Inhibition of plasmin by fibrinogen.

The kinetics of inhibition of the amidolytic activity of plasmin on D-Val-L-Leu-L-Lys p-nitroanilide hydrochloride (S-2251) by fibrinogen and fibrin were determined. Reciprocal (1/v versus 1/[S]) plots of plasmin inhibition by 0.50 microM-fibrinogen showed a non-linear downward curve. The Hill coefficient (h) was 0.68, suggesting negative co-operativity. By contrast, fibrin produced a simple competitive inhibition of plasmin (Ki = 12 micrograms/ml). Addition of 0.1 mM-6-aminohexanoic acid shifted the non-linear curve obtained in the presence of fibrinogen to a straight line as for controls, indicating that 6-aminohexanoic acid abolishes the fibrinogen-induced inhibition. Transient exposure of the enzyme to pH 1.0 abrogates the ability of fibrinogen to inhibit plasmin activity. Acidification had no effect on the Vmax but increased the Km of plasmin. The present evidence for modulation of plasmin reveals a novel mechanism for control of fibrinolysis by fibrinogen, a component of the coagulation system and the precursor of the physiological substrate of plasmin.     

Kringle domains and plasmin denaturation.

The rate of plasmin denaturation was in the order of Lys-plasmin greater than miniplasmin greater than microplasmin. Fibrinogen degradation products (FDP) dose dependently increased the denaturation rate of Lys-plasmin and mini-plasmin with a maximal rate constant at the FDP/plasmin ratio of about 0.5. The denaturation rate constant of microplasmin was not affected. FDP increased the rate of plasmin denaturation was in parallel with its effect on the interaction among kringle domains. Without FDP only trace amounts of plasminogen dimer could be detected by cross-linking with bis-(sulfo-succinimidyl)-suberate followed by SDS gel electrophoresis. In the low concentration of FDP significant amounts of oligomers of Glu-, mini-plasminogens, kringle 1-3 and kringle 1-5 were observed. High concentration of FDP, however, decreased plasminogen oligomer.     

Hydrosoluble fluorogenic substrates for plasmin.

New hydrosoluble fluorogenic substrates for plasmin gluconoylpeptidyl-3-amido-9-ethylcarbazole were synthesized. The substitution of the N-terminal end of the peptides by a gluconoyl group prevents the substrates from aminopeptidase degradation and highly increases their hydrosolubility. The substitution of the peptide C-terminal end by a 3-amino-9-ethylcarbazole group leads to substrates suitable for direct fluorometric assay of plasmin present in cell supernatants or in cell lysates. On the basis of the kinetic parameters of the substrate hydrolysis by plasmin, it was found that D amino acids in the P2 position decrease systematically the kinetic constants of the substrates. The L configuration of the P2 amino acid appears therefore as essential in optimum substrates for plasmin.     

Interaction of plasmin with endothelial cells.

Interaction of human plasmin with a monolayer culture of mini-pig aortic endothelial cells was studied by using the 125I-labelled enzyme. The binding of plasmin was time- and concentration-dependent. Equilibrium between bound and free enzyme was obtained within 90s, and Scatchard analysis indicated a high- and a low-affinity population of binding sites of approx. 1.24 X 10(4) sites/cell having a Kd of 1.4 X 10(-9) M and 7.2 X 10(4) sites/cell with a Kd of 2 X 10(-8) M respectively. Plasmin, bound to cell, was spontaneously released within 2 min, suggesting a rapid equilibrium. Chemical modification of the enzyme with phenylmethanesulphonyl fluoride or pyridoxal 5'-phosphate revealed that neither the active centre nor the heparin-binding site of plasmin was involved in the interaction with the endothelial cell. In terms of endothelial-cell receptors, the binding sites of cells for plasmin and thrombin were different: the two enzymes did not compete with each other, and the pretreatment of cells with neuraminidase or chondroitin ABC lyase resulted in a 50% decrease of thrombin or plasmin binding respectively. Arachidonic acid incorporated into phospholipids of the cell was released by plasmin, but a change in the rate of prostacyclin formation was not measurable. The interaction of plasmin with endothelial cells seems to be specific in the fibrinolytic system, since plasminogen did not bind to these cells under similar conditions.     

Actin is a noncompetitive plasmin inhibitor.

Actin, one of the most abundant cellular proteins, circulates at micromolar concentrations in peripheral blood. Because actin released from dying cells may be trapped in fibrin clots that form at sites of tissue injury, we examined the effects of actin upon lysis of fibrin clots in vitro. Incorporation of native rabbit skeletal muscle actin into fibrin clots slowed their rates of lysis for periods of up to 24 h, an effect not seen when comparable concentrations of human IgG or bovine serum albumin were added instead. Actins isolated from a variety of sources inhibited plasmin's hydrolysis of the synthetic substrate S-2251 in a noncompetitive manner, with a Ki of a 0.6-3.1 microM. Inhibition was rapid, but covalent actin-plasmin complexes were not formed. Both epsilon-aminocaproic acid and tranexamic acid prevented actin's inhibition of plasmin, suggesting that accessible lysine residues of actin interact with the kringle (lysine-binding) regions of plasmin. Neither of the high-affinity actin-binding proteins of plasma (plasma gelsolin and vitamin D-binding protein) prevented actin from inhibiting plasmin. These findings suggest that actin released into the extracellular space following cell death may modulate plasmin action, and hence a number of plasmin-dependent biological responses, at sites of inflammation and tissue injury.     

Primary structure of the B-chain of human plasmin.

The primary structure of the human plasmin B-chain has been determined. It consists of 230 residues divided in three cyanogen bromide fragments: The amino-terminal 24 residues, the carboxy-terminal three residues and the middle 203 residues. Sequence detemination was performed on the tryptic and the chymotryptic peptides obtained from the main cyanogen bromide fragment of this chain. Owing to similarities between some of the overlapping chymotryptic peptides, two different sequences were possible from these results. However, since the homologies with the pancreatic serine proteases and also the B-chains of thrombin and factor XA are pronounced, the arrangement still could be settled. By peptic digestion of partially reduced and S-carboxymethylated B-chain it was shown that there are two interchain disulphide bridges, which connect the A and B-chains of plasmin, involving Cys-5 and Cys-105 from the B-chain. The intrachain disulphides in the B-chain seem to be situated exactly as in chymotrypsin as partly judged from homologies.     

The primary inhibitor of plasmin in human plasma.

A complex between plasmin and an inhibitor was isolated by affinity chromatography from urokinase-activated human plasma. The complex did not react with antibodies against any of the known proteinase inhibitors in plasma. A rabbit antiserum against the complex was produced. It contained antibodies agianst plasminogen+plasmin and an alpha2 protein. By crossed immunoelectrophoresis the alpha2 protein was shown to form a complex with plasmin, when generated by urokinase in plasma, and with purified plasmin. The alpha2 protein was eluted by Sephadex G-200 gel filtration with KD approx. 0.35, different from the other inhibitors of plasmin in plasma, and corresponding to an apparent relative molecular mass (Mr) of about 75000. By sodium dodecyl sulphate/polyacrylamide-gel electrophoresis, the Mr of the complex was found to be approx. 130000. After reduction of the complex two main bands of protein were observed, with Mr, about 72000 and 66000, probably representing an acyl-enzyme complex of plasmin-light chain and inhibitor-heavy chain, and a plasmin-heavy chain. A weak band with Mr 9000 was possibly an inhibitor-light chain. The inhibitor was partially purified and used to titrate purified plasmin of known active-site concentration. The inhibitor bound plasmin rapidly and strongly. Assuming an equimolar combining ratio, the concentration of active inhibitor in normal human plasma was estimated to be 1.1 mumol/1. A fraction about 0.3 of the antigenic inhibitor protein appeared to be functionally inactive. In plasma, plasmin is primarily bound to the inhibitor. Only after its saturation does lysis of fibrinogen and fibrin occur and a complex between plasmin and alpha2 macroglobulin appear.     

A kinetic characterization of the rabbit plasmin isozymes.

Steady-state and presteady-state kinetic parameters for plasmins derived from the two rabbit plasminogen isozymes have been determined. Steady-state kinetic experiments with N-α-tosyl-l-arginine methyl ester indicate that each isozyme has a similar V. Plasmin isozyme 2 has a higher K_m value for this substrate as well as a higher K_i, for the competitive inhibitor, benzamidine-HCl. Presteady-state kinetic experiments, using the p-nitrophenyl esters of p-(methylethylsulfoniummethyl)benzoate, p-(pyridiniummethyl) benzoate, p-(thiouroniummethyl)benzoate and p-(guanidinium)benzoate, indicate that each plasmin has similar rate constants of acylation (k₂). However, values of the dissociation constant (K_S) indicate that plasmin isozyme 1 has a greater binding affinity for these substrates than does isozyme 2. The magnitude of this difference varies with the substrate and is the greatest for those containing analogs of the guanidino moiety of l-arginine.     

Thrombospondin is a slow tight-binding inhibitor of plasmin.

Thrombospondin is a multifunctional glycoprotein of platelet alpha-granules and a variety of growing cells. We demonstrate that thrombospondin is a slow tight-binding inhibitor of plasmin as determined by loss of amidolytic activity, loss of ability to cleave fibrinogen, and decreased lysis zones in fibrin plate assays. Stoichiometric titrations indicate that approximately 1 mol of plasmin interacts with 1 mol of thrombospondin, an unexpected result considering the trimeric nature of thrombospondin. Plasmin in a complex with streptokinase or bound to epsilon-aminocaproic acid is protected from inhibition by thrombospondin, thereby implicating the lysine-binding kringle domains of plasmin in the inhibition process. Thrombospondin also inhibits urokinase plasminogen activator, but more slowly than plasmin, stimulates the amidolytic activity of tissue plasminogen activator, and has no effect on the amidolytic activity of alpha-thrombin or factor Xa. These results, therefore, identify thrombospondin as a new type of serine proteinase inhibitor and potentially important regulator of fibrinolysis.     

A method using fibrin-fixed Blue Dextran for determining the plasmin and plasmin inhibitor activities in human plasma.

The fibrinolytic activity of plasmin was determined by incubating with fibrin-fixed Blue Dextran as a substrate, the Blue Dextran released being proportional to the plasmin activity. The applicability of this method for rapid and accurate evaluation of fibrinolytic activity was demonstrated by dose-response curves with purified plasmin, plasmin generated by urokinase in human plasma and euglobulin. The method can also be used to determined plasmin inhibitors in plasma.     

Synthesis of plasmin substrates and relationship between their structure and plasmin activity

The plasmin substrates, D-Ile-Phe-Lys-pNA (I), 3-MV-Phe-Lys-pNA (II), Ile-Phe-Lys-pNA (III), D-Pro-Phe-Lys-pNA (IV), CP-Phe-Lys-pNA (V) and Pro-Phe-Lys-pNA (VI), were synthesized by the conventional solution method and the kinetic parameters of their amidolysis by plasmin were determined. It was found that the free amino group of the D-amino acid in substrates (I) and (IV) made a contribution to an increment in affinity between the substrate and plasmin.     

Actin accelerates plasmin generation by tissue plasminogen activator.

Actin has been found to bind to plasmin's kringle regions, thereby inhibiting its enzymatic activity in a noncompetitive manner. We, therefore, examined its effect upon the conversion of plasminogen to plasmin by tissue plasminogen activator. Actin stimulated plasmin generation from both Glu- and Lys-plasminogen, lowering the Km for activation of Glu-plasminogen into the low micromolar range. Accelerated plasmin generation did not occur in the presence of epsilon-amino caproic acid or if actin was exposed to acetic anhydride, an agent known to acetylate lysine residues. Actin binds to tissue plasminogen activator (t-Pa) (Kd = 0.55 microM), at least partially via lysine-binding sites. Actin's stimulation of plasmin generation from Glu-plasminogen was inhibited by the addition of aprotinin and was restored by the substitution of plasmin-treated actin, indicating the operation of a plasmin-dependent positive feedback mechanism. Native actin binds to Lys-plasminogen, and promotes its conversion to plasmin even in the presence of aprotinin, indicating that plasmin's cleavage of either actin or plasminogen leads to further plasmin generation. Plasmin-treated actin binds Glu-plasminogen and t-PA simultaneously, thereby raising the local concentration of t-PA and plasminogen. Together, but not separately, actin and t-PA prolong the thrombin time of plasma through the generation of plasmin and fibrinogen degradation products. Actin-stimulated plasmin generation may be responsible for some of the changes found in peripheral blood following tissue injury and sepsis.     

Identification of annexin II heterotetramer as a plasmin reductase.

Annexin II heterotetramer (AIIt) is a Ca(2+)- and phospholipid-binding protein that consists of two copies of a p36 and p11 subunit. AIIt regulates the production and autoproteolysis of plasmin at the cell surface. In addition to its role as a key cellular protease, plasmin also plays a role in angiogenesis as the precursor for antiangiogenic proteins. Recently we demonstrated that the primary antiangiogenic plasmin fragment, called A(61) (Lys(78)-Lys(468)) was released from cultured cells. In the present study we report for the first time that AIIt possesses an intrinsic plasmin reductase activity. AIIt stimulated the reduction of the plasmin Cys(462)-Cys(541) bond in a time- and concentration-dependent manner, which resulted in the release of A(61) from plasmin. Mutagenesis of p36 C334S and either p11 C61S or p11 C82S inactivated the plasmin reductase activity of the isolated subunits, suggesting that specific cysteinyl residues participated in the plasmin reductase activity of each subunit. Furthermore, we demonstrated that the loss of AIIt from the cell surface of HT1080 cells transduced with a retroviral vector encoding p11 antisense dramatically reduced the cellular production of A(61) from plasminogen. This is the first demonstration that AIIt regulates the cellular production of the antiangiogenic plasminogen fragment, A(61).