Crystal structure of the haemopexin-like C-terminal domain of gelatinase A.

The crystal structure of the haemopexin-like C-terminal domain of gelatinase A reveals that it is a four-bladed beta-propeller protein. The four blades are arranged around a channel-like opening in which Ca2+ and a Na-Cl+ ion pair are bound.

Matrix metalloproteinases in blood vessel development in human fetal skin and in cutaneous tumors.

In vitro angiogenesis models suggest that new blood vessel formation requires the induction and secretion by endothelial cells of matrix metalloproteinases. These enzymes assist in the controlled proteolytic degradation of the surrounding extracellular matrix during blood vessel formation. The results of in vitro studies cannot be extrapolated directly to the process of in vivo angiogenesis because the type of matrix employed and the repertoire of enzymes secreted by cells in vivo differ dramatically from in vivo conditions. To investigate the in vivo role of matrix metalloproteinases in blood vessel development, we looked for the presence of these proteinases in endothelial cells involved in fetal angiogenesis and in neovascularization of certain invasive skin tumors using immunofluorescent staining. In fetal tissue, interstitial collagenase was present in both early microvessels developing from undifferentiated mesoderm and in microvessels involved in elongation and sprout formation from preexisting blood vessels. In aggressive skin tumors, i.e., morpheaform and recurrent basal cell carcinomas and squamous cell carcinomas, there was a marked increase in the number of collagenase-containing blood vessels, often extending into the tumor nests. Immunofluorescent staining failed to detect stromelysin, matrilysin, or gelatinase A and B (72- and 92-kDa type IV collagenases, respectively) in fetal or tumor blood vessels. These findings are consistent with the hypothesis that proteolytic degradation of the extracellular matrix is required for the formation of new blood vessels. Interstitial collagenase appears to play an important role in this process.

Mechanism of cell surface activation of 72-kDa type IV collagenase. Isolation of the activated form of the membrane metalloprotease.

Matrix metalloproteases are secreted by mammalian cells as zymogens and, upon activation, initiate tissue remodeling by proteolytic degradation of collagens and proteoglycans. Activation of the secreted proenzymes and interaction with their specific inhibitors determine the net enzymatic activity in the extracellular space. We have previously demonstrated that 72T4Cl can be activated by a plasma membrane-dependent mechanism specific for this enzyme. Here, we report purification of the membrane activator of 72T4Cl, which is a new metalloprotease identical to a recently cloned membrane-type matrix metalloprotease (MT-MMP). We demonstrate that activated MT-MMP acts as a cell surface tissue inhibitor of metalloprotease 2 (TIMP-2) receptor with Kd = 2.54 x 10(-9) M. The activator.TIMP-2 complex in turn acts as a receptor for 72T4Cl (Kd = 0.56 x 10(-9) M, binding to the carboxyl-end domain of the enzyme. Activation of 72T4Cl on the cell membrane provides a basic mechanism for spatially regulated extracellular proteolysis and presents a new target for prognosis and treatment of metastatic disease. The activation, purified as a tri-molecular complex of MT-MMP.TIMP2.carboxyl-end domain of 72T4Cl, is itself an activated form of MT-MMP, posing the following question: what is the mechanism of the activator's activation?

Matrilysin (PUMP) correlates with dermal invasion during appendageal development and cutaneous neoplasia.

Matrix-degrading metalloproteinases play a major role in tissue remodeling. Recent studies have shown that enzymes of this class are constitutively expressed primarily by stromal cells and not by epithelium. Here we present immunohistochemical evidence that matrilysin is localized within epidermal cells in developing skin and in tumor cells of cutaneous malignancies. The expression of matrilysin protein in developing fetal skin (6-15 weeks) is localized primarily to the germinative basal cell layer of fetal epidermis and early appendageal buds. The buds continue to express matrilysin during mesenchymal invasion. As development progresses (15-19 weeks) matrilysin is concentrated only in cells at the distal portion of the invading follicular and sweat gland appendageal cords. In adult skin, matrilysin was localized specifically to the outer root sheath of the hair follicles and the secretory cells of the eccrine glands but was absent in the epidermis. Nodulocystic, keratotic, adenoid basal cell carcinomas (BCCs) did not express matrilysin. In contrast, in the more aggressive morpheaform (infiltrative) BCCs and recurrent BCCs, matrilysin was localized at the tumor-stromal interface. In squamous cell carcinomas matrilysin was present in tumor cells at the stromal interface surrounding the tumor nests. The demonstration of matrilysin protein in germinal basal cells during fetal skin development and its presence in tumor cells at the stromal junction suggests that this enzyme may contribute to the proteolytic activity associated with cell-extracellular matrix interactions during appendageal development and tumor invasion.

Expression of 92-kD type IV collagenase/gelatinase (gelatinase B) in osteoarthritic cartilage and its induction in normal human articular cartilage by interleukin 1.

We report here that a 92-kD gelatinolytic metalloproteinase is expressed as protein and mRNA in human osteoarthritic cartilage, but not in normal adult articular cartilage. Western immunoblotting demonstrated that the 92-kD gelatinolytic activity corresponded to 92-kD type IV collagenase/gelatinase (gelatinase B); mRNA for gelatinase B was identified by Northern blotting. Chondrocytes from normal cartilage also exhibited mRNA for 72-kD type IV collagenase/gelatinase (gelatinase A), tissue collagenase, and stromelysin-1, and these mRNAs were increased in osteoarthritic cartilage. Regional analysis of osteoarthritic cartilage samples from four individuals revealed that gelatinase B mRNA was expressed in grossly fibrillated areas; two of four nonfibrillated cartilage samples failed to exhibit the mRNA, but did have increased levels of mRNA for other neutral metalloproteinases. IL-1 alpha treatment of normal human cartilage explants or isolated chondrocytes induced increased levels of gelatinase B and increased mRNA for tissue collagenase and stromelysin-1. Under identical conditions, mRNA levels for gelatinase A were not increased indicating that regulation of this enzyme in human articular chondrocytes is distinct from that of other metalloproteinases. Our data showing expression of gelatinase B in fibrillated cartilage suggest that it is a marker of progressive articular cartilage degradation in osteoarthritis.

Plasma membrane-dependent activation of the 72-kDa type IV collagenase is prevented by complex formation with TIMP-2.

Human 72-kDa type IV collagenase (72T4Cl) is secreted as a proenzyme that can form a specific stoichiometric complex with the tissue inhibitor of metalloproteases TIMP-2 via interaction with the carboxyl-terminal domain of the enzyme. Both complexed and free enzymes can be activated by treatment with organomercurials. The mechanism of the 72T4Cl activation under physiological conditions is not known. Here we describe a "plasma membrane-dependent" activation of inhibitor-free 72T4Cl and identify the first conversion intermediate as a 64-kDa species resulting from cleavage of the Asn37-Leu peptide bond in the presence of plasma membranes from 12-O-tetradecanoylphorbol-13-acetate-induced HT1080 cells. This reaction is specific for 72T4Cl in that a closely related proenzyme (92-kDa type IV collagenase) is resistant to activation under the same conditions. Formation of the 72T4Cl.TIMP-2 complex inhibits activation at the level of the initial Asn37-Leu cleavage. Addition of TIMP-1 has no effect on this reaction, but blocks the autocatalytic conversion of the Leu38 intermediate into a 62-kDa active enzyme with an amino-terminal Tyr81. Membrane-dependent activation of 72T4Cl is competitively inhibited in the presence of a 26-kDa peptide derived from the carboxyl-terminal domain of the enzyme. The results suggest that interaction of the carboxyl-terminal domain of the enzyme with a membrane-associated component(s) causes initiation of enzyme activation through an autoproteolytic mechanism.

Localization of 92-kDa type IV collagenase in human skin tumors: comparison with normal human fetal and adult skin.

To investigate the role of secreted metalloproteinases in the behavior of skin tumors we have studied immunoreactivity for 92-kDa type IV collagenase (92T4Cl) in benign tumors of sweat glands, basal cell carcinomas (BCC), baso-squamous cell carcinomas (BSCC), and squamous cell carcinomas (SCC). In all tumors, the enzyme was found in stromal cells, but not in tumor epithelium. 92T4Cl-positive cells contained the common leukocyte antigen HLe-1(CD45) and the polymorphonuclear leukocyte-specific antigen PMN-8C7. Only a few 92T4Cl-positive cells expressed either macrophage-specific Leu-M5 or eosinophil-specific cationic protein antigens. In benign sweat gland tumors, and in the majority of nodulocystic and adenoid BCCs, 92T4Cl-positive cells were relatively rare and no extracellular deposition of the enzyme was found. In the more aggressive tumors examined, SCCs, BSCC, recurrent, infiltrative, and morpheaform BCCs, 92T4Cl-positive cells were very abundant. In addition, a significant quantity of extracellular enzyme was deposited both within the extracellular matrix adjacent to the tumor nests and in their basement membrane zone. In normal adult skin only a few scattered 92T4Cl-containing cells were found in the dermis whereas in fetal skin, groups of 92T4Cl-positive, HLe-1-negative cells were present in the upper dermis. These observations suggest that in cutaneous tumors, extensive infiltration of 92T4Cl containing polymorphonuclear leukocytes and the extracellular deposition of the enzyme in the basement membrane zone are signs of more aggressive tumor behavior.

Human 92 kDa type IV collagenase: functional analysis of fibronectin and carboxyl-end domains.

Two closely related secreted metalloproteases 72 and 92 kDa type IV collagenases (72- and 92T4Cl) consist of several structural domains, the functions of which are poorly understood. Both metalloproteases can bind to gelatin as well as form complexes with specific inhibitors in the proenzyme form. The biologic role of the proenzyme-inhibitor complex formation remained unclear. Here we summarize results demonstrating that the fibronectin-like domain of 92T4Cl mediates gelatin binding of the proenzyme, while the hemopexin like carboxy-terminal domain is essential for the complex formation of the proenzyme with TIMP. The formation of a 92T4Cl proenzyme complex with TIMP prevents dimerization, formation of the novel complex with ClI proenzyme, and activation of the 92T4Cl by stromelysin. Conversely, formation of the covalent 92T4Cl homodimer excludes the formation of a proenzyme-TIMP complex, thus allowing this form of enzyme to enter into the proteolytic cascade of activation. Both components of the 92T4Cl-ClI complex can be activated in a fashion similar to that of free enzymes, yielding a complex active against both gelatin and fibrillar collagen.

Alanine scanning mutagenesis and functional analysis of the fibronectin-like collagen-binding domain from human 92-kDa type IV collagenase.

The human 72-kDa (CLG4A) and 92-kDa (CLG4B) type IV collagenases contain a domain consisting of three contiguous copies of the fibronectin (FN)-derived type II homology unit (T2HU), T2HU-1, T2HU-2, and T2HU-3. To investigate the functional role of this domain, we have constructed plasmids expressing beta-galactosidase fusion proteins with one or more of the CLG4B-derived T2HU. The gelatin binding assays demonstrate that a single copy of T2HU-2 renders beta-galactosidase capable of binding gelatin. The three repeats, however, differ dramatically in their capacity to bind gelatin, with T2HU-1 and T2HU-3 having significantly less binding activity than T2HU-2. Using alanine scanning mutagenesis we have defined the amino acid residues (Arg307, Asp309, Asn319, Tyr320, Asp323) that are critical for gelatin binding of T2HU-2. The low gelatin binding of T2HU-1 compared to T2HU-2 was traced to the non-conserved residues Ala228-Ala and Leu253-Pro. The results suggest that the gelatin binding of the type IV collagenase proenzyme is mediated by the FN-like domain, although the presence of another gelatin-binding site cannot be excluded. The FN domain-mediated binding, however, is not a rate-limiting step in the hydrolysis of gelatin by the enzyme.

Interaction of 92-kDa type IV collagenase with the tissue inhibitor of metalloproteinases prevents dimerization, complex formation with interstitial collagenase, and activation of the proenzyme with stromelysin.

Secreted metalloproteases initiating proteolytic degradation of collagens and proteoglycans play a critical role in remodeling of the connective tissue. Activation of the secreted proenzymes and interaction with their specific inhibitors TIMP and TIMP-2 are responsible for regulation of enzyme activity in extracellular space. We have previously demonstrated that 92- and 72-kDa Type IV procollagenases, in contrast to interstitial collagenase (ClI), form specific complexes with TIMP and the related inhibitor TIMP-2, respectively. The physiologic significance of the proenzyme-inhibitor complex and the mechanism of activation of Type IV collagenases remained unclear. Here, we demonstrate that in the absence of TIMP, 92-kDa Type IV procollagenase (92T4Cl) can form a covalent homodimer and a novel complex with ClI. In the presence of TIMP, the formation of a 92T4Cl proenzyme complex with TIMP prevents dimerization, formation of the complex with ClI, and activation of the 92T4Cl proenzyme by stromelysin, a related metalloprotease. The proenzyme homodimer is unable to form a complex with TIMP. All TIMP-free forms of the proenzyme can be activated by stromelysin. The 92T4Cl-ClI complex can be activated to yield a complex active against both gelatin and fibrillar Type I collagen, suggesting a mechanism for cooperative action of two enzymes in reducing collagen fibrils to small peptides under physiologic conditions.

Mosaic structure of the secreted ECM metalloproteases and interaction of the type IV collagenases with inhibitors.

SV-40 transformed human lung fibroblasts and HT 1080 fibrosarcoma cells secrete a 92-kDa type IV collagenase (in addition to 72-kDa type IV collagenase identical to that found in macrophages, phorbol ester differentiated U937 cells, and keratinocytes. The expression of this protease is induced by the tumor promoter TPA, and interleukin-1 and was not detected in the parental human lung fibroblast. The 92-kDa preproenzyme has a predicted Mr of 78,426, including a 19 amino acid long hydrophobic signal peptide. The apparent discrepancy between the predicted molecular weight and the molecular weight of the secreted protein is due to a post-translational modification of the enzyme through glycosylation. The 92-kDa type IV collagenase consists of five distinct domains, including a unique 54 amino acid long collagen--like domain, and is a member of the secreted ECM metalloprotease gene family. Both the 72 and 92-kDa type IV collagenase contain a fibronectin-like collagen binding domain. The mosaic structure of the secreted ECM metalloproteases is a result of a recruitment of the functional units from ECM structural macromolecules into an enzyme protein in the process of evolution. The 92-kDa and 72-kDa type IV collagenase proenzymes form a noncovalent complex with inhibitors, which is activatable by APMA, yielding an enzymes with similar if not identical substrate specificity profile. Our results demonstrate that while the 92-kDa type IV collagenase forms a stoichiometric complex with TIMP, the 72-kDa type IV collagenase, purified from the same starting material, contains a novel 24-kDa inhibitor-TIMP-2.

Activation of extracellular matrix metalloproteases by proteases and organomercurials.

Extracellular matrix metalloproteases are synthesized as proenzymes and are activated by certain physiological agents after secretion into the extracellular space. The identity of these agents and the stimulus that elicits their response in vivo is only recently becoming clear, but a variety of agents or stimuli are capable of activating these metalloproteases in vitro also. Of these, the most well studied and characterized are trypsin, plasmin and the organomercurials. These agents appear to have in common an ability to disrupt the structure of the stable latent enzyme in such a way as to allow the generation of a proteolytic active site. In the case of organomercurial activation, intramolecular proteolytic cleavage of the amino-terminus of the enzyme occurs subsequent to generation of activity. A similar intramolecular process is seen with trypsin and plasmin activation except that it is initiated by a single trypsin or plasmin catalyzed cleavage in the amino-terminus prior to the autocatalytic cleavages. A possible explanation for organomercurial activation is that the mercurial disrupts a cysteinyl residue coordination bond with the active site zinc that prevents interaction with substrate. Disruption of this complex would allow productive enzyme-substrate interaction via the newly available coordination site. In addition, activated stromelysin is capable of increasing the specific activity of active interstitial collagenase by approximately ten-fold through what appears to be proteolytic removal of a small peptide.

Primary structure and function of stromelysin/transin in cartilage matrix turnover.

Stromelysin/Transin is a member of the matrix metalloprotease gene family. This metalloprotease is synthesized as a preproenzyme with a predicted size of 53,977 Da including a 17 amino acid signal peptide. Prostromelysin is secreted from normal and transformed cells in two forms with apparent molecular masses on NaDodSO4 gels of 60 and 58-kDa. The minor 60-kDa species contains N-linked oligosaccharide(s). Stromelysin consists of three domains the amino terminal propeptide(s) domain contains the tribasic amino acid sequence RRK which is important in the proteolytic activation of this zymogen by trypsin-like serine proteases. The second domain consists of the catalytic domain which contains the zinc binding site. The carboxyl-terminal hemopexin domain has no known function and can be removed without a loss of enzymatic activity. Stromelysin has a broad range of substrate specificity including proteoglycans, casein, fibronectin, laminin, native type IV and IX collagen and gelatin but not type I collagen. In the presence of trypsin or plasmin, catalytic amounts of this enzyme can also fully activate interstitial fibroblast collagenase. We have developed a panel of monoclonal antibodies against stromelysin which will be useful for the tissue localization of the various species of this enzyme in tissues. In addition, we have demonstrated that either human rIL-1 (alpha) or rTNF (alpha) can stimulate the expression of this enzyme in cultured bovine articular cartilage at least 10-fold. Based on western blot analysis, the zymogen form of the enzyme was the major enzyme species detected in either the media or cartilage matrix compartments of cytokine treated cultures.

Human 92- and 72-kilodalton type IV collagenases are elastases.

Elastin is critical to the structural integrity of a variety of connective tissues. Only a select group of enzymes has thus far been identified capable of cleaving insoluble elastin. Recently, we observed that human alveolar macrophages secrete elastase activity that is largely inhibited by the tissue inhibitor of metalloproteinases (TIMP). This finding suggested that one or more of the metalloproteinases released by alveolar macrophages has elastase activity. Accordingly, we tested pure human interstitial collagenase, stromelysin, 92-kDa type IV collagenase, and 72-kDa type IV collagenase for elastolytic activity using kappa-elastin zymography and insoluble 3H-labeled elastin. The 92- and 72-kDa type IV collagenases were found to be elastolytic in both assay systems. A recombinant preparation of 92-kDa type IV collagenase with gelatinolytic activity was also found to be elastolytic. Organomercurial activation was essential to detect elastolytic activity of the native 92- and 72-kDa type IV collagenases and enhanced the elastase activity of the recombinant 92-kDa enzyme. On a molar basis the recombinant 92-kDa type IV collagenase was approximately 30% as active as human leukocyte elastase in solubilizing 3H-labeled elastin. Exogenously added TIMP in significant molar excess abolished the elastase activity of the 92- and 72-kDa type IV collagenases. Stromelysin and interstitial collagenase showed no significant elastolytic activity, although both were catalytically active against susceptible substrates. Conditioned media from cultures of human mononuclear phagocytes containing the 92-kDa enzyme produced a distinct zone of lysis in the kappa-elastin zymograms at this molecular mass. These results definitively extend the spectrum of human proteinases with elastolytic activity to metalloproteinases and suggest the enzymatic basis for elastase activity observed with certain cell types such as human alveolar macrophages.

On the structure and chromosome location of the 72- and 92-kDa human type IV collagenase genes.

The 72- and 92-kDa type IV collagenases are members of a group of secreted zinc metalloproteases. Two members of this family, collagenase and stromelysin, have previously been localized to the long arm of chromosome 11. Here we assign both of the two type IV collagenase genes to human chromosome 16. By sequencing, the 72-kDa gene is shown to consist of 13 exons, 3 more than have been reported for the other members of this gene family. The extra exons encode the amino acids of the fibronectin-like domain which has so far been found in only the 72- and 92-kDa type IV collagenase. The evolutionary relationship among the members of this gene family is discussed.

Neutral proteinases of human mononuclear phagocytes. Cellular differentiation markedly alters cell phenotype for serine proteinases, metalloproteinases, and tissue inhibitor of metalloproteinases.

Mononuclear phagocytes have the capacity to directly participate in extracellular matrix turnover via secretion of neutral proteinases. We have studied the effects of in vivo and in vitro differentiation upon cellular content or secretion of a spectrum of neutral proteinases, along with a counter-regulatory metalloproteinase inhibitor (TIMP). We found 1) matrix-degradative serine proteinases (leukocyte elastase and cathepsin G) were lost during cellular maturation and/or differentiation; 2) the 92-kDa type IV/type V collagenase and TIMP were secreted earliest in mononuclear phagocyte differentiation, whereas stromelysin secretion was observed only by LPS-stimulated alveolar macrophages; 3) exposure of alveolar macrophages, but not monocytes, to phorbol esters and LPS resulted in markedly augmented secretion of all studied metalloproteinases and TIMP; 4) monocyte-derived macrophages partially (but not completely) mimicked the metalloproteinase secretory phenotype of alveolar macrophages; and 5) the secretory phenotype of alveolar macrophages for interstitial collagenase (but not TIMP) was largely lost during in vitro culture. These results underscore the complexity of the process of differentiation in human mononuclear phagocytes, and provide insights into the variable capacity of mononuclear phagocytes to degrade extracellular matrix components. Moreover, we anticipate that human mononuclear phagocytes at various stages of differentiation will provide a useful model system for study of the variable regulation of secretion of human matrix-degrading metalloproteinases.

Neutral metalloproteinases produced by human mononuclear phagocytes. Enzyme profile, regulation, and expression during cellular development.

Mononuclear phagocytes are developmentally and functionally complex cells that play critical roles in extracellular matrix remodeling. We hypothesized that differentiated mononuclear phagocytes, typified by alveolar macrophages, use a spectrum of metalloproteinases to degrade various matrix macromolecules. To test this hypothesis, we have evaluated synthesis and secretion of four metalloproteinases (interstitial collagenase, stromelysin, 72-kD type IV collagenase, and 92-kD type IV collagenase) by human mononuclear phagocytes with regard to (a) the effect of cellular differentiation, (b) regulation of secretion, and (c) comparisons/contrasts with a prototype metalloproteinase-secretory cell, the human fibroblast. We found that regulated secretion of greater quantities and a wider spectrum of metalloenzymes correlated with a more differentiated cellular phenotype. As extreme examples, the 92-kD type IV collagenase was released by peripheral blood monocytes and uninduced U937 monocyte-like cells, whereas stromelysin was secreted only by lipopolysaccharide-stimulated alveolar macrophages. Macrophage production of interstitial collagenase, stromelysin, and 72-kD type IV collagenase was approximately 20%, 10%, and 1-2%, respectively, of that from equal numbers of fibroblasts; secretion of the 92-kD type IV collagenase was not shared by fibroblasts. This work confirms the potential of macrophages to directly degrade extracellular matrix via secreted metalloproteinases in a manner that differs both qualitatively and quantitatively from that of fibroblasts. Moreover, varying regulation of metalloenzyme synthesis, evidenced by distinct patterns of basal and stimulated secretion during differentiation, can be studied at a molecular level in this model system.

Human neutrophil collagenase. A distinct gene product with homology to other matrix metalloproteinases.

We have identified and sequenced a cDNA encoding human neutrophil collagenase from a lambda gt11 cDNA library constructed from mRNA extracted from the peripheral leukocytes of a patient with chronic granulocytic leukemia. The library was screened with an oligonucleotide probe constructed from the putative zinc-binding region of fibroblast collagenase. Eleven positive clones were identified, of which the one bearing the largest insert (2.2 kilobases (kb)) was sequenced. From the nucleotide sequence of the 2.2-kb cDNA clone we have deduced a 467-amino acid sequence representing the entire coding sequence of the enzyme. The deduced protein was confirmed as neutrophil collagenase by conformity with the amino-terminal sequence analyses of three tryptic peptides of purified neutrophil collagenase. The cDNA clone hybridizes to a 3.3-kb mRNA present in RNA extracted from human bone marrow but did not hybridize with RNA isolated from U937 cells induced to differentiate with phorbol myristate acetate. Neutrophil collagenase was found to possess 57% identity with the deduced protein sequence for fibroblast collagenase with 72% chemical similarity. Certain regions of the molecule, including the putative zinc-binding region, are highly conserved. When compared with the published sequence for fibroblast collagenase, neutrophil collagenase contains four additional sites for glycosylation. Medium from COS-7 cells transfected with a pcDNA1 eucaryotic expression vector containing cDNA for neutrophil collagenase degraded type I collagen into the three-quarter, one-quarter fragments characteristic of mammalian interstitial collagenase activity. Thus, definitive evidence based on the cDNA sequence confirms the neutrophil collagenase is a distinct gene product and a member of the family of matrix metalloproteinases.

Adenovirus E1A represses protease gene expression and inhibits metastasis of human tumor cells.

Stable transfection of human tumor cell lines with the adenovirus-5 E1A gene repressed the expression of the secreted proteases, type IV collagenase, interstitial collagenase and urokinase. In addition, E1A blocked the 12-O-tetradecanoyl phorbol acetate (TPA) induction of interstitial collagenase transcription in HT1080 fibrosarcoma cells. Plasmids bearing the interstitial collagenase or type IV collagenase 5' flanking regions linked to a chloramphenicol acetyl transferase coding sequence were constructed and analysed for expression by transient cotransfections into HT1080 cells. Cotransfection with a plasmid bearing a functional E1A gene repressed transcription of the type IV collagenase promoter and blocked the TPA induction of the interstitial collagenase promoter. Furthermore, E1A repressed transcription from a TK promoter driven by AP-1 complex binding sites (TRE), suggesting that E1A interferes with the AP-1 trans-activation pathway. This effect was not, however, due to the repression of c-jun gene transcription by E1A. In fact, the expression of E1A rendered the c-jun gene hypersensitive to TPA induction. Concomitant with reduction in expression levels of secreted proteases, stable E1A transfectants showed reduced metastatic activity in vivo and reduced ability to traverse a reconstituted basement membrane in vitro. Monospecific anti-type IV collagenase antibodies inhibited invasive activity of parental tumor cell lines in the in vitro assay, suggesting a possible causal relationship between the repression of secreted proteases and loss of metastatic properties of the transformants.