Topological localization of plasminogen activator inhibitor type 2

BACKGROUND: Plasminogen activator inhibitor type 2 (PAI-2) is a member of the serine protease inhibitor (SERPIN) superfamily and forms stable complexes with urokinase type plasminogen activator (uPA). uPA can be found on the cell surface attached to its specific receptor (uPAR), allowing for controlled degradation of the extracellular matrix by the activation of plasminogen into plasmin. The aim of this study was to evaluate if PAI-2 could also be detected on the cell surface, providing a means of regulating the activity of cell surface uPA. METHODS: Intact or permeabilized cell lines or human peripheral blood leukocytes were assayed by flow cytometry for cell surface uPA or PAI-2. Plasma membrane-enriched preparations prepared from Jurkat, HaCaT, THP-1, U937, or MM6 cells were assayed by enzyme-linked immunosorbent assay (ELISA) or Western blotting for PAI-2 antigen. RESULTS: By flow cytometry, cell surface PAI-2 was not detected on monocytes from human peripheral blood, MM6, or HaCaT cells. Cell surface PAI-2 was only detected very weakly on the surface of U937 cells. In contrast, PAI-2 could be detected in all of these cells when fixed and permeabilized. By ELISA, PAI-2 was very abundant in the cytosol-enriched preparations of U937, MM6, and HaCaT cells, but was present in lower amounts in the plasma membrane-enriched preparations. By Western blotting, monomeric nonglycosylated PAI-2, but not uPA/PAI-2 complexes, could be detected in the cytosol and plasma membrane-enriched preparations. CONCLUSIONS: These results indicate that PAI-2 cannot be detected on the surface of PAI-2-expressing cells, and confirm that PAI-2 is predominantly a cytosolic protein.     

Expression of plasminogen activator and plasminogen activator inhibitor mRNA in human fibroblasts grown on different substrates

mRNA levels for urokinase type plasminogen activator (uPA), tissue type plasminogen activator (tPA), plasminogen activator inhibitor-1 (PAI-1) and plasminogen activator inhibitor-2 (PAI-2) were examined in human diploid (neonatal foreskin) fibroblasts grown in 200-ml microcarrier suspension culture. Four different substrates were used. These included gelatin-coated polystyrene plastic, DEAE-dextran, glass-coated polystyrene plastic and uncoated polystyrene plastic. Our previous studies have shown that culture fluids from diploid fibroblasts grown on DEAE-dextran contained higher levels of plasminogen-dependent fibrinolytic activity than culture fluids from the same cells grown on other substrates. The increased plasminogen activator activity was due largely to elevated amounts of tPA (In Vitro Cell. Develop. Biol. 22: 575–582, 1986). The present study shows that there is a corresponding elevation of tPA mRNA in diploid fibroblasts cultured on DEAE-dextran relative to the other substrates. There does not appear to be any difference in uPA mRNA or in mRNA for PAI-1 or PAI-2 produced by the same cells on the four substrates. These data suggest that the influence of the substrate on plasminogen activator production is mediated at the genetic level.     

Regulated localization confers multiple functions on the protease urokinase plasminogen activator

We have investigated the role of the plasminogen activation cascade in skeletal muscle differentiation. Migrating, undifferentiated myoblasts express urokinase plasminogen activator (uPA) and its cell surface receptor (uPAR). Consequently, uPA is localized predominantly to the cell surface. Preventing uPA from associating with its receptor with a noncatalytic form of uPA (NC-uPA) hinders migration of myoblasts and inhibits differentiation. When myoblasts reach confluence, cease migrating, and start to differentiate, uPAR gets downregulated, and uPA becomes redistributed from the cell surface to the extracellular space. The function of uPA at this stage was tested using the protease inhibitors aprotinin, α₂-antiplasmin, or plasminogen activator inhibitor-1 (PAI-1). Contrary to the role of cell-associated uPA, inhibition of soluble uPA/plasmin stimulates differentiation of myoblasts. Aprotinin can inhibit activation of latent TGFβ and stimulates differentiation, suggesting PAI-1 and α₂-antiplasmin also may stimulate differentiation via this mechanism. These data suggest that regulation of uPA localization allows a dual function for this protease in regulating cell migration and controlling cell differentiation. J. Cell. Physiol. 171:217–225, 1997. © 1997 Wiley-Liss, Inc.     

Prostaglandin E2 regulates production of plasminogen activator isoenzymes,urokinase receptor,and plasminogen activator inhibitor-1 in primary cultures of rat calvarial osteoblasts

The bone resorbing agent, prostaglandin E₂ (PGE₂), was found to alter several components of the plasminogen activator (PA)/plasmin pathway in primary cultures of rat neonatal osteoblast-like cells. The mRNA and activities of both urokinase-type PA (uPA) and tissue-type PA (tPA) were enhanced by PGE₂ treatment. The presence of mRNA for the uPA receptor (uPAR) has been demonstrated in these cells and steady-state levels shown to be greatly enhanced, the response being rapid and sustained for at least 24 hours. mRNA for plasminogen activator inhibitor 1 (PAI-1) was modulated in a biphasic manner, with inhibition of the constitutive level apparent at 4 hours of treatment and stimulation apparent at 12 hours and longer, while PAI-1 protein, measured by an ELISA assay for rat PAI-1, was diminished over this period. Neither PAI-2 mRNA nor mRNA for the broad spectrum protease inhibitor, protease nexin-1 (PN-1), was found to be modulated by PGE₂. Therefore, PGE₂ is likely to stimulate cell surface proteolytic activity, since uPA mRNA and cell-associated activity were elevated, as was mRNA for the cellular receptor for uPA. Although it was not possible to measure uPAR number and affinity it seems likely that elevated uPAR mRNA would translate into increased uPARs which would localize the increased uPA activity to the pericellular region. tPA mRNA and activity were also increased transiently with the activity inhibited with prolonged incubations, apparently by PAI-1. Elevation of tPA mRNA and activity may result in elevated activity within the extracellular matrix as tPA has been reported to associate with several matrix proteins. Thus the early effect of PGE₂ would be to promote proteolysis, both pericellularly and in the extracellular matrix. The inhibition of PAI-1 mRNA and protein, which would contribute to the elevation of activity, is due to PGE₂, but the later stimulatory effect on PAI-1 mRNA may be due to feedback regulation by transforming growth factor beta (TGFβ), secreted by osteoblasts and activated by elevated levels of PA. © 1995 Wiley-Liss Inc.     

Differential Expression of Urokinase-Type Plasminogen Activator (uPA), Its Receptor (uPA-R), and Inhibitor Type-2 (PAI-2) during Differentiation of Keratinocytes in an Organotypic Coculture System

Cultured keratinocytes resemble migrating keratinocytes under conditions of reepithelialization during wound healing. Such keratinocytes express urokinase-type plasminogen activator (uPA) and its specific receptor (uPA receptor). Receptor-bound uPA activates plasminogen, thus providing plasmin for pericellular proteolysis. uPA is regulated by the plasminogen activator inhibitors PAI-1 and PAI-2. As indicated by immunohistology, neither uPA nor uPA receptor is expressed in normal epidermis. Thus, the down-regulation of uPA and uPA-receptor expression in keratinocytes appears to be an important event in epidermal healing and restoration of a normal epidermal tissue architecture. We have addressed this matter by using a culture and differentiation system for keratinocytes in vitro. Keratinocytes were grown in organotypic cocultures for 4, 7, and 14 days. Frozen sections were analyzed with indirect immunofluorescence staining and overlay zymography, the latter detecting activity of plasminogen activators. While tPA and PAI-I stainings were consistently negative over the entire observation period, uPA and uPA receptor were expressed by basal keratinocytes at Days 4 and 7, but not at Day 14. Accordingly, overlay zymography revealed uPA activity at Days 4 and 7. PAI-2 was found throughout the entire observation period, but with varying distribution: at Days 4 and 7 all suprabasal keratinocytes stained positive for PAI-2. At Day 14, PAI-2-specific stainings were confined to the uppermost cells of the stratum spinosum. Our data demonstrate that uPA and uPA receptor, which are up-regulated in cultured keratinocytes, are down-regulated upon restoration of an epidermis-like structure. The distribution of PAI-2 varied over the observation period and at Day 14 resembled the distribution of PAI-2 in normal epidermis. Taken together, keratinocytes in organotypic coculture behave like keratinocytes in healing wounds in vivo with respect to the expression of the plasminogen activator system.     

Insulin-like growth factor-binding protein-5 activates plasminogen by interaction with tissue plasminogen activator, independently of its ability to bind to plasminogen activator inhibitor-1, insulin-like growth factor-I, or heparin

Transgenic mice expressing IGFBP-5 in the mammary gland exhibit increased cell death and plasmin generation. Because IGFBP-5 has been reported to bind to plasminogen activator inhibitor-1 (PAI-1), we determined the effects of this interaction in HC11 cells. PAI-1 prevented plasmin generation from plasminogen and inhibited cleavage of focal adhesions, expression of caspase 3, and cell death. IGFBP-5 could in turn prevent the effects of PAI-1. IGFBP-5 mutants with reduced affinity for IGF-I (N-term) or deficient in heparin binding (HEP- and C-term E and F) were also effective. This was surprising because IGFBP-5 reportedly interacts with PAI-1 via its heparin-binding domain. Biosensor analysis confirmed that, although wild-type IGFBP-5 and N-term both bound to PAI-1, the C-term E had greatly decreased interaction with PAI-1. This suggests that IGFBP-5 does not antagonize the actions of PAI-1 by a direct molecular interaction. In a cell-free system, using tissue plasminogen activator (tPA) and urokinase plasminogen activator (uPA) to activate plasminogen, PAI-1 inhibited plasmin generation induced by both activators, whereas IGFBP-5 prevented the effects of PAI-1 on tPA but not uPA. Furthermore, we noted that IGFBP-5 activated plasminogen to a greater extent than could be explained solely by inhibition of PAI-1, suggesting that IGFBP-5 could directly activate tPA. Indeed, IGFBP-5 and the C-term E and F were all able to enhance the activity of tPA but not uPA. These data demonstrate that IGFBP-5 can enhance the activity of tPA and that this can result in cell death induced by cleavage of focal adhesions. Thus IGFBP-5 can induce cell death by both sequestering IGF-I and enhancing plasmin generation.     

Characterization of morphogenetic and invasive abilities of human mammary epithelial cells: Correlation with variations of urokinase-type plasminogen activator activity and type-1 plasminogen activator inhibitor level

Urokinase-type plasminogen activator (uPA) and one of its inhibitors, the PAI-1, are involved in the proteolytic cascade of matrix degradation during in vivo morphogenesis or metastasis. In the present study, we have characterized the in vitro morphological behavior of human normal and malignant mammary epithelial cells and determined the levels of uPA activity and PAI-1 during these events. Two-dimensional cultures in the presence of inductive fibroblast-conditioned medium (CM) allowed migration of HBL-100 cells and MDA-MB-231 cells. Normal human mammary epithelial cells (HMEC) and MCF-7 cells failed to migrate under these conditions. The epithelial cell migration correlated with an increase in the uPA activity whereas their immobility correlated with both increases in uPA activity and PAI-1 level. In three-dimensional cultures in collagen gel, fibroblasts or fibroblast CM induced branching tubular morphogenesis to HMEC, cord-like extensions to HBL-100 cells and a greater invasiveness ability to MDA-MB-231 cells. These events correlated with an increased uPA activity. In contrast, no morphological rearrangement was observed in MCF-7 cells and this correlated with both increases in uPA activity and PAI-1 level. Altogether, these results show that the in vitro mammary epithelial behavior is under the influence of mesenchymal inductive signals and is in agreement with modifications of uPA activity and PAI-1 levels. Our culture system gives a suitable model to study the mechanisms of mammary development and metastasis and to highlight the involvement of proteases and their inhibitors in cell-cell positioning and cell-matrix reorganization.     

Collagen modulates gene activation of plasminogen activator system molecules

Skin extracellular matrix (ECM) molecules regulate a variety of cellular activities, including cell movement, which are central to wound healing and metastasis. Regulated cell movement is modulated by proteases and their associated molecules, including the serine proteases urinary-type plasminogen activator (uPA) and tissue-type plasminogen activator (tPA) and their inhibitors (PAIs). As a result of wounding and loss of basement membrane structure, epidermal keratinocytes can become exposed to collagen. To test the hypothesis that during wounding, exposed collagen, the most abundant ECM molecule in the skin, regulates keratinocyte PA and PAI gene expression, we utilized an in vitro model in which activated keratinocytes were cultured in dishes coated with collagen or other ECM substrates. tPA, uPA, and PAI-1 mRNA and enzymatic activity were detected when activated keratinocytes attached to fibronectin, vitronectin, collagen IV, and RGD peptide. In contrast, adhesion to collagen I and collagen III completely suppressed expression of PAI-1 mRNA and protein and further increased tPA expression and activity. Similarly, keratinocyte adhesion to laminin-1 suppressed PAI-1 mRNA and protein expression and increased tPA activity. The suppressive effect of collagen I on PAI-1 gene induction was dependent on the maintenance of its native fibrillar structure. Thus, it would appear that collagen- and laminin-regulated gene expression of molecules associated with plasminogen activation provides an additional dimension in the regulation of cell movement and matrix remodeling in skin wound healing.     

The plasminogen activator inhibitor PAI-1 controls in vivo tumor vascularization by interaction with proteases, not vitronectin. Implications for antiangiogenic strategies

The plasminogen (Plg)/plasminogen activator (PA) system plays a key role in cancer progression, presumably via mediating extracellular matrix degradation and tumor cell migration. Consequently, urokinase-type PA (uPA)/plasmin antagonists are currently being developed for suppression of tumor growth and angiogenesis. Paradoxically, however, high levels of PA inhibitor 1 (PAI-1) are predictive of a poor prognosis for survival of patients with cancer. We demonstrated previously that PAI-1 promoted tumor angiogenesis, but by an unresolved mechanism. We anticipated that PAI-1 facilitated endothelial cell migration via its known interaction with vitronectin (VN) and integrins. However, using adenoviral gene transfer of PAI-1 mutants, we observed that PAI-1 promoted tumor angiogenesis, not by interacting with VN, but rather by inhibiting proteolytic activity, suggesting that excessive plasmin proteolysis prevents assembly of tumor vessels. Single deficiency of uPA, tissue-type PA (tPA), uPA receptor, or VN, as well as combined deficiencies of uPA and tPA did not impair tumor angiogenesis, whereas lack of Plg reduced it. Overall, these data indicate that plasmin proteolysis, even though essential, must be tightly controlled during tumor angiogenesis, probably to allow vessel stabilization and maturation. These data provide insights into the clinical paradox whereby PAI-1 promotes tumor progression and warrant against the uncontrolled use of uPA/plasmin antagonists as tumor angiogenesis inhibitors.     

PAI-1 in tissue fibrosis

Fibrosis is defined as a fibroproliferative or abnormal fibroblast activation-related disease. Deregulation of wound healing leads to hyperactivation of fibroblasts and excessive accumulation of extracellular matrix (ECM) proteins in the wound area, the pathological manifestation of fibrosis. The accumulation of excessive levels of collagen in the ECM depends on two factors: an increased rate of collagen synthesis and or decreased rate of collagen degradation by cellular proteolytic activities. The urokinase/tissue type plasminogen activator (uPA/tPA) and plasmin play significant roles in the cellular proteolytic degradation of ECM proteins and the maintenance of tissue homeostasis. The activities of uPA/tPA/plasmin and plasmin-dependent MMPs rely mostly on the activity of a potent inhibitor of uPA/tPA, plasminogen activator inhibitor-1 (PAI-1). Under normal physiologic conditions, PAI-1 controls the activities of uPA/tPA/plasmin/MMP proteolytic activities and thus maintains the tissue homeostasis. During wound healing, elevated levels of PAI-1 inhibit uPA/tPA/plasmin and plasmin-dependent MMP activities, and, thus, help expedite wound healing. In contrast to this scenario, under pathologic conditions, excessive PAI-1 contributes to excessive accumulation of collagen and other ECM protein in the wound area, and thus preserves scarring. While the level of PAI-1 is significantly elevated in fibrotic tissues, lack of PAI-1 protects different organs from fibrosis in response to injury-related profibrotic signals. Thus, PAI-1 is implicated in the pathology of fibrosis in different organs including the heart, lung, kidney, liver, and skin. Paradoxically, PAI-1 deficiency promotes spontaneous cardiac-selective fibrosis. In this review, we discuss the significance of PAI-1 in the pathogenesis of fibrosis in multiple organs.     

A truncated plasminogen activator inhibitor-1 protein induces and inhibits angiostatin (kringles 1-3), a plasminogen cleavage product

Plasminogen activator inhibitor-1 (PAI-1) is a serpin protease inhibitor that binds plasminogen activators (uPA and tPA) at a reactive center loop located at the carboxyl-terminal amino acid residues 320-351. The loop is stretched across the top of the active PAI-1 protein maintaining the molecule in a rigid conformation. In the latent PAI-1 conformation, the reactive center loop is inserted into one of the beta sheets, thus making the reactive center loop unavailable for interaction with the plasminogen activators. We truncated porcine PAI-1 at the amino and carboxyl termini to eliminate the reactive center loop, part of a heparin binding site, and a vitronectin binding site. The region we maintained corresponds to amino acids 80-265 of mature human PAI-1 containing binding sites for vitronectin, heparin (partial), uPA, tPA, fibrin, thrombin, and the helix F region. The interaction of "inactive" PAI-1, rPAI-1(23), with plasminogen and uPA induces the formation of a proteolytic protein with angiostatin properties. Increasing amounts of rPAI-1(23) inhibit the proteolytic angiostatin fragment. Endothelial cells exposed to exogenous rPAI-1(23) exhibit reduced proliferation, reduced tube formation, and 47% apoptotic cells within 48 h. Transfected endothelial cells secreting rPAI-1(23) have a 30% reduction in proliferation, vastly reduced tube formation, and a 50% reduction in cell migration in the presence of VEGF. These two studies show that rPAI-1(23) interactions with uPA and plasminogen can inhibit plasmin by two mechanisms. In one mechanism, rPAI-1(23) cleaves plasmin to form a proteolytic angiostatin-like protein. In a second mechanism, rPAI-1(23) can bind uPA and/or plasminogen to reduce the number of uPA and plasminogen interactions, hence reducing the amount of plasmin that is produced.     

The THP-1 cell line is a urokinase-secreting mononuclear phagocyte with a novel defect in the production of plasminogen activator inhibitor-2

Mononuclear phagocytes regulate the generation of plasmin by secreting urokinase-type plasminogen activator (uPA) and plasminogen activator inhibitor-2 (PAI-2). We investigated the production of plasminogen activator (PA) and PA inhibitor by the human monocytic leukemia cell line, THP-1. Similar to U937 monoblast-like cells and peripheral blood monocytes (PBM), THP-1 cells produce a PA that is specifically neutralized by anti-uPA antibody and comigrates with human high molecular mass uPA (54 kDa) on casein-plasminogen zymogaphy. PA activity could be dissociated from intact THP-1 cells by brief treatment with a weak acid-glycine buffer, indicating that the uPA is secreted and bound to receptors on the plasma membrane. Regulation of uPA proceeds normally in THP-1 cells, with cell-associated PA activity increasing from 77 +/- 20 to 163 +/- 26 and 325 +/- 30 mPU/10(6) cells in response to PMA and LPS, respectively; parallel increases in steady state levels of uPA mRNA were observed. In contrast to normal expression of uPA activity, functional PAI-2 could not be demonstrated in either the conditioned media or cell lysates of THP-1 under basal or stimulated conditions. Both U937 and PBM secrete low levels of PA inhibitor activity that increase substantially in response to stimulation with PMA and LPS. Immunoreactive PAI-2, measured by ELISA, was undetectable in THP-1 lysates or conditioned medium, but was consistently present in U937 and PBM, paralleling the presence of PA inhibitor activity. THP-1 cells express low levels of an abnormally sized mRNA for PAI-2 and demonstrate a regulatory defect whereby steady state levels of PAI-2 mRNA are markedly reduced upon stimulation with PMA or LPS. By contrast, U937 and PBM respond to identical stimulation with increases in PAI-2 mRNA. We conclude that THP-1 cells express a structurally abnormal species of PAI-2 mRNA, with complete loss of inhibitory activity as well as altered function of PMA- and LPS-responsive regulatory elements.     

Tissue-plasminogen activator stimulates endothelial cell migration in wound assays

The ability of tissue plasminogen activator (tPA) to induce human umbilical vein endothelial (HUVE) cell migration was studied using an in vitro, serum-free wound assay system. At pharmacological doses, tPA stimulated HUVE cell migration dose-dependently. Treatment of cells with epsilon amino caproic acid (EACA) to detach cell-surface and extracellular matrix bound plasminogen, which could lead to plasmin generation, resulted in increased HUVEcell migration on stimulation with tPA.Plasminogen activator inhibitor-1 (PAI-1), a natural plasminogen activator inhibitor, abolished tPA-induced HUVEcell migration. These results demonstrate for the first time that tPA is capable of stimulating endothelial cell migration in wound assays and this effect is susceptible to PAI-1 inhibition.     

Interaction of heparin with plasminogen activators and plasminogen: effects on the activation of plasminogen

The amidolytic plasmin activity of a mixture of tissue plasminogen activator (tPA) and plasminogen is enhanced by heparin at therapeutic concentrations. Heparin also increases the activity in mixtures of urokinase-type plasminogen activator (uPA) and plasminogen but has no effect on streptokinase or plasmin. Direct analyses of plasminogen activation by polyacrylamide gel electrophoresis demonstrate that heparin increases the activation of plasminogen by both tPA and uPA. Binding studies show that heparin binds to various components of the fibrinolytic system, with tight binding demonstrable with tPA, uPA, and Lys-plasminogen. The stimulation of tPA activity by fibrin, however, is diminished by heparin. The ability of heparin to promote plasmin generation is destroyed by incubation of the heparin with heparinase, whereas incubation with chondroitinase ABC or AC has no effect. Also, stimulation of plasmin formation is not observed with dextran sulfate or chondroitin sulfate A, B, or C. Analyses of heparin fractions after separation on columns of antithrombin III-Sepharose suggest that both the high-affinity and the low-affinity fractions, which have dramatically different anticoagulant activity, have similar activity toward the fibrinolytic components.     

Structural basis for recognition of urokinase-type plasminogen activator by plasminogen activator inhibitor-1

Plasminogen activator inhibitor-1 (PAI-1), together with its physiological target urokinase-type plasminogen activator (uPA), plays a pivotal role in fibrinolysis, cell migration, and tissue remodeling and is currently recognized as being among the most extensively validated biological prognostic factors in several cancer types. PAI-1 specifically and rapidly inhibits uPA and tissue-type PA (tPA). Despite extensive structural/functional studies on these two reactions, the underlying structural mechanism has remained unknown due to the technical difficulties of obtaining the relevant structures. Here, we report a strategy to generate a PAI-1·uPA(S195A) Michaelis complex and present its crystal structure at 2.3-Å resolution. In this structure, the PAI-1 reactive center loop serves as a bait to attract uPA onto the top of the PAI-1 molecule. The P4–P3′ residues of the reactive center loop interact extensively with the uPA catalytic site, accounting for about two-thirds of the total contact area. Besides the active site, almost all uPA exosite loops, including the 37-, 60-, 97-, 147-, and 217-loops, are involved in the interaction with PAI-1. The uPA 37-loop makes an extensive interaction with PAI-1 β-sheet B, and the 147-loop directly contacts PAI-1 β-sheet C. Both loops are important for initial Michaelis complex formation. This study lays down a foundation for understanding the specificity of PAI-1 for uPA and tPA and provides a structural basis for further functional studies.     

Expression of active plasminogen activator inhibitor-1 reduces cell migration and invasion in breast and gynecological cancer cells

Urokinase-type (uPA) plasminogen activator is regulated by serine protease inhibitors (serpins), especially plasminogen activator inhibitor-1 (PAI-1). In many cancers, uPA and PAI-1 contribute to the invasive phenotype. We examined the in vitro migration and invasive capabilities of breast, ovarian, endometrial, and cervical cancer cell lines compared to their plasminogen activator system profiles. We then overexpressed active wild-type PAI-1 and an inactive "substrate" P14 form of PAI-1 (T333R) using stable transfection and adenoviral gene delivery. We also upregulated endogenous uPA and PAI-1 in these cells by treatment with transforming growth factor-beta. Some breast and ovarian cancer cell lines with natural expression of uPA, PAI-1, and urokinase receptor showed substantial migration and invasion compared to other cell lines that lack expression of these proteins. However, overexpression of active wild-type PAI-1, but not P14-PAI-1 (T333R), in these cell lines showed reduced migration and invasion. Since vitronectin binding by both forms of PAI-1 is equivalent, these results imply that PAI-1-vitronectin interactions are less critical in altering migration and invasion. Our results show that the in vitro migratory and invasive phenotype in these breast and ovarian cancer cell lines is reduced by active PAI-1 due to its ability to inhibit plasminogen activation.     

Tumor-associated urokinase-type plasminogen activator: biological and clinical significance.

Evidence has accumulated that invasion and metastasis in solid tumors require the action of tumor-associated proteases, which promote the dissolution of the surrounding tumor matrix and the basement membranes. Receptor-bound urokinase-type plasminogen activator (uPA) appears to play a key role in these events. uPA converts plasminogen into plasmin and thus mediates pericellular proteolysis during cell migration and tissue remodeling under physiological and pathophysiological conditions. uPA is secreted as an enzymatically inactive proenzyme (pro-uPA) by tumor cells and stroma cells. uPA exerts its proteolytic function on normal cells and tumor cells as an ectoenzyme after having bound to a high-affinity cell surface receptor. After binding, pro-uPA is activated by serine proteases (e.g. plasmin, trypsin or plasma kallikrein) and by the cysteine proteases cathepsin B or L, resp. Receptor-bound enzymatically active uPA converts plasminogen to plasmin which is bound to a different low-affinity receptor on tumor cells. Plasmin then degrades components of the tumor stroma (e.g. fibrin, fibronectin, proteoglycans, laminin) and may activate procollagenase type IV which degrades collagen type IV, a major part of the basement membrane. Hence receptor-bound uPA will promote plasminogen activation and thus the dissolution of the tumor matrix and the basement membrane which is a prerequisite for invasion and metastasis. Tissues of primary cancer and/or metastases of the breast, ovary, prostate, cervix uteri, bladder, lung and of the gastrointestinal tract contain elevated levels of uPA compared to benign tissues. In breast cancer uPA and PAI-1 antigen in tumor tissue extracts are independent prognostic factors for relapse-free and overall survival.     

Regulation of tissue-type plasminogen activator and plasminogen activator inhibitor type-1 in cultured rat Sertoli and Leydig cells

New data are provided to show that (i) rat Sertoli cells produce two types of plasminogen activators, tissue type (tPA) and urokinase type (uPA), and a plasminogen activator inhibitor type-1 (PAI-1); (ii) both tPA (but not uPA) and PAI-1 secretion in the culture are modified by FSH, forskolin, dbcAMP, GnRH, PMA and growth factors (EGF and FGF), but not by hCG and androstenedione (△4); (iii) in vitro secretion of tPA and PA-PAI-1 complexes of Sertoli cells are greatly enhanced by presence of Leydig cells which produce negligible tPA but measurable PAI-1 activity;(iv) combination culture of Sertoli and Leydig cells remarkably increases FSH-induced PAI-1 activity and decreases hCG- and forskolin-induced inhibitor activity as compared with that of two cell types cultured alone. These data suggest that rat Sertoli cells, similar to ovarian granulosa cells, are capable of secreting both tPA and uPA, as well as PAI-1. The interaction of Sertoli cells and Leydig cells is essential for the cells to response to