[Role of lysine binding sites in activation of plasminogen by streptokinase]. / Rol' lizinsviazyvaiushchikh uchastkov v aktivatsii plazminogena streptokinazoi.

The function of lysine-binding sites in kringle domains K1-4 and K5 of plasminogen (Pg) during its activation by streptokinase (SK) was studied. Activation rates of Glu- and Lys-Pg exceed activation rate of mini- and micro-Pg 26 and 40 times, respectively. 6-Animohexanoic acid (6-AHA) in concentrations from 10(-5) to 10(-2) M inhibits activation of Glu-, Lys- and mini-Pg and does not impact the activation of micro-Pg. Complete inhibition of Lys-Pg activation occurs with presence of 10(-3) M 6-AHA while 90% inhibition of mini-Pg activation and 70% inhibition of Glu-Pg activation occur with 10(-2) M 6-AHA. Isolated kringles K1-3 and K4 of Pg inhibit activation of Glu-Pg by SK and concentrations [I]50 are 4.0 and 8.1 x 10(-6) M, respectively. Catalytic activity of Glu-Pg-SK, Lys-Pg-SK and Pm-SK complexes with respect to S 2251 is not inhibited by 6-AHA in concentrations from 10(-5) to 10(-2) M. Activation of substrate Pg by Pm-SK complex is also inhibited by 6-AHA in concentrations from 10(-5) to 10(-2) M; however, this effect of inhibition is significantly weaker than that with activation by SK. Cleavage of C-terminal Lys or chemical modification of NH2-groups of amino acid residues in SK molecule also results in the decrease of the Glu-Pg activation rate. Lysin-binding sites in K1-4 and K5 of Pg molecule are important at different steps of Pg activation process which includes formation of equimolar complex; structural reorganizations resulted in formation of active center in Pg; and binding of substrate Pg with Pg-SK complex. Lysin-binding sites in K1-4 of Pg are necessary for maintenance of high rate of Pg activation by SK.

[Modifying effect of antiplasminogen monoclonal antibody IV-1c on human plasmin catalytic properties]. / Modifitsiruiushchee deistvie antiplazminogenovogo monoklonal'nogo antitela IV-1c na kataliticheskie svoistva plazmina cheloveka.

Antiplasminogen monoclonal antibody IV-1c (IV-1c) binds to Val 709-Gly 718 site of plasminogen (Pg) protease domain, which is far removed from the active site. Pg-IV-1c complex formation induces catalytic activity in proenzymes active site. Influence of IV-1c binding to plasmin (Pm) on Pm catalytic properties has not been investigated yet. Data on catalytic properties of Pm in equimolar Pm-IV-1c complex are presented. It was found that Pm and mini-Pm amidolytic and caseinolytic activity was twice as high as in Pm-IV-1c and mini-Pm-IV-1c complexes. 20 mM 6-AHA and 100 mM arginine did not influence this rise. The increase of amidolytic activity is connected with reduction of K(m) of S 2251 hydrolysis reaction for Pm and mini-Pm from 0.125 and 0.43 to 0.05 and 0.23 mM, correspondingly. Kcat remains almost the same. Fibrinolytic and fibrinogenolytic activity of Pm in Pm-IV-1c complex decreased to 20% of initial value alpha 2-Antiplasmin inhibited Pm activity in complex Pm-IV-1c by 80%. Pm-IV-1c complex did not activate free Pg, but activated equimolar Pg-IV-1c complex. Affinity of IV-1c to Pm and Pg was the same as C50 approximately 1.5 nM. Binding of Pm with IV-1c in a complex: a) leads to increase of Pm active site affinity to LMW substrates; b) causes steric hindrances for fibrin/fibrinogen access to Pm active site; c) proceeds with the same affinity for Pm and Pg, that indicates to invariable Val 709-Gly 718 site conformation after Pg transition in Pm.

[Degradation of streptokinase and the catalytic properties of the plasmin-streptokinase complex]. / Dehradatsiia streptrokinazy ta katalitichi vlastyvosti plazmin-streptokinaznoho kompleksu.

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

[Isolation and characteristics of antistreptokinase antibodies from blood serum of myocardial infarct patients treated with streptokinase]. / Vydilennia ta kharakterystyka antystreptokinaznykh antytil iz syrovatky krovi khvorykh na infarkt miokarda, iakykh likuvaly streptokinazoiu.

Antistreptokinase IgG (antiSK IgG) from blood of 8 patients with acute myocardial infarction that were treated by streptokinase (SK) has been investigated. AntiSK IgG contained 1.8% of total serum IgG. They had high affinity to SK (K50% approximately 10 nM) and inhibited activation of plasminogen (Pg) by SK with K50% approximately 6 nM. AntiSK IgG were bound with chymothriptic fragments of SK with affinity decreased in the set of fragments: 47 > 36 > 30 > 17 > or = 11 > 7 kDa. 11 linear epitopes of antiSK IgG were localized in I1-S12, T43-M70, G139-Q152, T163-I190, T193-S222, F241-Y252, Y275-P286, T315-L336, I365-E376, S379-T390 and Y397-N410 sites of SK primary structure using SK decapeptides. 70% of antibodies were bound with T43-M70 (38.3%), T315-L336 (13.2%) and Y397-N410 (17.7%) SK sequences located in alpha and gamma SK domains. By depletion of antiSK IgG on Pg-SK complex it was shown that 80-85% of antiSK IgG bound to Pg-SK complex, 47.9% of that contained antibodies with epitopes located in I1-S12, T43-M70, T193-S222 and S379-T390 SK sequences, and rest of IgG had probably spatial epitopes. Unbound with Pg-SK complex antibodies inhibited activation of Pg by SK with higher affinity (Ki approximately 1.2 nM) in comparison with total antiSK IgG fraction. The role of different sites in antigenity of SK and in Pg-SK complex formation is discussed.

[Features of plasminogen activation in a complex with antiplasminogen monoclonal antibody IV-1C]. / Osoblyvosti aktyvatsiï plazminohena v kompleksi z antyplazminohenovim monoklonal'nym antytilom IV-1C.

Antiplasminogen monoclonal antibody IV-1c (IV-1c) with antigenic determinant in V709-G718 site of plasminogen (Pg) protease domain (Druzhina N.N. et al. 1996.) can induce catalytic activity in Pg moiety of the complex. Catalytic activity appeared in Pg-IV-1c complex after approximately 2 h lag-period. Rate of Lys-Pg activation was higher then that of Glu-Pg. Amidolytic activity of Pg-SK equimolar complex was completely inhibited by IV-1c at 2:1 = Pg:IV-1c molar ratio. At constant Glu-Pg concentration increasing of the IV-1c concentration to equimolar of Pg accelerated Pg activation. Subsequent increase of IV-1c concentration inhibited the Pg activation sharply. Increasing of Glu-Pg concentration at constant IV-1c one did not inhibit Glu-Pg activation in Pg-IV-1c complex. The rate dependence of Pg activation from Glu-Pg-IV-1c complex concentration curve had bell-shaped form with maximum at 500 nM. Electrophoretic analysis of components of Glu-Pg-IV-1c complex showed that Lys-Pg and Lys-Pm were not observed at 100 nM complex concentration for 6 h period of reaction. At 680 nM concentration Glu-Pg-IV-1c complex these forms appeared in initial moments of reaction activation after lag-period. Kinetic scheme and peculiarities of Pg activation reaction in Pg-IV-1c complex are discussed.

Evidence that the conformation of unliganded human plasminogen is maintained via an intramolecular interaction between the lysine-binding site of kringle 5 and the N-terminal peptide.

Human Glu-plasminogen adopts at least three conformations that provide a means for regulating the specificity of its activation in vivo. It has been proposed previously that the closed (alpha) conformation of human Glu-plasminogen is maintained through physical interaction of the kringle 5 domain and a lysine residue within the N-terminal peptide (NTP). To examine this hypothesis, site-directed mutagenesis was used to generate variant proteins containing substitutions either for aspartic acid residues within the anionic centre of the kringle 5 domain or for conserved lysine residues within the NTP. Size-exclusion HPLC and rates of plasminogen activation by urokinase-type plasminogen activator were used to determine the conformational states of these variants. Variants with substitutions within the kringle 5 lysine-binding site demonstrated extended conformations, as did variants with alanine substitutions for Lys50 and Lys62. In contrast, molecules in which NTP residues Lys20 or Lys33 were replaced were shown to adopt closed conformations. We conclude that the lysine-binding site of kringle 5 is involved in maintaining the closed conformation of human Glu-plasminogen via an interaction with the NTP, probably through Lys50 and/or Lys62. These conclusions advance the current model for the initial stages of fibrinolysis during which fibrin is thought to compete with the NTP for the kringle 5 lysine-binding site.

Neutralizing antibodies to streptokinase four years after intravenous thrombolytic therapy.

Neutralization antibodies to streptokinase increase to high levels within several days of administration. It is not known how long these high levels persist. The time course of antibody levels needs to be further characterized owing to the increasing need to readminister thrombolytic therapy, and to the possibility that these antibodies may compromise the safety and efficacy of a further dose of streptokinase or streptokinase-containing compounds. In this study, paired streptokinase neutralization titers (in vitro functional assay) and specific antistreptokinase immunoglobulin G (IgG) antibody levels were measured in 145 patients who received streptokinase between 10 and 48 months previously. Serologic evidence of recent streptococcal infection was also sought. Neutralization titers sufficient to inactivate a conventional dose of 1,500,000 units of streptokinase were still present in 50% of patients (95% confidence interval 36-64) at 24 months, 48% (34-62) at 36 months, and 51% (37-71) at 48 months after streptokinase administration. Levels of specific antistreptokinase IgG antibodies also remained constant over the 1- to 4-year period. Neutralization titers were weakly correlated with specific IgG levels (r = 0.35). Antistreptolysin titers > or = 250 and > or = 333 IU/ml were present in 30% (24-38) and 12% (8-18) of these patients, respectively. Neutralization titers were not correlated with antistreptolysin titers. Neutralizing antibodies (assessed by an in vitro functional assay) remained high in 51% of patients 4 years after intravenous streptokinase administration. It is not known whether persisting high in vitro neutralization titers affect the efficacy and safety of repeat administration of streptokinase or streptokinase-containing compounds.

Secretion of urokinase and tissue-plasminogen activator by epidermal cells in the presence of psoriatic fibroblast-conditioned medium.

The present study examined secretion of urokinase and tissue-plasminogen activator by epidermal cells in the presence of psoriatic or uninvolved skin fibroblast-conditioned medium. Using zymographic analyses, a 54kD lysis band and a small 110kD band derived from urokinase could be detected in the harvest fluid from keratinocytes treated with both psoriatic and uninvolved fibroblast-conditioned medium, as well as very weak lysis bands of 63kD and 120kD derived from tissue-plasminogen activator in the harvest fluid treated with psoriatic fibroblast-conditioned medium, but not with uninvolved fibroblast-conditioned medium.

Plasminogen: a structural review.

Plasminogen is the zymogen form of plasmin, a broad specificity serine protease whose activity contributes to a variety of normal and pathological conditions, including intravascular thrombolysis and extracellular proteolysis. Plasminogen contains seven structural units or 'domains', each of which confer specific properties on the molecule. The kringle domains possess fibrin-binding functions and, together with the N-terminal peptide, regulate the ability of plasminogen to adopt at least three dissimilar conformations. These conformational forms influence the rate of formation, following activation by plasminogen activators, of the plasmin active site within its C-terminal serine protease domain. Structural and functional analogies are postulated between these plasminogen structures and the conformations of other proteins related by sequence homology.

The effect of injecting endometriotic 'chocolate' cyst fluid into the peritoneal cavity of mice.

'Chocolate' fluid aspirated from endometriotic cysts was injected into the peritoneal cavity of mice. No peritoneal adhesions or endometriosis were noted when the animals were killed 7-37 days later.

The compact domain conformation of human Glu-plasminogen in solution.

A complete understanding of the accelerating mechanisms of plasminogen activation and fibrinolysis necessarily requires structural information on the conformational forms of plasminogen. Given the absence of high-resolution structural data on plasminogen the use of lower resolution approaches has been adopted. Two such approaches have previously indicated a compact conformation of Glu-plasminogen (Tranqui, L., Prandini, M., and Chapel, A. (1979) Biol. Cellulaire, 34, 39-42; Bányai, L. and Patthy, L. (1985) Biochim. Biophys. Acta, 832, 224-227) whereas a third has suggested a fairly extended conformation (Mangel, W., Lin, B. and Ramakrishnan, V. (1990) Science, 248, 69-73). Native Glu-plasminogen has been investigated using small-angle X-ray scattering (SAXS) experiments. It is concluded that this molecule in solution is compact (radius of gyration, RG 3.05 +/- 0.02 nm and maximum intramolecular distance, Im 9.1 +/- 0.3 nm) and that the data are consistent with the right-handed spiral structure observed using electron microscopy by Tranqui et al. (1979). A spiral structure of native plasminogen would have important implications for the conformational response of plasminogen to fibrin and concomitant stimulation of plasminogen activation.

A hybrid protein of urokinase growth-factor domain and plasminogen-activator inhibitor type 2 inhibits urokinase activity and binds to the urokinase receptor.

The binding of urokinase-type plasminogen activator (uPA) to its specific cell-surface receptor (uPAR) localises the proteolytic cascade initiated by uPA to the pericellular environment. Inhibition of uPA activity or prevention of uPA binding to uPAR might have a beneficial effect on disease states wherein this activity is deregulated, e.g. cancer and some inflammatory diseases. To this end, a bifunctional hybrid molecule consisting of the uPAR-binding growth-factor domain of uPA (amino acids 1-47; GFuPA) at the N-terminus of plasminogen-activator inhibitor type 2 (PAI-2) was produced in Saccharomyces cerevisiae. The purified protein inhibited uPA with kinetics similar to placental or recombinant PAI-2 and was also found to bind to U937 cells and to FL amnion cells. GFuPA-PAI-2 competed with uPA, the N-terminal fragment of uPA and a proteolytic fragment of uPA (amino acids 4-43) in cell binding experiments, indicating that the molecule bound to the cells via uPAR. Hence, both the uPA-inhibitory and uPAR-binding domains of the hybrid molecule were functional, demonstrating the feasibility of the novel concept of introducing an unrelated, functional domain onto a member of the serine-protease-inhibitor superfamily.

Plasminogen activator in human tears.

Measurements were made of the nature and levels of plasminogen activator in human tears using, as a model of inflammation, patients undergoing cataract surgery. Tissue plasminogen activator (t-PA) but not urokinase plasminogen activator (u-PA) was found in tears. A wide variation in the range of t-PA in pre-operative tears was found. In those patients not receiving per-operative subconjunctival betamethasone a significant rise in t-PA was found in tears on the first post-operative day over pre-operative levels. A significant fall was noted in those receiving per-operative subconjunctival betamethasone.