Urokinase-type Plasminogen Activator-like Proteases in Teleosts Lack Genuine Receptor-binding Epidermal Growth Factor-like Domains

Plasminogen activation catalyzed by urokinase-type plasminogen activator (uPA) plays an important role in normal and pathological tissue remodeling processes. Since its discovery in the mid-1980s, the cell membrane-anchored urokinase-type plasminogen activator receptor (uPAR) has been believed to be central to the functions of uPA, as uPA-catalyzed plasminogen activation activity appeared to be confined to cell surfaces through the binding of uPA to uPAR. However, a functional uPAR has so far only been identified in mammals. We have now cloned, recombinantly produced, and characterized two zebrafish proteases, zfuPA-a and zfuPA-b, which by several criteria are the fish orthologs of mammalian uPA. Thus, both proteases catalyze the activation of fish plasminogen efficiently and both proteases are inhibited rapidly by plasminogen activator inhibitor-1 (PAI-1). But zfuPA-a differs from mammalian uPA by lacking the exon encoding the uPAR-binding epidermal growth factor-like domain; zfuPA-b differs from mammalian uPA by lacking two cysteines of the epidermal growth factor-like domain and a uPAR-binding sequence comparable with that found in mammalian uPA. Accordingly, no zfuPA-b binding activity could be found in fish white blood cells or fish cell lines. We therefore propose that the current consensus of uPA-catalyzed plasminogen activation taking place on cell surfaces, derived from observations with mammals, is too narrow. Fish uPAs appear incapable of receptor binding in the manner known from mammals and uPA-catalyzed plasminogen activation in fish may occur mainly in solution. Studies with nonmammalian vertebrate species are needed to obtain a comprehensive understanding of the mechanism of plasminogen activation.     

Plasminogen activation is stimulated by prion protein and regulated in a copper-dependent manner

Prion diseases are associated with the conversion of the normal prion protein, PrP(C), to the infectious disease form PrP(Sc). Discrimination between these isoforms would significantly enhance diagnosis of these diseases, and it has recently been reported that PrP(Sc) is specifically recognized by the serine protease zymogen plasminogen (Fischer et al. (2000) Nature 408, 479). Here we have tested the hypothesis that PrP is a regulator of the plasminogen activation system. The effect of recombinant PrP, either containing copper (holo-PrP) or devoid of it (apo-PrP), on plasminogen activation by both uPA and tPA was determined. PrP had no effect on plasminogen activation by uPA. By contrast, the activity of tPA was stimulated by up to 280-fold. This was observed only with the apo-PrP isoforms. The copper-binding octapeptide repeat region of PrP was involved in the effects, as a mutant lacking this region failed to stimulate plasminogen activation, although a synthetic peptide corresponding to this region was unable to stimulate tPA activity. Competition experiments demonstrated that, in addition to plasminogen binding, the stimulation required a high-affinity interaction between tPA and PrP (K(d) < 2.5 nM). Kinetic analysis revealed a template mechanism for the stimulation, suggesting independent binding sites for tPA and plasminogen. Lack of copper-binding may be an early event in the conversion of PrP(C) to PrP(Sc), and our data therefore suggest that tPA-catalyzed plasminogen activation may provide the basis for a sensitive detection system for the early stages of prion diseases and also play a role in the pathogenesis of these diseases.     

Bacterial metastasis: the host plasminogen system in bacterial invasion

Several pathogenic bacterial species intervene with the mammalian proteolytic plasminogen-plasmin system. Recent developments have been made in understanding the structure and the virulence-associated functions of bacterial plasminogen receptors and activators, in particular by using plasminogen-deficient or transgenic gain-of-function mice. Bacteria can affect the regulation of the plasminogen system by degrading circulating plasmin inhibitors and by influencing the expression levels of mammalian plasminogen activators and activation inhibitors. Interaction with the plasminogen system promotes damage of extracellular matrices as well as bacterial spread and organ invasion during infection, suggesting common mechanisms in migration of eukaryotic and prokaryotic cells.     

Interference of active site specific reagents in plasminogen-streptokinase active site formation

We have recently observed slow, non-Michaelis-Menten kinetics of activation of native cat plasminogen by catalytic concentrations of streptokinase. In order to understand the reasons for this phenomenon, we undertook to study the formation of the plasminogen-streptokinase activator complex under the same plasminogen activation conditions. The results obtained in this study show that the potential active site in both cat and human plasminogen is capable of binding strongly the specific substrates (S) p-nitrophenyl p-guanidinobenzoate (NPGB) and H-D-valyl-L-leucyl-L-lysyl-p-nitroanilide, through the active site is incapable of hydrolyzing these substrates. Binding studies support these and the following conclusions. Streptokinase binds to this zymogen-substrate complex to create the ternary plasminogen-S-streptokinase complex, which then slowly converts to an acylated plasminogen-streptokinase form. This acylation reaction is 550 times slower than acylation of the preformed plasminogen-streptokinase complex by NPGB. The same reaction also occurs with human plasminogen, though the acylation reaction is 10 times faster than when the cat zymogen is used. NPGB binds specifically to plasminogen but not to streptokinase. These studies proved that inhibition of cat plasminogen activation by streptokinase occurs at the level of activator complex formation. We conclude from our studies that streptokinase binding to both cat and human plasminogen occurs at the potential active site of the zymogen. Consequently, it is probable that plasminogen activation in vivo is inhibited by binding of active site specific inhibitors to plasminogen.     

A Key Role for the Urokinase Plasminogen Activator (uPA) in Invasive Group A Streptococcal Infection

Recruitment of the serine protease plasmin is central to the pathogenesis of many bacterial species, including Group A streptococcus (GAS), a leading cause of morbidity and mortality globally. A key process in invasive GAS disease is the ability to accumulate plasmin at the cell surface, however the role of host activators of plasminogen in this process is poorly understood. Here, we demonstrate for the first time that the urokinase-type plasminogen activator (uPA) contributes to plasmin recruitment and subsequent invasive disease initiation in vivo. In the absence of a source of host plasminogen activators, streptokinase (Ska) was required to facilitate cell surface plasmin acquisition by GAS. However, in the absence of Ska, host activators were sufficient to promote cell surface plasmin acquisition by GAS strain 5448 during incubation with plasminogen or human plasma. Furthermore, GAS were able mediate a significant increase in the activation of zymogen pro-uPA in human plasma. In order to assess the contribution of uPA to invasive GAS disease, a previously undescribed transgenic mouse model of infection was employed. Both C57/black 6J, and AlbPLG1 mice expressing the human plasminogen transgene, were significantly more susceptible to invasive GAS disease than uPA−/− mice. The observed decrease in virulence in uPA−/−mice was found to correlate directly with a decrease in bacterial dissemination and reduced cell surface plasmin accumulation by GAS. These findings have significant implications for our understanding of GAS pathogenesis, and research aimed at therapeutic targeting of plasminogen activation in invasive bacterial infections.     

Antibody-mediated targeting of the urokinase-type plasminogen activator proteolytic function neutralizes fibrinolysis in vivo

Urokinase-type plasminogen activator (uPA) plays a central role in tissue remodeling processes. Most of our understanding of the role of uPA in vivo is derived from studies using gene-targeted uPA-deficient mice. To enable in vivo studies on the specific interference with uPA functionality in mouse models, we have now developed murine monoclonal antibodies (mAbs) directed against murine uPA by immunization of uPA-deficient mice with the recombinant protein. Guided by enzyme-linked immunosorbent assay, Western blotting, surface plasmon resonance, and enzyme kinetic analyses, we have selected two highly potent and inhibitory anti-uPA mAbs (mU1 and mU3). Both mAbs recognize epitopes located on the B-chain of uPA that encompasses the catalytic site. In enzyme activity assays in vitro, mU1 blocked uPA-catalyzed plasminogen activation as well as plasmin-mediated pro-uPA activation, whereas mU3 only was directed against the first of these reactions. We additionally provide evidence that mU1, but not mU3, successfully targets uPA-dependent processes in vivo. Hence, systemic administration of mU1 (i) rescued mice treated with a uPA-activable anthrax protoxin and (ii) impaired uPA-mediated hepatic fibrinolysis in tissue-type plasminogen activator (tPA)-deficient mice, resulting in a phenotype mimicking that of uPA;tPA double deficient mice. Importantly, this is the first report demonstrating specific antagonist-directed targeting of mouse uPA at the enzyme activity level in a normal physiological process in vivo.     

Complex interactions between bovine plasminogen and streptococcal plasminogen activator PauA

The interactions between bovine plasminogen and the streptococcal plasminogen activator PauA that culminate in the generation of plasmin are not fully understood. Formation of an equimolar activation complex comprising PauA and plasminogen by non-proteolytic means is a prerequisite to the recruitment of substrate plasminogen; however the determinants that facilitate these interactions have yet to be defined. A mutagenesis strategy comprising nested deletions and random point substitutions indicated roles for both amino and carboxyl-terminal regions of PauA and identified further essential residues within the alpha domain of the plasminogen activator. A critical region within the alpha domain was identified using non-overlapping PauA peptides to block the interaction between PauA and bovine plasminogen, preventing formation of the activation complex. Homology modelling of the activation complex based upon the known structures of streptokinase complexed with human plasmin supported these findings by placing critical residues in close proximity to the plasmin component of the activation complex.     

The compact domain conformation of human Glu-plasminogen in solution.

A complete understanding of the accelerating mechanisms of plasminogen activation and fibrinolysis necessarily requires structural information on the conformational forms of plasminogen. Given the absence of high-resolution structural data on plasminogen the use of lower resolution approaches has been adopted. Two such approaches have previously indicated a compact conformation of Glu-plasminogen (Tranqui, L., Prandini, M., and Chapel, A. (1979) Biol. Cellulaire, 34, 39-42; Bányai, L. and Patthy, L. (1985) Biochim. Biophys. Acta, 832, 224-227) whereas a third has suggested a fairly extended conformation (Mangel, W., Lin, B. and Ramakrishnan, V. (1990) Science, 248, 69-73). Native Glu-plasminogen has been investigated using small-angle X-ray scattering (SAXS) experiments. It is concluded that this molecule in solution is compact (radius of gyration, RG 3.05 +/- 0.02 nm and maximum intramolecular distance, Im 9.1 +/- 0.3 nm) and that the data are consistent with the right-handed spiral structure observed using electron microscopy by Tranqui et al. (1979). A spiral structure of native plasminogen would have important implications for the conformational response of plasminogen to fibrin and concomitant stimulation of plasminogen activation.     

Role of plasminogen/plasmin in functional activity of blood cells

The article deals with the data concerning structural peculiarities of plasminogen/plasmin molecule, which define the specificity of intermolecular interactions and provide the variety of its biological functions. The main principles of the modern classification of plasminogen receptors and factors, which modulate their expression, have been presented. We have considered the mechanisms regulating both plasmin formation and activity on the surface of cells, fibrin and proteins of extracellular matrix. The data of previous investigators and our own results, concerning the influence of plasminogen/plasmin on platelet aggregation induced by different agonists, have been summarized. The participation of plasminogen/plasmin in atherogenesis and angiogenesis mediated by endotheliocyte receptors has been discussed. Special attention was given to plasminogen/plasmin proinflammatory function, which is realized by regulatory processes of activation, secretion, migration and apoptosis of monocytes and macrophages.     

Stimulation of cell surface plasminogen activation by membrane-bound melanotransferrin: a key phenomenon for cell invasion

The activation of plasminogen at the cell surface is a crucial step in cell migration and invasion. In the present study, the effect of membrane-bound melanotransferrin (mMTf), also known as human melanoma antigen p97, on cell surface plasminogen binding and activation was investigated by using Chinese Hamster Ovary (CHO) cells transfected with full-length melanotransferrin (MTf) cDNA and SK-MeL-28 melanoma cells. The expression of mMTf in CHO increased cell surface plasminogen binding by about 2-fold. In addition, application of the monoclonal antibody L235 against MTf as well as truncated, soluble MTf (sMTf) abolished plasminogen binding to MTf-transfected and SK-MeL-28 cells, indicating that mMTf is a potential cell surface plasminogen receptor. Moreover, mMTf expression in CHO cells stimulates plasminogen activation at the cell surface by about 2.5-fold. In addition to the induced binding and activation of plasminogen, cell motility, migration and invasion were about 3-fold higher in CHO cells expressing mMTf. Both monoclonal antibody L235 and truncated sMTf inhibited mMTf-stimulated CHO cell motility, migration and invasion. Overall, our results indicate a key role for mMTf in cell surface plasminogen binding and in activation processes involved during cell migration and invasion.     

Inducible lung-specific urokinase expression reduces fibrosis and mortality after lung injury in mice

Plasminogen activator inhibitor-1 (PAI-1)-deficient transgenic mice have improved survival and less fibrosis after intratracheal bleomycin instillation. We hypothesize that PAI-1 deficiency limits scarring through unopposed plasminogen activation. If this is indeed true, then we would expect increased urokinase-type plasminogen activator (uPA) expression to result in a similar reduction in scarring and improvement in mortality. To test our hypothesis, using the tetracycline gene regulatory system, we have generated a transgenic mouse model with the features of inducible, lung-specific uPA production. After doxycycline administration, these transgenic animals expressed increased levels of uPA in their bronchoalveolar lavage (BAL) fluid that accelerated intrapulmonary fibrin clearance. Importantly, this increased plasminogen activator production led to a reduction in both lung collagen accumulation and mortality after bleomycin-induced injury. These results suggest that PAI-1 deficiency does protect against the effects of bleomycin-induced lung injury through unopposed plasmin generation. By allowing the manipulation of plasminogen activation at different phases of the fibrotic process, this model will serve as a powerful tool in further investigations into the pathogenesis of pulmonary fibrosis.     

Titles of related papers in other sections

Previous results have shown that the autoantibody eluted from the glomeruli of rats with active Heymann nephritis contain a population of antibodies not only to the putative autoantigen of the disease, gp330, but alos to plasminogen. Since gp330 has been shown to serve as a receptor for plasminogen, we have analyzed the effects of autoantibody on plasminogen-binding to gp330 and activation of plasminogen to plasmin by urokinase. Autoantibody does not inhibit the binding of plasminogen to gp330. The change in the conformation of plasminogen when its lysine-binding sites are occupied or after conversion to plasmin results in a significant decrease in autoantibody-binding. The most significant effect of autoantibody on this system is the inhibition of plasminogen activation to plasmin by urokinase. The binding of autoantibody to plasminogen acts as a competitive inhibitor of the reaction by apparently blocking access of urokinase to plasminogen's activation site. These results indicate that autoantibody obtained from the immune deposits in the glomeruli of rats with active Heyman nephritis does not inhibit the binding of plasminogen to gp330 but does significantly alter the urokinase catalyzed activation of plasminogen to plasmin.     

Receptor-mediated regulation of plasminogen activator function: plasminogen activation by two directly membrane-anchored forms of urokinase.

The generation of the broad specificity serine protease plasmin in the pericellular environment is regulated by binding of the urokinase-type plasminogen activator (uPA) to its specific glycosylphosphatidylinositol (GPI)-anchored cell-surface receptor, uPAR. This interaction potentiates the reciprocal activation of the cell-associated zymogens pro-uPA and plasminogen. To further study the role of uPAR in this mechanism, we have expressed two directly membrane-anchored chimeric forms of uPA, one anchored by a C-terminal GPI-moiety (GPI-uPA), the other with a C-terminal transmembrane peptide (TM-uPA). These were expressed in the monocyte-like cell lines U937 and THP-1, which are excellent models for kinetic and mechanistic studies of cell-surface plasminogen activation. In both cell-lines, GPI-uPA activated cell-associated plasminogen with characteristics both qualitatively and quantitatively indistinguishable from those of uPAR-bound uPA. By contrast, TM-uPA activated cell-associated plasminogen less efficiently. This was due to effects on the K, for plasminogen activation (which was increased up to five-fold) and the efficiency of pro-uPA activation (which was decreased approximately four-fold). These observations suggest that uPAR serves two essential roles in mediating efficient cell-surface plasminogen activation. In addition to confining uPA to the cell-surface, the GPI-anchor plays an important role by increasing accessibility to substrate plasminogen and, thus, enhancing catalysis. However, the data also demonstrate that, in the presence of an alternative mechanism for uPA localization, uPAR is dispensable and, therefore, unlikely to participate in any additional interactions that may be necessary for the efficiency of this proteolytic system. In these experiments zymogen pro-uPA was unexpectedly found to be constitutively activated when expressed in THP-1 cells, suggesting the presence of an alternative plasmin-independent proteolytic activation mechanism in these cells.     

Interactions of plasminogen and tissue plasminogen activator (t-PA) with amphoterin. Enhancement of t-PA-catalyzed plasminogen activation by amphoterin

The heparin-binding p30 protein amphoterin is proposed to mediate adhesive interactions of the advancing plasma membrane in migrating and differentiating cells. Since the NH2-terminal part of amphoterin is exceptionally rich in lysine residues, we have studied its interactions with plasminogen and tissue plasminogen activator (t-PA). On immunostaining of N18 neuroblastoma cells, amphoterin and t-PA showed a close co-localization in the filopodia of the leading membrane and in the substrate-attached material. In purified systems, both t-PA and plasminogen bound to immobilized amphoterin, and their binding was inhibited by the lysine analogue epsilon-aminocaproic acid. Plasminogen bound to immobilized amphoterin was activated by t-PA, and this resulted in effective degradation of the immobilized amphoterin. Correspondingly, amphoterin-bound t-PA activated plasminogen. In solution amphoterin accelerated t-PA-catalyzed plasminogen activation maximally 46-fold. The results indicate that t-PA and plasminogen form through their lysine-binding sites a complex with amphoterin, which results in acceleration of plasminogen activation and effective degradation of amphoterin. We suggest that local acceleration of t-PA-catalyzed plasminogen activation by amphoterin at the leading membrane enhances the penetration of growing cytoplasmic processes through extracellular materials during cell migration, differentiation and regeneration. The amphoterin-mediated adhesion at the leading membrane may be transient in nature, because the protein also enhances its own breakdown by accelerating t-PA-catalyzed plasminogen activation.     

Protein S attenuates the invasive potential of THP-1 cells by interfering with plasminogen binding on cell surface via a protein C-independent mechanism

Protein S, a cofactor for activated protein C (aPC) to inactivate coagulation factors, also plays a pivotal role in inflammation. Based on our recent findings that aPC and protein S modifies tissue plasminogen activator (tPA)-catalyzed activation of Glu-plasminogen (Glu-plg), we analyzed possible role of protein S in cell-associated plasminogen activation and invasive potential of inflammatory cells. Monocyte-like THP-1 cells, to which both plasminogen and tPA bind, enhanced tPA-catalyzed plasminogen activation, which was partially abolished by protein S but not by aPC. Protein S attenuated both the plasminogen binding to THP-1 cells and associated their invasive potential through Matrigel.     

Plasminogen activation in diabetes mellitus. Kinetic analysis of plasmin formation using components isolated from the plasma of diabetic donors

Two components of the fibrinolytic system, plasminogen and the vascular plasminogen activator, have been isolated to apparent homogeneity from the post-venous occlusion plasma of three diabetic patients (hemoglobin A1C greater than 7%) and of one nondiabetic control person. Plasminogen activation was studied for each person separately in the absence and presence of CNBr fragments of fibrinogen. Activation of diabetic plasminogen by urokinase was not significantly altered as compared to the activation of control plasminogen. The same was found when diabetic plasminogen was activated by control vascular plasminogen activator in the presence of fibrinogen fragments but only at plasminogen concentrations below 10-30 nM; at higher substrate concentrations, however, plasminogen activation was impaired in a pattern resembling substrate inhibition. Activation of control plasminogen by diabetic vascular plasminogen activator was completely impaired in the absence of fibrinogen fragments. Addition of fibrinogen fragments stimulated plasmin formation by diabetic vascular plasminogen activator resulting in kinetic constants which were similar to the activation of control plasminogen by control vascular plasminogen activator in the absence of fibrinogen fragments (Km = 7.5 microM, kcat = 0.05 S-1). Addition of fibrinogen fragments in controls decreased Km values to less than 0.1 microM. Despite addition of fibrinogen fragments the rate of plasmin formation from diabetic plasminogen by diabetic vascular plasminogen activator isolated from the same diabetic donor was so small that kinetic constants could not be calculated.     

纤溶酶原受体与相关疾病的分子机制

纤溶酶原(PLG)经激活为纤溶酶(PLM)后,除了发挥纤溶和栓溶作用,还广泛参与胚胎发育、组织重构、伤口愈合等生理过程.近年来研究显示:PLM还与炎症、自身免疫、肿瘤和神经变性等存在紧密联系,而且已在细胞表面发现十几种PLG受体(PLGR)、结合蛋白.我们综述了这些受体和结合蛋白的结构、信号通路和致病机制方面的研究进展,从而为进一步理解纤溶系统的功能、发展新的诊疗方法提供思路.     

Enhancement of plasminogen activation by surfactin C: augmentation of fibrinolysis in vitro and in vivo

The reciprocal activation of plasminogen and prourokinase (pro-u-PA) is an important mechanism in the initiation and propagation of local fibrinolytic activity. We have found that a bacterial lipopeptide compound, surfactin C (3-20 microM), enhances the activation of pro-u-PA in the presence of plasminogen. This effect accompanied increased conversions of both pro-u-PA and plasminogen to their two-chain forms. Surfactin C also elevated the rate of plasminogen activation by two-chain urokinase (tcu-PA) while not affecting plasmin-catalyzed pro-u-PA activation and amidolytic activities of tcu-PA and plasmin. The intrinsic fluorescence of plasminogen was increased, and molecular elution time of plasminogen in size-exclusion chromatography was shortened in the presence of surfactin C. These results suggested that surfactin C induced a relaxation of plasminogen conformation, thus leading to enhancement of u-PA-catalyzed plasminogen activation, which in turn caused feedback pro-u-PA activation. Surfactin C was active in enhancing [125I]fibrin degradation both by pro-u-PA/plasminogen and tcu-PA/plasminogen systems. In a rat pulmonary embolism model, surfactin C (1 mg/kg, i.v.) elevated 125I plasma clot lysis when injected in combination with pro-u-PA. The present results provide first evidence that pharmacological relaxation of plasminogen conformation leads to enhanced fibrinolysis in vivo.     

Plasminogen activation by a tissue activator and effector properties of fibrinogen-N-terminal disulfide (N-DSK) fibrin complex

Fibrinogen-NDSK complex is a model of protofibril having some features of the fibrin polymer structure. This complex has been studied for its ability to stimulate the plasminogen activation by t-PA. The fibrinogen-NDSK complex have increased the rate of plasminogen activation by t-PA as compared to fibrinogen or NDSK taken separately. This acceleration had slow and fast phases. Lys-plasminogen was activated more effectively as compared to glu-plasminogen. The kinetic parameters of glu- and lys-plasminogen activation at fast phase were: Km--0.18 and 0.015 mu/M, Kkat--0.27 and 0.06 s-1, respectively. Fibrinogen X2--fragments, deprived of alpha C-domains and NH2-end peptides of bB-chains, formed complexes with NDSK, which however did not stimulate the plasminogen activation by t-PA. These findings have shown that the fibrinogen-NDSK complex is an effective stimulator of the plasminogen activation by t-PA. The activating ability of the complex may be due to structures formed in the course of fibrinogen and NDSK polymerization as a result of alpha C-domain interaction.     

Plasminogen activation initiated by single-chain urokinase-type plasminogen activator. Potentiation by U937 monocytes

The binding of urokinase-type plasminogen activators (u-PA) to receptors on various cell types has been proposed to be an important feature of many cellular processes requiring extracellular proteolysis. We have investigated the effect of single-chain u-PA binding to the monocyte-like cell line U937 on plasminogen activation. A 16-fold acceleration of the activation of plasminogen was observed at optimal concentrations of single-chain u-PA. This potentiation was abolished by the addition of either 6-aminohexanoic acid or the amino-terminal fragment of u-PA, thus demonstrating the requirement for specific binding of both single-chain u-PA and plasminogen to the cells. The mechanism of the enhancement of plasmin generation appears to be due primarily to an increase in the rate of feedback activation of single-chain u-PA to the more active two-chain u-PA by cell-bound plasmin, initially generated by single-chain u-PA. This increased activity of the plasminogen activation system in the presence of U937 cells provides a mechanism whereby u-PAs may exert their influence in a variety of cell-associated proteolytic events.