 10 and 11. Differential reactivity of acinar and ductal cells in the developing SSG with either MAb 50B8 or JSE3 suggests the existence of intermediate progenitor cells restricted in their differentiation potential. An interesting pattern of immunoreactivity was observed with an MAb designated 33A10. During the first 2 weeks of SSG postnatal development, shared 33A10 immunoreactivity was observed among proacinar and differentiating acinar cells and all differentiating ductal segments. Coincident with a decrease in proliferative activity at about Day 18, 33A10 immunoreactivity became restricted to the GCT cell lineage before the appearance of GCT functional products, epidermal and nerve growth factors. Although the SSG antigen recognized by MAb 33A10 is presently undefined, its expression pattern suggest a molecule with a dual role in development and growth events and in hormone-dependent secretory function. Advantage was taken of the observed differential immunoreactivities to define the phenotypic identity of dissociated, mature SSG cells before and after culture. Dissociated SSG fractions enriched for either JSE3- or 50B8-positive cells could be maintained in short-term cultures without loss of expression of duct- or acinar cell-specific immunoreactivity. In addition to providing markers for defining dissociated SSG cells before and after culture, the described immunoreactivities may permit separation or enrichment of an early duct cell population before its commitment to a specific cell lineage. This approach may also provide the means to define regulatory signals involved in the differentiation of intermediate progenitor cells.

Influence of mammary cell differentiation on the expression of proteins encoded by endogenous BALB/c mouse mammary tumor virus genes.

The interactions between differentiation-associated cellular events in the intact mammary gland or in cultured mammary cells and the post-transcriptional activity of the endogenous mouse mammary tumor virus (MMTV) loci were investigated. The transcriptional activities of the endogenous MMTV proviruses of the BALB/c mouse strain (Mtv-6, Mtv-8 and Mtv-9) appear to be regulated differentially during pregnancy-induced mammary gland development (J.E. Knepper, D. Medina and J.S. Butel, J. Virol. 59, 518-521, 1986). Analysis of MMTV-specific proteins at various stages of mammary gland development (virgin, midpregnant, lactating, regressing) established the presence of steady-state levels of a 67,000-Mr env precursor-type polypeptide at all physiological stages. However, processing to lower-molecular-weight env-specific proteins, including a predominant 50,000-Mr species, was detected only with the transition to the functional mammary gland phenotype. The contributions of cell proliferation, cell-matrix interactions, and modulation of functional activity to the pattern of endogenous MMTV protein expression were investigated using a 3-dimensional collagen type I culture system. Growth and cell-matrix interactions (cell polarization, lumen formation) leading to formation of 3-dimensional duct-like structures were permissive for the synthesis and processing of MMTV-specific proteins; accumulation of high levels of the 50,000-Mr env-specific polypeptide was associated with the onset of the fully functional mammary cell phenotype. Expression of MMTV-specific proteins was not due to amplification of a specific cell subpopulation. The potential of the full-length Mtv-8 and Mtv-9 proviruses to be transcribed, as indicated by their methylation status, was not dramatically different between differentiated and undifferentiated mammary cells in culture. This study indicates that MMTV transcriptional activity is reflected at the protein level in mammary tissue of BALB/c mice and that viral protein synthesis and processing may serve as important markers of different physiological stages of mammary epithelial cells. These observations also suggest a general approach to the examination of potential modulatory effects of cellular interactions (cell-cell, cell-matrix or both) known to be important in various differentiated epithelial cell systems for the expression of viral genes.

Mouse submandibular salivary epithelial cell growth and differentiation in long-term culture: influence of the extracellular matrix.

The adult mouse submandibular salivary gland provides a good model system to study gene regulation during normal and abnormal cell behavior because it synthesizes functionally distinct products ranging from growth factors and digestive enzymes to factors of relevance to homeostatic mechanisms. The present study describes the long-term growth and differentiation of submandibular salivary epithelial cells from adult male mice as a function of the culture substratum. Using a two-step partial dissociation procedure, it was possible to enrich for ductal cells of the granular convoluted tubules, the site of epidermal growth factor synthesis. Long-term cell growth over a period of 2 to 3 mo. with at least 3 serial passages was obtained only within three-dimensional collagen gels. Cells grew as ductal-type structures, many of which generated lumens with time in culture. Electron microscopic analysis in reference to the submandibular gland in vivo revealed enrichment for and maintenance of morphologic features of granular convoluted tubule cells. Reactivity with a keratin-specific monoclonal antibody established the epithelial nature of the cells that grew within collagen. Maintenance of cell differentiation, using immunoreactivity for epidermal growth factor as criterion, was determined by both cytochemical and biochemical approaches and was found to be dependent on the collagen matrix and hormones. Greater than 50% of the cells in primary collagen cultures contained epidermal growth factor only in the presence of testosterone and triiodothyronine. In contrast, cells initially seeded on plastic or cycled to plastic from collagen gels were virtually negative for epidermal growth factor. Biochemical analysis confirmed the presence of a protein with an apparent molecular weight of 6000 which comigrated with purified mouse epidermal growth factor. Epidermal growth factor was also present in detectable levels in Passage 1 cells. This culture system should permit assessment of whether modulation of submandibular gland ductal cell growth can be exerted via a mechanism that in itself includes epidermal growth factor and its receptor and signal transduction pathway.

Clonal populations of the mouse mammary cell line, COMMA-D, which retain capability of morphogenesis in vivo.

Clonal populations were isolated from the mouse mammary cell line, COMMA-D, by transfection with a dominant-selectable gene, pSV2Neo, which confers resistance to the antibiotic, G418. Seven of twenty-four clones isolated retained the ability of the parental line to repopulate cleared mammary fat pads in vivo as ductal-alveolar hyperplasias. Two sublines designated CDNR2 and CDNR4 retained hyperplastic growth potential after multiple passages in vitro with low incidence of tumor formation. A third subpopulation, CDNR1, contained a single integration site for the pSV2Neo plasmid indicating a bonafide clonal origin for this subline. CDNR1 cells displayed heterogeneous growth phenotypes in vivo including hyperplasia, adenocarcinoma, and bone formation. Functional differentiation of CDNR1 cells organized as alveolarlike structures in vivo or on floating collagen gels in vitro was observed as determined by immunoperoxidase staining for the milk-specific protein, casein. Overall, the results indicate that a subset of cells from the COMMA-D cell line may be functionally analogous to stem cells existing in the mammary gland.

Comparative analysis of casein synthesis during mammary cell differentiation in collagen and mammary gland development in vivo.

Substrata upon which epithelial cells are cultured modulate their morphology,growth, and ability to differentiate. Mouse mammary epithelial cells cannot be induced to synthesize caseins, a marker of cell differentiation, when grown on a plastic surface. An analysis was made of the effect of time within a collagen matrix on the ability of normal mammary epithelial cells to be induced to synthesize caseins and that response was compared to mammary gland development in vivo. Primary cultures of mammary cells from unprimed virgin BALB/c mice were embedded in rat-tail collagen gel mixtures and maintained in growth medium. Induction medium containing lactogenic hormones was added at various times. The cells were monitored every 3-7 days over a period of 8 weeks for cell growth, casein synthesis, and ability to grow in vivo in cleared mammary fat pads. Casein accumulation was assayed quantitatively by an ELISA competition assay and qualitatively by the immunoblot procedure using specific antisera prepared against purified mouse caseins. No marked differences in cell numbers and transplantability potential were observed among cells cultured for various times in collagen. Mammary cells grown in collagen for up to 8 weeks retained the capacity to grow in vivo as normal ductal outgrowths. The duration of culture within collagen prior to hormonal stimulation did influence the kinetics of casein synthesis. Cells cultured for 1 week in growth medium did not accumulate detectable levels of casein until after 3 weeks of induction, whereas cells cultured for 2 or 4 weeks responded by accumulating caseins after 2 weeks and 3 days of induction, respectively. While the levels of total caseins that accumulated under optimal conditions of induction in culture approached levels found during lactation in vivo, the relative proportion of specific casein polypeptides synthesized in culture was altered from alpha casein (43K) in favor of the beta casein (30K) species. These results suggest that a period of culture within collagen is required to permit mammary epithelial cells to become responsive for hormone-induced differentiation. It is possible that during growth within the collagen the cells synthesize and deposit extracellular matrix components important in modulating gene expression.

A subclass of luminal epithelial cells in the human mammary gland, defined by antibodies to cytokeratins.

Two monoclonal antibodies, BA16 and BA17, have been developed using a detergent-insoluble extract of human mammary epithelial organoids as immunogen. Indirect immunofluorescent staining of cultured cells showed that the component reacting with the antibodies was filamentous and the intensity of staining was stronger in mitotic cells. Immunoblotting of cell extracts showed that both antibodies react with only one band of 40 X 10(3) molecular weight, which was present in keratin-enriched extracts of cells or organoids. Furthermore, the tissue distribution of the component reacting with the antibodies was that predicted for human keratin 19. The antibodies showed differences in the intensity of staining of cells or tissue sections fixed and prepared in different ways indicating that they reacted with different epitopes. The pattern of expression of the 40 X 10(3) Mr keratin by normal mammary epithelial cells was investigated by immunoperoxidase staining of tissue sections, cultured milk cells, and organoids of different sizes cultured in collagen gels. It was found that basal or myoepithelial cells did not express this keratin. Some heterogeneity of expression of this component was seen in luminal epithelial cells, found almost exclusively in the smaller structures. These cells did, however, express other keratins characteristic of luminal cells. The distribution in the mammary tree of the luminal cells that did not express the 40 X 10(3) Mr keratin appears to be similar to that expected for cells with the proliferative potential to produce new terminal ductal lobular units or an increase in branching of existing terminal ductal lobular units. It is shown that these cells have considerable proliferative potential by the fact that they form large colonies in milk cell cultures.

Epithelial mouse mammary cell line exhibiting normal morphogenesis in vivo and functional differentiation in vitro.

An epithelial cell line, designated COMMA-1D, was derived from mammary tissue of BALB/c mice in the middle of pregnancy. This line, in continuous cell culture for 12 months, exhibits several characteristics distinctive of normal mammary epithelial cells, including induction of casein synthesis in vitro and normal duct morphogenesis in the cleared mammary fat pads of syngeneic mice. The cells also form domes in high density culture and are positive for keratin intermediate filaments by indirect immunofluorescence. COMMA-1D cells have a near diploid number of chromosomes and do not grow in suspension culture or produce tumors in syngeneic hosts. This cell line should prove useful for studies examining the regulation of normal cellular differentiation of mammary cells as well as transformation of epithelial cells to the preneoplastic and neoplastic phenotypes.

Differential effects of transforming avian RNA tumor viruses on avian macrophages.

Functionally differentiated chicken macrophages were derived by in vitro differentiation of embryonic yolk sac cells and were characterized by several macrophage-specific cell markers. Uniform, infected, virus-producing cultures were obtained after exposure of these macrophages to avian myoblastosis virus (AMV), avian myelocytomatosis virus (MC29), myeloblastosis-associated virus (MAV-2), and Prague strain of Rous sarcoma virus (PR-B RSV). Both AMV and MC29 induced morphological transformation typical of the in vivo leukemias induced by these virus strains. Analysis of the expression of macrophage-specific markers in these two transformed cell types demonstrated that different markers of the mature macrophage were suppressed by each virus, even though the parental cell immediately preceding the transformation event was a mature macrophage in both cases. Cells infected with PR-B RSV and MAV-2 showed no observable difference from uninfected macrophages in terms of morphological characteristics, growth rate, or expression of the differentiated functions of macrophages. Ths system provides demonstrations of a cell type that produces infectious, transforming RSV but fails to respond by functional alterations induced by the transforming gene, src.

Replicating, differentiated macrophages can serve as in vitro targets for transformation by avian myeloblastosis virus.

Pure cultures of chicken macrophages were characterized functionally and transformed by avian myeloblastosis virus. Transformed cells exhibited an altered function. The efficiency of transformation was limited by the mitotic activity of the macrophages.