EC:3.4.21.7 - FACTA Search

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Query: EC:3.4.21.7 (plasmin)
9,023 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

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.
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PMID:The mechanism of activation of rabbit plasminogen by urokinase. 12 29

A method is described by which the heavy chain of human plasmin, obtained by partial reduction of urokinase-activated plasminogen with 2-mercaptoethanol, is adsorbed on lysine coupled to polyacrylamide. The heavy chain is recovered from the adsorbent by elution with 6-aminohexanoic acid (yield 60-65%). Sulfhydryl titrations of the heavy chain showed that the partial reduction involved primarily the cleavage of the sole interchain disulfide bridge of plasmin. Dodecylsulfate-polyacrylamide electrophoresis gave essentially a single band corresponding to a component of about 60000 molecular weight. The NH2-terminal amino acid was predominantly threonine. 6-Aminohexanoic acid at different concentrations caused significant variations of the sedimentation and diffusion constants of the heavy chain indicating inhibitor-induced conformational alterations of the protein. The present results suggest that in plasmin only the heavy chain is capable of interacting with 6-aminohexanoic acid, and it appears that it is primarily this chain which plays an important role in the inhibition of the enzyme by 6-aminohexanoic acid.
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PMID:A new method of isolation and some properties of the heavy chain of human plasmin. 12 54

When human plasminogen (Glu-Pga) is activated by urokinase in the presence of pancreatic trypsin inhibitor, the plasmin produced (Glu-Pma) exclusively contains a heavy chain (Glu-Ha) derived intact from the original NH2 terminus of Glu-Pga. Similar activations, utilizing a low molecular weight synthetic plasmin acylating agent, p-nitrophenyl-p-(pyridiniummethyl) benzoate, still result in a plasmin molecule with approximately 50% of the plasmin heavy chain containing the intact NH2 terminus of the original Glu-Pga. Activations performed at high levels of urokinase in the absence of any inhibitors initially produce Glu-Pma. However, the final stable plasmin, Lys-Pmb, which is obtained contains a heavy chain (Lys-Hb) which arises by plasminolysis of a small peptide from the NH2 terminus of Glu-Ha. Alternatively, Lys-Pmb can be formed in a separate series of reactions initially involving plasminolysis of Glu-Pga to yield Lys-Pgb. The peptide removed in this step is identical to the peptide removed in the Glu-Ha to Lys-Hb reaction. Next, urokinase catalyzes the conversion of Lys-Pgb to Lys-Pmb without further loss of peptide material. This latter pathway involving Lys-Pgb is probably the major pathway for human Lys-Pmb generation. These studies support a mechanism of activation of human plasminogen which involves at least two bond cleavages in Glu-Pga. However, these same studies strongly indicate that the Nh2-terminal peptide need not be released from Glu-Pga prior to plasmin formation. Further, we feel that plasmin and not urokinase catalyzes cleavage of the NH2-terminal peptide bond from Glu-Pga and the Glu-Ha heavy chain of Glu-Pma.
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PMID:Mechanism of the urokinase-catalyzed activation of human plasminogen. 13 42

A complex between plasmin and an inhibitor was isolated by affinity chromatography from urokinase-activated human plasma. The complex did not react with antibodies against any of the known proteinase inhibitors in plasma. A rabbit antiserum against the complex was produced. It contained antibodies agianst plasminogen+plasmin and an alpha2 protein. By crossed immunoelectrophoresis the alpha2 protein was shown to form a complex with plasmin, when generated by urokinase in plasma, and with purified plasmin. The alpha2 protein was eluted by Sephadex G-200 gel filtration with KD approx. 0.35, different from the other inhibitors of plasmin in plasma, and corresponding to an apparent relative molecular mass (Mr) of about 75000. By sodium dodecyl sulphate/polyacrylamide-gel electrophoresis, the Mr of the complex was found to be approx. 130000. After reduction of the complex two main bands of protein were observed, with Mr, about 72000 and 66000, probably representing an acyl-enzyme complex of plasmin-light chain and inhibitor-heavy chain, and a plasmin-heavy chain. A weak band with Mr 9000 was possibly an inhibitor-light chain. The inhibitor was partially purified and used to titrate purified plasmin of known active-site concentration. The inhibitor bound plasmin rapidly and strongly. Assuming an equimolar combining ratio, the concentration of active inhibitor in normal human plasma was estimated to be 1.1 mumol/1. A fraction about 0.3 of the antigenic inhibitor protein appeared to be functionally inactive. In plasma, plasmin is primarily bound to the inhibitor. Only after its saturation does lysis of fibrinogen and fibrin occur and a complex between plasmin and alpha2 macroglobulin appear.
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PMID:The primary inhibitor of plasmin in human plasma. 13 18

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.
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PMID:Activation of human plasminogen by equimolar levels of streptokinase. 13 1

The heavy polypeptide chains of human Glu-plasmin and human Lys-plasmin have been isolated in native solvents, after partial reduction and carboxymethylation of the corresponding plasmins. Two major forms of each heavy chain can be eluted, after adsorption to Sepharose/lysine, utilizing a gradient of epsilon-aminocaproic acid as the eluant. The elution profile of these heavy chains is practically identical to the elution behavior previously observed for human Glu- and Lys-plasminogen, and human Glu- and Lys-plasmin adsorbed to these columns. Sedimentation velocity analysis of the heavy chain of human Glu-plasmin, in the presence of epsilon-aminocaproic acid, demonstrated that a gross conformational alteration occurs in this peptide accompanying binding of this amino acid. A much smaller conformational alteration occurs under similar circumstances with the human Lys-plasmin heavy chain. We find that the NH2-terminal peptide released in the Glu-plasminogen to Lys-plasminogen and Glu-plasmin to Lys-plasmin conversions is also released in the Glu-plasmin heavy chain to Lys-plasmin heavy chain conversion. This reaction is catalyzed at a significant rate only by plasmin and not by urokinase. Finally, no strong interaction between streptokinase and the isolated plasmin heavy chains is observed.
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PMID:Purification and some properties of the Glu- and Lys-human plasmin heavy chains. 13 7

Rabbit immunoglobulin gamma (IgG) was digested with plasmin after being left for 15 min at pH2.5, 30 degrees C followed by a rapid increase in the pH to 7. The fragment antigen and complement binding (Facb) was isolated and characterized chemically and biologically. Sequence studies showed that the C-terminal quarter of the heavy chain had been removed, the split occurring at a lysine-alanine bond in the sequence Thr-Ile-Ser-Lys-Ala-Arg. The fragment Facb retained the capacity to precipitate with antigen and the precipitate caused activation of the first component of complement of the same order as that of acid-treated IgG. Both Facb and acid-treated IgG showed a fall in complement fixation relative to the native molecule of 30-40%.
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PMID:Characterization of a plasmin-digest fragment of rabbit immunoglobulin gamma that binds antigen and complement. 23 79

Two molecular forms of prekallikrein can be isolated from pooled normal human plasma. Their approximate molecular weights by sodium dodecyl sulfate-gel electrophoresis are 88,000 and 85,000. The two bands observed are shown to represent prekallikrein by functional, immunochemical, and structural criteria. Both forms are cleaved by activated Hageman factor, they appear to share antigenic determinants, they are not interconvertible upon incubation with activated Hageman factor or kallikrein, and the ratio of kinin-generating, and plasminogen-activating activities of the preparations are independent of the relative proportion of each band. Activated Factor XII converts prekallikrein to kallikrein by limited proteolysis and two disulfide-linked chains designated kallikrein heavy chain (Mr = 52,000) and kallikrein light chains (Mr = 36,000 or 33,000) are formed. The active site is associated with the light chains as assessed by incorporation of [3H]diisopropyl fluorophosphate. No dissociable fragments were observed in the absence of reducing agents. However, kallikrein could digest prekallikrein to diminish its molecular weight by 10,000. In addition, two factors capable of activating plasminogen to plasmin have been isolated; one is identified as kallikrein. The second principle fractionates with Factor XI and is demonstrable in normal and prekallikrein-deficient plasma.
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PMID:Hageman factor substrates. Human plasma prekallikrein: mechanism of activation by Hageman factor and participation in hageman factor-dependent fibrinolysis. 40 48

A 38-residue fragment is isolated from carboxymethylated plasminogen. Residues 29-38 have the same sequence as the amino-terminal end of the light chain of plasmin. The sequence 1-28 is therefore the sequence of the carboxyl-terminal end of the heavy chain and contains the specific sequence at which urokinase (EC 3.4.99.26) and other plasminogen-activating serine proteases split. Two of the five carboxymethyl-cysteine residues in the isolated fragment are situated close to the cleavage site and the fragment is not itself a substrate for plasminogen-activators. Residues 1-11 show extensive sequence homology with residues 137-147 and 242-252 in prothrombin, which are located in corresponding regions of the two internally homologous 83-residue structures in the non-thrombin part of the molecule, indicating that such structures may be a common feature of the non-protease part of the larger serine protease zymogens.
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PMID:Amino-acid sequence of activation cleavage site in plasminogen: homology with "pro" part of prothrombin. 105 75

The unstimulated platelet surface contains a specific and saturable binding site for high molecular weight kininogen (HK) and low molecular weight kininogen (LK). Investigations were performed with purified heavy and light chains of HK to determine which portion(s) of the HK molecule binds to the platelet surface. Purified 64-Kd heavy chain of HK and 56-Kd light chain of HK, independently, inhibited 125I-HK binding to unstimulated platelets with a 50% inhibitory concentration (IC50) of 84 nmol/L (apparent Ki, 30 nmol/L) and 30 nmol/L (apparent Ki, 11 nM), respectively. The ability of each of the purified chains of HK to independently inhibit 125I-HK binding was not due to cleavage, reduction, and alkylation of the protein, because two-chain HK, produced by treating HK the same way as purifying the separate chains, inhibited binding similarly to intact HK. Further, purified LK alone inhibited 125I-HK binding to platelets (Ki, 17 +/- 1 nmol/L, n = 7). The 64-Kd heavy chain of HK was a competitive inhibitor on a reciprocal plot of 125I-HK-platelet binding with an apparent Ki of 28 +/- 6 nmol/L (n = 4). Independently, purified 56-Kd light chain of HK was also found to be a competitive inhibitor of 125I-HK-platelet binding, with an apparent Ki of 11 +/- 3 nmol/L (mean +/- SEM, n = 4). These indirect studies indicated that HK binds to platelets by two portions of the molecule, one on the heavy chain and another on the light chain. Studies with 125I-light chain of HK showed that it specifically bound directly to platelets in the presence of zinc, since it was blocked by HK, light chain of HK, or EDTA, but not by LK, C1s, C1 inhibitor, plasmin, factor XIII, or fibrinogen. Purified light chain of HK did not inhibit direct 125I-LK binding to platelets. HK was found to bind to platelets in an unmodified form. HK bound to platelets was cleaved by plasma or urinary kallikrein at a slower rate than the same concentration of soluble HK or HK bound and subsequently eluted from the platelet surface. Cleavage of platelet-bound HK correlated with bradykinin liberation. These studies indicate that HK has two domains on its molecule that bind to platelets. Further, platelet-bound HK is protected from kallikreins' proteolysis. This latter finding suggests that cell binding may modify the rate of bradykinin liberation from HK.
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PMID:High molecular weight kininogen binds to platelets by its heavy and light chains and when bound has altered susceptibility to kallikrein cleavage. 153 48

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