Intact Fibrin Research Articles

The Significance of Fibrin Binding by Plasminogen Activator Inhibitor 1 for the Mechanism of Tissue-type Plasminogen Activator-mediated Fibrinolysis

The specific, reversible interaction between plasminogen activator inhibitor 1 (PAI-1) and intact fibrin polymers was studied using both purified components and isolated activated platelets as a source of PAI-1. A key reagent in these experiments is a PAI-1 mutant, having its P1 reactive center residue arginine replaced by methionine (PAI-1 R346M). The second-order association rate of PAI-1 R346M with tissue-type plasminogen activator is over 10,000-fold lower than that of wild-type PAI-1, whereas the ability of the variant to bind to fibrin is unaltered. Competition experiments demonstrated that PAI-1 R346M is equally effective as wild-type PAI-1 in displacing 125I-labeled PAI-1 from fibrin. Fibrinolysis, mediated by tissue-type plasminogen activator, is inhibited in a dose-dependent manner by purified PAI-1. The inhibition can be relieved in a dose-dependent manner by PAI-1 R346M, presumably due to displacement of wild-type PAI-1 by PAI-1 R346M. Perfusion studies, using platelet-rich clots, revealed that the incorporation of PAI-1 R346M dose dependently decreased the 50% clot lysis time. These data indicate that PAI-1 R346M displaces fibrin-bound, endogenous PAI-1 released from activated platelets. Implications to manipulate PAI-1 activity for the management of clinical complications, in particular reocclusion after thrombolytic therapy, are discussed.

The specific roles of finger and kringle 2 domains of tissue-type plasminogen activator during in vitro fibrinolysis.

The specific roles of the finger (F) and kringle 2 (K2) domains of tissue-type plasminogen activator (t-PA) were quantified with regard to fibrin binding and kinetic parameters for plasminogen activation by employing domain-deletion variants. On an intact fibrin clot, active site-blocked 125I-t-PA has a dissociation constant (Kd) of 0.36 +/- 0.08 microM and a single binding site per fibrin monomer (n = 1.1 +/- 0.1). Deletion of the K2 domain results in a 3-fold increase of the Kd (1.1 +/- 0.2 microM) and a 2-fold increase of the binding sites per fibrin monomer (n = 2.0 +/- 0.3). Deletion of the F domain results in nonsaturable binding with high Kd (3.2 +/- 0.6 microM). These results indicate that the high affinity binding of t-PA to intact fibrin is the resultant of the cooperation of two low affinity binding sites assembled on intact t-PA. Furthermore, fibrin clot lysis experiments were performed, using polymerized fibrin and plasminogen. Enzymatic activity of t-PA (variants) was assessed by following the decrease in turbidity of the polymerized fibrin. Intact recombinant t-PA exhibited a Michaelis constant for plasminogen activation (Km) of 37 +/- 2 nM. Deletion of either the K2 or F domain results in an increase of the Km for plasminogen of 4- and 16-fold, respectively. We interpret these kinetic parameters in terms of the ternary complex model: binding of t-PA to fibrin, mediated simultaneously by both the F and K2 domain, is essential for a correct orientation of the enzyme on the fibrin polymer to yield the optimal "Km-driven" stimulation of fibrin on the activation of plasminogen. The different potencies of various deletion mutants in a plasma clot are explained by decreased affinity of the enzymes both for fibrin and for the substrate plasminogen.

Molecular forms and concentration of fibronectin and fibrin in human gingival crevicular fluid before and after periodontal treatment.

A total of 23 periodontitis-affected sites from seven adults was selected for the study. Crevicular fluid (CF) samples were collected with paper strips before treatment (scaling, root planing, and curettage) and 2, 5, 10, 20, and 40 days after treatment. Each sample was eluted into sterile saline and two aliquots were drawn for gel electrophoresis: one for fibronectin and one for fibrin analysis. Peptides were transferred to nitrocellulose membranes, and molecules were detected by specific antibodies. The proportions of different molecular forms of fibronectin and fibrin were analyzed by laser densitometry. Plaque Index, Papilla Bleeding Index, and pocket depth were recorded before and 40 days after treatment. Radiologic bone loss was estimated from orthopantomograms. Two days after treatment, an increase was seen in the proportions of intact fibronectin, fibronectin fragments larger than 70 kDa, and fibrin-positive material with a greater molecular mass than intact fibrin. Between days 5 and 10, the proportions of these large fragments decreased. The highest fibronectin and fibrin concentrations were seen 10 days after treatment. These changes probably reflect degradation of the subgingival fibrin clot formed after treatment, and indicate resolution of the clot during the first 10 days of healing. This agrees well with previous observations of CF plasmin activity and concentration of collagen synthesis markers in CF after periodontal treatment, and with the histologic changes seen during periodontal healing. Results of the present study, together with earlier reported findings of collagen synthesis after periodontal treatment, also support the hypothesis of sequential appearance of fibronectin and collagens during the process of wound healing.

Molecular assembly of plasminogen and tissue‐type plasminogen activator on an evolving fibrin surface

A well characterized model of an intact and a degraded surface of fibrin that represents the states of fibrin during the initiation and the progression of fibrinolysis was used to quantitatively characterize the molecular interplay between tissue-type plasminogen activator (t-PA), plasminogen and fibrin. The molecular assembly of t-PA and plasminogen on these surfaces was investigated using combinations of proteins that preclude complications due to side reactions caused by generated plasmin: native plasminogen with di-isopropylphosphofluoridate-inactivated t-PA, and a recombinant human plasminogen with the active-site Ser741 mutagenized to Ala which renders the catalytic site inactive. Under these conditions, neither the affinity nor the maximal number of binding sites for plasminogen were modified by the presence of t-PA, indicating that binding sites for plasminogen pre-exist in intact fibrin and are not dependent on the presence of t-PA. In contrast, when plasminogen activation is allowed, increasing binding of plasminogen to the progressively degraded fibrin surface is directly correlated (r = 0.98) to the appearance of the fibrin E-fragment as shown using a monoclonal antibody (FDP-14) that has its epitope in the E domain of fibrin. t-PA was shown to bind with a high affinity to both the intact (Kd = 3.3 +/- 0.6 nM) and the degraded surface of fibrin (Kd = 1.2 +/- 0.4 nM). Binding of t-PA to carboxy-terminal lysine residues of degraded fibrin was shown to be efficiently competed by physiological concentrations of plasminogen (2 microM), indicating that the affinity of t-PA for these residues was lower than that of plasminogen (Kd = 0.66 +/- 0.22 microM) and unrelated to the high affinity of t-PA for specific binding sites on intact fibrin. These data confirm and establish that the generation of carboxy-terminal lysine residues on fibrin during ongoing fibrinolysis, and the binding of plasminogen to these sites, is an important pathway in the acceleration of clot dissolution.

A monoclonal antibody which recognises an epitopic region unique to the intact fibrin polymeric structure

A hybridoma cell line (MH-1) which produces monoclonal antibody, specific to the fibrin polymeric structure, has been established. The MH-1 antibody is an IgG, (κ light chain) which has a relatively high affinity for crosslinked fibrin (K D=6.7 × 10 −10 M) and a 10-fold lower avidity for non-crosslinked fibrin. The antibody is highly specific for fibrin, and no detectable immunoreactivity with fibrinogen was observed in a direct binding ELISA or in a competition assay using a 500-fold molar excess of fibrinogen. In an in vitro assay, plasma clot uptake of 125I-labelled MH-1 was greater than 70% in both the absence and presence of a plasma milieu. The epitope on fibrin, which the antibody recognises, is destroyed by plasmin digestion and therefore the antibody does not crossreact with any fibrin or fibrinogen degradation products. In addition, the antibody does not react with desAA fibrin or fibrin monomer. Disruption of the tertiary molecular structure of the fibrin polymer by reduction or cyanogen bromide cleavage yielded no immunoreactive fragments. Similarly, no immunoreactivity with the individual α β or γ chains of fibrinogen was detected.

A study of the activation of fibrin-bound plasminogen by tissue-type plasminogen activator, single chain urokinase and sequential combinations of the activators

The efficacy of tissue-type plasminogen activator (t-PA) and single chain urokinase-type plasminogen activator (scu-PA) to activate fibrin-bound plasminogen was determined. With the use of a solid-phase model of intact and plasmin-degraded fibrin, the initial rate, Vi (fmol of plasmin/min), of plasmin generation by t-PA, scu-PA and two chain u-PA (tcu-PA) and the ratio, R (mol of plasmin generated/mol of activator) were determined as indicators of the efficiency of plasminogen activation. [Glu)t-plasminogen bound to intact fibrin was most efficiently activated by t-PA (Vi=0.843 and R=4.08), while scu-PA and tcu-PA produced markedly lower activation coefficients (Vi=0.011 and 0.023, and R=0.13 and 0.50 respectively). In contrast, when [Glu] 1-plasminogen was bound to the degraded surface, it became activatable with equivalent efficiencies by both t-PA and scu-PA (R=4.95 and 4.72, respectively). No evidence of Lys-plasminogen formation was observed. Rather, the selective activation of plasminogen bound to degraded fibrin by scu-PA is consistent with a particular interaction of Glu-plasminogen with carboxy-terminal lysine residues on the degraded surface. The consequences of this interaction of scu-PA with plasminogen bound to degraded fibrin on sequential activations of plasminogen by both t-PA and scu-PA were further explored. While the activation by scu-PA and then t-PA produced only an additive effect on plasmin generation, the opposite combination induced a greater than additive affect; the concentration of activators needed to produce 50% of plasmin generation was 70pM for the scu-PA/t-PA combination; in contrast, the amount required to produce a similar degree of activation with the opposite combination (t-PA/scu-PA) was only 17 pM. These results indicate that the potentiation of the scu-PA activity requires both the previous generation of plasmin by t-PA, and plasminogen bound to carboxy-terminal lysine residues of the degraded fibrin surface as a substrate.

Characterization of fibronectin and fibrin(ogen) fragments in gingival crevicular fluid.

A total of 49 crevicular fluid (CF) samples were collected with paper strips from 12 healthy adults. Each sample was eluted into sterile saline and two aliquots were drawn for SDS-PAGE, one for fibronectin and one for fibrin analysis. Peptides were transferred to nitrocellulose membranes, and fibronectin and fibrin were detected using specific antibodies. The relative amounts of different molecular forms of fibronectin and fibrin were analyzed using a laser densitometer. After the sample collection, Plaque Index, Papilla Bleeding Index and pocket depth were measured. Bone loss was estimated from the orthopanthomograms. Fibronectin fragments were seen in all CF samples. Intact fibronectin was seen in 21 samples, of which 76% were collected from periodontitis-affected sites. There was a positive correlation between the proportion of intact fibronectin and the clinical parameters. Intact fibrin and fibrin fragments were seen in all samples. Fibrin-positive material with larger molecular weight than intact fibrin was also seen in all samples. A negative correlation was found between the proportion of intact fibrin and the clinical parameters. There was no correlation between total amounts and concentrations of fibronectin and fibrin. Molecular forms of fibronectin and fibrin may affect the pathogenesis and healing of periodontal diseases, since the biologic effects of the fragments of these molecules differ from those of the intact molecules.

Apolipoprotein(a) and plasminogen interactions with fibrin: a study with recombinant apolipoprotein(a) and isolated plasminogen fragments.

Lipoprotein(a) [Lp(a)], but not low-density lipoprotein (LDL), was previously shown to impair the generation of fibrin-bound plasmin [Rouy et al. (1991) Arterioscler. Thromb. 11, 629-638] by a mechanism involving binding of Lp(a) to fibrin. It was therefore suggested that the binding was mediated by apolipoprotein(a) [apo(a)], a glycoprotein absent from LDL which has a high degree of homology with plasminogen, the precursor of the fibrinolytic enzyme plasmin. Here we have evaluated this hypothesis by performing comparative fibrin binding studies using a recombinant form of apo(a) containing 17 copies of the apo(a) domain resembling kringle 4 of plasminogen, native Lp(a), and Glu-plasminogen (Glu1-Asn791). Attempts were also made to identify the kringle domains involved in such interactions using isolated elastase-derived plasminogen fragments. The binding experiments were performed using a well-characterized model of an intact and of a plasmin-digested fibrin surface as described by Fleury and Anglés-Cano [(1991) Biochemistry 30, 7630-7638]. Binding of r-apo(a) to the fibrin surfaces was of high affinity (Kd = 26 +/- 8.4 nM for intact fibrin and 7.7 +/- 4.6 nM for plasmin-degraded fibrin) and obeyed the Langmuir equation for adsorption at interfaces. The binding to both surfaces was inhibited by the lysine analogue AMCHA and was completely abolished upon treatment of the degraded surface with carboxypeptidase B, indicating that r-apo(a) binds to both the intrachain lysines of intact fibrin and the carboxy-terminal lysines of degraded fibrin. As expected from these results, both r-apo(a) and native Lp(a) inhibited the binding of Glu-plasminogen to the fibrin surfaces.(ABSTRACT TRUNCATED AT 250 WORDS)

A comparison of the rates of clot lysis in a plasma milieu induced by tissue plasminogen activator (t-PA) and rec-pro-urokinase: Evidence that t-PA has a more restricted mode of action

Tissue plasminogen activator (t-PA) and pro-urokinase (pro-UK) were previously found to have distinct and complementary mechanisms of action in a plasma milieu. The t-PA activated primarily plasminogen bound to intact fibrin (internal lysine-bound), whereas pro-UK activated plasminogen bound to partially degraded fibrin (C-terminal lysine-bound). These observations therefore suggested that each of these activators was restricted in its fibrin-dependent lytic effect. At least this is true at activator concentrations where activation of plasminogen is strictly fibrin dependent; at some high concentration all plasminogen is activated including free plasminogen in the ambient plasma. However, since some pro-UK is converted to UK at the plasmin rich fibrin surface during the course of lysis and since UK is a non-selective plasminogen activator, the pro-UK/UK system should not be similarly restricted. The present study was therefore designed to examine whether this is the case by determining the highest rates of lysis achievable at the threshold of specificity for t-PA and for pro-UK/UK respectively. Maximal rates of clot lysis by t-PA (0.1–5 μg/ml) and by rec-pro-UK (0.5–5 μg/ml) were determined and correlated with the degree of preservation of fibrinogen. The highest rate of clot lysis induced by a fibrin-specific (<10% fibrinogen degradation) dose of rec-pro-UK was 80%/h. A similar rate could not be induced by t-PA without causing >80% fibrinogen degradation. The highest fibrin-specific rate of lysis achievable with t-PA was only 42%/h. When a small amount of t-PA was added at intervals during clot lysis induced by rec-pro-UK, the t-PA significantly foreshortened the lag phase, but it did not enhance the maximal rate of clot lysis. By contrast, when rec-pro-UK was added during the course of clot lysis induced by a large, but fibrin-specific amount of t-PA, rec-pro-UK accelerated the rate of lysis thereby demonstrating the presence of some fibrin-bound plasminogen not activated by t-PA. The study indicates that in a plasma milieu t-PA is more restricted in its action and activates only about half the fibrin-bound plasminogen which is activated by rec-pro-UK/UK.

A comparative study of the promotion of tissue plasminogen activator and pro-urokinase-induced plasminogen activation by fragments D and E-2 of fibrin.

Plasmin generation by equimolar concentrations of tissue plasminogen activator (t-PA), pro-urokinase (pro-UK), and urokinase (UK), and a twofold higher concentration of a plasmin-resistant mutant rpro-UK (Ala-158-pro-UK) was measured on a microtiter plate reader. The promoting effects on this reaction of equimolar concentrations of fibrinogen, soluble fibrin (Desafib), CNBr fragment FCB-2 (an analogue of fragment D), or purified fragment E-2 were compared. Plasmin generation by t-PA was moderately promoted by fibrinogen, substantially promoted by Desafib and FCB-2, but not at all promoted by fragment E-2. By contrast, plasmin generation by pro-UK or by Ala-158-pro-UK was not promoted either by fibrinogen, Desafib, or FCB-2, but was significantly promoted by fragment E-2. Plasmin generation by UK was not significantly promoted by any of the fibrin(ogen) preparations. Treatment of fragment E-2 by carboxypeptidase-B (CPB), eliminated its promotion of pro-UK and Ala-158-pro-UK-induced plasmin generation. Pretreatment of FCB-2 with plasmin slightly potentiated its promotion of t-PA activity. This effect of plasmin pretreatment of FCB-2 was reversed by CPB treatment. Plasmin pretreatment of FCB-2 did not induce any promotion of activity in pro-UK or Ala-158-pro-UK. The findings show that the intrinsic activity of pro-UK and the activity of t-PA are promoted by different regions of the fibrin(ogen) molecule. The latter is stimulated primarily by a determinant in the fragment D region, which is available in intact fibrin. By contrast, plasminogen activation by the intrinsic activity of pro-UK was stimulated exclusively by fragment E-2, which is unavailable in intact fibrin. The findings are believed relevant to fibrinolysis and support the concept that t-PA and pro-UK are complementary, sequential, and synergistic in their actions.

Characterization of the binding of plasminogen to fibrin surfaces: The role of carboxy-terminal lysines

In the present study we have quantitatively characterized the interaction of purified human Glu- and Lys-plasminogen with intact and degraded fibrin by ligand-binding experiments using a radioisotopic dilution method and antibodies against human plasminogen. A fibrinogen monolayer was covalently linked to a solid support with polyglutaraldehyde and was treated with thrombin or with thrombin and then plasmin to respectively obtain intact and degraded fibrin surfaces. Under these conditions, a well-defined surface of fibrin is obtained (410 +/- 4 fmol/cm2) and, except for a 39-kDa fragment, most of the fibrin degradation products remain bound to the support. New binding sites for plasminogen were detected on the degraded surface of fibrin. These sites were identified as carboxy-terminal lysine residues both by inhibition of the binding by the lysine analogue 6-aminohexanoic acid and by carboxy-terminal end-group digestion with carboxypeptidase B. The binding curves exhibited a characteristic Langmuir adsorption isotherm saturation profile. The data were therefore analyzed accordingly, assuming a single-site binding model to simplify the analysis. Equilibrium dissociation constants (Kd) and the maximum number of binding sites (Bmax) were derived from linearized expression of the Langmuir isotherm equation. The Kd for the binding of Glu-plasminogen to intact fibrin was 0.99 +/- 0.17 microM and for degraded fibrin was 0.66 +/- 0.22 microM. The Kd for the binding of Lys-plasminogen to intact fibrin was 0.41 +/- 0.22 microM and for degraded fibrin was 0.51 +/- 0.12 microM.(ABSTRACT TRUNCATED AT 250 WORDS)

Characterization of fibrin(ogen) fragments in gingival crevicular fluid

Crevicular fluid (CF) samples were collected by paper strips from healthy and diseased sites. The molecular distribution of fibrin and fibronectin in CF and plasma samples was investigated using SDS-polyacrylamide gel electrophoresis and specific immunoglobulins. Intact fibrin was found in all CF samples. In addition several bands with both lower and higher molecular weights than intact fibrin were seen. These bands were not present in the plasma samples. The low molecular weight bands are suggested to represent degradation products of fibrin. The high molecular bands could be fibrin-fibronectin complexes or fragments of large fibrin polymers. Fibronectin degradation products, but not intact fibronectin, were seen in both healthy and diseased samples.

The dissociation constants and stoichiometries of the interactions of Lys-plasminogen and chloromethyl ketone derivatives of tissue plasminogen activator and the variant delta FEIX with intact fibrin.

Active-site-blocked, fluorescent derivatives of tPA (Activase) and a variant (delta FEIX) which lacks the finger and epidermal growth factor-like domains and possesses Asn to Gln and Val to Met mutations at residues 117 and 245, respectively, were prepared. The binding of these to fibrin was studied by adding them at systematically varying concentrations to fibrinogen, at a fixed concentration, inducing clotting with thrombin, separating free and bound tPA or delta FEIX by centrifugation, and measuring the concentration of unbound material by extrinsic fluorescence. Similar studies were performed with Glu and Lys-plasminogen, using intrinsic fluorescence. epsilon-amino caproic acid (EACA) was utilized to distinguish kringle-dependent from finger-dependent binding. In the absence of EACA, delta FEIX-bound fibrin through a single class of sites with Kd = 0.69 microM and n = 1.34 delta FEIX/fibrin. The binding of delta FEIX was completely inhibited by EACA and 50% displacement occurred at [EACA] = 300 microM. Fibrin-bound tPA was only partially displaced with EACA. In the presence of 30 mM EACA, tPA binding reflected a single class of sites with Kd = 0.26 microM and n = 0.60 tPA/fibrin. In the absence of EACA, tPA binding was complex, typified by downwardly curved Scatchard plots, and was consistent with interactions of the two classes of sites, characterized by Kd = 0.13 microM, n = 0.60 and Kd = 0.61 microM, n = 1.23. These were attributed to finger and kringle-dependent interactions, respectively. Under the experimental conditions employed, Glu-plasminogen exhibited no binding to fibrin, whereas Lys-plasminogen bound to a single class of sites with Kd = 0.25 microM and n = 1.02 plasminogen/fibrin. This binding was completely inhibited by EACA and 50% displacement occurred at [EACA] = 28 microM. Competition experiments indicated that Lys-plasminogen does not displace either tPA or delta FEIX from fibrin. From these results the conclusions are drawn that tPA can interact with intact fibrin by two different and independent modes, involving, respectively, the finger and kringle 2 domains, and neither of these modes are competitive with the kringle-dependent binding of Lys-plasminogen.

The role of fragment X polymers in the fibrin enhancement of tissue plasminogen activator-catalyzed plasmin formation.

When thrombin-mediated fibrin formation and tissue plasminogen activator (t-PA)-mediated fibrinolysis proceed in dynamic interaction, desA-(desB beta 1-42)-fragment X polymers are shown to be the predominant fibrin derivatives present during the rapid second phase of Glu1- and Lys78-plasminogen activation. To further investigate the effect of this intermediate, a method was developed for the production and purification of fibrinogen-derived desA-(desB beta 1-42)-fragment X, deprived of both COOH-terminal A alpha-chains, but still capable of thrombin-mediated polymerization. DesA-(desB beta 1-42)-fragment X polymer was compared to intact fibrin with regard to its stimulatory effect on Glu1-, Lys78-, and Val443-plasminogen activation, and its binding of Glu1- and Lys78-plasminogen. Pure fragment X polymer gave rise to a biphasic activation pattern like that of fibrin, demonstrating similar kinetics of rapid phase activation. The dissociation constant for the binding of plasminogen to the effector decreases by a factor of 14, and the stoichiometry increases by a factor of 2 upon plasmin-catalyzed cleavage of both native Glu1- to Lys78-plasminogen, and fibrin to fragment X polymer. We conclude that desA-fibrin protofibril formation is sufficient to initiate fibrin enhancement of t-PA-catalyzed plasminogen activation, and that optimal stimulation depends on further plasmin-mediated modification of the fibrin effector to desA-fragment X-related moieties. Optimal stimulation is dependent on the presence of the kringle 1-4 domains of plasminogen and probably results from altered and increased binding of both plasminogen and t-PA to the modified effector.

Effects of intact fibrin and partially plasmin-degraded fibrin on kinetic properties of one-chain tissue-type plasmanogen activator

A comparative kinetic analysis of the enzymatic activities of one-chain and two-chain tissue-type plasminogen activator (t-PA) demonstrates that two-chain t-PA catalyzes the hydrolysis of the peptide substrate d-Val-Leu-Arg-pNA about 4-fold more effectively than one-chain t-PA. The difference is accounted for almost entirely by a corresponding difference in the k cat values of the enzymes, whereas the K m values are similar. The amidolytic activity of two-chain t-PA is not enhanced by intact or partially plasmin-degraded fibrin. In contrast, the activity of one-chain t-PA is stimulated up to 3.7-fold by intact fibrin and up to 4.7-fold by plasmin-degraded fibrin (fibrin X-fragment). The stimulatory effects are realized via increases in the k cat values. It appears thus that in the presence of fibrin the intrinsically inferior catalytic properties of one-chain t-PA become similar to the properties of two-chain t-PA. The dependency of the activity of one-chain t-PA on the concentration of fibrin monomer is consistent with a single association site of both proteins and an association constant of K ass=6.25·10 6 1/mol. Stimulations of one-chain t-PA by plasmin-degraded fibrin is more complex and appears to involve two different binding sites with association constants of K ass=0.67·10 9 1/mol and K ass=3.85·10 6 1/mol, respectively. The stimulatory effects of fibrin and partially plasmin-degraded fibrin on one-chain t-PA are suppressed by ϵ-aminocaproic acid and by a monoclonal antibody directed against the lysine binding site of t-PA. The latter findings support the notion that fibrin activation of one-chain t-PA is mediated by the lysine binding site on kringel domains of the enzyme.

Biochemical and functional characterization of human tissue-type plasminogen activator variants obtained by deletion and/or duplication of structural/functional domains.

Five cDNA encoding human tissue-type plasminogen activator (t-PA) variants with deletion and/or duplication of structural/functional domains were cloned and expressed in Chinese hamster ovary cells. The mutants included: rt-PA-delta FE (where r represents recombinant), with deletion of the finger (F) and growth factor (E) domains; rt-PA-delta K1 delta K2, with replacement of kringle 1 (K1) by a second copy of kringle 2 (K2); and rt-PA-delta FK1 delta K2, rt-PA-delta EK1 delta K2, and rt-PA-delta FEK1 delta K2, with deletions in rt-PA-delta K1 delta K2 of the finger or growth factor domain or both, respectively. The variant rt-PAs, purified to homogeneity, were obtained essentially as single-chain molecules. CNBr-digested fibrinogen enhanced plasminogen activation between 110-fold with rt-PA-delta EK1 delta K2 and 150-fold with rt-PA-delta FEK1 delta K2 as compared to 140-fold with rt-PA. All rt-PA moieties showed a comparable concentration-dependent binding to fibrin, except rt-PA-delta FE, which had significantly reduced binding that was, however, partially restored by additional replacement of K1 with K2. All the rt-PA variants with two copies of K2 showed increased binding to lysine-Sepharose as compared to rt-PA, whereas rt-PA-delta FE had reduced binding. All rt-PA moieties induced a similar time- and concentration-dependent lysis of a 125I-fibrin-labeled plasma clot immersed in human plasma. Equally effective concentrations (causing 50% clot lysis in 2 h) ranged between 1.0 microgram/ml for rt-PA-delta K1 delta K2 and 1.6 micrograms/ml for rt-PA-delta FE as compared to 0.5 microgram/ml for rt-PA. Thus, replacement in rt-PA of K1 by a second copy of K2, which is known to contain a lysine-binding site, significantly enhances its affinity for lysine, with maintenance of its affinity for intact fibrin. Deletion of the finger and growth factor domains results in decreased fibrin affinity and fibrinolytic potency in a plasma milieu, which are partially restored by replacement of K1 by K2.

Comparison of the Effects of Fibrinogen and Fibrin Products and Isolated Peptide Chains on the Fibrin-Mediated Stimulation of Plasminogen Activation by Tissue-Type Plasminogen Activator, and on the Fibrin-Dependent Enhancement of the Amidolytic Activity of One-Chain Tissue-Type Plasminogen Activator

Intact fibrin monomer, the early fibrin degradation product (X-fragment), late fibrinogen degradation products (fragments D and E), fibrinogen cyanogen bromide fragment FCB-2, and isolated peptide chains of fibrinogen and fibrin were investigated for their ability to replace fibrin in the stimulation of one-chain tissue-type plasminogen activator. They were also investigated for their ability to stimulate plasminogen activation by one-chain tissue-type plasminogen activator, which occurs via ternary complex formation. The stimulatory effect of the different fibrin/ogen products decreased in the order: fibrin X-fragment greater than fibrin monomer greater than CNBr-fragment FCB-2 greater than fibrin alpha-chain. Fibrin beta/gamma-chains and fibrinogen peptide chains were found to be weak stimulators. Fibrinogen fragments D and E have almost no effect. The amidolytic activity of one-chain tissue-type plasminogen activator was stimulated by intact fibrin monomer and somewhat more strongly by fibrin X-fragment. This stimulation by fibrin monomer, which occurred via an increase in the kcat value, was competitively inhibited by isolated fibrin alpha-chain (Ki = 0.12 mumol/l). The results show that the fibrin-mediated stimulation of plasminogen activation occurs when both one-chain tissue-type plasminogen activator and plasminogen are bound to fibrin, and that this process is essentially independent of the conformation of the fibrin molecule. In comparison, the fibrin-dependent stimulation of the amidolytic activity of one-chain tissue-type plasminogen activator is a more complex process, which depends on the correct conformation of the fibrin molecule.

Identification of the Domains of Tissue-type Plasminogen Activator Involved in the Augmented Binding to Fibrin after Limited Digestion with Plasmin

The binding of recombinant tissue-type plasminogen activator (rt-PA) to fibrin increases upon digestion of fibrin with plasmin. Optimal binding is observed following a limited plasmin digestion of fibrin, coinciding with the generation of fibrin fragment X polymers. We studied the involvement of the separate domains of the amino-terminal "heavy" (H) chain of rt-PA in this augmentation of fibrin binding. The fibrin-binding characteristics of a set of rt-PA deletion mutants, lacking either one or more of the structural domains of the H chain, were determined on intact fibrin matrices and on fibrin matrices that were subjected to limited digestion with plasmin. The augmented fibrin binding of rt-PA is partially abolished when the plasmin-degraded fibrin matrices are subsequently treated with carboxypeptidase B, demonstrating that this increased binding is dependent on the generation of carboxyl-terminal lysine residues in the fibrin matrix. Evidence is provided that this increase of fibrin binding is mediated by the kringle 2 (K2) domain that contains a lysine-binding site. Further increase of the fibrin binding of rt-PA is independent of the presence of carboxyl-terminal lysines. It is shown that the latter increase is not mediated by the K2 domain. Based on our data, we propose that the increase in fibrin binding, unrelated to the presence of carboxyl-terminal lysine residues, is mediated by the finger (F) domain, provided that this domain is correctly exposed in the remainder of the protein.

Quantitative characterization of the binding of plasminogen to intact fibrin clots, lysine-sepharose, and fibrin cleaved by plasmin.

The binding of human Glu- and Lys-plasminogens to intact fibrin clots, to lysine-Sepharose, and to fibrin cleaved by plasmin was quantitatively characterized. On intact fibrin clots, there was one strong binding site for Glu-plasminogen with a dissociation constant, Kd, of 25 microM and one strong binding site for Lys-plasminogen with a Kd of 7.9 microM. In both cases, the number of plasminogen binding sites per fibrin monomer was 1. Also, a much weaker binding site for Glu-plasminogen was observed with a Kd of about 350 microM. Limited digestion of fibrin by plasmin created additional binding sites for plasminogen with Kd values similar to the binding of plasminogen to lysine-Sepharose. This was predictable given the observations that plasminogen binds to lysine-Sepharose and can be eluted with epsilon-aminocaproic acid [Deutsch, D.G., & Mertz, E.T. (1970) Science (Washington, D.C.) 170, 1095-1096] and that plasmin preferentially cleaves fibrin at the carboxy side of lysyl residues [Weinstein, M.J., & Doolittle, R.F. (1972) Biochim. Biophys. Acta 258, 577-590], because the structures of the lysyl moiety in lysine-Sepharose and of epsilon-aminocaproic acid are identical with the structure of a COOH-terminal lysyl residue created by plasmin cleavage of fibrin. The Kd for the binding of Glu-plasminogen to lysine-Sepharose was 43 microM and for fibrin partially cleaved by plasmin 48 microM. The Kd for the binding of Lys-plasminogen to lysine-Sepharose was 30 microM. With fibrin partially cleaved by plasmin, there were two types of binding sites for Lys-plasminogen, one with a Kd of 7.6 microM and the other with a Kd of 44 microM.(ABSTRACT TRUNCATED AT 250 WORDS)

Initial plasmin-degradation of fibrin as the basis of a positive feed-back mechanism in fibrinolysis.

This study deals with the effect of fibrin on the transformation of Glu-plasminogen to Glu-plasmin during fibrinolysis. It focuses particularly on changes in fibrin effector function caused by plasmin-catalysed fibrin degradation. Conversion of 125I-labelled Glu-plasminogen to Glu-plasmin was catalysed by urokinase or tissue plasminogen activator, in the presence of different preparations of progressively degraded fibrin. Plasmin catalysis of Glu-plasminogen and the fibrin (derivative) effector was inhibited by aprotinin. The presence of intact fibrin enhanced the rate of Glu-plasmin formation catalysed by tissue plasminogen activator, but not by urokinase. The presence of initially plasmin-cleaved fibrin, however, increased the rates of Glu-plasmin formation with both activators, as compared to those found with intact fibrin. The rate enhancements induced by initial plasmin degradation of the fibrin effector were associated with an increase in its affinity to both Glu-plasminogen and tissue plasminogen activator, suggesting causal relationships. The weak binding of urokinase was unaffected by fibrin degradation, indicating that effector function was solely exerted on the Glu-plasminogen moiety of urokinase-activated systems. Further degradation of fibrin decreased the stimulating effect on Glu-plasmin formation. This decrease occurred at an earlier stage of degradation with tissue plasminogen activator than with urokinase, indicating that greater integrity of the fibrin effector is necessary for its optimal interaction with the tissue plasminogen activator than with Glu-plasminogen. Concentrations of tranexamic acid that saturate low-affinity lysine-binding sites nearly completely dissociated the binding of Glu-plasminogen to degraded fibrin, but not to intact fibrin. In analogy with the binding of lysine analogues to these sites, the conformation of Glu-plasminogen may be altered by binding to degraded fibrin, thus giving rise to the increased activation rate.