A highly sensitive chromogenic microtiter plate assay for plasminogen activators which quantitatively discriminates between the urokinase and tissue-type activators

A simple and highly sensitive chromogenic microtiter plate assay for plasminogen activators is described. The assay is based on plasmin cleavage of the synthetic tripeptide plasmin substrate H-D-norleucyl-hexahydrotyrosyl-lysine p-nitroaniline, which yields the yellow chromophore p-nitroanilide. Production of the latter compound is then quantitated spectrophotometrically at 405 nm on an ELISA plate reader. Linearity of the assay can be achieved over at least four orders of magnitude in a single experiment (0.01-100 milliPloug units) with appropriate incubation times. Capitalizing on tissue-type plasminogen activator's dependence on fibrin for enzymatic activity, the selective use of soluble fibrin products allows discrimination between urokinase and tissue-type activator. The utility of this aspect of the assay for the analysis of complex samples containing both types of plasminogen activators is demonstrated.     

A chromogenic assay for the detection of plasmin generated by plasminogen activator immobilized on nitrocellulose using a para-nitroanilide synthetic peptide substrate

A direct solid phase chromogenic assay has been developed for the detection of plasmin (EC 3.4.21.7), generated by the interaction of a nitrocellulose-bound plasminogen activator, using the plasmin specific tripeptide substrate, H-D-valyl-leucyl-lysine - p-nitroaniline. para-Nitroaniline released by the cleavage of the lysine - p-nitroaniline bound by plasmin was derivatized to its diazonium salt and subsequently coupled to N-1-napthylethylenediamine in situ to form a diazoamino of an intense red color at the site of the plasminogen activator. This method was used to assay for the streptococcal plasminogen activator, streptokinase, not only in crude bacterial supernatants, but also to detect streptokinase secreted by individual bacterial colonies. In addition, this solid phase assay was used to identify monoclonal antibodies specific for streptokinase which could inhibit the activation of human plasminogen by streptokinase. This method also permitted simultaneous immunological and biochemical identification of the plasminogen activator, thus permitting unequivocal comparative observations. This assay is quantitative and sensitive to nanogram amounts of activator comparable to those obtained with soluble assays. This method may also be applicable for the detection of other plasminogen activators, such as tissue plasminogen activator, urokinase, and staphylokinase, and also for the detection of immobilized proteases which can cleave other substrates derivatized with p-nitroaniline. The reagents used in this assay are inexpensive and easy to prepare.     

Fluorometric microassay of plasminogen activators.

A new method for determining plasminogen activator levels has been developed. Data are presented which demonstrate measurements of trypsin, plasmin, urokinase, and plasminogen activation. The assay is based on the digestion of N-terminal-blocked protamine and subsequent measurement of the exposed amino groups using the fluorogenic amine reagent, Fluram. The soluble substrate provides an assay which is linear with respect to both time and concentration and which is sensitive enough to allow measurements on a microscale. As little as 1 ng of trypsin, 0.002 CTA units (established by the Committee on Thrombolytic Agents of the NIH) of plasmin, and 0.01 CTA units of urokinase can be detected under the conditions described.Interference with the amine determination due to Fluram-positive material found in biological samples is minimized with the high dilutions attainable with the system. Plasminogen activator in the urine of the female mouse can be detected using 1 μl of urine in a 200-μl test system.     

Regulation of extracellular plasminogen activator by human fibroblasts. The role of protease nexin

When the plasminogen activator urokinase was radioiodinated and incubated at 40 ng/ml in medium conditioned by human foreskin (HF) cells, within 30 min over 80% of the added plasminogen activator was complexed to cell-released protease nexin (PN). The urokinase complexed to PN had little if any activity. Incubation of purified PN with urokinase confirmed that PN is an inhibitor of this plasminogen activator. However, a widely used plasminogen-dependent fibrinolysis assay for plasminogen activator indicated that abundant endogenous plasminogen activator activity co-existed with PN in HF cell-conditioned medium. The source of this activity was electrophoretically and immunologically indistinguishable from urokinase. Furthermore, gel exclusion chromatography showed that about 90% of the urokinase antigen detected in conditioned medium had a molecular weight similar to that of free active urokinase. These paradoxical findings are resolved by evidence that this "PN-resistant urokinase-like" plasminogen activator is actually urokinase proenzyme that is activated by plasmin or conditions in the fibrinolysis assay for plasminogen activator. It is shown that the activated form of HF cell plasminogen activator is sensitive to inhibition by PN. PN may thus be an important component in the cellular regulation of endogenous plasminogen activator activity.     

Purification of epidermal plasminogen activator inhibitor

A plasminogen activator inhibitor was purified from human cornified cell extract by DEAE-Sepharose, Sephacryl S-200, and high-performance liquid chromatographies on hydroxyapatite HPHT and anion-exchanger Mono Q at pH 7.2 and 8.0. The purified inhibitor showed Mr 43,000 and pI 5.2 50% inhibition of fibrinolytic activity (1.5 IU) of urokinase and tissue-type plasminogen activator was attained by 0.60 ng and 11.0 ng purified inhibitor, respectively. Synthetic substrate assay demonstrated slow tight-binding inhibition to both urokinase and tissue-type plasminogen activator. The inhibitor did not inactivate plasmin, thrombin, glandular kallikrein or trypsin.     

Macrophage fibrinolytic activity: identification of two pathways of plasmin formation by intact cells and of a plasminogen activator inhibitor

Endotoxin-stimulated macrophages hydrolyze fibrin by a plasmin-mediated process in the absence of detectable soluble plasminogen activator (PAs). The data show that macrophages also activate plasmin by a membrane-associated plasminogen activator (PAm). In the presence of endotoxin, PAm activity increases, and plasmin is formed only by PAm. In addition, endotoxin stimulates macrophages to secrete a proteinase inhibitor that blocks PAs activity but not PAm or plasmin activity. The increased PAm activity and the PA inhibitor secretion in response to endotoxin explains the ability of intact macrophages to hydrolyze fibrin in the absence of detectable PAs. Endotoxin, 100 ng/ml, induced an intracellular PA inhibitor in cultured macrophages, and this correlated with accumulation of inhibitor in medium over the cells. The intracellular PA inhibitor was found to be 50--60 kilodaltons by gel chromatography, to be of anionic charge at pH 7.4 and to inhibit urokinase esterolytic and proteolytic activity but not preformed plasmin. These results define two pathways of plasmin formation by intact macrophages and identify the macrophage cell surface as a site of PA activity relatively protected from soluble proteinase inhibitors.     

The mechanism of activation of rabbit plasminogen by urokinase.

The data presented in this paper show that when rabbit plasminogen is activated to plasmin by urokinase at least two peptide bonds are cleaved in the process. Urokinase first cleaves an internal peptide bond in plasminogen, leading to two-chain disulfide-linked plasmin molecule. The plasmin heavy chain of molecular weight 66,000 to 69,000 possesses an NH2-terminal amino acid sequence identical with the original plasminogen (molecular weight 88,000 to 92,000). The plasmin light chain of molecular weight 24,000 to 26,000 is known to be derived from the COOH-terminal portion of plasminogen. The plasmin generated during the activation of plasminogen is capable, by a feedback process, of cleaving a peptide of molecular weight 6,000 to 8,000 from the NH2 terminus of the heavy chain, producing a proteolytically modified heavy chain of molecular weight 58,000 to 62,000. Plasmin also can cleave this same peptide from the original plasminogen, yielding an altered plasminogen of molecular weight 82,000 to 86,000. This plasmin-altered plasminogen and the plasmin heavy chain derived from it by urokinase activation process NH2-terminal amino acid sequences which are identical with each other and with the plasminolytic product of the original plasmin heavy chain. These studies support a mechanism of activation of plasminogen by urokinase which involves loss of a peptide located on the NH2 terminus of plasminogen. However, these same results show that this NH2-terminal peptide need not be released from rabbit plasminogen prior to the cleavage of the internal peptide bond which leads to the two-chain plasmin molecule. Furthermore, these studies show that urokinase cannot remove this peptide from either the original rabbit plasminogen molecule or from the heavy chain of the initial plasmin formed.     

Zymogen-activation kinetics. Modulatory effects of trans-4-(aminomethyl)cyclohexane-1-carboxylic acid and poly-D-lysine on plasminogen activation.

The kinetics of plasminogen activation catalysed by urokinase and tissue-type plasminogen activator were investigated. Kinetic measurements are performed by means of a specific chromogenic peptide substrate for plasmin, D-valyl-L-leucyl-L-lysine 4-nitroanilide. Two methods are proposed for the analysis of the resulting progress curve of nitroaniline formation in terms of zymogen-activation kinetics: a graphical transformation of the parabolic curve and transformation of the curve for nitroaniline production into a linear progress curve by the addition of a specific inhibitor of plasmin, bovine pancreatic trypsin inhibitor. The two methods give similar results, suggesting that the reaction between activator and plasminogen is a simple second-order reaction at least at plasminogen concentrations up to about 10 microM. The kinetics of both Glu1-plasminogen (residues 1-790) and Lys77-plasminogen (residues 77-790) activation were investigated. The results confirm previous observations showing that trans-4-(aminomethyl)cyclohexane-1-carboxylic acid at relatively low concentrations enhances the activation rate of Glu1-plasminogen but not that of Lys77-plasminogen. At higher concentrations both Glu1- and Lys77-plasminogen activation are inhibited. The concentration interval for the inhibition of urokinase-catalysed reactions is shown to be very different from that of the tissue-plasminogen activator system. Evidence is presented indicating that binding to the active site of urokinase (KD = 2.0 mM) is responsible for the inhibition of the urokinase system, binding to the active site of tissue-plasminogen activator is approx. 100-fold weaker, and inhibition of the tissue-plasminogen activator system, when monitored by plasmin activity, is mainly due to plasmin inhibition. Poly-D-lysine (Mr 160 000) causes a marked enhancement of plasminogen activation catalysed by tissue-plasminogen activator but not by urokinase. Bell-shaped curves of enhancement as a function of the logarithm of poly-D-lysine concentration are obtained for both Glu1- and Lys77-plasminogen activation, with a maximal effect at about 10 mg/litre. The enhancement of Glu1-plasminogen activation exerted by trans-4-(aminomethyl)cyclohexane-1-carboxylic acid is additive to that of poly-D-lysine, whereas poly-D-lysine-induced enhancement of Lys77-plasminogen activation is abolished by trans-4-(aminomethyl)cyclohexane-1-carboxylic acid. Analogies are drawn up between the effector functions of poly-D-lysine and fibrin on the catalytic activity of tissue-plasminogen activator.     

The mechanism of activation of rabbit plasminogen by urokinase. Lack of a preactivation peptide

We have obtained direct evidence which we interpret to prove that an amino terminal peptide need not be released from rabbit plasminogen prior to its conversion to plasmin by urokinase. The single chain plasminogen molecule possesses an amino terminal amino acid sequence of NH₂-glu-pro-leu-asp-asp. When this plasminogen is activated to plasmin by urokinase in the presence of the Kunitz bovine trypsin-plasmin-kallikrein inhibitor (BTI), a two chain disulfide linked molecule of plasmin is obtained. The heavy chain of this plasmin is directly derived from the original amino terminus of plasminogen since it possesses the identical amino terminal sequence as does native plasminogen. When the same plasminogen activation is carried out in the absence of BTI, the heavy chain of the plasmin obtained has a molecular weight of 6,000–8,000 less than the heavy chain of the plasmin obtained in the presence of this inhibitor. In addition, the heavy chain of this latter plasmin has an amino terminal sequence which differs from the original native plasminogen. These data show, in agreement with others, that the activation of plasminogen by urokinase is accompanied by the loss of an amino terminal peptide from plasminogen but also show, in contrast to the human plasminogen system, that cleavage of the internal peptide bond, leading to plasmin formation, can occur without cleavage of the amino terminal peptide.     

The plasminogen system and cell surfaces: evidence for plasminogen and urokinase receptors on the same cell type

The capacity of cells to interact with the plasminogen activator, urokinase, and the zymogen, plasminogen, was assessed using the promyeloid leukemic U937 cell line and the diploid fetal lung GM1380 fibroblast cell line. Urokinase bound to both cell lines in a time- dependent, specific, and saturable manner (Kd = 0.8-2.0 nM). An active catalytic site was not required for urokinase binding to the cells, and 55,000-mol-wt urokinase was selectively recognized. Plasminogen also bound to the two cell lines in a specific and saturable manner. This interaction occurred with a Kd of 0.8-0.9 microM and was of very high capacity (1.6-3.1 X 10(7) molecules bound/cell). The interaction of plasminogen with both cell types was partially sensitive to trypsinization of the cells and required an unoccupied high affinity lysine-binding site in the ligand. When plasminogen was added to the GM1380 cells, a line with high intrinsic plasminogen activator activity, the bound ligand was comprised of both plasminogen and plasmin. Urokinase, in catalytically active or inactive form, enhanced plasminogen binding to the two cell lines by 1.4-3.3-fold. Plasmin was the predominant form of the bound ligand when active urokinase was added, and preformed plasmin can also bind directly to the cells. Plasmin on the cell surface was also protected from its primary inhibitor, alpha 2-antiplasmin. These results indicate that the two cell lines possess specific binding sites for plasminogen and urokinase, and a family of widely distributed cellular receptors for these components may be considered. Endogenous or exogenous plasminogen activators can generate plasmin on cell surfaces, and such activation may provide a mechanism for arming cell surfaces with the broad proteolytic activity of this enzyme.     

The interaction of streptokinase.plasminogen activator complex, tissue-type plasminogen activator, urokinase and their acylated derivatives with fibrin and cyanogen bromide digest of fibrinogen. Relationship to fibrinolytic potency in vitro.

The effects of purified soluble fibrin and of fibrinogen fragments (fibrin mimic) on the activation of Lys-plasminogen (i.e. plasminogen residues 77-790) to plasmin by streptokinase.plasminogen activator complex and by tissue-type plasminogen activator were studied. Dissociation constants of both activators were estimated to lie in the range 90-160 nM (fibrin) and 16-60 nM (CNBr-cleavage fragments of fibrinogen). The kinetic mechanism for both types of activator comprised non-essential enzyme activation via a Rapid Equilibrium Ordered Bireactant sequence. In order to relate the fibrin affinity of plasminogen activators to their fibrinolytic potency, the rate of lysis of supported human plasma clots formed in the presence of unmodified or active-centre-acylated precursors of plasminogen activators was studied as a function of the concentration of enzyme derivative. The concentrations of unmodified enzyme giving 50% lysis/h in this assay were 0.9, 2.0 and 11.0 nM for tissue-type plasminogen activator, streptokinase.plasmin(ogen) and urokinase respectively. However, the potencies of active-centre-acylated derivatives of these enzymes suggested that acylated-tissue plasminogen activator and streptokinase.plasminogen complexes of comparable hydrolytic stability were of comparable potency. Both types of acyl-enzyme were significantly more potent than acyl-urokinases.     

Activation of plasminogen by pro-urokinase. II. Kinetics

The kinetics of the activation of plasminogen by recombinant pro-urokinase obtained by expression of human urokinase cDNA in Escherichia coli was studied. The conversion of pro-urokinase (U) and plasminogen (P) to urokinase (u) and plasmin (p) is represented by a sequence of three reactions which each obey Michaelis-Menten kinetics, i.e. (Formula: see text). In this model, pro-urokinase formally behaves as an enzyme in Reaction I and as a substrate in reaction II. The experimentally measured overall rates of formation of urokinase and plasmin are in good agreement with those calculated from the kinetic parameters and the initial concentrations of pro-urokinase and plasminogen, confirming the validity of the model. It appears that recombinant pro-urokinase is an equally potent activator of plasminogen (k2/Km = 0.05 microM-1 s-1), as in urokinase (k"2/K"m = 0.02 microM-1 s-1). This is due to the fact that the proenzyme, which is virtually inactive toward low Mr substrates for urokinase, forms an intermediate of the Michaelis-Menten type with plasminogen, with a much higher affinity than that of the active enzyme with its substrate. This is an exceptional phenomenon among the serine proteases.     

Assessment of plasminogen synthesis in vitro by mouse tumor cells using a competition radioimmunoassay for mouse plasminogen

A sensitive, specific competition radioimmunoassay for mouse plasmin(ogen) has been developed in order to determine whether mouse tumor cells can synthesize plasminogen in vitro. The rabbit anti-BALB/c mouse plasminogen antibodies used in the assay react with the plasminogen present in serum from BALB/c, C3H, AKR and C57BL/6 mice, and also recognized mouse plasmin. The competition radioimmunoassay can detect as little as 50 ng of mouse plasminogen. No competition was observed with preparations of fetal calf, human an rabbit plasminogens. A variety of virus-transformed and mouse tumor cell lines were all found to contain less than 100 ng mouse plasminogen/mg of cell extract protein. Thus, if the plasminogen activator/plasmin system is important in the growth or movement of this group of tumor cells, the cells will be dependent upon the circulatory system of the host for their plasminogen supply.     

Plasmin generation induces neutrophil aggregation: dependence on the catalytic and lysine binding sites.

We established that plasmin (10(-10) M to 10(-6) M) caused neutrophils (PMN) to aggregate using an in vitro assay. Plasminogen had no PMN aggregatory activity even at a concentration of 2 microM. However, plasminogen caused PMN to aggregate when incubated with plasminogen activators [tissue plasminogen activator (25-200 U/ml) or urokinase (5-500 U/ml)]. Tissue plasminogen activator and urokinase alone had no PMN aggregatory activity. Analysis of these incubation mixtures indicated that plasmin was generated in the process and that the time course of plasmin generation correlated with the aggregation response. Active-site-inhibited plasmin did not induce PMN aggregation, indicating that a functional catalytic site was required for the response. Pretreatment of PMN with either active-site-inhibited plasmin or tranexamic acid prevented PMN aggregation by plasmin, indicating that both binding of plasmin to the cell surface via the lysine binding sites and catalysis were required for the response. The generation of plasmin during activation of fibrinolysis may play a pro-inflammatory role by mediating aggregation of PMN.     

A soluble, ligand binding mutant of the human urokinase plasminogen activator receptor.

A truncated version of the human urokinase plasminogen activator receptor has been obtained by in vitro mutagenesis by insertion of a premature nonsense codon in the urokinase plasminogen activator receptor cDNA. This results in a protein truncated immediately upstream of the region which appears to be required for membrane attachment of the receptor via a glycolipid anchor. The modified receptor cDNA inserted into an expression vector has been transfected into mouse LB6 cells. Transfectants produce a urokinase plasminogen activator (u-PA)-binding protein that is secreted into the medium. It can be cross-linked to iodinated ATF (amino-terminal fragment of u-PA) and can also inhibit binding of iodinated ATF to mouse LB6 cells that express the wild type human receptor. The soluble u-PA receptor will be used in a variety of experiments aimed at identifying the role and mechanism of u-PA in physiological and pathological invasive processes, as well as in therapeutical attempts to block or decrease cancer cell invasion and in general u-PA-mediated tissue destruction.     

Macrophage plasminogen activator: modulation of enzyme production by anti-inflammatory steroids, mitotic inhibitors, and cyclic nucleotides.

Plasminogen activator production by cultured mouse peritoneal macrophages can be modulated in vitro by low concentrations of various pharmacologically active molecules. Glucocorticoid hormones and their synthetic derivatives, as well as cholera toxin, colchicine, and vinblastine markedly inhibit production of this enzyme without affecting other important macrophage functions. The effect of glucocorticoids is of particular interest, both because their relative in vivo anti-inflammatory potencies correlate exactly with their effect on plasminogen activator production in culture and because this effect occurs at near physiological concentrations. In view of the correlations established in other systems between plasminogen activator production and cell migration, we have also examined the age of the macrophages in thioglycollate-induced exudates. Confirming the results of Van Furth and Cohn (1968), we have found that the majority of these cells are young, having recently replicated and arrived in the peritoneal cavity. Using a fibrinagar overlay technique which allowed us to determine the production of plasminogen activator by individual cells. we have found that the majority of these cells produce the enzyme. The potential roles of plasminogen activator in monocyte migration and the relationship of this enzyme to the anti-inflammatory effect of gluccorticoids are correlated and emphasized.     

Comparative electrophoretic analysis of human and porcine plasminogen activators in SDS-polyacrylamide gels containing plasminogen and casein

Electrophoretic analysis of plasminogen activators from pig heart, human uterus, human plasma and human melanoma cells was performed in SDS-polyacrylamide gradient slab gels containing plasminogen and casein. Direct visualization of activator activity bands in polyacrylamide gels was achieved after removal of SDS, incubation in buffer, and staining with Coomassie brilliant blue. Tissue activator extracted from pig hearts displayed a molecular weight of 72000 and migrated similarly to activator secreted by human melanoma cells and to one activator component present in extracts of human uterus. Immunoadsorption experiments with melanoma cell activator antiserum indicated that these 72-kDa activators are all related immunologically. Human uterus also contained a second activator component with a molecular weight 55000, which migrated similarly to a higher molecular weight component of urokinase and cross-reacted with urokinase antiserum. We conclude that the 72-kDa uterine activator component represents a tissue activator and the 55-kDa component represents a urokinase-like activator. A euglobulin solution from venous occlusion plasma displayed multiple bands of plasmin activity in the Mr range 85000-96000. Two activator components were also present, one of Mr 72000 and another of Mr 62000. The 72-kDa euglobulin activator was adsorbed by MCA antiserum, and we conclude that this component represents vascular activator. The 62000 activator also had weak plasminogen-independent caseinolytic activity and was not affected by either melanoma cell activator or urokinase antisera. Conclusions concerning its identity cannot be made at this time.     

Vitronectin regulates the synthesis and localization of urokinase-type plasminogen activator in HT-1080 cells.

The effect of extracellular matrix composition on the location, amount, and activity of cell-associated urokinase-type plasminogen activator was tested using HT-1080 cells adherent to either fibronectin or vitronectin. Specific immunoprecipitation of newly synthesized urokinase indicated that cells adherent to fibronectin synthesized 2-3-fold more urokinase than cells adherent to vitronectin. Complexes of urokinase and plasminogen activator inhibitor type 1 (PAI-1) were detected in cell layers of vitronectin-adherent but not fibronectin-adherent cells. Inhibition of PAI-1 using a neutralizing monoclonal antibody resulted in a 3-fold increase in urokinase enzymatic activity on vitronectin adherent cells. Urokinase activity on fibronectin adherent cells was only slightly increased following PAI-1 neutralization. Examination of both HT-1080 and normal human fibroblast cells by immunofluorescent microscopy localized urokinase-type plasminogen activator to discrete, focal areas underneath cells adherent to vitronectin. Urokinase was not detectable by immunofluorescence on cells adherent to fibronectin. The addition of exogenous prourokinase to locate urokinase receptors on adherent HT-1080 cells indicated that the focal localization of cell-surface urokinase resulted from the clustering of urokinase receptors following adhesion to vitronectin but not fibronectin-coated substrates. These results suggest that vitronectin can contribute to the control of cell-surface plasmin activity by regulating the synthesis of urokinase and directing the localization of urokinase receptors.     

Expression of recombinant human plasminogen in mammalian cells is augmented by suppression of plasmin activity.

We present evidence that over-expression of human plasminogen, the precursor to the serine protease plasmin, can be cytotoxic to mammalian cells. When an expression vector containing plasminogen cDNA is transfected into baby hamster kidney cells, the number of drug-resistant colonies as well as the levels of plasminogen secreted by those colonies is lower than observed in similar transfections of other protease precursor genes. The recombinant plasminogen accumulates intracellularly as degraded NH2-terminal fragments. In contrast, a mutant of plasminogen that produces inactive plasmin (active site Ser740 changed to Ala) is synthesized by these cells as a full-length plasminogen molecule, and the colony numbers and expression levels are normal. Thus, the generation of plasmin activity is responsible for the cytotoxic phenomena and the degradation associated with plasminogen expression. In addition, experiments using a plasminogen mutant that cannot be activated to plasmin (activation cleavage site Arg560 to Gly) or using coexpression of antisense urokinase RNA indicate that an endogenous plasminogen activator is responsible for converting newly synthesized plasminogen to plasmin. Finally, coexpression of plasminogen with alpha 2-plasmin inhibitor, a serpin which is the physiologic inhibitor of plasmin, prevents the toxic effects of intracellular plasmin activity and allows the synthesis and secretion of native human plasminogen.     

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.