Impact of SMTP Targeting Plasminogen and Soluble Epoxide Hydrolase on Thrombolysis, Inflammation, and Ischemic Stroke.

Stachybotrys microspora triprenyl phenol (SMTP) is a large family of small molecules derived from the fungus S. microspora. SMTP acts as a zymogen modulator (specifically, plasminogen modulator) that alters plasminogen conformation to enhance its binding to fibrin and subsequent fibrinolysis. Certain SMTP congeners exert anti-inflammatory effects by targeting soluble epoxide hydrolase. SMTP congeners with both plasminogen modulation activity and anti-inflammatory activity ameliorate various aspects of ischemic stroke in rodents and primates. A remarkable feature of SMTP efficacy is the suppression of hemorrhagic transformation, which is exacerbated by conventional thrombolytic treatments. No drug with such properties has been developed yet, and SMTP would be the first to promote thrombolysis but suppress disease-associated bleeding. On the basis of these findings, one SMTP congener is under clinical study and development. This review summarizes the discovery, mechanism of action, pharmacological activities, and development of SMTP.

Drug-release system of microchannel transport used in minimally invasive surgery for hemostasis.

BACKGROUND: Sucrose allyl ether (SAE) containing hemostatic drugs and a photoinitiator was established to treat mild postpartum hemorrhage or long-term continuous abnormal uterine bleeding in minimally invasive surgery (MIS) using a photopolymerization method. METHODS AND RESULTS: Real-time infrared spectroscopy and rheological experiments showed that the SAE monomer with shear-thinning characteristics could polymerize rapidly into a transparent membrane. Cytotoxicity experiments in vitro showed that this system could elicit a long-term hemostatic effect. Tissue adhesion was also evaluated. The photo-stability of four delivered antifibrinolytic drugs (6-aminocaproic acid, ethylenediaminediacetic acid, tranexamic acid and p-(aminomethyl) benzoic acid) was tested by ultraviolet-photolysis experiments and illustrated by time-dependent density functional theory. Sustained-release experiments revealed that the formed film could be used as a drug carrier. Molecular docking and molecular dynamics were done to investigate the binding mechanism between hemostatic drugs as ligands and the human plasminogen kringle-1 (1HPK) as a target. CONCLUSION: It has been suggested that SAE with tranexamic acid could be a drug-release system of microchannel transport used in MIS. This system could tackle the dilemma of fluidity and adhesion in MIS. The photo-stable tranexamic acid was the most suitable drug according to its satisfactory binding energy, good photo-stability, and sustained release.

Tranexamic acid mediates proinflammatory and anti-inflammatory signaling via complement C5a regulation in a plasminogen activator-dependent manner.

BACKGROUND: Both tissue plasminogen activator (tPA) in the circulation and urokinase (uPA) in tissues cleave plasminogen (PLG) to plasmin to promote clot lysis. Tranexamic acid (TXA) blocks both the tPA-dependent generation of plasmin on blood clots as well as active plasmin binding to polymerized fibrin, and is commonly administered for bleeding in trauma to limit fibrinolysis. In addition to lysing clots, however, active plasmin also cleaves complement proteins, potentially enhancing inflammation. Because TXA does not block uPA-dependent plasmin generation from PLG and instead augments it, we hypothesized that administration of TXA could enhance or inhibit proinflammatory C5a formation in a PLG activator-dependent manner. METHODS: Citrate platelet-poor plasma (PPP) and PPP depleted of complement protein C3 or PLG were obtained from healthy donors and commercial sources. Platelet-poor plasma was treated ex vivo with or without TXA and either with or without tPA or with or without uPA. Clotting was then induced by calcium and thrombin in clotted PPP experiments, while unclotted PPP experiments were treated with vehicle controls. C5a levels were measured via enzyme-linked immunosorbent assay. Data were expressed as mean ± SEM. RESULTS: Plasmin-mediated fibrinolysis by tPA in clotted PPP led to an approximately threefold increase in C5a production (p < 0.0001), which was significantly inhibited by TXA (p < 0.001). Paradoxically, when fibrinolysis was induced by uPA, TXA treatment led to further increases in C5a production beyond uPA alone (p < 0.0001). Furthermore, clotting was not required for C5a generation from uPA + TXA. C3 depletion had no effect on C5a production, while depletion of PLG eliminated it. CONCLUSIONS: Tranexamic acid administration can have proinflammatory or anti-inflammatory effects through regulating C5a generation by plasmin, depending on the predominating PLG activator. Tranexamic acid may cause significant inflammatory C5a elevations in injured tissues by augmenting uPA-mediated plasmin generation in a fibrin-independent manner. In contrast, TXA reduces C5a generation during tPA-mediated fibrinolysis that may reduce inflammatory responses. In vivo validation of these novel ex vivo findings is warranted and may have important clinical consequences.

SmSP2: A serine protease secreted by the blood fluke pathogen Schistosoma mansoni with anti-hemostatic properties.

BACKGROUND: Serine proteases are important virulence factors for many pathogens. Recently, we discovered a group of trypsin-like serine proteases with domain organization unique to flatworm parasites and containing a thrombospondin type 1 repeat (TSR-1). These proteases are recognized as antigens during host infection and may prove useful as anthelminthic vaccines, however their molecular characteristics are under-studied. Here, we characterize the structural and proteolytic attributes of serine protease 2 (SmSP2) from Schistosoma mansoni, one of the major species responsible for the tropical infectious disease, schistosomiasis. METHODOLOGY/PRINCIPAL FINDINGS: SmSP2 comprises three domains: a histidine stretch, TSR-1 and a serine protease domain. The cleavage specificity of recombinant SmSP2 was determined using positional scanning and multiplex combinatorial libraries and the determinants of specificity were identified with 3D homology models, demonstrating a trypsin-like endopeptidase mode of action. SmSP2 displayed restricted proteolysis on protein substrates. It activated tissue plasminogen activator and plasminogen as key components of the fibrinolytic system, and released the vasoregulatory peptide, kinin, from kininogen. SmSP2 was detected in the surface tegument, esophageal glands and reproductive organs of the adult parasite by immunofluorescence microscopy, and in the excretory/secretory products by immunoblotting. CONCLUSIONS/SIGNIFICANCE: The data suggest that SmSP2 is secreted, functions at the host-parasite interface and contributes to the survival of the parasite by manipulating host vasodilatation and fibrinolysis. SmSP2 may be, therefore, a potential target for anti-schistosomal therapy.

Novel Thrombolytic Drug Based on Thrombin Cleavable Microplasminogen Coupled to a Single-Chain Antibody Specific for Activated GPIIb/IIIa.

BACKGROUND: Thrombolytic therapy for acute thrombosis is limited by life-threatening side effects such as major bleeding and neurotoxicity. New treatment options with enhanced fibrinolytic potential are therefore required. Here, we report the development of a new thrombolytic molecule that exploits key features of thrombosis. We designed a recombinant microplasminogen modified to be activated by the prothrombotic serine-protease thrombin (HtPlg), fused to an activation-specific anti-glycoprotein IIb/IIIa single-chain antibody (SCE5), thereby hijacking the coagulation system to initiate thrombolysis. METHODS AND RESULTS: The resulting fusion protein named SCE5-HtPlg shows in vitro targeting towards the highly abundant activated form of the fibrinogen receptor glycoprotein IIb/IIIa expressed on activated human platelets. Following thrombin formation, SCE5-HtPlg is activated to contain active microplasmin. We evaluate the effectiveness of our targeted thrombolytic construct in two models of thromboembolic disease. Administration of SCE5-HtPlg (4 µg/g body weight) resulted in effective thrombolysis 20 minutes after injection in a ferric chloride-induced model of mesenteric thrombosis (48±3% versus 92±5% for saline control, P<0.01) and also reduced emboli formation in a model of pulmonary embolism (P<0.01 versus saline). Furthermore, at these effective therapeutic doses, the SCE5-HtPlg did not prolong bleeding time compared with saline (P=0.99). CONCLUSIONS: Our novel fusion molecule is a potent and effective treatment for thrombosis that enables in vivo thrombolysis without bleeding time prolongation. The activation of this construct by thrombin generated within the clot itself rather than by a plasminogen activator, which needs to be delivered systemically, provides a novel targeted approach to improve thrombolysis.

Tissue-type plasminogen activator-mediated plasminogen activation and contact activation, implications in and beyond haemostasis.

Due to its discovery as initiator of fibrinolysis and its well-studied activation by fibrin, tissue-type plasminogen activator (tPA) and the fibrinolytic system are generally associated with the dissolution of blood clots. However, it has been demonstrated over the years that (i) tPA can be activated by multiple proteins, (ii) plasmin has many substrates other than fibrin and (iii) tPA and plasmin have biological functions independent of fibrin and distinct from their role in blood clot lysis. We here review the data with respect to the activation of tPA by fibrin and its multiple other cofactors, in relation to tPA's role in pathophysiology, notably fibrinolysis and amyloidosis, with emphasis on Alzheimer's disease. We demonstrate a common structural element, termed cross-ß structure, in misfolded proteins that is causal to tPA activation. The implications for protein misfolding diseases that are known to be associated with the deposition of amyloid and for diseases for which this has not (yet) been established are discussed.

The effect of the fibrinolytic enzyme FIIa from Agkistrodon acutus venom on acute pulmonary thromboembolism.

AIM: To evaluate the effects of the fibrinolytic enzyme FII(a) from Agkistrodon acutus venom on acute pulmonary thromboembolism (APT) in animal models. METHODS: Both rabbit and dog APT models were used. For the rabbit APT model, the thrombi weight before and after administration was measured. Central venous pressure (CVP) and mean arterial pressure (MAP) were measured before and 15, 30, 60, and 120 min after the injection of the blood clot. Partial thromboplastin time (APTT), prothrombin time (PT), platelet count, and fibrinogen concentration were measured using auto analyzers. Plasminogen activity was measured based on chromogenic substrates. In the dog APT model, pulmonary blood flow was recorded using pulmonary angiography. RESULTS: Intravenous administration of FIIa (0.1-5.0 mg/kg) improved the APT-induced hemodynamic derangements and reduced thrombi weight. The angiography evidence also showed that the pulmonary emboli had almost disappeared after FII(a) infusion. FII(a) (0.1, 0.5, or 1.0 mg/kg) did not impair the coagulation pathways, although very high doses of FII(a) (5.0 mg/kg) could stimulate the production of plasminogen and result in impairment of the pathways. CONCLUSION: FII(a) could effectively protect against APT via degradation of thrombi with less activation of plasminogen, and may provide a novel fibrinolytic enzyme for targeting the main pathological processes of the disease.

Mechanism of the synergistic effect between oversulfated chondroitin-6-sulfate and lysine or 6-aminohexanoic acid in enhancing the in-vitro activation of glutamic plasminogen by tissue plasminogen activator or urokinase.

Earlier studies of addition of naturally sulfated polysaccharides including unfractionated heparin showed a significant enhancement of the in-vitro activation of glutamic plasminogen (Glu-Plg) by tissue plasminogen activator (t-PA) or urokinase plasminogen activator (u-PA). However, supplementing of physiological concentration of NaCl (0.9%) to the buffer reversed the enhancement. To overcome this reversal attempts were made to oversulfate the compounds and re-evaluate their biological properties. Chondroitin-6-sulfate (N-2) was oversulfated using chlorosulfonic acid-pyridine complex and isolated as the sodium salt. Infrared and H-NMR studies of the oversulfated compound showed introduction of new sulfate groups with the formation of 60% of chondroitin-4-6-disulfate. In-vitro studies were conducted on comparing the effect of oversulfated chondroitin-6-sulfate (S-2) with native compound (N-2) and unfractionated heparin in enhancing the activation of Glu-Plg by t-PA or u-PA using 0.05 mol/l Tris buffer (pH 7.3) containing 0.9% of NaCl. The enhancement of activation of Glu-Plg by t-PA or u-PA was measured by formation of plasmin using H-D-Glu-Phe-Lys-pNA (S-2403) as the substrate. The activation by t-PA was enhanced two-fold by 2.86 microg/ml of S-2, 4-6-fold by addition of 32.4 mmol/l of lysine or 5.4 mmol/l of 6-aminohexanoic acid (6-AH) and 14-16-fold enhancement by addition of both S-2 and lysine or S-2 and 6-AH showing a synergistic effect, whereas unfractionated heparin alone gave no enhancement and in conjunction with lysine or 6-AH gave no additional enhancement. Similar studies using u-PA in place of t-PA gave identical results. During the activation of Glu-Plg to plasmin, lysine plasminogen (Lys-Plg) is reported to be an intermediate. Therefore we investigated the role of S-2, lysine and 6-AH in the activation of Lys-Plg to plasmin. The results showed that S-2 enhanced this activation, whereas lysine or 6-AH which were active in enhancing the activation of Glu-Plg were not active using Lys-Plg indicating that the site of enhancement by lysine or 6-AH was during the initial phase. Double reciprocal plot of Glu-Plg activation by t-PA with or without S-2 and lysine showed no change in Km but a 10-fold increase of Kcat suggesting a template mechanism for the attenuation when both cofactors are used.

Effect of epsilon-aminocaproyl-S-benzyl-L-cysteine on the activity of plasminogen activators.

The effect of epsilon-aminocaproyl-S-benzyl-L-cysteine on the activation of plasminogen by t-PA. streptokinase and urokinase has been examined using fibrinolytic method. The obtained results have been compared with the obtained results for epsilon-aminocaproic acid and trans-4-(aminomethyl)cyclohexanecarboxylic acid. The inhibition of the plasminogen activation determined with the use of epsilon-aminocaproyl-S-benzyl-L-cysteine was weaker than the inhibition determined by using antifibrinolytic aminoacids.

Two coagulation factor X activators from Vipera a. ammodytes venom with potential to treat patients with dysfunctional factors IXa or VIIa.

Two activators of coagulation factor X, 58kDa VAFXA-I and 70kDa VAFXA-II, were purified from the venom of long-nosed viper (Vipera ammodytes ammodytes) by chromatography on gel filtration, affinity, ion-exchange and hydroxyapatite media. Both enzymes are glycoproteins composed of a heavy chain and two C-type lectin-like light chains all joined by disulphide bonds. LC-MS and LC-MS/MS analysis of their tryptic fragments demonstrated that the heavy chain consists of three domains, metalloproteinase, disintegrin-like and cysteine-rich domains. The partial amino acid sequences of VAFXAs are very similar to those of the known factor X activators, RVV-X from Vipera russelli and VLFXA from Vipera lebetina venoms, as well as to other members of the reprolysin family of metalloproteinases. The VAFXAs activate factor X in a Ca(2+)-dependent manner with the same specificity as physiological activators. The activators weakly hydrolyzed insulin B-chain, fibrinogen and some components of the extracellular matrix in vitro, but did not activate prothrombin or plasminogen. VAFXAs inhibit collagen-induced platelet aggregation in vitro. They activate coagulation factor X to Xa without toxic effects. Their application in treating patients with dysfunctional factors IXa or VIIa to restore the normal blood coagulation process is thus promising.

Effect of oversulfation on the chemical and biological properties of chondroitin-4-sulfate.

Chondroitin-4-sulfate was oversulfated using chlorosulfonic acid-pyridine complex and was isolated as the sodium salt. A comparison of the infrared analysis of the native (N-2) and oversulfated (S-2) compounds showed that the two spectra were identical except for a new peak in S-2 at 825 cm corresponding to the equatorial C-6 position of galactosamine. There was a 2.7-fold increase of sulfate content in S-2 and a generation of a significant anticoagulant activity as measured by doubling of the prothrombin time of normal citrated human plasma using 7.5 microg, while N-2 was inactive even at 2,000 microg. The result of the in-vitro studies of the activation of glutamic plasminogen by tissue plasminogen activator (t-PA) or by high-molecular-weight urokinase using 0.05 mol/l Tris buffer (pH 7.35) containing a physiological concentration of NaCl (0.9%) showed that 28.6 microg/ml S-2 enhanced the activation by three-fold to four-fold by t-PA or by urokinase, while the same concentrations of N-2 or unfractionated heparin gave less than 30% enhancement of t-PA and no enhancement of urokinase. The mechanism of enhancement by S-2 was investigated by dilution studies. The results showed that S-2 interacted with both urokinase or t-PA and glutamic plasminogen favoring a template model, while N-2 or unfractionated heparin interacted only with t-PA.

Effect of oversulfated chondroitin-6-sulfate or oversulfated fucoidan in the activation of glutamic plasminogen by tissue plasminogen activator: role of lysine and cyanogen bromide-fibrinogen.

Fucoidan and chondroitin-6-sulfate were oversulfated using chlorosulfonic acid-pyridine complex and were isolated as the sodium salt. Infrared analysis of oversulfated compounds showed introduction of sulfate groups in new positions, and in-vitro studies of the compounds showed a significant increase in the anticoagulant property. Addition of 28.6 microg/ml oversulfated compound gave a two-fold to four-fold increase in the rate of enhancement of activation of glutamic plasminogen by tissue plasminogen activator using 0.05 mol/l Tris buffer (pH 7.35) containing physiological concentrations of NaCl (0.9%). Under these conditions, unfractionated heparin was not active and the native compounds gave less than 30% enhancement. In the present study, the effect of lysine or cyanogen bromide-treated fibrinogen, alone or in combination with the oversulfated compounds, on the activation of glutamic plasminogen by tissue plasminogen activator was investigated. Addition of 16.2 mmol/l L-lysine gave three-fold to four-fold enhancement of activation, which was further enhanced to five-fold to six-fold by addition of 2.86 microg/ml oversulfated chondroitin-6-sulfate or oversulfated fucoidan. Cyanogen bromide-treated fibrinogen (50 microg/ml) gave a 10-fold enhancement of activation by itself, and addition of 2.86 microg/ml oversulfated compounds amplified this to 15-fold. A 25-fold to 35-fold enhancement of activation of glutamic plasminogen was obtained when 2.86 microg/ml oversulfated compounds were combined with 16.2 mmol/l lysine and 50 microg/ml cyanogen bromide-treated fibrinogen. Dilution studies showed that the amplification of the enhancement of lysine by 2.86 microg/ml oversulfated compound was related to interaction of the cofactors with both glutamic plasminogen and tissue plasminogen activator.

Antithrombin activity is inhibited by acrolein and homocysteine thiolactone: Protection by cysteine.

Conditions in which serum or tissue acrolein levels are high (e.g.: renal failure, heavy smoking, oxidative stress) are also associated with increased thrombogenicity. Another emerging cardiovascular risk factor is homocysteine, and its derivative, homocysteine thiolactone. Antithrombin is one of the most important inhibitors of blood coagulation Since its activation by heparin binding requires critical interactions involving 3 Lys residues; we hypothesized that acrolein or homocysteine thiolactone impair antithrombin activity. When we incubated human antithrombin with increasing concentrations of acrolein (0-2 mmol/L) over a short period of time (0-4 h), a time and concentration dependent loss of activity was apparent (IC(50)=0.25 mmol/L). At 2 mmol/L, maximum inhibition (60%) is achieved at 1 h. This loss of activity was mirrored by changes in the electrophoretic pattern (homogeneity of the native antithrombin band as well as polymerization). In the same conditions, homocysteine thiolactone produces a significant, yet far less pronounced effect; acrolein being 3 times more potent than homocysteine thiolactone. When antithrombin was co-incubated with acrolein and cysteine, only less than 10% of antithrombin activity was lost. Aminoguanidine or carnosine displayed a significant yet, minor protective effect. The results suggest that in conditions where circulating or local acrolein concentrations are increased (atheroma plaque, thrombosis, sites of lipoperoxidation, smokers), acrolein-mediated loss of antithrombin activity could be a plausible phenomenon. This could contribute to explain increased thrombogenicity in smokers and in other conditions, as well as pointing at dietary intervention or the use of thiol-conserving reducing compounds as putative coadjuvant therapeutic measures.

C1-inhibitor prevents non-specific plasminogen activation by a prourokinase mutant without impeding fibrin-specific fibrinolysis.

BACKGROUND: Prourokinase (prouPA) is unstable in plasma at therapeutic concentrations. A mutant form, M5, made more stable by reducing its intrinsic activity was therefore developed. Activation to two-chain M5 (tcM5) induced a higher catalytic activity than two-chain urokinase plasminogen activator (tcuPA), implicating an active site functional difference. Consistent with this, an unusual tcM5 complex with plasma C1-inhibitor was recently described in dog and human plasma. The effect of C1-inhibitor on fibrinolysis and fibrinogenolysis by M5 is the subject of this study. METHODS AND RESULTS: Zymograms of tcM5 and tcuPA incubated in plasma revealed prominent tcM5-C1-inhibitor complexes, which formed within 5 min. The inhibition rate by purified human C1-inhibitor (250 microg mL(-1)) was about 7-fold faster for tcM5 than it was for tcuPA (10 microg mL(-1)). The effect of the inhibitor on the stability of M5 and prouPA was determined by incubating them in plasma at high concentrations (10-20 microg mL(-1)) +/- C1-inhibitor supplementation. Above 10 microg mL(-1), depletion of all plasma plasminogen occurred, indicating plasmin generation and tcM5/tcuPA formation. With supplemental C1-inhibitor, M5 stability was restored but not prouPA stability. Clot lysis by M5 +/- supplemental C1-inhibitor showed no attenuation of the rate of fibrinolysis, whereas fibrinogenolysis was prevented by C1-inhibitor. Moreover, because of higher dose-tolerance, the rate of fibrin-specific lysis reached that achievable by non-specific fibrinolysis without inhibitor. CONCLUSIONS: Plasma C1-inhibitor stabilized M5 in its proenzyme configuration in plasma by inhibiting tcM5 and thereby non-specific plasminogen activation. At the same time, fibrin-specific plasminogen activation remained unimpaired. This unusual dissociation of effects has significant implications for improving the safety and efficacy of fibrinolysis.

Plasminogen activation by fibroblasts from periodontal ligament and gingiva is not directly affected by chemokines in vitro.

OBJECTIVE: Chronic inflammation in periodontal disease is associated with increased plasminogen activation and elevated levels of chemokines. It is unknown whether chemokines can regulate the activation of plasminogen via modulation of plasminogen activators (PA) and the corresponding plasminogen activator inhibitors (PAI) in periodontal tissue. DESIGN: To establish a link between chemokines and activation of plasminogen, human periodontal ligament fibroblasts (PDL) and gingival fibroblasts (GF) were incubated with IL-8, monocyte chemoattractant protein-1, macrophage inflammatory protein-1alpha, and platelet factor-4, either alone or in the presence of the inflammatory mediators TGF-beta and IL-1. The potential of the cell lysates to activate plasminogen was based on kinetic studies with the substrate casein. Casein zymography was performed to determine the molecular sizes of the PA. Total PAI-1 in the cell-conditioned medium was quantified by immunoassay. RESULTS: We report that the chemokines did not affect activation of plasminogen by PDL and GF. Even in the presence of TGF-beta which suppressed, and IL-1 which stimulated plasminogen activation, the chemokines had no direct effect. Inhibition of PA and plasmin, but not of matrix metalloproteinases and cysteine proteinases prevented caseinolysis. The plasminogen activation capacity of the cell lysates was represented by a single band with features of uPA. The immunoassay showed that the release of PAI-1 in PDL and GF remained unaffected by the chemokines, also when stimulated with TGF-beta. CONCLUSIONS: These results suggest that plasminogen activation by PDL and GF is not directly affected by the chemokines even in the presence of the inflammatory mediators TGF-beta and IL-1.

Effects of a protease inhibitor, ulinastatin, on coagulation and fibrinolysis in abdominal surgery.

PURPOSE: Ulinastatin is well known to inhibit the activity of polymorphonuclear leukocyte elastase (PMNE). The PMNE concentration correlates with the activities of coagulation and fibrinolysis. The purpose of the present study was to investigate the effects of ulinastatin, a protease inhibitor, on coagulation and fibrinolysis in abdominal surgery. METHODS: Thirty patients, aged 40 to 70 years, with American Society of Anesthesiologists (ASA) physical status I or II, scheduled for major abdominal surgery, were enrolled. Anesthesia was induced with midazolam and thiopental, and was maintained with sevoflurane, nitrous oxide in oxygen, and an epidural block. An infusion of ulinastatin, 6000 units x kg(-1) in 30 min, was started 1 h after the start of surgery in the ulinastatin group (15 patients). In the control group (15 patients), no protease inhibitors were infused. White blood cell count; platelet count; prothrombin time; activated partial thromboplastin time; and plasma concentrations of PMNE, antithrombin (AT), fibrin/fibrinogen degradation product (FDP), fibrinogen, plasminogen, plasmin-(alpha2) plasmin inhibitor complex (PIC), and thrombin-antithrombin complex (TAT) were measured before, at the end of, and 12 h after surgery. RESULTS: TAT, PIC, and FDP after surgery were significantly lower in the ulinastatin group than in the control group. AT was decreased in the control group but not in the ulinastatin group, with significant differences between the two groups. CONCLUSION: Ulinastatin could inhibit coagulation and fibrinolysis in abdominal surgery.

Heparin modulation of human plasma kallikrein on different substrates and inhibitors.

The interplay of different proteases and glycosaminoglycans is able to modulate the activity of the enzymes and to affect their structures. Human plasma kallikrein (huPK) is a proteolytic enzyme involved in intrinsic blood clotting, the kallikrein-kinin system and fibrinolysis. We investigated the effect of heparin on the action, inhibition and secondary structure of huPK. The catalytic efficiency for the hydrolysis of substrates by huPK was determined by Michaelis-Menten kinetic plots: 5.12x10(4) M-1 s-1 for acetyl-Phe-Arg-p-nitroanilide, 1.40x10(5) M-1 s-1 for H-D-Pro-Phe-Arg-p-nitroanilide, 2.25x10(4) M-1 s-1 for Abz-Gly-Phe-Ser-Pro-Phe-Arg-Ser-Ser-Arg-Gln-EDDnp, 4.24x10(2)M-1 s-1 for factor XII and 5.58x10(2) M-1 s-1 for plasminogen. Heparin reduced the hydrolysis of synthetic substrates (by 2.0-fold), but enhanced factor XII and plasminogen hydrolysis (7.7- and 1.4-fold, respectively). The second-order rate constants for inhibition of huPK by antithrombin and C1-inhibitor were 2.40x10(2) M-1 s-1 and 1.70x10(4) M-1 s-1, respectively. Heparin improved the inhibition of huPK by these inhibitors (3.4- and 1.4-fold). Despite the fact that huPK was able to bind to a heparin-Sepharose matrix, its secondary structure was not modified by heparin, as monitored by circular dichroism. These actions may have a function in the control or maintenance of some pathophysiological processes in which huPK participates.

[Staphylokinase--a specific plasminogen activator]. / Stafylokinaza--selektywny aktywator plazminogenu.

Staphylokinase is a 135 amino acid protein produced by certain strains of Staphylococcus aureus. It belongs to fibrin-specific plasminogen activator. Staphylokinase converts plasminogen--the inactive proenzyme--to the plasmin, which dissolves the fibrin of a blood clots. This review will focus on the biochemical and thrombolytic properties of staphylokinase and its derivatives, which would make use of treatment in acute myocardial infarction and other cardiovascular diseases.