Comparative Assessment of the Proteolytic Stability and Impact of Poly-Arginine Peptides R18 and R18D on Infarct Growth and Penumbral Tissue Preservation Following Middle Cerebral Artery Occlusion in the Sprague Dawley Rat.

Poly-arginine peptides R18 and R18D have previously been demonstrated to be neuroprotective in ischaemic stroke models. Here we examined the proteolytic stability and efficacy of R18 and R18D in reducing infarct core growth and preserving the ischaemic penumbra following middle cerebral artery occlusion (MCAO) in the Sprague Dawley rat. R18 (300 or 1000 nmol/kg), R18D (300 nmol/kg) or saline were administered intravenously 10 min after MCAO induced using a filament. Serial perfusion and diffusion-weighted MRI imaging was performed to measure changes in the infarct core and penumbra from time points between 45- and 225-min post-occlusion. Repeated measures analyses of infarct growth and penumbral tissue size were evaluated using generalised linear mixed models (GLMMs). R18D (300 nmol/kg) was most effective in slowing infarct core growth (46.8 mm3 reduction; p < 0.001) and preserving penumbral tissue (21.6% increase; p < 0.001), followed by R18 at the 300 nmol/kg dose (core: 29.5 mm3 reduction; p < 0.001, penumbra: 12.5% increase; p < 0.001). R18 at the 1000 nmol/kg dose had a significant impact in slowing core growth (19.5 mm3 reduction; p = 0.026), but only a modest impact on penumbral preservation (6.9% increase; p = 0.062). The in vitro anti-excitotoxic neuroprotective efficacy of R18D was also demonstrated to be unaffected when preincubated for 1-3 h or overnight, in a cell lysate prepared from dying neurons or with the proteolytic enzyme, plasmin, whereas the neuroprotective efficacy of R18 was significantly reduced after a 2-h incubation. These findings highlight the capacity of poly-arginine peptides to reduce infarct growth and preserve the ischaemic penumbra, and confirm the superior efficacy and proteolytic stability of R18D, which indicates that this peptide is likely to retain its neuroprotective properties when co-administered with alteplase during thrombolysis for acute ischaemic stroke.

Computational simulations assessment of mutations impact on streptokinase (SK) from a group G streptococci with enhanced activity - insights into the functional roles of structural dynamics flexibility of SK and stabilization of SK-µplasmin catalytic complex.

Streptokinase (SK), a plasminogen activator (PA) that converts inactive plasminogen (Pg) to plasmin (Pm), is a protein secreted by groups A, C, and G streptococci (GAS, GCS, and GGS, respectively), with high sequence divergence and functional heterogeneity. While roles of some residual changes in altered SK functionality are shown, the underlying structural mechanisms are less known. Herein, using computational approaches, we analyzed the conformational basis for the increased activity of SK from a GGS (SKG132) isolate with four natural residual substitutions (Ile33Phe, Arg45Gln, Asn228Lys, Phe287Ile) compared to the standard GCS (SKC). Using the crystal structure of SK.Pm catalytic complex as main template SKC.µPm catalytic complex was modeled through homology modeling process and validated by several online validation servers. Subsequently, SKG132.µPm structure was constructed by altering the corresponding residual substitutions. Results of three independent MD simulations showed increased RMSF values for SKG132.µPm, indicating the enhanced structural flexibility compared to SKC.µPm, specially in 170 and 250 loops and three regions: R1 (149-161), R2 (182-215) and R3 (224-229). In parallel, the average number of Hydrogen bonds in 170 loop, R2 and R3 (especially for Asn228Lys) of SKG132 compared to that of the SKC was decreased. Accordingly, residue interaction networks (RINs) analyses indicated that Asn228Lys might induce more level of structural flexibility by generation of free Lys256, while Phe287Ile and Ile33Phe enhanced the stabilization of the SKG132.µPm catalytic complex. These results denoted the potential role of the optimal dynamic state and stabilized catalytic complex for increased PA potencies of SK as a thrombolytic drug.

Assessment of Selected ROTEM Parameters, Kinetics of Fibrinogen Polymerization and Plasmin Amidolytic Activity in Patients with Congenital Fibrinogen Defects.

BACKGROUND: Congenital fibrinogen disorders (CFD) are rare fibrinogen deficiencies which may be quantitative or functional. The clinical course of hypofibrinogenemia (hypoFI) or dysfibrinogenemia (dysFI) is unpredictable and cannot be determined by the application of standard hemostasis tests. OBJECTIVES: The main aim of this study was to assess ROTEM parameters in CFD patients. MATERIAL AND METHODS: Nine patients with CFD were studied. The fibrinogen concentration was measured functionally and antigenically. EXTEM, INTEM, FIBTEM and APTEM tests were used to measure selected ROTEM parameters, including maximum clot firmness (MCF). Fibrin plasma polymerization, clot lysis and plasmin amidolytic activity were determined by spectrophotometric methods. RESULTS: Incorporating the antigenic, ELISA method, to the diagnostic workup allowed the initial diagnosis to be switched from hypoFI to dysFI in 3/7 patients. MCF readings (the most important parameter describing fibrin polymerization capacity) were significantly lower in patients than in controls according to all ROTEM tests. Cases with hypoFI demonstrated markedly lower readings of MCF according to all ROTEM tests than cases with dysFI. All patients demonstrated disturbances of fibrin polymerization process assessed by turbidimetry. In contrast, no marked differences were identified between studied groups in reference to plasmin amidolytic activity. CONCLUSIONS: Our data suggests that ROTEM and fibrin plasma polymerization according to the turbidimetric method have a high sensitivity towards detection of different CFD. Although ROTEM MCF assessment may help discriminate patients with hypoor dysfibrinogenemia, this finding has to be confirmed on larger groups of patients.

Treatment of episodes of hereditary angioedema with C1 inhibitor: serial assessment of observed abnormalities of the plasma bradykinin-forming pathway and fibrinolysis.

BACKGROUND: Hereditary angioedema (HAE) is typically the result of a deficiency of C1 inhibitor (C1-INH) with gene defects that lead to diminished plasma levels or the production of a dysfunctional protein. Replacement therapy with C1-INH has been shown to be effective in ameliorating episodes of swelling. We have reported elevated baseline levels of bradykinin, C4a, and plasmin-alpha2-antiplasmin complexes in the plasma of patients with HAE compared with the plasma of healthy controls. The production of factor XII fragment on in vitro activation of plasma with HAE has also been observed. OBJECTIVE: To perform serial assessment of abnormalities of the bradykinin-forming pathway and fibrinolysis in patients with HAE after treatment of episodes of swelling with intravenous C1-INH. METHODS: We obtained samples of plasma from 9 patients with HAE at a quiescent period (baseline), during an attack of swelling, and at 1, 4, and 12 hours after termination of an infusion of C1-INH. Factor XIIa, kallikrein, and plasmin were each measured by cleavage of synthetic substrates specific for each item. RESULTS: Each enzyme was strikingly elevated at baseline compared with the levels in pooled healthy plasma, and there was a progressive decline of activity to normal for factor XIIa and plasmin. Kallikrein decreased in 7 of the 9 patients at 1 hour and then decreased in all patients. Bradykinin levels were elevated at the outset in all patients, increased prominently during an attack of swelling, decreased to baseline after 1 hour, and then decreased toward normal by 4 and 12 hours. CONCLUSION: The plasma levels of factor XIIa, kallikrein, and bradykinin decreased when measured serially subsequent to the infusion of nanofiltered C1-INH.

Assessment of the relative contribution of different protease inhibitors to the inhibition of plasmin in vivo.

It has been shown that the most important inhibitor of plasmin is alpha 2-antiplasmin, however, other protease inhibitors are able to inhibit this proteolytic enzyme as well. The contribution of the various protease inhibitors to the inhibition of plasmin in vivo has never been quantitatively assessed. To assess the relative contribution of the different protease inhibitors on the inhibition of plasmin we developed a series of sensitive immunoassays for the detection of complexes between plasmin and the protease inhibitors alpha 2-antiplasmin, alpha 2-macroglobulin, antithrombin III, alpha 1-antitrypsin and C1-inhibitor, utilizing monoclonal antibodies that are specifically directed against complexed protease inhibitors and a monoclonal antibody against plasmin. It was confirmed that alpha 2-antiplasmin is the most important inhibitor of plasmin in vivo, however, complexes of plasmin with alpha 2-macroglobulin, antithrombin III, alpha 1-antitrypsin- and C1-inhibitor were also detected. Particularly during activation of fibrinolysis complexes between plasmin and inhibitors other than alpha 2-antiplasmin were detected. It was observed that during different situations the inhibition profile of plasmin was not constant e.g. in patients with diffuse intravascular coagulation plasma levels of plasmin-alpha 1-antitrypsin and plasmin-C1-inhibitor were increased whereas in plasma from patients who were treated with thrombolytic agents complexes of plasmin with alpha 2-macroglobulin and with antithrombin III were significantly elevated. In conclusion, we confirmed the important role of alpha 2-antiplasmin in the inhibition of plasmin, however, in situations in which fibrinolysis is activated other protease inhibitors also account for the inhibition of plasmin in vivo.(ABSTRACT TRUNCATED AT 250 WORDS)

Different assessment of plasmin with different substrates. In vitro alteration of plasmin, influence of epsilon-aminocaproic acid and tranexamic acid upon its activity.

The alteration of human and porcine plasmin and the influence of EACA and AMCHA on their activity were investigated. Solutions of both plasmins undergo storage induced alteration, which is best recorded by Chromozym PL, whereas the other chromogenic substrates, S-2251 and S-2302, and casein are less sensitive, and the fibrin plate inadequate. Plasmin amidolytic and fibrinolytic activity is maximally enhanced at 7.6 x 10(-3) M EACA and 6.4 x 10(-4) M AMCHA, and decay through storage is reversed. The caseinolytic activity seems slightly inhibited at the same EACA and AMCHA concentrations. Our results show: 1. The quotient: plasmin activity towards Chromozym PL/Activity towards S-2251 is a useful indicator of "plasmin quality". The quotient decreases markedly upon storage of plasmin solutions. 2. Plasmin stability is improved in the presence of AMCHA. 3. It is valueless to add EACA or AMCHA to inhibit plasmin in amidolytic assays since the chosen concentration enhances the amidolytic activity of already formed plasmin.