Enhanced hippocampal long-term potentiation and learning by increased neuronal expression of tissue-type plasminogen activator in transgenic mice.

Adult cortical neurons can produce tissue-type plasminogen activator (tPA), an extracellular protease that plays a critical role in fibrinolysis and tissue remodelling processes. There is growing evidence that extracellular proteolysis may be involved in synaptic plasticity, axonal remodelling and neurotoxicity in the adult central nervous system. Here we show that transgenic mice overexpressing tPA in post-natal neurons have increased and prolonged hippocampal long-term potentiation (LTP), and improved performance in spatial orientation learning tasks. Extracellular proteolysis catalysed by tPA may facilitate synaptic micro-remodelling, and thereby play a role in activity-dependent neuronal plasticity and learning.     

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.     

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.     

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.     

Processing of Laminin-5 and Its Functional Consequences: Role of Plasmin and Tissue-type Plasminogen Activator

The laminin-5 component of the extracellular matrices of certain cultured cells such as the rat epithelial cell line 804G and the human breast epithelial cell MCF-10A is capable of nucleating assembly of cell– matrix adhesive devices called hemidesmosomes when other cells are plated upon them. These matrices also impede cell motility. In contrast, cells plated onto the laminin-5–rich matrices of pp126 epithelial cells fail to assemble hemidesmosomes and are motile. To understand these contradictory phenomena, we have compared the forms of heterotrimeric laminin-5 secreted by 804G and MCF-10A cells with those secreted by pp126 cells, using a panel of laminin-5 subunit-specific antibodies. The α3 subunit of laminin-5 secreted by pp126 cells migrates at 190 kD, whereas that secreted by 804G and MCF-10A cells migrates at 160 kD. The pp126 cell 190-kD α3 chain of laminin-5 can be specifically proteolyzed by plasmin to a 160-kD species at enzyme concentrations that do not apparently effect the laminin-5 β and γ chains. After plasmin treatment, pp126 cell laminin-5 not only impedes cell motility but also becomes competent to nucleate assembly of hemidesmosomes. The possibility that plasmin may play an important role in processing laminin-5 subunits is supported by immunofluorescence analyses that demonstrate colocalization of laminin-5 and plasminogen in the extracellular matrix of MCF-10A and pp126 cells. Whereas tissue-type plasminogen activator (tPA), which converts plasminogen to plasmin, codistributes with laminin-5 in MCF-10A matrix, tPA is not present in pp126 extracellular matrix. Treatment of pp126 laminin-5–rich extracellular matrix with exogenous tPA results in proteolysis of the laminin-5 α3 chain from 190 to 160 kD. In addition, plasminogen and tPA bind laminin-5 in vitro. In summary, we provide evidence that laminin-5 is a multifunctional protein that can act under certain circumstances as a motility and at other times as an adhesive factor. In cells in culture, this functional conversion appears dependent upon and is regulated by tPA and plasminogen.     

Tissue plasminogen activator as a modulator of neuronal survival and function

The tissue plasminogen activator (tPA)/plasmin proteolytic system has been implicated in both physiological and pathological processes in the mammalian brain. The physiological roles include facilitating neurite outgrowth and pathfinding. The pathological role involves mediating a critical step in the progression of excitotoxin-induced neurodegeneration. Mechanistically, tPA appears to function through two pathways. The first pathway proceeds via its well established ability to convert plasminogen into plasmin. Plasmin then either promotes neuronal death via both the degradation of the extracellular matrix and the establishment of chemoattractant gradients for microglia, or facilitates neurite outgrowth through the processing of extracellular matrix proteoglycans. The second pathway for tPA does not involve its proteolytic activity: rather tPA functions as an agonist to stimulate a cell-surface receptor on microglia (the macrophage-like immunocompetent cells of the central nervous system) and results in their activation. Once activated after neuronal injury, microglia contribute to the ensuing neurodegeneration. Using tPA as a link between neurons and microglia, we are focusing on understanding their communication and interactions in the normal and diseased central nervous system.     

Structural requirements for activation of latent platelet-derived growth factor CC by tissue plasminogen activator

Platelet-derived growth factor C (PDGF-C) is one of four members in the PDGF family of growth factors, which are known mitogens and survival factors for cells of mesenchymal origin. PDGF-C has a unique two-domain structure consisting of an N-terminal CUB and a conserved C-terminal growth factor domain that are separated by a hinge region. PDGF-C is secreted as a latent dimeric factor (PDGF-CC), which undergoes extracellular removal of the CUB domains to become a PDGF receptor alpha agonist. Recently, the multidomain serine protease tissue plasminogen activator (tPA), a thrombolytic agent used for treatment of acute ischemic stroke, was shown to cleave and activate PDGF-CC. In this study we determine the molecular mechanism of tPA-mediated activation of PDGF-CC. Using various PDGF-CC and tPA mutants, we were able to demonstrate that both the CUB and the growth factor domains of PDGF-C, as well as the kringle-2 domain of tPA, are required for the interaction and cleavage to occur. We also show that Arg231 in PDGF-C is essential for tPA-mediated proteolysis and that the released "free" CUB domain of PDGF-C can act as a competitive inhibitor of the cleavage reaction. Furthermore, we studied how the PDGF-C/tPA axis is regulated in primary fibroblasts and found that PDGF-C expression is down-regulated by hypoxia but induced by transforming growth factor (TGF)-beta1 treatment. Elucidating the regulation and the mechanism of tPA-mediated activation of PDGF-CC will advance our knowledge of the physiological function of PDGF-CC and tPA and may provide new therapeutic opportunities for thrombolytic and cardiovascular therapies.     

Proteolytic fragments of laminin promote excitotoxic neurodegeneration by up-regulation of the KA1 subunit of the kainate receptor

Degradation of the extracellular matrix (ECM) protein laminin contributes to excitotoxic cell death in the hippocampus, but the mechanism of this effect is unknown. To study this process, we disrupted laminin γ1 (lamγ1) expression in the hippocampus. Lamγ1 knockout (KO) and control mice had similar basal expression of kainate (KA) receptors, but the lamγ1 KO mice were resistant to KA-induced neuronal death. After KA injection, KA1 subunit levels increased in control mice but were unchanged in lamγ1 KO mice. KA1 levels in tissue plasminogen activator (tPA)–KO mice were also unchanged after KA, indicating that both tPA and laminin were necessary for KA1 up-regulation after KA injection. Infusion of plasmin-digested laminin-1 into the hippocampus of lamγ1 or tPA KO mice restored KA1 up-regulation and KA-induced neuronal degeneration. Interfering with KA1 function with a specific anti-KA1 antibody protected against KA-induced neuronal death both in vitro and in vivo. These results demonstrate a novel pathway for neurodegeneration involving proteolysis of the ECM and KA1 KA receptor subunit up-regulation.     

Modulation of Proteolytic Activity During Neuritogenesis in the PC12 Nerve Cell: Differential Control of Plasminogen Activator and Plasminogen Activator Inhibitor Activities by Nerve Growth Factor and Dibutyryl-Cyclic AMP

Extracellular proteolysis is considered to be required during neuritic outgrowth to control the adhesiveness between the growing neurite membrane and extracellular matrix proteins. In this work, PC12 nerve cells were used to study the modulation of proteolytic activity during neuronal differentiation. PC12 cells were found to contain and release a 70-75-kDa tissue-type plasminogen activator (tPA) and a much less abundant 48-kDa urokinase-type plasminogen activator. A plasminogen activator inhibitor (PAI) activity with molecular sizes of 54 and 58 kDa was also detected in PC12 cell conditioned medium and formed high-molecular-mass complexes with released tPA. Release of PAI activity was dependent on treatment with nerve growth factor (NGF), whereas tPA synthesis and release were under control of a cyclic AMP-dependent mechanism and increased on treatment with dibutyryl-cyclic AMP [(But)2cAMP] or cholera toxin. Simultaneous treatment with NGF and (But)2cAMP resulted in increases of both tPA and PAI release and enhancement of tPA-PAI complex formation. The resulting plasminogen activator activity in conditioned medium was high in (But)2cAMP-treated cultures with short neuritic outgrowth but remained low in NGF- or NGF plus (But)2cAMP-treated cultures, where neurite extension was, respectively, large and very large. These results suggest that excess proteolytic activity may be detrimental to neuritic outgrowth and that not only PAI release but also tPA-PAI complex formation is associated with production of large and stable neuritic outgrowth. This can be understood as an involvement of PAI in the protection against neurite-destabilizing proteolytic activity.     

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.     

Zinc-triggered induction of tissue plasminogen activator by brain-derived neurotrophic factor and metalloproteinases

Tissue plasminogen activator (tPA) is necessary for hippocampal long-term potentiation. Synaptically released zinc also contributes to long-term potentiation, especially in the hippocampal CA3 region. Using cortical cultures, we examined whether zinc increased the concentration and/or activity of tPA. Two hours after a 10-min exposure to 300 μM zinc, expression of tPA and its substrate, plasminogen, were significantly increased, as was the proteolytic activity of tPA. In contrast, increasing extracellular or intracellular calcium levels did not affect the expression or secretion of tPA. Changing zinc influx or chelating intracellular zinc also failed to alter tPA/plasminogen induction by zinc, indicating that zinc acts extracellularly. Zinc-mediated extracellular activation of matrix metalloproteinase (MMP) underlies the up-regulation of brain-derived neurotrophic factor (BDNF) and tropomyosin receptor kinase (Trk) signaling. Consistent with these findings, co-treatment with a neutralizing antibody against BDNF or specific inhibitors of MMPs or Trk largely reversed tPA/plasminogen induction by zinc. Treatment of cortical cultures with p-aminophenylmercuric acetate, an MMP activator, MMP-2, or BDNF alone induced tPA/plasminogen expression. BDNF mRNA and protein expression was also increased by zinc and mediated by MMPs. Thus, an extracellular zinc-dependent, MMP- and BDNF-mediated synaptic mechanism may regulate the levels and activity of tPA.     

Lysine 156 promotes the anomalous proenzyme activity of tPA: X-ray crystal structure of single-chain human tPA.

Tissue type plasminogen activator (tPA) is the physiological initiator of fibrinolysis, activating plasminogen via highly specific proteolysis; plasmin then degrades fibrin with relatively broad specificity. Unlike other chymotrypsin family serine proteinases, tPA is proteolytically active in a single-chain form. This form is also preferred for therapeutic administration of tPA in cases of acute myocardial infarction. The proteolytic cleavage which activates most other chymotrypsin family serine proteinases increases the catalytic efficiency of tPA only 5- to 10-fold. The X-ray crystal structure of the catalytic domain of recombinant human single-chain tPA shows that Lys156 forms a salt bridge with Asp194, promoting an active conformation in the single-chain form. Comparisons with the structures of other serine proteinases that also possess Lys156, such as trypsin, factor Xa and human urokinase plasminogen activator (uPA), identify a set of secondary interactions which are required for Lys156 to fulfil this activating role. These findings help explain the anomalous single-chain activity of tPA and may suggest strategies for design of new therapeutic plasminogen activators.     

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.     

PC12 Cells Overexpressing Tissue Plasminogen Activator Regenerate Neurites to a Greater Extent and Migrate Faster than Control Cells in Complex Extracellular Matrix

Abstract: PC12 cells were stably transfected with expression vectors containing rat tissue plasminogen activator (tPA) under control of either a cytomegalovirus or rous sarcoma virus promoter. Cell lines were characterized using protease assays, ELISAs, immunoblots, northern blots, and Southern blots. Control PC12 cells or cells containing vectors alone released about 1 pg tPA/cell/24 h, whereas cells stably transfected with a tPA cDNA released 2–5 pg tPA/cell/24 h. A strong correlation existed between the amount of tPA released and the ability of cells to degrade extracellular matrix. Experiments with protease inhibitors and antibodies against tPA and plasminogen indicated that degradation of matrix involved tPA-generated plasmin and that the amount of matrix degraded was dependent on the amount of tPA released. Cells expressing high levels of tPA migrated on a three-dimensional matrix about twice as fast as control cells and regenerated neurites within three-dimensional gels of Matrigel to a greater extent than control cells. Antibodies that inhibited tPA and plasminogen decreased migration and neurite regeneration, indicating that tPA was involved in both events. PC12 cells overexpressing tPA should provide a useful model system for investigating neural functions of tPA including its role in migration and regeneration.     

Regulation of the plasminogen activator system in the ovary

Extracellular matrix (ECM) not only provides a structural support for the organism, but also actively conducts cell-to-cell signal transduction and regulates cell proliferation, migration, development and metabolism. The targeted ECM degradation generated by plasminogen activator (PA) and regulated by plasminogen activator inhibitor (PAI) is, therefore, an event that affects a wide variety of physiological and pathological processes. The ovary is the best model to study the regulation and function of extracellular proteolysis mediated by multicomponents like the PA system. Studies carried out over the past 10 years in a number of laboratories have elucidated some of the biochemical events related to the function and regulation of the PA system in the ovary: hormone-induced proteolytic activity provided by tissue-type PA(tPA) and modulated by PAI-1 in the preovulatory follicles is responsible for a controlled and directed proteolysis leading to rupture of selected follicles during ovulation, whereas the coordinated expression of urokinase-type PA (uPA) and PAI-1 in the early growing follicle may be important in ECM degradation during cell proliferation and migration; the PA system may also play a role in the control of corpus luteum (CL) development through an autocrine or paracrine mechanism. Increase in tPA and PAI-1 expression in CL at a later stage is well correlated with a sharp decrease in CL progesterone production, while the increase in uPA mRNA levels and activity in the early stage of CL development is correlated with an increase in progesterone secretion.     

Responses of vascular smooth muscle cell to extracellular matrix degradation.

Vessels remodel to compensate for increases in blood flow/pressure. The chronic exposure of blood vessels to increased flow and circulatory redox-homocysteine may injure vascular endothelium and disrupt elastic laminae. In order to understand the role of extracellular matrix (ECM) degradation in vascular structure and function, we isolated human vascular smooth muscle cells (VSMC) from normal and injured coronary arteries. The apparently normal vessels were isolated from explanted human hearts. The vessels were injured by inserting a blade into the lumen of the vessel, which damages the inner elastic laminae in the vessel wall and polarizes the VSMC by producing a pseudopodial phenotypic shift in VSMC. This shift is characteristic of migratory, invasive, and contractile nature of VSMC. We measured extracellular matrix metalloproteinases (MMPs), tissue plasminogen activator (tPA), tissue inhibitor of metalloproteinase (TIMP), and collagen I expression in VSMC by specific substrate zymography and Northern blot analyses. The injured and elastin peptide, val-gly-val-ala-pro-gly, treated VSMC synthesized active MMPs and reduced expression of TIMP. The level of tPA and collagen type I was induced in the injured, invasive VSMC and in the val-gly-val-ala-pro-gly treated cells. To demonstrate the angiogenic role of elastin peptide to VSMC we performed in vitro organ culture with rings from normal coronary artery. After 3 days in culture the vascular rings in the collagen gel containing elastin peptide elaborated MMP activity and sprouted and grew. The results suggest that val-gly-val-ala-pro-gly peptide generated at the site of proteolysis during vascular injury may have angiogenic activity.     

Tissue plasminogen activator and its receptor in the human amnion, chorion, and decidua at preterm and term

The plasminogen activator system consists of two proteins: tissue plasminogen activator (tPA) and urokinase plasminogen activator (uPA), which act upon their specific receptors to generate plasmin from plasminogen located on the cell surface. Plasmin then acts directly and indirectly to degrade the components of the extracellular matrix (ECM). This process is likely to be important in the normal turnover of the ECM of fetal membranes and in its premature weakening in preterm premature rupture of the fetal membranes. Quantitative Northern analysis and in situ hybridization have shown that the decidua expresses mRNA for tPA. However, the immunolocalized tPA protein was most strongly associated with the amnion and chorion, as was its receptor annexin II, suggesting that the amnion and chorion are the targets for decidual tPA. At term, decidual tPA expression was unaffected by labor, and the tPA receptor was elevated both before and after labor. At preterm, the converse was found: decidual tPA expression was significantly (p < 0. 05) up-regulated by labor, but the tPA receptor was not. The results suggest that the generation of plasmin at term would be controlled by an increased concentration of the tPA receptor in the amnion and chorion, whereas at preterm a pathological increase in plasmin would be generated by an overexpression of tPA, initiated by labor.     

Apolipoprotein E isoprotein-specific interactions with tissue plasminogen activator

Apolipoprotein E (Apo E) is an important genetic risk factor for multiple neurological, vascular and cardiovascular diseases. Previously, we reported Apo E isoprotein-specific modulation of tissue plasminogen activator (tPA) using an in vitro blood-clotting assay. Here, we studied the conformational changes of Apo E2, E3 and E4 in the presence of tPA and vice versa using circular dichroism (CD) and dual polarization interferometry (DPI). We report isoprotein and state-specific intermolecular interactions between the Apo E isoforms and tPA. Apo E2 interaction with immobilized tPA leads to significant conformational changes which are not observed with Apo E3 or E4. Additionally, tPA induces changes in helicity of lipidated Apo E2 whereas no detectable changes were observed in Apo E3 or E4. The Tukey's test for interaction indicated a significant (P < 0.001) interaction between tPA and Apo E2 in the lipidated environment. These results may be important regarding the mechanism by which Apo E has isoprotein-specific effects on many biological processes and diseases involving blood clotting, proteolysis and perfusion.     

Different mechanisms contribute to simultaneous inhibition of urokinase and tissue-type plasminogen activators by glucocorticoids in human ovarian carcinoma cells

Previous studies from our laboratory have demonstrated that OVCA 433 human ovarian carcinoma cells are glucocorticoid responsive by several criteria and contain high affinity, saturable, steroid-specific glucocorticoid receptors. These cells secrete both mammalian plasminogen activators (PAs), urokinase (uPA) and tissue-type PA (tPA). Treatment of OVCA 433 cells with 1 x 10(-7) M dexamethasone (Dex) for 4 days led to 77% and 83% reductions in the extracellular activities of uPA and tPA, respectively, released into serum-free conditioned medium during a 1-h period. Dex treatment led to a 71% decrease in the rate of extracellular uPA antigen accumulation, as determined by enzyme-linked immunosorbent assay, as well as a 73% reduction in steady state uPA mRNA levels. In contrast, Dex treatment led to only a 42% decrease in the rate of extracellular tPA antigen accumulation and a 48% decrease in tPA mRNA levels; such decreases were insufficient to account for the 83% reduction in tPA activity. Thus, while Dex-induced decreases in uPA antigen and mRNA levels accounted for all but 6% of the decrease in uPA activity, a large discrepancy existed between the magnitudes of decreased tPA activity and decreased tPA antigen and mRNA levels. OVCA 433 cells produce both PAI-1 and PAI-2, two specific PA inhibitors. Treatment of cells with 1 x 10(-7) M Dex for 4 days led to a 3.3-fold increase in the rate of extracellular PAI-1 accumulation, with little or no effect on PAI-2 accumulation.(ABSTRACT TRUNCATED AT 250 WORDS)     

A spectrophotometric solid-phase fibrin-tissue plasminogen activator activity assay (SOFIA-tPA) for high-fibrin-affinity tissue plasminogen activators

A new spectrophotometric solid-phase fibrin-tissue plasminogen activator activity assay (SOFIA-tPA), specific for the quantitation of tissue plasminogen activators, is described. The method is based on (1) the high-affinity binding (Kp = 1.4 +/- 2 nM) of tPA to a solid-phase fibrin network constructed by thrombin proteolysis of fibrinogen covalently coupled to polyglutaraldehyde-activated polyvinyl chloride microtiter plates, and (2) the subsequent development of PA activity by the fibrin-tPA complex and its measurement with a coupled assay using a chromogenic substrate highly selective for plasmin. Conditions were chosen such that the rate of para-nitroaniline release from the substrate is directly proportional to the concentration of tPA. The support is able to isolate tPA from the bulk of proteins present in any biological fluid allowing the assay to specifically detect tPA activity (range: 0.01 to 50 IU/ml) even in the presence of other activators, proteases, and inhibitors. Since the assay is done in a well-defined reaction mixture (the fibrin-tPA complex, plasminogen, and the synthetic substrate), kinetics studies using pure or crude tPA can be performed. Standard curves (rate measurement and endpoint methods) were made using the international standard (preparation 83/517) for tPA.