Biological and thrombolytic properties of proenzyme and active forms of human urokinase--IV. Variability in fibrinolytic response of plasma of several mammalian species

The fibrinolytic and fibrinogenolytic properties of recombinant pro-urokinase (Rec-pro-UK) and recombinant urokinase (Rec-UK) were compared with those of natural urokinase (Nat-UK) and of tissue-type plasminogen activator (t-PA) in an in vitro system consisting of 125I-labeled autologous plasma clots immersed in plasma of humans, five primate species, dogs, rabbits and pigs. With each of the four plasminogen activators, a dose-dependent clot lysis was observed, the degree of which differed, however, very markedly from one species to the other. At a concentration of 100 IU/ml of urokinase extensive plasma clot lysis was obtained in plasma of man, Macaca mulatta, Macaca fascicularis and Macaca radiata, while the plasma clots of Papio cynocephalus, Papio anubis and rabbit, dog and pig were much more resistant to lysis. No significant differences in the extent of lysis were observed between Rec-pro-UK and Rec-UK nor between Rec-UK and Nat-UK. Comparable degrees of lysis were obtained with t-PA at 3- to 5-fold lower concentrations. Lysis with Rec-UK or Nat-UK was always associated with extensive activation of the fibrinolytic system in plasma, evidenced by fibrinogen breakdown and plasminogen activation and alpha 2-antiplasmin consumption. With t-PA, extensive clot lysis was obtained in the absence of fibrinolytic activation in the plasma. With Rec-pro-UK the response was intermediate; at high concentrations (200 IU/ml) extensive lysis in the reactive species was associated with fibrinogen consumption, while at intermediate concentrations (50-100 IU/ml) significant clot lysis was obtained in the reactive species in the absence of marked activation of the fibrinolytic system in the plasma.     

Absence of synergism between tissue-type plasminogen activator (t-PA), single-chain urokinase-type plasminogen activator (scu-PA) and urokinase on clot lysis in a plasma milieu in vitro

A potential synergic effect of tissue-type plasminogen activator (t-PA), single-chain urokinase-type plasminogen activator (scu-PA) or urokinase on clot lysis was investigated in a whole human plasma system in vitro. The system consisted of a human plasma clot labeled with 125I-fibrinogen, immersed in citrated whole human plasma, to which the thrombolytic agents were added. Clot lysis was quantitated by measurement of released 125I, and activation of the fibrinolytic system in the surrounding plasma by measurements of fibrinogen and alpha 2-antiplasmin. t-PA, scu-PA and urokinase induced a dose-dependent and time-dependent clot lysis; 50 percent lysis after 2 h was obtained with 5 nM t-PA, 20 nM scu-PA and 12 nM urokinase. At these concentrations no significant activation of the fibrinolytic system in the plasma was observed with t-PA and scu-PA, whereas urokinase caused significant alpha 2-antiplasmin consumption and concomitant fibrinogen degradation. The shape of the dose-response curves was different; t-PA and urokinase showed a log linear dose-response whereas that of scu-PA was sigmoidal. Combinations of t-PA and scu-PA, of t-PA and urokinase or of scu-PA and urokinase at thrombolytic doses of each showed no synergism for thrombolysis. Fifty percent clot lysis in 2 h was obtained at total concentrations of the combined agents of 5 to 15 nM with molar ratios ranging from 1:4 to 4:1.(ABSTRACT TRUNCATED AT 250 WORDS)     

Euglobulin clot lysis induced by tissue-type plasminogen activator is reduced in subjects with increased levels of lipoprotein (a).

Several reports have evaluated the in vitro effect of lipoprotein(a) [Lp(a)] levels on the fibrinolytic system, suggesting that high Lp(a) levels may inhibit fibrinolysis by competing for plasminogen binding in different systems. We have studied plasminogen activation induced by tissue-type plasminogen activator (t-PA), as well as other fibrinolytic parameters, in 25 subjects with Lp(a) levels greater than 30 mg/dl and the results were compared with those found in 23 subjects with Lp(a) less than 30 mg/dl. Both groups were similar in age, sex distribution, living habits and lipid pattern. Plasminogen activation, when measured by t-PA-induced euglobulin clot lysis, was significantly decreased in the group with elevated Lp(a) levels (lysis time, 16.7 +/- 3.3 min) compared with the group with low Lp(a) levels (11.8 +/- 2.0 min), although 8 of the 25 subjects with high Lp(a) levels showed plasminogen activation within the range of the control group. A positive significant correlation between Lp(a) levels and t-PA-induced euglobulin clot lysis time was found. No statistical differences were demonstrated between groups for the other fibrinolytic parameters studied. Addition of purified Lp(a) to the euglobulin fraction or to plasma resulted in a decrease in euglobulin clot lysis. The present study shows that t-PA induced plasminogen activation is decreased in individuals with high circulating levels of Lp(a) supporting the hypothesis that Lp(a) may interfere with the physiological functions of plasminogen.     

Influence of heparin and a low molecular weight heparinoid on specific endogenous and exogenous fibrinolytic factors during rest and exercise.

The effects of heparin (5,000 IU i.v.) and the low molecular weight heparinoid Org 10172 (Orgaran) (3,250 anti-Xa units i.v.) on components of the fibrinolytic system were studied in two double-blind, randomised, placebo-controlled, cross-over trials using healthy subjects. In study A (n = 6) the effects were studied during rest and standardized exercise and in study B (n = 6) during a low dose infusion of recombinant tissue-type plasminogen activator (rt-PA; 80 micrograms over 16 min). At rest, heparin and Org 10172 did not influence the plasma concentrations of endogenous t-PA antigen and activity, urokinase-type PA (u-PA) antigen, plasmin activatable pro-urokinase (scu-PA), active urokinase (tcu-PA) and plasminogen activator inhibitor-1 (PAI-1) antigen. Recombinant t-PA antigen and activity during rt-PA infusion were also not affected. During exercise, neither heparin nor Org 10172 influenced the area under the curve (AUC) of t-PA and u-PA antigen and t-PA activity when compared with placebo. Unexpectedly, after heparin the AUC of t-PA activity was 49% larger (range +19 to +245%) than after Org 10172 (p < 0.05). The last difference was considered spurious, scu-PA, tcu-PA and PAI-1 antigen levels at 2 min after termination of exercise were unaffected by both compounds (p > 0.05). Sulphated polysaccharides do not increase fibrinolytic activity of the plasma by changing the concentrations of the components of the fibrinolytic system.     

Factor XIIa is a kinetically favorable plasminogen activator

Initiation of the plasma contact system has been shown to play a significant role in the fibrinolysis, activating both pro-urokinase and plasminogen. The aim of the present study was to further evaluate the functional role of the factor XIIa catalyzed activation of plasminogen. Activation of plasminogen by factor XIIa followed the Michaelis-Menten rate equation. In a continuous assay system the Km was 0.27 microM; the kcat 0.078 min(-1) and the kcat/Km 0.31x10(6) M(-1) x min(-1). In an end-point assay system the Km was 0.58 microM; the kcat 0.096 min(-1) and the kcat/Km 0.16x10(6) M(-1) x min(-1). The discrepancy between the kcat in the two assays is not significant. Theoretically the higher Km in the end-point assay system may be due to the presence or generation of an unidentified competitive inhibitor in this assay system. Comparing the catalytic constants of factor XIIa with those of urokinase activation of plasminogen, the specificity constant, kcat/Km, of factor XIIa activation of plasminogen was 20-fold lower. However, taking the low physiological concentration of urokinase into account, the efficiency of activated factor XII is equivalent to that of urokinase. When monitoring factor XIIa activation of plasminogen in a clot lysis assay, the clot lysis time was 2- to 4-fold as long as that accommodated by urokinase at factor XIIa concentrations equivalent with 5-20% of the zymogen concentration in plasma. The factor XIIa mediated clot lysis was prevented completely by the presence of a polyclonal antibody to factor XII.     

Influence of exogenous and endogenous tissue-type plasminogen activator on the lysability of clots in a plasma milieu in vitro

The fibrinolytic potential of tissue-type plasminogen activator (t-PA) either incorporated in a clot (endogenous) or added to the surrounding plasma (exogenous), was studied in an in vitro system consisting of 125I-labeled human plasma clots (200 microliters) immersed in human plasma (2 ml). Clot lysis was measured as a function of endogenous t-PA concentration (in the absence of added exogenous t-PA), as a function of exogenous t-PA concentration (without added endogenous t-PA) and as a function of the same concentration of both endogenous and exogenous t-PA. Equivalent clot lysis was obtained with a 2 to 4 times lower concentration of endogenous t-PA as compared to exogenous t-PA, corresponding to a 20 to 40 times smaller total amount of endogenous versus exogenous t-PA. Fifty percent lysis in 5 hrs was obtained with about 5 IU/ml of endogenous t-PA or with 10 IU/ml of exogenous t-PA. The presence of both exogenous (10 IU/ml) and endogenous (5 IU/ml) t-PA resulted in 50 percent lysis in 1.5 hrs, indicating that t-PA incorporated in a thrombus contributes significantly to its lysis by exogenous t-PA. Similar results were obtained with plasma obtained after 10 min of venous occlusion in seven healthy subjects. Spontaneous clot lysis within 5 hrs was only observed with post-occlusion clots in pre- or post- occlusion plasma in two subjects in whom the t-PA level rose to 10-15 IU t-PA/ml. In the five other subjects with post-occlusion t-PA levels below 2 IU/ml, no clot lysis was observed within 24 hrs. The influence of the fast-acting inhibitor of t-PA on clot lysability by endogenous or exogenous t-PA was investigated by immersing clots prepared from normal or inhibitor-rich plasma (endogenous inhibitor) in normal or inhibitor-rich plasma (exogenous inhibitor). Exogenous t-PA inhibitor efficiently neutralizes clot lysis by both exogenous and endogenous t-PA. Endogenous t-PA inhibitor, however, efficiently neutralizes endogenous t-PA but has little influence on clot lysis by exogenous t-PA. These findings indicate that t-PA inhibitor is not concentrated into a clot and that t-PA inhibitor in plasma efficiently neutralizes t-PA incorporated in a clot. alpha 2-Antiplasmin depleted plasma clots were more susceptible to lysis by both endogenous and exogenous t-PA than normal clots.(ABSTRACT TRUNCATED AT 400 WORDS)     

Thrombin activatable fibrinolysis inhibitor (TAFI) does not inhibit in vitro thrombolysis by pharmacological concentrations of t-PA

TAFI (thrombin activatable fibrinolysis inhibitor) is a plasma procarboxypeptidase that upon activation inhibits the fibrinolytic process by removing the C-terminal lysines from partially degraded fibrin. The generation of activated TAFI (TAFIa) has been suggested to represent a mechanism of thrombus resistance to thrombolytic therapy. However, the ability of TAFI to inhibit fibrinolysis by pharmacological concentrations of t-PA has not been properly investigated. We used an in vitro model consisting of 125I-fibrin blood clots submerged in autologous defibrinated plasma. Upon addition of t-PA (125-5,000 ng/ml) and CaCl2 (25 mM), samples were incubated at 37 degrees C, and clot lysis was measured at intervals from the radioactivity released into solution. The role of TAFI was assessed either by neutralizing the generated TAFIa with the specific inhibitor PTI (50 microg/ml) or by enhancing TAFI activation through the addition of recombinant soluble thrombomodulin (solulin, 1 microg/ml). In our clot lysis model, activation of TAFI amounted to about 20% of inducible carboxypeptidase activity. Addition of PTI, however, produced a significant increase in the extent of lysis only at concentrations of t-PA equal to or lower than 250 ng/ml. When solulin was added to the plasma surrounding the clot, about 70% of TAFI was activated within 15 min. Under these conditions, inhibition of clot lysis was very marked in samples containing 125 or 250 ng/ml of t-PA, but negligible in those containing pharmacological concentrations of the activator (1,000 and 5,000 ng/ml). Additional experiments suggest that loss of fibrin-dependence by elevated concentrations of t-PA may be one of the mechanisms explaining the lack of effect of TAFIa. Our data indicate that, under our experimental conditions, clot lysis by pharmacological concentrations of t-PA is not influenced by TAFIa even after maximal activation of this procarboxy-peptidase.     

An inhibitor of activated thrombin-activatable fibrinolysis inhibitor potentiates tissue-type plasminogen activator-induced thrombolysis in a rabbit jugular vein thrombolysis model

When activated in vitro, thrombin-activatable fibrinolysis inhibitor (TAFI) slows clot lysis by cleaving the C-terminal lysine and arginine residues from partially degraded fibrin. An inhibitor of carboxypeptidase isolated from potato (CPI) reverses prolongation of clot lysis by inhibiting activated TAFI. We investigated in vivo effect of TAFI inhibition on tissue-type plasminogen activator (t-PA)-induced clot lysis using CPI in a rabbit jugular vein thrombolysis model. It was found necessary to further purify the CPI preparations from commercial sources by HPLC chromatography to remove endotoxin and anti-plasmin activity that would affect the endogenous fibrinolytic system. The effect of intravenous administration of the purified CPI with t-PA was determined by measuring thrombus weight at the end of 90 minutes in six groups of animals. In the control group receiving saline, the median thrombus weight was 116 mg. In the group that received CPI only (0.5 mg/kg bolus injection followed by 0.3 mg/kg/h infusion), the median thrombus weight was 121 mg. In the group that received t-PA at a dose of 10 microg/kg bolus followed by 67 microg/kg/h infusion, the median thrombus weight decreased to 86 mg. When CPI was coadministered with the same regimen of t-PA, the median value further decreased to 58 mg. When animals were given three times higher the dose of t-PA (30 microg/kg bolus followed by 200 microg/kg/h infusion) in the absence or presence of CPI, median thrombus weights were 56 mg and 0 mg, respectively. Our results demonstrate that systemic coadministration of the purified CPI improves clot lysis induced by t-PA.     

Plasma fibronectin enhances fibrinolytic system in vitro

The effects of plasma fibronectin on the fibrinolytic system were studied in vitro. Fibronectin caused a time and concentration-dependent increase (up to 99% with 330 micrograms/ml) in the amidolytic activity of tissue plasminogen activator (TPA) but not of urokinase. In the presence of fibronectin the Km of the amidolytic activity of TPA decreased without a change in Vmax. It also caused a concentration-dependent increase in lys-plasminogen activation by TPA (up to 825% with 375 micrograms/ml) and by urokinase (up to 400% with 250 micrograms/ml), as well as in the amidolytic activity of plasmin (up to 55% with 300 micrograms/ml). Fibronectin did not enhance the activation of glu-plasminogen. In the presence of fibronectin the Km of lys-plasminogen activation decreased without a change in Vmax. In purified systems fibronectin significantly shortened the clot lysis time (CLT) by up to 28% and 30% in TPA- and plasmin-activated lysis, respectively. The presence of Ca2+ did not change fibronectin's effect on CLT. Clots of non-fibronectin-depleted plasma were lysed up to about twice as fast as the clots of fibronectin-depleted plasma. In conclusion, physiologic concentrations of fibronectin enhanced the fibrinolytic system in vitro. Further studies will be required to elucidate the mechanisms involved and to document whether fibronectin has a similar effect in vivo.     

In vitro studies on the fibrinolytic, thrombolytic and fibrinogenolytic properties of a tissue plasminogen activator from guinea pig keratocytes

The fibrinolytic and thrombolytic properties of a tissue plasminogen activator (tPA) purified from the conditioned medium of an established guinea pig keratocyte (GPK) cell line were investigated in in vitro systems and compared with urokinase. Using the fibrin clot lysis assay, GPK activator appears to be similar to human melanoma tPA and not to human urokinase. GPK activator also caused negligible fibrinogen breakdown, when incubated with human plasma at 37 degrees C over 23 hr. Urokinase on the other hand caused significant fibrinogenolysis, under similar conditions. Comparison of the lysis of plasma clots by GPK activator and human urokinase have shown that GPK activator was a much more effective fibrinolytic agent than urokinase, especially at lower concentrations (less than 50 IU/ml). Studies on the thrombolytic effect of GPK activator on the lysis of aged and cross-linked whole human blood clots and plasma clots hanging in artificially circulating human plasma suggest that GPK activator can lyse both these types of clots equally well. The lysis is dose dependent, attaining complete lysis within 3-6 hr with the concentration of GPK activator in the range of 1-5 micrograms/ml plasma. It is concluded that GPK activator has a higher fibrinolytic and thrombolytic activity and lower fibrinogenolytic activity than urokinase.     

Stimulation of the plasma fibrinolytic activity in rats by the prostacyclin analogue CG 4203

In anesthetized rats the intravenous infusion (15-120 min) of the prostacyclin analogue CG 4203 (0.215-2.15 micrograms.kg-1.min-1) resulted in a time and dose dependent shortening of the ex vivo euglobulin clot lysis time (ECLT). This effect that appeared to be significant already in the non-hypotensive dose range of CG 4203, was still existing at 2 hours after cessation of the infusion. The phosphodiesterase inhibitor theophylline (4.64 mg.kg-1 i.v.) potentiated the ECLT shortening effect of CG 4203. Even the highest dose of CG 4203 did not change the plasma fibrinogen levels. In contrast to low molecular weight urokinase (100 PU/ml) CG 4203 (10 microM) did not shorten the in vitro lysis of preformed euglobulin clots from untreated rats nor did it reduce the 125J-fibrin content of human thrombi in the Chandler loop system. From these results it is concluded that intravenously infused CG 4203 increases the plasma fibrinolytic activity in rats by a c-AMP dependent mechanism, probably by release of plasminogen activator. Direct urokinase like activation of plasminogen does not occur with CG 4203. The relevance of this activity is discussed with respect to the CG 4203 treatment of occlusive vascular diseases.     

An experimental study of local fibrinolysis using tissue plasminogen activator and urokinase in a canine common carotid artery thrombus model

Tissue-type plasminogen activator (t-PA) is thought to be a promising fibrinolytic agent because of its high affinity to fibrin without evidence of significant systemic fibrinolysis. The feasibility of t-PA and urokinase (UK) in local fibrinolytic therapy was investigated in a canine common carotid artery thrombus model. After the screening of coagulation-fibrinolytic activities, autologous blood clot was injected into the segment of intimal injured common carotid artery. The fibrinolytic agent was locally applied from the origin of the common carotid artery under temporary flow arrest with a double lumen balloon catheter. T-PA used in this study was produced by the cell culture technique of normal human cells. Its activity was-expressed by AK units (AKU), namely, the fibrinolytic area of the fibrin-agar plate induced by 10 AKU/ml of t-PA solution corresponds to that of 10 IU/ml of UK solution. The doses of t-PA required to produce angiographical recanalization were 600-1,200 AKU/kg (approximately 0.015-0.03 mg/kg) of t-PA, while 24,000 IU/kg was necessary for UK. In these doses, t-PA evoked no adverse effects on the plasma coagulation-fibrinolytic system, while UK produced significant decrease in plasma fibrinogen and alpha-2 plasmin inhibitor levels. Thus, t-PA may be considered to have higher fibrinolytic ability and lower adverse effect on the plasma coagulation-fibrinolytic system than UK. Local fibrinolytic therapy for acute cerebral infarction using t-PA is considered to be a promising intravascular therapeutic procedure with less systemic fibrinolytic complications such as hemorrhagic infarction.     

Comparative analysis of fibrinolytic properties of Alteplase,Tenecteplase and Urokinase in an in vitro clot model of intracerebral haemorrhage

ObjectiveHematoma lysis with recombinant tissue plasminogen activator (rtPA) has emerged as an alternative therapy for spontaneous intracerebral and intraventricular haemorrhage (ICH and IVH). However, the MISTIE III and CLEAR III trial failed to show significant improvement of favourable outcomes. Besides experimental and clinical trials revealed neurotoxic effects of rtPA. The demand for optimization of fibrinolytic therapy persists. Herein, we used our recently devised clot model of ICH to systematically analyse fibrinolytic properties of rtPA, tenecteplase and urokinase.MethodsIn vitro clots of human blood (size: 25 ml and 50 ml; age: 1.5 tenecteplase, 24 tenecteplase and 48 tenecteplase) were produced and equipped with a catheter into the clot core for drug delivery and drainage. Various doses of tenecteplase and urokinase with different treatment periods were examined (overall 117 clots), assessing the optimal dose and treatment time of these fibrinolytics. Clots were weighed before and at the end of treatment. These results were compared with clots treated with 1 mg rtPA or with 0.9% sodium chloride solution.ResultsThe optimal treatment scheme of tenecteplase was found to be 100 IU with an incubation time of 30 min, for urokinase it was 50 000 IU with an incubation time of 20 min. The relative clot end weight of tenecteplase and urokinase (31.3±11.9%, 34.8 ±7.7%) was comparable to rtPA (36.7±10.7%). Larger clots were more effectively treated with tenecteplase compared to the control group (P=0.0013). urokinase and tenecteplase had similar lysis rates in aged clots and 90 min clots. One and two repetitive treatments with tenecteplase were as effective as two and three cycles of urokinase.ConclusionsIn our in vitro clot model we could determine optimal treatment regimens of tenecteplase (100 IU, 30 min) and urokinase (50 000 IU, 20 min). Urokinase and tenecteplase were comparable in their fibrinolytic potential compared to 1mg rtPA in small clots and showed an effective lysis in aged clots. tenecteplase was more effective in larger clots.     

Standard and low molecular weight heparin have no effect on tissue plasminogen activator induced plasma clot lysis or fibrinogenolysis.

Although heparin is often given as an adjunct to tissue plasminogen activator (t-PA), the effect of heparin on t-PA induced fibrin(ogen)olysis is controversial. To address this controversy, we examined the effects of standard and low molecular weight heparin (enoxaparine) on both t-PA induced clot lysis and t-PA mediated fibrinogenolysis in a human plasma system. Accordingly, 125I-labeled fibrin clots were incubated in t-PA containing citrated plasma in the presence or absence of these glycosaminoglycans, and the extent of thrombolysis was determined by measuring residual radioactivity of the clots, while B beta 1-42 levels were used as a specific index of fibrinogenolysis. Over a wide range of t-PA concentrations (0.1 to 1.6 micrograms/ml), neither heparin nor enoxaparine influences either t-PA induced clot lysis or t-PA mediated B beta 1-42 generation. These findings suggest that either agent could be used as an adjunct to t-PA without compromising either the thrombolytic potential of t-PA or its clot-selectivity.     

IMPAIRED CLOT LYSIS BY rt-PA CATALYZED MINI-PLASMINOGEN ACTIVATION

The fibrinolytic system contains a proenzyme plasminogen (Plg) which is converted to plasmin (Plm) by the action of Plg activators. Physiological Plg activators are: tissue-type plasminogen activator (t-PA) and urokinase-type plasminogen activator. Plg was shown to be further cleaved by leukocyte elastase producing several fragments, one of wich is called mini-plasminogen (mini-Plg) or neo-plasminogen Val₄₄₂. In this paper we studied whether mini-Plg is able to produce clot lysis when it is activated by rt-PA in purified systems and in Plg depleted normal plasma. We found that mini-Plg clot lysis time was longer than that of Plg. Clot lysis times were 2.3 minutes ± 0.06 for Plg and 9.8 minutes ± 0.1 for mini-Plg. Mini-Plg is less efficient than Plg in producing clot lysis at all studied concentrations (0.1–1.2μM). In Plg depleted normal human plasma mini-Plg is unable to produce complete clot lysis in presence of rt-PA. Although mini-Plg can be activated to mini-Plm by rt-PA, these results show that the activation process is insufficient to produce an efficient clot lysis. © 1997 Elsevier Science Ltd     

Biological and thrombolytic properties of proenzyme and active forms of human urokinase--III. Thrombolytic properties of natural and recombinant urokinase in rabbits with experimental jugular vein thrombosis

The thrombolytic properties of recombinant pro-urokinase (Rec-pro-UK), recombinant active urokinase (Rec-UK) and natural urinary urokinase (Nat-UK) were compared with those of tissue-type plasminogen activator (t-PA) in rabbits with a radiolabeled thrombus in the jugular vein. The thrombolytic agents were infused intravenously over a time period of 4 hr and the extent of thrombolysis measured two hours later. In control animals the extent of thrombolysis was 11 +/- 2% (n = 8) after 6 hr. Nat-UK and Rec-UK had very similar thrombolytic properties. Significant thrombolysis was only obtained with infusion of 240,000 IU per kg (41 +/- 2%, n = 4 for Nat-UK and 37 +/- 4%, n = 4 for Rec-UK) and this was associated with a marked systemic activation of the fibrinolytic system, as evidenced by consumption of plasminogen and alpha 2-antiplasmin and fibrinogen breakdown. Infusion of Rec-pro-UK induced thrombolysis at a dose of 60,000 IU per kg (44 +/- 8%, n = 3) but without associated systemic activation of the fibrinolytic system. In this respect the properties of Rec-pro-UK were similar to those of t-PA, which, however, had a 2- to 4-fold higher specific thrombolytic activity (30,000 IU/kg yielding 48 +/- 1% lysis, n = 4). It is concluded that Rec-UK has very similar thrombolytic properties as Nat-UK and that Rec-pro-UK has a better thrombus-selectivity and less systemic side effects than the active enzymes.     

Detection of both type 1 and type 2 plasminogen activator inhibitors in human monocytes

Increasing evidence suggests the involvement of leukocytes in the fibrinolytic system. Monocytes secrete pro-urokinase (Grau, Thromb Res 1989; 53: 145) and it has been shown that these cells have specific receptors for urokinase and plasminogen (Miles, Thromb Haemostas 1987; 58: 936). The aim of this study was to analyse the presence of plasminogen activator inhibitor(s) in platelet-free suspensions of human peripheral blood monocytes and polymorphonuclear leukocytes (PMN). SDS-PAGE and reverse fibrin autography showed an inhibitory band of 50 kDa in the monocyte extracts (Triton X-100) but not in the PMN extracts. Urokinase (u-PA) was mixed with increasing amounts of monocyte extract for 10 min and the mixtures were added to 125I-fibrin coated wells containing plasminogen. A dose-dependent decrease in the u-PA fibrinolytic activity was observed. The amount of inhibition increased when the monocyte releasates were preincubated with u-PA (40% inhibition after 5 min preincubation and 80% after 15 min), indicating a direct interaction between this activator and an inhibitor(s). After SDS-PAGE of monocyte extracts, immunoblotting and peroxidase staining identified both PAI1 and PAI2, with an apparent molecular weight of 47-50 kDa. Monocyte-associated PAI1 formed complexes with single chain t-PA with a molecular mass 50 kDa higher than the molecular mass of the free PAI1. However, a significant amount of PAI1 remained unbound to t-PA. This inactive PAI1 could have come from a rapid inactivation of the primary active PAI1. These PAI1 and PAI2 detected in human monocytes may be transcendent in the regulation of the fibrinolytic system.     

Differences in the activation rates of plasminogen by tissue plasminogen activator and urokinase

The activation of a native form of plasminogen (Glu-plg) by tissue plasminogen activator(t-PA) was enhanced when the plasma was clotted by the addition of thrombin or thrombin plus Ca++. Cross-linking of fibrin in the clotted plasma did not inhibit the fibrin-associated enhancement of the activation of plasminogen by t-PA. When fibrinolysis induced by t-PA in the clotted plasma was measured using enzyme immunoassay, lysis of non cross-linked fibrin in the clotted plasma was faster than lysis of cross-linked fibrin, however such decrease in the extent of fibrinolysis was observed in cross-linked fibrin even in the absence of alpha 2antiplasmin (alpha 2AP) in a purified system. When Glu- or Lys-plg (modified plg) was activated by t-PA, the presence of fibrin enhanced significantly the extent of activation of both Glu- and Lys-plg, but the activation of Glu-plg by urokinase (UK) was enhanced in the presence of fibrin. The activation of Lys-plg by UK was rather inhibited in the presence of fibrin.     

Effects of tranexamic acid, CIS-AMCHA, and 6-aminohexanoic acid on the activation rate of plasminogen by urokinase in the presence of clot

When human plasma was mixed with 50 units of urokinase and clotted with thrombin in the presence of S-2251, the hydrolysis of S-2251 in the clot was higher than that in the plasma. The presence of 10 μM of tranexamic acid resulted in decrease in the activation rate of plasminogen in the clot but not in the plasma. Further increase in its concentration resulted in marked increase in plasminogen activation in both clot and plasma. The addition of 6-aminohexanoic acid or cis-AMCHA showed changes in the rate of plasminogen activation similar to that shown in the presence of tranexamic acid. Fifty μM of tranexamic acid totally inhibited urokinase induced clot lysis, while 1 mM of cis-AMCHA and 6-aminohexanoic acid totally inhibited clot lysis. The presence of 1 mM of these ω-aminoacids remarkably increased the activation of plasminogen by urokinase, but no clot lysis was observed.     

Tissue plasminogen activator in human megakaryocytes and platelets: immunocytochemical localization, immunoblotting and zymographic analysis

Two approaches were used to identify and characterize the presence of tissue plasminogen activator (t-PA) in megakaryocytes and platelets. We investigated the fibrinolytic activity of human megakaryocytes (MK) and platelets. The presence of t-PA antigen in megakaryocytes and platelets was demonstrated using immunocytochemical techniques and polyclonal or monoclonal antibodies specific for t-PA. When cells were applied to fibrin plates, lysis zones developed around isolated human megakaryocytes, whereas no fibrinolytic activity appeared when either intact washed platelets or platelet lysate were deposited. After SDS-PAGE of platelet and MK extracts (Triton X-100) immunoblotting and peroxidase staining identified t-PA antigen in several bands. Zymographic analysis of SDS-PAGE carried out on fibrin film overlays identified one or two zones corresponding to free or complexed t-PA. These results indicate that t-PA is present in platelets as well as in the precursor cells, however, in platelets, t-PA may not be immediately available for plasminogen activation and fibrin degradation. From our findings and from previous work of others, it appears that platelets may either activate or inhibit the fibrinolytic system. Therefore the conditions of plasminogen activation by platelet t-PA and plasmin inhibition by platelet alpha 2-antiplasmin or other inhibitors have to be precised before the role of platelets in clot dissolution is understood. The physiological role of platelets in fibrinolysis and clot dissolution remains unclear. In 1953, the antifibrinolytic activity of blood platelets was demonstrated and in the early 1960's a fibrinolytic activity, increasing with platelet concentration in the experimental system, was shown.(ABSTRACT TRUNCATED AT 250 WORDS)