Interaction of one-chain and two-chain tissue plasminogen activator with intact and plasmin-degraded fibrin

Tissue-type plasminogen activator (t-PA) plays a central role in fibrinolysis in vivo. Although it is known to bind to fibrin, the dissociation constant (Kd) and number of moles bound per mole of fibrin monomer (n) have never been measured directly. In this study, the binding of both the one-chain form and the two-chain form of recombinant, human t-PA to fibrin was measured. Although more one-chain t-PA than two-chain t-PA is bound to fibrin, the Kd's and n's were within experimental error of each other. Significantly more t-PA is bound to clots made from fibrinogen which has been digested with plasmin than to clots made from intact fibrinogen. The additional binding was shown to be due to the formation of new set(s) of binding site(s) with dissociation constants that are 2-4 orders of magnitude tighter than the binding site present on clots made from intact fibrinogen. epsilon-Aminocaproic acid was capable of competing for the loose binding site present on both intact and degraded fibrin but had little effect on the binding of t-PA to the new site(s) formed by plasmin digestion. This increase in binding caused by plasmin-mediated proteolysis of fibrin suggests a possible mechanism for a positive regulation capable of accelerating fibrinolysis.     

Molecular mechanisms of fibrinolysis and their application to fibrin-specific thrombolytic therapy

The fibrinolytic system comprises a proenzyme, plasminogen, which can be converted to the active enzyme, plasmin, which degrades fibrin. Plasminogen activation is mediated by plasminogen activators, which are classified as either tissue-type plasminogen activators (t-PA) or urokinase-type plasminogen activators (u-PA). Inhibition of the fibrinolytic system may occur at the level of the activators or at the level of generated plasmin. Plasmin has a low substrate specificity, and when circulating freely in the blood it degrades several proteins including fibrinogen, factor V, and factor VIII. Plasma does, however, contain a fast-acting plasmin inhibitor, alpha 2-antiplasmin, which inhibits free plasmin extremely rapidly but which reacts much slower with plasmin bound to fibrin. A "systemic fibrinolytic state" may, however, occur by extensive activation of plasminogen and depletion of alpha 2-antiplasmin. Clot-specific thrombolysis therefore requires plasminogen activation restricted to the vicinity of the fibrin. Two physiological plasminogen activators, t-PA and single-chain u-PA (scu-PA) induce clot-specific thrombolysis, via entirely different mechanisms, however. t-PA is relatively inactive in the absence of fibrin, but fibrin strikingly enhances the activation rate of plasminogen by t-PA. This is explained by an increased affinity of fibrin-bound t-PA for plasminogen and not by alteration of the catalytic rate constant of the enzyme. The high affinity of t-PA for plasminogen in the presence of fibrin thus allows efficient activation on the fibrin clot, while no significant plasminogen activation by t-PA occurs in plasma. scu-PA has a high affinity for plasminogen (Km = 0.3 microM) but a low catalytic rate constant (kcat = 0.02 sec-1). However, scu-PA does not activate plasminogen in plasma in the absence of a fibrin clot, owing to the presence of (a) competitive inhibitor(s). Fibrin-specific thrombolysis appears to be due to the fact that fibrin reverses the competitive inhibition. The thrombolytic efficacy and fibrin specificity of natural and recombinant t-PA has been demonstrated in animal models of pulmonary embolism, venous thrombosis, and coronary artery thrombosis. In all these studies intravenous infusion of t-PA at sufficiently high rates caused efficient thrombolysis in the absence of systemic fibrinolytic activation. The efficacy and relative fibrinogen-sparing effect of t-PA was recently confirmed in three multicenter clinical trials in patients with acute myocardial infarction.(ABSTRACT TRUNCATED AT 400 WORDS)     

A region of tissue plasminogen activator that affects plasminogen activation differentially with various fibrin(ogen)-related stimulators.

The dissolution of blood clots by plasmin is normally initiated in vivo by the activation of plasminogen to plasmin through the activity of tissue plasminogen activator (t-PA). The rate of plasminogen activation can be stimulated several orders of magnitude by the presence of fibrin-related proteins. Here we describe the kinetic analysis of both recombinant human t-PA (wild-type) and a t-PA variant produced by site-directed mutagenesis in which the original sequence from amino acids 296 to 299, KHRR, has been altered to AAAA. This tetra-alanine variant form of t-PA, K296A/H297A/R298A/R299A t-PA, we refer to as "KHRR" t-PA here. The plasminogen activating kinetics of wild-type t-PA (Activase alteplase) showed a catalytic efficiency which changed over 100-fold dependent on the stimulator in the assay. The lowest rate was in the absence of a stimulator. The following stimulators showed increasing ability to accelerate the catalytic efficiency of the reaction: fibrinogen, fragments of fibrinogen obtained by digestion with plasmin, fibrin, and slightly degraded fibrin. This increase in efficiency was driven primarily by decreases in the Michaelis constant (KM) of the reaction, whereas the catalytic rate constant (kcat) of the reaction did not change significantly. The "KHRR" variant of t-PA displayed novel kinetics with all stimulators tested. In the absence of a stimulator or with the poorer stimulators (fibrinogen and fibrinogen fragments), the KM values of the reaction with Activase alteplase and "KHRR" t-PA were similar. The kcat however, was lower with "KHRR" t-PA than with wild-type t-PA.(ABSTRACT TRUNCATED AT 250 WORDS)     

Plasminogen activation by tissue plasminogen activator on fibrin clots with different surface structures

Transformation of fibrinogen into fibrin with consequent formation of the fibrin clot trimeric structure is one of the final steps in the blood coagulation system. The plasminogen activation by the tissue plasminogen activator (t-PA) is one of the fibrinolysis system key reactions. The effect of different factors on transformation of plasminogen into plasmin is capable to change essentially the equilibrium between coagulation and fibrinolytic sections of haemostasis system. We have studied the plasminogen activation by tissue plasminogen activator on fibrin clots surface formed on the interface between two phases and in presence of one phase. The t-PA plasminogen activation rate on fibrin clots both with film and without it the latter has been analyzed. These data allow to assume that the changes of fibrin clot structure depend on its formations, as well as are capable to influence essentially on plasminogen activation process by means of its tissue activating agent.     

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     

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

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

Mechanisms of plasminogen activation by mammalian plasminogen activators

Plasminogen activators convert the proenzyme plasminogen to the active serine protease plasmin by hydrolysis of the Arg560-Val561 peptide bond. Physiological plasminogen activation is however regulated by several additional molecular interactions resulting in fibrin-specific clot lysis. Tissue-type plasminogen activator (t-PA) binds to fibrin and thereby acquires a high affinity for plasminogen, resulting in efficient plasmin generation at the fibrin surface. Single-chain urokinase-type plasminogen activator (scu-PA) activates plasminogen directly but with a catalytic efficiency which is about 20 times lower than that of urokinase. In plasma, however, it is inactive in the absence of fibrin. Chimeric plasminogen activators consisting of the NH2-terminal region of t-PA (containing the fibrin-binding domains) and the COOH-terminal region of scu-PA (containing the active site), combine the mechanisms of fibrin specificity of both plasminogen activators. Combination of t-PA and scu-PA infusion in animal models of thrombosis and in patients with coronary artery thrombosis results in a synergic effect on thrombolysis, allowing a reduction of the therapeutic dose and elimination of side effects on the hemostatic system.     

Modification of fibrinogen by homocysteine thiolactone increases resistance to fibrinolysis: a potential mechanism of the thrombotic tendency in hyperhomocysteinemia

We have previously shown functional differences in fibrinogen from hyperhomocysteinemic rabbits compared to that in control rabbits. This acquired dysfibrinogenemia is characterized by fibrin clots that are composed of abnormally thin, tightly packed fibers with increased resistance to fibrinolysis. Homocysteine thiolactone is a metabolite of homocysteine (Hcys) that can react with primary amines. Recent evidence suggests that Hcys thiolactone-lysine adducts form in vivo. We now demonstrate that the reaction of Hcys thiolactone with purified fibrinogen in vitro produces fibrinogen (Hcys fibrinogen) with functional properties that are strikingly similar to those we have observed in homocysteinemic rabbits. Fibrinogen purified from homocysteinemic rabbits and Hcys fibrinogen are similar in that (1) they both form clots composed of thinner, more tightly packed fibers than their respective control rabbit and human fibrinogens; (2) the clot structure could be made to be more like the control fibrinogens by increased calcium; and (3) they both form clots that are more resistant to fibrinolysis than those formed by the control fibrinogens. Further characterization of human fibrinogens showed that Hcys fibrin had similar plasminogen binding to that of the control and an increased capacity for binding tPA. However, tPA activation of plasminogen on Hcys fibrin was slower than that of the control. Mass spectrometric analysis of Hcys fibrinogen revealed twelve lysines that were homocysteinylated. Several of these are close to tPA and plasminogen binding sites. Lysines are major binding sites for fibrinolytic enzymes and are also sites of plasmin cleavage. Thus, modification of lysines in fibrinogen could plausibly lead to impaired fibrinolysis. We hypothesize that the modification of lysine by Hcys thiolactone might occur in vivo, lead to abnormal resistance of clots to lysis, and thereby contribute to the prothrombotic state associated with homocysteinemia.     

Fibrin and plasminogen structures essential to stimulation of plasmin formation by tissue-type plasminogen activator

Plasminogen activation catalysed by tissue-type plasminogen activator (t-PA) has been examined in the course of concomitant fibrin formation and degradation. Plasmin generation has been measured by the spectrophotometric method of Petersen et al. (Biochem. J. 225 (1985) 149-158), modified so as to allow for light scattering caused by polymerized fibrin. Glu1-, Lys77- and Val442-plasminogen are activated in the presence of fibrinogen, des A- and des AB-fibrin and the rate of plasmin formation is found to be greatly enhanced by both des A- and des AB-fibrin polymer. Plasmin formation from Glu1- and Lys77-plasminogen yields a sigmoidal curve, whereas a linear increase is obtained with Val442-plasminogen. The rate of plasmin formation from Glu1- and Lys77-plasminogen declines in parallel with decreasing turbidity of the fibrin polymer effector. In order to study the effect of polymerization, this has been inhibited by the synthetic polymerization site analogue Gly-Pro-Arg-Pro, by fibrinogen fragment D1 or by prior methylene blue-dependent photooxidation of the fibrinogen used. Inhibition of polymerization by Gly-Pro-Arg-Pro reduces plasmin generation to the low rate observed in the presence of fibrinogen. Antipolymerization with fragment D1 or photooxidation has the same effect on Glu1-plasminogen activation, but only partially reduces and delays the stimulatory effect on Lys77- and Val442-plasminogen activation. The results suggest that protofibril formation (and probably also gelation) of fibrin following fibrinopeptide release is essential to its stimulatory effect. The gradual increase and subsequent decline in the rate of plasmin formation from Glu1- or Lys77-plasminogen during fibrinolysis may be explained by sequential exposure, modification and destruction of different t-PA and plasminogen binding sites in fibrin polymer.     

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.     

Lys-plasminogen is a significant intermediate in the activation of Glu-plasminogen during fibrinolysis in vitro.

Plasminogen, the zymogen form of the fibrinolytic enzyme plasmin, is known to undergo plasmin-mediated modification in vitro. The modified form, Lys-plasminogen, is superior to the native Glu-plasminogen in fibrin binding and as a substrate for activation by tissue-type plasminogen activator (t-PA). The present study was undertaken to determine the existence and significance of the Glu- to Lys-plasminogen conversion during t-PA-mediated lysis of plasma clots in vitro. When human plasma was supplemented with exogenous Lys-plasminogen and clotted, a dose-dependent shortening of lysis time was observed. Formation of Lys-plasminogen in situ during fibrinolysis was determined using 131I-Glu-plasminogen-supplemented plasma. By the time of lysis, Lys-plasminogen had accumulated to about 20% of the initial concentration of Glu-plasminogen. Quantitation of activation of both Glu- and Lys-plasminogen as well as the conversion of Glu- to Lys-plasminogen in plasma supplemented with both 131I-Glu-plasminogen and 125I-Lys-plasminogen was accomplished by determining the flux of the isotopically labeled species along three pathways: Glu-plasminogen-->Glu-plasmin, Glu-plasminogen-->Lys-plasminogen, and Lys-plasminogen-->Lys-plasmin. After a brief lag, the Glu-plasminogen activation rate was constant until lysis was achieved, at which point activation ceased. The Lys-plasminogen activation rate also was essentially constant until lysis but was not characterized by a lag phase. The rate of conversion of Glu- to Lys-plasminogen was nonlinear and correlated directly with the rate of fibrinolysis. By the time lysis had occurred, Glu-plasminogen consumption had been distributed equally between direct activation to plasmin and conversion to Lys-plasminogen, and 45% of the plasmin which had been formed was derived from Lys-plasminogen. These results demonstrate both the formation and the subsequent activation of Lys-plasminogen during fibrinolysis. As a result of improved fibrin binding and activation of Lys-plasminogen compared to Glu-plasminogen, the formation of Lys-plasminogen within a clot constitutes a positive feedback mechanism that can further stimulate the activation of plasminogen by t-PA as fibrinolysis progresses.     

Characterization of a fusion protein consisting of amino acids 1 to 263 of tissue-type plasminogen activator and amino acids 144 to 411 of urokinase-type plasminogen activator

A hybrid human cDNA was constructed by splicing of a cDNA fragment of tissue-type plasminogen activator (t-PA), encoding 5'-untranslated, the pre-pro region and amino acids Ser1-Thr263, with a cDNA fragment of urokinase-type plasminogen activator (u-PA), encoding amino acids Leu144-Leu411. The cDNA fragments were obtained from full length t-PA cDNA, cloned from Bowes melanoma poly(A)+ mRNA, and from full length u-PA cDNA, cloned from CALU-3 lung adenocarcinoma poly(A)+ mRNA. The hybrid (t-PA/u-PA) cDNA was expressed in Chinese hamster ovary cells and the translation product purified from the conditioned cell culture media. On SDS-gel electrophoresis under reducing conditions, the protein migrated as a single band with approximate Mr 70,000. On immunoblotting, it reacted both with rabbit antisera raised against human t-PA and against human u-PA. The urokinase-like amidolytic activity of the protein was only 320 IU/mg but increased to 43,000 IU/mg after treatment with plasmin, which resulted in conversion of the single-chain molecule (t-PA/scu-PA) to a two-chain molecule (t-PA/tcu-PA). The specific activity of the protein on fibrin plates was 57,000 IU/mg by comparison with the International Reference Preparation for Urokinase. Both the single-chain hybrid (t-PA/scu-PA) and the two-chain plasmin derivative (t-PA/tcu-PA) bound specifically to fibrin, albeit more weakly than t-PA. The t-PA/tcu-PA hybrid had a higher selectivity for fibrin than tcu-PA, measured in a system composed of a whole human 125I-fibrin-labeled plasma clot immersed in human plasma. Both hybrid proteins activated plasminogen directly with Km = 1.5 microM and k2 = 0.0058 s-1 for t-PA/scu-PA and with Km = 80 microM and k2 = 5.6 s-1 for t-PA/tcu-PA. CNBr-digested fibrinogen stimulated the activation of plasminogen with t-PA/tcu-PA (Km = 0.20 microM and k2 = 1.2 s-1). It is concluded that these t-PA/u-PA hybrid proteins combine, at least to some extent, the fibrin-affinity of t-PA with the enzymatic properties of u-PA (either scu-PA or tcu-PA), which in some assays result in improved fibrin-mediated plasminogen activation.     

Role of plasminogen, plasmin, and plasminogen activators in the migration of fibroblasts into plasma clots

Human diploid fibroblasts were seeded onto or into plasma clots and different aspects of cell adhesion and migration were measured. The roles of plasminogen activators and plasmin were studied by either the removal of plasminogen from plasma prior to clotting or by the addition of 10 mM epsilon-aminocaproic acid, which brings about an inhibition of plasmin in this system. When cells were seeded onto the surface of plasma clots, rates of attachment, spreading, and migration were unaffected by plasminogen depletion or plasmin inhibition. In contrast, when cells were seeded into plasma clots, then, although the rates of cells spreading were unaffected, cell migration was abolished by plasminogen depletion or by plasmin inhibition. When cells were seeded onto the surface of plasma clots and the rate of migration into the clots was measured, there was an absolute requirement for plasmin activity; while fibroblasts migrated rapidly into the fibrin lattice of control clots, in the case of plasminogen-depleted clots, cells failed to penetrate the lattice. Focussing through a plasma clot revealed that fibroblasts do not migrate through the fibrin lattice but instead, localized areas of fibrinolysis are generated and cells migrate over the surface of the area of lysis.     

Kinetic studies on the effect of heparin and fibrin on plasminogen activators.

1. Possible interactions between fibrin(ogen) and heparin in the control of plasminogen activation were studied in model systems using the thrombolytic agents tissue-type plasminogen activator (t-PA), urokinase and streptokinase.plasminogen activator complex and the substrates Glu- and Lys-plasminogen. 2. Both t-PA and urokinase activities were promoted by heparin and by pentosan polysulphate, but not by chondroitin sulphate or hyaluronic acid. The effect was on Km. 3. In the presence of soluble fibrin (and its mimic, CNBr-digested fibrinogen) the effect of heparin on t-PA was attenuated, although not abolished. In studies using a monoclonal antibody and 6-aminohexanoic acid, it was found that heparin and fibrin did not seem to share a binding site on t-PA. 4. The activity of t-PA B-chain was unaffected by heparin, so the binding site is located on the A-chain of t-PA (and urokinase). 5. Fibrin potentiated the activity of heparin on urokinase. The activity of streptokinase.plasminogen was unaffected by heparin whether or not fibrin was present. 6. If these influences of heparin and fibrin also occur in vivo, then, in the presence of heparin, the relative fibrin enhancement of t-PA will be diminished and the likelihood of systemic activation by t-PA is increased.     

Characterization of plasmin-mediated activation of plasma procarboxypeptidase B. Modulation by glycosaminoglycans

Plasma carboxypeptidase B (PCB) is an exopeptidase that exerts an antifibrinolytic effect by releasing C-terminal Lys and Arg residues from partially degraded fibrin. PCB is produced in plasma via limited proteolysis of the zymogen, pro-PCB. In this report, we show that the K(m) (55 nM) for plasmin-catalyzed activation of pro-PCB is similar to the plasma concentration of pro-PCB (50-70 nM), whereas the K(m) for the thrombin- or thrombin:thrombomodulin-catalyzed reaction is 10-40-fold higher than the pro-PCB level in plasma. Additionally, tissue-type plasminogen activator triggers activation of pro-PCB in blood plasma in a reaction that is stimulated by a neutralizing antibody versus alpha(2)-antiplasmin. Together, these results show that plasmin-mediated activation of pro-PCB can occur in blood plasma. Heparin (UH) and other anionic glycosaminoglycans stimulate pro-PCB activation by plasmin but not by thrombin or thrombin:thrombomodulin. Pro-PCB is a more favorable substrate for plasmin in the presence of UH (16-fold increase in k(cat)/K(m)). UH also stabilizes PCB against spontaneous inactivation. The presence of UH in clots prepared with prothrombin-deficient plasma delays tissue-type plasminogen activator-triggered lysis; this effect of UH on clot lysis is blocked by a PCB inhibitor from potato tubers. These results show that UH accelerates plasmin-catalyzed activation of pro-PCB in plasma and PCB, in turn, stabilizes fibrin against fibrinolysis. We propose that glycosaminoglycans in the subendothelial extracellular matrix serve to augment the levels of PCB activity thereby stabilizing blood clots at sites where there is a breach in the integrity of the vasculature.     

Binding of synthetic B knobs to fibrinogen changes the character of fibrin and inhibits its ability to activate tissue plasminogen activator and its destruction by plasmin

Synthetic peptides corresponding to the amino-terminal sequence of the beta chain of fibrin increase the turbidity of fibrin clots, whether they are generated by the direct interaction of thrombin and fibrinogen or by the reassociation of fibrin monomers. The turbidity of batroxobin-induced clots, which are characteristically "fine," is increased even more dramatically. Pentapeptides are more effective than tetrapeptides. Surprisingly, the same peptides also delay fibrinolysis, whether activated by exogenously added plasmin or from the fibrin-enhanced stimulation of tissue plasminogen activator (tPA) activation of plasminogen. The peptides have only a very slight effect on the plasmic hydrolysis of a chromogenic peptide, either by the direct addition of plasmin or by plasmin generated from plasminogen by tPA. The synthetic peptides mimicking the B knobs appear to exert their action in two ways. First, they render fibrin less vulnerable to attack by plasmin. Second, they delay the fibrin activation of tPA. The latter is attributed to their ability to prevent the binding of the authentic B knob, which itself is located at the end of a flexible 50-residue tether and which needs time to find its elusive "hole". We propose that, when after a while the tethered knob does become inserted, it locks the betaC domain in a conformation that allows access to tPA-plasminogen-binding sites, whereas the untethered synthetic knobs restrict the fibrin to a conformation in which those sites remain inaccessible. Thus, although the interaction involving the A knob and gammaC hole is the basis for the polymerization of fibrin, the comparable but delayed interaction involving the B knob and the betaC hole is ultimately directed at preparing the clot for its eventual destruction.     

Fibrinolytic and thrombolytic properties of thiol-dependent serine proteinase from Thermoactinomyces vulgaris in vitro

Fibrinolytic and thrombolytic properties of the subtilisin-like thiol-dependent serine proteinase were studied. At concentrations from 50 to 4000 micrograms/ml the enzyme causes lysis of fibrin plates and activates plasminogen. At concentrations above 100 micrograms/ml it shows a pronounced thrombolytic effect on the clots formed in vitro from both plasma and human and rat blood. Plasma inhibitors partly inactivate the thiol-dependent serine proteinase. The enzyme hydrolyses also fibrinogen, thrombin, plasmin and plasminogen.     

Functional effects of asparagine-linked oligosaccharide on natural and variant human tissue-type plasminogen activator

The role of Asn-linked oligosaccharide in the functional properties of both human tissue-type plasminogen activator (t-PA) and a genetic variant of t-PA was studied. Nonglycosylated and glycosylated wild-type t-PA were produced in mammalian cells which express recombinant t-PA. These proteins were compared in fibrin binding and 125I-labeled fibrin clot lysis assays, using purified components. The nonglycosylated form showed higher fibrin binding, as well as higher fibrinolytic potency than the glycosylated form. Subsequently, prevention of glycosylation of a t-PA variant which lacked the finger and epidermal growth factor domains (delta FE), was carried out in an attempt to enhance its fibrinolytic activity. Glycosylation was prevented by changing Asn to Gln; at Asn-117 to produce delta FE1X t-PA, and at Asn-117, -184, and -448 to produce delta FE3X t-PA. All variants were similar to wild-type t-PA in their catalytic dependence on fibrinogen fragments, fibrinolytic activity in fibrin autography analysis, and plasminogen activator activity. In a clot lysis assay, using citrated human plasma, the fibrinolytic potency of the variants were comparable to that of wild-type t-PA at activator concentrations of 17-51 nM (approximately 1-3 micrograms/ml). At 0.5-5.1 nM (approximately 0.03-0.3 micrograms/ml), however, the variant proteins had lower fibrinolytic potency than wild-type t-PA. Fifty percent lysis in 1.5 h for wild-type, delta FE, delta FE1X, and delta FE3X t-PA, required 2.5, 10, 7.5, and 5.5 nM t-PA, respectively. The fibrinogenolytic activity in human plasma was measured for wild-type, delta FE, delta FE1X, and delta FE3X t-PA, and showed significant fibrinogen depletion after 3 h of incubation at 51 nM, decreasing to 11, 11, 50, and 72% of basal levels, respectively. These data indicate that partial or total nonglycosylated t-PA variants have a higher fibrinolytic versus fibrinogenolytic ratio than their fully glycosylated counterparts.     

The potential improvement of thrombolytic therapy by targeting with bispecific monoclonal antibodies: Why they are used and how they are made

The generation of the proteolytic enzyme plasmin from its inactive precursor plasminogen, mediated by so called plasminogen activators, is the essential step in thrombolytic therapy. Plasmin is responsible for the degradation of the insoluble fibrin, the major component of a thrombus, to soluble fibrin degradation products. So far, the use of the more recently developed thrombolytic agents single-chain urokinase-type plasminogen activator (scu-PA) and tissue-type plasminogen activator (t-PA) were disappointing, mainly due to some of their negative propertiesin vivo, i.e., rapid inhibition and/or hepatic clearance. Besides some background information on the haemostatic balance; t-PA and scu-PA structure; and mechanisms of action, we here review some reported attempts to improve on these agents for thrombolytic therapy following various strategies. One of the more potential strategies, antibody-targeted thrombolytic therapy using bispecific monoclonal antibodies, is discussed somewhat more extensively, as are the several procedures that can befollowed for bispecific antibody preparation.