Tissue plasminogen activator is a potent activator of PDGF-CC

Tissue plasminogen activator (tPA) is a serine protease involved in the degradation of blood clots through the activation of plasminogen to plasmin. Here we report on the identification of tPA as a specific protease able to activate platelet-derived growth factor C (PDGF-C). The newly identified PDGF-C is secreted as a latent dimeric factor (PDGF-CC) that upon proteolytic removal of the N-terminal CUB domains becomes a PDGF receptor alpha agonist. The CUB domains in PDGF-CC directly interact with tPA, and fibroblasts from tPA-deficient mice fail to activate latent PDGF-CC. We further demonstrate that growth of primary fibroblasts in culture is dependent on a tPA-mediated cleavage of latent PDGF-CC, generating a growth stimulatory loop. Immunohistochemical analysis showed similar expression patterns of PDGF-C and tPA in developing mouse embryos and in tumors, indicating both autocrine and paracrine modes of activation of PDGF receptor-mediated signaling pathways. The identification of tPA as an activator of PDGF signaling establishes a novel role for the protease in normal and pathological tissue growth and maintenance, distinct from its well-known role in plasminogen activation and fibrinolysis.     

Plasminogen activation: biochemistry, physiology, and therapeutics

The mammalian serine protease zymogen, plasminogen, can be converted into the active enzyme plasmin by vertebrate plasminogen activators urokinase (uPA), tissue plasminogen activator (tPA), factor XII-dependent components, or by bacterial streptokinase. The biochemical properties of the major components of the system, plasminogen/plasmin, plasminogen activators, and inhibitors of the plasminogen activators, are reviewed. The plasmin system has been implicated in a variety of physiological and pathological processes such as fibrinolysis, tissue remodeling, cell migration, inflammation, and tumor invasion and metastasis. A defective plasminogen activator/inhibitor system also has been linked to some thromboembolic complications. Recent studies of the mechanism of fibrinolysis in human plasma suggest that tPA may be the primary initiator and that overall fibrinolytic activity is strongly regulated at the tPA level. A simple model for the initiation and regulation of plasma fibrinolysis based on these studies has been formulated. The plasminogen activators have been used for thrombolytic therapy. Three new thrombolytic agents--tPA, pro-uPA, and acylated streptokinase-plasminogen complex--have been found to possess better properties over their predecessors, urokinase and streptokinase. Further improvements of these molecules using genetic and protein engineering tactics are being pursued.     

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.     

Importance, localization and functional properties of the cell-associated form of plasminogen activator in mouse peritoneal macrophages

In inflammatory macrophages, plasminogen activator exists in two active forms, a soluble form released into the extracellular medium and a cell-associated form. This communication describes some properties of the cellular form of plasminogen activator, in intact macrophages and in cell lysates. Cellular plasminogen activator is a membrane protein, associated with the outer face of the plasma membrane; in intact macrophages, it participates in the activation of exogenous plasminogen and, thus, has to be considered as an ectoenzyme. A plasminogen activator activity can be detected in cell lysates (macrophage monolayers lysed in 0.1% Triton X-100) only when plasmin production is followed by the use of small synthetic substrates because a soluble inhibitor, released during extraction, blocks plasmin fibrinolytic activity. In these lysates, plasminogen activator molecules exist as high molecular weight unstable complexes exhibiting a high affinity for plasminogen.     

Biological control of tissue plasminogen activator-mediated fibrinolysis

Fibrinolysis, the body's ability to degrade fibrin, is an integrated part of hemostasis. Overactivity in the fibrinolytic system causes bleeding and underactivity causes thrombosis. Tissue plasminogen activator (tPA), plasminogen activator inhibitor type 1 (PAI-1), alpha 2-antiplasmin (alpha 2-AP) and plasminogen are definitely involved in fibrinolysis because: (1) these components can be assigned a fibrinolytic role in purified systems, i.e. in vitro, and (2) abnormal structural variants and abnormal levels of these components give rise to bleeding or to thrombosis. The biological control of tPA-mediated fibrinolysis is both cellular and humoral. The cellular regulation compasses synthesis of tPA and PAI-1 and release/uptake of these components. The humoral regulation involves: (1) the reaction between tPA and PAI-1; (2) the fibrin-stimulated plasminogen activation; (3) the reaction between plasmin and alpha 2-AP and (4) plasmin degradation of fibrin. The highly developed biological control of tPA-mediated fibrinolysis is indicative of its physiological importance.     

Tissue plasminogen activator-mediated fibrinolysis protects against axonal degeneration and demyelination after sciatic nerve injury

Tissue plasminogen activator (tPA) is a serine protease that converts plasminogen to plasmin and can trigger the degradation of extracellular matrix proteins. In the nervous system, under noninflammatory conditions, tPA contributes to excitotoxic neuronal death, probably through degradation of laminin. To evaluate the contribution of extracellular proteolysis in inflammatory neuronal degeneration, we performed sciatic nerve injury in mice. Proteolytic activity was increased in the nerve after injury, and this activity was primarily because of Schwann cell-produced tPA. To identify whether tPA release after nerve damage played a beneficial or deleterious role, we crushed the sciatic nerve of mice deficient for tPA. Axonal demyelination was exacerbated in the absence of tPA or plasminogen, indicating that tPA has a protective role in nerve injury, and that this protective effect is due to its proteolytic action on plasminogen. Axonal damage was correlated with increased fibrin(ogen) deposition, suggesting that this protein might play a role in neuronal injury. Consistent with this idea, the increased axonal degeneration phenotype in tPA- or plasminogen-deficient mice was ameliorated by genetic or pharmacological depletion of fibrinogen, identifying fibrin as the plasmin substrate in the nervous system under inflammatory axonal damage. This study shows that fibrin deposition exacerbates axonal injury, and that induction of an extracellular proteolytic cascade is a beneficial response of the tissue to remove fibrin. tPA/plasmin-mediated fibrinolysis may be a widespread protective mechanism in neuroinflammatory pathologies.     

Phospholipid barrier to fibrinolysis: role for the anionic polar head charge and the gel phase crystalline structure

The massive presence of phospholipids is demonstrated in frozen sections of human arterial thrombi. Purified platelet phospholipids and synthetic phospholipids retard in vitro tissue-type plasminogen activator (tPA)-induced fibrinolysis through effects on plasminogen activation and plasmin function. The inhibition of plasminogen activation on the surface of fibrin correlates with the fraction of anionic phospholipid. The phospholipids decrease the amount of tPA penetrating into the clot by 75% and the depth of the reactive surface layer occupied by the activator by up to 30%, whereas for plasmin both of these parameters decrease by approximately 50%. The phospholipids are not only a diffusion barrier, they also bind the components of the fibrinolytic system. Isothermal titration calorimetry shows binding characterized with dissociation constants in the range 0.35-7.64 microm for plasmin and tPA (lower values with more negative phospholipids). The interactions are endothermic and thermodynamically driven by an increase in entropy, probably caused by the rearrangements in the ordered gel structure of the phospholipids (in line with the stronger inhibition at gel phase temperatures compared with liquid crystalline phase temperatures). These findings show a phospholipid barrier, which should be overcome during lysis of arterial thrombi.     

Statin Drugs and Dietary Isoprenoids Downregulate Protein Prenylation in Signal Transduction and Are Antithrombotic and Prothrombolytic Agents

Statins and various isoprenoids of dietary origins inhibit L-mevalonic acid synthesis, which in turn downregulates cholesterol and various other dependent substances, including farnesyl- and geranylgeranyl-conjugated proteins involved in cell signaling processes. Such signaling processes are stimulated by protease activated receptor-1 (PAR-1), which upon activation, causes the expression of various substances including tissue factor (TF) and plasminogen activator inhibitor-1 (PAI-1). Tissue factor promotes thrombin generation, where thrombin stimulates a variety of cellular processes, as well as activating PAR-1 to produce more thrombin. Statins downregulate TF mitigating thrombin generation and also downregulate PAI-1, which normally consumes tissue plasminogen activator (tPA). In the absence of PAI-1, tPA activates plasminogen to generate plasmin. Thus, statins behave as antithrombotic agents and prothrombolytic agents.     

Endocytic receptor LRP together with tPA and PAI-1 coordinates Mac-1-dependent macrophage migration

Migration of activated macrophages is essential for resolution of acute inflammation and the initiation of adaptive immunity. Here, we show that efficient macrophage migration in inflammatory environment depends on Mac-1 recognition of a binary complex consisting of fibrin within the provisional matrix and the protease tPA (tissue-type plasminogen activator). Subsequent neutralization of tPA by its inhibitor PAI-1 enhances binding of the integrin-protease-inhibitor complex to the endocytic receptor LRP (lipoprotein receptor-related protein), triggering a switch from cell adhesion to cell detachment. Genetic inactivation of Mac-1, tPA, PAI-1 or LRP but not the protease uPA abrogates macrophage migration. The defective macrophage migration in PAI-1-deficient mice can be restored by wild-type but not by a mutant PAI-1 that does not interact with LRP. In vitro analysis shows that tPA promotes Mac-1-mediated adhesion, whereas PAI-1 and LRP facilitate its transition to cell retraction. Our results emphasize the importance of ordered transitions both temporally and spatially between individual steps of cell migration, and support a model where efficient migration of inflammatory macrophages depends on cooperation of three physiologically prominent systems (integrins, coagulation and fibrinolysis, and endocytosis).     

Inhibition of fibrinolytic enzymes by thrombin inhibitors

Thrombin inhibitors have recently advanced to the stage of preclinical testing as anticoagulants. However, little is known about the effects of these inhibitors on the enzymes of the fibrinolytic system. In the present study we evaluated the effect of two protein and two synthetic inhibitors of thrombin on tissue plasminogen activator (tPA), urokinase, and plasmin. We found that hirudin inhibited the amidolytic activity of plasmin but had no effect on tPA or urokinase. Antithrombin III inhibited plasmin and urokinase but had no effect on tPA. D-Phe-Pro-Arg-CH2Cl inhibited plasmin and tPA but had no effect on urokinase. Thromstop inhibited all three fibrinolytic enzymes: plasmin, urokinase, and tPA. Thus each thrombin inhibitor tested had different inhibitory effects on the fibrinolytic enzymes. These effects should be carefully considered when thrombin inhibitors are used as antithrombotic drugs.     

Fibrinolysis and liver regeneration.

The plasmin and plasminogen activator proteases of the plasma fibrinolytic system were investigated as potential blood-borne mediators of the proliferative activation of hepatocytes by partial hepatectomy. Partial (68%) liver resection, as well as proliferatively activating the remaining hepatocytes, rapidly (by 30 minutes) doubled the level (or activity) of circulating plasminogen activator but later (2 hours) greatly depressed this level. This later depression of the activity of circulating plasminogen activator lasted for eight to ten hours before returning to the normal level two to four hours before the hepatocytes in the liver remnant began to synthesize DNA. This sequence of changes in the fibrinolytic potential was not abolished by prior thyroparathyroidectomy which is known to inhibit the initiation of hepatocyte DNA synthesis and to prevent the secretion of the calcium homeostatic hormones, another early systemic consequence of partial liver resection. Since the early rise in plasminogen activator activity did not cause the appearance of active (free) circulating plasmin, and since the injection of large doses of the fibrinolytic and protease inhibitors, EACA and Trasylol®, during this early, post-operative period of hyperfibrinolytic potential did not prevent hepatocytes from initiating DNA synthesis, it is unlikely that either plasmin or its activator protease are blood-borne initiators of hepatocyte proliferative development.     

Effects of extracellular DNA on plasminogen activation and fibrinolysis

The increased levels of extracellular DNA found in a number of disorders involving dysregulation of the fibrinolytic system may affect interactions between fibrinolytic enzymes and inhibitors. Double-stranded (ds) DNA and oligonucleotides bind tissue-(tPA) and urokinase (uPA)-type plasminogen activators, plasmin, and plasminogen with submicromolar affinity. The binding of enzymes to DNA was detected by EMSA, steady-state, and stopped-flow fluorimetry. The interaction of dsDNA/oligonucleotides with tPA and uPA includes a fast bimolecular step, followed by two monomolecular steps, likely indicating slow conformational changes in the enzyme. DNA (0.1-5.0 μg/ml), but not RNA, potentiates the activation of Glu- and Lys-plasminogen by tPA and uPA by 480- and 70-fold and 10.7- and 17-fold, respectively, via a template mechanism similar to that known for fibrin. However, unlike fibrin, dsDNA/oligonucleotides moderately affect the reaction between plasmin and α(2)-antiplasmin and accelerate the inactivation of tPA and two chain uPA by plasminogen activator inhibitor-1 (PAI-1), which is potentiated by vitronectin. dsDNA (0.1-1.0 μg/ml) does not affect the rate of fibrinolysis by plasmin but increases by 4-5-fold the rate of fibrinolysis by Glu-plasminogen/plasminogen activator. The presence of α(2)-antiplasmin abolishes the potentiation of fibrinolysis by dsDNA. At higher concentrations (1.0-20 μg/ml), dsDNA competes for plasmin with fibrin and decreases the rate of fibrinolysis. dsDNA/oligonucleotides incorporated into a fibrin film also inhibit fibrinolysis. Thus, extracellular DNA at physiological concentrations may potentiate fibrinolysis by stimulating fibrin-independent plasminogen activation. Conversely, DNA could inhibit fibrinolysis by increasing the susceptibility of fibrinolytic enzymes to serpins.     

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.     

Tissue-type plasminogen activator is a multiligand cross-beta structure receptor

Tissue-type plasminogen activator (tPA) regulates fibrin clot lysis by stimulating the conversion of plasminogen into the active protease plasmin. Fibrin is required for efficient tPA-mediated plasmin generation and thereby stimulates its own proteolysis. Several fibrin regions can bind to tPA, but the structural basis for this interaction is unknown. Amyloid beta (Abeta) is a peptide aggregate that is associated with neurotoxicity in brains afflicted with Alzheimer's disease. Like fibrin, it stimulates tPA-mediated plasmin formation. Intermolecular stacking of peptide backbones in beta sheet conformation underlies cross-beta structure in amyloid peptides. We show here that fibrin-derived peptides adopt cross-beta structure and form amyloid fibers. This correlates with tPA binding and stimulation of tPA-mediated plasminogen activation. Prototype amyloid peptides, including Abeta and islet amyloid polypeptide (IAPP) (associated with pancreatic beta cell toxicity in type II diabetes), have no sequence similarity to the fibrin peptides but also bind to tPA and can substitute for fibrin in plasminogen activation by tPA. Moreover, the induction of cross-beta structure in an otherwise globular protein (endostatin) endows it with tPA-activating potential. Our results classify tPA as a multiligand receptor and show that cross-beta structure is the common denominator in tPA binding ligands.     

Tissue‐type plasminogen activator induces plasmin‐dependent proteolysis of intracellular neuronal nitric oxide synthase

Background information. Despite its pro‐fibrinolytic activity, tPA (tissue plasminogen activator) is a serine protease known to influence a number of physiological and pathological functions in the central nervous system. Accordingly, tPA was reported to mediate some of its functions in the central nervous system through NMDA (N‐methyl‐d ‐aspartate) receptors, LRP (low‐density lipoprotein receptor‐related protein) or annexin II. Results. We provide here both in vitro and in vivo evidence that tPA could mediate proteolysis and subsequent delocalization of neuronal nitric oxide synthase, thereby reducing endogenous neuronal nitric oxide release. We also demonstrate that although this effect is independent of NMDA receptors, LRP signalling and calpain‐mediated proteolysis, it is dependent on the ability of tPA to promote the conversion of plasminogen into plasmin. Conclusion. Altogether, these results demonstrate a new function for tPA in the central nervous system, which most likely contributes to its pleiotropic functions.     

Tissue-type plasminogen activator requires a co-receptor to enhance NMDA receptor function

Glutamate is the main excitatory neurotransmitter of the CNS. Tissue-type plasminogen activator (tPA) is recognized as a modulator of glutamatergic neurotransmission. This attribute is exemplified by its ability to potentiate calcium signaling following activation of the glutamate-binding NMDA receptor (NMDAR). It has been hypothesized that tPA can directly cleave the NR1 subunit of the NMDAR and thereby potentiate NMDA-induced calcium influx. In contrast, here we show that this increase in NMDAR signaling requires tPA to be proteolytically active, but does not involve cleavage of the NR1 subunit or plasminogen. Rather, we demonstrate that enhancement of NMDAR function by tPA is mediated by a member of the low-density lipoprotein receptor (LDLR) family. Hence, this study proposes a novel functional relationship between tPA, the NMDAR, a LDLR and an unknown substrate which we suspect to be a serpin. Interestingly, whilst tPA alone failed to cleave NR1, cell-surface NMDARs did serve as an efficient and discrete proteolytic target for plasmin. Hence, plasmin and tPA can affect the NMDAR via distinct avenues. Altogether, we find that plasmin directly proteolyses the NMDAR whilst tPA functions as an indirect modulator of NMDA-induced events via LDLR engagement.     

Role of plasminogen activators in peritoneal adhesion formation

Intra-abdominal adhesion formation is a major complication of serosal repair following surgery, ischaemia or infection, leading to conditions such as intestinal obstruction and infertility. It has been proposed that the persistence of fibrin, due to impaired plasminogen activator activity, results in the formation of adhesions between damaged serosal surfaces. This study aimed to assess the role of fibrinolysis in adhesion formation using mice deficient in either of the plasminogen activator proteases, tissue-type plasminogen activator (tPA) or urokinase-type plasminogen activator (uPA). We hypothesize that, following serosal injury, mice with decreased peritoneal fibrinolytic activity will be more susceptible to adhesion formation. Adhesion formation was induced in tPA- and uPA-deficient and wild-type mice following either surgical trauma to the serosa with haemorrhage and acute or chronic intraperitoneal inflammation. Adhesion formation was assessed from 1 to 4 weeks post-injury. Mice deficient in tPA were more susceptible to adhesion formation following both a surgical insult and a chronic inflammatory episode compared with uPA-deficient and wild-type mice. In addition, the time of maximal adhesion formation varied depending on the nature of the initial insult. It is proposed that the persistence of fibrin due to decreased tPA activity following surgery or chronic inflammation plays a major role in peritoneal adhesion formation.     

Activity of an enzyme converting single-chain tissue-type plasminogen activator to the two-chain form in preovulatory human follicular fluid

The biological role of the tissue-type plasminogen activator (tPA)/plasmin system has long been implicated in ovarian function. We have recently shown that the follicular fluid of human ovaries contains an alpha(2)-macroglobulin/protease complex capable of converting single-chain (sc) tPA to the two-chain (tc) enzyme tPA, suggesting the occurrence of its corresponding enzyme in a free form in the fluid. The aim of the current study is therefore to gain further information about the putative sctPA-converting enzyme present in follicular fluid. Incubation of human recombinant sctPA with the fluid brought about the production of tctPA. It was also demonstrated that tctPA production resulted in the activation of endogenous fluid plasminogen. Production of tctPA and plasmin both was strongly inhibited by aprotinin, suggesting that the enzyme is a serine protease. The sctPA-converting enzyme was partially purified from the fluid by column chromatographies. The enzyme preferably hydrolyzed synthetic peptide substrates containing arginine at the P(1) position. The enzyme preparation had a protease inhibitor profile similar to that observed with the crude fluid sample. These results clearly demonstrated that follicular fluid contains an enzyme capable of efficiently converting sctPA to tctPA. Discovery of this sctPA-converting enzyme strongly suggests that the tPA/plasmin system in the preovulatory follicle of human ovaries is operated through the proteolytic conversion of sctPA to tctPA rather than being regulated by a fibrin-dependent mechanism.     

The role of pannexin1 in the induction and resolution of inflammation

Extracellular ATP is an important signaling molecule throughout the inflammatory cascade, serving as a danger signal that causes activation of the inflammasome, enhancement of immune cell infiltration, and fine-tuning of several signaling cascades including those important for the resolution of inflammation. Recent studies demonstrated that ATP can be released from cells in a controlled manner through pannexin (Panx) channels. Panx1-mediated ATP release is involved in inflammasome activation and neutrophil/macrophage chemotaxis, activation of T cells, and a role for Panx1 in inducing and propagating inflammation has been demonstrated in various organs, including lung and the central and peripheral nervous system. The recognition and clearance of dying cells and debris from focal points of inflammation is critical in the resolution of inflammation, and Panx1-mediated ATP release from dying cells has been shown to recruit phagocytes. Moreover, extracellular ATP can be broken down by ectonucleotidases into ADP, AMP, and adenosine, which is critical in the resolution of inflammation. Together, Panx1, ATP, purinergic receptors, and ectonucleotidases contribute to important feedback loops during the inflammatory response, and thus represent promising candidates for new therapies.