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.     

Functional properties of the recombinant kringle-2 domain of tissue plasminogen activator produced in Escherichia coli

The kringle-2 domain (residues 176-262) of tissue-type plasminogen activator (t-PA) was cloned and expressed in Escherichia coli. The recombinant peptide, which concentrated in cytoplasmic inclusion bodies, was isolated, solubilized, chemically refolded, and purified by affinity chromatography on lysine-Sepharose to apparent homogeneity. [35S]Cysteine-methionine-labeled polypeptide was used to study the interactions of kringle-2 with lysine, fibrin, and plasminogen activator inhibitor-1. The kringle-2 domain bound to lysine-Sepharose and to preformed fibrin with a Kd = 104 +/- 6.2 microM (0.86 +/- 0.012 binding site) and a Kd = 4.2 +/- 1.05 microM (0.80 +/- 0.081 binding site), respectively. Competition experiments and direct binding studies showed that the kringle-2 domain is required for the formation of the ternary t-PA-plasminogen-intact fibrin complex and that the association between the t-PA kringle-2 domain and fibrin does not require plasmin degradation of fibrin and exposure of new COOH-terminal lysine residues. We also observed that kringle-2 forms a complex with highly purified guanidine-activated plasminogen activator inhibitor-1, dissociable by 0.2 M epsilon-aminocaproic acid. The kringle-2 polypeptide significantly inhibited tissue plasminogen activator/plasminogen activator inhibitor-1 interaction. The kringle-2 domain bound to plasminogen activator inhibitor-1 in a specific and saturable manner with a Kd = 0.51 +/- 0.055 microM (0.35 +/- 0.026 binding site). Therefore, the t-PA kringle-2 domain is important for the interaction of t-PA not only with fibrin, but also with plasminogen activator inhibitor-1 and thus represents a key structure in the regulation of fibrinolysis.     

Structure-function analysis of tissue-type plasminogen activator by linker-insertion, point and deletion mutagenesis

We undertook a structure--function analysis of human tissue plasminogen activator (tPA) using linker-scanning and deletion mutagenesis. Synthetic oligonucleotide linkers were introduced into the tPA cDNA at pre-existing restriction enzyme sites. This generated a series of tPA variants which contained small primary sequence alterations consisting of point mutations, deletions or insertions. The majority of the linker-insertion variants demonstrate a significant reduction in amidolytic and fibrinolytic activity in comparison to wild-type tPA. The exceptions are the variants with linker-inserts placed at the BglII(115) and StyI(277) sites of the tPA cDNA (4SLEG5 and 57LEA58 respectively), which encode insertions at the boundaries of the finger domain. The variants with linker-inserts in the light chain (protease domain) of tPA are the lowest in enzymatic activity. Particularly sensitive to mutation are highly conserved amino acids. Heavy chain deletion variants were constructed from point mutants at the domain boundaries of tPA. Deletion of the kringle domains lowers the fibrinolytic activity to a greater extent than deletion of the finger or growth factor domains. We conclude that alterations in any domain of the tPA molecule, and particularly in the highly conserved residues within these domains, can affect fibrinolytic activity.     

Regulation of tissue plasminogen activator activity by cells. Domains responsible for binding and mechanism of stimulation

A number of cell types have previously been shown to bind tissue plasminogen activator (tPA), which in some cases can remain active on the cell surface resulting in enhanced plasminogen activation kinetics. We have investigated several cultured cell lines, U937, THP1, K562, Molt4, and Nalm6 and shown that they bind both tPA and plasminogen and are able to act as promoters of plasminogen activation in kinetic assays. To understand what structural features of tPA are involved in cell surface interactions, we performed kinetic assays with a range of tPA domain deletion mutants consisting of full-length glycosylated and nonglycosylated tPA (F-G-K1-K2-P), DeltaFtPA (G-K1-K2-P), K2-P tPA (BM 06.022 or Reteplase), and protease domain (P). Deletion variants were made in Escherichia coli and were nonglycosylated. Plasminogen activation rates were compared with and without cells, over a range of cell densities at physiological tPA concentrations, and produced maximum levels of stimulation up to 80-fold with full-length, glycosylated tPA. Stimulation for nonglycosylated full-length tPA dropped to 45-60% of this value. Loss of N-terminal domains as in DeltaFtPA and K2P resulted in a further loss of stimulation to 15-30% of the full-length glycosylated value. The protease domain alone was stimulated at very low levels of up to 2-fold. Thus, a number of different sites are involved in cell interactions especially within finger and kringle domains, which is similar to the regulation of tPA activity by fibrin. A model was developed to explain the mechanism of stimulation and compared with actual data collected with varying cell, plasminogen, or tPA concentrations and different tPA variants. Experimental data and model predictions were generally in good agreement and suggest that stimulation is well explained by the concentration of reactants by cells.     

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.     

Involvement of finger domain and kringle 2 domain of tissue-type plasminogen activator in fibrin binding and stimulation of activity by fibrin.

Human tissue-type plasminogen activator (t-PA) catalyses the conversion of inactive plasminogen into active plasmin, the main fibrinolytic enzyme. This process is confined to the fibrin surface by specific binding of t-PA to fibrin and stimulation of its activity by fibrin. Tissue-type plasminogen activator contains five domains designated finger, growth factor, kringle 1, kringle 2 and protease. The involvement of the domains in fibrin specificity was investigated with a set of variant proteins lacking one or more domains. Variant proteins were produced by expression in Chinese hamster ovary cells of plasmids containing part of the coding sequence for the activator. It was found that kringle 2 domain only is involved in stimulation of activity by fibrin. In the absence of plasminogen and at low concentration of fibrin, binding of t-PA is mainly due to the finger domain, while at high fibrin concentrations also kringle 2 is involved in fibrin binding. In the presence of plasminogen, fibrin binding of the kringle 2 region of t-PA also becomes important at low fibrin concentrations.     

On the interaction of the finger and the kringle-2 domain of tissue-type plasminogen activator with fibrin. Inhibition of kringle-2 binding to fibrin by epsilon-amino caproic acid

The binding of tissue-type plasminogen activator (t-PA) to fibrin is mediated both by its finger domain and by its kringle-2 domain. In this report, we investigate the relative affinities of these domains for lysine. Human recombinant t-PA deletion-mutant proteins were prepared and their ability to bind to lysine-Sepharose was investigated. Mutants containing the kringle-2 domain bound to lysine-Sepharose, whereas mutants lacking this domain but containing the finger domain, the epidermal growth factor domain or the kringle-1 domain did not bind to lysine-Sepharose. Mutant proteins containing the kringle-2 domain could be specifically eluted from lysine-Sepharose with epsilon-amino caproic acid. This lysine derivative also abolished fibrin binding by the kringle-2 domain but had no effect on the fibrin-binding property of the finger domain. Thus, a lysine-binding site is involved in the interaction of the kringle-2 domain with fibrin but not in the interaction of the finger domain with fibrin. The implications of the nature of these two distinct interactions of t-PA with fibrin on plasminogen activation by t-PA will be discussed.     

Structural domains of human tissue-type plasminogen activator that confer stimulation by heparin

Heparin has been shown recently to stimulate the activity of human tissue-type plasminogen activator (t-PA). To investigate this effect further, mutant proteins lacking various domains of t-PA were screened for the ability to be stimulated by heparin. Those mutants harboring either the finger domain or the 2nd kringle were found to have enhanced enzymatic activity in the presence of heparin. Only mutants containing these structures would bind to heparin-agarose beads; monoclonal antibodies directed against these domains blocked binding. The stimulatory effect of heparin was more pronounced in finger-containing mutants than kringle-2 proteins. Earlier results had localized the fibrin-binding domains to the same two structures. Unlike heparin, the 2nd kringle was shown to be more important than the finger for fibrin stimulation. Our results have implications for producing recombinant t-PA variants for use in thrombolytic therapy.     

Expression of a Novel Chimeric-Truncated tPA in Pichia pastoris with Improved Biochemical Properties

Thrombolytic therapy by plasminogen activators (PAs) has been a main goal in the treatment of acute myocardial infarction. Despite improved outcomes of currently available thrombolytic therapies, all these agents have different drawbacks that may result in less than optimal outcomes. In order to make tissue plasminogen activator (tPA) more potent, while being more resistant to plasminogen activator inhibitor-1 (PAI-1) and having a higher affinity to fibrin, a new chimeric-truncated form of tPA (CT tPA) was designed and expressed in Pichia pastoris. This novel variant consists of a finger domain of Desmoteplase, an epidermal growth factor (EGF) domain, a kringle 1 (K1) domain, a kringle 2 (K2) domain, in which the lysine binding site (LBS) was deleted, and a protease domain, where the four amino acids lysine 296, arginine 298, arginine 299, and arginine 304 were substituted by aspartic acid. The chimera CT tPA showed 14-fold increase in its activity in the presence of fibrin compared to the absence of fibrin. Furthermore, CT tPA showed about 10-fold more potency than commercially available full-length tPA (Actylase^®) and provided 1.2-fold greater affinity to fibrin. A residual activity of only 68 % was observed after incubation of Actylase^® with PAI-1, however, 91 % activity remained for CT tPA. These promising findings suggest that the novel CT tPA variant might be an acceptable PA with superior characteristics and properties.     

Tissue-type plasminogen activator variants with domain duplications and rearrangements

The interactions between tPA domains that are important for catalysis are poorly understood. We have probed the function of interdomain interactions by generating tPA variants in which domains are duplicated or rearranged. The proteins were expressed in a transient mammalian expression system and tested in vitro for their ability to activate plasminogen, induce fibrinolysis and bind to a forming fibrin clot. Duplication of the heavy chain domains of tPA produced enzymatically active tPA variants, many of which demonstrated similar in vitro amidolytic and fibrinolytic activity and similar fibrin affinity to the parent molecule. Zymographic analysis of the domain duplication tPA variants showed one major active species for each variant. Selection of the residues duplicated and the interdomain spacing were found to be critical considerations in the design of tPA variants with duplicated domains. We also rearranged the domains of tPA such that kringle 1 replaced the second kringle domain and vice versa. An analysis of these variants indicates that the first kringle domain can confer fibrin affinity to a tPA variant and function in place of kringle 2. Therefore, in wild-type tPA, the functions of kringle 1 and kringle 2 must be dependent partially on their orientation within the heavy chain of the protein. The functional autonomy of the heavy and light chains of tPA is demonstrated by the activity of a tPA variant in which the order of the heavy and light chains was reversed.     

Variants of human tissue-type plasminogen activator substituted at the protease cleavage site and glycosylation sites, and truncated at the N- and C-termini

Mutations were directed to specific regions of the human tissue-type plasminogen activator (t-PA) gene in an effort to better define structure-function relationships of the enzyme. Three types of modifications were effected by in vitro mutagenesis: elimination of glycosylation sites; substitutions of amino acids at the cleavage site for conversion of single-chain t-PA to two-chain t-PA; and truncations of the N- and C-termini. Thirteen variants were purified from permanent CHO cell lines and analyzed for specific activity, fibrin stimulation, fibrin binding, inhibition by plasminogen activator inhibitor-2 (PAI-2) and half-life. The results of these analyses are: (i) variants with carbohydrate-depleted kringle domains possessed higher specific activities than wild-type t-PA; (ii) a cleavage site variant substituted at Arg275 with Gly had greatly reduced specific activity; (iii) two variants substituted at Lys277 exhibited altered interactions with PAI-2; (iv) the variant with a truncated C-terminus had reduced activity in the absence of fibrin; and (v) no variants had significantly altered half-lives. In order to test the effects of combining mutations, four additional variants were produced. Each combination variant retained at least one of the altered properties observed in the original variants, and in three of the variants the diverse properties were additive.     

Involvement of aspartic and glutamic residues in kringle-2 of tissue-type plasminogen activator in lysine binding, fibrin binding and stimulation of activity as revealed by chemical modification and oligonucleotide-directed mutagenesis

Modification of glutamic and aspartic acid residues of tissue-type plasminogen activator (t-PA) with 1-ethyl-3(3-dimethyl-aminopropyl)-carbodiimide leads to a decrease in affinity for lysine and fibrin, to a decrease of plasminogen activation activity in the presence of a fibrin mimic, but leaves amidolytic activity and plasminogen activation without fibrin mimic unaffected. Experiments with kringle-2 ligands and a deletion mutant of t-PA (K2P) suggests that glutamic or aspartic acid residues in K2 of t-PA are involved in stimulation of activity, lysine binding and fibrin binding. Mutant t-PA molecules were constructed by site-directed mutagenesis in which one or two of the five aspartic or glutamic acid residues in K2 were changed to asparagine or glutamine respectively. Mutation of Asp236 and/or Asp238 leads to t-PA molecules with 3- to 4-fold lower specific activity in the presence of fibrin mimic and having no detectable affinity for lysine analogs. However, fibrin binding was not influenced. Mutation of Glu254 also leads to a 3- to 4-fold lower activity, but to a much smaller reduction of lysine or fibrin binding. Residues Asp236 and Asp238 are both essential for binding to lysine derivatives, while Glu254 might be involved but is not essential. Residues Asp236, Asp238 and Glu254 are all three involved in stimulation of activity. Remarkably, mutation of residues Asp236 and/or Asp238 appears not to influence fibrin binding of t-PA whereas that of Glu254 does.     

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.     

Saturation mutagenesis of the plasminogen activator inhibitor-1 reactive center.

Plasminogen activator inhibitor-1 (PAI-1) is a specific inhibitor of the serine proteases tissue-type plasminogen activator (tPA) and urokinase-type plasminogen activator (uPA). To systematically investigate the roles of the reactive center P1 and P1' residues in PAI-1 function, saturation mutagenesis was utilized to construct a library of PAI-1 variants. Examination of 177 unique recombinant proteins indicated that a basic residue was required at P1 for significant inhibitory activity toward uPA, whereas all substitutions except proline were tolerated at P1'. P1Lys variants exhibited lower inhibition rate constants and greater sensitivity to P1' substitutions than P1Arg variants. Alterations at either P1 or P1' generally had a larger effect on the inhibition of tPA. A number of variants that were relatively specific for either uPA or tPA were identified. P1Lys-P1'Ala reacted 40-fold more rapidly with uPA than tPA, whereas P1Lys-P1'Trp showed a 6.5-fold preference for tPA. P1-P1' variants containing additional mutations near the reactive center demonstrated only minor changes in activity, suggesting that specific amino acids in this region do not contribute significantly to PAI-1 function. These findings have important implications for the role of reactive center residues in determining serine protease inhibitor (serpin) function and target specificity.     

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

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

Tissue plasminogen activator binds to human vascular smooth muscle cells by a novel mechanism. Evidence for a reciprocal linkage between inhibition of catalytic activity and cellular binding.

Human vascular smooth muscle cells (VSMC) bind tissue plasminogen activator (tPA) specifically, saturably, and with relatively high affinity (K(d) 25 nM), and this binding potentiates the activation of cell-associated plasminogen (Ellis, V., and Whawell, S. A. (1997) Blood 90, 2312-2322). We have observed that this binding can be efficiently competed by DFP-inactivated tPA and S478A-tPA but not by tPA inactivated with H-D-Phe-Pro-Arg-chloromethyl ketone (PPACK). VSMC-bound tPA also exhibited a markedly reduced inhibition by PPACK, displaying biphasic kinetics with second-order rate constants of 7. 5 x 10(3) M(-1) s(-1) and 0.48 x 10(3) M(-1) s(-1), compared with 7. 2 x 10(3) M(-1) s(-1) in the solution phase. By contrast, tPA binding to fibrin was competed equally well by all forms of tPA, and its inhibition was unaltered. These effects were shown to extend to the physiological tPA inhibitor, plasminogen activator inhibitor 1. tPA.plasminogen activator inhibitor 1 complex did not compete tPA binding to VSMC, and the inhibition of bound tPA was reduced by 30-fold. The behavior of the various forms of tPA bound to VSMC correlated with conformational changes in tPA detected by CD spectroscopy. These data suggest that tPA binds to its specific high affinity site on VSMC by a novel mechanism involving the serine protease domain of tPA and distinct from its binding to fibrin. Furthermore, reciprocally linked conformational changes in tPA appear to have functionally significant effects on both the interaction of tPA with its VSMC binding site and the susceptibility of bound tPA to inhibition.     

Kringle 1 domain of human tissue-type plasminogen activator is a functional module mediating fibrinogen-stimulated plasminogenolytic activity

The functions of the finger and kringle-2 (K2) domains of human tissue-type plasminogen activator (t-PA) in mediating fibrin-stimulated plasminogenolytic activity are well documented. Contradictory results have been reported for the kringle-1 (K1) domain with respect to this property. To clarify this issue we have deleted the finger and the K2 domains of t-PA according to the exon-intron organization of the gene by site-directed mutagenesis. The resulting derivative (GK1L) was constitutively expressed in permanent clones of Chinese hamster ovary cells. The secreted proteins have been partially purified and characterized by Western blotting. Since the plasminogenolytic activity of GK1L is stimulated by fibrin, the K1 domain of t-PA must be a functional domain in this context.     

Replacement of finger and growth factor domains of tissue plasminogen activator with plasminogen kringle 1. Biochemical and pharmacological characterization of a novel chimera containing a high affinity fibrin-binding domain linked to a heterologous protein.

A novel triple-kringle plasminogen activator protein, PK1 delta FE1X, has been produced which is a genetic chimera between the fibrin binding kringle 1 domain of plasminogen and the two kringles and serine protease domains of naturally occurring wild-type tissue plasminogen activator (wt t-PA). This chimera also contains a modification to prevent high mannose type N-linked glycosylation on kringle 1 of t-PA. PK1 delta FE1X is biochemically and fibrinolytically similar to wt t-PA in vitro but retains the decreased plasma clearance rate characteristic of other t-PA variants which lack fibronectin finger-like and epidermal growth factor domains. The serine protease domain of PK1 delta FE1X exhibits the amidolytic activity characteristic of wt t-PA. In an indirect coupled plasminogen activator assay, the specific activity of PK1 delta FE1X is approximately 1.4 times greater than that of wt t-PA. In a fibrin film-binding assay, greater binding to untreated fibrin is observed with wt t-PA than with PK1 delta FE1X. However, following limited plasmin digestion of the fibrin film, PK1 delta FE1X binding increases to the level observed with wt t-PA. The incremental binding to plasmin-digested fibrin observed with PK1 delta FE1X is eliminated if plasmin digestion of the fibrin film is followed by carboxypeptidase B treatment. This result suggests that plasminogen kringle 1 binds plasmin-digested fibrin even after recombination with a heterologous protein. The fibrinolytic activity of PK1 delta FE1X in human plasma clot lysis assays was similar to that of wt t-PA at activator concentrations of approximately 1 microgram/ml. At substantially lower concentrations, approximately 0.1 microgram/ml, PK1 delta FE1X was only slightly less active than wt t-PA. Pharmacokinetic analysis showed that wt t-PA activity is cleared approximately 15 times as rapidly as PK1 delta FE1X following intravenous bolus injection. In a rabbit jugular vein clot lysis model, intravenous bolus injection of 0.06 mg/kg of PK1 delta FE1X showed greater thrombolytic potency than a similar administration of 0.5 mg/kg of wt t-PA. Thus it appears that in vitro exon shuffling techniques can be used to generate novel fibrinolytic agents which biochemically and pharmacologically represent the combination of individual domains of naturally occurring proteins.     

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.     

Functional characterization of monoclonal antibodies directed against fibrin binding domains of tissue-type plasminogen activator

Fibrin interacts with tissue-type plasminogen activator (tPA) via the finger and the kringle 2 domains. Three monoclonal antibodies against tPA, designated MPW3VPA, MPW6VPA, and MPW7VPA, which react with epitopes in the tPA molecule involved in fibrin binding, were characterized. The IgM monoclonal antibody MPW6VPA, directed against an epitope close to the finger and epidermal growth factor domains, stimulated plasminogen activation only in the absence of CNBr-fibrinogen fragments by increasing kcat in a dose-dependent fashion, an effect which was not restricted to the intact molecule. These results suggest that MPW6VPA mimics the initial effect of fibrin bound to the tPA molecule, which results in a change of kcat values. The MPW6VPA effect was reversed by another antibody, MPW3VPA, also directed against epidermal growth factor and finger domains. The latter antibody also inhibited plasminogen activation by tPA in the presence of CNBr-fibrinogen fragments in a dose-dependent, apparently noncompetitive way. No effect of MPW3VPA was seen in the absence of CNBr-fibrinogen fragments. MPW7VPA directed against kringle 2 of tPA inhibited plasminogen activation by tPA only when CNBr-fibrinogen fragments were present. This inhibition was apparently competitive and dose-dependent. These data suggest that MPW3VPA interferes with the first phase of fibrin binding to tPA, whereas MPW7VPA interferes with the second phase of fibrin binding to the tPA molecule via kringle 2, resulting in Km changes.