Characterization of an antibody-urokinase conjugate. A plasminogen activator targeted to fibrin

Engineering of plasminogen activators for targeting to thrombus and heightening thrombolytic efficacy

Thrombotic occlusion of the coronary artery, which triggers acute myocardial infarction, is one of the major causes of death in the USA. Currently, arterial occlusions are treated with intravenous plasminogen activators (PAs), which dissolve the clot by activating plasminogen. However, PAs indiscriminately generate plasmin, which depletes critical clotting factors (fibrinogen, factor V, and factor VIII), precipitates a lytic state in the blood, and produces bleeding complications in a large patient population. PAs have been extensively investigated to achieve thrombus specificity, to attenuate the bleeding risk, and to widen their clinical applications. In this review, we discuss various strategies that have been pursued since the beginning of thrombolytic therapy. We review the biotechnological approaches that have been used to develop mutant and chimeric PAs for thrombus selectivity, including the use of specific antibodies for targeting thrombi. We discuss particulate carrier-based systems and triggered-release concepts. We propose new hypotheses and strategies to spur future studies in this research arena. Overall, we describe the approaches and accomplishments in the development of patient-friendly and workable delivery systems for thrombolytic drugs.

Liposomes for targeted delivery of antithrombotic drugs

BACKGROUND

Targeted delivery of antithrombotic (thrombolytic) drugs is expected to increase their efficacy and decrease side effects, especially in the case of thrombolytic enzymes. Liposomes, phospholipid nanosized bubbles with a bilayered membrane structure, have drawn a lot of interest as pharmaceutical carriers for drugs and genes. In particular, several attempts have been made to use liposomes as vehicles for antithrombotic agents.

OBJECTIVE

This review analyzes the available data on the application of liposomes, including liposomes targeted by specific ligands, for the delivery of antithrombotic/thrombolytic agents in order to increase their efficacy and decrease side effects.

METHODS

The papers published on the subject of liposomes loaded with antithrombotic agents, mainly over the last 10 - 15 years, will be discussed.

CONCLUSION

Liposomes loaded with various antithrombotic drugs, though they have been the subject of a significant number of experimental papers, can hardly be considered as real candidates for clinical application in the near future.

Chemical coupling of a monoclonal antisurfactant protein-B antibody to human urokinase for targeting surfactant-incorporating alveolar fibrin

Intraalveolar fibrin formation is a common histopathological finding in acute inflammatory and chronic interstitial lung diseases. Incorporation of hydrophobic surfactant components into polymerizing fibrin results in a severe loss of surface activity, altered mechanical and structural clot properties, and a reduced susceptibility toward fibrinolytic degradation. Such events have been implicated in atelectasis formation, impairment of gas exchange, and provocation of fibroproliferative changes. In an effort to address the unique features of alveolar fibrin, we designed a hybrid molecule consisting of a monoclonal antibody against surfactant protein SP-B (8B5E) and the catalytic domain of urokinase (B-chain), which was termed MABUC. The urokinase B-chain was prepared by limited reduction of human two-chain-urokinase and subsequent affinity purification and coupled to the antibody using a heterobifunctional cross-linker. Purification of the chimeric protein included gel filtration chromatography and affinity chromatography. An ELISA-like microtiter plate assay, based on the immunological detection of the SP-B moiety and the fibrinolytic activity of the u-PA domain, was developed for the detection of the hybrid molecule. Chromogenic substrate assays, (125)I-based fibrin plate assays, and active site titration were performed to analyze the specific fibrinolytic activity of the conjugate. MABUC was found to fully retain the ability of SP-B binding and the fibrinolytic activity of u-PA. In addition, MABUC was noted to be 1.5-2-fold more effective in the dissolution of surfactant embedding clots and to be approximately 3-fold more resistant against PAI-1, the predominant fibrinolysis inhibitor in the alveolar compartment, as compared to the native u-PA. The superiority of MABUC was particularly prominent (>5-fold efficacy) when investigating clot material incorporating both PAI-1 and surfactant, as a mimicry of alveolar fibrin. We conclude that urokinase and 8B5E can be cross-linked chemically, thus yielding a fibrinolytic enzyme with enhanced substrate specifity for surfactant-containing clots and higher PAI-1 resistance as compared to native u-PA.

Drug targeting

The main problems currently associated with systemic drug administration are: even biodistribution of pharmaceuticals throughout the body; the lack of drug specific affinity toward a pathological site; the necessity of a large total dose of a drug to achieve high local concentration; non-specific toxicity and other adverse side-effects due to high drug doses. Drug targeting, i.e. predominant drug accumulation in the target zone independently on the method and route of drug administration, may resolve many of these problems. Currently, the principal schemes of drug targeting include direct application of a drug into the affected zone, passive drug targeting (spontaneous drug accumulation in the areas with leaky vasculature, or Enhanced Permeability and Retention-EPR-effect), 'physical' targeting (based on abnormal pH value and/or temperature in the pathological zone), magnetic targeting (or targeting of a drug immobilized on paramagnetic materials under the action of an external magnetic field), and targeting using a specific 'vector' molecules (ligands having an increased affinity toward the area of interest). The last approach provides the widest opportunities. Such pharmaceutical carriers as soluble polymers, microcapsules, microparticles, cells, cell ghosts, liposomes, and micelles have been successfully used for targeted drug delivery in vivo. Though the direct conjugation of a drug molecule with a targeted moiety is also possible (immunotoxin), the use of microreservoir-type systems provides clear advantages, such as high loading capacity, possibility to control size and permeability of drug carrier systems and use relatively small number of vector molecules to deliver substantial quantities of a drug to the target. The practical use of the listed systems and approaches for the delivery of therapeutic and diagnostic agents will be considered.

Chimeric fibrolase: covalent attachment of an RGD-like peptide to create a potentially more effective thrombolytic agent

We have prepared an agent possessing both thrombolytic and antiplatelet properties, by conjugating fibrolase, a direct-acting fibrinolytic enzyme isolated from southern copperhead venom, to a peptide which inhibits platelet aggregation. Heterobifunctional coupling reagents, N-succinimidyl 3-(2-pyridyldithio) propionate (SPDP) or sulfosuccinimidyl 6-[alpha-methyl-alpha-(2-pyridyldithio)-toluamido]hexanoate (Sulfo-LC-SMPT), were used in a molar ratio of 10:1 (coupling agent/fibrolase). The N-hydroxy-succinimide of the coupling agent reacts with surface epsilon-amino groups of lysine residues on fibrolase and provides a dithio group that is highly reactive with small thiol compounds. The derivatives obtained in the first reaction contain approximately two moles of 2-pyridyl disulphide per mole of enzyme. These derivatives were then reacted with the free thiol group in an antiplatelet peptide at a molar ratio of 2:1 (peptide/fibrolase). The peptide-fibrolase conjugate was purified by cation exchange HPLC and analyzed by amino acid analysis. The conjugate contains one mole peptide per mole of fibrolase and retains approximately 85% fibrinolytic activity. The IC50 for inhibition of platelet aggregation in human PRP is 300 nM for the conjugate and 67 nM for the antiplatelet peptide. These results demonstrate the successful formation of a novel chimeric protein with bifunctional activity.

Antithrombotic potency of hirudin is increased in nonhuman primates by fibrin targeting

BACKGROUND

Inhibition of thrombin by either the indirect thrombin inhibitor heparin or by more potent direct thrombin inhibitors such as hirudin reduces thrombus formation after arterial injury. The present study was designed to determine if a fibrin-specific thrombin inhibitor could, by local thrombin inhibition, prevent thrombosis more effectively.

METHODS AND RESULTS

We first studied antithrombotic potency in vitro, comparing fibrin-targeted hirudin (recombinant hirudin covalently linked to the Fab' fragment of the anti-fibrin monoclonal antibody 59D8) to recombinant hirudin in baboon plasma. Fibrin-targeted hirudin was nine times more effective than recombinant hirudin in inhibiting fibrin deposition on experimental clot surfaces in baboon plasma (P < .01). The potency of fibrin-targeted hirudin was then compared with that of recombinant hirudin in a baboon model of thrombus formation. 111In-labeled platelet deposition was measured in a synthetic graft segment of an extracorporeal arteriovenous shunt in control animals and in animals receiving either fibrin-targeted hirudin or hirudin. In these experiments, fibrin-targeted hirudin was 10-fold more potent than hirudin in inhibiting platelet deposition and thrombus formation (P < .05).

CONCLUSIONS

These data indicate that targeting a thrombin inhibitors such as hirudin to an epitope present in thrombi results in increased antithrombotic potency.

Fibrin-targeted recombinant hirudin inhibits fibrin deposition on experimental clots more efficiently than recombinant hirudin

BACKGROUND

Although the indirect thrombin inhibitor heparin and the more potent direct inhibitor hirudin are useful in preventing thrombosis, a substantial opportunity remains for improving the thrombus selectivity of thrombin inhibitors.

METHODS AND RESULTS

To explore the effect of targeting an antithrombin to the surface of a clot, we covalently linked recombinant hirudin to the Fab' (or IgG) of a monoclonal antibody (59D8) that selectively binds to an epitope on fibrin that becomes exposed only after thrombin cleaves fibrinopeptide B. Antibody-coupled hirudin bound to an immobilized peptide of the fibrin beta-chain amino-terminal sequence and inhibited the peptidolytic activity of thrombin more efficiently than free hirudin. Thrombin inhibition dependent on binding to immobilized fibrin monomer was enhanced 1100-fold (P < .0001). Hirudin-59D8 Fab' was 10 times more effective than hirudin in inhibiting fibrin deposition on experimental clot surfaces in fibrinogen solution (P < .0001) and human plasma (P < .0001). The more effective inhibition of thrombin by the conjugate was supported by significantly diminished concentrations of fibrinopeptide A in the plasma supernatant of the clot (P = .0001). Inhibition of clotting by an uncoupled mixture of hirudin and 59D8 Fab' was indistinguishable from that by hirudin alone, indicating that the conjugate's greater inhibitory activity was due to the covalent linkage between antibody and hirudin.

CONCLUSIONS

Fibrin-targeted hirudin (in comparison with unmodified hirudin) significantly reduces fibrin deposition on the surface of experimental clots.

Thrombolytic therapy in acute myocardial infarction--selected recent developments

Thrombolytic therapy is the established treatment of choice for most eligible patients with acute myocardial infarction. Early initiation of treatment and early, complete and maintained patency of the infarct-related coronary artery are desirable, because these variables correlate with a reduction in mortality. As a consequence, considerable efforts have been undertaken to develop new pharmacological agents that serve these purposes. Among these, new plasminogen activators such as reteplase (r-PA), saruplase (scuPA), and staphylokinase are in clinical development, and DSPA (bat t-PA) and antibody-targeted plasminogen activators (ScuPA-59D8) have undergone extensive animal testing. Anticoagulants such as recombinant hirudin, hirulog, argatrobane, and Factor Xa inhibitors, as well as antiplatelet agents on the basis of monoclonal antibody 7E3 offer promise as adjunctive therapy to thrombolysis or to invasive intracoronary procedures.

Thrombolytic profiles of clot-targeted plasminogen activators. Parameters determining potency and initial and maximal rates

BACKGROUND

Targeting of plasminogen activators to the thrombus by means of fibrin-specific monoclonal antibodies may enhance their thrombolytic potency. The kinetics of clot binding of two human fibrin-specific monoclonal antibodies (MA-12B3 and MA-15C5) and of clot lysis with their chemical 1:1 stoichiometric complexes with recombinant single-chain urokinase-type plasminogen activator (rscu-PA) (rscu-PA/MA-12B3 and rscu-PA/MA-15C5) were determined in hamsters and rabbits. Thrombolytic potencies, maximal rates of clot lysis, and the duration of the lag phases before clot lysis of the antibody/rscu-PA conjugates were compared with those of rscu-PA and tissue-type plasminogen activator (rt-PA).

METHODS AND RESULTS

Bolus injection of 7.5 micrograms of 125I-labeled antibody in rabbits with an extracorporeal arteriovenous loop containing a 0.3-mL human plasma clot produced clot-to-blood ratios of 6.6 +/- 1.0 (mean +/- SEM) for MA-12B3 and 1.1 +/- 0.15 for MA-15C5 (p < 0.001 versus MA-12B3) within 6 hours. Progressive digestion of the clot did not alter the binding of MA-12B3 but resulted in as much as a 10-fold increase of the binding of MA-15C5. The conjugates infused intravenously over 90 minutes in hamsters with a human plasma clot in the pulmonary artery produced dose-related in vivo clot lysis. Thrombolytic potencies (maximal slope of the percent lysis versus dose in milligrams of u-PA equivalent per kilogram body weight) were 2,500 +/- 440 for rscu-PA/MA-12B3, 3,600 +/- 640 for rscu-PA/MA-15C5 (p = NS vs. rscu-PA/MA-12B3), 60 +/- 8 for rscu-PA (p < 0.001 versus both conjugates), and 380 +/- 66 for rt-PA (p < 0.001 versus both conjugates). The plasma clearances of the conjugates were fourfold to sixfold slower than those of rscu-PA and rt-PA. Maximal rates of clot lysis, determined by continuous external radioisotope scanning over the thorax, were 0.90 +/- 0.13%, 0.91 +/- 0.17%, 0.84 +/- 0.12%, and 1.1 +/- 0.16% lysis per minute for rscu-PA/MA-12B3, rscu-PA/MA-15C5, rscu-PA, and rt-PA, respectively; these maximal rates were obtained with 0.016, 0.016, 1.0, and 0.25 mg/kg, respectively, and were associated with minimal lag phases of 18 +/- 3.2, 28 +/- 4.9, 34 +/- 3.7, and 25 +/- 3.9 minutes, respectively.

CONCLUSIONS

The thrombolytic potency of the rscu-PA/antifibrin conjugates is determined by their clearance, as well as by rate and extent of initial binding to clots and by changes in binding during clot lysis. Clot targeting of rscu-PA with fibrin-specific antibodies increases its thrombolytic potency but does not alter the maximal rate or the minimal lag phase of clot lysis. These parameters appear to be independent of the nature of the plasminogen activator and of targeting.

Advances in thrombolytic therapy

Alteplase and saruplase are more fibrin-specific thrombolytic drugs than anistreplase. These and the thrombolytic drugs of the first generation (streptokinase and urokinase) have shortcomings and limitations. The prolonged intravenous maintenance infusions have been replaced by a bolus injection, accelerated infusions, or the combined intravenous administration of thrombolytic agents. Numerous truncated alteplase or saruplase molecules have been constructed by deletion and domain substitution or hybrids made of the two molecules without gaining in thrombolytic potency. Recombinant staphylokinase and plasminogen activator from bat saliva have some interesting properties and are being investigated. Thrombus-targeted thrombolytic drugs were constructed using monoclonal antibodies against fibrin fragments or against epitopes of activated platelets. Fibrin-specific thrombolytic drugs require the concomitant use of a potent antithrombotic drug to prevent reocclusion. Whether hirudin or synthetic thrombin inhibitors are superior to heparin and whether novel antiplatelet agents, including monoclonal antibodies to platelet receptors and disintegrins, are more effective than aspirin is under clinical investigation. The place of stable analogues of prostacyclin during thrombolytic treatment is still unsettled.

Platelet-targeted fibrinolysis enhances clot lysis and inhibits platelet aggregation

BACKGROUND

Although plasminogen activator therapy has been shown to reduce mortality in patients with severe myocardial infarction, several problems fuel the search for more potent and specific thrombolytic agents.

METHODS AND RESULTS

To explore the effect of plasminogen activator targeting to platelets, we covalently linked urokinase that had been modified with N-succinimidyl-3-(2-pyridyldithio)propionate to the Fab' of a monoclonal antibody (7E3) that selectively binds to platelet membrane glycoprotein (GP) IIb/IIIa. In an assay measuring (as reflected by plasmin generation) a plasminogen activator's ability to bind GP IIb/IIIa immobilized on plastic, urokinase-7E3 Fab' produced 31-fold more plasmin than did urokinase (p = 0.0001). The addition of solubilized GP IIb/IIIa blocked this enhancement of plasmin generation, indicating that binding was impaired. Plasmin generation reflecting binding to immobilized intact platelets was 2.4-fold greater for urokinase-7E3 Fab' than for unconjugated urokinase (p = 0.002). In a plasma clot lysis assay, urokinase-7E3 Fab' was at least 25-fold more potent than either urokinase alone or a mixture of urokinase and 7E3 (Fab')2 (p less than 0.009), and potency could be related to platelet concentration in the clot. Ex vivo, ADP-induced platelet aggregation was inhibited by a urokinase-7E3 IgG conjugate at a concentration of 8 nM, whereas a mixture of urokinase and 7E3 (Fab')2 in equimolar amounts required 60 nM and urokinase alone required 1 microM to achieve the same effect.

CONCLUSIONS

Therefore, the targeting of urokinase to the GP IIb/IIIa platelet receptor both accelerates clot lysis (when platelets are associated with a fibrin clot) and inhibits platelet aggregation.

Construction and characterization of a functional chimeric murine-human antibody directed against human fibrin fragment-D dimer

Fibrin-directed monoclonal antibodies may be clinically useful for in vitro thrombus imaging and for the targeting of fibrinolytic agents to blood clots. One such murine monoclonal antibody, (mAb-15C5), raised against the fragment-D dimer epitope of cross-linked human fibrin, was previously characterized [Holvoet, P., Stassen, J. M., Hashimoto, Y., Spriggs, D., Devos, P. & Collen, D. (1989) Thromb. Haemostasis 61, 307-313] has recently been cloned and expressed [Vandamme, A.-M., Bulens, F., Bernar, H., Nelles, L., Lijnen, H. R. & Collen, D. (1990) Eur. J. Biochem. 192, 767-775]. In order to reduce the immunogenicity of the murine mAb-15C5 in man, we have now constructed a murine--human chimera of mAb-15C5, by substituting the cDNA sequences encoding the constant regions of the murine kappa light chain and gamma 1 heavy chain by the corresponding human genomic sequences. Both chimeric murine--human Ig chains were cloned into two separately selectable expression vectors, which were contransfected into Chinese hamster ovary (CHO) cells. Murine--human chimeric mAb-15C5 (mAb-15C5Hu) was purified from the conditioned medium of selected cell lines by chromatography on Zn-chelating Sepharose, protein-A-Sepharose and on insolubilized antigen (fragment-D dimer), with a final yield of 29 micrograms/l and a recovery of 33%. SDS/PAGE without reduction revealed a homogeneous band with a mobility similar to that of natural mAb-15C5, whereas after reduction, both the heavy and the light chains had slightly slower mobilities than their natural counterparts. Expression in the presence of tunicamycin suggested that the differences in gamma 1-chain mobility were due to different N-glycosylation patterns. Immunoblotting of proteins from SDS gels showed immunological reactivity of recombinant mAb-15C5Hu with goat anti-(human IgG) IgG and of recombinant and natural murine mAb-15C5 with goat anti-(mouse IgG) IgG. Competitive binding revealed a comparable affinity of recombinant murine mAb-15C5, recombinant mAb-15C5Hu and natural mAb-15C5, for fragment-D dimer, indicating that recombinant mAb-15C5Hu was obtained in a functionally intact form. Thus, mAb-15C5Hu may constitute a useful alternative to mAb-15C5 for in vivo use in man.

Targeted killing of yeast expressing a HIV-1 peptide by antibody-conjugated glucose oxidase and horseradish peroxidase

The epitope recognized by monoclonal antibody directed against the HIV-1 recombinant gp160 protein was precisely delineated by using a number of peptides comprising amino acid positions 302-330 of the protein. Two different enzymes, glucose oxidase and horseradish peroxidase, were then coupled to distinct antibody molecules and the efficacy of the immunoenzymes in killing yeast cells which express the recognized peptide was evaluated by flow cytometry analysis. The antibody-glucose oxidase conjugate alone was cytotoxic only at large doses (over 35 micrograms/ml) while in the presence of the antibody-horseradish peroxidase conjugate, killing was observed at nine times lower concentrations (4 micrograms/ml). The procedure described here may provide a new immunotherapy tool for microbial infection.

Development of new thrombolytic agents using recombinant DNA technology

The increasing incidence of thromboembolic diseases has sustained the search for new agents able to stimulate the natural fibrinolytic system. The first generation of antithrombotic agents include bacterial streptokinase and human urine urokinase. Because these molecules lack specificity for the fibrin clot, important efforts have been made to produce, using recombinant DNA technology, agents presenting higher fibrin clot selectivity such as t-PA (tissue-type plasminogen activator) and scu-PA (single chain urokinase-type plasminogen activator). In parallel, several laboratories are presently attempting to create mutants and hybrids plasminogen activators displaying improved thrombolytic properties with respect to the natural molecules. In this paper, we describe briefly the mechanisms of fibrinolysis and the role of the different natural thrombolytic agents. In addition, we review the possibilities of genetic engineering for the production of natural and novel plasminogen activators.

Conjugation to antifibrin Fab' enhances fibrinolytic potency of single-chain urokinase plasminogen activator

Single-chain urokinase plasminogen activator (scu-PA) that had been modified with N-succinimidyl-3-(2-pyridyldithio)propionate was covalently linked by disulfide bonds to the Fab' of a monoclonal antibody specific for the beta-chain of fibrin (antibody 59D8). scu-PA-59D8 Fab' conjugate was separated from free scu-PA and two-chain urokinase coupled to 59D8 Fab' by two-step affinity chromatography. First, the reaction mixture was chromatographed on a column containing Sepharose linked to the peptide that had been used as immunogen for antibody 59D8; scu-PA-59D8 Fab' conjugate and unconjugated 59D8 Fab' were retained but not unconjugated scu-PA. Then, the eluate from the peptide-Sepharose column was chromatographed on a column containing Sepharose linked to benzamidine, which acts as a ligand for two-chain urokinase. The molecular weight of the scu-PA-59D8 Fab' conjugate was approximately 100 kDa when electrophoresed on a nonreducing sodium dodecylsulfate-polyacrylamide gel. Enzymatic assay after purification revealed that more than 97% of the scu-PA present in the conjugate retained the single-chain form. The Fab' portion of the conjugate functioned in a manner indistinguishable from that of native antibody 59D8. In an in vitro assay for lysis of fibrin monomer, the fibrinolytic potency of scu-PA-59D8 Fab' was 33-fold more than that of tissue plasminogen activator (p less than 0.001), 230-fold more than that of unconjugated scu-PA (p less than 0.0001), and 420-fold more than that of urokinase (p less than 0.0001).(ABSTRACT TRUNCATED AT 250 WORDS)

Future directions in plasminogen activator therapy

Thrombotic disorders such as myocardial infarction and stroke are the leading causes of death and disability in industrialized nations. Timely institution of thrombolytic therapy can achieve a reduction of infarct size, a preservation of left ventricular function, and a reduction in mortality. The administration of streptokinase, urokinase, and acylated plasminogen-streptokinase activator complex (APSAC) can be associated with a complete breakdown of the hemostatic system. Tissue-type plasminogen activator (t-PA) and single-chain urokinase-type plasminogen activator (scu-PA, prourokinase) are more fibrin specific; however, at the large dosages of activator needed for therapeutic efficacy, bleeding complications are still a problem. New approaches to optimizing the risk/benefit ratio for the patient by improving efficacy without sacrificing specificity include the use of synergistic combinations of plasminogen activators, mutants of t-PA and scu-PA, chimeric molecules, and antibody-targeted thrombolytic agents. The last approach opens the possibility of targeting several different components of the clot with either fibrinolytic or antiplatelet effector functions in one optimized molecule.

Enhanced in vitro cytotoxicity of 1,3-bis-(2-chloroethyl)-1-nitrosourea or buthionine sulfoximine combined with a reactive oxygen-generating enzyme immunotoxin

The glutathione inhibitor drugs, 1,3-bis(2-chloroethyl)-1-nitrosourea (BCNU) and buthionine sulfoximine (BSO), were tested in vitro in order to assess their cytotoxic effectiveness when combined with an enzyme immunotoxin (eIT) composed of a T-cell reactive monoclonal antibody (mAb) 097 coupled to the reactive oxygen-generating enzyme, glucose oxidase (GO) (EC 1.1.3.4). As targets of this eIT we used mature human T-cells or leukemia cells that expressed the 097 epitope. We found that treatment of the cells with subtoxic amounts of mixtures of both a drug and the 097 eIT markedly potentiated cytotoxicity compared to either drug or eIT alone.

Biochemical properties of conjugates of urokinase-type plasminogen activator with a monoclonal antibody specific for cross-linked fibrin

Equimolar mixtures of recombinant single chain urokinase-type plasminogen activator (rscu-PA) and a murine monoclonal antibody (MA-15C5) directed against fragment-D dimer of human cross-linked fibrin were conjugated, using the cross-linking agent N-succinimidyl 3-(2-pyridyldithio)propionate (PySSProSu). The conjugate (rscu-PA/MA-15C5), purified by immunoadsorption on a urokinase antibody and affinity chromatography on fibrin fragment-D dimer with a yield of 42 +/- 15% (mean +/- SD, n = 3), contained an average of 1.2 +/- 0.3 IgG molecules/rscu-PA molecule. On non-reduced SDS/PAGE it migrated as a main band with apparent Mr of 200,000. Specific amidolytic activities expressed/mass of u-PA were less than 250 IU/mg for rscu-PA/MA-15C5 and rscu-PA, 140,000 +/- 13,000 IU/mg and 100,000 +/- 17,000 IU/mg for their plasmin-generated two chain derivatives rtcu-PA/MA-15C5 and rtcu-PA respectively. Specific activities on fibrin plates were 100,000 +/- 24,000 IU/mg and 130,000 +/- 49,000 IU/mg for rscu-PA/MA-15C5 and rtcu-PA/MA-15C5 respectively, as compared to 180,000 +/- 15,000 IU/mg for both rscu-PA and rtcu-PA. Activation of plasminogen with rscu-PA/MA-15C5 (Km = 0.37 +/- 0.16 microM, k2 = 0.0063 +/- 0.0030 s-1 or rtcu-PA/MA-15C5 (Km = 19 +/- 3.0 microM, k2 = 2.0 +/- 0.10 s-1) in purified systems followed Michaelis-Menten kinetics with Km and k2 values comparable to those of rscu-PA and rtcu-PA. In an in vitro system composed of a 125I-fibrin-labeled whole human plasma clot immersed in citrated human plasma, dose- and time-dependent lysis was obtained; 50% lysis in 2 h required 1.4 microgram/ml of rscu-PA or 0.33 microgram/ml of rtcu-PA, but only 0.22 microgram u-PA/ml of rscu-PA/MA-15C5 or 0.15 microgram u-PA/ml of rtcu-PA/MA-15C5. Addition of purified fragment-D dimer reversed the increased fibrinolytic potency of rscu-PA/MA-15C5 in a concentration-dependent way (50% inhibition at 7.2 micrograms fragment-D dimer/ml). Thus, conjugation of u-PA moieties with the fibrin-specific antibody MA-15C5 targets the plasminogen activator to the clot, resulting in a significant increase of their fibrinolytic potencies as compared to their unconjugated counterparts: 6.4-fold for rscu-PA and 2.2-fold for rtcu-PA.

[Antibody mediated thrombolysis. A new therapeutic principle]

Thrombosis of a coronary artery is the most common cause of myocardial infarction. Thrombolytic therapy, when instituted timely, has been shown capable of reducing morbidity and mortality. However, the use of presently available thrombolytic agents is associated with a bleeding tendency and efficacy is not optimal. This article reviews one of several lines of investigation that are presently being pursued in order to improve efficacy and specificity of thrombolytic therapy. The chemical conjugation of a fibrin specific monoclonal antibody and urokinase or tissue plasminogen activator results in markedly enhanced thrombolytic potency, both in vitro and in vivo. Specificity of the conjugates is greater than that of the parent plasminogen activators as reflected by conservation of fibrinogen, plasminogen and alpha-2 antiplasmin. A bispecific antibody, with specificity for both, fibrin and tissue plasminogen activator, has the potential of concentrating endogenous tissue plasminogen activator at the site of a thrombus. In the presence of the bispecific antibody, efficacy and specificity of tissue plasminogen activator are markedly enhanced in vitro and in vivo. The tools of molecular biology are presently being applied in order to translate these findings into better thrombolytic therapy.

New strategies in the development of thrombolytic agents

Recombinant DNA technology has allowed large-scale production of the physiological, fibrin-specific, plasminogen activators tissue-type plasminogen activator (t-PA) and single-chain urokinase-type plasminogen activator (scu-PA). The results of clinical trials with these agents, mainly for the treatment of acute myocardial infarction, have revealed a limited fibrin specificity at the large therapeutic doses required for efficient thrombolysis. Mutants and variants of t-PA and scu-PA have given important information on structure-function relationships in these proteins and have resulted in rt-PA variants with significantly prolonged half-lives in vivo. Construction of chimaeric plasminogen activators containing various portions of t-PA and scu-PA has produced functionally active enzymes, however with a lower fibrin-affinity than wild-type t-PA. The promise of antibody targeting and the use of synergistic combinations of thrombolytic agents remains to be further investigated. We anticipate that eventually these research lines will yield artificial plasminogen activators with improved efficacy, risk/benefit and cost/benefit ratios.