Targeted expression of stromelysin-1 in mammary gland provides evidence for a role of proteinases in branching morphogenesis and the requirement for an intact basement membrane for tissue-specific gene expression.

The extracellular matrix (ECM) is an important regulator of the differentiated phenotype of mammary epithelial cells in culture. Despite the fact that ECM-degrading enzymes have been implicated in morphogenesis and tissue remodeling, there is little evidence for a direct role for such regulation in vivo. We generated transgenic mice that express autoactivated isoforms of the matrix metalloproteinase stromelysin-1, under the control of the whey acidic protein gene promoter, to examine the effect of inappropriate expression of this enzyme. Stromelysin-1 is implicated as the primary player in the loss of basement membrane and loss of function in the mammary gland during involution. The transgene was expressed at low levels in mammary glands of virgin female mice, leading to an unexpected phenotype: The primary ducts had supernumerary branches and showed precocious development of alveoli that expressed beta-casein at levels similar to that of an early- to mid-pregnant gland. Lactating glands showed high levels of transgene expression, with accumulation at the basement membrane, and a decrease in laminin and collagen IV, resulting in a loss of basement membrane integrity; this was accompanied by a dramatic alteration of alveolar morphology, with decreased size and shrunken lumina containing little beta-casein. During pregnancy, expression of endogenous whey acidic protein and beta-casein was reduced in transgenic glands, confirming the observed dependence of milk protein transcription of ECM in mammary epithelial cells in culture. These data provide direct evidence that stromelysin-1 activity can be morphogenic for mammary epithelial cells, inducing hyperproliferation and differentiation in virgin animals, and that its lytic activity can, indeed, disrupt membrane integrity and reduce mammary-specific function. We conclude that the balance of ECM-degrading enzymes with their inhibitors, and the associated regulation of ECM structure, is crucial for tissue-specific gene expression and morphogenesis in vivo.

Suppression of ICE and apoptosis in mammary epithelial cells by extracellular matrix.

Apoptosis (programmed cell death) plays a major role in development and tissue regeneration. Basement membrane extracellular matrix (ECM), but not fibronectin or collagen, was shown to suppress apoptosis of mammary epithelial cells in tissue culture and in vivo. Apoptosis was induced by antibodies to beta 1 integrins or by overexpression of stromelysin-1, which degrades ECM. Expression of interleukin-1 beta converting enzyme (ICE) correlated with the loss of ECM, and inhibitors of ICE activity prevented apoptosis. These results suggest that ECM regulates apoptosis in mammary epithelial cells through an integrin-dependent negative regulation of ICE expression.

A novel pathway for mammary epithelial cell invasion induced by the helix-loop-helix protein Id-1.

Mammary epithelial cells undergo changes in growth, invasion, and differentiation throughout much of adulthood, and most strikingly during pregnancy, lactation, and involution. Although the pathways of milk protein expression are being elucidated, little is known, at a molecular level, about control of mammary epithelial cell phenotypes during normal tissue morphogenesis and evolution of aggressive breast cancer. We developed a murine mammary epithelial cell line, SCp2, that arrests growth and functionally differentiates in response to a basement membrane and lactogenic hormones. In these cells, expression of Id-1, an inhibitor of basic helix-loop-helix transcription factors, declines prior to differentiation, and constitutive Id-1 expression blocks differentiation. Here, we show that SCp2 cells that constitutively express Id-1 slowly invade the basement membrane but remain anchorage dependent for growth and do not form tumors in nude mice. Cells expressing Id-1 secreted a approximately 120-kDa gelatinase. From inhibitor studies, this gelatinase appeared to be a metalloproteinase, and it was the only metalloproteinase detectable in conditioned medium from these cells. A nontoxic inhibitor diminished the activity of this metalloproteinase in vitro and repressed the invasive phenotype of Id-1-expressing cells in culture. The implications of these findings for normal mammary-gland development and human breast cancer were investigated. A gelatinase of approximately 120 kDa was expressed by the mammary gland during involution, a time when Id-1 expression is high and there is extensive tissue remodeling. Moreover, high levels of Id-1 expression and the activity of a approximately 120-kDa gelatinase correlated with a less-differentiated and more-aggressive phenotype in human breast cancer cells. We suggest that Id-1 controls invasion by normal and neoplastic mammary epithelial cells, primarily through induction of a approximately 120-kDa gelatinase. This Id-1-regulated invasive phenotype could contribute to involution of the mammary gland and possibly to the development of invasive breast cancer.

Extracellular matrix remodeling and the regulation of epithelial-stromal interactions during differentiation and involution.

An intact basement membrane is essential for the proper function, differentiation and morphology of many epithelial cells. The disruption or remodeling of the basement membrane occurs during normal development as well as in the disease state. To examine the importance of basement membrane during development in vivo, we altered the matrix metalloproteinase and tissue inhibitor of metalloproteinases balance in mammary gland. Inhibition of matrix metalloproteinase synthesis by glucocorticoids or implants or transgenic overexpression of tissue inhibitor of metalloproteinases -1 delays matrix degradation and the involution process after weaning. The mammary glands from transgenic mice that inappropriately express auto-activating isoforms of stromelysin-1 are both functionally and morphologically altered throughout development. Transgenic mammary glands have supernumerary branches, and show precocious development of alveoli that express beta-casein expression and undergo unscheduled apoptosis during pregnancy. This is accompanied by progressive development of an altered stroma, which becomes fibrotic after postweaning involution, and by development of neoplasias. These data suggest that metalloproteinases and disruption of the basement membrane may play key roles in branching morphogenesis of mammary gland, cell cycle, apoptosis, and stromal fibrosis as well as in induction and progression of breast cancer.

Actin gene expression in murine erythroleukemia cells treated with cytochalasin D.

The expression of cytoskeletal protein genes may be linked to both cell growth and the status of the cytoskeleton. Actin gene expression was examined in murine erythroleukemia cells treated with the microfilament disrupting agent, cytochalasin D (CD), at a concentration which was determined to inhibit cell growth and arrest cells in the S and G1 phase of the cell cycle. Levels of actin mRNA and protein synthesis were elevated eight- and sixfold, respectively, after 9 h in CD. This increase was reflected in levels of nuclear run-on actin transcripts and prevented by actinomycin D, suggesting that enhanced transcription of the actin gene was responsible for the increase. Removal of CD resulted in immediate resumption of cell cycle progression with the accumulation of a G2-phase-enriched population and a rapid return of actin mRNA and protein synthesis to control levels (half-life 4.8 h). These results are consistent with a model linking actin gene expression to cell growth by regulating transcription during the G1 and mRNA decay during the G2 phase of the cell cycle.

Cytochalasin D-induced actin gene expression in murine erythroleukemia cells.

There is a dynamic equilibrium between monomeric G-actin and polymeric F-actin microfilaments (MFs) in eucaryotic cells. We have previously shown that disruption of MFs with cytochalasin D (CD) induced beta-actin gene transcription, resulting in elevated levels of beta-actin mRNA and protein synthesis. CD also inhibited cell growth by arresting progression through the S phase of the cell cycle. These CD-induced responses were reversible since recovering cells progressed through the G2 phase and resumed normal growth while beta-actin mRNA and protein synthesis rapidly returned to control levels. In the present study, we show that the response of beta- and gamma-actin genes is due to the synthesis of a protein(s) acting at a 5' regulatory element that may be independent of or require sequences in addition to the serum response element (SRE). CD induces beta- and gamma-actin mRNA in a dose-dependent manner, reaching a maximum of 20-fold over control mRNA levels at 30 microM. beta- and gamma-Actin gene expression was also induced 5-fold by serum stimulation of quiescent murine erythroleukemia (MEL) cells, while combined treatment with serum and CD had an additive effect. Two protein synthesis inhibitors, cycloheximide and puromycin, blocked the CD-induced increase in beta-actin mRNA, in contrast to the serum-induced increase which is insensitive to inhibitors of protein synthesis. The rapid return of beta-actin mRNA to basal levels following CD removal did not require protein synthesis nor did it require progression through the G2 phase of the cell cycle. A vector containing the 5' end of the beta-actin gene linked to a CAT reporter responded to CD when transfected into MEL cells, localizing the responsive element to the 5' portion of the beta-actin gene. By contrast, a minimal 99-bp actin promoter-CAT construct containing a functional SRE did not respond to CD.

Mammary gland tumor formation in transgenic mice overexpressing stromelysin-1.

An intact basement membrane (BM) is essential for the proper function, differentiation and morphology of many epithelial cells. The disruption or loss of this BM occurs during normal development as well as in the disease state. To examine the importance of BM during mammary gland development in vivo, we generated transgenic mice that inappropriately express autoactivating isoforms of the matrix metalloproteinase stromelysin-1. The mammary glands from these mice are both functionally and morphologically altered throughout development. We have now documented a dramatic incidence of breast tumors in several independent lines of these mice. These data suggest that overexpression of stromelysin-1 and disruption of the BM may be a key step in the multi-step process of breast cancer.

Misregulation of stromelysin-1 expression in mouse mammary tumor cells accompanies acquisition of stromelysin-1-dependent invasive properties.

Stromelysin-1 is a member of the metalloproteinase family of extracellular matrix-degrading enzymes that regulates tissue remodeling. We previously established a transgenic mouse model in which rat stromelysin-1 targeted to the mammary gland augmented expression of endogenous stromelysin-1, disrupted functional differentiation, and induced mammary tumors. A cell line generated from an adenocarcinoma in one of these animals and a previously described mammary tumor cell line generated in culture readily invaded both a reconstituted basement membrane and type I collagen gels, whereas a nonmalignant, functionally normal epithelial cell line did not. Invasion of Matrigel by tumor cells was largely abolished by metalloproteinase inhibitors, but not by inhibitors of other proteinase families. Inhibition experiments with antisense oligodeoxynucleotides revealed that Matrigel invasion of both cell lines was critically dependent on stromelysin-1 expression. Invasion of collagen, on the other hand, was reduced by only 40-50%. Stromelysin-1 was expressed in both malignant and nonmalignant cells grown on plastic substrata. Its expression was completely inhibited in nonmalignant cells, but up-regulated in tumor cells, in response to Matrigel. Thus misregulation of stromelysin-1 expression appears to be an important aspect of mammary tumor cell progression to an invasive phenotype.

The stromal proteinase MMP3/stromelysin-1 promotes mammary carcinogenesis.

Matrix metalloproteinases (MMPs) are invariably upregulated in the stromal compartment of epithelial cancers and appear to promote invasion and metastasis. Here we report that phenotypically normal mammary epithelial cells with tetracycline-regulated expression of MMP3/stromelysin-1 (Str1) form epithelial glandular structures in vivo without Str1 but form invasive mesenchymal-like tumors with Str1. Once initiated, the tumors become independent of continued Str1 expression. Str1 also promotes spontaneous premalignant changes and malignant conversion in mammary glands of transgenic mice. These changes are blocked by coexpression of a TIMP1 transgene. The premalignant and malignant lesions have stereotyped genomic changes unlike those seen in other murine mammary cancer models. These data indicate that Str1 influences tumor initiation and alters neoplastic risk.

Expression of autoactivated stromelysin-1 in mammary glands of transgenic mice leads to a reactive stroma during early development.

Extracellular matrix and extracellular matrix-degrading matrix metalloproteinases play a key role in interactions between the epithelium and the mesenchyme during mammary gland development and disease. In patients with breast cancer, the mammary mesenchyme undergoes a stromal reaction, the etiology of which is unknown. We previously showed that targeting of an autoactivating mutant of the matrix metalloproteinase stromelysin-1 to mammary epithelia of transgenic mice resulted in reduced mammary function during pregnancy and development of preneoplastic and neoplastic lesions. Here we examine the cascade of alterations before breast tumor formation in the mammary gland stroma once the expression of the stromelysin-1 transgene commences. Beginning in postpubertal virgin animals, low levels of transgene expression in mammary epithelia led to increased expression of endogenous stromelysin-1 in stromal fibroblasts and up-regulation of other matrix metalloproteinases, without basement membrane disruption. These changes were accompanied by the progressive development of a compensatory reactive stroma, characterized by increased collagen content and vascularization in glands from virgin mice. This remodeling of the gland affected epithelial-mesenchymal communication as indicated by inappropriate expression of tenascin-C starting by day 6 of pregnancy. This, together with increased transgene expression, led to basement membrane disruption starting by day 15 of pregnancy. We propose that the highly reactive stroma provides a prelude to breast epithelial tumors observed in these animals.