Modulation of neutral matrix metalloproteinases of involuting rat mammary gland by different cations and glycosaminoglycans

The synthesis and regulation of the matrix metalloproteinases (MMPs) are important factors contributing to the involution of mammary gland. In order to understand the role of these MMPs in involution and in remodeling of the mammary gland, the different MMPs (130K, 68K, and 60K gelatinases) were partially purified by gel filtration and affinity chromatography over gelatin Sepharose and subjected to kinetic analysis. Comparative analysis of the different gelatinases showed that the 130K that appears at the early involuntary phase and the constitutive 68K enzyme are more specific for Col IV of the basement membrane, while the inducible 60K that appeared at the later phase of involution degraded Col I more efficiently. These neutral proteinases required Ca2+/Zn2+ for their activity and the analysis of cation dependence revealed that Ca2+ at 10 mM concentration and above completely inhibited the enzyme. The 60K was active at very low concentration of Zn2+ (5 microM); but at higher concentration of Zn2+ (2 mM), where the 68K and 130K were active, the 60K gelatinase was inhibited, indicating a difference in the cation dependence of these enzymes. Chondroitin sulfate A and chondroitin sulfate C caused inhibition of the 130K, 68K, and 60K, while hyaluronic acid and heparin did not show any effect, suggesting that the chondroitin sulfate proteoglycan that decorates collagen in the ECM can modu late the activity of the collagenases in vivo. These results suggest that the 130K gelatinase expressed during the early phase of involution degraded Col IV of the basement membrane, making the 60K gelatinase formed at a later stage of involution more accessible to its preferred substrate (Col I of the underlying stroma), highlighting the role of these MMPs in mammary gland involution.     

Coordinated expression of extracellular matrix-degrading proteinases and their inhibitors regulates mammary epithelial function during involution

Extracellular matrix (ECM) plays an important role in the maintenance of mammary epithelial differentiation in culture. We asked whether changes in mouse mammary specific function in vivo correlate with changes in the ECM. We showed, using expression of beta-casein as a marker, that the temporal expression of ECM-degrading proteinases and their inhibitors during lactation and involution are inversely related to functional differentiation. After a lactation period of 9 d, mammary epithelial cells maintained beta-casein expression up to 5 d of involution. Two metalloproteinases, 72-kD gelatinase (and its 62-kD active form), and stromelysin, and a serine proteinase tissue plasminogen activator were detected by day four of involution, and maintained expression until at least day 10. The expression of their inhibitors, the tissue inhibitor of metalloproteinases (TIMP) and plasminogen activator inhibitor-1, preceded the onset of ECM-degrading proteinase expression and was detected by day two of involution, and showed a sharp peak of expression centered on days 4-6 of involution. When involution was accelerated by decreasing lactation to 2 d, there was an accelerated loss of beta-casein expression evident by day four and a shift in expression of ECM-remodeling proteinases and inhibitors to a focus at 2-4 d of involution. To further extend the correlation between mammary-specific function and ECM remodeling we initiated involution by sealing just one gland in an otherwise hormonally sufficient lactating animal. Alveoli in the sealed gland contained casein for at least 7 d after sealing, and closely resembled those in a lactating gland. The relative expression of TIMP in the sealed gland increased, whereas the expression of stromelysin was much lower than that of a hormone-depleted involuting gland, indicating that the higher the ratio of TIMP to ECM-degrading proteinases the slower the process of involution. To test directly the functional role of ECM-degrading proteinases in the loss of tissue-specific function we artificially perturbed the ECM-degrading proteinase-inhibitor ratio in a normally involuting gland by maintaining high concentrations of TIMP protein with the use of surgically implanted slow-release pellets. In a concentration-dependent fashion, involuting mammary glands that received TIMP implants maintained high levels of casein and delayed alveolar regression. These data suggest that the balance of ECM-degrading proteinases and their inhibitors regulates the organization of the basement membrane and the tissue-specific function of the mammary gland.(ABSTRACT TRUNCATED AT 400 WORDS)     

Enhanced synthesis of gelatinase and stromelysin by myoepithelial cells during involution of the rat mammary gland.

During the involution of the mammary gland there is destruction of the basement membrane as the secretory alveolar structures degenerate. Immunofluorescence staining of sections of rat mammary gland with antibodies to 72 KD gelatinase (MMP-2) and stromelysin (MMP-3) revealed increased production of these two proteinases during involution. This increased expression was mostly restricted to myoepithelial cells. Increased expression during involution was also demonstrated by immunoblotting techniques. Gelatin zymography indicated that the predominant metalloproteinase present in involuting rat mammary glands was a 66 KD gelatinase.     

Matrix Metalloproteinase in Mammary Gland Remodeling-Modulation by Glycosaminoglycans

Mammary gland which undergoes proliferation, differentiation and involution in adult life is a useful model system to study the role of extracellular matrix (ECM) in regulating tissue specific functions. The involution that follows weaning results in the suppression of casein gene expression, collapse of alveolar structures and degradation of basement membrane as evidenced by biochemical analysis of matrix components like proteoglycans and collagen. Differential expression of three different MMPs viz. 130 K, 68 K and 60 K with varying specificity to Col IV of basement membrane and Col I of stroma, their selective inhibition by TIMP and proteoglycans and modulation by estrogen highlight the importance of these in the remodeling of the ECM in the mammary gland. The inhibition of these MMPs by glycosaminoglycans, particularly CS and change in the concentration of CS at different stages of mammary gland development suggests the existence of a novel mechanism for the regulation of the activity of MMPs at extracellular sites.     

Matrix metalloproteinases and their expression in mammary gland

The matrix metalloproteinases (MMPs) are a family of zine-dependent endopeptidases that play a key role in both normal and pathological processes involving tissue remodeling events.The expression of these proteolytic enzymes is highly regulated by a balance between extracellular matrix (ECM) deposition and its degradation,and is controlled by growth factors,cytokines,hormones,as well as interactions with the ECM macromolecules.Furthermore,the activity of the MMPs is regulated by their natural endogenous inhibitors,which are members of the tissue inhibitor of metalloproteinases (TIMP) family.In the normal mammary gland,MMPs are expressed during ductal development,lobulo-alveolar development in pregnancy and involution after lactation.Under pathological conditions,such as tumorigenesis,the dysregulated expression of MMPs play a role in tumor initiation,progression and malignant conversion as well as facilitating invasion and metastasis of malignant cells through degradation of the ECM and basement membranes.     

Differential expression of claudin 1, 3, and 4 during normal mammary gland development in the mouse

The claudins are a family of tight junction proteins that display varied tissue distribution and preferential specificity. We recently identified by microarray analysis, members of this family, particularly claudin 1 (cldn1), as highly upregulated genes in the mouse mammary gland during early involution. Gene expression was confirmed by immunohistochemistry and real-time PCR. We then examined gene and protein expression throughout normal mammary gland development. The cldn3 gene showed a steady increase in expression from pregnancy to involution, while cldn1 and cldn4 gene expression increased during pregnancy, but decreased sharply by D10 of lactation, and once again was significantly increased by D1 of involution (P < 0.001 for both genes). The different patterns of gene expression observed between cldn3, and cldn1, and 4 suggest that different family members may be functionally important at different times during mouse mammary gland development. All three genes exhibited a high level of expression at day 1 (D1) of involution, followed by a dramatic decrease in gene expression to day 10 of involution. Immunostaining with the cldn3 antibody showed intense staining of epithelial cells; however, a lesser degree of staining was evident with the cldn1 antibody. In addition to the lateral staining of epithelial cells, basal staining was evident at D1 and D2 of involution and cytoplasmic staining was evident during lactation. Since claudins are known to play a role as tight junction proteins, lateral and basal staining may suggest a role in other functions such as vesicle trafficking or remodeling of tight junctions at different stages of mammary gland development. Cldn1 and 3 antibodies also stained epithelial cells in mouse mammary tumors. In summary, cldn1, 3, and 4 are differentially expressed in the mammary gland during pregnancy, lactation, and involution, suggesting different roles for these proteins at different stages of mammary gland function. In addition, cldn1 and cldn3 are detected in mammary tumors and the wide distribution of cldn3 in particular, suggest specific roles for these proteins in mammary tumorigenesis.     

Differential expression of TGF-β isoforms during postlactational mammary gland involution

After cessation of lactation, the mammary gland undergoes involution, which is characterized by a massive epithelial cell death and proteolytic degradation of the extracellular matrix. Whereas the expression patterns and also the function of TGF-beta isoforms during mammary gland branching morphogenesis and lactation are well understood, their expression during postlactational involution and therefore a possible role in this process is poorly known. In this study we show that TGF-beta3 expression is dramatically induced (>fivefold) during mouse mammary gland involution when compared to that of virgin mouse, reaching a maximal expression level at day 4 after weaning. In contrast, other TGF-beta isoforms do not display significant increase in expression during involution (TGF-beta1, 1.3-fold and TGF-beta2, <1.5-fold) when compared to that of virgin or lactating mice. During mammary gland involution, TGF-beta3 is expressed in the epithelial layer and particularly in myoepithelial cells. A comparison of the kinetics of TGF-beta3 expression to that of programmed cell death and degradation of the basement membrane suggests that TGF-beta3 functions in the remodeling events of the extracellular matrix during the second stage of involution.     

Identification of Cell Types in the Developing Goat Mammary Gland

The goat was chosen as the model system for investigating mammary gland development in the ruminant. Histological and immunocytochemical staining of goat mammary tissue at key stages of development was performed to characterize the histogenesis of the ruminant mammary gland. The mammary gland of the virgin adult goat consisted of a ductal system terminating in lobules of ductules. Lobuloalveolar development of ductules occurred during pregnancy and lactation which was followed by the regression of secretory alveoli at involution. The ductal system was separated from the surrounding stroma by a basement membrane which was defined by antisera raised against laminin and Type IV collagen. Vimentin, smooth-muscle actin and myosin monoclonal antisera as well as antisera to cytokeratin 18 and multiple cytokeratins stained a layer of myoepithelial cells which surround the ductal epithelium. Staining of luminal epithelial cells by monoclonal antibodies to cytokeratins was dependent on their location along the ductal system, from intense staining in ducts to variable staining in ductules. The staining of epithelial cells by monoclonals to cytokeratins also varied according to the developmental status of the goat, being maximal in virgin and involuting glands, lowest at lactation and intermediate during gestation. In addition, cuboidal cells, situated perpendicular to myoepithelial cells and adjacent to alveolar cells in secretory alveoli, were also stained by cytokeratin monoclonal antibodies and antisera to the receptor protein, erbB-2, in similar fashion to luminal epithelial cells. These results demonstrate that caprine mammary epithelial cell differentiation along the alveolar pathway is associated with the loss of certain types of cytokeratins and that undifferentiated and secretory alveolar epithelial cells are present within lactating goat mammary 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.     

Distribution of myoepithelial cells and basement membrane proteins in the resting, pregnant, lactating, and involuting rat mammary gland

Using antisera to specific proteins, the localization of the rat mammary parenchymal cells (both epithelial and myoepithelial), the basement membrane, and connective tissue components has been studied during the four physiological stages of the adult rat mammary gland, viz. resting, pregnant, lactating, and involuting glands. Antisera to myosin and prekeratin were used to localize myoepithelial cells, antisera to rat milk fat globule membrane for epithelial cells, antisera to laminin and type IV collagen to delineate the basement membrane and antisera to type I collagen and fibronectin as markers for connective tissue. In the resting, virgin mammary gland, myoepithelial cells appear to form a continuous layer around the epithelial cells and are in turn surrounded by a continuous basement membrane. Antiserum to fibronectin does not delineate the basement membrane in the resting gland. The ductal system is surrounded by connective tissue. Only the basal or myoepithelial cells in the terminal end buds of neonatal animals demonstrate cytoplasmic staining for basement membrane proteins, indicating active synthesis of these proteins during this period. In the secretory alveoli of the lactating rat, the myoepithelial cells no longer appear to form a continuous layer beneath the epithelial cells and in many areas the epithelial cells appear to be in contact with the basement membrane. The basement membrane in the lactating gland is still continuous around the ducts and alveoli. In the lactating gland, fibronectin appears to be located in the basement membrane region in addition to being a component of the stroma. During involution, the alveoli collapse, and appear to be in a state of dissolution. The basement membrane is thicker and is occasionally incomplete, as also are the basket-like myoepithelial structures. Basement membrane components can also be demonstrated throughout the collapsed alveoli.     

Matrix metalloproteinases are expressed during ductal and alveolar mammary morphogenesis, and misregulation of stromelysin-1 in transgenic mice induces unscheduled alveolar development.

The matrix-degrading metalloproteinases stromelysin-1, stromelysin-3, and gelatinase A are expressed during ductal branching morphogenesis of the murine mammary gland. Stromelysin-1 expression in particular correlates with ductal elongation, and in situ hybridization and three-dimensional reconstruction studies revealed that stromelysin-1 mRNA was concentrated in stromal fibroblasts along the length of advancing ducts. Transgenic mice expressing an activated form of stromelysin-1 under the control of the MMTV promoter/enhancer exhibited inappropriate alveolar development in virgin females. Ultrastructural analysis demonstrated that the basement membrane underlying epithelial and myoepithelial cells was amorphous and discontinuous compared with the highly ordered basal lamina in control mammary glands. Transgenic mammary glands had at least a twofold increase in the number of cells/unit area and a 1.4-fold increase in the percent of cycling cells by 13 wk of age compared with nontransgenic littermates. In addition, transgenic glands expressed beta-casein mRNA, but not protein, and resembled the proliferative and differentiated state of an animal between 8 and 10 days pregnant. An analysis of metalloproteinase expression in the glands of normal pregnant females demonstrated that the same matrix metalloproteinase family members, including stromelysin-1, were expressed in connective tissue cells surrounding epithelial clusters during the time of lobuloalveolar development. These results suggest that metalloproteinases may assist in remodeling ECM during normal ductal and alveolar branching morphogenesis, and that disruption of the basement membrane by an activated metalloproteinase can affect basic cellular processes of proliferation and differentiation.     

Calmodulin content of rat mammary tissue and isolated cells during pregnancy and lactation.

The calmodulin content of heat-treated extracts of rat mammary tissue and isolated cells was measured by using stimulation of cyclic nucleotide phosphodiesterase (PDE) activity and radioimmunoassay (r.i.a.) procedures. The calmodulin content of mammary tissue increased 2.5-fold near the time of parturition, remained at the elevated level during lactation, then, after the onset of involution, decreased to values similar to those measured from mammary tissue of pregnant rats. When tissue from 15 animals in different stages of pregnancy, lactation and involution were compared, the r.i.a. gave 2.6-fold higher results than the PDE assay. To investigate further the increase in calmodulin content of mammary tissue, secretory and myoepithelial cells were enzymically dissociated from rat mammary tissue during different stages of pregnancy, lactation and involution. Protein, DNA, lactose, glucose-6-phosphate dehydrogenase and alkaline phosphatase were assayed to characterize the cell fractions. By using r.i.a., the calmodulin content per mg of protein in isolated secretory-cell fractions was high near parturition, then decreased and remained relatively constant during lactation. The amount of calmodulin expressed per mg of DNA in secretory cells did not show a marked change near parturition, suggesting a constant amount of calmodulin per cell. The calmodulin content of myoepithelial cells dissociated from mammary tissue and measured by using r.i.a. was 6-fold lower than in secretory cells and remained relatively constant during the course of lactation. The changing levels of calmodulin in rat mammary tissue during development are suggested to be related to proliferation and destruction of secretory epithelial cells, events that occur near parturition and involution respectively.     

Non-steroidal anti-inflammatory drugs target the pro-tumorigenic extracellular matrix of the postpartum mammary gland

Breast cancer patients diagnosed postpartum have poor prognosis. The postpartum mammary gland undergoes tissue regression to return to the pre-pregnant state. This involution is characterized by wound healing programs known to be tumor promotional in other contexts. Previous studies have shown that mammary extracellular matrix (ECM) from nulliparous rats has tumor suppressive attributes, while mammary ECM from involuting mammary glands is promotional. In models of pregnancy-associated breast cancer, non-steroidal anti-inflammatory drug (NSAID) treatment targeted to postpartum involution inhibits tumor progression, in part by suppressing COX-2 dependent collagen deposition. Because mammary ECM proteins are coordinately regulated, NSAID treatment is anticipated to result in additional protective changes in the mammary extracellular matrix. Here, systemic NSAID treatment was utilized during postpartum involution to reduce mammary COX-2 activity. ECM was isolated from actively involuting glands of rats treated with NSAIDs and compared to ECM isolated from control-involution and nulliparous rats in 3D cell culture and xenograft assays. Compositional changes in ECM between groups were identified by proteomics. In four distinct 3D culture assays, normal and transformed mammary epithelial cells plated in NSAID-involution ECM, phenocopied cells plated in ECM from nulliparous rats rather than ECM from control-involution rats. Tumor cells mixed with NSAID-involution ECM and injected orthotopically in mice formed smaller tumors than cells mixed with control-involution ECM. Proteomic analyses identified and 3D culture assays implicated the ECM protein tenascin-C as a potential mediator of tumor progression during involution that is decreased by NSAID treatment. In summary, NSAID treatment decreases tumor-promotional attributes of postpartum involution mammary ECM.     

Binding to EGF receptor of a laminin-5 EGF-like fragment liberated during MMP-dependent mammary gland involution

Extracellular matrix (ECM) fragments or cryptic sites unmasked by proteinases have been postulated to affect tissue remodeling and cancer progression. Therefore, the elucidation of their identities and functions is of great interest. Here, we show that matrix metalloproteinases (MMPs) generate a domain (DIII) from the ECM macromolecule laminin-5. Binding of a recombinant DIII fragment to epidermal growth factor receptor stimulates downstream signaling (mitogen-activated protein kinase), MMP-2 gene expression, and cell migration. Appearance of this cryptic ECM ligand in remodeling mammary gland coincides with MMP-mediated involution in wild-type mice, but not in tissue inhibitor of metalloproteinase 3 (TIMP-3)-deficient mice, supporting physiological regulation of DIII liberation. These findings indicate that ECM cues may operate via direct stimulation of receptor tyrosine kinases in tissue remodeling, and possibly cancer invasion.