Novel self-cleavage activity of Staphylokinase fusion proteins: An interesting finding and its possible applications

Staphylokinase (SAK) is reported to have a serine protease domain with no proteolytic activity unlike other plasminogen activators like tissue plasminogen activator (t-PA) and urokinase. A unique protease property of Staphylokinase was observed when SAK was expressed as a fusion protein in inducible Escherichia coli expression vectors. This finding was further investigated by cloning and expressing different SAK fusions, both native and N-terminal deletions, with fusion tags like glutathione S-transferase (GST) and signal sequence of SAK in bacterial system. While all the N-terminal SAK fusions were found to self-cleave in crude and purified preparations, the C-terminal SAK fusion was stable. The cleavage property of Staphylokinase fusion proteins, inhibited by reduced glutathione and PMSF, was independent of its thrombolytic activity and also independent on the type of host employed for its expression. The serine protease domain of the SAK gene possibly lies between 20th to 77th amino acid and serine 41 of this region appears critical for such a cleavage property.     

Fibrin‐targeted plasminogen activation by plasminogen activator,PadA, from Streptococcus dysgalactiae

Bacterial plasminogen activators differ from each other in their mechanism of plasminogen activation besides their host specificity. Three‐domain streptokinase (SK) and two‐domain PauA generate nonproteolytic active site center in their cognate partner plasminogen but their binary activator complexes are resistant to α2‐antiplasmin (a2AP) inhibition causing nonspecific plasminogen activation in plasma. In contrast, single‐domain plasminogen activator, staphylokinase (SAK), requires proteolytic cleavage of human plasminogen into plasmin for the active site generation, and this activator complex is inhibited by a2AP. The single‐domain plasminogen activator, PadA, from Streptococcus dysgalatiae, having close sequence and possible structure homology with SAK, was recently reported to activate bovine Pg in a nonproteolytic manner similar to SK. We report hereby that the binary activator complex of PadA with bovine plasminogen is inhibited by a2AP and PadA is recycled from this complex to catalyze the activation of plasminogen in the clot environment, where it is completely protected from a2AP inhibition. Catalytic efficiency of the activator complex formed by PadA and bovine plasminogen is amplified several folds in the presence of cyanogen bromide digested fibrinogen but not by intact fibrinogen indicating that PadA may be highly efficient at the fibrin surface. The present study, thus, demonstrates that PadA is a unique single‐domain plasminogen activator that activates bovine plasminogen in a fibrin‐targeted manner like SAK. The sequence optimization by PadA for acquiring the characteristics of both SK and SAK may be exploited for the development of efficient and fibrin‐specific plasminogen activators for thrombolytic therapy.     

Role of the N-terminal region of staphylokinase (SAK): evidence for the participation of the N-terminal region of SAK in the enzyme-substrate complex formation

Staphylokinase (SAK) forms an inactive 1:1 complex with plasminogen (PG), which requires both the conversion of PG to plasmin (Pm) to expose an active site in PG-SAK activator complex and the amino-terminal processing of SAK to expose the positively charged (Lys-11) amino-terminus after removal of the 10 N-terminal amino acid residues from the full length protein. The mechanism by which the N-terminal segment of SAK affects its PG activation capability was investigated by generating SAK mutants, blocked in the native amino-terminal processing site of SAK, and carrying an alteration in the placement of the positively charged amino acid residue, Lys-11, and further studying their interaction with PG, Pm, miniplasmin and kringle structures. A ternary complex formation between PG-SAK PG was observed when an immobilized PG-SAK binary complex interacted with free radiolabelled PG in a sandwich binding experiment. Formation of this ternary complex was inhibited by a lysine analog, 6-aminocaproic acid (EACA), in a concentration dependent manner, suggesting the involvement of lysine binding site(s) in this process. In contrast, EACA did not significantly affect the formation of binary complex formed by native SAK or its mutant derivatives. Furthermore, the binary (activator) complex formed between PG and SAK mutant, PRM3, lacking the N-terminal lysine 11, exhibited 3-4-fold reduced binding with PG, Pm or miniplasmin substrate during ternary complex formation as compared to native SAK. Additionally, activator complex formed with PRM3 failed to activate miniplasminogen and exhibited highly diminished activation of substrate PG. Protein binding studies indicated that it has 3-5-fold reduction in ternary complex formation with miniplasmin but not with the kringle structure. In aggregate, these observations provide experimental evidence for the participation of the N-terminal region of SAK in accession and processing of substrate by the SAK-Pm activator complex to potentiate the PG activation by enhancing and/or stabilizing the interaction of free PG.     

Amino-Terminal Fusion of Epidermal Growth Factor 4,5,6 Domains of Human Thrombomodulin on Streptokinase Confers Anti-Reocclusion Characteristics along with Plasmin-Mediated Clot Specificity

Streptokinase (SK) is a potent clot dissolver but lacks fibrin clot specificity as it activates human plasminogen (HPG) into human plasmin (HPN) throughout the system leading to increased risk of bleeding. Another major drawback associated with all thrombolytics, including tissue plasminogen activator, is the generation of transient thrombin and release of clot-bound thrombin that promotes reformation of clots. In order to obtain anti-thrombotic as well as clot-specificity properties in SK, cDNAs encoding the EGF 4,5,6 domains of human thrombomodulin were fused with that of streptokinase, either at its N- or C-termini, and expressed these in Pichia pastoris followed by purification and structural-functional characterization, including plasminogen activation, thrombin inhibition, and Protein C activation characteristics. Interestingly, the N-terminal EGF fusion construct (EGF-SK) showed plasmin-mediated plasminogen activation, whereas the C-terminal (SK-EGF) fusion construct exhibited ‘spontaneous’ plasminogen activation which is quite similar to SK i.e. direct activation of systemic HPG in absence of free HPN. Since HPN is normally absent in free circulation due to rapid serpin-based inactivation (such as alpha-2-antiplasmin and alpha-2-Macroglobin), but selectively present in clots, a plasmin-dependent mode of HPG activation is expected to lead to a desirable fibrin clot-specific response by the thrombolytic. Both the N- and C-terminal fusion constructs showed strong thrombin inhibition and Protein C activation properties as well, and significantly prevented re-occlusion in a specially designed assay. The EGF-SK construct exhibited fibrin clot dissolution properties with much-lowered levels of fibrinogenolysis, suggesting unmistakable promise in clot dissolver therapy with reduced hemorrhage and re-occlusion risks.     

Kinetics of activated thrombin-activatable fibrinolysis inhibitor (TAFIa)-catalyzed cleavage of C-terminal lysine residues of fibrin degradation products and removal of plasminogen-binding sites

Partial digestion of fibrin by plasmin exposes C-terminal lysine residues, which comprise new binding sites for both plasminogen and tissue-type plasminogen activator (tPA). This binding increases the catalytic efficiency of plasminogen activation by 3000-fold compared with tPA alone. The activated thrombin-activatable fibrinolysis inhibitor (TAFIa) attenuates fibrinolysis by removing these residues, which causes a 97% reduction in tPA catalytic efficiency. The aim of this study was to determine the kinetics of TAFIa-catalyzed lysine cleavage from fibrin degradation products and the kinetics of loss of plasminogen-binding sites. We show that the k(cat) and K(m) of Glu(1)-plasminogen (Glu-Pg)-binding site removal are 2.34 s(-1) and 142.6 nm, respectively, implying a catalytic efficiency of 16.21 μm(-1) s(-1). The corresponding values of Lys(77)/Lys(78)-plasminogen (Lys-Pg)-binding site removal are 0.89 s(-1) and 96 nm implying a catalytic efficiency of 9.23 μm(-1) s(-1). These catalytic efficiencies of plasminogen-binding site removal by TAFIa are the highest of any TAFIa-catalyzed reaction with a biological substrate reported to date and suggest that plasmin-modified fibrin is a primary physiological substrate for TAFIa. We also show that the catalytic efficiency of cleavage of all C-terminal lysine residues, whether they are involved in plasminogen binding or not, is 1.10 μm(-1) s(-1). Interestingly, this value increases to 3.85 μm(-1) s(-1) in the presence of Glu-Pg. These changes are due to a decrease in K(m). This suggests that an interaction between TAFIa and plasminogen comprises a component of the reaction mechanism, the plausibility of which was established by showing that TAFIa binds both Glu-Pg and Lys-Pg.     

The blockage of the high-affinity lysine binding sites of plasminogen by EACA significantly inhibits prourokinase-induced plasminogen activation

Prourokinase-induced plasminogen activation is complex and involves three distinct reactions: (1) plasminogen activation by the intrinsic activity of prourokinase; (2) prourokinase activation by plasmin; (3) plasminogen activation by urokinase. To further understand some of the mechanisms involved, the effects of epsilon-aminocaproic acid (EACA), a lysine analogue, on these reactions were studied. At a low range of concentrations (10-50 microM), EACA significantly inhibited prourokinase-induced (Glu-/Lys-) plasminogen activation, prourokinase activation by Lys-plasmin, and (Glu-/Lys-) plasminogen activation by urokinase. However, no inhibition of plasminogen activation by Ala158-prourokinase (a plasmin-resistant mutant) occurred. Therefore, the overall inhibition of EACA on prourokinase-induced plasminogen activation was mainly due to inhibition of reactions 2 and 3, by blocking the high-affinity lysine binding interaction between plasmin and prourokinase, as well as between plasminogen and urokinase. These findings were consistent with kinetic studies which suggested that binding of kringle 1-4 of plasmin to the N-terminal region of prourokinase significantly promotes prourokinase activation, and that binding of kringle 1-4 of plasminogen to the C-terminal lysine158 of urokinase significantly promotes plasminogen activation. In conclusion, EACA was found to inhibit, rather than promote, prourokinase-induced plasminogen activation due to its blocking of the high-affinity lysine binding sites on plasmin(ogen).     

A chromogenic assay for the detection of plasmin generated by plasminogen activator immobilized on nitrocellulose using a para-nitroanilide synthetic peptide substrate

A direct solid phase chromogenic assay has been developed for the detection of plasmin (EC 3.4.21.7), generated by the interaction of a nitrocellulose-bound plasminogen activator, using the plasmin specific tripeptide substrate, H-D-valyl-leucyl-lysine - p-nitroaniline. para-Nitroaniline released by the cleavage of the lysine - p-nitroaniline bound by plasmin was derivatized to its diazonium salt and subsequently coupled to N-1-napthylethylenediamine in situ to form a diazoamino of an intense red color at the site of the plasminogen activator. This method was used to assay for the streptococcal plasminogen activator, streptokinase, not only in crude bacterial supernatants, but also to detect streptokinase secreted by individual bacterial colonies. In addition, this solid phase assay was used to identify monoclonal antibodies specific for streptokinase which could inhibit the activation of human plasminogen by streptokinase. This method also permitted simultaneous immunological and biochemical identification of the plasminogen activator, thus permitting unequivocal comparative observations. This assay is quantitative and sensitive to nanogram amounts of activator comparable to those obtained with soluble assays. This method may also be applicable for the detection of other plasminogen activators, such as tissue plasminogen activator, urokinase, and staphylokinase, and also for the detection of immobilized proteases which can cleave other substrates derivatized with p-nitroaniline. The reagents used in this assay are inexpensive and easy to prepare.     

Actin accelerates plasmin generation by tissue plasminogen activator.

Actin has been found to bind to plasmin's kringle regions, thereby inhibiting its enzymatic activity in a noncompetitive manner. We, therefore, examined its effect upon the conversion of plasminogen to plasmin by tissue plasminogen activator. Actin stimulated plasmin generation from both Glu- and Lys-plasminogen, lowering the Km for activation of Glu-plasminogen into the low micromolar range. Accelerated plasmin generation did not occur in the presence of epsilon-amino caproic acid or if actin was exposed to acetic anhydride, an agent known to acetylate lysine residues. Actin binds to tissue plasminogen activator (t-Pa) (Kd = 0.55 microM), at least partially via lysine-binding sites. Actin's stimulation of plasmin generation from Glu-plasminogen was inhibited by the addition of aprotinin and was restored by the substitution of plasmin-treated actin, indicating the operation of a plasmin-dependent positive feedback mechanism. Native actin binds to Lys-plasminogen, and promotes its conversion to plasmin even in the presence of aprotinin, indicating that plasmin's cleavage of either actin or plasminogen leads to further plasmin generation. Plasmin-treated actin binds Glu-plasminogen and t-PA simultaneously, thereby raising the local concentration of t-PA and plasminogen. Together, but not separately, actin and t-PA prolong the thrombin time of plasma through the generation of plasmin and fibrinogen degradation products. Actin-stimulated plasmin generation may be responsible for some of the changes found in peripheral blood following tissue injury and sepsis.     

α-Enolase of Streptococcus pneumoniae is a plasmin(ogen)-binding protein displayed on the bacterial cell surface

Binding of human plasminogen to Streptococcus pneumoniae and its subsequent activation promotes penetration of bacteria through reconstituted basement membranes. In this study, we have characterized a novel pneumococcal surface protein with a molecular mass of 47 kDa, designated Eno, which specifically binds human plasmin(ogen), exhibits alpha-enolase activity and is necessary for viability. Using enzyme assays, we have confirmed the alpha-enolase activity of both pneumococcal surface-displayed Eno and purified recombinant Eno protein. Immunoelectron microscopy indicated the presence of Eno in the cytoplasm as well as on the surface of encapsulated and unencapsulated pneumococci. Plasminogen-binding activity was demonstrated with whole pneumococcal cells and purified Eno protein. Binding of activated plasminogen was also shown for Eno; however, the affinity for plasmin is significantly reduced compared with plasminogen. Results from competitive inhibition assays indicate that binding is mediated through the lysine binding sites in plasmin(ogen). Carboxypeptidase B treatment and amino acid substitutions of the C-terminal lysyl residues of Eno indicated that the C-terminal lysine is pivotal for plasmin(ogen)-binding activity. Eno is ubiquitously distributed among pneumococcal serotypes, and binding experiments suggested the reassociation of secreted Eno to the bacterial cell surface. The reassociation was also confirmed by immunoelectron microscopy. The results suggest a mechanism of plasminogen activation for human pathogens that might contribute to their virulence potential in invasive infectious processes.     

Staphylokinase-Annexin XI Chimera Exhibited Efficient in Vitro Thrombolytic Activities

Annexins (ANXs) are a family of calcium dependent phospholipid binding proteins. Phospholipids such as phosphatidylserine are rapidly exposed on the surfaces of injured endothelial cells, activated platelets, and apoptotic cells in a large number of disorders. In this study, annexin V and XI (ANXV and ANXXI) were individually fused to the C-terminal of staphylokinase (SAK), a fibrin-selective thrombolytic protein, to form chimeras for evaluation of their in-vitro thrombolytic activities. The two chimeras were found to have plasminogen activation activity of comparable efficiency. When the chimeras were challenged under higher concentrations of plasmin for 1 h, hydrolysis of them into moieties was not seen on SDS–PAGE. In two thrombolytic assays, SAK-ANXXI was found to resolve both platelet rich plasma (PRP) clots and platelet poor plasma (PPP) clots with an efficiency similar to that of SAK. However, SAK-ANXV showed significantly reduced efficiency. With regard to anticoagulation ability, SAK-ANXXI was also found to have a stronger effect on dose-dependent extension of clotting time among the four tested proteins. The unique long N-terminal tail of ANXXI, composed of 202 residues, in contrast to the 16 residues of ANXV, probably served successfully to dispatch two moieties to function properly in a complicated microenvironment. Hence, a new option other than the most committed ANXV for the ANX based chimera without elaboration of linker construction is presented.     

Staphylokinase-annexin XI chimera exhibited efficient in vitro thrombolytic activities

Annexins (ANXs) are a family of calcium dependent phospholipid binding proteins. Phospholipids such as phosphatidylserine are rapidly exposed on the surfaces of injured endothelial cells, activated platelets, and apoptotic cells in a large number of disorders. In this study, annexin V and XI (ANXV and ANXXI) were individually fused to the C-terminal of staphylokinase (SAK), a fibrin-selective thrombolytic protein, to form chimeras for evaluation of their in-vitro thrombolytic activities. The two chimeras were found to have plasminogen activation activity of comparable efficiency. When the chimeras were challenged under higher concentrations of plasmin for 1 h, hydrolysis of them into moieties was not seen on SDS-PAGE. In two thrombolytic assays, SAK-ANXXI was found to resolve both platelet rich plasma (PRP) clots and platelet poor plasma (PPP) clots with an efficiency similar to that of SAK. However, SAK-ANXV showed significantly reduced efficiency. With regard to anticoagulation ability, SAK-ANXXI was also found to have a stronger effect on dose-dependent extension of clotting time among the four tested proteins. The unique long N-terminal tail of ANXXI, composed of 202 residues, in contrast to the 16 residues of ANXV, probably served successfully to dispatch two moieties to function properly in a complicated microenvironment. Hence, a new option other than the most committed ANXV for the ANX based chimera without elaboration of linker construction is presented.     

Crystal structure of a staphylokinase: variant a model for reduced antigenicity.

Staphylokinase (SAK) is a 15.5-kDa protein from Staphylococcus aureus that activates plasminogen by forming a 1 : 1 complex with plasmin. Recombinant SAK has been shown in clinical trials to induce fibrin-specific clot lysis in patients with acute myocardial infarction. However, SAK elicits high titers of neutralizing antibodies. Biochemical and protein engineering studies have demonstrated the feasibility of generating SAK variants with reduced antigenicity yet intact thrombolytic potency. Here, we present X-ray crystallographic evidence that the SAK(S41G) mutant may assume a dimeric structure. This dimer model, at 2.3-A resolution, could explain a major antigenic epitope (residues A72-F76 and residues K135-K136) located in the vicinity of the dimer interface as identified by phage-display. These results suggest that SAK antigenicity may be reduced by eliminating dimer formation. We propose several potential mutation sites at the dimer interface that may further reduce the antigenicity of SAK.     

Proteolytically induced variations in the enzymatic properties of tissue plasminogen activator. Activations, inactivations and reactivations

Tissue plasminogen activator was treated with Sepharose-bound trypsin or chymotrypsin. Trypsin rapidly converted the one-chain activator to the two-chain form. This caused a marked increase in the amidolytic activity, while plasminogen activation initially increased but then decreased again. SDS/polyacrylamide gel electrophoresis in combination with [3H]diisopropylfluorophosphate active-site labeling revealed that after the conversion to the two-chain activator a minor cleavage occurred in the B chain, while the A chain was substantially degraded. Chymotrypsin caused a marked decrease in both amidolytic activity and plasminogen activation. SDS/polyacrylamide gel electrophoresis under reducing conditions revealed that two pairs of new bands had appeared, with Mr or about 50,000/52,000 and 17,000/20,000 respectively. N-terminal sequence analysis identified cleavage sites at peptide bonds 420-421 and 423-424. These bonds are located in a region of the activator which is homologues to the segments of trypsin and chymotrypsin, where autocatalytic cleavages occur during their activations. However, treatment of two-chain activator with chymotrypsin had markedly less effect on plasminogen activation and amidolytic activity. By treatment of samples of chymotrypsin-digested one-chain activator with plasmin, amidolytic activity could be largely restored. Thus, chymotrypsin may, by cleaving bonds 420-421 and 423-424, convert the active one-chain activator into an 'inactive' zymogen, which is again 'activated' by plasmin cleavage.     

Kinetic studies on novel plasminogen activators. Demonstration of fibrin enhancement for hybrid enzymes comprising the A-chain of plasmin (Lys-78) and B-chain of tissue-type plasminogen activator (Ile-276) or urokinase (Ile-159).

The activation of plasminogen by two novel hybrid enzymes, constructed from the A-chain of plasmin and the B-chains of tissue-type plasminogen activator (t-PA) or urokinase, was compared with the activation by the parent enzymes. Basal kinetic constants for 'Lys-plasminogen' (human plasminogen with N-terminal lysine) and 'Glu-plasminogen' (human plasminogen with N-terminal glutamic acid) activation were similar to those of the parent activators. The Km for plasminogen turnover for both hybrid enzymes was considerably decreased in the presence of both soluble fibrin and a mimic, a CNBr digest of fibrinogen. These enhancements and the related apparent negative co-operativity are similar to the behaviour of t-PA itself. The results are discussed with regard to the molecular features involved in the mechanism of fibrin stimulation.     

Synthesis of recombinant human single-chain urokinase-type plasminogen activator variants resistant to plasmin and thrombin

Single-chain urokinase-type plasminogen activator (scu-PA), a potential therapeutic reagent for thrombosis, is activated in plasma by plasmin. The activated enzyme is further digested by plasmin to generate low-molecular-weight urokinase (LMW-UK), which has no affinity for fibrin. To circumvent this dual effect of plasmin, we synthesized in Escherichia coli a variant of scu-PA, which is not converted to LMW-UK on treatment with plasmin. In another variant, the activation cleavage site was modified such that activation by plasmin was slowed down and that inactivation by thrombin was greatly diminished. The combination of these variants may be applicable as an effective thrombolytic reagent for clinical use.     

Identification of a plasminogen-binding motif in PAM, a bacterial surface protein

Surface-associated plasmin(ogen) may contribute to the invasive properties of various cells. Analysis of plasmin(ogen)-binding surface proteins is therefore of interest. The N-terminal variable regions of M-like (ML) proteins from five different group A streptococcal serotypes (33,41,52,53 and 56) exhibiting the plasminogen-binding phenotype were cloned and expressed in Escherichia coli . The recombinant proteins all bound plasminogen with high affinity. The binding involved the kringle domains of plasminogen and was blocked by a lysine analogue, 6-aminohexanoic acid, indicating that lysine residues in the M-like proteins participate in the interaction. Sequence analysis revealed that the proteins contain common 13–16-amino-acid tandem repeats, each with a single central lysine residue. Experiments with fusion proteins and a 30-amino-acid synthetic peptide demonstrated that these repeats harbour the major plasminogen-binding site in the ML53 protein, as well as a binding site for the tissue-type plasminogen activator. Replacement of the lysine in the first repeat with alanine reduced the plasminogen-binding capacity of the ML53 protein by 80%. The results precisely localize the binding domain in a plasminogen surface receptor, thereby providing a unique ligand for the analysis of interactions between kringles and proteins with internal kringle-binding determinants.     

Plasmin generation induces neutrophil aggregation: dependence on the catalytic and lysine binding sites.

We established that plasmin (10(-10) M to 10(-6) M) caused neutrophils (PMN) to aggregate using an in vitro assay. Plasminogen had no PMN aggregatory activity even at a concentration of 2 microM. However, plasminogen caused PMN to aggregate when incubated with plasminogen activators [tissue plasminogen activator (25-200 U/ml) or urokinase (5-500 U/ml)]. Tissue plasminogen activator and urokinase alone had no PMN aggregatory activity. Analysis of these incubation mixtures indicated that plasmin was generated in the process and that the time course of plasmin generation correlated with the aggregation response. Active-site-inhibited plasmin did not induce PMN aggregation, indicating that a functional catalytic site was required for the response. Pretreatment of PMN with either active-site-inhibited plasmin or tranexamic acid prevented PMN aggregation by plasmin, indicating that both binding of plasmin to the cell surface via the lysine binding sites and catalysis were required for the response. The generation of plasmin during activation of fibrinolysis may play a pro-inflammatory role by mediating aggregation of PMN.     

Plasmin desensitization of the PAR1 thrombin receptor: kinetics, sites of truncation, and implications for thrombolytic therapy

It has been hypothesized that protease-activated receptors may be activated and attenuated by more than one protease. Here, we explore a desensitization mechanism of the PAR1 thrombin receptor by anticoagulant proteases and provide an explanation to the enigma of why plasmin/tissue plasminogen activator (t-PA) can both activate and deactivate platelets prior to thrombin treatment. By using a soluble N-terminal exodomain (TR78) as a model for the full-length receptor, we were able to unambiguously compare cleavage rates and specificities among the serum proteases. Thrombin cleaves TR78 at the R41-S42 peptide bond with a kcat of 120 s-1 and a KM of 16 microM to produce TR62 (residues 42-103). We found that, of the anticoagulant proteases, only plasmin can rapidly truncate the soluble exodomain at the R70/K76/K82 sites located on a linker region that tethers the ligand to the body of the receptor. Plasmin cleavage of the TR78 exodomain is nearly equivalent to that of thrombin cleavage at R41 with similar rates (kcat = 30 s-1) and affinity (KM = 18 microM). Specificity was demonstrated since there is no observed cleavage at the five other potential plasmin-cleavage sites. Plasmin also cleaves the TR78 exodomain at the R41 thrombin-cleavage site generating transiently activated exodomain. We directly demonstrated that plasmin cleaves these same sites in full-length membrane-embedded receptor expressed in yeast and COS7 fibroblasts. The rate of plasmin truncation is similar between the extensively glycosylated COS7-expressed receptor and the nonglycosylated yeast-produced receptor. Mutation of the R70/K76/K82 sites to A70/A76/A82 eliminates plasmin truncation and desensitization of thrombin-dependent Ca2+ signaling and converts PAR1 into a plasmin-activated receptor with full agonist activity for plasmin. Plasmin does not desensitize the Ca2+ response of platelets or COS7 cells to SFLLRN consistent with intermolecular ligand-binding sites being located to the C-terminal side of K82. Truncation of the wild-type receptor at the C-terminal plasmin-cleavage sites removes the N-terminal tethered ligand or preligand, thereby providing an effective pathway for PAR1 desensitization in vivo.     

Mhp182 (P102) binds fibronectin and contributes to the recruitment of plasmin(ogen) to the Mycoplasma hyopneumoniae cell surface

Mycoplasma hyopneumoniae is a major, economically damaging respiratory pathogen. Although M. hyopneumoniae cells bind plasminogen, the identification of plasminogen-binding surface proteins and the biological ramifications of acquiring plasminogen requires further investigation. mhp182 encodes a highly expressed 102 kDa protein (P102) that undergoes proteolytic processing to generate surface-located N-terminal 60 kDa (P60) and C-terminal 42 kDa (P42) proteins of unknown function. We show that recombinant P102 (rP102) binds plasminogen at physiologically relevant concentrations (K(D) ~ 76 nM) increasing the susceptibility of plasmin(ogen) to activation by tissue-specific plasminogen activator (tPA). Recombinant proteins constructed to mimic P60 (rP60) and P42 (rP42) also bound plasminogen at physiologically significant levels. M. hyopneumoniae surface-bound plasminogen was activated by tPA and is able to degrade fibrinogen, demonstrating the biological functionality of M. hyopneumoniae-bound plasmin(ogen) upon activation. Plasmin(ogen) was readily detected in porcine ciliated airways and plasmin levels were consistently higher in bronchoalveolar lavage fluid from M. hyopneumoniae-infected animals. Additionally, rP102 and rP42 bind fibronectin with K(D) s of 26 and 33 nM respectively and recombinant P102 proteins promote adherence to porcine kidney epithelial-like cells. The multifunctional binding ability of P102 and activation of M. hyopneumoniae-sequestered plasmin(ogen) by an exogenous activator suggests P102 plays an important role in virulence.     

Portal fusion protein constraints on function in DNA packaging of bacteriophage T4

Architecturally conserved viral portal dodecamers are central to capsid assembly and DNA packaging. To examine bacteriophage T4 portal functions, we constructed, expressed and assembled portal gene 20 fusion proteins. C-terminally fused (gp20-GFP, gp20-HOC) and N-terminally fused (GFP-gp20 and HOC-gp20) portal fusion proteins assembled in vivo into active phage. Phage assembled C-terminal fusion proteins were inaccessible to trypsin whereas assembled N-terminal fusions were accessible to trypsin, consistent with locations inside and outside the capsid respectively. Both N- and C-terminal fusions required coassembly into portals with approximately 50% wild-type (WT) or near WT-sized 20am truncated portal proteins to yield active phage. Trypsin digestion of HOC-gp20 portal fusion phage showed comparable protection of the HOC and gp20 portions of the proteolysed HOC-gp20 fusion, suggesting both proteins occupy protected capsid positions, at both the portal and the proximal HOC capsid-binding sites. The external portal location of the HOC portion of the HOC-gp20 fusion phage was confirmed by anti-HOC immuno-gold labelling studies that showed a gold 'necklace' around the phage capsid portal. Analysis of HOC-gp20-containing proheads showed increased HOC protein protection from trypsin degradation only after prohead expansion, indicating incorporation of HOC-gp20 portal fusion protein to protective proximal HOC-binding sites following this maturation. These proheads also showed no DNA packaging defect in vitro as compared with WT. Retention of function of phage and prohead portals with bulky internal (C-terminal) and external (N-terminal) fusion protein extensions, particularly of apparently capsid tethered portals, challenges the portal rotation requirement of some hypothetical DNA packaging mechanisms.