Your search keyword '"Plasminogen chemistry"' showing total 39 results

1. C-terminal lysine residues enhance plasminogen activation by inducing conformational flexibility and stabilization of activator complex of staphylokinase with plasmin.

Author

Kaur P, Sethi D, Hade MD, Kaur J, and Dikshit KL

Subjects

Plasminogen chemistry, Plasminogen Activators chemistry, Fibrinolysin chemistry, Lysine

Abstract

Staphylokinase (SAK), a potent fibrin-specific plasminogen activator secreted by Staphylococcus aureus, carries a pair of lysine at the carboxy-terminus that play a key role in plasminogen activation. The underlaying mechanism by which C-terminal lysins of SAK modulate its function remains unknown. This study has been undertaken to unravel role of C-terminal lysins of SAK in plasminogen activation. While deletion of C-terminal lysins (Lys135, Lys136) drastically impaired plasminogen activation by SAK, addition of lysins enhanced its catalytic activity 2-2.5-fold. Circular dichroism analysis revealed that C-terminally modified mutants of SAK carry significant changes in their beta sheets and secondary structure. Structure models and RING (residue interaction network generation) studies indicated that the deletion of lysins has conferred extensive topological alterations in SAK, disrupting vital interactions at the interface of SAK.plasmin complex, thereby leading significant impairment in its functional activity. In contrast, addition of lysins at the C-terminus enhanced its conformational flexibility, creating a stronger coupling at the interface of SAK.plasmin complex and making it more efficient for plasminogen activation. Taken together, these studies provided new insights on the role of C-terminal lysins in establishment of precise intermolecular interactions of SAK with the plasmin for the optimal function of activator complex., Competing Interests: Declaration of competing interest The authors declare that they have no conflicts of interest with the contents of this article., (Copyright © 2023 Elsevier Inc. All rights reserved.)

Published

2023

2. Assessing Plasmin Generation in Health and Disease.

Author

Miszta A, Huskens D, Donkervoort D, Roberts MJM, Wolberg AS, and de Laat B

Subjects

Animals, Antifibrinolytic Agents blood, Fibrin analysis, Fibrin chemistry, Fibrinolytic Agents blood, Humans, Plasminogen analysis, Plasminogen chemistry, Plasminogen metabolism, Blood Chemical Analysis methods, Disease, Fibrinolysin analysis, Fibrinolysin metabolism

Abstract

Fibrinolysis is an important process in hemostasis responsible for dissolving the clot during wound healing. Plasmin is a central enzyme in this process via its capacity to cleave fibrin. The kinetics of plasmin generation (PG) and inhibition during fibrinolysis have been poorly understood until the recent development of assays to quantify these metrics. The assessment of plasmin kinetics allows for the identification of fibrinolytic dysfunction and better understanding of the relationships between abnormal fibrin dissolution and disease pathogenesis. Additionally, direct measurement of the inhibition of PG by antifibrinolytic medications, such as tranexamic acid, can be a useful tool to assess the risks and effectiveness of antifibrinolytic therapy in hemorrhagic diseases. This review provides an overview of available PG assays to directly measure the kinetics of plasmin formation and inhibition in human and mouse plasmas and focuses on their applications in defining the role of plasmin in diseases, including angioedema, hemophilia, rare bleeding disorders, COVID-19, or diet-induced obesity. Moreover, this review introduces the PG assay as a promising clinical and research method to monitor antifibrinolytic medications and screen for genetic or acquired fibrinolytic disorders.

Published

2021

3. Kringles of substrate plasminogen provide a 'catalytic switch' in plasminogen to plasmin turnover by Streptokinase.

Author

Sharma V, Kumar S, and Sahni G

Subjects

Catalysis, Fibrinolysin chemistry, Fluorescence Resonance Energy Transfer methods, Humans, Plasminogen chemistry, Protein Structure, Secondary, Streptokinase chemistry, Substrate Specificity physiology, Catalytic Domain physiology, Fibrinolysin metabolism, Kringles physiology, Plasminogen metabolism, Streptokinase metabolism

Abstract

To understand the role of substrate plasminogen kringles in its differential catalytic processing by the streptokinase - human plasmin (SK-HPN) activator enzyme, Fluorescence Resonance Energy Transfer (FRET) model was generated between the donor labeled activator enzyme and the acceptor labeled substrate plasminogen (for both kringle rich Lys plasminogen - LysPG, and kringle less microplasminogen - µPG as substrates). Different steps of plasminogen to plasmin catalysis i.e. substrate plasminogen docking to scissile peptide bond cleavage, chemical transformation into proteolytically active product, and the decoupling of the nascent product from the SK-HPN activator enzyme were segregated selectively using (1) FRET signal as a proximity sensor to score the interactions between the substrate and the activator during the cycle of catalysis, (2) active site titration studies and (3) kinetics of peptide bond cleavage in the substrate. Remarkably, active site titration studies and the kinetics of peptide bond cleavage have shown that post docking chemical transformation of the substrate into the product is independent of kringles adjacent to the catalytic domain (CD). Stopped-flow based rapid mixing experiments for kringle rich and kringle less substrate plasminogen derivatives under substrate saturating and single cycle turnover conditions have shown that the presence of kringle domains adjacent to the CD in the macromolecular substrate contributes by selectively speeding up the final step, namely the product release/expulsion step of catalysis by the streptokinase-plasmin(ogen) activator enzyme., (© 2020 The Author(s). Published by Portland Press Limited on behalf of the Biochemical Society.)

Published

2020

4. Amorphous protein aggregates stimulate plasminogen activation, leading to release of cytotoxic fragments that are clients for extracellular chaperones.

Author

Constantinescu P, Brown RA, Wyatt AR, Ranson M, and Wilson MR

Subjects

Amino Acid Substitution, Animals, Cell Line, Cell Survival drug effects, Clusterin chemistry, Clusterin metabolism, Conalbumin chemistry, Conalbumin metabolism, Endothelium, Vascular drug effects, Endothelium, Vascular metabolism, Endothelium, Vascular pathology, Endothelium, Vascular ultrastructure, Fibrinolysin antagonists & inhibitors, Fibrinolysin chemistry, Humans, Hydrophobic and Hydrophilic Interactions, Mice, Microglia metabolism, Microglia pathology, Microglia ultrastructure, Mutation, Peptide Fragments chemistry, Peptide Fragments genetics, Peptide Fragments metabolism, Plasminogen chemistry, Plasminogen metabolism, Plasminogen Activators chemistry, Plasminogen Activators genetics, Plasminogen Activators metabolism, Recombinant Proteins chemistry, Recombinant Proteins metabolism, Solubility, Superoxide Dismutase-1 chemistry, Superoxide Dismutase-1 genetics, Superoxide Dismutase-1 metabolism, Tissue Plasminogen Activator chemistry, Fibrinolysin metabolism, Microglia drug effects, Peptide Fragments toxicity, Plasminogen Activators toxicity, Protein Aggregates, Tissue Plasminogen Activator metabolism, alpha-2-Antiplasmin metabolism

Abstract

The misfolding of proteins and their accumulation in extracellular tissue compartments as insoluble amyloid or amorphous protein aggregates are a hallmark feature of many debilitating protein deposition diseases such as Alzheimer's disease, prion diseases, and type II diabetes. The plasminogen activation system is best known as an extracellular fibrinolytic system but was previously reported to also be capable of degrading amyloid fibrils. Here we show that amorphous protein aggregates interact with tissue-type plasminogen activator and plasminogen, via an exposed lysine-dependent mechanism, to efficiently generate plasmin. The insoluble aggregate-bound plasmin is shielded from inhibition by α 2 -antiplasmin and degrades amorphous protein aggregates to release smaller, soluble but relatively hydrophobic fragments of protein (plasmin-generated protein fragments (PGPFs)) that are cytotoxic. In vitro , both endothelial and microglial cells bound and internalized PGPFs before trafficking them to lysosomes. Clusterin and α 2 -macroglobulin bound to PGPFs to significantly ameliorate their toxicity. On the basis of these findings, we hypothesize that, as part of the in vivo extracellular proteostasis system, the plasminogen activation system may work synergistically with extracellular chaperones to safely clear large and otherwise pathological protein aggregates from the body., Competing Interests: The authors declare that they have no conflicts of interest with the contents of this article., (© 2017 by The American Society for Biochemistry and Molecular Biology, Inc.)

Published

2017

5. Effect of fibrin degradation products on fibrinolytic process.

Author

Yatsenko TA, Rybachuk VM, Yusova OI, Kharchenko SM, and Grinenko TV

Subjects

Buffers, Chromatography, Gel, Chromatography, Ion Exchange, Enzyme Activation, Fibrin Fibrinogen Degradation Products chemistry, Fibrinolysis physiology, Humans, Kinetics, Protein Binding, Fibrin chemistry, Fibrin Fibrinogen Degradation Products isolation & purification, Fibrinolysin chemistry, Plasminogen chemistry, Tissue Plasminogen Activator chemistry, alpha-2-Antiplasmin chemistry

Abstract

Fibrin clot lysis by plasminogen/plasmin system results in fibrin degradation products formation with subsequent release into bloodstream. The fragments contain specific binding sites for fibrinolytic system components and can interact with them. In this study, we investigated the way in which fibrin fragments effect fibrinolytic process. We have shown that high molecular weight products of fibrin degradation and fibrin fragments of DDE-complex and DD, but not end product Е3, stimulate plasmin formation. Additionally, components of DDE-complex mixture of fragments Е1 and Е2 have potentiation ability. The intermediate fibrin fragments hmFDPs and DDE attenuate clot lysis by plasmin and hmFDPs protect plasmin from α2-antiplasmin inhibition but under further fragmentation to endpoint fibrin fragments loose this ability. The plasma inhibitors reduce fibrinolytic system activity generated by the degradation products. Thus, fibrin fragments formed during the clot lysis can bind and move out fibrinolytic system components from clot volume and in this way result in clot resistance to hydrolysis.

Published

2016

6. Peroxynitrite and fibrinolytic system-The effects of peroxynitrite on t-PA-induced plasmin activity.

Author

Kolodziejczyk-Czepas J, Ponczek MB, and Nowak P

Subjects

Amino Acid Sequence, Enzyme Activation drug effects, Humans, Models, Molecular, Molecular Sequence Data, Oxidative Stress drug effects, Peroxynitrous Acid chemistry, Peroxynitrous Acid metabolism, Plasminogen chemistry, Plasminogen metabolism, Protein Binding, Protein Conformation, Sequence Alignment, Tyrosine analogs & derivatives, Fibrinolysin metabolism, Fibrinolysis drug effects, Fibrinolysis physiology, Peroxynitrous Acid pharmacology, Tissue Plasminogen Activator metabolism

Abstract

The aim of the present study was the investigation of peroxynitrite (ONOO(-)) effects on fibrinolysis in vitro and in silico. The exposure of human plasminogen to ONOO(-) (10-1000μM) resulted in a decrease of t-PA-induced amidolytic activity of plasmin; the inhibitory effect was associated with the increasing level of 3-nitrotyrosine in plasminogen/plasmin molecule. Furthermore, ONOO(-) displayed both the ability to impair the t-PA-induced activation of plasminogen to plasmin, and to reduce the rate of fibrin lysis by plasmin. The susceptibility of plasminogen in blood plasma to nitrative action of ONOO(-) was revealed by the immunoprecipitation technique. To confirm the hypothesis that 3-nitrotyrosine generation is crucial for the impairment of plasmin activity, (-)-epicatechin, a polyphenolic antioxidant that selectively prevents tyrosine nitration, was used both for in vitro experiments as well as for in silico studies on ONOO(-), ONOOH and (-)-epicatechin binding and plasminogen nitration. (-)-Epicatechin effectively protected plasminogen against ONOO(-)-induced inactivation and significantly reduced the level of 3-nitrotyrosine. The obtained results revealed tyrosine nitration as the most likely mechanism of the inhibitory effect of ONOO(-) on plasmin(ogen) functions. The possible role of tyrosine modifications was additionally confirmed by bioinformatics calculations with indication of nitration susceptible tyrosine residues., (Copyright © 2015 Elsevier B.V. All rights reserved.)

Published

2015

7. Comparative study on the inhibition of plasmin and delta-plasmin via benzamidine derivatives.

Author

Alves NJ and Kline JA

Subjects

Antifibrinolytic Agents chemistry, Benzamidines chemistry, Fibrinolysin chemistry, Fibrinolysin genetics, Humans, Kinetics, Models, Molecular, Mutant Proteins antagonists & inhibitors, Mutant Proteins chemistry, Mutant Proteins genetics, Plasminogen chemistry, Protein Conformation, Protein Structure, Tertiary, Recombinant Proteins chemistry, Recombinant Proteins genetics, Structure-Activity Relationship, Antifibrinolytic Agents pharmacology, Benzamidines pharmacology, Fibrinolysin antagonists & inhibitors

Abstract

The potent fibrinolytic enzyme, plasmin has numerous clinical applications for recannulizing vessels obstructed by thrombus. Despite its diminutive size, 91 kDa, success in the recombinant expression of this serine protease has been limited. For this reason, a truncated non-glycosylated plasmin variant was developed capable of being expressed and purified from E. coli. This mutated plasmin, known as δ-plasmin, eliminates four of the five kringle domains present on native plasmin, retaining only kringle 1 fused directly to the unmodified catalytic domain of plasmin. This study demonstrates that δ-plasmin exhibits similar kinetic characteristics to full length plasmin despite its heavily mutated form; KM = 268.78 ± 19.12, 324.90 ± 8.43 μM and Kcat = 770.48 ± 41.73, 778.21 ± 1.51 1/min for plasmin and δ-plasmin, respectively. A comparative analysis was also carried out to investigate the inhibitory effects of a range of benzamidine based small molecule inhibitors: benzamidine, p-aminobenzamidine, 4-carboxybenzamidine, 4-aminomethyl benzamidine, and pentamidine. All of the small molecule inhibitors, with the exception of unmodified benzamidine, demonstrated comparable competitive inhibition constants (Ki) for both plasmin and δ-plasmin ranging from Ki < 4 μM for pentamidine to Ki > 1000 μM in the case of aminomethyl benzamidine. This result further supports that δ-plasmin retains much of the same functionality as native plasmin despite its greatly reduced size and complexity. This study serves the purpose of demonstrating the tunable inhibition of plasmin and δ-plasmin with potential applications for the improved clinical delivery of δ-plasmin to treat various thrombi., (Copyright © 2015 Elsevier Inc. All rights reserved.)

Published

2015

8. [Structure and functions of plasminogen/plasmin system].

Author

Aĭsina RB and Mukhametova LI

Subjects

Amino Acid Sequence, Angiostatins chemistry, Angiostatins metabolism, Extracellular Matrix chemistry, Extracellular Matrix metabolism, Fibrinolysin antagonists & inhibitors, Fibrinolysin metabolism, Humans, Inflammation genetics, Inflammation metabolism, Neoplasms genetics, Neoplasms metabolism, Neoplasms pathology, Neovascularization, Pathologic metabolism, Plasminogen antagonists & inhibitors, Plasminogen metabolism, Plasminogen Activators antagonists & inhibitors, Plasminogen Activators chemistry, Fibrinolysin chemistry, Fibrinolysis, Neovascularization, Pathologic genetics, Plasminogen chemistry

Abstract

The main physiological function of plasmin is a blood clot fibrinolysis and restore normal blood flow. To date, however, it became apparent that in addition to thrombolysis plasminogen/plasmin system plays an important physiological and pathological role in the degradation of extracellular matrix, embryogenesis, cell migration, tissue remodeling, wound healing, angiogenesis, inflammation and tumor cells migration. This review focuses on the structural features of plasminogen, the regulation of its activation by physiological plasminogen activators, inhibitors of plasmin and plasminogen activators, the role of the plasminogen binding to fibrin, cellular receptors and extracellular ligands in performing various functions by formed plasmin.

Published

2014

9. Characterization of a reduced form of plasma plasminogen as the precursor for angiostatin formation.

Author

Butera D, Wind T, Lay AJ, Beck J, Castellino FJ, and Hogg PJ

Subjects

Allosteric Regulation, Angiostatins chemistry, Cysteine chemistry, Cysteine metabolism, Disulfides chemistry, Fibrinolysin chemistry, Humans, Oxidation-Reduction, Plasminogen chemistry, Protein Precursors chemistry, Protein Structure, Tertiary, Sulfhydryl Compounds chemistry, Sulfhydryl Compounds metabolism, Angiostatins metabolism, Disulfides metabolism, Fibrinolysin metabolism, Plasminogen metabolism, Protein Precursors metabolism

Abstract

Plasma plasminogen is the precursor of the tumor angiogenesis inhibitor, angiostatin. Generation of angiostatin in blood involves activation of plasminogen to the serine protease plasmin and facilitated cleavage of two disulfide bonds and up to three peptide bonds in the kringle 5 domain of the protein. The mechanism of reduction of the two allosteric disulfides has been explored in this study. Using thiol-alkylating agents, mass spectrometry, and an assay for angiostatin formation, we show that the Cys(462)-Cys(541) disulfide bond is already cleaved in a fraction of plasma plasminogen and that this reduced plasminogen is the precursor for angiostatin formation. From the crystal structure of plasminogen, we propose that plasmin ligands such as phosphoglycerate kinase induce a conformational change in reduced kringle 5 that leads to attack by the Cys(541) thiolate anion on the Cys(536) sulfur atom of the Cys(512)-Cys(536) disulfide bond, resulting in reduction of the bond by thiol/disulfide exchange. Cleavage of the Cys(512)-Cys(536) allosteric disulfide allows further conformational change and exposure of the peptide backbone to proteolysis and angiostatin release. The Cys(462)-Cys(541) and Cys(512)-Cys(536) disulfides have -/+RHHook and -LHHook configurations, respectively, which are two of the 20 different measures of the geometry of a disulfide bond. Analysis of the structures of the known allosteric disulfide bonds identified six other bonds that have these configurations, and they share some functional similarities with the plasminogen disulfides. This suggests that the -/+RHHook and -LHHook disulfides, along with the -RHStaple bond, are potential allosteric configurations.

Published

2014

10. New insights into the structure and function of the plasminogen/plasmin system.

Author

Law RH, Abu-Ssaydeh D, and Whisstock JC

Subjects

Bacterial Physiological Phenomena, Carbohydrate Metabolism, Disease, Fibrinolysin antagonists & inhibitors, Humans, Fibrinolysin chemistry, Fibrinolysin metabolism, Plasminogen chemistry, Plasminogen metabolism

Abstract

Plasminogen is the zymogen form of plasmin, an enzyme that plays a fundamental role in the dissolution of fibrin clots, the extracellular matrix and other key proteins involved in immunity and tissue repair. Comprising seven distinct domains (an N-terminal Pan-apple domain (PAp), 5 kringle domains (KR) and the serine protease domain (SP)), plasminogen undergoes a complex, incompletely understood conformational change that is key to its activation. Here, we review our current understanding of the structural basis for plasminogen activation with regard to new insights derived from crystallographic and biochemical studies., (Crown Copyright © 2013. Published by Elsevier Ltd. All rights reserved.)

Published

2013

11. Human tissue kallikreins 3 and 5 can act as plasminogen activator releasing active plasmin.

Author

de Souza LR, M Melo P, Paschoalin T, Carmona AK, Kondo M, Hirata IY, Blaber M, Tersariol I, Takatsuka J, Juliano MA, Juliano L, Gomes RA, and Puzer L

Subjects

Amino Acid Sequence, Baculoviridae genetics, Chromogenic Compounds chemistry, Enzyme Assays, Humans, Kinetics, Molecular Sequence Data, Proteolysis, Recombinant Proteins chemistry, Solutions, Fibrinolysin chemistry, Kallikreins chemistry, Plasminogen chemistry, Plasminogen Activator Inhibitor 1 chemistry, Tissue Plasminogen Activator chemistry

Abstract

Human tissue kallikreins (KLKs) are a group of serine proteases found in many tissues and biological fluids and are differentially expressed in several specific pathologies. Here, we present evidences of the ability of these enzymes to activate plasminogen. Kallikreins 3 and 5 were able to induce plasmin activity after hydrolyzing plasminogen, and we also verified that plasminogen activation was potentiated in the presence of glycosaminoglycans compared with plasminogen activation by tPA. This finding can shed new light on the plasminogen/plasmin system and its involvement in tumor metastasis, in which kallikreins appear to be upregulated., (Copyright © 2013 Elsevier Inc. All rights reserved.)

Published

2013

12. Regulation of fibrinolysis by C-terminal lysines operates through plasminogen and plasmin but not tissue-type plasminogen activator.

Author

Silva MM, Thelwell C, Williams SC, and Longstaff C

Subjects

Binding Sites, Carboxypeptidase B chemistry, Fibrin chemistry, Humans, Kinetics, Kringles, Protein Binding, Protein Structure, Tertiary, Tranexamic Acid chemistry, Urokinase-Type Plasminogen Activator chemistry, Fibrinolysin chemistry, Fibrinolysis, Lysine chemistry, Plasminogen chemistry, Tissue Plasminogen Activator chemistry

Abstract

Background: Binding of tissue-type plasminogen (Pgn) activator (t-PA) and Pgn to fibrin regulates plasmin generation, but there is no consistent, quantitative understanding of the individual contribution of t-PA finger and kringle 2 domains to the regulation of fibrinolysis. Kringle domains bind to lysines in fibrin, and this interaction can be studied by competition with lysine analogs and removal of C-terminal lysines by carboxypeptidase B (CPB)., Methods: High-throughput, precise clot lysis assays incorporating the lysine analog tranexamic acid (TA) or CPB and genetically engineered variants of t-PA were performed. In particular, wild-type (WT) t-PA (F-G-K1-K2-P) and a domain-switched variant K1K1t-PA (F-G-K1-K1-P) that lacks kringle 2 but retains normal t-PA structure were compared to probe the importance of fibrin lysine binding by t-PA kringle 2., Results: WT t-PA showed higher rates of fibrinolysis than K1K1t-PA, but the inhibitory effects of TA or CPB were very similar for WT t-PA and the variant t-PA (< 10% difference). Urokinase plasminogen activator (u-PA)-catalyzed fibrinolysis was also inhibited by TA, even though Pgn activation could be stimulated. Fibrin treated with factor XIIIa (FXIIIa) generates crosslinked degradation products, but these did not affect the results obtained with WT t-PA and K1K1t-PA., Conclusions: t-PA kringle 2 has a minor role in the initial interaction of t-PA and fibrin, but stimulation of fibrinolysis by C-terminal lysines (or inhibition by carboxypeptidases or TA) operates through Pgn and plasmin binding, not through t-PA. This is also true when fibrin is crosslinked by treatment with FXIIIa., (© 2012 International Society on Thrombosis and Haemostasis.)

Published

2012

13. Alendronate promotes plasmin-mediated MMP-9 inactivation by exposing cryptic plasmin degradation sites within the MMP-9 catalytic domain.

Author

Farina AR, Cappabianca L, Di Ianni N, Ruggeri P, Ragone M, Merolle S, Gulino A, and Mackay AR

Subjects

Catalysis, Catalytic Domain, Cations, Cell Line, Tumor, Chelating Agents pharmacology, Dose-Response Relationship, Drug, Edetic Acid chemistry, Hemopexin chemistry, Humans, Plasminogen chemistry, Protein Structure, Tertiary, Recombinant Proteins chemistry, Alendronate pharmacology, Fibrinolysin metabolism, Matrix Metalloproteinase 9 metabolism

Abstract

Irreversible MMP-9 inhibition is considered a significant therapeutic goal in inflammatory, vascular and tumour pathology. We report that divalent cation chelators Alendronate and EDTA not only directly inhibited MMP-9 but also promoted irreversible plasmin-mediated MMP-9 inactivation by exposing cryptic plasmin-degradation sites within the MMP-9 catalytic-domain and producing an inhibitory hemopexin-domain fragment. This effect was also observed using MDA-MB-231 breast cancer cells, which activated exogenous plasminogen to degrade endogenous proMMP-9 in the presence of Alendronate or EDTA. Degradation-mediated inactivation of proMMP-9 occurred in the absence of transient activation, attesting to the incapacity of plasmin to directly activate proMMP-9 and direct MMP-9 inhibition by Alendronate and EDTA. Our study provides a novel rational for therapeutic Alendronate use in MMP-9-dependent pathology characterised by plasminogen activation., (Copyright © 2012 Federation of European Biochemical Societies. Published by Elsevier B.V. All rights reserved.)

Published

2012

14. Kinetics of activated thrombin-activatable fibrinolysis inhibitor (TAFIa)-catalyzed cleavage of C-terminal lysine residues of fibrin degradation products and removal of plasminogen-binding sites.

Author

Foley JH, Cook PF, and Nesheim ME

Subjects

Binding Sites, Carboxypeptidase B2 metabolism, Catalysis, Fibrin metabolism, Fibrinolysin metabolism, Humans, Plasminogen metabolism, Carboxypeptidase B2 chemistry, Fibrin chemistry, Fibrinolysin chemistry, Fibrinolysis physiology, Plasminogen chemistry

Abstract

Partial digestion of fibrin by plasmin exposes C-terminal lysine residues, which comprise new binding sites for both plasminogen and tissue-type plasminogen activator (tPA). This binding increases the catalytic efficiency of plasminogen activation by 3000-fold compared with tPA alone. The activated thrombin-activatable fibrinolysis inhibitor (TAFIa) attenuates fibrinolysis by removing these residues, which causes a 97% reduction in tPA catalytic efficiency. The aim of this study was to determine the kinetics of TAFIa-catalyzed lysine cleavage from fibrin degradation products and the kinetics of loss of plasminogen-binding sites. We show that the k(cat) and K(m) of Glu(1)-plasminogen (Glu-Pg)-binding site removal are 2.34 s(-1) and 142.6 nm, respectively, implying a catalytic efficiency of 16.21 μm(-1) s(-1). The corresponding values of Lys(77)/Lys(78)-plasminogen (Lys-Pg)-binding site removal are 0.89 s(-1) and 96 nm implying a catalytic efficiency of 9.23 μm(-1) s(-1). These catalytic efficiencies of plasminogen-binding site removal by TAFIa are the highest of any TAFIa-catalyzed reaction with a biological substrate reported to date and suggest that plasmin-modified fibrin is a primary physiological substrate for TAFIa. We also show that the catalytic efficiency of cleavage of all C-terminal lysine residues, whether they are involved in plasminogen binding or not, is 1.10 μm(-1) s(-1). Interestingly, this value increases to 3.85 μm(-1) s(-1) in the presence of Glu-Pg. These changes are due to a decrease in K(m). This suggests that an interaction between TAFIa and plasminogen comprises a component of the reaction mechanism, the plausibility of which was established by showing that TAFIa binds both Glu-Pg and Lys-Pg.

Published

2011

15. Plasmin on adherent cells: from microvesiculation to apoptosis.

Author

Doeuvre L, Plawinski L, Goux D, Vivien D, and Anglés-Cano E

Subjects

Animals, Apoptosis, Blood Platelets cytology, Blotting, Western, CHO Cells, Cell Survival physiology, Cricetinae, Cricetulus, Fibrinolysin biosynthesis, Fibrinolysin chemistry, Humans, In Situ Nick-End Labeling, Kinetics, Microscopy, Electron, Plasminogen chemistry, Plasminogen genetics, Plasminogen isolation & purification, Tissue Plasminogen Activator physiology, Blood Platelets physiology, Cell Adhesion physiology, Fibrinolysin physiology

Abstract

Cell activation by stressors is characterized by a sequence of detectable phenotypic cell changes. A given stimulus, depending on its strength, induces modifications in the activity of membrane phospholipid transporters and calpains, which lead to phosphatidylserine exposure, membrane blebbing and the release of microparticles (nanoscale membrane vesicles). This vesiculation could be considered as a warning signal that may be followed, if the stimulus is maintained, by cell detachment-induced apoptosis. In the present study, plasminogen incubated with adherent cells is converted into plasmin by constitutively expressed tPA (tissue-type plasminogen activator) or uPA (urokinase-type plasminogen activator). Plasmin formed on the cell membrane then induces a unique response characterized by membrane blebbing and vesiculation. Hitherto unknown for plasmin, these membrane changes are similar to those induced by thrombin on platelets. If plasmin formation persists, matrix proteins are then degraded, cells lose their attachments and enter the apoptotic process, characterized by DNA fragmentation and specific ultrastructural features. Since other proteolytic or inflammatory stimuli may evoke similar responses in different types of adherent cells, the proposed experimental procedure can be used to distinguish activated adherent cells from cells entering the apoptotic process. Such a distinction is crucial for evaluating the effects of mediators, inhibitors and potential therapeutic agents.

Published

2010

16. The human alpha(2)-plasmin inhibitor: functional characterization of the unique plasmin(ogen)-binding region.

Author

Gerber SS, Lejon S, Locher M, and Schaller J

Subjects

Amino Acid Sequence, Animals, Binding Sites, Fibrinolysin chemistry, Fibrinolysin genetics, Humans, Kringles, Lysine chemistry, Lysine metabolism, Models, Molecular, Molecular Sequence Data, Peptides chemistry, Peptides genetics, Peptides metabolism, Plasminogen chemistry, Plasminogen genetics, Protein Binding, Recombinant Proteins chemistry, Recombinant Proteins genetics, Recombinant Proteins metabolism, Sequence Alignment, alpha-2-Antiplasmin genetics, Fibrinolysin metabolism, Plasminogen metabolism, Protein Conformation, alpha-2-Antiplasmin chemistry, alpha-2-Antiplasmin metabolism

Abstract

The human alpha(2)-plasmin inhibitor (A2PI) possesses unique N- and C-terminal extensions that significantly influence its biological activities. The C-terminal segment, A2PIC (Asn(398)-Lys(452)), contains six lysines thought to be involved in the binding to lysine-binding sites in the kringle domains of human plasminogen, of which four (Lys(422), Lys(429), Lys(436), Lys(452)) are completely and two (Lys(406), Lys(415)) are partially conserved. Multiple Lys to Ala mutants of A2PIC were expressed in Escherichia coli and used in intrinsic fluorescence titrations with kringle domains K1, K4, K4 + 5, and K1 + 2 + 3 of human plasminogen. We were able to identify the C-terminal Lys(452) as the main binding partner in recombinant A2PIC (rA2PIC) constructs with isolated kringles. We could show a cooperative, zipper-like enhancement of the interaction between C-terminal Lys(452) and internal Lys(436) of rA2PIC and isolated K1 + 2 + 3, whereas the other internal lysine residues contribute only to a minor extent to the binding process. Sulfated Tyr(445) in the unique C-terminal segment revealed no influence on the binding affinity to kringle domains.

Published

2010

17. Thrombin-activable fibrinolysis inhibitor zymogen does not play a significant role in the attenuation of fibrinolysis.

Author

Foley JH, Kim P, and Nesheim ME

Subjects

Carboxypeptidase B2 antagonists & inhibitors, Carboxypeptidase B2 metabolism, Carboxypeptidases antagonists & inhibitors, Carboxypeptidases metabolism, Fibrin Fibrinogen Degradation Products chemistry, Fibrinolysin metabolism, Humans, Plant Proteins chemistry, Plant Proteins pharmacology, Plasminogen metabolism, Protease Inhibitors chemistry, Protease Inhibitors pharmacology, Carboxypeptidase B2 chemistry, Carboxypeptidases chemistry, Fibrinolysin chemistry, Fibrinolysis physiology, Plasminogen chemistry

Abstract

Activated thrombin-activable fibrinolysis inhibitor (TAFIa) plays a significant role in the prolongation of fibrinolysis. During fibrinolysis, plasminogen is activated to plasmin, which lyses a clot by cleaving fibrin after selected arginine and lysine residues. TAFIa attenuates fibrinolysis by removing the exposed C-terminal lysine residues. It was recently reported that TAFI zymogen possesses sufficient carboxypeptidase activity to attenuate fibrinolysis through a mechanism similar to TAFIa. Here, we show with a recently developed TAFIa assay that when thrombin is used to clot TAFI-deficient plasma supplemented with TAFI, there is some TAFI activation. The extent of activation was dependent upon the concentration of zymogen present in the plasma, and lysis times were prolonged by TAFIa in a concentration-dependent manner. Potato tuber carboxypeptidase inhibitor, an inhibitor of TAFIa but not TAFI, abolished the prolongation of lysis in TAFI-deficient plasma supplemented with TAFI zymogen. In addition, TAFIa but not TAFI catalyzed release of plasminogen bound to soluble fibrin degradation products. The data presented confirm that TAFI zymogen is effective in cleaving a small substrate but does not play a role in the attenuation of fibrinolysis because of its inability to cleave plasmin-modified fibrin degradation products.

Published

2008

18. Effect of heat on the distribution of fluorescently labeled plasminogen and plasminogen activators in bovine skim milk.

Author

Wang L and Mauer LJ

Subjects

Animals, Caseins chemistry, Cattle, Chemical Precipitation, Female, Fibrinolysin chemistry, Fibrinolysin metabolism, Fluorescent Dyes, Micelles, Milk enzymology, Plasminogen chemistry, Plasminogen metabolism, Plasminogen Activators chemistry, Plasminogen Activators metabolism, Tissue Plasminogen Activator analysis, Tissue Plasminogen Activator chemistry, Tissue Plasminogen Activator metabolism, Ultracentrifugation, Urokinase-Type Plasminogen Activator analysis, Urokinase-Type Plasminogen Activator chemistry, Urokinase-Type Plasminogen Activator metabolism, Fibrinolysin analysis, Hot Temperature, Milk chemistry, Plasminogen analysis, Plasminogen Activators analysis

Abstract

Differentially fluorescently labeled bovine plasminogen (PG-594) and human tissue- and urokinase-type plasminogen activators (tPA-647 and uPA-546) were added to bovine skim milk to track the effect of heat on the location and concentration of these plasmin system components following acid precipitation or ultracentrifugation. In unheated milk, the majority (71.7% to 89.0%) of the added PG and PAs associated with casein micelles or acid curd, and PG-594 in the serum fraction was partially due to associations with nonsedimentable caseins. Heat treatment (85 degrees C for 16 s) significantly (P < 0.05) affected distribution of PG-594, tPA-647, and uPA-546, resulting in reduced concentrations of PG and PAs in the serum fractions and reciprocal increases in their levels in the nonsedimentable casein fractions. Overall, almost all of the added PG and PAs (95.9% to 97.5%) became associated with caseins following heat treatment. This is the 1st study to successfully use fluorescent labeling to quantify effects of heat on the location of plasmin components in skim milk.

Published

2008

19. Fibrinolysis is amplified by converting alpha-antiplasmin from a plasmin inhibitor to a substrate.

Author

Sazonova IY, Thomas BM, Gladysheva IP, Houng AK, and Reed GL

Subjects

Amino Acid Sequence, Antibodies, Monoclonal chemistry, Epitopes chemistry, Fibrinolysin chemistry, Humans, Molecular Sequence Data, Plasminogen chemistry, Protein Binding, Protein Conformation, Protein Structure, Tertiary, Recombinant Proteins chemistry, Substrate Specificity, Tissue Plasminogen Activator chemistry, Fibrinolysin antagonists & inhibitors, Fibrinolysis, alpha-2-Antiplasmin biosynthesis

Abstract

alpha(2)-Antiplasmin (alpha(2)-AP) is the fast serpin inhibitor of plasmin and appears to limit the success of treatment for thrombosis. We examined the mechanisms through which monoclonal antibodies (mAbs) against alpha(2)-AP amplify fibrinolysis. The mAbs RWR, 49 and 77 interfered with the ability of alpha(2)-AP to inhibit plasmin, microplasmin and trypsin. In solution, mAbs 49 and 77 bound to alpha(2)-AP with 5-fold to 10-fold higher relative affinity than mAb-RWR, while mAb-RWR bound with greater avidity to immobilized or denatured alpha(2)-AP. Binding studies with chimeric alpha(2)-APs revealed that none of the mAbs bound to sites in alpha(2)-AP that form putative contacts with plasmin, namely the carboxy terminal lysines of alpha(2)-AP, or the reactive center loop in the serpin domain of alpha(2)-AP. Rather, mAb-RWR recognized an epitope in the amino-terminus of alpha(2)-AP (L(13)GNQEPGGQTALKSPPGVCS(32)) near the site at which alpha(2)-AP cross-links to fibrin. mAbs 49 and 77 bound to another conformational epitope in the serpin domain of alpha(2)-AP. mAbs 49 and 77 markedly increased the stoichiometry of plasmin inhibition by alpha(2)-AP (from 1.1 +/- 0.1 to 51 +/- 4 and 67 +/- 7) indicating that they convert alpha(2)-AP from an inhibitor to a substrate of plasmin. This was confirmed by sodium dodecylsulfate polyacrylamide gel electrophoresis analysis showing cleavage of alpha(2)-AP by plasmin in the presence of these mAbs. In summary, these mAbs appear to act at sites distinct from known alpha(2)-AP-plasmin contacts to enhance fibrinolysis by converting alpha(2)-AP from an inhibitor to a plasmin substrate.

Published

2007

20. Plasminogen and plasmin activity in patients with coronary artery disease.

Author

Drinane MC, Sherman JA, Hall AE, Simons M, and Mulligan-Kehoe MJ

Subjects

Adolescent, Adult, Coronary Artery Disease blood, Epitope Mapping, Female, Fibrin Fibrinogen Degradation Products metabolism, Humans, Kringles, Male, Plasma metabolism, Plasminogen chemistry, Plasminogen Activator Inhibitor 1 blood, Protein Binding, Tissue Plasminogen Activator blood, Urokinase-Type Plasminogen Activator blood, Coronary Artery Disease enzymology, Fibrinolysin metabolism, Plasminogen metabolism, Tissue Plasminogen Activator metabolism

Abstract

Objective: While coronary artery disease (CAD) is associated with disturbances of the plasma fibrinolytic system, the nature of these disturbances is not fully defined. Fibrinolysis is regulated by plasmin, whose production is mediated by plasminogen activator conversion of plasminogen (Plg) to plasmin. The cascade is modulated by feedback loops that include Plg activator inhibitor 1 (PAI-1). Molecular interactions with Plg kringle domains play an important role in regulating plasmin production and its modulation of fibrinolysis. We hypothesized that interactions of tissue plasminogen activator (tPA) with Plg kringle domains regulates plasmin levels in patients with stable CAD., Methods: Plasma was collected from patients (n = 33) with an angiographically significant CAD and controls (n = 18) with angiographically established normal or minimally diseased arteries. Plasmin activity, tPA activity, and plasma levels of Plg, PAI-1, uPA, and tPA were determined., Results: CAD patients had 1.7-fold greater plasmin activity (P = 0.02) that correlated with 1.5-fold higher tPA activity when compared to controls. Epitope mapping of Plg domains showed Plg differences in epitope exposure between the two groups. Plasma from CAD patients had 50% less (P < 0.001) detectable kringle 4 and 48% less (P = 0.007) detectable kringles 1-3., Conclusions: Based on detectable differences in Plg, we conclude that in patients with stable CAD, Plg complexed with tPA exists in a conformation that enables increased tPA activity and Plg conversion to plasmin.

Published

2006

21. A method for direct application of human plasmin on a dithiothreitol-containing agarose stacking gel system.

Author

Choi NS, Chung DM, Yoon KS, Maeng PJ, and Kim SH

Subjects

Amino Acid Sequence, Disulfides chemistry, Dithiothreitol chemistry, Electrophoresis, Agar Gel methods, Electrophoresis, Gel, Two-Dimensional, Electrophoresis, Polyacrylamide Gel, Fibrinogen chemistry, Humans, Hydrogen-Ion Concentration, Plasminogen chemistry, Protein Structure, Tertiary, Sepharose chemistry, Thrombin chemistry, Biochemistry methods, Dithiothreitol pharmacology, Fibrinolysin chemistry

Abstract

A new simplified procedure for identifying human plasmin was developed using a DTT copolymerized agarose stacking gel (ASG) system. Agarose (1 %) was used for the stacking gel because DTT inhibits the polymerization of acrylamide. Human plasmin showed the lowest activity at pH 9.0. There was a similar catalytically active pattern observed under acidic conditions (pH 3.0) to that observed under alkaline conditions (pH 10.0 or 11.0). Using the ASG system, the primary structure of the heavy chain could be established at pH 3.0. This protein was found to consist of three fragments, 45 kDa, 23 kDa, and 13 kDa. These results showed that the heavy chain has a similar structure to the autolysed plasmin (Wu et al., 1987b) but there is a different start amino acid sequence of the N-termini.

Published

2005

22. Role of the streptokinase alpha-domain in the interactions of streptokinase with plasminogen and plasmin.

Author

Bean RR, Verhamme IM, and Bock PE

Subjects

Aminocaproic Acid chemistry, Binding Sites, Catalysis, Catalytic Domain, Chlorine chemistry, Gene Deletion, Humans, Lipopolysaccharides chemistry, Lysine chemistry, Microscopy, Fluorescence, Mutation, Protein Binding, Protein Conformation, Protein Folding, Protein Structure, Tertiary, Recombinant Proteins chemistry, Thermodynamics, Fibrinolysin chemistry, Plasminogen chemistry, Streptokinase chemistry

Abstract

The role of the streptokinase (SK) alpha-domain in plasminogen (Pg) and plasmin (Pm) interactions was investigated in quantitative binding studies employing active site fluorescein-labeled [Glu]Pg, [Lys]Pg, and [Lys]Pm, and the SK truncation mutants, SK-(55-414), SK-(70-414), and SK-(152-414). Lysine binding site (LBS)-dependent and -independent binding were resolved from the effects of the lysine analog, 6-aminohexanoic acid. The mutants bound indistinguishably, consistent with unfolding of the alpha-domain on deletion of SK-(1-54). The affinity of SK for [Glu]Pg was LBS-independent, and although [Lys]Pg affinity was enhanced 13-fold by LBS interactions, the LBS-independent free energy contributions were indistinguishable. alpha-Domain truncation reduced the affinity of SK for [Glu]Pg 2-7-fold and [Lys]Pg

Published

2005

23. Peroxynitrite and fibrinolytic system: the effect of peroxynitrite on plasmin activity.

Author

Nowak P, Kołodziejczyk J, and Wachowicz B

Subjects

Blotting, Western, Chromatography, Affinity, Dose-Response Relationship, Drug, Electrophoresis, Polyacrylamide Gel, Fibrinogen drug effects, Fibrinogen metabolism, Fibrinolysin antagonists & inhibitors, Glutathione pharmacology, Inhibitory Concentration 50, Plasminogen chemistry, Plasminogen isolation & purification, Plasminogen metabolism, Spectrophotometry, Streptokinase antagonists & inhibitors, Streptokinase drug effects, Time Factors, Tyrosine analysis, Tyrosine chemical synthesis, Tyrosine drug effects, Tyrosine metabolism, Fibrinolysin drug effects, Oxidants pharmacology, Peroxynitrous Acid pharmacology, Plasminogen drug effects, Tyrosine analogs & derivatives

Abstract

We have shown that peroxynitrite (ONOO-) inhibits streptokinase-induced conversion of plasminogen to plasmin in a concentration-dependent manner and reduces both amidolytic (IC5o approximately 280 microM at 10 microM concentration of enzyme) and proteolytic activity of plasmin. Spectrophotometric and immunoblot analysis of peroxynitrite-treated plasminogen demonstrates a concentration-dependent increase in its nitrotyrosine residues that correlates with a decreased generation of active plasmin. Peroxynitrite (1 mM) causes the nitration of 2.9 tyrosines per plasminogen molecule. Glutathione, like deferoxamine, partially protects plasminogen from peroxynitrite-induced inactivation and reduces the extent of tyrosine nitration. These data suggest that nitration of plasminogen tyrosine residues by peroxynitrite might play an important role in the inhibition of plasmin catalytic activity.

Published

2004

24. Coupling of conformational and proteolytic activation in the kinetic mechanism of plasminogen activation by streptokinase.

Author

Boxrud PD and Bock PE

Subjects

Catalysis, Dose-Response Relationship, Drug, Hydrolysis, Kinetics, Models, Chemical, Models, Molecular, Protein Binding, Protein Conformation, Sodium Dodecyl Sulfate pharmacology, Streptokinase pharmacology, Time Factors, Fibrinolysin chemistry, Plasminogen chemistry, Plasminogen Activators, Streptokinase chemistry

Abstract

Binding of streptokinase (SK) to plasminogen (Pg) induces conformational activation of the zymogen and initiates its proteolytic conversion to plasmin (Pm). The mechanism of coupling between conformational activation and Pm formation was investigated in kinetic studies. Parabolic time courses of Pg activation by SK monitored by chromogenic substrate hydrolysis had initial rates (v(1)) representing conformational activation and subsequent rates of activity increase (v(2)) corresponding to the rate of Pm generation determined by a specific discontinuous assay. The v(2) dependence on SK concentration for [Lys]Pg showed a maximum rate at a Pg to SK ratio of approximately 2:1, with inhibition at high SK concentrations. [Glu]Pg and [Lys]Pg activation showed similar kinetic behavior but much slower activation of [Glu]Pg, due to an approximately 12-fold lower affinity for SK and an approximately 20-fold lower k(cat)/K(m). Blocking lysine-binding sites on Pg inhibited SK.Pg* cleavage of [Lys]Pg to a rate comparable with that of [Glu]Pg, whereas [Glu]Pg activation was not significantly affected. The results support a kinetic mechanism in which SK activates Pg conformationally by rapid equilibrium formation of the SK.Pg* complex, followed by intermolecular cleavage of Pg to Pm by SK.Pg* and subsequent cleavage of Pg by SK.Pm. A unified model of SK-induced Pg activation suggests that generation of initial Pm by SK.Pg* acts as a self-limiting triggering mechanism to initiate production of one SK equivalent of SK.Pm, which then converts the remaining free Pg to Pm.

Published

2004

25. Bivalency of plasminogen monoclonal antibodies is required for plasminogen bridging to fibrin and enhanced plasmin formation.

Author

Dominguez M, Montes R, Páramo JA, and Anglés-Cano E

Subjects

Binding Sites, Antibody, Cell Membrane metabolism, Factor XII metabolism, Fibrinolysis, Fibronectins metabolism, Humans, Immunoglobulin Fab Fragments immunology, Kinetics, Models, Molecular, Plasminogen chemistry, Protein Conformation, Surface Plasmon Resonance methods, Antibodies, Monoclonal immunology, Fibrin metabolism, Fibrinolysin metabolism, Plasminogen immunology, Plasminogen metabolism

Abstract

Binding of plasminogen to fibrin and cell surfaces is essential for fibrinolysis and pericellular proteolysis. We used surface plasmon resonance and enzyme kinetic analyses to study the effect of two mAbs (A10.2, CPL15) on plasminogen binding and activation at fibrin surfaces. A10.2 is directed against the lysine-binding site (LBS) of kringle 4, whereas CPL15 recognises a region in kringle 1 outside the LBS. In the presence of CPL15 and A10.2 mAbs, binding of plasminogen (K(d)=1.16+/-0.22 micromol/l) to fibrin was characterised by a mAb concentration-dependent bell-shaped isotherm. A progressive increase in the concentration of mAbs at the surface was also detected, and reached a plateau corresponding to the maximum of plasminogen bound. These data indicated that at low mAb concentration, bivalent plasminogen-mAb-plasminogen ternary complexes are formed, whereas at high mAb concentration, a progressive shift to monovalent plasminogen-mAb binary complexes is observed. Plasmin formation in the presence of mAbs followed a similar bell-shaped profile. Monovalent Fab fragments of mAb A10.2 showed no effect on the binding of plasminogen, confirming the notion that a bivalent mAb interaction is essential to increase plasminogen binding and activation at the surface of fibrin.

Published

2002

26. [Degradation of streptokinase and the catalytic properties of the plasmin-streptokinase complex].

Author

Hrynenko TV, Makohonenko IeM, Iusova OI, and Cederholm-Williams SA

Subjects

Catalysis, Enzyme Stability, Fibrinolysis drug effects, Humans, Kinetics, Molecular Weight, Plasminogen chemistry, Protein Binding, Streptokinase chemistry, Structure-Activity Relationship, Tissue Plasminogen Activator chemistry, alpha-2-Antiplasmin chemistry, Fibrinolysin chemistry, Streptokinase metabolism

Abstract

Streptokinase (SK) interacts with human plasminogen (Pg) or plasmin (Pm) with formation of Pg-SK or Pm-SK complex. Pm-SK complex manifests a fibrinolytic, amidolytic and Pg activator activity. SK in complex with Pm isn't stable and so capable to be hydrolysed rapidly. We investigated a correlation between molecular form of SK and catalytic properties of equimolar Pm-SK complex during preincubation at 20 degrees C. It was found out that amidolytic activity of Pm-SK complex was not changing for 5 hours and decreased to the initial Pm value after 24 hours. During this time alpha 2-antiplasmin (alpha 2-AP) has any effect on amidolytic activity of the complex. Fibrinolytic activity of Pm-SK complex makes up 20% of the initial Pm value and wasn't changing within the investigated period. Pg activator activity was decreasing rapidly to 30-40% of the initial one within few minutes from the moment of Pm-SK complex formation. It was 10-20% of that initial after 24 hours. The decrease in Pg activator activity of Pm-SK complex correlated with the initial very rapid conversion of 47 kDa SK to 36 kDa SK within few minutes and following more slow conversion of SK in 31, 25 and 15 kDa fragments after 5 hours. alpha 2-AP didn't influence on the Pg activator activity of Pm-SK complex but eliminated its fibrinolytic activity completely. It was supposed that alpha 2-AP inhibited fibrinolytic activity of Pm-SK complex similarly to 6-aminohexanoic acid by preventing Pm-SK complex binding to fibrin polymer.

Published

2002

27. Measurement of reduction of disulfide bonds in plasmin by phosphoglycerate kinase.

Author

Lay AJ and Hogg PJ

Subjects

Amino Acid Sequence, Angiostatins, Disulfides chemistry, Fibrinolysin genetics, Humans, In Vitro Techniques, Kringles, Lysine analogs & derivatives, Maleimides, Molecular Sequence Data, Oxidation-Reduction, Peptide Fragments chemistry, Peptide Fragments metabolism, Plasminogen chemistry, Plasminogen metabolism, Recombinant Proteins metabolism, Fibrinolysin chemistry, Fibrinolysin metabolism, Phosphoglycerate Kinase metabolism

Published

2002

28. Purification and characterization of A61. An angiostatin-like plasminogen fragment produced by plasmin autodigestion in the absence of sulfhydryl donors.

Author

Kassam G, Kwon M, Yoon CS, Graham KS, Young MK, Gluck S, and Waisman DM

Subjects

Angiostatins, Animals, Electrophoresis, Polyacrylamide Gel, Humans, Hydrolysis, Mice, Mice, Inbred C57BL, Tumor Cells, Cultured, Fibrinolysin metabolism, Peptide Fragments chemistry, Peptide Fragments isolation & purification, Plasminogen chemistry, Plasminogen isolation & purification, Sulfhydryl Compounds metabolism

Abstract

Plasmin, a broad spectrum proteinase, is inactivated by an autoproteolytic reaction that results in the destruction of the heavy and light chains of the protein. Recently we demonstrated that a 61-kDa plasmin fragment was one of the major products of this autoproteolytic reaction (Fitzpatrick, S. L., Kassam, G., Choi, K. S., Kang, H. M., Fogg, D. K., and Waisman, D. M. (2000)Biochemistry 39, 1021-1028). In the present communication we have identified the 61-kDa plasmin fragment as a novel four kringle-containing protein consisting of the amino acid sequence Lys(78)-Lys(468). To avoid confusion with the plasmin(ogen) fragment, angiostatin(R) (Lys(78)-Ala(440)), we have named this protein A(61). Unlike angiostatin, A(61) was produced in vitro from plasmin autodigestion in the absence of sulfhydryl donors. A(61) bound to lysine-Sepharose and also underwent a large increase in fluorescence yield upon binding of the lysine analogue, trans-4-aminomethylcyclohexanecarboxylic acid. Circular dichroism suggested that A(61) was composed of 21% beta-strand, 14% beta-turn, 18% 3(1)-helix and 8% 3(10)-helix. A(61) was an anti-angiogenic protein as indicated by the inhibition of bovine capillary endothelial cell proliferation. Plasminogen was converted to A(61) by HT1080 cells and bovine capillary endothelial cells. Furthermore, a plasminogen fragment similar to A(61) was present in the serum of humans as well as normal and tumor-bearing mice. These results establish that plasmin turnover can generate anti-angiogenic plasmin fragments in a nonpathological setting.

Published

2001

29. Modulation of plasminogen activation and plasmin activity by methylglyoxal modification of the zymogen.

Author

Léránt I, Kolev K, Gombás J, and Machovich R

Subjects

Animals, Arginine chemistry, Catalysis, Electrophoresis, Polyacrylamide Gel, Fibrinolysin chemistry, Fibrinolysis, Kinetics, Lysine chemistry, Male, Plasminogen chemistry, Rats, Rats, Wistar, Spectrometry, Fluorescence, Fibrinolysin metabolism, Plasminogen metabolism, Pyruvaldehyde chemistry

Abstract

The effect of methylglyoxal on the plasminogen-plasmin system is studied. Treatment of plasminogen with methylglyoxal at a 20-fold molar excess results in covalent modification of the molecule as evidenced by the decreased number of NH(2) side chains, arginine side chain residues and the new band in the non-tryptophan dependent fluorescent spectrum. This structural modification is associated with profound functional alterations: the rate of activation by streptokinase, tissue-type plasminogen activator, urokinase-type plasminogen activator and trypsin decreases and the amidolytic activity of the generated plasmin is impaired. Plasmin treatment with methylglyoxal on the other hand does not alter its steady-state kinetic parameters on a peptidyl-anilide synthetic substrate, indicating that modification susceptible side chains are sensitive to methylglyoxal only in the zymogen. Our data suggest that in vivo fibrinolysis could be impaired under pathological conditions, e.g. increased methylglyoxal formation in diabetes mellitus.

Published

2000

30. Molecular mechanisms of plasminogen activation: bacterial cofactors provide clues.

Author

Parry MA, Zhang XC, and Bode I

Subjects

Amino Acid Sequence, Fibrinolysin metabolism, Humans, Metalloendopeptidases chemistry, Molecular Sequence Data, Peptide Fragments metabolism, Plasminogen chemistry, Plasminogen Activators chemistry, Streptokinase chemistry, Streptokinase metabolism, Fibrinolysin antagonists & inhibitors, Fibrinolysin chemistry, Metalloendopeptidases metabolism, Peptide Fragments chemistry, Plasminogen metabolism, Plasminogen Activators metabolism

Abstract

Plasminogen activation is a key event in the fibrinolytic system that results in the dissolution of blood clots, and also promotes cell migration and tissue remodelling. The recent structure determinations of microplasmin in complex with the bacterial plasminogen activators staphylokinase and streptokinase have provided novel insights into the molecular mechanisms of plasminogen activation and cofactor function. These bacterial proteins are cofactor molecules that contribute to exosite formation and enhance the substrate presentation to the enzyme. At the same time, they modulate the specificity of plasmin towards substrates and inhibitors, making a 'specificity switch' possible.

Published

2000

31. Guiding a docking mode by phage display: selection of correlated mutations at the staphylokinase-plasmin interface.

Author

Jespers L, Lijnen HR, Vanwetswinkel S, Van Hoef B, Brepoels K, Collen D, and De Maeyer M

Subjects

Amino Acid Substitution, Bacteria enzymology, Binding Sites, Catalysis, Catalytic Domain, Fibrinolysin chemistry, Fibrinolysin genetics, Humans, Inhibitory Concentration 50, Kinetics, Metalloendopeptidases chemistry, Metalloendopeptidases genetics, Models, Molecular, Peptide Fragments chemistry, Peptide Fragments genetics, Plasminogen chemistry, Plasminogen genetics, Plasminogen metabolism, Plasminogen Activators chemistry, Plasminogen Activators genetics, Plasminogen Activators metabolism, Static Electricity, Thermodynamics, Bacteriophages genetics, Fibrinolysin metabolism, Metalloendopeptidases metabolism, Peptide Fragments metabolism, Peptide Library, Suppression, Genetic genetics

Abstract

During co-evolution of interacting proteins, functionally disruptive mutations on one side of the interface may be compensated by local amino acid changes on the other to restore binding affinity. This information can be useful for geometry-based docking approaches by reducing the translational and rotational space available to the proteins. Here, we demonstrate that correlated mutations at a protein-protein interface can be rapidly identified by selecting a phage-displayed library of a randomly mutated component of the complex for complementation of mutations that decreased binding in the interacting partner. This approach was used to deduce the binding mode of staphylokinase (Sak), a 15.5 kDa "indirect" plasminogen activator on microplasmin (microPli), the 28 kDa serine protease domain of plasmin. Biopanning indicated that residues Arg94 and Gly174 in microPli are located in close proximity to Glu75 and the Glu88:Ile128 pair in Sak, respectively. The coupled mutations Glu94<-->Lys75 reversed and Gly174<-->Lys88:Val128 introduced a salt bridge, whereby the binding affinities (with coupling energies of 1.8 to 2.3 kcal mol-1, respectively) and the plasminogen activation ability of the mutated complexes were partially restored. These findings suggested a unique docking mode of Sak at the western rim of the active-site cleft of microPli, that is in agreement with the structure of the Sak-microPli complex as recently derived by other methods., (Copyright 1999 Academic Press.)

Published

1999

32. Kinetic properties of the activator complexes plasmin--staphylokinase and plasmin(ogen)--streptokinase in vitro.

Author

Sazonova IY, Aisina RB, Muhametova LI, and Varfolomeyev SD

Subjects

Dose-Response Relationship, Drug, Esterases chemistry, Fibrinolysis, Humans, Kinetics, Plasminogen Activators chemistry, Time Factors, Fibrinolysin chemistry, Metalloendopeptidases chemistry, Plasminogen chemistry, Streptokinase chemistry

Abstract

Comparative kinetic and electrophoretic study of the interaction of plasminogen (PG) with equimolar concentrations of staphylokinase (SPK) and streptokinase (SK) at 4 and 37 degreesC showed that the PG--SK complex has fibrinolytic and esterase activities, whereas the PG--SPK complex was inactive. Both esterase and fibrinolytic activities were enhanced during the conversion of the PG--SPK complex to the complex of plasmin (PL) with SPK (PL--SPK) at 37 and 4 degreesC, while the PG--SK complex was rapidly converted to the PL--SK complex with higher esterase activity only at 37 degreesC. The catalytic efficiency of Z-Lys-pNP hydrolysis (kcat/Km) by the preformed PL--SPK complex was twofold lower than that in the case of the PL--SK complex. Incubation of the PL--SPK and PG--SK(PL--SK) complexes at 37 degreesC for 24 h was associated with the degradation of the proteins and with different kinetics of lowering of esterase, plasminogen activator, and fibrinolytic activities. The PL--SPK complex was considerably more stable than the PG--SK(PL--SK) complex; streptokinase degraded more rapidly than staphylokinase. Kinetics of lysis of fibrin clots by the two complexes were similar, but the efficiency of lysis of plasma clots by the PL--SPK complex was significantly higher than that in the case of the PG--SK(PL--SK) complex (at 0.03-1 microM). Probably, unlike streptokinase, staphylokinase which is less susceptible to degradation in the PL--SPK complex and is released from the triple complex alpha2-antiplasmin--PL--SPK, forms a potentially highly active new complex with free molecules of plasminogen in the plasma.

Published

1999

33. Evaluation of the factors contributing to fibrin-dependent plasminogen activation.

Author

Mosesson MW, Siebenlist KR, Voskuilen M, and Nieuwenhuizen W

Subjects

Afibrinogenemia blood, Enzyme Activation, Epitopes chemistry, Factor XIII metabolism, Fibrin chemistry, Fibrinogen chemistry, Fibrinogen metabolism, Humans, Macromolecular Substances, Plasminogen chemistry, Protein Conformation, Sequence Deletion, Structure-Activity Relationship, Tissue Plasminogen Activator pharmacology, Fibrin physiology, Fibrinolysin biosynthesis, Plasminogen metabolism

Abstract

Polymerized fibrin strongly enhances tissue plasminogen activator (tPA)-mediated plasminogen activation, concomitant with exposure of 'fibrin-specific' epitopes at 'Aalpha148-160' and 'gamma312-324'. To investigate which aspects of polymerization are involved in these activities, we explored the fibrin polymerization process by evaluating the ability of factor XIIIa-crosslinked fibrinogen polymers to expose 'fibrin-specific' epitopes and enhance plasminogen activation. Crosslinked normal fibrinogen, fibrinogen with deficient [des Bbeta1-42] or defective [Birmingham (AalphaR16H)] fibrin 'D:E' assembly sites ('E(A)'), or with defective end-to-end self-association sites ('D:D') [Cedar Rapids (gammaR275C)], exposed both 'fibrin-specific' epitopes and enhanced tPA-dependent plasminogen activation, whereas non-crosslinked fibrinogens showed minimal or no such activities. Epitope expression in crosslinked fibrinogen was retained in the presence of the fibrin E(A) site peptide homolog, gly-pro-arg-pro (GPRP), which inhibits fibrin D:E association, except for the Aalpha148-160 epitope in des Bbeta1-42 fibrinogen, which was not expressed. Fibrin prepared from crosslinked normal or abnormal fibrinogen, except for the des Bbeta1-42 fibrin epitopes, which were reduced or absent, expressed 'fibrin-specific' epitopes even in the presence of GPRP, which otherwise impairs such expression in non-crosslinked fibrin. Epitope exposure in fibrin prepared from non-crosslinked fibrinogen was nearly normal in Cedar Rapids fibrin (heterozygous D:D defect), but reduced in Birmingham fibrin (heterozygous E(A) defect), nil in des Bbeta1-42 fibrin (E(A) deficient), and absent in all cases in the presence of GPRP. In contrast, plasminogen activation stimulatory activity that had been exposed in crosslinked normal fibrinogen or in crosslinked des Bbeta1-42 or Cedar Rapids fibrin, was preserved to a large extent in the presence of GPRP, suggesting that once enhanced stimulatory activity and epitopes are exposed, they are not completely reversible. The findings indicate that end-to-end intermolecular associations (D:D) are not critical for 'fibrin-specific' epitope exposure, but that polymerization brought about in fibrinogen through factor XIIIa crosslinking, or in fibrin through 'D:E' interactions, is necessary for 'fibrin-specific' (more correctly, 'polymerization-specific') epitope exposure and enhancement of plasminogen activation.

Published

1998

34. Enhancement of fibrin binding and activation of plasminogen by staplabin through induction of a conformational change in plasminogen.

Author

Takayasu R, Hasumi K, Shinohara C, and Endo A

Subjects

Allosteric Regulation, Aminocaproic Acid pharmacology, Enzyme Activation, Fibrinogen metabolism, Humans, Kinetics, Peptide Fragments chemistry, Peptide Fragments pharmacology, Plasminogen chemistry, Plasminogen drug effects, Thrombin metabolism, Benzopyrans pharmacology, Fibrin metabolism, Fibrinolysin metabolism, Peptide Fragments metabolism, Plasminogen metabolism, Plasminogen Activators pharmacology, Protein Conformation drug effects, Pyrrolidinones pharmacology

Abstract

Staplabin (0.3-0.6 mM), a fungal triprenyl phenol, enhanced 3-fold the plasminogen activator-catalyzed activation of Glu-plasminogen and Lys-plasminogen as well as their binding to fibrin. Staplabin was not stimulatory to the amidolytic activity of plasmin and plasminogen activators. Even in the presence of epsilon-aminocaproic acid (EACA) and fibrinogen fragments, allosteric effectors for Glu-plasminogen, staplabin increased the activation of both forms of plasminogen. In size-exclusion chromatography of Glu-plasminogen and Lys-plasminogen, the molecular elution time, which varies as the conformation of a protein changes, was shortened by staplabin. These results suggest that staplabin causes plasminogens to be more susceptible to activation and fibrin binding by inducing a conformational change that is, at least in part, different from that induced by EACA and fibrinogen fragments.

Published

1997

35. Structure and function of microplasminogen: reconstitution of microplasminogen and microplasmin from isolated fragments.

Author

de los Santos T, Wang J, and Reich E

Subjects

Amino Acid Sequence, Drug Stability, Fibrinolysin physiology, Humans, Molecular Sequence Data, Mutation, Peptide Fragments genetics, Peptide Fragments isolation & purification, Peptide Fragments physiology, Plasminogen antagonists & inhibitors, Plasminogen genetics, Plasminogen physiology, Structure-Activity Relationship, Fibrinolysin chemistry, Peptide Fragments chemistry, Plasminogen chemistry

Abstract

We describe limited chemical proteolysis of microplasminogen/microplasmin (mPlg/mPlm) and their reconstitution from isolated fragments. A V141-->M141 substitution in methionineless human mPlg/mPlm allowed the protein(s) to be cleaved in CNBr/formic acid. The resulting two fragments (141 and 118 residues, respectively), each internally disulfide bonded, were separated by preparative non-reducing gradient SDS-PAGE, and could then be mixed to reconstitute the characteristic mPlg/mPlm, including their activation by urokinase (uPA) and streptokinase (SK), and inhibition by macromolecular inhibitors. The isolated larger, N-terminal fragment, which contains the mPlg activation site in a normal disulfide configuration, was not cleaved by uPA in the absence of its smaller C-terminal companion, showing that the linear amino acid sequence is not by itself sufficient to confer substrate character, even when its conformation is constrained by the disulfide structure.

Published

1997

36. Lipoprotein(a), plasmin modulation, and atherogenesis.

Author

Harpel PC, Hermann A, Zhang X, Ostfeld I, and Borth W

Subjects

Adult, Animals, Arteriosclerosis pathology, Cell Division, Child, Haplorhini, Humans, Kringles physiology, Lipoprotein(a) chemistry, Mice, Mice, Transgenic, Muscle, Smooth, Vascular physiology, Plasminogen chemistry, Transforming Growth Factor beta metabolism, Arteriosclerosis blood, Fibrin physiology, Fibrinolysin physiology, Lipoprotein(a) physiology, Plasminogen physiology

Abstract

Lipoprotein(a) [Lp(a)] is an atherogenic lipoprotein however the mechanisms by which Lp(a) promote the atherosclerotic process are not clear. The apolipoprotein(a) portion of Lp(a) shares partial homology with plasminogen, a finding that has stimulated numerous studies. Lp(a) binds to fibrin and the affinity between fibrin surfaces and Lp(a) appears to be related to the state of oxidation of the lipoprotein particle. Lp(a) also effects fibrin-dependent plasminogen activation. Recent findings suggest that dependent plasminogen activation. Recent findings suggest that depending upon the in vitro conditions, Lp(a) either promotes or inhibits plasmin formation. Lp(a) also inhibits cell-surface dependent plasmin generation that is associated with an inhibition of transforming growth factor-beta (TGF-beta) production in cell coculture systems. Lp(a) stimulates smooth muscle cell migration and proliferation as a secondary response to this decrease in TGF-beta concentration. Studies in transgenic mice containing the human apolipoprotein(a) gene, document that both plasmin and TGF-beta formation in the media of the aorta is markedly decreased in the presence of apo(a). Thus the atherogenicity of Lp(a) may be mediated, in part, through its modulation of plasmin and TGF-beta production in the blood vessel wall.

Published

1995

37. Dual effect of synthetic plasmin substrates on plasminogen activation.

Author

Kolev K, Owen WG, and Machovich R

Subjects

Enzyme Activation, Kinetics, Oligopeptides pharmacology, Plasminogen chemistry, Substrate Specificity, Tissue Plasminogen Activator antagonists & inhibitors, Tissue Plasminogen Activator pharmacology, Fibrinolysin chemistry, Plasminogen Activators pharmacology

Abstract

The effect of plasmin substrates D-valyl-L-leucyl-lysine-p-nitroanilide (S-2251) and H-D-norleucyl-hexahydrotyrosyl-lysine-p-nitro-anilide (Spectrozyme-PL) on the rate of activation of native human plasminogen in physiological salt solution is studied. Plasminogen activation by two-chain urokinase-type plasminogen activator (urokinase), two-chain tissue-type plasminogen activator (tc-tPA) or trypsin, but not by single chain tPA (sc-tPA) is increased 5- to 10-fold by both substrates, as determined by electrophoretic and spectrophotometric kinetic analysis. The amidolytic activity of sc-tPA, on the other hand, is inhibited by the plasmin substrates in a non-competitive manner (K1 of 6.4 . 10(-4) M for S-2251 and 2.9 . 10(-4) M for Spectrozyme-PL), whereas urokinase and tc-tPA activities are not affected. It is concluded that plasmin substrates containing a lysine residue have a general capacity to enhance plasminogen activation presumably by inducing a conformational change in the native zymogen in a manner similar to 6-aminohexanoate, while the same substrates are inhibitory both on the amidolytic activity of sc-tPA and the activation of native and des1-77-plasminogen by sc-tPA.

Published

1995

38. Binding of a substrate analogue can induce co-operative structure in the plasmin serine-proteinase domain.

Author

Teuten AJ, Cooper A, Smith RA, and Dobson CM

Subjects

Affinity Labels metabolism, Amino Acid Sequence, Calorimetry, Differential Scanning, Fibrinolysin chemistry, Magnetic Resonance Spectroscopy, Molecular Sequence Data, Molecular Structure, Peptide Fragments chemistry, Plasminogen chemistry, Protease Inhibitors metabolism, Protein Binding, Protein Folding, Substrate Specificity, Thermodynamics, Amino Acid Chloromethyl Ketones, Fibrinolysin metabolism, Peptide Fragments metabolism, Plasminogen metabolism, Serine Endopeptidases metabolism

Abstract

Human miniplasminogen and miniplasmin were studied by n.m.r. spectroscopy and differential scanning calorimetry (d.s.c.) in order to investigate the structural properties of the serine-proteinase domain. The d.s.c. thermograms of both miniplasminogen and non-inactivated miniplasmin at pH 4.0 can be closely fitted to two transitions, at 62 +/- 2 and 72 +/- 2 degrees C, corresponding to unfolding of the kringle 5 and proteinase domains respectively. No evidence was found, under these conditions, for non-co-operative unfolding of the proteinase domain. On inactivation of miniplasmin with an affinity label, a number of additional resonances arising from residues of the proteinase domain are observed in resolved regions of the n.m.r. spectrum. A combination of variable-temperature n.m.r. and d.s.c. has shown that part of the proteinase domain undergoes a major conformational transition on heating which is distinct from the unfolding of the remainder of the proteinase domain or the kringle 5 domain. This additional transition occurs at a temperature that depends on the nature of the affinity label present and is not observed in the absence of an inactivating agent. These results provide direct evidence for the existence of a region of the proteinase domain which, under these conditions, becomes structured only in the presence of a bound substrate.

Published

1993

39. Distribution of plasminogen and plasmin in fractions of bovine milk.

Author

Politis I, Barbano DM, and Gorewit RC

Subjects

Animals, Blotting, Western, Electrophoresis, Polyacrylamide Gel, Enzyme-Linked Immunosorbent Assay, Female, Fibrinolysin chemistry, Plasminogen chemistry, Precipitin Tests, Cattle physiology, Fibrinolysin analysis, Milk enzymology, Plasminogen analysis

Abstract

The relative amounts of immunoreactive plasminogen and active plasmin in different fractions of bovine milk were examined. Raw milk was centrifuged to separate skim, cream, and a somatic cell pellet. Skim milk was centrifuged to separate milk serum and casein micelles. Milk fat globule membranes were isolated from the cream fraction of bovine milk. Proteins from somatic cells were isolated following sonication of the cells. Western blot analysis showed the presence of several forms of plasminogen in bovine milk. The predominant forms of plasminogen identified following electrophoresis under nonreducing conditions were proteins with approximate molecular weights of 88,000, 152,000, and 160,000. The predominant forms of plasminogen identified after electrophoresis under reducing conditions were two proteins with approximate molecular weights of 88,000 and 50,000. The highest amount (82% of the total plasminogen), as determined by an ELISA, was associated with the casein fraction. Lower plasminogen concentrations were associated with the serum, cream fractions, and milk fat globule membranes. The SDS-PAGE of the cream and milk fat globule membranes indicated that some casein was present in both fractions. Thus, the low plasminogen concentrations in these fractions may be associated with the caseins there. No immunoreactive plasminogen was present in the somatic cells. Active plasmin was present in the same milk fractions in which plasminogen was detected: casein, serum, and cream.

Published

1992