Tissue Plasminogen Activator (Tpa) Inhibits Plasmin Degradation of Fibrin
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Tissue plasminogen activator (tPA) inhibits plasmin degradation of fibrin. A mechanism that slows tPA-mediated fibrinolysis but does not require alpha 2-antiplasmin or leakage of intrinsic plasminogen. J H Wu, S L Diamond J Clin Invest. 1995;95(6):2483-2490. https://doi.org/10.1172/JCI117949. Research Article Thrombolysis is dramatically slower when high concentrations of lytic agent are used. This paradoxical observation, first described as "plasminogen steal," was originally believed to be due to depletion of extrinsic plasminogen and consequent leaching of clot-bound plasminogen. We report that administration of increasing concentrations of recombinant human tissue plasminogen activator (tPA) to fibrin gels resulted in lysis rates that displayed a maximum, with significantly slower rates found at higher tPA, regardless of whether plasminogen was supplied extrinsically or intrinsically. A similar maximum in lysis rates was observed in a system lacking an extrinsic phase when plasminogen was added to fibrin suspensions preincubated with increasing tPA. Thus, intrinsic plasminogen leakage and alpha 2-antiplasmin were not required for the decreased lysis at high tPA. No maximum was observed for increasing concentrations of urokinase. Using fibrin suspensions or gels preincubated with tPA before addition of plasmin, we report that tPA, but not urokinase, caused a dose-dependent inhibition of the fibronolytic action of plasmin. With respect to optimal dosage schemes and the design of novel lytic agents, these findings indicate that (a) there exists a biochemical mechanism against minimizing reperfusion time with increasing tPA dosages and (b) the fibrin affinity of tPA may cause reduced fibrinolysis by plasmin. Find the latest version: https://jci.me/117949/pdf Tissue Plasminogen Activator (tPA) Inhibits Plasmin Degradation of Fibrin A Mechanism That Slows tPA-mediated Fibnnolysis but Does Not Require a2-Antiplasmin or Leakage of Intrinsic Plasminogen Jung He Wu and Scott L. Diamond Bioengineering Laboratory, Department of Chemical Engineering, State University of New York at Buffalo, Buffalo, New York 14260 Abstract ical observation was first described as "plasminogen steal" (1) and was postulated to be due to depletion of extrinsic plasmino- Thrombolysis is dramatically slower when high concentra- gen and an associated leaching of clot-bound plasminogen out tions of lytic agent are used. This paradoxical observation, of the clot and into the plasminogen-depleted plasma (2). first described as "plasminogen steal," was originally be- Within dissolving fibrin, reactions in the interstitial fluid of the lieved to be due to depletion of extrinsic plasminogen and clot combined with reactions on the fibrin fibers result in a consequent leaching of clot-bound plasminogen. We report continually evolving kinetic phenomena. The rates of transport that administration of increasing concentrations of recombi- of species across the boundary between the clot and the external nant human tissue plasminogen activator (tPA) to fibrin plasma contribute to the overall kinetics of clot lysis (5-8). In gels resulted in Iysis rates that displayed a maximum, with general, the more plasminogen within the clot (intrinsic) or significantly slower rates found at higher tPA, regardless of external to the clot (extrinsic) that is available for activation, whether plasminogen was supplied extrinsically or intrinsi- the more rapidly lysis will occur (3, 9). When the local plasmin- cally. A similar maximum in lysis rates was observed in a ogen concentration within a clot exceeds the local antiplasmin system lacking an extrinsic phase when plasminogen was concentration, increasing the rate of plasminogen activation added to fibrin suspensions preincubated with increasing with increasing amounts of tPA or uPA is expected to produce tPA. Thus, intrinsic plasminogen leakage and a2-antiplas- plasmin activity in a more rapid manner. Although inhibition min were not required for the decreased lysis at high tPA. reactions mediated by a2-antiplasmin or plasminogen activator No maximum was observed for increasing concentrations inhibitor type 1 are expected to slow lysis, these inhibitors of urokinase. Using fibrin suspensions or gels preincubated would not be expected to produce attenuated lysis rates as the with tPA before addition of plasmin, we report that tPA, concentration of thrombolytic agent is increased. but not urokinase, caused a dose-dependent inhibition of Given the relatively slow rate of diffusional processes to the fibrinolytic action of plasmin. With respect to optimal transport fibrin binding proteins over distances of millimeters dosage schemes and the design of novel lytic agents, these (5-8), we hypothesized that the dramatically decreased lytic findings indicate that (a) there exists a biochemical mecha- rate observed at high tPA concentration was a direct biochemi- nism against minimizing reperfusion time with increasing cal effect and did not require a "steal" of plasminogen from tPA dosages and (b) the fibrin affinity of tPA may cause the clot. That the lysis rate of thrombi can display a bell-shaped reduced fibrinolysis by plasmin. (J. Clin. Invest. 1995. dose-response curve (3) at increasingly high tPA concentrations 95:2483-2490.) Key words: fibrinogen * fluorescence * uro- is suggestive of competition between species for limited number kinase * diffusion * thrombolysis of binding or cleavage sites. The present study was focused at determining the requirements in a purified system for a maxi- Introduction mum to be observed in the lysis rate vs tPA dose-response curves. We have found that a maximum in lysis rates is observed The observation that thrombolysis is dramatically slower when for tPA-mediated lysis, but that this observed maximum does high concentrations of urokinase plasminogen activator (uPA)' not require the presence of a2-antiplasmin and is independent or tissue plasminogen activator (tPA) are used (1-4) is com- of intrinsic plasminogen leakage. Using fibrin gel lysis assays pletely unexpected and only partially understood. This paradox- which have an extrinsic phase and assays using well mixed fibrin fiber suspensions which have no extrinsic phase, we have found that tPA can directly reduce the activity of plasmin on fibrin. These findings identify a mechanism that establishes opti- Address correspondence to Scott L. Diamond, Bioengineering Labora- mal upper tory, State University of New York, 907 Furnas Hall, Buffalo, NY dosage during thrombolytic therapy via tPA adminis- 14260. Phone: 716-645-2911; FAX: 716-645-3822. tration. Continually increasing the concentration of tPA at the Received for publication 7 September 1994 and in revised form 27 site of the thrombus will not lead to faster and faster reperfusion December 1994. because high levels of tPA will eventually attenuate the action of plasmin on fibrin. High fibrin affinity plasminogen activator 1. Abbreviations used in this paper: sc-tPA, single chain tissue plasmin- mutants may suffer a similar limitation of reducing plasmin ogen activator; tc-tPA, two chain tissue plasminogen activator; tPA, degradation of fibrin. tissue plasminogen activator; uPA, urokinase PA; vi', steady state lysis front velocity. Methods J. Clin. Invest. © The American Society for Clinical Investigation, Inc. Reagents. Purified human thrombin was obtained from Sigma Chemical 0021-9738/95/06/2483/08 $2.00 Co. (St. Louis, MO) as a lyophilized powder (sp act: 3,000 NIH U/ Volume 95, June 1995, 2483-2490 mg). Lyophilized human fibrinogen (Grade L; Kabi AB, Stockholm, Tissue Plasminogen Activator Inhibits Plasmin Degradation of Fibrin 2483 Sweden) was dissolved in 0.05 M Tris-HCl (pH 7.4) and dialyzed at -. Figure 1. Plasmin-medi- 40C against 0.05 M Tris-HCl containing 0.1 M NaCl, centrifuged at ated lysis of fibrin under 2,000 g for 20 min (40C) and the supernatant was frozen in small c 0.1 conditions of diffusion- aliquots at -750C. Purified human Glu- and Lys-plasminogen and hu- mediated transport of ex- man plasmin (American Diagnostica Inc., Greenwich, CT) and human E trinsic Glu-plasmin (-) a2-antiplasmin (Calbiochem-Novabiochem Corp., La Jolla, CA) were 0.01o or Lys-plasmin (u) into reconstituted, centrifuged at 2,000 g for 20 min (40C), and stored at preformed coarse fibrin -750C. Recombinant human tPA was obtained as a gift from Dr. W. 0.001, (3 mg/ml). The fluid/ Bennett (Genentech, Inc., South San Francisco, CA). Urokinase was fibrin interface moved at obtained as a gift from Dr. A. Sasahara (Abbott Laboratories, Abbott a steady state lysis front Park, IL). For fluorescence labeling, fibrinogen (10 mg/ml) was incu- o.001o Ol 1 lo 100 velocity for over 100 bated with 1 mg/ml FITC (Molecular Probes, Inc., Eugene, OR) with [pIsr,'] (pa4) min. Lys-plasmin was continuous stirring for 1 h at 220C in 0.1 M sodium bicarbonate (pH generated from Lys-plas- 9.0). The reaction was stopped with hydroxylamine (0.15 M), dialyzed, minogen by 30-min incubation with uPA before the placement of the and stored at -750C. All concentrations are given as final concentrations solution next to the fibrin. in the reaction mixture. Preparation offibrin gels and gel lysis experiments. Gel lysis experi- ments with unmixed extrinsic phase were conducted as previously de- due to of was measured in a lumines- scribed (8) and carried out at 370C in an environmental room. Purified generation dequenched fragments cence spectrometer at room temperature. fibrin gels (2-cm long) were formed by suction pipetting a rapidly For SDS-PAGE analysis, 1.5 AtM fibrinogen was polymerized with mixed up into solution of fibrinogen (3 mg/ml) and thrombin (1 U/ml) 1 U/ml thrombin, sonicated for 5 min, and subjected to lytic regimes. The buffer for 100-j1 glass capillary tubes (1.5 mm inner diameter). Small samples were removed from fibrinolytic reactions at various times fibrin polymerization was 0.05 M Tris-HCI, 5 mM CaCl2 (pH 7.4) with and promptly heated at 950C for S min in SDS running buffer (Tris- 0.1 M NaCl to obtain turbid, coarse gels (10). The gels were allowed EDTA buffer [pH 8.0], 2% [vol/vol] SDS, 8 M urea (13, 14).