Importance, localization and functional properties of the cell-associated form of plasminogen activator in mouse peritoneal macrophages

In inflammatory macrophages, plasminogen activator exists in two active forms, a soluble form released into the extracellular medium and a cell-associated form. This communication describes some properties of the cellular form of plasminogen activator, in intact macrophages and in cell lysates. Cellular plasminogen activator is a membrane protein, associated with the outer face of the plasma membrane; in intact macrophages, it participates in the activation of exogenous plasminogen and, thus, has to be considered as an ectoenzyme. A plasminogen activator activity can be detected in cell lysates (macrophage monolayers lysed in 0.1% Triton X-100) only when plasmin production is followed by the use of small synthetic substrates because a soluble inhibitor, released during extraction, blocks plasmin fibrinolytic activity. In these lysates, plasminogen activator molecules exist as high molecular weight unstable complexes exhibiting a high affinity for plasminogen.     

Isolation and characterization of microplasminogen. A low molecular weight form of plasminogen

A functionally active human microplasminogen without kringle structures was produced by incubation of plasminogen with urokinase-free plasmin at an alkaline pH. The microplasminogen was purified by affinity chromatography on lysine- and soybean trypsin inhibitor-Sepharose and by chromofocusing. Human plasminogen is specifically cleaved at Arg529-Lys530 by plasmin to form microplasminogen, which consists of a single polypeptide of 261 residues from the COOH-terminal portion of native plasminogen. It has an Mr of 28,617, calculated from the sequence, which is consistent with the molecular weight determined by sodium dodecyl sulfate gel electrophoresis. Microplasminogen is a slightly basic protein and is eluted from a chromofocusing column at pH 8.3. It can be activated by urokinase and streptokinase to a catalytically active microplasmin. The specific amidolytic activity of microplasmin is about three times higher than Lys77-plasmin on a weight basis and is about the same on a molar basis. The activation of microplasminogen by streptokinase is slower than that of either Glu-plasminogen or Lys77-plasminogen. On the other hand, the activation of microplasminogen by urokinase is faster than that of either of the latter. The Arg560-Val561 bond is cleaved during activation of both microplasminogen and native plasminogen.     

Isolation of a prokaryotic plasmin receptor. Relationship to a plasminogen activator produced by the same micro-organism.

Plasminogen receptors have been identified on the surface of a number of prokaryotic and eukaryotic cells. A receptor demonstrating high affinity for plasmin with minimal reactivity with the native zymogen Glu-plasminogen has been identified on the surface of certain group A streptococci. In this study the group A streptococcal plasmin receptor has been solubilized and purified to homogeneity. The isolated protein was an Mr approximately 41,000 molecule which retained its ability to bind plasmin following solubilization and affinity purification on a column of enzymatically inactivated human plasmin. The isolated plasmin receptor was compared functionally, antigenically, and physicochemically to the secreted plasminogen activator, streptokinase, produced by the same organism. The Mr approximately 41,000 surface plasmin receptor was shown to be functionally and antigenically distinct from the Mr approximately 48,000 streptokinase molecule produced by the same strain and lacked any plasminogen activator activity. The streptokinase molecule produced by this strain was shown to be closely related to the plasminogen activator protein secreted by other group A and C streptococci. This study represents the first report of the isolation of a plasmin receptor, either prokaryotic or eukaryotic, with functional activity.     

Amino terminal amino acid sequences and carbohydrate of the two major forms of rabbit plasminogen

Two major forms of plasminogen exist in the plasma of many animal species and are distinguished by their affinities for certain antifibrinolytic amino acids. Quantitative end group analysis demonstrated that each isolated form of rabbit plasminogen possessed a single amino terminal residue of glutamic acid. Amino acid sequence analysis indicated that at least the first twelve amino terminal amino acids were identical in the two forms. The unique amino terminal sequence obtained for each form was NH₂-glu-pro-leu-asp-asp-tyr-val-asn-thr-gln-gly-ala-. Analysis of the carbohydrate content of each major plasminogen form revealed some striking differences. The first major form of rabbit plasminogen isolated from affinity chromatography columns contained 1.5–1.7 percent neutral carbohydrate and 3.0–3.3 moles of sialic acid per mole of protein. The second major form of rabbit plasminogen isolated from affinity chromatography columns contained 0.6–0.8 percent neutral carbohydrate and 1.8–2.2 moles of sialic acid per mole of protein.     

Binding and activation of plasminogen at the surface of Staphylococcus aureus. Increase in affinity after conversion to the Lys form of the ligand.

Untreated Staphylococcus aureus cells, strain Cowan I, specifically bound 125I-Glu-plasminogen. The binding was inhibited by both unlabeled Glu-plasminogen and Glu-plasmin. The Lys form of plasminogen, which lacks the 8-kDa amino-terminal activation peptide, was approximately 100-fold more effective than the Glu form in competing with the binding of 125I-labeled Glu-plasminogen. This suggests an increase in binding affinity upon removal of the activation peptide. Fibronectin, fibrinogen and IgG, plasma components known to bind to the staphylococcal surface, did not significantly interfere with the binding. The competing activity in plasma was abolished by specifically absorbing plasminogen from the plasma sample. L-Lysine and a fragment of plasminogen containing three of the first five protein attachment domains present in the molecule (kringle structures) also competed with plasminogen for binding suggesting that the lysine-binding sites of plasminogen were involved in its interaction with staphylococci. Scatchard analysis revealed high- and low-affinity binding sites. Kd and the number of high-affinity binding sites were 1.7 nM and 780 binding sites/bacterial cell, respectively. 125I-Glu-plasminogen bound to staphylococcal surface was converted to plasmin by tissue-type plasminogen activator. The conversion took place also in the presence of plasma. If the conversion was carried out in the absence of low-molecular-mass plasmin inhibitors such as aprotinin, the bound Glu-plasmin was further converted to Lys-plasmin. The surface-bound plasmin was enzymically active, as judged by digestion of the synthetic substrate, S-2251. The plasminogen conversion shown by the present experiments not only leads to the surface-bound plasmin but seems to considerably increase the affinity of plasmin for its binding site. This may represent a physiologically relevant method for a bacterial cell to retain surface-bound active plasmin which is also protected from its soluble plasma inhibitors. This novel mechanism for staphylococci to adopt surface-bound proteolytic activity, without the interference of plasma components, may have some role in the tissue penetration and invasion of microbes during infection.     

Tissue plasminogen activator and urokinase enhance the binding of plasminogen to thrombospondin

Thrombospondin (TSP) is a multifunctional platelet alpha-granule and extracellular matrix glycoprotein that binds specifically to plasminogen (Plg) via that protein's lysine-binding site and modulates activation by tissue activator (TPA). In this study we report that the plasminogen activators, TPA and urokinase, greatly influence the binding of Plg to TSP. Using an enzyme-linked immunosorbent assay and a TSP-Sepharose affinity bead-binding assay we have found that Plg-TSP complex formation was markedly enhanced (up to 5-fold) when catalytic concentrations of Plg activators were included in the reaction mixtures. The enhancement was dependent upon the generation of small amounts of active plasmin and was duplicated by pretreatment of the immobilized TSP with plasmin prior to addition of the Plg. The enhancement effect was associated with selective proteolysis of the immobilized TSP. Purified Lys-Plg (the plasmin modified form of native Glu-Plg) bound to TSP to a greater extent than Glu-Plg, and binding of both forms was augmented by Plg activators. The apparent KD values of complex formation were unchanged in the presence of Plg activators suggesting that the enhancement effect was due to the generation of additional binding sites. The increased amount of bound Plg was demonstrated to result in a similar increase in the amount of plasmin generated from the complexes by TPA. Plg activators did not influence binding of Plg to histidine-rich glycoprotein or of histidine-rich glycoprotein to TSP, demonstrating specificity. In addition when TSP was treated with other proteases (human thrombin or human leukocyte elastase) no augmentation of Plg binding was seen. Thus, the initial production of small amounts of plasmin from Plg immobilized on TSP in fibrin-free microenvironments could generate a positive feedback loop by enzymatically modifying both TSP and Plg, resulting in an increase in TSP-Plg complex formation leading to the localized production of substantially more plasmin.     

Role of cell-surface lysines in plasminogen binding to cells: identification of alpha-enolase as a candidate plasminogen receptor.

Plasminogen binding to cell surfaces results in enhanced plasminogen activation, localization of the proteolytic activity of plasmin on cell surfaces, and protection of plasmin from alpha 2-antiplasmin. We sought to characterize candidate plasminogen binding sites on nucleated cells, using the U937 monocytoid cell as a model, specifically focusing on the role of cell-surface proteins with appropriately placed lysine residues as candidate plasminogen receptors. Lysine derivatives with free alpha-carboxyl groups and peptides with carboxy-terminal lysyl residues were effective inhibitors of plasminogen binding to the cells. One of the peptides, representing the carboxy-terminal 19 amino acids of alpha 2-antiplasmin, was approximately 5-fold more effective than others with carboxy-terminal lysines. Thus, in addition to a carboxy-terminal lysyl residue, other structural features of the cell-surface proteins may influence their affinity for plasminogen. Affinity chromatography has been used to isolate candidate plasminogen receptors from U937 cells. A major protein of Mr 54,000 was recovered and identified as alpha-enolase by immunochemical and functional criteria. alpha-Enolase was present on the cell surface and was capable of binding plasminogen in ligand blotting analyses. Plasminogen binding activity of a molecular weight similar to alpha-enolase also was present in a variety of other cell types. Carboxypeptidase B treatment of alpha-enolase abolished its ability to bind plasminogen, consistent with the presence of a C-terminal lysyl residue. Thus, cell-surface proteins with carboxy-terminal lysyl residues appear to function as plasminogen binding sites, and alpha-enolase has been identified as a prominent representative of this class of receptors.     

Phospholipid-associated annexin A2-S100A10 heterotetramer and its subunits: characterization of the interaction with tissue plasminogen activator,plasminogen, and plasmin

Annexin A2 (p36) is a highly alpha-helical molecule that consists of two opposing sides, a convex side that contains the phospholipid-binding sites and a concave side, which faces the extracellular milieu and contains multiple ligand-binding sites. The amino-terminal region of annexin A2 extends along the concave side of the protein and contains the binding site for the S100A10 (p11) subunit. The interaction of these subunits results in the formation of the heterotetrameric form of the protein, annexin A2-S100A10 heterotetramer (AIIt). To simulate the orientation of AIIt on the plasma membrane we bound AIIt to a phospholipid bilayer that was immobilized on a BIAcore biosensor chip. Surface plasmon resonance was used to observe in real time the molecular interactions between phospholipid-associated AIIt or its annexin A2 subunit and the ligands, tissue-type plasminogen activator (t-PA), plasminogen, and plasmin. AIIt bound t-PA (Kd = 0.68 microm), plasminogen (Kd = 0.11 microm), and plasmin (Kd = 75 nm) with moderate affinity. Contrary to previous reports, the phospholipid-associated annexin A2 subunit failed to bind t-PA or plasminogen but bound plasmin (Kd = 0.78 microm). The S100A10 subunit bound t-PA (Kd = 0.45 microm), plasminogen (Kd = 1.81 microm), and plasmin (Kd = 0.36 microm). Removal of the carboxyl-terminal lysines from the S100A10 subunit attenuated t-PA and plasminogen binding to AIIt. These results show that the carboxyl-terminal lysines of S100A10 form t-PA and plasminogen-binding sites. In contrast, annexin A2 and S100A10 contain distinct binding sites for plasmin.     

Isolation and characterization of a soybean lectin having 4-O-methylglucuronic acid specificity

A new lectin from soybeans having specificity toward the extracellular 4-O-methyl-D-glucurono-L-rhamnans produced by certain strains of Rhizobium japonicum has been purified and characterized. Isolation was accomplished initially by isoelectric precipitation of contaminating globulins and subsequently by affinity chromatography on partially hydrolyzed glucuronorhamnan covalently coupled to amino-hexylagarose. Residual globulins were removed by adsorption of the lectin on concanavalin A-agarose and elution with methyl alpha-mannoside. The lectin is a glycoprotein (3-5% carbohydrate) with a molecular weight of approximately 175 000. It is a tetramer with subunit molecular weights of 45 000 when dissociated with sodium dodecyl sulfate. Reverse-phase high-pressure liquid chromatography analysis indicates the presence of two types of subunits, both having equivalent molecular weights. According to amino acid analyses, the lectin is rich in acidic but low in sulfur-containing amino acids. The carbohydrate portion of the lectin contains mannose; no hexosamines could be detected. Chemical modification of the lectin indicated that neither sulfhydryl groups nor amino groups participate in binding. Quantitative binding studies of the lectin with various carbohydrate haptens showed that specificity was directed toward 4-O-methyl-D-glucuronic acid, D-glucuronic acid, and their methyl glycosides with 4-O-methyl-D-glucuronic acid 3-4-fold more effective. In each instance, the methyl glycoside is a more effective hapten.     

Binding and activation of plasminogen on immobilized immunoglobulin G. Identification of the plasmin-derived Fab as the plasminogen-binding fragment

We have found that tissue plasminogen activator catalyzes the binding of plasminogen (Pg) to immunoglobulin G (IgG) immobilized on a surface. This enhancement is due to the formation of plasmin, since plasmin treatment of immobilized IgG produced a 20-fold increase in Pg binding. Pg binding is lysine site dependent and reversible. The augmentation of Pg binding by plasmin is specific as other proteases produced significantly less or no effect. Immobilized plasmin-treated IgG also specifically binds Pg in plasma. IgG-immobilized Pg is activated by tissue plasminogen activator, and a significant portion of the plasmin formed remains bound to the IgG. The Pg reactive species in a plasmin-treated IgG digest was identified as the Fab fragment by chromatography utilizing the immobilized high affinity lysine-binding site of plasminogen. Specificity of the interaction was further demonstrated by immunoblot-ligand analysis which demonstrated that the plasmin-derived Fab fragment bound Pg whereas papain-derived Fab or plasmin-derived Fc fragments did not. These data suggest that Pg binds to the new COOH-terminal lysine residue of the plasmin-derived Fab. Pg also binds to an immobilized immune complex following plasmin treatment. These findings indicate that surface-bound IgG localizes plasminogen thus extending the spectrum of activity of the plasmin system to immunologic reactions.     

Binding and activation of plasminogen on the platelet surface

A mechanism by which platelets might participate in fibrinolysis by binding plasminogen and influencing its activation has been examined. Binding of radioiodinated human Glu-plasminogen to washed human platelets was time-dependent and was enhanced 3-9-fold by stimulation of platelets with thrombin but not with ADP. The interaction with both stimulated and unstimulated cells was specific, saturable, divalent ion-independent, and reversible. The platelet-bound ligand had the molecular weight of plasminogen, and no conversion to plasmin was detected. Scatchard analyses provided evidence for a single class of plasminogen-binding sites on both stimulated and unstimulated cells. The Kd for thrombin-stimulated platelets was 2.6 +/- 1.3 microM, and 190,000 +/- 45,000 molecules were bound per cell, whereas unstimulated platelets bound 37,000 +/- 10,500 molecules/cell with a Kd of 1.9 +/- 0.15 microM. Plasminogen binding was inhibited in a dose-dependent manner by omega-aminocarboxylic acids at concentrations consistent with a requirement for an unoccupied high affinity lysine-binding site for plasminogen binding to the cells. When platelet-bound plasminogen was incubated with tissue plasminogen activator, urokinase, or streptokinase, gel analysis established that plasmin was preferentially associated with the platelet relative to the supernatant. Plasminogen and plasmin interacted with thrombin-stimulated platelets with similar binding characteristics, and there was no evidence for a binding site for plasmin which did not also bind plasminogen. Therefore, the results suggest that plasminogen activation is enhanced on the cell surface. In sum, these results indicate that platelets bind plasminogen at physiologic zymogen concentrations and this interaction may serve to localize and promote plasminogen activation.     

Mapping of binding sites for heparin, plasminogen activator inhibitor-1, and plasminogen to vitronectin's heparin-binding region reveals a novel vitronectin-dependent feedback mechanism for the control of plasmin formation.

Vitronectin (VN) has been implicated as a major matrix-associated regulator component of plasminogen activation by serving as a potent stabilizing cofactor of plasminogen activator inhibitor-1 (PAI-1). The direct binding of heparin, plasminogen as well as PAI-1 in its latent and active form to immobilized VN was studied in the absence or presence of competitors. Monoclonal antibodies against the carboxyl-terminal portion of VN inhibited both PAI-1 and plasminogen binding, whereas heparin, heparan sulfate with a high degree of sulfation, or dextran sulfate interfered with PAI-1 binding (KD = 20 nM) only. Utilizing synthetic peptides encompassing overlapping sequences of the heparin-binding domain of VN, adjacent heparin and PAI-1-binding sites were localized within the sequence 348-370 of VN. Although a number of other serine protease inhibitors which do not form binary complexes with VN contain a reactive-site Ser at their P1'-position, a reactive-site P1' mutant of PAI-1 (Met----Ser) showed comparable if not increased binding to VN. Binding of Lys-plasminogen and active-site-blocked plasmin was at least 10-fold higher in affinity (KD = 85-100 nM) compared to Glu-plasminogen (KD approximately 1 microM) and could be inhibited by lysine analogs but not by glycosaminoglycans or PAI-1, indicating that heteropolar plasmin(ogen) binding of VN occurs to an adjacent segment upstream to the heparin and PAI-1-binding sites. This contention was further supported in binding studies with plasmin-modified VN which lost both heparin and PAI-1 binding but exhibited 2-3-fold higher capacity to bind plasminogen. The essential plasmin(ogen)-binding site was mapped by ligand blot analysis to the carboxyl-terminal portion of proteolytically trimmed VN (M(r) = 61,000). Moreover, treatment of the extracellular matrix of human umbilical vein endothelial cells with plasmin resulted in partial degradation of matrix-associated VN and concomitant release of PAI-1, but increased the ability of the matrix by about 2-fold to bind plasminogen. These results are indicative of differential interactions of VN with components of the plasminogen activation system, whereby plasmin itself may provoke the switch of VN from an anti-fibrinolytic into a pro-fibrinolytic cofactor. This process reflects a novel role for the adhesive protein and its degradation product(s) in the possible feedback regulation of localized plasmin formation at extracellular sites.     

Characterization of a fragment of bovine von Willebrand factor that binds to platelets

Bovine von Willebrand factor was digested with human plasmin in order to isolate and characterize a fragment that can bind to human platelets. A terminal plasmin digest of bovine von Willebrand factor is composed of five fragments, ranging in relative molecular weight (Mr) from 250,000 to 35,000. The major fragment has a Mr of 250,000 and consists of four disulfide-linked polypeptide chains with Mr from 69,000 to 35,000. The Mr 69,000 and 49,000 polypeptides possess carbohydrate moieties, as indicated by their reaction with periodate-Schiff reagent. Gel filtration studies suggest that, at physiological ionic strength, four of the Mr 250,000 fragments associate into a limited noncovalent oligomer. Monoclonal antibodies were prepared against native von Willebrand factor and used to characterize the distribution of epitopes on native vWF and the Mr 250,000 major fragment. Two of the monoclonal antibodies that recognize the major fragment (2 and H-9) inhibit platelet agglutination. The Mr 250,000 fragment binds to human platelets, and the binding is inhibited by monoclonal antibodies 2 and H-9. The Mr 250,000 fragment does not agglutinate platelets, consistent with a requirement for high molecular weight oligomers of von Willebrand factor for platelet agglutination. The Mr 250,000 fragment can compete with intact, bovine von Willebrand factor for binding to human platelets. However, its affinity is one-tenth that of intact von Willebrand factor.     

The mechanism of activation of rabbit plasminogen by urokinase.

The data presented in this paper show that when rabbit plasminogen is activated to plasmin by urokinase at least two peptide bonds are cleaved in the process. Urokinase first cleaves an internal peptide bond in plasminogen, leading to two-chain disulfide-linked plasmin molecule. The plasmin heavy chain of molecular weight 66,000 to 69,000 possesses an NH2-terminal amino acid sequence identical with the original plasminogen (molecular weight 88,000 to 92,000). The plasmin light chain of molecular weight 24,000 to 26,000 is known to be derived from the COOH-terminal portion of plasminogen. The plasmin generated during the activation of plasminogen is capable, by a feedback process, of cleaving a peptide of molecular weight 6,000 to 8,000 from the NH2 terminus of the heavy chain, producing a proteolytically modified heavy chain of molecular weight 58,000 to 62,000. Plasmin also can cleave this same peptide from the original plasminogen, yielding an altered plasminogen of molecular weight 82,000 to 86,000. This plasmin-altered plasminogen and the plasmin heavy chain derived from it by urokinase activation process NH2-terminal amino acid sequences which are identical with each other and with the plasminolytic product of the original plasmin heavy chain. These studies support a mechanism of activation of plasminogen by urokinase which involves loss of a peptide located on the NH2 terminus of plasminogen. However, these same results show that this NH2-terminal peptide need not be released from rabbit plasminogen prior to the cleavage of the internal peptide bond which leads to the two-chain plasmin molecule. Furthermore, these studies show that urokinase cannot remove this peptide from either the original rabbit plasminogen molecule or from the heavy chain of the initial plasmin formed.     

Multiple molecular forms of diarylpropane oxygenase, an H2O2-requiring, lignin-degrading enzyme from Phanerochaete chrysosporium

Three different molecular forms of the H2O2-requiring heme enzyme, diarylpropane oxygenase, were isolated from the extracellular medium of Na-acetate buffered, agitated cultures of Phanerochaete chrysosporium. Forms I, II, and III were separated by DEAE-Sepharose and further purified on Sephadex G-100. Absorption maxima of the native, reduced, and a variety of ligand complexes of the three enzyme forms are essentially identical, indicating similar heme environments. All forms also have similar, but not identical, reactivity. The homogeneous proteins oxidized a diarylpropane, an olefin, a beta-aryl ether dimer, a phenylpropane, phenylpropane diols, and veratryl alcohol. Identical products were produced from each form. However, the specific activities of the three homogeneous enzymes for veratryl alcohol oxidation were 18.75, 11.80, and 8.48 mumol min-1 mg-1. In the presence of one equivalent of H2O2 the Soret maximum of diarylpropane oxygenase II shifted from 408 to 418 nm, and two additional maxima appeared at 526 and 553 nm, indicating the presence of an Fe(IV)-oxo species equivalent to horseradish peroxidase II. This oxidized species could be reduced back to the native form by veratryl alcohol and several reducing agents (e.g., Na2S2O4, NH2NH2, thiourea, or NADH). The molecular weights of diarylpropane oxygenases I, II, and III were approximately 39,000, 41,000, and 43,000, respectively. The major form (II) (85% of the activity) contained approximately 6% neutral carbohydrate. The affinity of the forms for concanavalin A-agarose suggests that they all are glycoenzymes.     

Purification and further characterization of enteropeptidase from porcine duodenum

Enteropeptidase [EC 3.4.21.9] is a membrane-bound serine endopeptidase present in the duodenum that converts trypsinogen to trypsin. We previously cloned the cDNA of the porcine enzyme and deduced its entire amino acid sequence [M. Matsushima et al. (1994) J. Biol. Chem. 269, 19976-19982]. In the present study, we purified the porcine enzyme approximately 2,200-fold in a 12% yield from a duodenal mucosal extract to apparent homogeneity by an improved procedure comprising four steps of chromatography including benzamidine-Sepharose affinity chromatography. Lectin blotting analysis suggested that the enzyme is glycosylated mainly with N-linked carbohydrate chains of the tri- and/or tetraantennary complex type. The H and L chains of the enzyme were separated into two major bands upon SDS-PAGE under reducing conditions, suggesting that the enzyme mainly comprises two isoforms, a higher molecular weight form and a lower molecular weight form. The enzyme was also separated by lectin affinity chromatography into two major fractions, named isoforms I and II, which corresponded to the higher and lower molecular weight forms, respectively. These two isoforms appeared to be different only in the carbohydrate moiety, having essentially the same enzymatic properties. The enzyme was optimally active at pH 8.0 toward Gly-Asp-Asp-Asp-Asp-Lys-beta-naphthylamide, and was inhibited strongly by various serine proteinase inhibitors. Furthermore, it was also strongly inhibited by E-64 [L-trans-epoxysuccinyl-leucylamide-(4-guanido)-butane], a cysteine proteinase inhibitor. Substrate specificity studies involving various synthetic peptides indicated that acidic residues at the P2, P3, and/or P4 positions are especially favorable for maximal activity, but are not absolutely necessary, at least in the cases of peptide substrates.     

Activation of interstitial collagenase, MMP-1, by Staphylococcus aureus cells having surface-bound plasmin: a novel role of plasminogen receptors of bacteria

Plasmin, the enzymatically active form of plasminogen, can activate several matrix metalloproteinases (MMPs). In this study, we investigated the activation of MMP-1, one of the major interstitial collagenases, by plasmin which was generated on the surface of Staphylococcus aureus cells. Plasmin bound to plasminogen receptors on S. aureus degraded the major (125)I-labeled 55-kDa proMMP-1 into the 42-kDa form corresponding to the size of active MMP-1. MMP-1 formed by S. aureus-bound plasmin was also enzymatically active as judged by digestion of the synthetic collagenase substrate, DNP-Pro-Leu-Gly-Leu-Trp-Ala-D-Arg-NH(2). The finding that, in MMP-1 molecules generated either by soluble plasmin or by S. aureus-bound plasmin, the amino-terminal amino acid sequences were identical indicated that the activation mechanisms of the two plasmin forms do not differ from each other. The present observations emphasise and broaden the physiological importance of bacterial plasminogen receptors. In addition to direct proteolytic effects on components of the extracellular matrix, receptor-bound plasmin is also capable of initiating an MMP-1-dependent matrix-degrading enzymatic cascade.     

Activation of pro-urokinase and plasminogen on human sarcoma cells: a proteolytic system with surface-bound reactants

Human HT-1080 fibrosarcoma cells produce urokinase-type plasminogen activator (u-PA) and type 1 plasminogen activator inhibitor (PAI-1). We found that after incubation of monolayer cultures with purified native human plasminogen in serum-containing medium, bound plasmin activity could be eluted from the cells with tranexamic acid, an analogue of lysine. The bound plasmin was the result of plasminogen activation on the cell surface; plasmin activity was not taken up onto cells after deliberate addition of plasmin to the serum-containing medium. The cell surface plasmin formation was inhibited by an anticatalytic monoclonal antibody to u-PA, indicating that this enzyme was responsible for the activation. Preincubation of the cells with diisopropyl fluorophosphate-inhibited u-PA led to a decrease in surface-bound plasmin, indicating that a large part, if not all, of the cell surface plasminogen activation was catalyzed by surface-bound u-PA. In the absence of plasminogen, most of the cell surface u-PA was present in its single-chain proenzyme form, while addition of plasminogen led to formation of cell-bound two-chain u-PA. The latter reaction was catalyzed by cell-bound plasmin. Cell-bound u-PA was accessible to inhibition by endogenous PAI-1 and by added PAI-2, while the cell-bound plasmin was inaccessible to serum inhibitors, but accessible to added aprotinin and an anticatalytic monoclonal antibody. A model for cell surface plasminogen activation is proposed in which plasminogen binding to cells from serum medium is followed by plasminogen activation by trace amounts of bound active u-PA, to form bound plasmin, which in turn serves to produce more active u-PA from bound pro-u-PA. This exponential process is subject to regulation by endogenous PAI-1 and limited to the pericellular space.     

Activation of human plasminogen by equimolar levels of streptokinase.

Native Glu-human plasminogen (Mr approximately 92,000 with NH2-terminal glutamic acid) is able to combine directly with streptokinase in an equivalent molar ratio, to yield a stoichiometric complex. The plasminogen moiety in the complex then undergoes streptokinase-induced conformational changes. As a result of such, an active center develops in the plasminogen moiety of the complex. This proteolytically active complex then activates plasminogen in the complex to plasmin and at least two peptide bonds are cleaved in the process. The data presented in this paper reveal that initially an internal peptide bond of plasminogen (in the complex) is cleaved to yield a two-chain, disulfide-linked plasmin molecule. The heavy chain (Mr approximately 67,000 with NH2-terminal glutamic acid) of this plasmin molecule has an identical NH2-terminal amico acid as the native plasminogen. The light chain (Mr approximately 25,000 with NH2-terminal valine) of plasmin is known to be derived from the COOH-terminal portion of the parent plasminogen molecule. A second peptide is then cleaved from the NH2-terminal end of the heavy chain of plasmin producing a proteolytically modified heavy chain (Mr =60.000 with NH2-terminal lysine). This cleavage of the NH2-terminal peptide from the heavy chain of plasmin is shown to be mediated by the dissociated free plasmin present in the activation mixture. Plasmin in the streptokinase-plasmin complex is unable to cleave this NH2-terminal peptide. This same NH2-terminal peptide can also be cleaved from native Glu-plasminogen or from the Glu-plasminogen-streptokinase complex by free plasmin and not by a complex of streptokinase-plasmin. From these studies we conclude (a) in the streptokinase-plasminogen complex, the NH2-terminal peptide need not be released prior to the cleavage of the essential Arg-Val peptide bond which leads to the formation of a two chain plasmin molecule and (b) that this peptide is cleaved from the native plasminogen or from the heavy chain of the initially formed plasmin in the streptokinase complex by free plasmin and not by the plasmin associated with streptokinase. In agreement with this, plasmin associated with streptokinase was unable to cleave the NH2-terminal peptide from the isolated native heavy chain possessing glutamic acid as the NH2-terminal amino acid; whereas free plasmin readily cleaved this peptide from the same isolated Glu-heavy chain.     

Effect of endogenous fibrinolysis activation on human plasminogen

Plasminogen preparation from donor blood and fibrinolytically active blood plasma from humans after sudden death were obtained using affinity chromatography on Lysin-sepharose 4B. The plasminogen preparation from donor blood was shown to be highly purified native plasminogen (Glu-plasminogen). The preparation containing activated plasminogen (Lys-plasminogen), plasmin, plasminogen activator, alpha 2-macroglobulin, alpha 1-antitrypsin, fibrin/fibrinogen was obtained from the blood plasma of humans after sudden death. The appearance of proteins lacking biological specificity to lysin-sepharose in the plasminogen preparation shows the ability of activated plasminogen and plasmin to form complexes with these proteins and demonstrates the retention of the functional activity in lysin-binding regions on their molecules. Monospecific sera to the isolated preparations were obtained, demonstrating the presence of the same immunochemical determinants in native and activated plasminogen.