[Modifying effect of antiplasminogen monoclonal antibody IV-1c on human plasmin catalytic properties]

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.

Inhibition of unwanted proteolysis during sample preparation: evaluation of its efficiency in challenge experiments

Measures to counteract proteolysis during sample preparation are widely used; among them, protein extraction at a basic pH (Tris pH 11.0), sample boiling in sodium dodecyl sulfate (SDS), extraction in denaturing lysis solutions and the use of proteinase inhibitors combined with some of these approaches. Here, we tested their efficiency under stringent conditions using a high proteinase (trypsin and a mixture of pancreatic proteinases) contamination and as substrate, streptokinase, a protein highly sensitive to proteolytic degradation. Total degradation was observed in Tris pH 11.0. There was an efficient inhibition for the pancreatic proteinases after boiling in 1% SDS, 1% dithiothreitol (DTT), while trypsin inhibition was dependent on the enzyme-to-substrate ratio. A panel of 21 lysis solutions with variable concentrations of urea, thiourea and detergents was essayed for the ability to counteract proteolysis. In all solutions containing 7-9 M urea, detergents and proteinase inhibitors but not containing thiourea, there was a strong proteolysis. However, in all samples containing 2 M thiourea, proteolysis was inhibited. Moreover, inhibition was dependent on the thiourea concentration. According to these results, we are prompted to consider that the well-known benefits of incorporating thiourea into the lysis solution are a result of two factors, its efficiency in solubilizing proteins and the inhibition of the proteolysis of sensitive substrates; both contributing to the detection of a higher number of species in two-dimensional electrophoresis (2-DE) gels.

The effect of 6-aminohexanoic acid and fucoidan on the activation of glutamic plasminogen by streptokinase

Studies were conducted on the effect of 6-aminohexanoic acid (6-AH) or fucoidan on the activation of glutamic plasminogen (glu-plg) by streptokinase using 0.05 mol/l Tris buffer containing a physiological concentration of NaCl. In contrast to the earlier reports where no NaCl was added to the buffer solution, addition of 6-AH enhanced the initial rate while the inhibition by fucoidan was not affected. Double reciprocal plots of the activation of glu-plg by streptokinase in the presence of 6-AH showed an increase in Vmax, but no change in Km. However, the addition of fucoidan showed a decrease in Vmax, but no change in Km. To determine whether the stimulatory effect of 6-AH was specifically directed towards glu-plg or streptokinase, the ratios of the initial rate of plasmin generation in the presence of 6-AH over the controls were plotted against the inverse of the volume fraction of glu-plg or streptokinase after serial dilutions. The results indicated that the dilutions of glu-plg, but not of streptokinase, influenced the ratios, suggesting an interaction of 6-AH with glu-plg. Similar experiments were conducted to determine the mechanism of inhibition of streptokinase by fucoidan. The results indicated that fucoidan was interacting with streptokinase, but not with glu-plg. Circular dichroism studies of glu-plg in the near-ultraviolet spectra (250-308 nm) showed that addition of 6-AH enhanced the spectra in the region around certain chromophores, which reflected conformational changes. On the contrary, the far-ultraviolet spectra were almost identical.

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

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.

Involvement of a nine-residue loop of streptokinase in the generation of macromolecular substrate specificity by the activator complex through interaction with substrate kringle domains

The selective deletion of a discrete surface-exposed epitope (residues 254-262; 250-loop) in the beta domain of streptokinase (SK) significantly decreased the rates of substrate human plasminogen (HPG) activation by the mutant (SK(del254-262)). A kinetic analysis of SK(del254-262) revealed that its low HPG activator activity arose from a 5-6-fold increase in K(m) for HPG as substrate, with little alteration in k(cat) rates. This increase in the K(m) for the macromolecular substrate was proportional to a similar decrease in the binding affinity for substrate HPG as observed in a new resonant mirror-based assay for the real-time kinetic analysis of the docking of substrate HPG onto preformed binary complex. In contrast, studies on the interaction of the two proteins with microplasminogen showed no difference between the rates of activation of microplasminogen under conditions where HPG was activated differentially by nSK and SK(del254-262). The involvement of kringles was further indicated by a hypersusceptibility of the SK(del254-262).plasmin activator complex to epsilon-aminocaproic acid-mediated inhibition of substrate HPG activation in comparison with that of the nSK.plasmin activator complex. Further, ternary binding experiments on the resonant mirror showed that the binding affinity of kringles 1-5 of HPG to SK(del254-262).HPG was reduced by about 3-fold in comparison with that of nSK.HPG . Overall, these observations identify the 250 loop in the beta domain of SK as an important structural determinant of the inordinately stringent substrate specificity of the SK.HPG activator complex and demonstrate that it promotes the binding of substrate HPG to the activator via the kringle(s) during the HPG activation process.

[Activation of key proenzymes of the blood coagulation system by the fibrin E fragment]

Plasminogen and prothrombin are key proenzymes of fibrinolytic and clotting system. It is known that they can be activated by indirect activators streptokinase and staphylocoagulase. In this paper it is shown that fibrin E fragment purified from DD-E complex induced catalytic activity in plasminogen and clotting activity in prothrombin. Streptokinase increased 2 times the rate of catalytic activity induction by E fragment in prothrombin. It's possibly that process is one of the factors providing for rethrombosis after thrombolytic therapy of myocardial infarction.

Specificity role of the streptokinase C-terminal domain in plasminogen activation

Several pathogenic bacteria secrete plasminogen activator proteins. Streptokinase (SKe) produced by Streptococcus equisimilis and staphylokinase secreted from Staphylococcus aureus are human plasminogen activators and streptokinase (SKu), produced by Streptococcus uberis, is a bovine plasminogen activator. Thus, the fusion proteins among these activators can explain the function of each domain of SKe. Replacement of the SKalpha domain with staphylokinase donated the staphylokinase-like activation activity to SKe, and the SKbetagamma domain played a role of nonproteolytic activation of plasminogen. Recombinant SKu also activated human plasminogen by staphylokinase-like activation mode. Because SKu has homology with SKe, the bovine plasminogen activation activities of SKe fragments were checked. SKebetagamma among them had activation activity with bovine plasminogen. This means that the C-terminal domain (gamma-domain) of streptokinase determines plasminogen species necessary for activation and converses the ability of substrate recognition to human species.

Effect of earthworm (G-90) extract on formation and lysis of clots originated from venous blood of dogs with cardiopathies and with malignant tumors

The stability of homeostasis is important to keep a balance between coagulation and fibrinolysis. A disorder of homeostasis leads to different physiological changes and causes different diseases such as cardiopathies and malignant tumors. Cardiopathies is characterized by a hypercoagulation. In the malignant tumors, besides the hypercoagulation due to plasminogen activators (PA) formed inside the tumor, a disorder of homeostasis leads also to acceleration of the fibrinolysis. The variety of internal and external factors in both cases determine the deviation of time for the clots formation, as well as the lyses of blood and fibrin clots. In this study the venous blood as well as the blood and the fibrin clots, derived from healthy dogs, the dogs with cardiopathies and with malignant tumors, were examined for the time of coagulation and fibrinolysis by adding different substances. In these experiments we used a glycolipoprotein extract from earthworm tissue homogenate (G-90) and the proteolytic enzymes P I and P II, isolated from G-90. The efficacy of the tested substances was comparable with the clinically administered anticoagulants. The most significant differences in clotting time among the three tested groups of dogs were obtained by application of the original G-90. The results suggest a possibility that G-90, along with the fibrinolytic enzymes and other biologically active factors, also contains a factor that decelerates the formation of clot in a specific medium, such as the blood from the dogs with malignant tumors.

Domain interactions between streptokinase and human plasminogen

Plasmin (Pm), the main fibrinolytic protease in the plasma, is derived from its zymogen plasminogen (Plg) by cleavage of a peptide bond at Arg(561)-Val(562). Streptokinase (SK), a widely used thrombolytic agent, is an efficient activator of human Plg. Both are multiple-domain proteins that form a tight 1:1 complex. The Plg moiety gains catalytic activity, without peptide bond cleavage, allowing the complex to activate other Plg molecules to Pm by conventional proteolysis. We report here studies on the interactions between individual domains of the two proteins and their roles in Plg activation. Individually, all three SK domains activated native Plg. While the SK alpha domain was the most active, its activity was uniquely dependent on the presence of Pm. The SK gamma domain also induced the formation of an active site in Plg(R561A), a mutant that resists proteolytic activation. The alpha and gamma domains together yielded synergistic activity, both in Plg activation and in Plg(R561A) active site formation. However, the synergistic activity of the latter was dependent on the correct N-terminal isoleucine in the alpha domain. Binding studies using surface plasmon resonance indicated that all three domains of SK interact with the Plg catalytic domain and that the beta domain additionally interacts with Plg kringle 5. These results suggest mechanistic steps in SK-mediated Plg activation. In the case of free Plg, complex formation is initiated by the rapid and obligatory interaction between the SK beta domain and Plg kringle 5. After binding of all SK domains to the catalytic domain of Plg, the SK alpha and gamma domains cooperatively induce the formation of an active site within the Plg moiety of the activator complex. Substrate Plg is then recognized by the activator complex through interactions predominately mediated by the SK alpha domain.

Coiled coil region of streptokinase gamma-domain is essential for plasminogen activation

The specific functions of the amino acid residues in the streptokinase (SK) gamma-domain were analyzed by studying the interactions of human plasminogen (HPlg) and SK mutants prepared by charge-to-alanine mutagenesis. SK with mutations of groups of amino acids outside the coiled coil region of SK gamma-domain, SK(K278A,K279A,E281A,K282A), and SK(D360A,R363A) had similar HPlg activator activities as wild-type SK. However, significant changes of the functions of SK with mutations within the coiled coil region were observed. Both SK(D322A,R324A,D325A) and SK(R330A,D331A,K332A,K334A) had decreased amounts of complex formation with microplasminogen and failed to activate HPlg. SK(D328A,R330A) had a 21-fold reduced catalytic efficiency for HPlg activation. The studies of SK with single amino acid mutation to Ala demonstrate that Arg(324), Asp(325), Lys(332), and Lys(334) play important roles in the formation of a HPlg.SK complex. On the other hand, amino acid residues Asp(322), Asp(328), and Arg(330) of SK are involved in the virgin enzyme induction. Potential contact between Lys(332) of SK and Glu(623) of human microplasmin and strong interactions between Asp(328) and Lys(330), Asp(331) and Lys(334), and Asp(322) and Lys(334) of SK are noticed. These interactions are important in maintaining a coiled coil conformation. Therefore, we conclude that the coiled coil region of SK gamma-domain, SK(Leu(314)-Ala(342)), plays very important roles in HPlg activation by participating in virgin enzyme induction and stabilizing the activator complex.

The mechanism of a bacterial plasminogen activator intermediate between streptokinase and staphylokinase

The therapeutic properties of plasminogen activators are dictated by their mechanism of action. Unlike staphylokinase, a single domain protein, streptokinase, a 3-domain (alpha, beta, and gamma) molecule, nonproteolytically activates human (h)-plasminogen and protects plasmin from inactivation by alpha(2)-antiplasmin. Because a streptokinase-like mechanism was hypothesized to require the streptokinase gamma-domain, we examined the mechanism of action of a novel two-domain (alpha,beta) Streptococcus uberis plasminogen activator (SUPA). Under conditions that quench trace plasmin, SUPA nonproteolytically generated an active site in bovine (b)-plasminogen. SUPA also competitively inhibited the inactivation of plasmin by alpha(2)-antiplasmin. Still, the lag phase in active site generation and plasminogen activation by SUPA was at least 5-fold longer than that of streptokinase. Recombinant streptokinase gamma-domain bound to the b-plasminogen.SUPA complex and significantly reduced these lag phases. The SUPA-b.plasmin complex activated b-plasminogen with kinetic parameters comparable to those of streptokinase for h-plasminogen. The SUPA-b.plasmin complex also activated h-plasminogen but with a lower k(cat) (25-fold) and k(cat)/K(m) (7.9-fold) than SK. We conclude that a gamma-domain is not required for a streptokinase-like activation of b-plasminogen. However, the streptokinase gamma-domain enhances the rates of active site formation in b-plasminogen and this enhancing effect may be required for efficient activation of plasminogen from other species.

Multidomain structure of a recombinant streptokinase. A differential scanning calorimetry study

The temperature dependence of the heat capacity function of a recombinant streptokinase (rSK) has been studied by high-sensitivity differential scanning microcalorimetry and circular dichroism as a function of pH in low- and high-ionic strength buffers. At low ionic strength it is found that this protein, between pH 7 and 10, undergoes four reversible and independent two-state transitions during its unfolding, suggesting the existence of four domains in the native structure of the protein. This result reconciles previous conflicting reports about the number of domains of this protein obtained by differential scanning calorimetry and small-angle X-ray scattering. The number of two-state transitions decreases when the pH of the medium is decreased, without noticeable changes in its circular dichroism spectrum. A plausible localization of the four domains in the streptokinase sequences is proposed and their thermodynamic parameters are given. Increase of ionic strength to 200 mM NaCl affects positively the protein stability and confirms the existence of four reversible two-state transitions. Above 200 mM NaCl the protein stability decreases, resulting in low percentage of reversibility, and even irreversible transitions.

Biochemical characterization of signal peptidase I from gram-positive Streptococcus pneumoniae

Bacterial signal peptidase I is responsible for proteolytic processing of the precursors of secreted proteins. The enzymes from gram-negative and -positive bacteria are different in structure and specificity. In this study, we have cloned, expressed, and purified the signal peptidase I of gram-positive Streptococcus pneumoniae. The precursor of streptokinase, an extracellular protein produced in pathogenic streptococci, was identified as a substrate of S. pneumoniae signal peptidase I. Phospholipids were found to stimulate the enzymatic activity. Mutagenetic analysis demonstrated that residues serine 38 and lysine 76 of S. pneumoniae signal peptidase I are critical for enzyme activity and involved in the active site to form a serine-lysine catalytic dyad, which is similar to LexA-like proteases and Escherichia coli signal peptidase I. Similar to LexA-like proteases, S. pneumoniae signal peptidase I catalyzes an intermolecular self-cleavage in vitro, and an internal cleavage site has been identified between glycine 36 and histidine 37. Sequence analysis revealed that the signal peptidase I and LexA-like proteases show sequence homology around the active sites and some common properties around the self-cleavage sites. All these data suggest that signal peptidase I and LexA-like proteases are closely related and belong to a novel class of serine proteases.

Leucine 42 in the fibronectin motif of streptokinase plays a critical role in fibrin-independent plasminogen activation

The NH(2) terminus (residues 1-59) of streptokinase (SK) is a molecular switch that permits fibrin-independent plasminogen activation. Targeted mutations were made in recombinant (r) SK1-59 to identify structural interactions required for this process. Mutagenesis established the functional roles of Phe-37and Glu-39, which were projected to interact with microplasmin in the activator complex. Mutation of Leu-42 (rSK1-59(L42A)), a conserved residue in the SK fibronectin motif that lacks interactions with microplasmin, strongly reduced plasminogen activation (k(cat) decreased 50-fold) but not amidolysis (k(cat) decreased 1.5-fold). Otherwise rSK1-59(L42A) and native rSK1-59 were indistinguishable in several parameters. Both displayed saturable and specific binding to Glu-plasminogen or the remaining SK fragment (rSKDelta59). Similarly rSK1-59 and rSK1-59(L42A) bound simultaneously to two different plasminogen molecules, indicating that both plasminogen binding sites were intact. However, when bound to SKDelta59, rSK1-59(L42A) was less effective than rSK1-59 in restructuring the native conformation of the SK A domain, as detected by conformation-dependent monoclonal antibodies. In the light of previous studies, these data provide evidence that SK1-59 contributes to fibrin-independent plasminogen activation through 1) intermolecular interactions with the plasmin in the activator complex, 2) binding interactions with the plasminogen substrate, and 3) intramolecular interactions that structure the A domain of SK for Pg substrate processing.

Streptokinase binds preferentially to the extended conformation of plasminogen through lysine binding site and catalytic domain interactions

Binding of streptokinase (SK) to plasminogen (Pg) activates the zymogen conformationally and initiates its conversion into the fibrinolytic proteinase, plasmin (Pm). Equilibrium binding studies of SK interactions with a homologous series of catalytic site-labeled fluorescent Pg and Pm analogues were performed to resolve the contributions of lysine binding site interactions, associated changes between extended and compact conformations of Pg, and activation of the proteinase domain to the affinity for SK. SK bound to fluorescein-labeled [Glu]Pg(1) and [Lys]Pg(1) with dissociation constants of 624 +/- 112 and 38 +/- 5 nM, respectively, whereas labeled [Lys]Pm(1) bound with a 57000-fold tighter dissociation constant of 11 +/- 2 pM. Saturation of lysine binding sites with 6-aminohexanoic acid had no effect on SK binding to labeled [Glu]Pg(1), but weakened binding to labeled [Lys]Pg(1) and [Lys]Pm(1) 31- and 20-fold, respectively. At low Cl(-) concentrations, where [Glu]Pg assumes the extended conformation without occupation of lysine binding sites, a 23-fold increase in the affinity of SK for labeled [Glu]Pg(1) was observed, which was quantitatively accounted for by expression of new lysine binding site interactions. The results support the conclusion that the SK affinity for the fluorescent Pg and Pm analogues is enhanced 13-16-fold by conversion of labeled [Glu]Pg to the extended conformation of the [Lys]Pg derivative as a result of lysine binding site interactions, and is enhanced 3100-3500-fold further by the increased affinity of SK for the activated proteinase domain. The results imply that binding of SK to [Glu]Pg results in transition of [Glu]Pg to an extended conformation in an early event in the SK activation mechanism.

Asp41-His48 region of streptokinase is important in binding to a substrate plasminogen

Streptokinase is a plasminogen activator protein produced by several strains of beta-hemolytic streptococci. Random mutagenesis of streptokinase was carried out for the determination of critical amino acid residues in plasminogen activation. We selected and sequenced 14 streptokinase mutants with no plasminogen activation activity on skim milk-plasminogen overlay plate. Specific activities of the selected streptokinase mutants were determined with chromogenic assay. Eight mutants (V19F, V35E, E85D, L292R, D325P, D341E, I345N, and M369L) resulted in greatly decreased amidolytic activities. However, unexpectedly, six mutants (D41C, S44K, S44P, R45P, H48T, and D220G) showed substantial amidolytic activities comparable to that of wild type. Moreover, five-point mutations were concentrated on the Asp41-His48 region. These data indicate that the Asp41-His48 region in a streptokinase-plasminogen binary complex plays an important role in binding to a substrate plasminogen.

Interaction of group A streptococci with human plasmin(ogen) under physiological conditions

A series of methods for analyzing the interaction of group A streptococci with the human plasminogen system are described. Examples of group A streptococcal isolates capable of assembling surface plasminogen activator activity when grown in human plasma are presented and the key requirements for this process are evaluated. The stabilities of cell-associated plasmin and plasminogen activator complexes are compared and a model for the interaction of group A streptococci with the plasminogen system in an infected host is presented.

Kinetic and structural characterization of a two-domain streptokinase: dissection of domain functionality

The mammalian protease plasminogen can be activated by bacterial activators, the three-domain (alpha, beta, gamma) streptokinases and the one-domain (alpha) staphylokinases. These activators act as plasmin(ogen) cofactors, and the resulting complexes initiate proteolytic activity of host plasminogen which facilitates bacterial colonization of the host organism. We have investigated the kinetic mechanism of the plasminogen activation mediated by a novel two-domain (alpha, beta) streptokinase isolated from Streptococcus uberis (Sk(U)) with specificity toward bovine plasminogen. The interaction between Sk(U) and plasminogen occurred in two steps: (1) rapid association of the proteins and (2) slow transition to the active complex Sk(U)-PgA. The complex Sk(U)-PgA converted plasminogen to plasmin with the following parameters: K(m) < or = 1.5 microM and k(cat) = 0.55 s(-)(1). The ability of proteolytic fragments of Sk(U) to activate plasminogen was investigated. Only two C-terminal segments (97-261 and 123-261), which both contain the beta-domain (126-261), were shown to be active. They initiated plasminogen activation in complex with plasmin, but not with plasminogen, and thereby exhibited functional similarity to the staphylokinase. The fusion protein His(6)-Sk(U) (i.e., Sk(U) with a small N-terminal tag) acted exclusively in complex with plasmin as well. These observations demonstrate that (1) the N-terminal alpha-domain, including a native N-terminus, was necessary for "virgin" activation of the associated plasminogen in the Sk(U)-PgA complex and (2) the C-terminal beta-domain of Sk(U) is important for recognition of the substrate in the Sk(U)-PgA complex.

Streptokinase binds to human plasmin with high affinity, perturbs the plasmin active site, and induces expression of a substrate recognition exosite for plasminogen

Binding of streptokinase (SK) to plasminogen (Pg) conformationally activates the zymogen and converts both Pg and plasmin (Pm) into specific Pg activators. The interaction of SK with Pm and its relationship to the mechanism of Pg activation were evaluated in equilibrium binding studies with active site-labeled fluorescent Pm derivatives and in kinetic studies of SK-induced changes in the catalytic specificity of Pm. SK bound to fluorescein-labeled and native Pm with dissociation constants of 11 +/- 2 pm and 12 +/- 4 pm, which represented a 1,000-10,000-fold higher affinity than determined for Pg. Stoichiometric binding of SK to native Pm was followed by generation of a two-fragment form of SK cleaved at Lys(59) (SK'), which exhibited an indistinguishable affinity for labeled Pm, while a truncated, SK(55-414) species had a 120-360-fold reduced affinity. Binding of SK to native Pm was accompanied by a >50-fold enhancement in specificity for activation of Pg, which was paralleled by a surprising 2.6-10-fold loss of specificity of Pm for 8 of 11 tripeptide-pNA substrates. Further studies with Pm labeled at the active site with 2-anilinonaphthalene-6-sulfonic acid demonstrated directly that binding of SK to Pm resulted in expression of a new substrate binding exosite for Pg on the SK.Pm complex. It is concluded that SK activates Pg in part by preferential binding to the active zymogen conformation. High affinity binding of SK to Pm enhances Pg substrate specificity principally through emergence of a substrate recognition exosite.

Epsilon amino caproic acid inhibits streptokinase-plasminogen activator complex formation and substrate binding through kringle-dependent mechanisms

Lysine side chains induce conformational changes in plasminogen (Pg) that regulate the process of fibrinolysis or blood clot dissolution. A lysine side-chain mimic, epsilon amino caproic acid (EACA), enhances the activation of Pg by urinary-type and tissue-type Pg activators but inhibits Pg activation induced by streptokinase (SK). Our studies of the mechanism of this inhibition revealed that EACA (IC(50) 10 microM) also potently blocked amidolytic activity by SK and Pg at doses nearly 10000-fold lower than that required to inhibit the amidolytic activity of plasmin. Different Pg fragments were used to assess the role of the kringles in mediating the inhibitory effects of EACA: mini-Pg which lacks kringles 1-4 of Glu-Pg and micro-Pg which lacks all kringles and contains only the catalytic domain. SK bound with similar affinities to Glu-Pg (K(A) = 2.3 x 10(9) M(-1)) and to mini-Pg (K(A) = 3.8 x 10(9) M(-)(1)) but with significantly lower affinity to micro-Pg (K(A) = 6 x 10(7) M(-)(1)). EACA potently inhibited the binding of Glu-Pg to SK (K(i) = 5.7 microM), but was less potent (K(i) = 81.1 microM) for inhibiting the binding of mini-Pg to SK and had no significant inhibitory effects on the binding of micro-Pg and SK. In assays simulating substrate binding, EACA also potently inhibited the binding of Glu-Pg to the SK-Glu-Pg activator complex, but had negligible effects on micro-Pg binding. Taken together, these studies indicate that EACA inhibits Pg activation by blocking activator complex formation and substrate binding, through a kringle-dependent mechanism. Thus, in addition to interactions between SK and the protease domain, interactions between SK and the kringle domain(s) play a key role in Pg activation.

Characteristics of glycosylated streptokinase secreted from Pichia pastoris: enhanced resistance of SK to proteolysis by glycosylation

Degradation of streptokinase (SK) has been frequently observed during large-scale protein production. An enhanced susceptibility of SK to degradation has been correlated with its existence in a partially unfolded state. The influence of the carbohydrate moiety on the stability and functional characteristics of SK has been examined by obtaining the glycoform of SK following its secretion through the methylotrophic yeast Pichia pastoris. Secretion of the protein product was achieved by replacing the native secretion signal codons of SK with those from alpha-factor leader peptide and expressing the fusion construct under the control of the methanol-inducible alcohol oxidase (ox) promoter of P. pastoris after its integration into the host chromosome. Western blot and zymographic analysis of proteins secreted from the recombinant P. pastoris indicated that SK was glycosylated by the host cells, which resulted in the appearance of a SK species migrating slowly, corresponding to a 55-kDa protein product as compared to the 47-kDa native SK. The glycosylated SK retained a plasminogen activation capability identical to that of its unglycosylated counterpart. Glycoform SK exhibited an enhanced stability profile at 25 degrees C and 37 degrees C and improved resistance towards protease treatment compared to unglycosylated SK secreted through P. pastoris after tunicamycin treatment or that secreted from the recombinant Escherichia coli. The results presented thus illustrate that N-linked glycosylation of SK results in 30-40% enhancement of the protein stability and resistance towards degradation but does not interfere with its fibrinolytic function.

Molecular mechanisms of plasminogen activation: bacterial cofactors provide clues

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

Human plasminogen catalytic domain undergoes an unusual conformational change upon activation

Activation of the serine protease plasmin from its zymogen, plasminogen, is the key step in fibrinolysis leading to blood clot dissolution. It also plays critical roles in cell migration, such as in tumor metastasis. Here, we report the crystal structure of an inactive S741A mutant of human plasminogen catalytic domain at 2.0 A resolution. This structure permits a direct comparison with that of the plasmin catalytic unit. Unique conformational differences are present between these two structures that are not seen in other zymogen-enzyme pairs of the trypsin family. The functional significance of these differences and the structural basis of plasminogen activation is discussed in the light of this new structure.

Cloning, expression, sequence analysis, and characterization of streptokinases secreted by porcine and equine isolates of Streptococcus equisimilis

Streptokinases secreted by nonhuman isolates of group C streptococci (Streptococcus equi, S. equisimilis, and S. zooepidemicus) have been shown to bind to different mammalian plasminogens but exhibit preferential plasminogen activity. The streptokinase genes from S. equisimilis strains which activated either equine or porcine plasminogen were cloned, sequenced, and expressed in Escherichia coli. The streptokinase secreted by the equine isolate had little similarity to any known streptokinases secreted by either human or porcine isolates. The streptokinase secreted by the porcine isolate had limited structural and functional similarities to streptokinases secreted by human isolates. Plasminogen activation studies with immobilized (His)(6)-tagged recombinant streptokinases indicated that these recombinant streptokinases interacted with plasminogen in a manner similar to that observed when streptokinase and plasminogen interact in the fluid phase. Analysis of the cleavage products of the streptokinase-plasminogen interaction indicated that human, equine, and porcine plasminogens were all cleaved at the same highly conserved site. The site at which streptokinase was cleaved to form altered streptokinase (Sk*) was also determined. This study confirmed not only the presence of streptokinases in nonhuman S. equisimilis isolates but also that these proteins belong to a family of plasminogen activators more diverse than previously thought.

Species specificity of plasminogen activation and acquisition of surface-associated proteolytic activity by group C streptococci grown in plasma

Our laboratory previously demonstrated that group C streptococcal isolates from humans and horses secrete streptokinases that preferentially activate plasminogens reflecting the origin of the isolates. To analyze the significance of these findings, series of streptokinase-producing Streptococcus equisimilis isolates recovered from humans and horses were examined. Southern blot analysis revealed that chromosomal DNA of the streptococcal isolates from humans reacted exclusively with a skc(hu) probe and that chromosomal DNA of streptococcal isolates from horses reacted preferentially with an skc(eq) probe in a distinct pattern. The streptococcal isolates were examined for the ability to acquire surface-bound plasmin-like activity when grown in the presence of human or equine plasma. Each of eight isolates from humans acquired significant enzymatic activity only when grown in the presence of human plasma, while each of eight isolates from horses acquired activity only when grown in the presence of equine plasma. Analysis of bacterial and host protein requirements indicated critical roles for streptokinase, activatable plasminogen, and fibrinogen. These requirements may explain why certain streptococcal isolates cause disease only in a limited number of mammalian hosts.

Function of the central domain of streptokinase in substrate plasminogen docking and processing revealed by site-directed mutagenesis

The possible role of the central beta-domain (residues 151-287) of streptokinase (SK) was probed by site-specifically altering two charged residues at a time to alanines in a region (residues 230-290) previously identified by Peptide Walking to play a key role in plasminogen (PG) activation. These mutants were then screened for altered ability to activate equimolar "partner" human PG, or altered interaction with substrate PG resulting in an overall compromised capability for substrate PG processing. Of the eight initial alanine-linker mutants of SK, one mutant, viz. SK(KK256.257AA) (SK-D1), showed a roughly 20-fold reduction in PG activator activity in comparison to wild-type SK expressed in Escherichia coli (nSK). Five other mutants were as active as nSK, with two [SK(RE248.249AA) and SK(EK281.282AA), referred to as SK(C) and SK(H), respectively] showing specific activities approximately one-half and two-thirds, respectively, that of nSK. Unlike SK(C) and SK(H), however, SK(D1) showed an extended initial delay in the kinetics of PG activation. These features were drastically accentuated when the charges on the two Lys residues at positions 256 and 257 of nSK were reversed, to obtain SK(KK256.257EE) [SK(D2)]. This mutant showed a PG activator activity approximately 10-fold less than that of SK(D1). Remarkably, inclusion of small amounts of human plasmin (PN) in the PG activation reactions of SK(D2) resulted in a dramatic, PN dose-dependent rejuvenation of its PG activation capability, indicating that it required pre-existing PN to form a functional activator since it could not effect active site exposure in partner PG on its own, a conclusion further confirmed by its inability to show a "burst" of p-nitrophenol release in the presence of equimolar human PG and p-nitrophenyl guanidino benzoate. The steady-state kinetic parameters for HPG activation of its 1:1 complex with human PN revealed that although it could form a highly functional activator once "supplied" with a mature active site, the Km for PG was increased nearly eightfold in comparison to that of nSK-PN. SK mutants carrying simultaneous two- and three-site charge-cluster alterations, viz., SK(RE24249AA:EK281.282AA) [SK(CH)], SK(EK272.273AA;EK281.282AA) [SK(FH)], and SK(RE248.249AA;EK272.273AA:EK281.282AA+ ++) [SK(CFH)], showed additive/synergistic influence of multiple charge-cluster mutations on HPG activation when compared to the respective "single-site" mutants, with the "triple-site" mutant [SK(CFH)] showing absolutely no detectable HPG activation ability. Nevertheless, like the other constructs, the double- and triple-charge cluster mutants retained a native like affinity for complexation with partner PG. Their overall structure also, as judged by far-ultraviolet circular dichroism, was closely similar to that of nSK. These results provide the first experimental evidence for a direct assistance by the SK beta-domain in the docking and processing of substrate PG by the activator complex, a facet not readily evident probably because of the flexibility of this domain in the recent X-ray crystal structure of the SK-plasmin light chain complex.

Identification of pel, a Streptococcus pyogenes locus that affects both surface and secreted proteins

A Tn917 insertion mutant of an M49 serotype, opacity factor-positive Streptococcus pyogenes, was isolated. It had the following phenotypes: decreased beta-hemolysis mediated by streptolysin S, reduction in the activity of a secreted cysteine protease and streptokinase, and an altered immunoglobulin and fibrinogen-binding phenotype. The site of insertion of Tn917 into the chromosome and the surrounding sequence, the pel region (pleiotropic effect locus), was determined. Phage A25 transduction confirmed that the pleiotropic changes in phenotype could be cotransduced with Tn917. The pel region was cloned and sequenced, and the transposon was found to be inserted upstream of a single open reading frame which led to a failure to transcribe a 500-base mRNA. The loss of this transcript decreased the transcription of emm and speB genes and reduced the secretion of streptokinase. Enhanced Pel expression from a nisin-inducible plasmid resulted in increased message levels for emm in a wild-type organism. Characterization of the pel mutant provides evidence for the coordinated regulation of secreted and surface proteins and suggests the existence of a new global regulatory factor in S. pyogenes.

[Plasminogen binding with decapeptide and polypeptide fragments of streptokinase]

The plasminogen binding with streptokinase decapeptides, modeling the primary structure of molecule, and chymotryptic fragments of streptokinase have been investigated. The immunoenzymatic assay has shown that plasminogen binds to all streptokinase fragments with the decreasing affinity in the set of fragments: 36 > 30 > 17 > 7 > 11 kDa. Location of the binding sites in streptokinase primary structure was performed using the immobilized decapeptides on plastic pins adopted to IEA. In the presence of 10 mM 6-aminohexanoic acid 11 sites for human Glu- and mini-plasminogens, pig and bovine plasminogens binding have been found. They were of the same location for human, bovine and pig plasminogens. 3 sites were located in plasminogen alpha-domain--T43-A72, N113-T126, Q133-V158, 5 sites in beta-domain--T163-L188, A203-S222, Q239-I264, Y275-L294, T315-L340, and 3 sites in gamma-domain--T361-R362, N377-E392, T397-N410. Participation of linear part of streptokinase polypeptide chain in plasminogen--streptokinase complex formation is suggested.

A catalytic switch and the conversion of streptokinase to a fibrin-targeted plasminogen activator

Plasminogen (Pg) activators such as streptokinase (SK) save lives by generating plasmin to dissolve blood clots. Some believe that the unique ability of SK to activate Pg in the absence of fibrin limits its therapeutic utility. We have found that SK contains an unusual NH(2)-terminal "catalytic switch" that allows Pg activation through both fibrin-independent and fibrin-dependent mechanisms. Unlike SK, a mutant (rSKDelta59) fusion protein lacking the 59 NH(2)-terminal residues was no longer capable of fibrin-independent Pg activation (k(cat)/K(m) decreased by >600-fold). This activity was restored by coincubation with equimolar amounts of the NH(2)-terminal peptide rSK1-59. Deletion of the NH(2) terminus made rSKDelta59 a Pg activator that requires fibrin, but not fibrinogen, for efficient catalytic function. The fibrin-dependence of the rSKDelta59 activator complex apparently resulted from selective catalytic processing of fibrin-bound Pg substrates in preference to other Pg forms. Consistent with these observations, the presence (rSK) or absence (rSKDelta59) of the SK NH(2)-terminal peptide markedly altered fibrinolysis of human clots suspended in plasma. Like native SK, rSK produced incomplete clot lysis and complete destruction of plasma fibrinogen; in contrast, rSKDelta59 produced total clot lysis and minimal fibrinogen degradation. These studies indicate that structural elements in the NH(2) terminus are responsible for SK's unique mechanism of fibrin-independent Pg activation. Because deletion of the NH(2) terminus alters SK's mechanism of action and targets Pg activation to fibrin, there is the potential to improve SK's therapeutic efficacy.

[Val709-Glu724 streptokinase binding site on plasminogen interacts with streptokinase sequence Thr361-Arg372 during plasminogen-streptokinase complex formation]

Localization of the human plasminogen binding site on the streptokinase of complementary Val709-Glu724 plasminogen being crucial one in providing for the plasminogen streptokinase complex activity has been investigated. Experiments were performed with streptokinase fragments and synthetic decapeptides, antiplasminogen monoclonal anti-body IV-1c and synthetic peptide corresponding to Val709-Gly718 sequence of human plasminogen. It was found that plasminogen sequence Val709-Glu724 interacted with Thr361-Arg372 sequence of strepto-kinase.

Deletion of Ile1 changes the mechanism of streptokinase: evidence for the molecular sexuality hypothesis

Plasminogen (Plgn) is usually activated by proteolytic cleavage of Arg561-Val562. The new N-terminal amino group of Val562 forms a salt bridge with Asp740, creating the active protease plasmin (Pm). However, streptokinase (SK) binds to Plgn, generating an active protease in a poorly understood, nonproteolytic process. We hypothesized that the N-terminus of SK, Ile1, substitutes for the N-terminal Val562 of Pm, forming an analogous salt bridge with Asp740. SK initially forms an inactive complex with Plgn, which subsequently rearranges to create an active complex; this rearrangement is rate limiting at 4 degrees C. SK.Plgn efficiently hydrolyzes amide substrates at 4 degrees C, although DeltaIle1-SK. Plgn has no amidolytic activity. DeltaIle1-SK prevents formation of wild-type SK.Plgn. These results indicate that DeltaIle1-SK forms the initial inactive complex with plasminogen, but cannot form the active complex. However, when the experiment is performed at 37 degrees C, amidolytic activity is observed when DeltaIle1-SK is added to plasminogen. SDS-PAGE analysis demonstrates that the amidolytic activity results from the formation of DeltaIle1-SK.Pm. To further demonstrate that the activity of DeltaIle1-SK requires the conversion of Plgn to Pm, we characterized the reaction of SK with a mutant microplasminogen, Arg561Ala-microPlgn, that cannot be converted to microplasmin. Amidolytic activity is observed when Arg561Ala-microPlgn is incubated with wild-type SK at 37 degrees C; however, no amidolytic activity is observed in the presence of DeltaIle1-SK. These observations demonstrate that the amidolytic activity of DeltaIle1-SK at 37 degrees C requires the conversion of Plgn to Pm. Our findings indicate that Ile1 of SK is required for the nonproteolytic activation of Plgn by SK and are consistent with the hypothesis that Ile1 of SK substitutes for Val562 of Pm.

The rgg gene of Streptococcus pyogenes NZ131 positively influences extracellular SPE B production

Streptococcus pyogenes produces several extracellular proteins, including streptococcal erythrogenic toxin B (SPE B), also known as streptococcal pyrogenic exotoxin B and streptococcal proteinase. Several reports suggest that SPE B contributes to the virulence associated with S. pyogenes; however, little is known about its regulation. Nucleotide sequence data revealed the presence, upstream of the speB gene, of a gene, designated rgg, that was predicted to encode a polypeptide similar to previously described positive regulatory factors. The putative Rgg polypeptide of S. pyogenes NZ131 consisted of 280 amino acids and had a predicted molecular weight of 33,246. To assess the potential role of Rgg in the production of SPE B, the rgg gene was insertionally inactivated in S. pyogenes NZ131, which resulted in markedly decreased SPE B production, as determined both by immunoblotting and caseinolytic activity on agar plates. However, the production of other extracellular products, including streptolysin O, streptokinase, and DNase, was not affected. Complementation of the rgg mutant with an intact rgg gene copy in S. pyogenes NZ131 could restore SPE B production and confirmed that the rgg gene product is involved in the production of SPE B.

Expression and characterization of the intact N-terminal domain of streptokinase

Proteolytic studies have enabled two of the three putative domains of the fibrinolytic protein streptokinase to be isolated and characterized (Conejero-Lara F et al., 1996, Protein Sci 5:2583-2591). The N-terminal domain, however, could not be isolated in these experiments because of its susceptibility to proteolytic cleavage. To complete the biophysical characterization of the domain structure of streptokinase we have overexpressed, purified, and characterized the N-terminal region of the protein, residues 1-146. The results show this is cooperatively folded with secondary structure content and overall stability closely similar to those of the equivalent region in the intact protein.

Analysis of the interactions between streptokinase domains and human plasminogen

The contrasting roles of streptokinase (SK) domains in binding human Glu1-plasminogen (Plg) have been studied using a set of proteolytic fragments, each of which encompasses one or more of SK's three structural domains (A, B, C). Direct binding experiments have been performed using gel filtration chromatography and surface plasmon resonance. The latter technique has allowed estimation of association and dissociation rate constants for interactions between Plg and intact SK or SK fragments. Each of the SK fragments that contains domain B (fragments A2-B-C, A2-B, B-C, and B) binds Plg with similar affinity, at a level approximately 100- to 1,000-fold lower than intact SK. Experiments using 10 mM 6-aminohexanoic acid or 50 mM benzamidine demonstrate that either of these two lysine analogues abolishes interaction of domain B with Plg. Isolated domain C does not show detectable binding to Plg. Moreover, the additional presence of domain C within other SK fragments (B-C and A2-B-C) does not alter significantly their affinities for Plg. In addition, Plg-binding by a noncovalent complex of two SK fragments that contains domains A and B is similar to that of domain B. By contrast, species containing domain B and both domains A and C (intact SK and the two-chain complex A1 x A2-B-C) show a significantly higher affinity for Plg, which could not be completely inhibited by saturating amounts of 6-AHA. These results show that SK domain B interacts with Plg in a lysine-dependent manner and that although domains A and C do not appear independently to possess affinity for Plg, they function cooperatively to establish the additional interactions with Plg to form an efficient native-like Plg activator complex.

Crystal structure of the catalytic domain of human plasmin complexed with streptokinase

Streptokinase is a plasminogen activator widely used in treating blood-clotting disorders. Complexes of streptokinase with human plasminogen can hydrolytically activate other plasminogen molecules to plasmin, which then dissolves blood clots. A similar binding activation mechanism also occurs in some key steps of blood coagulation. The crystal structure of streptokinase complexed with the catalytic unit of human plasmin was solved at 2.9 angstroms. The amino-terminal domain of streptokinase in the complex is hypothesized to enhance the substrate recognition. The carboxyl-terminal domain of streptokinase, which binds near the activation loop of plasminogen, is likely responsible for the contact activation of plasminogen in the complex.

Streptokinase secretion by Serratia marcescens signaled by the C-terminal 41 amino acid segment of metalloprotease

In order to investigate the secretion signal of Serratia marcescens metalloprotease (SMP) and examine the ability of the secretion signal to secrete foreign proteins, hybrid genes encoding the passenger-SMP C-terminal segments were constructed. As a passenger protein, streptokinase (SK) deprived of its signal peptide was used. Three kinds of SMP C-terminal segments containing 41, 80, or 220 amino acid residues were fused to the C-terminus of SK as secretion signals. The SK-SMP chimeric proteins containing 41 or 220 amino acid segments of the SMP C-terminus were secreted into the culture medium by the SMP transporter of S. marcescens. This result suggests that cytoplasmic SK is secreted into the external medium by the C-terminal segments of SMP and also shows that the smallest, 41 amino acid segment of the SMP C-terminus functions as a secretion signal of foreign proteins as well as SMP.

Interaction of a group A Streptococcus within human plasma results in assembly of a surface plasminogen activator that contributes to occupancy of surface plasmin-binding structures

Group A streptococcal isolate 187061 incubated in human plasma or serum reconstituted with fibrinogen but not plasminogen-depleted plasma or serum alone acquired a surface plasminogen activator activity. Assembly of the surface plasminogen activator was inhibited by the presence of neutralizing antibodies to streptokinase. Once assembled, the bacterial-associated plasminogen activator could generate plasmin when incubated in human plasminogen, plasmin or serum which could bind to bacterial surface plasmin-binding structures despite the presence of host physiological inhibitors. These studies provide evidence that the pathways by which group A isolates interact with human plasmin(ogen) are potentially linked and may provide a mechanism for bacteria to acquire host enzymatic activity efficiently in the infected host.

Effect of signal peptide changes on the extracellular processing of streptokinase from Escherichia coli: requirement for secondary structure at the cleavage junction

Streptokinase (SK), an extracellular protein from Streptococcus equisimilis, is secreted post-translationally by Escherichia coli using both its native and E. coli-derived transport signals. In this communication we report that cleavage specificity of signal peptidase I, and thus efficiency of secretion, varies in E. coli when SK export is directed by different transport signals. The native (+1) N-terminus of mature SK was retained when it was transported under the control of its own, PelB or LamB signal peptide. However, when translocation of SK was controlled by the OmpA or MalE signal peptide, Ala2 of mature SK was preferred as a cleavage site for the pre-SK processing. Our results indicate that compatibility of the leader peptide with the mature sequences of SK, which fulfills the requirement for a given secondary structure within the cleavage region, is essential for maintaining the correct processing of pre-SK. An OmpA-SK fusion, which results in the deletion of two N-terminal amino acid residues of mature SK, was further studied with respect to the recognition of alternative cleavage site in E. coli. The alanine at +2 in mature SK was changed to glycine or its relative position was changed to +3 by introducing a methionine residue at the +1 position. Both alterations resulted in the correct cleavage of pre-SK at the original OmpA fusion site. In contrast, introduction of an additional alanine at +4, creating three probable cleavage sites (Ala-x-Ala-x-Ala-x-Ala), resulted in the recognition of all three target sites for cleavage, with varying efficiency. The results indicate that the nature of the secondary structure generated at the cleavage junction of pre-SK, resulting from the fusion of different signal peptides, modulates the cleavage specificity of signal peptidase I during extracellular processing of SK. Based on these findings it is proposed that flexibility in the interaction of the active site of signal peptidase I with the cleavage sites of signal peptides may occur when it encounters two or more juxtaposed cleavage sites. Preference for one cleavage site over another, then, may depend on fulfillment of secondary structure requirements in the vicinity of the pre-protein cleavage junction.

Molecular co-operation between protein PAM and streptokinase for plasmin acquisition by Streptococcus pyogenes

Bacterial surface-associated plasmin formation is believed to contribute to invasion, although the underlying molecular mechanisms are poorly understood. To define the components necessary for plasmin generation on group A streptococci we used strain AP53 which exposes an M-like protein ("PAM") that contains a plasminogen-binding sequence with two 13-amino acid residues long tandem repeats (a1 and a2). Utilizing an Escherichia coli-streptococcal shuttle vector, we replaced a 29-residue long sequence segment of Arp4, an M-like protein that does not bind plasminogen, with a single (a1) or the combined a1a2 repeats of PAM. When expressed in E. coli, the purified chimeric Arp/PAM proteins both bound plasminogen, as well as plasmin, and when used to transform group A streptococcal strains lacking the plasminogen-binding ability, transformants with the Arp/PAM constructs efficiently bound plasminogen. Moreover, when grown in the presence of plasminogen, both Arp/PAM- and PAM-expressing streptococci acquired surface-bound plasmin. In contrast, plasminogen activation failed to occur on PAM- and Arp/PAM-expressing streptococci carrying an inactivated streptokinase gene: this block was overcome by exogenous streptokinase. Together, these results provide evidence for an unusual co-operation between a surface-bound protein, PAM, and a secreted protein, streptokinase, resulting in bacterial acquisition of a host protease that is likely to spur parasite invasion of host tissues.

Elimination of the Cys558-Cys566 bond in Lys78-plasminogen--effect on activation and fibrin interaction

Plasminogen contains a unique disulphide bond, Cys558-Cys566, responsible for the cyclic nature of the peptide sequence surrounding the activation site at Arg561-Val562. A recombinant [Ser558, Ser566]-Lys78-plasminogen variant was produced in which the two cysteine residues were replaced by serine residues. The variant was used to study the functional implications of removing the structural restrains imposed to the activation loop by this disulphide bond. Elimination of the Cys558-Cys566 bond attenuated activation by urokinase-type plasminogen activator (uPA) and tissue-type plasminogen activator (tPA), but resulted in an increased susceptibility to cleavage by trypsin and plasma kallikrein. Two opposite effects on the interaction of plasminogen with streptokinase were produced by modification of this bond; (a) attenuation of the rate at which the active complex with streptokinase was formed and (b) a 7.5-fold increase in plasminogen activation catalysed by this complex. Activation by tPA in the presence of fibrin, in contrast to activation in its absence, was not attenuated by elimination of this disulphide bond. However, the activation rate as a function of plasminogen concentration followed a different saturation curve, and the fibrin degradation pattern was changed. The results suggest that the Cys558-Cys566 disulphide bond is of importance for the specificity of plasminogen. This applies to its activation and also to its role in subsequent fibrin clot degradation.

Streptokinase as a mediator of acute post-streptococcal glomerulonephritis in an experimental mouse model

Group A streptococcal infections are sometimes followed by the inflammatory kidney disease acute post-streptococcal glomerulonephritis (APSGN). To test the importance of streptokinase in the pathogenesis of this disease, isogenic strains of the nephritis isolate NZ131, differing only in the ability to produce streptokinase of the nephritis-associated ska1 genotype, were used for infection in a mouse tissue cage model for APSGN. Streptokinase production was found to be a prerequisite for the capacity of the strain to induce APSGN in mice. In addition, streptokinase was demonstrated in the kidneys of mice infected with the nephritogenic NZ131 and EF514 strains. After infection with the nonnephritogenic strain S84, neither streptokinase nor C3 deposition were observed. Deposition of streptokinase in the glomeruli was detected as soon as 4 days after infection. These findings provide support for the hypothesis that streptokinase initiates the nephritis process by glomerular deposition, which leads to local activation of the complement cascade. Detection of streptokinase in kidney tissue increased with the degree of glomerular hypercellularity. Thus, the severity of the pathological process may be a reflection of the degree of streptokinase deposition.

Streptococcal pyrogenic exotoxin A, streptolysin O, exoenzymes, serotype and biotype profiles of Streptococcus pyogenes isolates from patients with toxic shock syndrome and other severe infections

The determination of protein M and T serotypes, biotypes and pyrogenic (erythrogenic) exotoxin A (SPE A), streptolysin O (SLO), streptokinase (SK), hyaluronidase (HA) and cysteine proteinase release by 212 S. pyogenes isolates from patients with severe invasive group A streptococcal (GAS) infections, among them 74 cases of streptococcal toxic shock syndrome (STSS) has been investigated. M1 or M3 serotypes were expressed by 25% of the isolates (53/212), whereas 59% (125/212) belonged to 15 other different serotypes and 16% (34/212) were untypeable. Of the 74 isolates from STSS patients, 42% (31/74) expressed M1 and to a lesser extent M3 serotypes versus 19% of the non STSS isolates (26/138). Among the ten different biotypes known, biotypes 1 and 3 were prevalent, particularly the former in the case of STSS isolates. SPE A was detectably produced by about 25% (54/212) of the strains. However, as high as 40.5% of the STSS isolates (30/74) versus 17.4% of non STSS isolates (24/138) released SPE A. Moreover, 67% of the SPE A producing strains were of serotype M1 or M3. SK and HA were released by 71% and 10% of the isolates respectively. All strains released SLO (4 to 256 HU/ml) and 85% cysteine proteinase. No relationship between toxin or enzyme titer and the type of disease or clinical origin of the strains was found. Culture supernatants of all isolates showed moderate to high lymphocyte transforming activity with index values ranging from 14.5 to 50.3 including those strains which did not release detectable amounts of SPE A suggesting that SPE C and other mitogenic factor(s) are released by the isolates investigated.

Mapping of the plasminogen binding site of streptokinase with short synthetic peptides

Although several recent studies employing various truncated fragments of streptokinase (SK) have demonstrated that the high-affinity interactions of this protein with human plasminogen (HPG) to form activator complex (SK-HPG) are located in the central region of SK, the exact location and nature of such HPG interacting site(s) is still unclear. In order to locate the "core" HPG binding ability in SK, we focused on the primary structure of a tryptic fragment of SK derived from the central region (SK143-293) that could bind as well as activate HPG, albeit at reduced levels in comparison to the activity of the native, full-length protein. Because this fragment was refractory to further controlled proteolysis, we took recourse to a synthetic peptide approach wherein the HPG interacting properties of 16 overlapping 20-mer peptides derived from this region of SK were examined systematically. Only four peptides from this set, viz., SK234-253, SK254-273, SK274-293, and SK263-282, together representing the contiguous sequence SK234-293, displayed HPG binding ability. This was established by a specific HPG-binding ELISA as well as by dot blot assay using 125I-labeled HPG. These results showed that the minimal sequence with HPG binding function resided between residues 234 and 293. None of the synthetic SK peptides was found to activate HPG, either individually or in combination, but, in competition experiments where each of the peptides was added prior to complex formation between SK and HPG, three of the HPG binding peptides (SK234-253, SK254-273, and SK274-293) inhibited strongly the generation of a functional activator complex by SK and HPG. This indicated that residues 234-293 in SK participate directly in intermolecular contact formation with HPG during the formation of the 1:1 SK-HPG complex. Two of the three peptides (SK234-253 and SK274-293), apart from interfering in SK-HPG complex formation, also showed inhibition of the amidolytic activity of free HPN by increasing the K(m) by approximately fivefold. A similar increase in K(m) for amidolysis by HPN as a result of complexation with SK has been interpreted previously to arise from the steric hinderance at or near the active site due to the binding of SK in this region. Thus, our results suggest that SK234-253 and SK274-293 also, like SK, bound close to the active site of HPN, an event that was reflected in the observed alteration in its substrate accessibility. By contrast, whereas the intervening peptide (SK254-273) could not inhibit amidolysis by free HPN, it showed a marked inhibition of the activation of "substrate" PG (human or bovine plasminogen) by activator complex, indicating that this particular region is intimately involved in interaction of the SK-HPG activator complex with substrate plasminogen during the catalytic cycle. This finding provides a rational explanation for one of the most intriguing aspects of SK action, i.e., the ability of the SK-HPG complex to catalyze selectively the activation of substrate molecules of PG to PN, whereas free HPN alone cannot do so. Taken together, the results presented in this paper strongly support a model of SK action in which the segment 234-293 of SK, by virtue of the epitopes present in residues 234-253 and 274-293, binds close to the active center of HPN (or, a cryptic active site, in the case of HPG) during the intermolecular association of the two proteins to form the equimolar activator complex; the segment SK254-273 present in the center of the core region then imparts an ability to the activator complex to interact selectively with substrate PG molecules during each PG activation cycle.

Identification of key gene products required for acquisition of plasmin-like enzymatic activity by group A streptococci

Group A streptococci incubated in human plasma can acquire a plasmin-like enzymatic activity. This process involves at least two bacterial proteins and two human protein cofactors. In this study, the key bacterial proteins were identified by using a series of isogenic mutants of group A isolate, CS101. These studies confirm a key role for the secreted plasminogen activator, streptokinase, and identify the major surface fibrinogen-binding protein as the product of the mrp gene. The requirement for human fibrinogen and plasminogen as key cofactors was also confirmed.

Conformation and stability of streptokinases from nephritogenic and nonnephritogenic strains of streptococci

Conformation and stability of three Sks from Streptococcus equisimilis strain H46A, Streptococcus pyogenes strain A374, and Streptococcus pyogenes strain AT27 were compared by limited proteolysis, CD, and fluorescence measurements and by DSC. The general similarity of the peptide CD spectra in the spectral region 185 to 260 nm indicates the same type of folding for the three proteins. Fluorescence and aromatic CD spectra are consistent with a predominant surface localization of the aromatic amino acids and a low rigidity of their surroundings. A major difference among the three Sks is shown by deconvolution of their excessive heat capacity functions. Deconvolution reveals two energetic folding units in Sk H46A but three energetic folding units in Sk A374 and Sk AT27. Digestion of the Sks with trypsin indicates a reduced sensitivity of the C-terminal region of Sk A374 and Sk AT27 in comparison to Sk H46A. This suggests that amino acids of the C-terminal region participate in the formation of the third folding unit of Sk A374 and Sk AT27.

Mutation of lysines in a plasminogen binding region of streptokinase identifies residues important for generating a functional activator complex

Through a unique but poorly understood mechanism, streptokinase (SK) interacts with human plasminogen to generate an "activator complex" that efficiently cleaves substrate plasminogen molecules. Previous studies have suggested that lysine residues in SK may play a role in the binding and function of the activator complex. To investigate this hypothesis, 10 different lysine residues in the plasminogen binding region of SK were altered to construct 8 recombinant (r) SK mutants. Only one double mutant, rSKK256,257A (replacing Lys with Ala at residues 256 and 257), showed a statistically significant reduction (63%) in binding affinity for Glu-plasminogen. This mutant also displayed a lagtime in the appearance of maximal activity, and modest impairments (2-5-fold) in kinetic parameters for amidolytic and plasminogen activator activity compared to rSK. In contrast, another mutant, rSKK332,334A, formed an activator complex with profound and nearly selective defects in the catalytic processing of substrate plasminogen molecules. When compared to rSK in kinetic assays of plasminogen activation, the rSKK332,334A mutant formed an activator complex that bound substrate plasminogens normally (normal K(m), but its ability to activate or cleave these molecules (kcat) was reduced by 34-fold. In contrast, in amidolytic assays, the kinetic parameters of rSKK332,334A showed only minor differences (< 2-fold) from rSK. Similarly, the binding affinity of this mutant to human Glu-plasminogen was indistinguishable from rSK [(2.6 +/- 0.8) x 10(9) vs (2.4 +/- 0.2) x 10(9) M-1, respectively]. In summary, these experiments have identified lysine residues in a plasminogen binding region of SK which appear to be necessary for normal high-affinity binding to plasminogen, and for the efficient catalytic processing of substrate plasminogen molecules by the activator complex.

An experimental model for acute poststreptococcal glomerulonephritis in mice

A number of factors have been implicated in the pathogenesis of acute poststreptococcal glomerulonephritis (APSGN). The lack of a reliable animal model has made it difficult to further examine the role of these factors in the pathogenetic process. In this report, we present a tissue cage model in mice for the study of APSGN. Morphological and immunohistological changes in the kidney, resembling those of APSGN in man, were induced at high frequency in the experimental model after infection with group A streptococcal nephritis isolates. Nephritis-associated strain induced hypercellularity, occlusion of capillaries, and C3 deposition at high frequencies compared to the changes induced in animals infected with a non-nephritis-associated strain and non-infected controls. In animals infected with a nephritis isolate, hematuria and proteinuria were also detected. If penicillin treatment was initiated on the third day of infection, the development of the nephritis process was prevented. Streptokinase, as well as preabsorbing antigen and streptococcal pyrogenic exotoxin B (SpeB), have been implicated in the pathogenesis of APSGN. These proteins, as well as SpeA and SpeF, were detected in the fluids of the infectious focus, regardless of the origin of the strains and whether or not glomerulonephritis was seen. Antibodies to streptokinase were evoked in the majority of the infected animals. This immune response did not correlate with the nephritic process since hypercellularity was also seen in animals which lacked detectable streptokinase antibodies. The results show that the mouse tissue cage model can be used to study APSGN and to evaluate factors involved in the pathogenesis of the disease.

C-terminal peptide of streptokinase, Met369-Pro373, is important in plasminogen activation

Streptokinase(SK), a plasminogen activator, is known to have multi-domain structure. The function of the C-terminal region of streptokinase was investigated with SK mutants constructed by truncating 26, 33, 37, 40, 41, 46, 47, 70 or 97 amino acid residues from the C-terminus. The truncated SKs were expressed in E. coli and purified. The 41 residue deletion (SKP373) from the C-terminus had not effect on the plasminogen activation activity. However, the deletion of 46 amino acid residues (SKP368) resulted in the dramatic reduction of the plasminogen activation efficiency. The result suggests that the C-terminal peptide from Met369 to Pro373 of SK may play an important role on the plasminogen activation.

Role of N-terminal domain of streptokinase in protein transport

Streptokinase (SK), an extracellular protein of several haemolytic strains of Streptococcus, is utilized as a potent thrombolytic agent for the treatment of various myocardial disorders. Functional properties of SK remain unchanged when the first 13 N-terminal amino acid (aa) residues are removed. At present, role of this segment in protein structure function is unclear. skc gene encoding for the mature SK and its deletion variant, lacking its first 13 aa residues, were cloned and expressed in E. coli. Full length SK, deprived of any leader sequences, was able to translocate slowly, across the cyto-plasmic and outer membranes of E.coli. Whereas, SK derivative, devoid of its first 13 N-terminal aa residues, could not do so. Cell fractionation studies as well as genetic evidences utilizing alkaline phosphatase fusion, point towards the existence of additional information for protein transport, within the N-terminal domain of SK. To further investigate the role of this region in protein secretion, genetic fusions were created in between full length and 13 aa deleted SK with OmpA leader peptide. Studies on kinetics of SK export from E.coli, revealed that translocation of protein is 3-4 times faster when the first 13 N-terminal residues of SK are intact. On the basis of results obtained, it has been proposed that the N-terminus of mature SK maintains the export competent status of protein and, thus, confer speed and efficiency upon the translocation process of streptokinase.