Kinetic analysis of the interaction between plasminogen activator inhibitor-1 and tissue-type plasminogen activator.

The kinetics of inhibition of tissue-type plasminogen activator (t-PA) by the fast-acting plasminogen activator inhibitor-1 (PAI-1) was investigated in homogeneous (plasma) and heterogeneous (solid-phase fibrin) systems by using radioisotopic and spectrophotometric analysis. It is demonstrated that fibrin-bound t-PA is protected from inhibition by PAI-1, whereas t-PA in soluble phase is rapidly inhibited (K1 = 10(7) M-1.s-1) even in the presence of 2 microM-plasminogen. The inhibitor interferes with the binding of t-PA to fibrin in a competitive manner. As a consequence the Kd of t-PA for fibrin (1.2 +/- 0.4 nM) increases and the maximal velocity of plasminogen activation by fibrin-bound t-PA is not modified. From the plot of the apparent Kd versus the concentration of PAI-1 a Ki value of 1.3 +/- 0.3 nM was calculated. The quasi-similar values for the dissociation constants between fibrin and t-PA (Kd) and between PAI-1 and t-PA (Ki), as well as the competitive type of inhibition observed, indicate that the fibrinolytic activity of human plasma may be the result of an equilibrium distribution of t-PA between both the amount of fibrin generated and the concentration of circulating inhibitor.     

Plasminogen and tissue-type plasminogen activator bind to immobilized fibronectin

Fibronectin immobilized onto polystyrene surface was found to bind plasminogen and tissue-type plasminogen activator (t-PA) but only slightly the urokinase type as determined using mono- and polyclonal antibodies against the activators. Of the defined fibronectin fragments tested, the Mr 120,000-140,000 fragment was found to bind both plasminogen and t-PA. Proteolytically modified plasminogen (Lys-plasminogen) bound considerably better than the native form (Glu-plasminogen). Experiments with 125I-plasminogen yielded Kd = 9.1 X 10(-8) M for the binding to immobilized fibronectin. The partially or completely inactive single-chain form of t-PA (pro-t-PA) bound considerably better than the activated two-chain form. Lysine at greater than 3 mM inhibited the binding of plasminogen. The interaction was independent of calcium ions. CaCl2 (greater than 0.5 mM) and NaCl (greater than 0.2 M) inhibited the binding of pro-t-PA and of t-PA. Fibronectin-bound t-PA retained its ability to activate plasminogen. The observed interactions may operate in directional proteolysis localizing plasminogen and plasminogen activator to degrade fibronectin-containing extracellular matrix including fibrin clots.     

On the reversible interaction of plasminogen activator inhibitor-1 with tissue-type plasminogen activator and with urokinase-type plasminogen activator

The reaction between plasminogen activators and plasminogen activator inhibitor-1 is characterized by an initial rapid formation of an inactive reversible complex. The second-order association rate constant (k1) of complex formation of recombinant two-chain tissue-type plasminogen activator (rt-PA) or recombinant two-chain urokinase-type plasminogen activator (rtcu-PA) by recombinant plasminogen activator inhibitor-1 (rPAI-1) is 2.9 +/- 0.4 x 10(7) M-1 s-1 (mean +/- S.D., n = 30) and 2.0 +/- 0.6 x 10(7) M-1 s-1 (n = 12), respectively. Different molecular forms of tissue- or urokinase-type plasminogen activator which do not form covalent complexes with rPAI-1, including rt-PA-Ala478 (rt-PA with the active-site Ser478 mutagenized to Ala) and anhydro-urokinase (rtcu-PA with the active-site Ser356 converted to dehydroalanine) reduced k1 in a concentration-dependent manner, compatible with 1:1 stoichiometric complex formation between rPAI-1 and these ligands. The apparent dissociation constant (KD) of the complex between rPAI-1 and rt-PA-Ala478, determined as the concentration of rt-PA-Ala478 which reduced k1 to 50% of its control value, was 3-5 nM. Corresponding concentrations of active-site-blocked two-chain rt-PA were 150-250-fold higher. The concentration of anhydro-urokinase which reduced k1 to 50% was 4-6 nM, whereas that of active-site-blocked rtcu-PA was 100-250-fold higher. Recombinant single-chain urokinase-type plasminogen activator had an apparent KD of about 2 microM. These results suggest that inhibition of rt-PA or rtcu-PA by rPAI-1 proceeds via a reversible high affinity interaction which does not require a functional active site but which is markedly reduced following inactivation of the enzymes with active-site titrants.     

Oncostatin M induces tissue-type plasminogen activator and plasminogen activator inhibitor-1 in Calu-1 lung carcinoma cells

Oncostatin M (OSM) is a glycoprotein cytokine that is produced by activated T-lymphocytes, monocytes, and macrophages. In a DNA synthesis assay, OSM reduced tritiated thymidine incorporation by 53% in Calu-1 lung carcinoma cells. Radiolabeled cDNAs from untreated Calu-1 cells and 30-h OSM-treated cells were used to probe duplicate nylon membrane cDNA expression arrays. This study revealed OSM-mediated expression of mRNAs encoding tissue-type plasminogen activator (tPA) and plasminogen activator inhibitor-1 (PAI-1). Northern blot analysis showed that the steady-state level of tPA mRNA is nearly undetectable in Calu-1 cells. Exposure of these cells to OSM for 30 h increased tPA mRNA expression by 20-fold and PAI-1 mRNA expression by 5-fold. Exposure of these cells to other gp130 receptor family cytokines, including leukemia inhibitory factor (LIF), interleukin-6 (IL-6), and IL-11, do not significantly affect DNA synthesis or induction of tPA/PAI-1. Western blot studies demonstrated that OSM mediates a marked increase in secretion of the tPA protein. Secreted tPA was present in the conditioned medium almost exclusively as tPA/PAI-1 complexes. Inhibitor studies demonstrated that OSM-mediated induction of tPA and PAI-1 mRNAs is largely dependent upon activation of the MEK1/2 pathway. The JAK3/STAT3 pathway potentially serves a secondary role in these regulatory events.     

Type 1 plasminogen activator inhibitor binds to fibrin via vitronectin

Type 1 plasminogen activator inhibitor (PAI-1), the primary inhibitor of tissue-type plasminogen activator (t-PA), circulates as a complex with the abundant plasma glycoprotein, vitronectin. This interaction stabilizes the inhibitor in its active conformation In this report, the effects of vitronectin on the interactions of PAI-1 with fibrin clots were studied. Confocal microscopic imaging of platelet-poor plasma clots reveals that essentially all fibrin-associated PAI-1 colocalizes with fibrin-bound vitronectin. Moreover, formation of platelet-poor plasma clots in the presence of polyclonal antibodies specific for vitronectin attenuated the inhibitory effects of PAI-1 on t-PA-mediated fibrinolysis. Addition of vitronectin during clot formation markedly potentiates PAI-1-mediated inhibition of lysis of (125)I-labeled fibrin clots by t-PA. This effect is dependent on direct binding interactions of vitronectin with fibrin. There is no significant effect of fibrin-associated vitronectin on fibrinolysis in the absence of PAI-1. The binding of PAI-1 to fibrin clots formed in the absence of vitronectin was characterized by a low affinity (K(d) approximately 3.5 micrometer) and rapid loss of PAI-1 inhibitory activity over time. In contrast, a high affinity and stabilization of PAI-1 activity characterized the cooperative binding of PAI-1 to fibrin formed in the presence of vitronectin. These findings indicate that plasma PAI-1.vitronectin complexes can be localized to the surface of fibrin clots; by this localization, they may modulate fibrinolysis and clot reorganization.     

Interactions between the finger and kringle-2 domains of tissue-type plasminogen activator and plasminogen activator inhibitor-1.

We have shown that plasminogen activator inhibitor-1 (PAI-1) inhibits the fibrin binding of both the single chain and two chain forms of tissue-type plasminogen activator (tPA) through two different mechanisms. PAI-1 inhibits the finger domain-dependent fibrin binding of diisopropylfluorophosphate-inactivated single chain tPA and the kringle-2 domain-dependent fibrin binding of diisopropylfluorophosphate-inactivated two chain tPA. In accordance with the data, preformed complexes of single chain tPA/PAI-1 and of two chain tPA/PAI-1 lost the fibrin binding abilities mediated by the finger and kringle-2 domains, respectively. These effects of PAI-1 appear to be mediated by steric hindrance of the fibrin binding sites after PAI-1 binding to adjacent regions in the functional domains of tPA. We thus propose a model in which a PAI-1 binding site resides in the finger domain of a single chain, and plays a role in the reversible association of single chain tPA and PAI-1. Conformational changes may take place during the conversion of single chain tPA to two chain tPA, resulting in burying of the original PAI-1 binding site and exposure of an alternate PAI-1 binding site on the surface of the kringle-2 domain.     

The plasminogen activator inhibitor-1 binding site in the kringle-2 domain of tissue-type plasminogen activator

We have shown that synthetic peptides containing the amino acid sequence Asn-Arg-Arg-Leu, derived from the amino acid sequence of the inner loop of the kringle-2 domain of tissue-type plasminogen activator (tPA), inhibited complex formation between two chain tPA and plasminogen activator inhibitor-1 (PAI-1) by binding to PAI-1. This binding was reversible and was inhibited by not only tPA but also by enzymatically inactive tPA. Quantitative analyses of the interaction of PAI-1 with the peptide containing the Asn-Arg-Arg-Leu sequence indicated that the PAI-1 binding site residues in the inner loop of the kringle-2 domain and is preferentially expressed in two chain tPA.     

Characterization of interaction of active-site serine mutants of tissue-type plasminogen activator with plasminogen activator inhibitor-1

To define determinants of interactions of tissue-type plasminogen activator (t-PA) with plasminogen activator inhibitor type-1 (PAI-1), we utilized site-directed mutagenesis to substitute either threonine or glycine for the active-site serine of tissue-type plasminogen activator. Assays of conditioned media of transfected cells demonstrated that the threonine substitution markedly decreased but did not entirely abolish plasminogen activating activity. In contrast, the glycine substitution yielded a mutant with absolutely no detectable plasminogen activating activity. Wild-type t-PA formed stable complexes with PAI-1. However, even when exogenous inhibitor was present in the medium or purified mutant was added to plasma that had been rendered PAI-1-rich in vivo, the mutants were present in the free form exclusively judging from results of fibrin autography and Western blot analysis. Thus, despite maintenance of some residual plasminogen-activating activity associated with preservation of the hydroxyl group at the active site, the threonine mutant did not form stable complexes with inhibitor. The glycine mutant, developed so that steric hindrance or other unfavorable interactions at the modified active site would be minimal, was similarly incapable of forming complexes with PAI-1. These results show that the presence of an active site serine residue is necessary for formation of stable complexes between t-PA and PAI-1.     

Tetranectin binds hepatocyte growth factor and tissue-type plasminogen activator.

In the search for new ligands for the plasminogen kringle 4 binding-protein tetranectin, it has been found by ligand blot analysis and ELISA that tetranectin specifically bound to the plasminogen-like hepatocyte growth factor and tissue-type plasminogen activator. The dissociation constants of these complexes were found to be within the same order of magnitude as the one for the plasminogen-tetranectin complex. The study also revealed that tetranectin did not interact with the kindred proteins: macrophage-stimulating protein, urokinase-type plasminogen activator and prothrombin. In order to examine the function of tetranectin, a kinetic analysis of the tPA-catalysed plasminogen activation was performed. The kinetic parameters of the tetranectin-stimulated enhancement of tPA were comparable to fibrinogen fragments, which are so far the best inducer of tPA-catalysed plasminogen activation. The enhanced activation was suggested to be caused by tetranectin's ability to bind and accumulate tPA in an active conformation.     

An experimental and theoretical study on the dissolution of mural fibrin clots by tissue-type plasminogen activator.

During thrombolytic therapy and after recanalization is achieved, reduction in the volume of mural thrombi is desirable. Mural thrombi are known to contribute to rethrombosis and reocclusion. The lysis rate of mural thrombi has been demonstrated to increase with fluid flow in different experimental models, but the mechanisms responsible are unknown. An experimental and a theoretical study were developed to determine the contribution of outer convective transport to the lysis of mural fibrin clots. Normal human plasma containing recombinant tissue-type plasminogen activator (tPA; 0.5 microg/mL) was (re)perfused over mural fibrin clots with fluorescently labeled fibrin at low arterial, arterial, or higher wall shear stresses (4, 18, or 41 dyn/cm(2), respectively) and lysis was monitored in real time. Flow accelerated lysis, but significantly only at the highest shear stress: The average lysis front velocity was 3 x 10(-5) cm/s at 41 dyn/cm(2) vs. almost half of that at the lower shear stresses. Confocal microscopy showed fibrin fibers dissolving only in a narrow region close to the surface when permeation velocity was predicted to be low. A heterogeneous transport-reaction finite element model was used to describe mural fibrinolysis. After scaling the effects of outer and inner convection, inner diffusion, and chemical reactions, a simplified inner diffusion/reaction model was used. Correlation to fibrin lysis data in purified systems dictated higher rates of plasmin(ogen) and tPA adsorption onto fibrin and a decreased catalytic rate of plasmin-mediated fibrin degradation, compared with published parameters. At each shear stress, the model predicted a temporal pattern of lysis of mural fibrin (similar to that observed experimentally), and protease accumulation in a narrow fibrin region and significant lysis inhibition by plasma alpha(2)-antiplasmin (according to the literature). Increasing outer convection accelerated mural fibrinolysis, but the model did not predict the big increase in lysis rate at the highest shear stress. At higher than arterial flows, additional mechanisms not accounted for in the current model, such as fibrin collapse at the fibrin front, may regulate the lysis of mural clots and determine the outcome of thrombolytic therapy.     

Maspin binds to urokinase-type and tissue-type plasminogen activator through exosite-exosite interactions

Maspin is a member of the serpin family with a reactive center loop that is incompatible with proteinase inhibition by the serpin conformational change mechanism. Despite this there are reports that maspin might regulate uPA-dependent processes in vivo. Using exogenous and endogenous fluorescence, we demonstrate here that maspin can bind uPA and tPA in both single-chain and double-chain forms, with K(d) values between 300 and 600 nM. Binding is at an exosite on maspin close to, but outside of, the reactive center loop and is therefore insensitive to mutation of Arg(340) within the reactive center loop. The binding site on tPA does not involve the proteinase active site, with the result that maspin can bind to S195A tPA that is already complexed to plasminogen activator inhibitor-1. The ability of maspin to bind these proteinases without involvement of the reactive center loop leaves the latter free to engage in additional, as yet unidentified, maspin-protein interactions that may serve to regulate the properties of the exosite-bound proteinase. This may help to reconcile apparently conflicting studies that demonstrate the importance of the reactive center loop in certain maspin functions, despite the inability of maspin to directly inhibit tPA or uPA catalytic activity in in vitro assays through engagement between its reactive center loop and the active site of the proteinase.     

Effect of retinoic acid on the synthesis of tissue-type plasminogen activator and plasminogen activator inhibitor-1 in human endothelial cells

The synthesis of plasminogen activators and inhibitors in endothelial cells is highly regulated by hormones, drugs and growth factors. The present study evaluates the effect of retinoic acid on the synthesis of tissue-type plasminogen activator (t-PA) and of plasminogen activator inhibitor-1 (PAI-1) by cultured human umbilical vein endothelial cells (HUVEC). Retinoic acid produced a time- and concentration-dependent increase in the secretion of t-PA-related antigen but not of PAI-1 related antigen into the culture medium. A maximal sevenfold increase of t-PA antigen after 24 h was observed with 10 microM and a half-maximal increase with 0.1 microM retinoic acid. Retinoic acid induced a time-dependent increase of the t-PA mRNA, with a maximum at 8 h and returning to normal at 24 h. The protein kinase inhibitor H7 decreased the t-PA antigen induced by both retinoic acid and phorbol 12-myristate 13-acetate. These results suggest that treatment of HUVEC with retinoic acid increases t-PA production by a pathway which, at some level, involves protein kinases. Thus, retinoic acid induces t-PA synthesis in the absence of altered PAI-1 synthesis, which may enhance the fibrinolytic potential of the endothelium.     

Binding of tissue-type plasminogen activator with human endothelial cell monolayers. Characterization of the high affinity interaction with plasminogen activator inhibitor-1

The formation and release of covalent complexes between tissue-type plasminogen activator (t-PA) and plasminogen activator inhibitor-1 (PAI-1) limits the application of equilibrium radioligand binding analysis to characterize the interaction between t-PA and human umbilical vein endothelial cell (HUVEC) monolayers. To avoid this difficulty, we used a recombinant mutant of t-PA, S478A rt-PA, in which alanine has been substituted for the active-site serine. Although the mutant is incapable of covalently reacting with PAI-1, 125I-labeled S478A rt-PA binding to HUVEC monolayers is specific and reversible and is characterized by a high affinity (Kd of 1.5 nM) and a large number of sites (1.5 x 10(6)/cell). This binding was shown to occur through noncovalent interaction with PAI-1 in the HUVEC monolayer by the fact that a monoclonal anti-PAI-1 antibody (MA-7D4) completely blocked S478A rt-PA binding. Two solution-phase assays with recombinant PAI-1 (rPAI-1) confirmed this noncovalent interaction: complexes between 125I-S478A rt-PA and rPAI-1 could be isolated by immunoprecipitation with anti-PAI-1 antibodies, and S478A rt-PA competed with rt-PA for inactivation by rPAI-1. In contrast diisopropylphosphate rt-PA (in which the active site serine is chemically modified) showed minimal binding to HUVEC monolayers, as a result of impaired interaction with PAI-1, in the two assays. Thus, both wild-type rt-PA and S478A rt-PA interact with the HUVEC monolayer through PAI-1. With rt-PA this results in the formation of covalent rt-PA.PAI-1 complexes that are released from the monolayer into the supernatant. With S478A rt-PA this results in the formation of noncovalent complexes that remain associated with the HUVEC monolayer, thereby identifying a large pool of reactive PAI-1 molecules in the monolayer.     

Vitronectin governs the interaction between plasminogen activator inhibitor 1 and tissue-type plasminogen activator.

The "serpin" plasminogen activator inhibitor 1 (PAI-1) is the fast acting inhibitor of plasminogen activators (tissue-type (t-PA) and urokinase type-PA) and is an essential regulatory protein of the fibrinolytic system. Its P1-P1' reactive center (R346 M347) acts as a "bait" for tight binding to t-PA/urokinase-type PA. In vivo, PAI-1 is encountered in complex with vitronectin, an interaction known to stabilize its activity but not to affect the second-order association rate constant (k1) between PAI-1 and t-PA. Nevertheless, by using PAI-1 reactive site variants (R346M, M347S, and R346M M347S), we show that the binding of vitronectin to the PAI-1 mutant proteins improves plasminogen activator inhibition. In the absence of vitronectin the PAI-1 R346M mutants are virtually inactive toward t-PA (k1 less than 1 x 10(3) M-1 s-1). In contrast, in the presence of vitronectin the rate of association increases about 1,000-fold (k1 of 6-8 x 10(5) M-1 s-1). This inhibition coincides with the formation of serpin-typical, sodium dodecyl sulfide-stable t-PA.PAI-1 R346M (R346M M347S) complexes. As evidenced by amino acid sequence analysis, the newly created M346-M/S347 peptide bond is susceptible to attack by t-PA, similar to the wild-type R346-M347 peptide bond, indicating that in the presence of vitronectin M346 functions as an efficient P1 residue. In addition, we show that the inhibition of t-PA and urokinase-type PA by PAI-1 mutant proteins is accelerated by the presence of the nonprotease A chains of the plasminogen activators.     

Structural determinants of the noncatalytic chain of tissue-type plasminogen activator that modulate its association rate with plasminogen activator inhibitor-1

In order to identify the regions of recombinant (r) tissue plasminogen activator (tPA) that mediate its kinetically relevant interaction with r-plasminogen activator inhibitor-1 (rPAI-1), we have determined the second-order association rate (k1) constants of domain-altered variants of tPA with rPAI-1, at 10 degrees C. With two-chain, wild-type recombinant tPA (tcwt-rtPA), obtained by expression of the human cDNA for tPA in five different cell systems (viz. insect cells, human kidney 293 cells, Chinese hamster ovary cells, human melanoma cells, and mouse C127 cells), the average k1 was 1.45 x 10(7) M-1 s-1 (range, 1.34 10(7) M-1 s-1-1.68 x 10(7) M-1 s-1). Since this value was not significantly different for the different tcwt-rtPA preparations, it appears as though the nature of the glycosylation of tPA plays little role in its initial interaction with PAI-1. The k1 determined for tcwt-rtPA was slightly higher than that of 0.87 x 10(7) M-1 s-1, obtained for a similar inhibition of human urokinase by rPAI-1. The k1 value obtained for single-chain (sc) wt-rtPA was approximately 6-fold lower than that of the two-chain molecules, results consistent with previous conclusions on this matter. The k1 value for tcwt-rtPA was not influenced by the presence of epsilon-aminocaproic acid, suggesting that the lysine-binding site associated with the kringle 2 (K2) region of tPA does not modulate the rate of its initial interaction with rPAI-1. Removal of the K2 domain from tPA, by recombinant DNA technology, results in a protein, F-E-K1-P (tc-r delta K2-tPA), containing only the finger (F), growth factor (E), kringle 1 (K1), and serine protease (P) domains. This variant protein was more rapidly inhibited by rPAI-1 (k1 = 3.00 x 10(7) M-1 s-1) than its wild-type counterparts. Deletion of both the K1 and K2 domains resulted in a variant molecule, F-E-P (tc-r delta K1 delta K2-tPA), that was slightly more rapidly inhibited by rPAI-1 (k1 = 2.01 x 10(7) M-1 s-1).(ABSTRACT TRUNCATED AT 400 WORDS)     

Identification of a conformationally distinct form of plasminogen activator inhibitor-1, acting as a noninhibitory substrate for tissue-type plasminogen activator.

Plasminogen activator inhibitor-1 (PAI-1), the primary physiological inhibitor of tissue-type plasminogen activator (t-PA) in plasma, is a serine proteinase inhibitor (serpin) that forms a 1:1 stoichiometric complex with its target proteinase leading to the formation of a stable inactive complex. The active, inhibitory form of PAI-1 spontaneously converts to a latent form that can be reactivated by protein denaturants. In the present study we have isolated another molecular form of intact PAI-1 that, in contrast with active PAI-1, does not form stable complexes with t-PA but is cleaved at the P1-P1' bond (Arg346-Met347). Other serine proteinases, e.g. urokinase-type plasminogen activator and thrombin, also cleaved this "substrate" form of PAI-1. Fluorescence spectroscopy revealed conformational differences between the latent, active, and substrate forms of PAI-1. This observation confirms our hypothesis that the three functionally different forms of PAI-1 are the consequence of conformational transitions. Thus PAI-1 may occur in three interconvertible conformations: latent, inhibitor, and substrate PAI-1. The identification of two distinct conformations of PAI-1 which interact with their target protease either as an inhibitor or as a substrate is a previously unrecognized phenomenon among the serpins. Conversion of substrate PAI-1 to its inactive degradation product may constitute a pathway for the physiological regulation of PAI-1 activity.     

Reversible interactions between plasminogen activators and plasminogen activator inhibitor-1.

We have shown that the urokinase (UK) kringle domain contains a high-affinity plasminogen activator inhibitor-1 (PAI-1) binding site, responsible for the 10-fold faster complex formation between UK and PAI-1 than between PAI-1 and low-molecular-weight urokinase (LMWUK). Complex formation between UK and PAI-1, but not between LMWUK and PAI-1, was suppressed 10-fold in the presence of peptide U-107 derived from the UK kringle domain. Peptide U-373 derived from the UK catalytic domain slowed complex formation between UK and PAI-1 and also LMWUK and PAI-1. Inactivation of tissue-type plasminogen activator (tPA) by PAI-1 was slowed 10-fold in the presence of peptides derived from the tPA finger and kringle-2 domains. DFP-inactivated (DIP) UK and both forms of DIP-tPA inhibited PAI-1 binding to U-107 and to U-373 whereas single-chain urokinase-type PA (scuPA) was unable to compete with either peptide for PAI-1 binding. These data suggest that the reversible PAI-1 binding site in the UK A-chain plays a role in the rapid association with PAI-1 as important as those that reside in the tPA A-chain and that reversible PAI-1 binding sites are expressed on the surface of UK upon conversion from scuPA, in contrast to tPA.     

Fibrin structures during tissue-type plasminogen activator-mediated fibrinolysis studied by laser light scattering: relation to fibrin enhancement of plasminogen activation

The aim was to relate fibrin structure and the stimulatory effect of fibrin on plasminogen activation during t-PA-mediated fibrinolysis using Lys⁷⁸-plasminogen as activator substrate. Structural studies were undertaken by static and dynamic laser light scattering, cryo transmission electron microscopy and by the measurement of conversion of fibrin to X-, Y- and D-fragments. The kinetics of plasmin formation were monitored by measurement of the rate of pNA-release from Val-LeuLys-pNA. The process of fibrin formation and degradation comprised three phases. In the first phase, protofibrils with an average length of about 10 times that of fibrinogen were formed. The duration of this phase decreased with increasing t-PA concentration. The second phase was characterized by a sudden elongation and lateral aggregation of fibrin fibers, most pronounced at low levels of t-PA, and by formation of fragment X-polymer. The third phase was dominated by fragmentation of fibers and by formation of Y- and D-fragments: Plasmin degraded the fibers from within, resulting in the formation of long loose bundles, which subsequently disintegrated into thin filaments with a length of less than 10 and a mass per length close to one relative to fibrinogen. Plasmin generation at high t-PA concentrations sets in just prior to (and at low t-PA concentrations shortly after) the onset of the rapid second phase of elongation and lateral aggregation of fibrin fibers. The maximal rate of plasmin formation per mol t-PA was the same at all concentrations of activator and was achieved close to the time of the peak level of fragment X-polymer. Plasmin formation ceased after formation of substantial amounts of Y- and D-fragments. At this stage the length was between 300 and 3 and the mass per length close to 1, both relative to fibrinogen. In conclusion our results indicate that (1) formation of short fibrin protofibrils is the minimal requirement for the onset of the stimulatory effect of fibrin on plasminogen activation by t-PA, (2) formation of fragment X protofibrils is sufficient to induce optimal stimulation of plasminogen activation, and (3) plasmin degrades laterally aggregated fibrin fibers from within, resulting in the conversion of the fibers into long loose bundles, which later disintegrate into thin filaments.Abbreviations t-PA tissue-type plasminogen activator - Lys⁷⁸-plasminogen plasmin-modified plasminogen, mainly with NH₂-terminal lysine (residues 78-791, residue numbering according to Forsgren et al. 1987) - Val-Leu-Lys-pNA H-D-valyl-L-leucyl-L-lysine-4-nitroanilide - Phe-Pip-Arg-pNA H-D-phenylalanyl-L-arginine-4-nitroanilide - pNA p-nitroanilide - SDS sodium dodecyl sulphate The present work has been supported by the Danish Natural Science Research Council and the Danish Agricultural and Veterinary Research CouncilDeceased on August 2, 1991 Correspondence to: R. Bauer