On the role of the carbohydrate side chains of human plasminogen in its interaction with alpha 2-antiplasmin and fibrin

Lactoferrin is a natural inhibitor of plasminogen activation

The plasminogen system is essential for dissolution of fibrin clots, and in addition, it is involved in a wide variety of other physiological processes, including proteolytic activation of growth factors, cell migration, and removal of protein aggregates. On the other hand, uncontrolled plasminogen activation contributes to many pathological processes (e.g. tumor cells' invasion in cancer progression). Moreover, some virulent bacterial species (e.g. Streptococci or Borrelia) bind human plasminogen and hijack the host's plasminogen system to penetrate tissue barriers. Thus, the conversion of plasminogen to the active serine protease plasmin must be tightly regulated. Here, we show that human lactoferrin, an iron-binding milk glycoprotein, blocks plasminogen activation on the cell surface by direct binding to human plasminogen. We mapped the mutual binding sites to the N-terminal region of lactoferrin, encompassed also in the bioactive peptide lactoferricin, and kringle 5 of plasminogen. Finally, lactoferrin blocked tumor cell invasion in vitro and also plasminogen activation driven by Borrelia Our results explain many diverse biological properties of lactoferrin and also suggest that lactoferrin may be useful as a potential tool for therapeutic interventions to prevent both invasive malignant cells and virulent bacteria from penetrating host tissues.

Natural heterogeneity of α2-antiplasmin: functional and clinical consequences

Human α2-antiplasmin (α2AP, also called α2-plasmin inhibitor) is the main physiological inhibitor of the fibrinolytic enzyme plasmin. α2AP inhibits plasmin on the fibrin clot or in the circulation by forming plasmin-antiplasmin complexes. Severely reduced α2AP levels in hereditary α2AP deficiency may lead to bleeding symptoms, whereas increased α2AP levels have been associated with increased thrombotic risk. α2AP is a very heterogeneous protein. In the circulation, α2AP undergoes both amino terminal (N-terminal) and carboxyl terminal (C-terminal) proteolytic modifications that significantly modify its activities. About 70% of α2AP is cleaved at the N terminus by antiplasmin-cleaving enzyme (or soluble fibroblast activation protein), resulting in a 12-amino-acid residue shorter form. The glutamine residue that serves as a substrate for activated factor XIII becomes more efficient after removal of the N terminus, leading to faster crosslinking of α2AP to fibrin and consequently prolonged clot lysis. In approximately 35% of circulating α2AP, the C terminus is absent. This C terminus contains the binding site for plasmin(ogen), the key component necessary for the rapid and efficient inhibitory mechanism of α2AP. Without its C terminus, α2AP can no longer bind to the lysine binding sites of plasmin(ogen) and is only a kinetically slow plasmin inhibitor. Thus, proteolytic modifications of the N and C termini of α2AP constitute major regulatory mechanisms for the inhibitory function of the protein and may therefore have clinical consequences. This review presents recent findings regarding the main aspects of the natural heterogeneity of α2AP with particular focus on the functional and possible clinical implications.

Preferential Acquisition and Activation of Plasminogen Glycoform II by PAM Positive Group A Streptococcal Isolates

Plasminogen (Plg) circulates in the host as two predominant glycoforms. Glycoform I Plg (GI-Plg) contains glycosylation sites at Asn289 and Thr346, whereas glycoform II Plg (GII-Plg) is exclusively glycosylated at Thr346. Surface plasmon resonance experiments demonstrated that Plg binding group A streptococcal M protein (PAM) exhibits comparative equal affinity for GI- and GII-Plg in the "closed" conformation (for GII-Plg, KD = 27.4 nM; for GI-Plg, KD = 37.0 nM). When Plg was in the "open" conformation, PAM exhibited an 11-fold increase in affinity for GII-Plg (KD = 2.8 nM) compared with that for GI-Plg (KD = 33.2 nM). The interaction of PAM with Plg is believed to be mediated by lysine binding sites within kringle (KR) 2 of Plg. PAM-GI-Plg interactions were fully inhibited with 100 mM lysine analogue ε-aminocaproic acid (εACA), whereas PAM-GII-Plg interactions were shown to be weakened but not inhibited in the presence of 400 mM εACA. In contrast, binding to the KR1-3 domains of GII-Plg (angiostatin) by PAM was completely inhibited in the presence 5 mM εACA. Along with PAM, emm pattern D GAS isolates express a phenotypically distinct SK variant (type 2b SK) that requires Plg ligands such as PAM to activate Plg. Type 2b SK was able to generate an active site and activate GII-Plg at a rate significantly higher than that of GI-Plg when bound to PAM. Taken together, these data suggest that GAS selectively recruits and activates GII-Plg. Furthermore, we propose that the interaction between PAM and Plg may be partially mediated by a secondary binding site outside of KR2, affected by glycosylation at Asn289.

Crystal structure of the native plasminogen reveals an activation-resistant compact conformation

BACKGROUND

Plasminogen is the zymogen form of plasmin and the precursor of angiostatin. It has been implicated in a variety of disease states, including thrombosis, bleeding and cancers. The native plasminogen, known as Glu-plasminogen, contains seven domains comprising the N-terminal peptide domain (NTP), five kringle domains (K1-K5) and the C-terminal serine protease domain (SP). Previous studies have established that the lysine binding site (LBS) of the conserved kringle domains plays a crucial role in mediating the regulation of plasminogen function. However, details of the related conformational mechanism are unknown.

OBJECTIVES

We aim to understand in more detail the conformational mechanism of plasminogen activation involving the kringles.

METHODS

We crystallized the native plasminogen under physiologically relevant conditions and determined the structure at 3.5 Å resolution. We performed structural analyses and related these to the literature data to gain critical understanding of the plasminogen activation.

RESULTS AND CONCLUSIONS

The structure reveals the precise architecture of the quaternary complex. It shows that the Glu-plasminogen renders its compact form as an activation-resistant conformation for the proteolytic activation. The LBSs of all kringles, except K1, are engaged in intra-molecular interactions while only K1-LBS is readily available for ligand binding or receptor anchorage. The structure also provides insights into the interactions between plasminogen and α2-antiplasmin, the primary physiological inhibitor of plasmin. Furthermore, the data presented explain why a conformational transition to the open form is necessary for plasminogen activation as well as angiostatin generation, and provide a rationale for the functional hierarchy of the different kringles.

The role of carbohydrate side chains of plasminogen in its activation by staphylokinase

Kinetic parameters (k(Pg) and K(Pg)) were determined for activation of Glu-plasminogen (Glu-Pg) and Lys-plasminogen (Lys-Pg) type I (with N-linked carbohydrate chain at Asn-289) and type II (with unsubstituted Asn-289) by plasmin-staphylokinase (Pm-STA) complex. The K(Pg) values for Glu-Pg I and Lys-Pg I (17.1 and 11.2 microM, respectively) were higher than those for Glu-Pg II and Lys-Pg II (14.9 and 5.4 microM, respectively), while only minor differences in the k(Pg) values were observed between plasminogens type I and type II. Soluble fibrin significantly increased the k(Pg)/K(Pg) values for activation of all four plasminogens due to a decrease in the K(Pg) values but did not alter the k(Pg) values. However, the activation of plasminogens type I was stimulated by fibrin lesser degree than that of plasminogens type II. These findings indicate that N-glycosylation of kringle 3 of plasminogen decreases the stability of Pm-STA-Pg ternary enzyme-substrate complex in solution as well as interferes with its formation and rearrangement on the fibrin surface.

Influence of soluble fibrin on reaction kinetics of plasmin type 1 and type 2 with alpha2-antiplasmin

This study investigates, by slow binding kinetics methods, reaction kinetics of both plasmin types 1 and 2 with alpha -antiplasmin in the presence of increasing concentrations of either epsilon-amino-caproic acid (EACA) or soluble fibrin. All curves of plasmin-alpha -antiplasmin interaction followed the same pattern, indicating reversible slow binding inhibition with an initial loose complex and a following tight complex. Without soluble fibrin or EACA, differences between plasmin types 1 and 2 could be seen in the initial loose complex formation. The presence of increasing concentrations of EACA slowed down the first step of the reaction (without any effect on the second step), resulting in increasing values for K. Plasmin type 1 demonstrated a steep slope of K at an EACA concentration of 1 mmol/l. In plasmin type 2, the increase of K started at higher EACA concentrations. The value for K at a high EACA concentration (100 mmol/l) was the same for both plasmin types. In contrast to EACA, increasing concentrations of soluble fibrin slowed down both reaction steps. At high concentrations of soluble fibrin, the inhibitory effect of alpha -antiplasmin was almost completely abolished. Our data demonstrate that the effect of soluble fibrin and the lysine analogue EACA on plasmin-antiplasmin reactions are different and that the use of lysine analogues does not mimic fibrin in laboratory analyses of plasmin inhibition. In addition, our data indicate theoretical differences between plasmin type 1 and plasmin type 2, when used for local thrombolytic therapy.(2) (2) (i initial) (i initial) (i initial) (i initial) (2)

Interaction of amorphous calcium phosphate with fibrin in vitro causes decreased fibrinolysis and altered protease profiles: implications for atherosclerotic disease

Previously, we demonstrated that amorphous calcium phosphate (ACP), chemical precursor to apatite, strongly interacted with fibrin and facilitated binding of matrix metalloproteinase (MMP)-9, a type IV collagenase. Plasmin-dependent fibrinolysis resulted in coordinate MMP-9 activation. Here we report on the effect(s) of ACP on fibrin degradation and binding of endogenous plasma proteases. Electrophoresis (8.5% SDS-PAGE) revealed that fibrin formed in the presence of ACP demonstrated characteristic gamma-gamma dimers (90-kDa) and beta-monomers (55-kDa), but resisted spontaneous fibrinolysis (72 h, 37 degrees C) or degradation by plasminogen activators (uPA, tPA). Casein zymography revealed an ACP-dependent decrease in fibrin binding of a low molecular weight (Mw) protease triplet (47-, 43-, 42-kDa) and increased fibrin binding of two high Mw proteases (94- and 84-kDa). The low Mw triplet also possessed gelatinolytic activity, but was not an MMP since 1,10-phenanthroline was ineffective as an inhibitor. Fibrin-binding proteases were inhibited to some degree by the serine protease inhibitor aprotinin. Competition/dissociation experiments with epsilon-aminocaproic acid revealed that the low Mw triplet lacked kringle regions whereas the 94- and 84-kDa proteases were tentatively identified and glu-/lys-plasmin(ogen)s. The triplet may, however, represent one or more kringle deficient mini-plasminogen(s), since electrophoretic mobility and substrate specificity was similar to elastase-generated mini-plasminogen. To explore these findings in a clinically relevant setting, a series of plasma samples was collected from a patient with unstable angina prior to, during, and post coronary artery bypass graft (CABG) surgery. Fibrin formed from plasma collected during and immediately post CABG was associated with increased fibrinolytic capacity and enhanced binding of a) MMP-9, b) the low Mw protease triplet (described above), and c) PA (as putative 110-kDa tPA:PAI-1 complex). The relevance of these findings to pathologic calcification of atherosclerotic plaques is discussed.

Fibrin-mediated plasminogen activation

Fibrin, but not fibrinogen, enhances the rate of activation of plasminogen by tissue type plasminogen activator (t-PA). Studies with enzymatic and chemical fragments of fibrinogen showed that several sites in fibrinogen are involved in this rate enhancement; these are, A alpha 148-160 (located in CNBr fragment FCB-2), and FCB-5 (a CNBr fragment comprising gamma 312-324), and recently discovered sites in the fibrinogen alpha C domains. All these sites are buried in fibrinogen, but exposed in fibrin and some fibrinogen fragments. For the first two of these, located in the D-domains, this was shown by the fact that monoclonal antibodies against A alpha 148-160 and gamma 312-324 bind to fibrin and rate enhancing fibrin(ogen) fragments, but not to fibrinogen. Direct binding studies indicate that at physiological concentrations plasminogen binds to FCB-2, and t-PA to FCB-5. More detailed studies have demonstrated the importance of residues A alpha-157 and A alpha-152, and that the minimum stretch with rate enhancing properties is A alpha 154-159. The sites in the alpha C domains await further identification. With the recently reported three-dimensional structure of fragments D and D-dimer it is now possible to explain these findings at the molecular level. Molecular calculations and experimental data show that the site A alpha 148-160 in fibrinogen is covered among others by a part of the A alpha chain (A alpha 166-195) that forms an alpha-helix, and by a globular domain formed by the beta-chain. On fibrin formation, the last two may move away, and give access to A alpha 148-160. It is conceivable that in the alpha C domain sites are involved in the early phases of fibrinolysis. The site A alpha 148-160 and that in FCB-5 may be more important at later stages. It is also clear that fibrin polymerization is important. This polymerization has probably several effects: exposure of the rate enhancing sites; mutual positioning of the t-PA and plasminogen binding sites; a concentrating effect of t-PA and plasminogen on the fibrin surface; effects on the kinetic properties of t-PA and plasminogen. These effects together explain the rate enhancement.

Depletion of circulating alpha(2)-antiplasmin by intravenous plasmin or immunoneutralization reduces focal cerebral ischemic injury in the absence of arterial recanalization

In the absence of arterial recanalization, thrombolytic agents induce a dose-related extension of focal cerebral ischemic injury (FII) in experimental animals. However, FII is smaller in mice lacking alpha(2)-antiplasmin (alpha(2)-AP), the physiologic inhibitor of plasmin, suggesting its depletion might reduce FII in the absence of reperfusion. Therefore, the effect of human plasmin (Pli), human miniplasmin (mPli), and an Fab fragment neutralizing murine alpha(2)-AP (Fab-4H9) on FII after middle cerebral artery (MCA) ligation was studied in mice and in hamsters. In BALB/c mice, the median FII after 24 hours was 28 microL (range, 20-34) (n = 10) with saline and 23 microL (range, 17-26) (n = 9) with a single bolus of 0.07 mg Pli, given after MCA ligation (P =.010), which reduced alpha(2)-AP to 44% and fibrinogen from 0.75 to 0.44 g/L. FII was 20 microL (range, 13-26) (n = 6, P =.025) with 0.2 mg mPli and was 24 microL (range, 20-27) (n = 6, P =.020) with 1.7 mg Fab-4H9. Neuronal atrophy and reduction of laminin immunoreactivity were comparably observed in the infarct area after saline and Pli. In hamsters, a single bolus injection of 1 mg Pli, after MCA ligation, depleted alpha(2)-AP and fibrinogen and reduced FII at 24 hours from 20 microL (range, 9.9-38) (n = 6) to 7.0 microL (range, 0.44-31) (n = 7, P =.032). Thus, reduction of circulating alpha(2)-AP, with a single bolus of plasmin or of a neutralizing antibody fragment, significantly reduced FII after MCA ligation in mouse and hamster models, suggesting that, provided these observations can be extrapolated to human beings, transient depletion of circulating alpha(2)-AP might reduce ischemic stroke in the absence of reperfusion.

Matrix metalloproteinase deficiencies do not impair cell-associated fibrinolytic activity

The matrix metalloproteinase (MMP) and fibrinolytic (plasminogen/plasmin) systems cooperate in many (patho)physiological processes requiring extracellular proteolysis. The effect of MMP-3 (stromelysin-1), MMP-7 (matrilysin), MMP-9 (gelatinase B) or MMP-12 (metalloelastase) on cellular fibrinolytic activity was studied with the use of smooth muscle cells (SMC) and fibroblasts derived from mice with specific inactivation of these genes. Activation of cell-bound plasminogen by two-chain urokinase-type plasminogen activator (tcu-PA) was not significantly different with SMC or fibroblasts from the gene-deficient mice (78% to 140% of wild-type). For all cell types, very limited conversion of plasminogen to angiostatin-like kringle-containing fragments was observed (< 3% of the total cell-bound plasminogen). Activation of plasminogen in solution by cell-associated tcu-PA was also comparable for SMC or fibroblasts of the different genotypes (54% to 160% of wild-type). In vitro SMC migration on scrape wounded collagen-coated surfaces was comparable for wild-type, MMP-7(-/-), MMP-9(-/-) and MMP-12(-/-) SMC, but was significantly reduced for MMP-3(-/-) SMC (P < .005 vs. wild-type). Serum-free conditioned medium of MMP-3(-/-) and MMP-7(-/-) SMC or fibroblasts induced similar lysis of fibrin films as wild-type cells. These findings indicate that several interactions that have been described between these MMPs and the plasminogen/plasmin system in a purified system do not significantly affect plasmin-mediated cellular fibrinolytic activity under cell culture conditions.

Prostromelysin-1 (proMMP-3) stimulates plasminogen activation by tissue-type plasminogen activator

Matrix metalloproteinase-3 (MMP-3 or stromelysin-1) specifically binds to tissue-type plasminogen activator (t-PA), without however, hydrolyzing the protein. Binding affinity to proMMP-3 is similar to single chain t-PA, two chain t-PA and active site mutagenized t-PA (Ka of 6.3 x 106 to 8.0 x 106 M-1), but is reduced for t-PA lacking the finger and growth factor domains (Ka of 2.0 x 106 M-1). Activation of native Glu-plasminogen by t-PA in the presence of proMMP-3 obeys Michaelis-Menten kinetics; at saturating concentrations of proMMP-3, the catalytic efficiency of two chain t-PA is enhanced 20-fold (kcat/Km of 7.9 x 10-3 vs. 4.1 x 10-4 microM-1.s-1). This is mainly the result of an enhanced affinity of t-PA for its substrate (Km of 1.6 microM vs. 89 microM in the absence of proMMP-3), whereas the kcat is less affected (kcat of 1.3 x 10-2 vs. 3.6 x 10-2 s-1). Activation of Lys-plasminogen by two chain t-PA is stimulated about 13-fold at a saturating concentration of proMMP-3, whereas that of miniplasminogen is virtually unaffected (1.4-fold). Plasminogen activation by single chain t-PA is stimulated about ninefold by proMMP-3, whereas that by the mutant lacking finger and growth factor domains is stimulated only threefold. Biospecific interaction analysis revealed binding of Lys-plasminogen to proMMP-3 with 18-fold higher affinity (Ka of 22 x 106 M-1) and of miniplasminogen with fivefold lower affinity (Ka of 0.26 x 106 M-1) as compared to Glu-plasminogen (Ka of 1.2 x 106 M-1). Plasminogen and t-PA appear to bind to different sites on proMMP-3. These data are compatible with a model in which both plasminogen and t-PA bind to proMMP-3, resulting in a cyclic ternary complex in which t-PA has an enhanced affinity for plasminogen, which may be in a Lys-plasminogen-like conformation. Maximal binding and stimulation require the N-terminal finger and growth factor domains of t-PA and the N-terminal kringle domains of plasminogen.

Specific proteolysis of human plasminogen by a 24 kDa endopeptidase from a novel Chryseobacterium Sp

A novel single polypeptide endopeptidase of 24 kDa (24k-endopeptidase) was purified with a yield of 300-400 microg/L from conditioned medium of a bacterial strain which was identified as a new species in the genus Chryseobacterium Sp. on the basis of its 16S rDNA sequence and DNA:DNA hybridizations. The NH(2)-terminal amino acid sequence (Val-Ala-Thr-Pro-Asn-Leu-Glu-.) was not found in the availabe databases. The 24k-endopeptidase specifically hydrolyzed the Ser(441)-Val(442) peptide bond in human plasmin(ogen), with additional cleavage of the Lys(78)-Val(79) and Pro(447)-Val(448) peptide bonds, and a secondary cleavage at Lys(615)-Val(616). Thereby, plasminogen is converted into an angiostatin-like fragment containing kringles 1-4 (K1-4) and miniplasminogen (kringle 5 and the serine proteinase domain). The purified K1-4 fragment showed a comparable cytotoxicity toward endothelial cells as the elastase-derived K1-3 fragment (12.7% versus 10.6% at a concentration of 10 microg/mL). Plasminogen, bound to monocytoid THP-1 cells, was also cleaved by the 24k-endopeptidase, resulting in generation of an angiostatin-like fragment and in a decreased capacity to generate cell-associated plasmin following activation by urokinase. The 24k-endopeptidase was not efficiently neutralized by specific inhibitors against the serine, cysteine, aspartic, or matrix metalloproteinase classes of enzymes. In human plasma or serum, however, it induced only very limited plasminogen degradation, apparently due to neutralization of its activity by alpha(2)-macroglobulin. Interaction of this novel 24k-endopeptidase with plasminogen thus yields an angiostatin-like fragment and affects plasmin-mediated cellular proteolytic activity.

Plasminogen II accumulates five times faster than plasminogen I at the site of a balloon de-endothelializing injury in vivo to the rabbit aorta: comparison with other hemostatic proteins

In the rabbit blood stream, plasminogen circulates as two glycoforms, plasminogen I (PLG-I) and plasminogen II (PLG-II), in a molar ratio of 1:2.2. To compare their relative behaviors toward a site of vascular injury, radiolabeled samples of PLG-I and PLG-II were coinjected intravenously into NZW rabbits before inducing a de-endothelializing (balloon catheter) injury to the thoracic aorta. At various times (5 to 60 minutes) after injury, each rabbit was anesthetized and exsanguinated, the aorta was excised, and the radioactivity per centimeters squared of aortic intima-media (IM) was measured relative to that of blood at exsanguination. The uptake of iodine 125-labeled PLG-I and iodine 131-labeled PLG-II showed that the IM was essentially saturated by both glycoforms by 30 to 40 minutes after injury. Extrapolation of the flux rates to 1 minute after injury indicated that the uptake of PLG-II (2.4 pmol/min/cm2) exceeded PLG-I (0.5 pmol/min/cm2) almost five-fold. This result is consistent with an earlier report (Metabolism 1994;43:1430-7) that PLG-II is released by the liver and catabolized in vivo approximately five times faster than PLG-I. By molar comparison, the flux of total plasminogen (ie, PLG-I plus PLG-II) into the injured aorta wall in vivo was 2.4 times greater than that for prothrombin. Assuming both zymogens are converted to their respective proteases within the wound site, then approximately 2 to 3 molecules of plasmin are released for each molecule of thrombin in vivo. The possible significance of this plasmin:thrombin ratio is discussed in respect to the turnover of fibrin(ogen) within the site of vascular injury.

Glycosylation profile of a recombinant urokinase-type plasminogen activator receptor expressed in Chinese hamster ovary cells

Association of urokinase-type plasminogen activator (uPA) to cells via binding to its specific cellular receptor (uPAR) augments the potential of these cells to support plasminogen activation, a process that has been implicated in the degradation of extracellular matrix proteins during cell migration and tissue remodeling. The uPA receptor is a glycolipid-anchored membrane protein belonging to the Ly-6/uPAR superfamily and is the only multidomain member identified so far. We have now purified the three individual domains of a recombinant soluble uPAR variant, expressed in Chinese hamster ovary cells, after limited proteolysis using chymotrypsin and pepsin. The glycosylation patterns of these domains have been determined by matrix assisted laser desorption ionization and electrospray ionization mass spectrometry. Of the five potential attachment sites for asparagine-linked carbohydrate in uPAR only four are utilized, as the tryptic peptide derived from domain III containing Asn233 was quantitatively recovered without carbohydrate. The remaining four attachment sites were shown to exhibit site-specific microheterogeneity of the asparagine-linked carbohydrate. The glycosylation on Asn52 (domain I) and Asn172 (domain II) is dominated by the smaller biantennary complex-type oligosaccharides, while Asn162 (domain II) and Asn200 (domain III) predominantly carry tri- and tetraantennary complex-type oligosaccharides. The carbohydrate moiety on Asn52 in uPAR domain I could be selectively removed by N-glycanase treatment under nondenaturing conditions. This susceptibility was abrogated when uPAR participitated in a bimolecular complex with pro-uPA or smaller receptor binding derivatives thereof, demonstrating the proximity of the ligand-binding site to this particular carbohydrate moiety. uPAR preparations devoid of carbohydrate on domain I exhibited altered binding kinetics toward uPA (a 4-6-fold increase in Kd) as assessed by real time biomolecular interaction analysis.

Proteolytic cleavage of urokinase-type plasminogen activator by stromelysin-1 (MMP-3)

Matrix metalloproteinase-3 (MMP-3, or stromelysin-1) specifically hydrolyzes the Glu143-Leu144 peptide bond in 45-kDa single-chain urokinase-type plasminogen activator (scu-PA) and in its two-chain (tcu-PA) derivative, yielding a 17-kDa NH2-terminal domain comprising the u-PA receptor (u-PAR) binding site and a 32-kDa COOH-terminal moiety containing the serine proteinase domain of u-PA. The conversion is completely abolished in the presence of the MMP inhibitors EDTA or 1,10-phenanthroline. Biospecific interaction analysis indicates that binding of MMP-3 occurs through the 32-kDa fragment. The 32-kDa fragment derived from scu-PA (scu-PA-32k) has a specific activity of </=500 IU/mg, but it can be activated with plasmin to a two-chain derivative (tcu-PA-32k) with a specific activity of 79 000 IU/mg. tcu-PA and tcu-PA-32k moieties derived from scu-PA-32k by plasmin or from tcu-PA by MMP-3 have comparable amidolytic activities toward the chromogenic substrate S-2444 (kcat/Km of 110 and 160 mM-1 s-1, respectively) and similar plasminogen activating activities in a coupled chromogenic substrate assay. Specific binding of the 17-kDa NH2-terminal domain to THP-1 monocytoid cells is completely abolished by competition with scu-PA but is not affected by scu-PA-32k (residual binding of 88 +/- 9% (mean +/- SEM; n = 3) with 25-fold molar excess). Thus, MMP-3 removes a functional NH2-terminal u-PAR-binding domain from u-PA without affecting its enzymatic properties.

Generation of an angiostatin-like fragment from plasminogen by stromelysin-1 (MMP-3)

Matrix metalloproteinase-3 (MP-3 or stromelysin-1) specifically hydrolyzes the Glu59-Asn60, Pro447-Val448, and Pro544-Ser545 peptide bonds in plasminogen, yielding a 55 kDa NH2-terminal angiostatin-like domain (comprising kringles 1-4), a 14 kDa domain comprising kringle 5, and a 30 kDa domain comprising the serine proteinases domain. The conversion is completely abolished in the presence of the MMP inhibitors EDTA or 1,10-phenanthroline. Biospecific interactions analysis indicates that binding of proMMP-3 and MMP-3 to plasminogen occurs with comparable affinity (KA of 4.7 x 10(6) and 4.1 x 10(6) M-1, respectively) and is mediated via the miniplasminogen moiety (kringle 5 plus the proteinase domain) and via the catalytic domain of MMP-3. Thus, proteolytic cleavage of plasminogen by MMP-3 generates angiostatin-like fragments.

Glycosylation at Asn-289 facilitates the ligand-induced conformational changes of human Glu-plasminogen

Glu-plasminogen exists in two major glycoforms (I and II). Glycoform I contains carbohydrate chains linked to Asn-289 and Thr-346, whereas glycoform II is glycosylated only at Thr-346. Disparities in carbohydrate content lead to differences in the important functional properties of the zymogen, e.g. the kinetics of activation. The kinetics of the large ligand-induced conformational changes of each of the Glu-plasminogen glycoforms have been studied using stopped-flow fluorescence. The results are in accordance with a conformational change governed by positive co-operative binding at two weak lysine-binding sites. Additional glycosylation at Asn-289 in Glu-plasminogen I results in a two-fold increase in the overall dissociation constant of a ligand, trans-4-aminomethyl-cyclohexane carboxylic acid. This effect stems directly from the reaction step during which the conformational changes occur. This implies a higher population of Glu-plasminogen I in the open conformation even in the absence of ligands, and thus accounts for a higher rate of activation of Glu-plasminogen I, in comparison with Glu-plasminogen II.

Suppression of plasminogen activator inhibitor-1 release from human cerebral endothelium by plasminogen activators. A factor potentially predisposing to intracranial bleeding

BACKGROUND

Intracranial bleeding is the most catastrophic potential complication of treatment with thrombolytic agents. To identify potential factors that may contribute to this problem, we characterized elaboration by human brain endothelial cells of plasminogen activator inhibitor-1 (PAI-1) and measured PAI-1 mRNA levels.

METHODS AND RESULTS

When human cerebral microvascular endothelial cells (HCMEC), pial arterial endothelial cells, and middle meningeal arterial endothelial cells were exposed to 10 to 1000 ng/mL recombinant tissue-type plasminogen activator (RTPA), urokinase-type plasminogen activator (UPA), or streptokinase/ plasminogen (37 U streptokinase plus 2 mumol/L plasminogen) for 24 hours, they exhibited concentration-dependent decreases in elaboration of PAI-1 of 65 +/- 3%, 48 +/- 3%, and 59 +/- 8%. UPA and streptokinase/plasminogen elicited decreases of 33 +/- 8% and 35 +/- 4%, respectively, that were specific with respect to the protease agonists as to total protein synthesis and cell type; ie, neither human umbilical vein endothelial cells nor cerebral pericytes exhibited inhibition of PAI-1 elaboration. No decrease in HCMEC PAI-1 elaboration was induced by coagulation factor XB (10 nmol/L). A 2.7 +/- 0.5-fold increase was induced by alpha-thrombin (10 nmol/L). PAI-1 secretion from HCMEC decreased within 4 hours of exposure to 100 ng/mL RTPA. In HCMEC exposed to RTPA for 8 hours, PAI-1 mRNA decreased from 176 +/- 20 to 43 +/- 2.2 pg/microgram RNA.

CONCLUSIONS

These results indicate that brain endothelial cells exposed to RTPA exhibit paradoxically diminished elaboration of PAI-1. This property may render brain vasculature vulnerable to attack by serine proteases, thereby predisposing to injury and initiating an underlying subsequent intracerebral hemorrhage in patients given plasminogen activators for treatment of coronary thrombosis.

Functional properties of a recombinant chimeric protein with combined thrombin inhibitory and plasminogen-activating potential

A chimeric protein (rscu-PA-40-kDa/Hir), consisting of the C-terminal amino acids 53-65 of hirudin (Hir), fused via a 14-amino-acid linker sequence to the C-terminal of a 40-kDa fragment (Ser47-Leu411) of recombinant (r) single-chain (sc) urokinase-type plasminogen activator (rscu-PA), was produced by expression of the corresponding chimeric cDNA in Escherichia coli cells. The thrombin inhibitory potential of purified rscu-PA-40-kDa/Hir was confirmed by complete inhibition of the coagulant activity of thrombin at 20-30-fold molar excess of the chimera, and by the resistance of rscu-PA-40-kDa/Hir to proteolytic cleavage by thrombin, rscu-PA-40-kDa/Hir prolonged the thrombin time of normal human plasma in a dose-dependent way (reduction of the apparent thrombin concentration to 50% with 95 nM chimeric protein as compared to 4.7 nM hirudin), and inhibited thrombin-mediated platelet aggregation (reduction of the apparent thrombin concentration to 50% with 40 nM chimeric protein). The chimera had a specific activity on fibrin films of 57,000 IU/mg as compared to 95,000 IU/mg for rscu-PA. The urokinase-like amidolytic activity of the single-chain protein was only 220 IU/mg but increased to 169,000 IU/mg after treatment with plasmin, which resulted in quantitative conversion to a two-chain (tc) derivative (rtcu-PA-40-kDa/Hir). Corresponding values for rscu-PA were 270 and 226,000 IU/mg. The catalytic efficiencies for plasmin-mediated conversion to two-chain molecules were comparable for rscu-PA-40-kDa/Hir and rscu-PA (0.63 and 0.65 microM-1.s-1, respectively). The plasminogen-activating potential of the single-chain chimera was comparable to that of rscu-PA; the catalytic efficiencies for plasminogen activation by their two-chain counterparts were also similar (0.55 and 0.73 microM-1.s-1, respectively). In 2 h, 50% lysis of 125I-fibrin-labeled clots prepared from platelet-poor human plasma and immersed in normal plasma was obtained with 1.3 micrograms/ml rscu-PA-40-kDa/Hir and with 0.67 micrograms/ml rscu-PA, with corresponding residual fibrinogen levels of 74% and 87%, respectively. In the absence of fibrin, 50% fibrinogenolysis in 2 h in normal human plasma required 2.1 micrograms/ml rscu-PA, but 7.9 micrograms/ml rscu-PA-40-kDa/Hir. Thus, the chimera rscu-PA-40-kDa/Hir has maintained the specific fibrinolytic and plasminogen activating activity of rscu-PA as well as its fibrinolytic potency in plasma, whereas it displayed a similar or somewhat better fibrin specificity.(ABSTRACT TRUNCATED AT 250 WORDS)

Role of N-linked glycosylation in human osteonectin. Effect of carbohydrate removal by N-glycanase and site-directed mutagenesis on structure and binding of type V collagen

In this study we demonstrate that the binding region of recombinant truncated human bone osteonectin (tHON) for type V collagen resides between amino acids 1 and 146. After removal of oligosaccharide chain structures from tHON, bovine bone osteonectin (BBON) and human platelet osteonectin (HPON) by N-glycanase, their ability to bind to type V collagen is increased, and HPON affinity to collagen V is the same as that of BBON. These data suggest that glycosylation of osteonectin has a direct or regulatory effect on osteonectin binding to collagen V and that the increase in tHON binding upon removal of carbohydrate is the result of a loss of a down-regulation site or direct interference of the carbohydrate at the binding site. To determine the specific role of each N-glycosylation site in tHON, Asn71 and Asn99 were mutated to Gln (N71Q, N99Q) and Thr73 and Thr101 mutated to Ala (T73A, T101A) to selectively inhibit oligosaccharide attachment. The binding affinity of N99Q and T101Q to collagen V is markedly increased over wild-type tHON, whereas N71Q and T73A are the same as wild-type tHON. The doubled mutant (N71,99Q) binds identically to collagen V as N99Q and T101A. These data suggest that only the position 99 glycosylation site (Asn99-X-Thr101) in tHON is important in the reduction of binding of osteonectin to collagen V. Consistent with the binding data is the observation that both the N71Q and T73A mutant proteins migrate on SDS-polyacrylamide gel electrophoresis gels identically to wild-type tHON, suggesting that there is little or no N-glycosylation of residue 71 in wild-type osteonectin.

Sialic acid content of plasminogen 2 glycoforms as a regulator of fibrinolytic activity. Isolation, carbohydrate analysis, and kinetic characterization of six glycoforms of plasminogen

Six glycoforms of plasminogen 2 were isolated using a combination of lectin affinity chromatography and chromatofocussing, and the sialic acid content of each glycoform was determined. The kinetics of activation of each glycoform by tissue-type plasminogen activator were analyzed on a fibrin surface and in solution. The second-order rate constant (measured on a fibrin surface) decreased from 1.65 x 10(6) M-1 s-1 to 3.77 x 10(4) M-1 s-1 as the sialic acid content of the glycoforms increased from 1.3 mol/mol of protein to 13.65 mol/mol of protein. A similar correlation was noted for activation in solution. Each glycoform was converted to plasmin, and the inhibition constants for the reaction between alpha 2-antiplasmin and plasmin glycoforms were determined. All overall Ki values, reflecting the final essentially irreversible complex, were in the picomolar range. Sialic acid does not affect inhibition of plasmin by alpha 2-antiplasmin; however, hypersialylated plasmin does not appear to have a kringle-dependent component to inhibition.

Biochemical properties of recombinant mutants of nonglycosylated single chain urokinase-type plasminogen activator

The role of glycosylation on the enzymatic properties of single chain urokinase-type plasminogen activator (scu-PA) was investigated by site-specific mutagenesis of the glycosylated Asn-302 residu to Gln. In addition, the role of the NH2-terminal polypeptide chain and of the Cys-148 to Cys-279 interchain disulphide bond on the activity of non-glycosylated scu-PA was investigated. Therefore, variants of recombinant scu-PA (rscu-PA) were produced by transfecting Chinese hamster ovary cells with cDNA encoding rscu-PA N302Q (rscu-PA with Asn-302 to Gln mutation), rscu-PA C279A,N302Q (rscu-PA with Cys-279 to Ala and Asn-302 to Gln mutations) or rscu-PA del(N2-F157)C279A,N302Q (rscu-PA C279A,N302Q with deletion of Asn-2 through Phe-157). These mutants were purified to homogeneity from conditioned cell culture medium and were obtained essentially as single chain molecules with specific activities on fibrin plates of (mean +/- S.E.; n = 6) 45,000 +/- 5000. IU/mg, 19,000 +/- 800 IU/mg and < or = 100 IU/mg for rscu-PA N302Q, rscu-PA C279A,N302Q and rscu-PA del(N2-F157)C279A,N302Q, respectively, as compared to 64,000 +/- 2600 IU/mg for wild-type rscu-PA obtained in the same expression system. Plasmin quantitatively converts rscu-PA N302Q and rscu-PA C279A,N302Q to amidolytically active two-chain derivatives with a specific activity of 56,000 IU/mg and 32,000 IU/mg, respectively, as compared to 75,000 IU/mg for wild-type rscu-PA. Plasminogen activation as a function of time was comparable for rscu-PA N302Q and wild-type rscu-PA, and somewhat slower for rscu-PA C279A,N302Q. In a human plasma milieu in vitro, consisting of a 125I-fibrin labeled plasma clot submerged in plasma, 50 percent clot lysis in 2 h required 2.2 micrograms/ml rscu-PA N302Q and 6.0 micrograms/ml rscu-PA C279A,N302Q, as compared to 3.2 micrograms/ml wild-type rscu-PA. In contrast, rscu-PA del(N2-F157)C279A,N302Q was not converted to an amidolytically active two chain derivative by plasmin, and did not induce significant plasminogen activation in purified systems or clot lysis in a human plasma milieu. Following bolus injections in hamsters, the initial half-lives (1.8-2.6 min) and the plasma clearances (0.6-1.5 ml min-1) were comparable for wild-type rscu-PA and for the three rscu-PA mutants. These results suggest that the fibrinolytic activity in a plasma milieu in vitro and the in vivo turnover of rscu-PA are not markedly affected by the absence of carbohydrate.(ABSTRACT TRUNCATED AT 400 WORDS)

Biochemical properties of recombinant single-chain urokinase-type plasminogen activator mutants with deletion of Asn2 through Phe157 and/or substitution of Cys279 with Ala

The contribution of the NH2-terminal polypeptide chain and of the Cys148-Cys279 interchain disulphide bond to the enzyme activity of urokinase-type plasminogen activator (u-PA) was studied using site-specific mutagenesis. Recombinant single-chain u-PA (rscu-PA) variants were produced by transfecting Chinese hamster ovary cells with cDNA encoding des(Asn2-Phe157)rscu-PA (rscu-PA with deletion of Asn2-Phe157), [Ala279]rscu-PA (rscu-PA with Cys279----Ala mutation) or des(Asn2-Phe157)[Ala279]rscu-PA [des(Asn2-Phe157)rscu-PA with Cys279----Ala mutation]. Des(Asn2-Phe157)rscu-PA, [Ala279]rscu-PA and des(Asn2-Phe157)[Ala279]rscu-PA, purified from conditioned cell culture medium, were obtained as nearly homogeneous single-chain molecules with Mr approximately 30,000, 54,000 and 30,000, and specific fibrinolytic activities on fibrin plates of (mean +/- SD; n = 3) 860 +/- 150 IU/mg, 43.0 +/- 2.5 IU/micrograms and 240 +/- 20 IU/mg, respectively, compared to 69.0 +/- 4.3 IU/micrograms for wild-type rscu-PA obtained in the same expression system. The plasminogen activating potential in a buffer milieu of [Ala279]rscu-PA was somewhat lower than that of rscu-PA, but that of both deletion mutants was virtually abolished. In a human plasma milieu in vitro, consisting of a radiolabelled human plasma clot submerged in plasma, 50% clot lysis in 2 h required 6.5 micrograms/ml [Ala279]rscu-PA or 3.4 micrograms/ml rscu-PA, whereas with both deletion mutants no significant clot lysis was observed with up to 16 micrograms/ml. Treatment of [Ala279]rscu-PA or rscu-PA with plasmin resulted in quantitative conversion to two-chain molecules and was associated with an increase in specific amidolytic activity from about 600 IU/mg to 62.5 IU/micrograms for [Ala279]rscu-PA as compared to an increase from about 0.3 IU/micrograms to 75.0 IU/micrograms for rscu-PA. In contrast, no significant amidolytic activity could be generated by treatment of des(Asn2-Phe157)rscu-PA or des(Asn2-Phe157)[Ala279]rscu-PA with plasmin. The u-PA B-chain, isolated from plasmin-treated [Ala279]rscu-PA, had enzymic properties which were comparable to those of rtcu-PA, with respect to specific fibrinolytic activity, amidolytic activity, kinetics of plasminogen activation and clot-lysis activity in a human plasma milieu in vitro. Following bolus injection into hamsters, the plasma clearances were comparable (0.7-1.1 ml/min) for wild-type rscu-PA and for the three truncated rscu-PA mutants.(ABSTRACT TRUNCATED AT 400 WORDS)

Hedgehog lipoprotein(a) is a modulator of activation of plasminogen at the fibrin surface. An in vitro study

Lipoprotein(a) (Lp[a]), a highly atherogenic lipoprotein particle, is the prominent apolipoprotein B-containing lipoprotein in the hedgehog (Laplaud PM et al, J Lipid Res 1988;29:1157-1170). In the present work, we studied the consequences of the structural homology between the specific Lp(a) glycoprotein, apoprotein(a), and plasminogen on the generation of plasmin by fibrin-bound tissue-type plasminogen activator. The activation of plasminogen was initiated by adding either native plasma or Lp(a)-free plasma supplemented with the equivalent of 0.25 mg/ml of either purified Lp(a) or albumin to a surface of fibrin prepared on micortitration plates and to which human tissue-type plasminogen activator was specifically bound. With the Lp(a)-free plasma, an increase in the binding and activation of plasminogen as a function of time was observed. In contrast, in the presence of Lp(a) (i.e., native plasma or the reconstituted system), a significant decrease in the binding of plasmin(ogen) (approximately 60%) was obtained. These data indicate that hedgehog Lp(a) interferes with the binding and activation of plasminogen at the fibrin surface and may thereby behave as a factor regulating the extent of fibrin deposition. These results support our previous data indicating that high levels of Lp(a) may have antifibrinolytic effects in humans (Rouy D et al, Arterioscler Thromb 1991;11:629-638), are in agreement with the observation that Lp(a) is a risk factor for atherosclerotic disease, and provide further support to the view of Lp(a) as a link between atherosclerosis and thrombosis.

The mechanism of activation of plasminogen at the fibrin surface by tissue-type plasminogen activator in a plasma milieu in vitro. Role of alpha 2-antiplasmin

The mechanism of activation of human Glu-plasminogen by fibrin-bound tissue-type plasminogen activator (t-PA) in a plasma environment or in a reconstituted system was characterized. A heterogeneous system was used, allowing the setting of experimental conditions as close as possible to the physiological fibrin/plasma interphase, and permitting the separate analysis of the products present in each of the phases as a function of time. The generation of plasmin was monitored both by spectrophotometric analysis and by radioisotopic analysis with a plasmin-selective chromogenic substrate and radiolabelled Glu-plasminogen respectively. Plasmin(ogen)-derived products were identified by SDS/PAGE followed by autoradiography and/or immunoblotting. When the activation was performed in a plasma environment, the products identified on the fibrin surface were Glu-plasmin (90%) and Glu-plasminogen (10%), whereas in the soluble phase only complexes between Glu-plasmin and its fast-acting inhibitor were detected. Identical results were obtained with a reconstituted system comprising solid-phase fibrin, t-PA, Glu-plasminogen and and alpha 2-antiplasmin. In contrast, when alpha 2-antiplasmin was omitted from the solution, Lys-plasmin was progressively generated on to the fibrin surface (30%) and released to the soluble phase. In the presence of alpha 2-antiplasmin or in plasma, the amount of active plasmin generated on the fibrin surface was lower than in the absence of the inhibitor: in a representative experiment the initial velocity of plasmin generation was 2.8 x 10(-3), 2.0 x 10(-3) and 1.8 x 10(-3) (delta A405/min) for 200 nM-plasminogen, 200 nM-plasminogen plus 100 nM-alpha 2-antiplasmin and native plasma respectively. Our results indicate that in plasma or in a reconstituted purified system containing plasminogen and alpha 2-antiplasmin at a ratio similar to that found in plasma (1) the activation pathway of native Glu-plasminogen proceeds directly to the formation of Glu-plasmin, (2) Lys-plasminogen is not an intermediate of the reaction and therefore (3) Lys-plasmin is not the final active product. However, in the absence of the inhibitor, Lys-plasmin and probably Lys-plasminogen, which is more readily activated to plasmin than is Glu-plasminogen, are generated as well.

Plasminogen carbohydrate side chains in receptor binding and enzyme activation: a study of C6 glioma cells and primary cultures of rat hepatocytes

The human [Glu1]-plasminogen carbohydrate isozymes, plasminogen type I (Pg 1) and plasminogen type II (Pg 2), were separated by chromatography and studied in cell binding experiments at 4 degrees C with primary cultures of rat hepatocytes and rat C6 glioma cells. In both cell systems, Pg 1 and Pg 2 bound to an equivalent number of receptors, apparently representing the same population of surface molecules. The affinity for Pg 2 was slightly higher. With hepatocytes, the KD for Pg 1 was 3.2 +/- 0.2 microM, and the KD for Pg 2 was 1.9 +/- 0.1 microM, as determined from Scatchard transformations of the binding isotherms. The Bmax was approximately the same for both isozymes. With C6 cells, the KD for Pg 1 was 2.2 +/- 0.1 microM vs. 1.5 +/- 0.2 microM for Pg 2. Again, the Bmax was similar with both isozymes. 125I-Pg 1 and 125I-Pg 2 were displaced from specific binding sites by either nonradiolabeled isozyme. The KI for Pg 2 was slightly lower than the KI for Pg 1 with hepatocytes (0.9 vs. 1.3 microM) and with C6 cells (0.6 vs. 1.1 microM). No displacement was detected with miniplasminogen at concentrations up to 5.0 microM. Activation of Pg 1 and Pg 2 by recombinant two-chain tissue-plasminogen activator (rt-PA) was enhanced by hepatocyte cultures. The enhancing effect was greater with Pg 2. Hepatocyte cultures did not affect the activation of miniplasminogen by rt-PA or the activation of plasminogen by streptokinase. Unlike the hepatocytes, C6 cells did not enhance the activation of plasminogen by rt-PA or streptokinase; however, plasmin generated in the presence of C6 cells reacted less readily with alpha 2-antiplasmin.

Effects of N-glycosylation on in vitro activity of Bowes melanoma and human colon fibroblast derived tissue plasminogen activator

Tissue-type plasminogen activator (t-PA), when isolated from human colon fibroblast (hcf) cells, is N-glycosylated differently than when isolated from the Bowes melanoma (m) cell line (Parekh et al., 1988). Both hcf- and m-t-PA can be separated into type I t-PA (with three occupied N-glycosylation sequons, at Asn-117, -184, and -448) and type II t-PA (with two occupied sequons, at Asn-117 and -448). Oligosaccharide analysis of each of these types of t-PA indicates that hcf-t-PA and m-t-PA have no glycoforms in common, despite having the same primary amino acid sequence. We have therefore compared in vitro the enzymatic activities and fibrin binding of type I and type II hcf- and m-t-PA with those of aglycosyl t-PA isolated from tunicamycin-treated cells. Plasminogen activation kinetics were determined by using an indirect amidolytic assay with Glu-plasminogen and a chromogenic plasmin substrate. In the absence of stimulator, there was little difference in activity between type I and type II t-PA, but the activity of aglycosyl t-PA was 2-4-fold higher than that of the corresponding glycosylated t-PA. In the presence of a fibrinogen fragment stimulator, the Kcat value of type II t-PA was approximately 5-fold that of type I t-PA from the same cell line, while the Km values for activation of Glu-plasminogen were similar (0.13-0.18 microM). The stimulated activity of glycosyl t-PA was similar to that of type II t-PA.(ABSTRACT TRUNCATED AT 250 WORDS)

Purification and characterization of natural and recombinant human plasminogen activator inhibitor-1 (PAI-1)

Human plasminogen activator inhibitor-1 (PAI-1) was purified from the conditioned medium of endotoxin-stimulated umbilical vein endothelial cell cultures by combinations of zinc-chelate-Sepharose chromatography, gel filtration on Sephacryl S-300 and immunoadsorption on an insolubilized murine monoclonal antibody (MA-7D4). The final product was obtained with a recovery of approximately 20% from conditioned medium containing about 3 micrograms/ml PAI-1. The yield of PAI-1 was 15-100 micrograms/umbilical cord, depending on the culture and harvest conditions. SDS gel electrophoresis revealed a main band with Mr = 46,000 both under reducing and non-reducing conditions. On gel filtration on Sephacryl S-300, however, the material was separated in two fractions, one eluting at the void volume, which contains active PAI-1, and one with Mr = 46,000 containing inactive material that could be reactivated with 12 M urea. SDS gel electrophoresis of the isolated high-Mr fraction revealed several bands including a main 46,000-Mr component, which reacted with anti-(PAI-1) antibodies on immunoblotting and neutralized tissue-type plasminogen activator (t-PA). The active high-Mr fraction and the reactivated low-Mr fraction of PAI-1 inhibited t-PA very rapidly with an apparent second-order rate constant of (1.5-4) x 10(7) M-1 s-1. The cDNA of endothelial cell PAI-1 was cloned and expressed in Chinese hamster ovary cells. The translation product, purified from conditioned medium of transfected cells, also revealed a high-Mr and a low-Mr fraction on gel filtration, which were indistinguishable from the natural proteins by physicochemical, immunochemical and functional analysis. On reduced SDS gel electrophoresis, the high-Mr fraction was separated into the Mr-46,000 low-Mr PAI-1 and two other components with Mr 65,000 and one barely entering the gel. When reactivated low-Mr PAI-1 was added to plasma, PAI activity and PAI-1 antigen eluted with an apparent Mr greater than or equal to 300,000 on gel filtration, indicating that active PAI-1 complexes with one or more binding proteins in plasma.

The N- and O-linked carbohydrate chains of human, bovine and porcine plasminogen. Species specificity in relation to sialylation and fucosylation patterns

The structures of the N- and O-glycans of human, bovine and porcine plasminogen were determined by 500-MHz 1H-NMR spectroscopy. The N-glycans of all three species proved to be of the N-acetyllactosamine type differing from one another with respect to the sialylation and fucosylation patterns. In the N-glycan of human plasminogen the two antennae are sialylated with N-acetylneuraminic acid (NeuAc), whereas in the bovine counterpart both branches carry significant amounts of N-glycolylneuraminic acid (NeuGc). In porcine plasminogen the sialic acid is mainly NeuAc; the Man alpha 1----6 branch, however, is only partially sialylated. In addition, the porcine N-glycan is fucosylated to about 80% in alpha 1----6 linkage to the GlcNAc-1 residue. The O-glycans of the three species possess an identical Gal beta 1----3GalNAc core which is alpha 2----3 sialylated with NeuAc at Gal. The disialylated form, which is also present in all three species, has an additional NeuAc residue in alpha 2----6 linkage to GalNAc. Mono- and disialylated forms occur in different molar ratios in the different plasminogens: 80:20 in human, 70:30 in bovine and 50:50 in porcine. This study on the carbohydrate moiety of these three plasminogens reveals species specificity in terms of various types of microheterogeneities.

Binding site of alpha 2-plasmin inhibitor to plasminogen

Peptide T-11, a carboxyl terminal tryptic fragment of alpha 2-plasmin inhibitor, inhibits the reversible first step of the reaction between plasmin and alpha 2-plasmin inhibitor. To elucidate which amino-acid residues played a important role in the inhibitory activity of peptide T-11, we prepared the various synthetic derivatives of peptide T-11 and determined the peptide concentration that inhibited the apparent rate constant of the reaction between plasmin and alpha 2-plasmin inhibitor by 50% (IC50). Peptide III, which lacked the residues Gly-1 to Pro-7 of peptide I (peptide T-11), had a strong inhibitory activity, like peptide I (IC50: peptide I, 7 microM; peptide III, 13 microM). The peptides that lacked the Leu-9 and Lys-10 or Lys-26 of peptide III showed much weaker activity, and the loss or amidation of the C-terminal lysine of peptide III also markedly reduced the inhibitory activity. Peptide III competitively inhibited the binding of [14C]tranexamic acid to kringle 1 + 2 + 3 (K1-3) and kringle 4 (K4) in a binding assay performed by the gel-diffusion method. The respective dissociation constants (Kd) of peptide III for K1-3 and K4 were 0.85 microM and 35.2 microM. These data suggest that the amino residue of Lys-10 and the carboxylic acid of Lys-26 in peptide T-11 play crucial roles in the ionic binding of alpha 2-plasmin inhibitor to the tranexamic acid-binding site (lysine-binding site) of plasminogen. Peptide T-11: H-G-D-K-L-F-G-P-D-L-K-L-V-P-P-M-E-E-D-Y-P-Q-F-G-S-P-K-OH.

Effects of kringles derived from human plasminogen on fibrinolysis in vitro

Plasminogen kringle 1+2+3 (K1-3) containing lysine-binding sites inhibited the reaction of plasmin with alpha 2-plasmin inhibitor (alpha 2PI), in a rate assay using a synthetic chromogenic substrate, S-2251. However, K1-3 did not inhibit the reaction to any degree between alpha 2PI and mini-plasmin which lacked the kringle 1 to 4 portion of plasmin. These results suggest that K1-3 blocked the binding of alpha 2PI to the lysine-binding site of plasmin. In the urokinase (UK)-induced fibrinolysis, K1-3 shortened the human plasma clot lysis time at low concentration (0.5-6 microM), and prolonged the lysis time at a high concentration (20 microM). Similar results were obtained in the lysis time of a fibrin clot consisting of plasminogen, fibrinogen and alpha 2PI isolated from human plasma. The kringle 4 (K4) of human plasminogen did not accelerate human plasma clot lysis at any concentration (1.2-24.1 microM). Furthermore, in the tissue plasminogen activator (TPA)-induced fibrinolysis, K1-3 also shortened both the lysis time of human plasma clot and fibrin clot as observed in UK-induced fibrinolysis, but K4 did not. The above findings indicate that the reaction of alpha 2PI with the lysine-binding site of plasmin is involved in the inhibition of plasmin activity by alpha 2PI, and in the presence of an inhibitor of this reaction, the balance of coagulofibrinolytic activity in plasma will be shifted towards the fibrinolytic side.

Characterization of recombinant human alpha 2-antiplasmin and of mutants obtained by site-directed mutagenesis of the reactive site

Human alpha 2-antiplasmin (alpha 2AP) has been expressed in Chinese hamster ovary cells and purified from conditioned media. The recombinant protein (r alpha 2AP) is immunologically identical with natural alpha 2AP and indistinguishable with respect to plasmin(ogen) binding properties. Second-order rate constants (k1) for the interaction of alpha 2AP and r alpha 2AP with plasmin are both (1-2) X 10(7) M-1 s-1. In order to examine the effects of alterations within the reactive site of alpha 2AP, deletions of the P1 residue Arg-364 (r alpha 2AP-delta Arg364) or the P'1 residue Met-365 (r alpha 2AP-delta Met365) were introduced by in vitro site-directed mutagenesis. r alpha 2AP-delta Met365 completely retains its ability to inhibit both plasmin and trypsin, indicating that alpha 2AP has no absolute requirement for Met in the P'1 position. Unexpectedly, no increase in antithrombin activity was observed. r alpha 2AP-delta Arg364 has lost the ability to inhibit plasmin, trypsin, and thrombin, but unlike the wild-type protein, this variant is an effective elastase inhibitor (k1 = 1.5 X 10(5) M-1 s-1).

Differential reactivity of Glu-Gly-Arg-CH2Cl, a synthetic urokinase inhibitor, with single-chain and two-chain forms of urokinase-type plasminogen activator

Glu-Gly-Arg-CH2Cl, a synthetic inhibitor which alkylates the active-site histidine of urokinase with an apparent second-order rate constant of approximately 10(4) M-1 s-1, reacts differently with single-chain and two-chain forms of urokinase-type plasminogen activators (scu-PA and tcu-PA). Kinetic analysis indicated that the plasminogen activating potential of tcu-PA is irreversibly inhibited in a two-step reaction according to (formula; see text) with Ki = 5.0 X 10(-6) M and k2 = 0.05 s-1. The plasminogen-activating potential of scu-PA, however, is competitively inhibited by Glu-Gly-Arg-CH2Cl with Ki = 1.3 X 10(-6) M. Reversibility of the interaction of Glu-Gly-Arg-CH2Cl with scu-PA was confirmed by the restoration of full enzymatic activity after removal of inhibitor. The differential interaction of Glu-Gly-Arg-CH2Cl with scu-PA and tcu-PA supports the hypothesis that these molecular forms of urokinase-type PA have intrinsically different enzymatic properties.

Topography of the high-affinity lysine binding site of plasminogen as defined with a specific antibody probe

An antibody population that reacted with the high-affinity lysine binding site of human plasminogen was elicited by immunizing rabbits with an elastase degradation product containing kringles 1-3 (EDP I). This antibody was immunopurified by affinity chromatography on plasminogen-Sepharose and elution with 0.2 M 6-aminohexanoic acid. The eluted antibodies bound [125I]EDP I, [125I]Glu-plasminogen, and [125I]Lys-plasminogen in radioimmunoassays, and binding of each ligand was at least 99% inhibited by 0.2 M 6-aminohexanoic acid. The concentrations for 50% inhibition of [125I]EDP I binding by tranexamic acid, 6-aminohexanoic acid, and lysine were 2.6, 46, and 1730 microM, respectively. Similar values were obtained with plasminogen and suggested that an unoccupied high-affinity lysine binding site was required for antibody recognition. The antiserum reacted exclusively with plasminogen derivatives containing the EDP I region (EDP I, Glu-plasminogen, Lys-plasminogen, and the plasmin heavy chain) and did not react with those lacking an EDP I region [miniplasminogen, the plasmin light chain or EDP II (kringle 4)] or with tissue plasminogen activator or prothrombin, which also contain kringles. By immunoblotting analyses, a chymotryptic degradation product of Mr 20,000 was derived from EDP I that retained reactivity with the antibody. The high-affinity lysine binding site was equally available to the antibody probe in Glu- and Lys-plasminogen and also appeared to be unoccupied in the plasmin-alpha 2-antiplasmin complex. alpha 2-Antiplasmin inhibited the binding of radiolabeled EDP I, Glu-plasminogen, or Lys-plasminogen by the antiserum, suggesting that the recognized site is involved in the noncovalent interaction of the inhibitor with plasminogen.(ABSTRACT TRUNCATED AT 250 WORDS)

The fibrinolytic system in man

The fibrinolytic system comprises a proenzyme, plasminogen, which can be activated to the active enzyme plasmin, that will degrade fibrin by different types of plasminogen activators. Inhibition of fibrinolysis may occur at the level of plasmin or at the level of the activators. Fibrinolysis in human blood seems to be regulated by specific molecular interactions between these components. In plasma, normally no systemic plasminogen activation occurs. When fibrin is formed, small amounts of plasminogen activator and plasminogen adsorb to the fibrin, and plasmin is generated in situ. The formed plasmin, which remains transiently complexed to fibrin, is only slowly inactivated by alpha 2-antiplasmin, while plasmin, which is released from digested fibrin, is rapidly and irreversibly neutralized. The fibrinolytic process, thus, seems to be triggered by and confined to fibrin. Thrombus formation may occur as the result of insufficient activation of the fibrinolytic system and (or) the presence of excess inhibitors, while excessive activation and/or deficiency of inhibitors might cause excessive plasmin formation and a bleeding tendency. Evidence obtained in animal models suggests that tissue-type plasminogen activator, obtained by recombinant DNA technology, may constitute a specific clot-selective thrombolytic agent with higher specific activity and fewer side effects than those currently in use.

Glu-plasminogen I and II: their activation by urokinase and streptokinase in the presence of fibrin and fibrinogen

Two isozymes of a native form of human plasminogen (plg), Glu-plg I and II, were isolated. Glu-plg I or II was activated by urokinase (UK) or streptokinase (SK) in the presence of fibrinogen or fibrin. The activation of Glu-plg I was enhanced more than that of Glu-plg II in the presence of fibrin. Fibrin caused better activation of both Glu-plg I and II than fibrinogen. When fibrinolysis or fibrinogenolysis was measured, fibrin was degraded faster than fibrinogen after the activation of Glu-plg I and II by UK. These results suggest that the activation of Glu-plg I was enhanced more than that of Glu-plg II in the presence of fibrin or to less extent fibrinogen.

Recurring thromboembolic disease and pulmonary hypertension associated with severe hypoplasminogenemia

In a patient with pulmonary hypertension and a history of recurrent venous thrombosis, plasma concentrations of all known coagulant and inhibitor proteins were normal except for severe deficiency of plasminogen. Repeated analyses showed the circulating plasma plasminogen level to be 30% of normal by either functional or immunologic methods. We sought evidence for either increased activation of plasminogen or for dysplasminogen. There was no evidence for the former. Purified plasminogen studies disclosed a normal number of active sites and normal activation. Generated plasmin had normal catalytic activity. Isoelectric focusing disclosed normal distribution of isoforms. Affinity chromatography with lysine-sepharose showed the presence of the two variant forms; however, an increased proportion of the protein eluted in the first peak. Danazol administration induced an increase in circulating plasminogen, but the differences in affinity chromatography elution profile remained. We conclude that this patient has a deficiency of normally functioning plasminogen, probably due to decreased synthesis.

Fibrinolysis mediated by tissue plasminogen activator. Disclosure of a kinetic transition

The rate of 'Glu'-plasminogen activation by tissue plasminogen activator was repeatedly determined during a fibrinolytic process. The process was found to proceed via two distinct phases. The kinetics of each phase obeyed Michaelis-Menten equation: First phase; kcat about 0.17 s-1 and Km about 1 microM, second phase; kcat about 0.13 s-1 and Km about 0.06 microM. Practically identical results were obtained with one-chain as with two-chain tissue plasminogen activator. Transition from first to second phase occurred when the system had been exposed to a certain degree of plasmin digestion. Electrophoretic analysis demonstrated time correlation between the appearance of minimally degraded fibrin (X-fragments) and the transition. No such correlation was found between transition and conversion of 'Glu'-plasminogen to 'Lys'-plasminogen. The effect can result in an acceleration (up to 13-fold) of the fibrinolytic process once a slight degradation of the fibrin has taken place. In vivo, the effect described may constitute a mechanism that protects a fibrin clot from premature lysis.