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.     

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.     

Characterization of Lys-698-to-Met substitution in human plasminogen catalytic domain

Streptokinase (SK) is a human plasminogen (Pg) activator secreted by streptococci. The activation mechanism of SK differs from that of physiological Pg activators in that SK is not a protease and cannot proteolytically activate Pg. Instead, it forms a tight complex with Pg that proteolytically activates other Pg molecules. The residue Lys-698 of human Pg was hypothesized to participate in triggering activation in the SK-Pg complex. Here, we report a study of the Lys-698 to Met substitution in the catalytic domain of Pg (microPg) containing the proteolytic activation-resistant background (R561A). While it remains competent in forming a complex with SK, maintaining a comparable equilibration dissociation constant (K(D)), the recombinant protein shows a nearly 60-fold reduction in amidolytic activity relative to its R561A background when mixed with native SK. A 2.3 A crystal structure of this mutant microPg confirmed the correct folding of this recombinant protein. Combined with other biochemical data, these results support the premise that Lys-698 of human Pg plays a functional role in the so-called N-terminal insertion activation mechanism by SK.     

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.     

Substrate kringle-mediated catalysis by the streptokinase-plasmin activator complex: Critical contribution of kringle-4 revealed by the mutagenesis approaches

Streptokinase (SK) is a protein co-factor with a potent capability for human plasminogen (HPG) activation. Our previous studies [1] have indicated a major role of long-range protein-protein contacts between the three domains (alpha, beta, and gamma) of SK and the multi-domain HPG substrate (K1-K5CD). To further explore this phenomenon, we prepared truncated derivatives of HPG with progressive removal of kringle domains, like K5CD, K4K5CD, K3-K5CD (K3K4K5CD), K2-K5CD (K2K3K4K5CD) and K1-K5CD (K1K2K3K4K5CD). While urokinase (uPA) cleaved the scissile peptide in the isolated catalytic domain (μPG) with nearly the same rate as with full-length HPG, SK-plasmin showed only 1-2% activity, revealing mutually distinct mechanisms of HPG catalysis between the eukaryotic and prokaryotic activators. Remarkably, with SK.HPN (plasmin), the ‘addition’ of both kringles 4 and 5 onto the catalytic domain showed catalytic rates comparable to full length HPG, thus identifying the dependency of the “long-range” enzyme-substrate interactions onto these two CD-proximal domains. Further, chimeric variants of K5CD were generated by swapping the kringle domains of HPG with those of uPA and TPA (tissue plasminogen activator), separately. Surprisingly, although native-like catalytic turnover rates were retained when either K1, K2 or K4 of HPG was substituted at the K5 position in K5CD, these were invariably lost once substituted with the evolutionarily more distant TPA- and uPA-derived kringles. The present results unveil a novel mechanism of SK.HPN action in which augmented catalysis occurs through enzyme-substrate interactions centered on regions in substrate HPG (kringles 4 and 5) that are spatially distant from the scissile peptide bond.     

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.     

Effects of plasminogen, streptokinase, and their equimolar complexes with pyruvate kinase on the human neuroblastoma IMR-32 cells

The system of extracellular proteolysis consisted of plasminogen (PGn), its active protease, plasmin, and PGn activators and their inhibitors affect the growth, differentiation, and proliferation of nervous cells both under normal and pathological conditions. The purpose of our investigation was to study the effects of exogenous PGn, its activator, streptokinase (SK), pyruvate kinase (PK), and their equimolar complexes on morphological and functional properties of IMR-32 neuroblastoma cells. It has been found that PGn, SK, PK, and their complexes stimulate cell proliferation during 1–3 days of incubation. We also observed increased DNA, RNA, and protein content. The low-lactate dehydrogenase (LDH) efflux indicated that the addition of the proteins we assayed to the culture medium prevented the development of degenerative processes caused by serum deprivation. The levels of extracellular PGn-activator activity, as measured by the fibrinolytic method, increased in the presence of SK. The SK effect vanished if SK was in the complex with PK on the 3rd day of cultivation. New original facts were obtained to testify the probability of initiation of neoplastic transformation and tumor growth potentiation.     

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.     

Substrate kringle-mediated catalysis by the streptokinase-plasmin activator complex: critical contribution of kringle-4 revealed by the mutagenesis approaches

Streptokinase (SK) is a protein co-factor with a potent capability for human plasminogen (HPG) activation. Our previous studies [1] have indicated a major role of long-range protein-protein contacts between the three domains (alpha, beta, and gamma) of SK and the multi-domain HPG substrate (K1-K5CD). To further explore this phenomenon, we prepared truncated derivatives of HPG with progressive removal of kringle domains, like K5CD, K4K5CD, K3-K5CD (K3K4K5CD), K2-K5CD (K2K3K4K5CD) and K1-K5CD (K1K2K3K4K5CD). While urokinase (uPA) cleaved the scissile peptide in the isolated catalytic domain (μPG) with nearly the same rate as with full-length HPG, SK-plasmin showed only 1-2% activity, revealing mutually distinct mechanisms of HPG catalysis between the eukaryotic and prokaryotic activators. Remarkably, with SK.HPN (plasmin), the 'addition' of both kringles 4 and 5 onto the catalytic domain showed catalytic rates comparable to full length HPG, thus identifying the dependency of the "long-range" enzyme-substrate interactions onto these two CD-proximal domains. Further, chimeric variants of K5CD were generated by swapping the kringle domains of HPG with those of uPA and TPA (tissue plasminogen activator), separately. Surprisingly, although native-like catalytic turnover rates were retained when either K1, K2 or K4 of HPG was substituted at the K5 position in K5CD, these were invariably lost once substituted with the evolutionarily more distant TPA- and uPA-derived kringles. The present results unveil a novel mechanism of SK.HPN action in which augmented catalysis occurs through enzyme-substrate interactions centered on regions in substrate HPG (kringles 4 and 5) that are spatially distant from the scissile peptide bond.     

Structure-function analysis of the streptokinase amino terminus (residues 1-59)

Streptokinase (SK) binds to plasminogen (Pg) to form a complex that converts substrate Pg to plasmin. Residues 1-59 of SK regulate its capacity to induce an active site in bound Pg by a nonproteolytic mechanism and to activate substrate Pg in a fibrin-independent manner. We analyzed 24 SK mutants to better define the functional properties of SK-(1-59). Mutations within the alphabeta1 strand (residues 17-26) of SK completely prevented nonproteolytic active site induction in bound Pg and rendered SK incapable of protecting plasmin from inhibition by alpha2-antiplasmin. However, when fibrin-bound, the activities of alphabeta1 strand mutants were similar to that of wild-type (WT) SK and resistant to alpha2-antiplasmin. Mutation of Ile1 of SK also prevented nonproteolytic active site induction in bound Pg. However, unlike alphabeta1 strand mutants, the functional defect of Ile1 mutants was not relieved by fibrin, and complexes of Ile1 mutants and plasmin were resistant to alpha2-antiplasmin. Plasmin enhanced the activities of alphabeta1 strand and Ile1 mutants, suggesting that SK-plasmin complexes activated mutant SK.Pg complexes by hydrolyzing the Pg Arg561-Val562 bond. Mutational analysis of Glu39 of SK suggested that a salt bridge between Glu39 and Arg719 of Pg is important, but not essential, for nonproteolytic active site induction in Pg. Deleting residues 1-59 rendered SK dependent on plasmin and fibrin to generate plasminogen activator (PA) activity. However, the PA activity of SK-(60-414) in the presence of fibrin was markedly reduced compared with WT SK. Despite its reduced PA activity, the fibrinolytic potency of SK-(60-414) was greater than that of WT SK at higher (but not lower) SK concentrations due to its capacity to deplete plasma Pg. These studies define mechanisms by which the SK alpha domain regulates rapid active site induction in bound Pg, contributes to the resistance of the SK-plasmin complex to alpha2-antiplasmin, and controls fibrin-independent Pg activation.     

Domain truncation studies reveal that the streptokinase-plasmin activator complex utilizes long range protein-protein interactions with macromolecular substrate to maximize catalytic turnover

To explore the interdomain co-operativity during human plasminogen (HPG) activation by streptokinase (SK), we expressed the cDNAs corresponding to each SK domain individually (alpha, beta, and gamma), and also their two-domain combinations, viz. alphabeta and betagamma in Escherichia coli. After purification, alpha and beta showed activator activities of approximately 0.4 and 0.05%, respectively, as compared with that of native SK, measured in the presence of human plasmin, but the bi-domain constructs alphabeta and betagamma showed much higher co-factor activities (3.5 and 0.7% of native SK, respectively). Resonant Mirror-based binding studies showed that the single-domain constructs had significantly lower affinities for "partner" HPG, whereas the affinities of the two-domain constructs were remarkably native-like with regards to both binary-mode as well as ternary mode ("substrate") binding with HPG, suggesting that the vast difference in co-factor activity between the two- and three-domain structures did not arise merely from affinity differences between activator species and HPG. Remarkably, when the co-factor activities of the various constructs were measured with microplasminogen, the nearly 50-fold difference in the co-factor activity between the two- and three-domain SK constructs observed with full-length HPG as substrate was found to be dramatically attenuated, with all three types of constructs now exhibiting a low activity of approximately 1-2% compared to that of SK.HPN and HPG. Thus, the docking of substrate through the catalytic domain at the active site of SK-plasmin(ogen) is capable of engendering, at best, only a minimal level of co-factor activity in SK.HPN. Therefore, apart from conferring additional substrate affinity through kringle-mediated interactions, reported earlier (Dhar et al., 2002; J. Biol. Chem. 277, 13257), selective interactions between all three domains of SK and the kringle domains of substrate vastly accelerate the plasminogen activation reaction to near native levels.     

Thermodynamic Characteristics of Plasminogen Activation by Indirect Activators

Several indirect plasminogen (Pg) activators are known including streptokinase and the monoclonal antibody IV-Ic, whose mechanism of activation is well studied. To characterize thermodynamically the activation of Pg by streptokinase (SK) and the monoclonal antibody (mAB) IV-Ic, the activation energies were calculated for various reaction stages. Activation energy of 7.4 kcal/mol was determined for the interaction of the chromogenic substrate S-2251 with plasmin (Pm) and activated equimolar complexes Pm-SK and Pg*SK at the steady-state reaction stage, and 18.7 kcal/mol with the complexes Pg*IV-Ic. A 2.5-fold increase in the energy of activation for the Pg*IV-Ic complex suggests a more intricate mechanism of its interaction with the substrate. At the stage of increasing active center concentrations and the formation of activated complexes Pg*SK and Pg*mAB IV-Ic, the activation energy was found to be 10.5 and 38 kcal/mol, respectively. At this reaction stage the conformational rearrangement of Pg molecule with the formation of active center is the limiting stage determining the reaction rate. Unexpectedly high energy of activation at the second stage of interaction between mAB IV-Ic and Pg suggests several simultaneous reactions and complexity of conformation rearrangement in the Pg molecule in activated complexes, thus requiring large energy expense. Formation of the active center is probably accompanied by its transition within a narrow temperature range into another conformation state with the change in activation parameters of the reaction. Quantitative evaluation of the studied reactions from the perspective of thermodynamics of the enzymatic reactions gives more comprehensive characteristics of the activation mechanism.     

链激酶研究概况及其进展

链激酶(Streptok inase,SK)是世界上最早发现的纤维蛋白酶原激活剂,也是最早作为临床药品治疗血栓性疾病的溶栓酶。它是由A,C,G群链球菌中β-溶血性链球菌分泌的胞外非酶蛋白质,能和纤溶酶原结合,将纤溶酶原激活为纤溶酶,具有溶解血栓的作用。本文详细综述了该酶的性质、在溶栓酶中的地位、研究历史、作用机理等。此外,由于它有半衰期短、不具有纤维蛋白特异性、治疗后出血和血栓易复发的缺点,所以有必要用基因工程的手段进行改造,以达到更好的治疗效果。     

Structure and function of microplasminogen: II. Determinants of activation by urokinase and by the bacterial activator streptokinase.

We have used a group of human microplasminogens (mPlg), modified by residue substitutions, insertions, deletions, and chain breaks (1) to study the determinants of productive interactions with two plasminogen activators, urokinase (uPA), and streptokinase (SK); (2) to explore the basis of species specificity in the zymogen-SK complex activity; and (3) to compare active SK complex formation in mPlg and microplasmin (mPlm). Modifications within the disulfide-bonded loop containing the activation site and the adjacent hexadecapeptide upstream sequence showed that uPA recognition elements encompassed R29 at the activation site and multiple elements extending upstream to perhaps 13 residues, all maintained in specific conformational register by surrounding pairs of disulfide bonds. A generally parallel pattern of structural requirements was observed for active zymogen-SK complex formation. Changes within the loop downstream of the activation site were tolerated well by uPA and poorly by SK. The introduction of selected short bovine (Plg) sequences in human mPlg reduced the activity of the resulting SK complexes. The requirements for active SK complex formation are different for mPlg and mPlm.     

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.     

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.     

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.     

alpha Domain deletion converts streptokinase into a fibrin-dependent plasminogen activator through mechanisms akin to staphylokinase and tissue plasminogen activator

The mechanism of action of plasminogen (Pg) activators may affect their therapeutic properties in humans. Streptokinase (SK) is a robust Pg activator in physiologic fluids in the absence of fibrin. Deletion of a "catalytic switch" (SK residues 1-59), alters the conformation of the SK alpha domain and converts SKDelta59 into a fibrin-dependent Pg activator through unknown mechanisms. We show that the SK alpha domain binds avidly to the Pg kringle domains that maintain Glu-Pg in a tightly folded conformation. By virtue of deletion of SK residues 1-59, SKDelta59 loses the ability to unfold Glu-Pg during complex formation and becomes incapable of nonproteolytic active site formation. In this manner, SKDelta59 behaves more like staphylokinase than like SK; it requires plasmin to form a functional activator complex, and in this complex SKDelta59 does not protect plasmin from inhibition by alpha(2)-antiplasmin. At the same time, SKDelta59 is unlike staphylokinase or SK and is more like tissue Pg activator, because it is a poor activator of the tightly folded form of Glu-Pg in physiologic solutions. SKDelta59 can only activate Glu-Pg when it was unfolded by fibrin interactions or by Cl(-)-deficient buffers. Taken together, these studies indicate that an intact alpha domain confers on SK the ability to nonproteolytically activate Glu-Pg, to unfold and process Glu-Pg substrate in physiologic solutions, and to alter the substrate-inhibitor interactions of plasmin in the activator complex. The loss of an intact alpha domain makes SKDelta59 activate Pg through classical "fibrin-dependent mechanisms" (akin to both staphylokinase and tissue Pg activator) that include: 1) a marked preference for a fibrin-bound or unfolded Glu-Pg substrate, 2) a requirement for plasmin in the activator complex, and 3) the creation of an activator complex with plasmin that is readily inhibited by alpha(2)-antiplasmin.     

Thermal stability of the three domains of streptokinase studied by circular dichroism and nuclear magnetic resonance.

Streptococcus equisimilis streptokinase (SK) is a single-chain protein of 414 residues that is used extensively in the clinical treatment of acute myocardial infarction due to its ability to activate human plasminogen (Plg). The mechanism by which this occurs is poorly understood due to the lack of structural details concerning both molecules and their complex. We reported recently (Parrado J et al., 1996, Protein Sci 5:693-704) that SK is composed of three structural domains (A, B, and C) with a C-terminal tail that is relatively unstructured. Here, we report thermal unfolding experiments, monitored by CD and NMR, using samples of intact SK, five isolated SK fragments, and two two-chain noncovalent complexes between complementary fragments of the protein. These experiments have allowed the unfolding processes of specific domains of the protein to be monitored and their relative stabilities and interdomain interactions to be characterized. Results demonstrate that SK can exist in a number of partially unfolded states, in which individual domains of the protein behave as single cooperative units. Domain B unfolds cooperatively in the first thermal transition at approximately 46 degrees C and its stability is largely independent of the presence of the other domains. The high-temperature transition in intact SK (at approximately 63 degrees C) corresponds to the unfolding of both domains A and C. Thermal stability of domain C is significantly increased by its isolation from the rest of the chain. By contrast, cleavage of the Phe 63-Ala 64 peptide bond within domain A causes thermal destabilization of this domain. The two resulting domain portions (A1 and A2) adopt unstructured conformations when separated. A1 binds with high affinity to all fragments that contain the A2 portion, with a concomitant restoration of the native-like fold of domain A. This result demonstrates that the mechanism whereby A1 stimulates the plasminogen activator activities of complementary SK fragments is the reconstitution of the native-like structure of domain A.     

Streptokinase triggers conformational activation of plasminogen through specific interactions of the amino-terminal sequence and stabilizes the active zymogen conformation

Cleavage of Arg(561)-Val(562) in plasminogen (Pg) generates plasmin (Pm) through a classical activation mechanism triggered by an insertion of the new amino terminus into a binding pocket in the Pg catalytic domain. Streptokinase (SK) circumvents this process and activates Pg through a unique nonproteolytic mechanism postulated to be initiated by the intrusion of Ile(1) of SK in place of Val(562). This hypothesis was evaluated in equilibrium binding and kinetic studies of Pg activation with an SK mutant lacking Ile(1) (SK(2--414)). SK(2--414) retained the affinity of native SK for fluorescein-labeled [Lys]Pg and [Lys]Pm but induced no detectable conformational activation of Pg. The activity of SK(2--414) was partially restored by the peptides SK(1--2), SK(1--5), SK(1--10), and SK(1--15), whereas Pg(562--569) peptides were much less effective. Active site-specific fluorescence labeling demonstrated directly that the active catalytic site was formed on the Pg zymogen by the combination of SK(1--10) and SK(2--414), whereas sequence-scrambled SK(1-10) was inactive. The characterization of SK(1--10) containing single Ala substitutions demonstrated the sequence specificity of the interaction. SK(1--10) did not restore activity to the further truncated mutant SK(55-414), which was correlated with the loss of binding affinity of SK(55--414) for labeled [Lys]Pm but not for [Lys]Pg. The studies support a mechanism for conformational activation in which the insertion of Ile(1) of SK into the Pg amino-terminal binding cleft occurs through sequence-specific interactions of the first 10 SK residues. This event and the preferentially higher affinity of SK(2--414) for the activated proteinase domain of Pm are thought to function cooperatively to trigger the conformational change and stabilize the active zymogen conformation.