Bizarre parosteal osteochondromatous proliferation (Nora's Lesion) of the mandible. a rare bony lesion.

Bizarre parosteal osteochondromatous proliferation (BPOP) also eponymically called "Nora's lesion", is a rare benign reactive bone lesion first reported in 1983. BPOP occurs classically on the bones of the hands and feet and long bones. This lesion can easily be confused, both clinically and microscopically, with other benign and malignant lesions of bone, including osteochondroma, parosteal osteosarcoma, myositis ossificans and reactive periostitis. BPOP has been reported to have a high rate of recurrence. Only 3 cases of BPOP of the head and neck have been reported in the literature, of which one involved the maxilla. We present a rare case of BPOP involving the mandible in a 10 year old African American male. Microscopically, a fibro-cartilaginous cap giving rise to a proliferation of variably mineralized osteophytic finger-like projections of bone was seen. Multiple trabeculae of "blue bone" were noted as well as numerous atypical appearing chondrocytes. The lesion recurred within 4 months following the initial excision but has not recurred to date after the second local excision. To the best of our knowledge, this is the first report of BPOP arising in the mandible. In addition, we discuss the clinical and microscopic features, differential diagnosis, and prognosis of this rare entity. We present a case of BPOP of the mandible and believe this is the first report of such a case in the mandible.

The prolyl cis/trans isomerase cyclophilin 18 interacts with the tumor suppressor p53 and modifies its functions in cell cycle regulation and apoptosis.

The functional diversity of the tumor suppressor protein p53 is mainly regulated by protein interactions. In this study, we describe a new interaction with the peptidyl-prolyl cis/trans isomerase cyclophilin 18 (Cyp18). The interaction reduced the sequence-specific DNA binding of p53 in vitro, whereas the inhibition of the interaction increased p53-reporter gene activity in vivo. The active site of the folding helper enzyme Cyp18 was directly involved in binding. The proline-rich region (amino acids 64-91) of p53 was most likely responsible for the observed binding because a synthetic peptide comprising amino acids 68-81 of p53 inhibited this interaction, and a p53 variant containing a proline residue at position 72 (p53(P72)) interacted with Cyp18 more effectively than the corresponding p53(R72) variant. Impairment of the Cyp18-p53 interaction induced an accumulation of cells in the G2/M phase of the cell cycle, which was more pronounced when p53(P72) was expressed compared with p53(R72) in an otherwise isogenic cellular background. Moreover, p53-dependent apoptosis was elevated in Cyp18 knockout cells, suggesting an antiapoptotic potential of Cyp18-p53 complexes. Functional in vivo data hint to a possible clinical relevance of the p53-Cyp18 interaction observed.

A lytic enzyme cocktail from Streptomyces sp. B578 for the control of lactic and acetic acid bacteria in wine.

Beside yeasts, lactic acid bacteria (LAB) are the most abundant microbes in must during vinification. Whereas Oenococcos oeni is commercially used as a starter culture for the biological acid reduction in wines, other species are responsible for different types of wine spoilage. Members of the genera Pediococcus, Weissella, Leuconostoc, and Lactobacillus are producers of exopolysaccharide slimes, biogenic amines, acetic acid, and other off-flavors. In order to control microbial growth, different procedures such as heating of must and addition of sulfite or lysozyme from egg white are generally applied. Yet, because of health risks, the application of sulfite should be reduced and lysozyme is not effective against all LAB. In this study, we describe exoenzymes from a Streptomyces sp. strain B578 lysing nearly all wine-relevant strains of LAB and Gram-negative acetic acid bacteria. The lytic enzymes were active under wine-making conditions, such as the presence of sulfite and ethanol, low temperatures, and low pH values. The analysis of the exoenzyme composition revealed a synergistic action of different cell wall hydrolases. In conclusion, the lytic cocktail of Streptomyces sp. B578 is a promising tool for the control of wine-spoiling bacteria.

Environmental conditions impinge on dragline silk protein composition.

The silk formed in the major ampullate (MA) gland of the orb weaving spider Nephila clavipes is composed of two silk fibroins, which are called major ampullate spidroins 1 (MaSp1) and 2 (MaSp2). Analysis of proteolytic peptides and reactivity to spidroin type specific antibodies indicated that MaSp2 constituted only a minor part in the spinning dope as well as in the spun filaments. Upon starvation, a change in the silk's characteristic features was observed that was concomitant of a decrease in the contribution of MaSp2. The silk became less elastic and stiffer, which will better tailor its usability for the safety line, albeit at the expense of its employment as the web frame threads. In addition, since MaSp2 production requires greater ATP consumption, such a shift in the protein ratio cuts down on the energy costs to produce the silk. From this change in protein composition the spider might therefore benefit twice, by synthesizing 'cheaper' silk that into the bargain has properties that potentially can better support foraging in times of food shortage.

A novel inhalation allergen present in the working environment of beekeepers.

BACKGROUND: Inhalation allergies, caused by allergens from various kinds of pollen, house dust mites, animal epithelium, and mould fungi, are strongly increasing in frequency. In 2.6% of the cases the allergen source remains unidentified. The present paper describes a so far unknown inhalation allergy which was observed in the case of a patient working with hives. METHODS AND RESULTS: The allergen was characterized by immunoblotting, enzyme-linked immunosorbent assay inhibition, and isoelectrofocusing, using the serum of the patient. It is present in both the bee bodies and the larvae, has a molecular mass of 13 kDa, and an isoelectric point of 5.85. It is thermolabile and does not cross-react with allergens from birch, mugwort and timothy grass pollen, mould fungi, or bee venom. The N-terminal amino acid sequence of allergen from larvae was determined to be (2)QIEELKTRLHT(12). A similar allergen of 13 kDa was also found in Varroa mite accompanying bee populations. CONCLUSION: Honey bees (including the larva stadium) and Varroa mite contain a 13-kDa protein causing an allergic reaction. Presently, there is no evidence whether the case described is a singular phenomenon or whether this allergen is a more common inducer of allergies among subjects exposed to honey bees. However, a bee and Varroa mite allergy has to be considered for beekeepers after exclusion of known inhalation allergies.

Further characterization of IgE-binding antigens from guinea pig hair as new members of the lipocalin family.

BACKGROUND: Guinea pigs are important sources of inhalant allergens in home and working environments. However, little is known about the molecular characteristics and the relevant epitopes of guinea pig allergens. Recently, several allergens have been identified in hair extract and urine, and the major allergen Cav p 1 (20 kDa) has been characterized. OBJECTIVE: The aim of the present study was to isolate and to characterize a further major allergen from guinea pig hair with 17 kDa. METHODS: Guinea pig hair extract was fractionated using anion exchange chromatography and reverse-phase high performance liquid chromatography. Analyses were carried out by sodium dodecyl sulphate-polyacrylamide gel electrophoresis, 2D-PAGE, immunoblotting, immunoblot inhibition, glycoprotein detection, and N-terminal amino acid sequencing. RESULTS: The nonglycosylated 17 kDa allergen, which was named Cav p 2, was purified to homogeneity. On the basis its 15 N-terminal residues, there was 69% identity with a sequence of Bos d 2, an allergenic protein from cow dander belonging to the lipocalin family. The 2D-immunoblotting analyses of guinea pig hair extract demonstrated that Cav p 2 and Cav p 1, contained several isoforms with pI values ranging from 3.6 to 5.3. The 2D-immunoblot inhibition disclosed cross-reactive IgE epitopes on the allergens Cav p 2 and Cav p 1. Furthermore, Cav p 1 can form both monomers (20 kDa) and dimers (40-42 kDa). CONCLUSION: These studies provide important information on the isoallergen character of two relevant guinea pig allergens Cav p 1 and Cav p 2 as well as on their cross-reactive properties.

Purification and partial characterization of the major allergen, Cav p 1, from guinea pig Cavia porcellus.

BACKGROUND: Allergic reaction to guinea pig has been recognized as a problem in domestic settings and work environments for many years. Until recently, limited information was available on the properties of guinea pig allergen(s). In this study the major allergen Cav p 1 was characterized and the N-terminal amino-acid sequence was determined. METHODS AND RESULTS: Sera from 40 patients with IgE-mediated allergy to guinea pigs were investigated by means of immunoblotting using extracts prepared from guinea pig hair and urine. Three major allergens were identified within both sources with molecular weights (MW) of 8 kDa, 17 kDa and 20 kDa, respectively. From aqueous hair extracts the 20 kDa allergen (Cav p 1) was purified to homogeneity by anion exchange chromatography and reverse-phase HPLC and the N-terminal amino-acid sequence was determined. On the basis of the 15 residues, 57% identity was obtained from computer search with a sub-sequence of MUP (major urinary protein), a member of the lipocalin superfamily. Allergenic relationships among guinea pig allergens derived from various sources (hair and urine) or different animal species (mouse, rat, cat) were studied by ELISA inhibition assays. Neither urine of mouse, rat and cat, nor hair extracts of rat and cat produced appreciable inhibitions in guinea pig ELISA. CONCLUSION: Although the physicochemical characteristics of isolated Cav p 1 are very similar to those for other rodent allergens and furthermore partial sequence identity with Mus m 1 was found, it is clearly shown here to be an immunologically independent major allergen.

Protein-protein interactions of the primase subunits p58 and p48 with simian virus 40 T antigen are required for efficient primer synthesis in a cell-free system.

DNA polymerase alpha-primase (pol-prim, consisting of p180-p68-p58-p48), and primase p58-p48 (prim(2)) synthesize short RNA primers on single-stranded DNA. In the SV40 DNA replication system, only pol-prim is able to start leading strand DNA replication that needs unwinding of double-stranded (ds) DNA prior to primer synthesis. At high concentrations, pol-prim and prim(2) indistinguishably reduce the unwinding of dsDNA by SV40 T antigen (Tag). RNA primer synthesis on ssDNA in the presence of replication protein A (RPA) and Tag has served as a model system to study the initiation of Okazaki fragments on the lagging strand in vitro. On ssDNA, Tag stimulates whereas RPA inhibits the initiation reaction of both enzymes. Tag reverses and even overcompensates the inhibition of primase by RPA. Physical binding of Tag to the primase subunits and RPA, respectively, is required for these activities. Each subunit of the primase complex, p58 and p48, performs physical contacts with Tag and RPA independently of p180 and p68. Using surface plasmon resonance, the dissociation constants of the Tag/pol-prim and Tag/primase interactions were 1.2 x 10(-8) m and 1.3 x 10(-8) m, respectively.

The ternary microplasmin-staphylokinase-microplasmin complex is a proteinase-cofactor-substrate complex in action.

The serine proteinase plasmin is the key fibrinolytic enzyme that dissolves blood clots and also promotes cell migration and tissue remodeling. Here, we report the 2.65 A crystal structure of a ternary complex of microplasmin-staphylokinase bound to a second microplasmin. The staphylokinase 'cofactor' does not affect the active-site geometry of the plasmin 'enzyme', but instead modifies its subsite specificity by providing additional docking sites for enhanced presentation of the plasminogen 'substrate' to the 'enzymes's' active site. The activation loop of the plasmin 'substrate', cleaved in these crystals, can be reconstructed to show how it runs across the active site of the plasmin 'enzyme' prior to activation cleavage. This is the first experimental structure of a productive proteinase-cofactor-macromolecular substrate complex. Furthermore, it provides a template for the design of improved plasminogen activators and plasmin inhibitors with considerable therapeutical potential.

Nuclear magnetic resonance solution structure of the plasminogen-activator protein staphylokinase.

Staphylokinase, a 15.5 kDa protein from Staphylococcus aureus, is a plasminogen activator which is currently undergoing clinical trials for the therapy of myocardial infarction and peripheral thrombosis. The three-dimensional (3D) NMR solution structure has been determined by multidimensional heteronuclear NMR spectroscopy on uniformly 15N- and 15N,13C-labeled samples of staphylokinase. Structural constraints were obtained from 82 3JHNH alpha as well as 22 3JNH beta scalar coupling constants and 2345 NOE cross-peaks, derived from 15N-edited and 13C-edited 3D NOE spectra. NOE cross-peak assignments were confirmed by analysis of ¿15N,13C¿-edited and ¿13C,13C¿-edited 4D NOE spectra. The structure is presented as a family of 20 conformers which show an average rmsd of 1.02 +/- 0.15 A from the mean structure for the backbone atoms. The tertiary structure of staphylokinase shows a well-defined global structure consisting of a central 13-residue alpha-helix flanked by a two-stranded beta-sheet, both of which are located above a five-stranded beta-sheet. Two of the connecting loops exhibit a higher conformational heterogeneity. Overall, staphylokinase shows a strong asymmetry of hydrophilic and hydrophobic surfaces. The N-terminal sequence, including Lys10 which is the site of the initial proteolytic cleavage during activation of plasminogen, folds back onto the protein core, thereby shielding amino acids with functional importance in the plasminogen activation process. From a comparison of the structure with mutational studies, a binding region for plasminogen is proposed.

NH2-terminal structural motifs in staphylokinase required for plasminogen activation.

Staphylokinase (Sak) forms an inactive 1:1 stoichiometric complex with plasminogen which requires both conversion of plasminogen to plasmin and hydrolysis of the Lys10-Lys11 peptide bond of Sak to become a potent plasminogen activator (Schlott, B., Guhrs, K.-H., Hartmann, M., Rocker, A., and Collen, D. (1997) J. Biol. Chem. 272, 6067-6072). Exposure of a positively charged NH2-terminal amino acid after hydrolysis of Sak is a major determinant of the plasminogen-activating potential, but in itself is neither necessary nor sufficient. Here, the structural motifs of the NH2-terminal region Lys11-Gly-Asp-Asp-Ala-Ser16-Tyr-Phe-Glu of processed Sak, required for plasminogen activating potential, were studied by deletion and substitution mutagenesis. Expression in Escherichia coli of variants with deletion of 11, 14, 15, or 16 NH2-terminal amino acids yielded correctly processed but inactive molecules. Expression of their homologues with the NH2-terminal amino acid substituted with Lys-generated derivatives from which the NH2-terminal initiation Met was no longer removed, yielding inactive (50%) Sak42DDeltaN14(M), A15K and Sak42DDeltaN15(M),S16K, and inactive Sak42DDeltaN16(M),Y17K. Lys variants without NH2-terminal Met, generated from fusion proteins in which a His6 tag and a factor Xa recognition sequence were linked to the NH2 terminus of the Sak variants, were indistinguishable from their NH2-terminal Met-containing counterparts. All variants studied had intact affinities for plasminogen as measured by biospecific interaction analysis. The activity of Sak42DDeltaN11(M),G12K could be restored by additional substitution of both Asp13 and Asp14 with Asn, yielding active Sak42DDeltaN11(M),G12K, D13N, D14N, whereas substitution in Sak42DDeltaN16(M),Y17K of Phe18 and Glu19 with Asn yielded inactive Sak42DDeltaN16(M),Y17K,F18N,E19N. These data, in combination with the recent finding that the 20 NH2-terminal amino acids of Sak lack secondary structure, suggest that the NH2-terminal region of Sak is not required for binding to plasmin/plasminogen, but that a positively charged amino acid in the ultimate or penultimate NH2-terminal position corresponding to amino acids 11-16 of this flexible region participates in the reconfiguration of the active site of the plasmin molecule to endow it with plasminogen-activating potential.

NMR secondary structure of the plasminogen activator protein staphylokinase.

Staphylokinase (Sak) is a 15.5 kDa protein secreted by several strains of Staphylococcus aureus. Due to its ability to convert plasminogen, the inactive proenzyme of the fibrinolytic system, into plasmin, Sak is presently undergoing clinical trials for blood clot lysis in the treatment of thrombovascular disorders. With a view to developing a better understanding of the mode of action of Sak, we have initiated a structural investigation of Sak via multidimensional heteronuclear NMR spectroscopy employing uniformly 15N- and 15N, 13C-labelled Sak. Sequence-specific resonance assignments have been made employing 15N-edited TOCSY and NOE experiments and from HNCACB, CBCA(CO)NH, HBHA-(CBCACO) NH and CC(CO)NH sets of experiments. From an analysis of the chemical shifts, 3JHNH alpha scalar coupling constants, NOEs and HN exchange data, the secondary structural elements of Sak have been characterized.

Staphylokinase requires NH2-terminal proteolysis for plasminogen activation.

Staphylokinase (Sak), a single-chain protein comprising 136 amino acids with NH2-terminal sequence,SSSFDKGKYKKGDDA forms a complex with plasmin, that is endowed with plasminogen activating properties. Plasmin is presumed to process mature (high molecular weight, HMW) Sak to low molecular weight derivatives (LMW-Sak), primarily by hydrolyzing the Lys10-Lys11 peptide bond, but the kinetics of plasminogen activation by HMW-Sak and LMW-Sak are very similar. Here, the requirement of NH2-terminal proteolysis of Sak for the induction of plasminogen activating potential was studied by mutagenesis of Lys10 and Lys11 in combination with NH2-terminal microsequence analysis of equimolar mixtures of Sak and plasminogen and determination of kinetic parameters of plasminogen activation by catalytic amounts of Sak. Substitution of Lys10 with Arg did not affect processing of the Arg10-Lys11 site nor plasminogen activation, whereas substitution with His resulted in cleavage of the Lys11-Gly12 peptide bond and abolished plasminogen activation. Substitution of Lys11 with Arg did not affect Lys10-Arg11 processing or plasminogen activation, whereas replacement with His did not prevent Lys10-His11 hydrolysis but abolished plasminogen activation. Substitution of Lys11 with Cys yielded an inactive processed derivative which was fully activated by aminoethylation. Deletion of the 10 NH2-terminal amino acids did not affect plasminogen activation, but additional deletion of Lys11 eliminated plasminogen activation. Thus generation of plasminogen activator potential in Sak proceeds via plasmin-mediated removal of the 10 NH2-terminal amino acids with exposure of Lys11 as the new NH2 terminus. This provides a structural basis for the hypothesis, derived from kinetic measurements, that plasminogen activation by Sak needs to be primed by plasmin and a mechanism for the high fibrin selectivity of Sak in a plasma milieu.

Functional significance of NH2- and COOH-terminal regions of staphylokinase in plasminogen activation.

Structure/function relationships in the activation of plasminogen with staphylokinase were studied using mutants of recombinant staphylokinase (Sak42D). Deletion of up to 10 NH2-terminal amino acids (Sak42D delta N10) did not affect plasminogen activation, but removal of 11 amino acids completely abolished the ability to activate plasminogen. Elimination of potential plasmin cleavage sites in the NH2-terminal region yielding mutants Sak42D(K8H,K10H,K11H) and Sak42D(K6H,K8H,K11H) did not alter the rate of the exposure of a proteolytically active site (amidolytic activity) in equimolar mixtures with plasminogen, but destroyed the plasminogen activator properties of these muteins. Deleting two residues following the preferred processing site at position 10 (Sak42 delta (K11,G12)) resulted in a mutein also inactive in plasminogen activation. Removal of the COOH-terminal Lys136, yielding Sak42D delta C1, or of Lys135 and Lys136 in Sak42D delta C2 resulted in proteins with strongly reduced plasminogen activation capacity. In contrast, substitution of Lys135 and Lys136 with Ala in Sak42D(K135A,K136A) did not affect activation. Cyanogen bromide cleavage of Sak42D(M26L,E61M,D82E) produced a 61 amino acid NH2-terminal and a 65 amino acid COOH-terminal fragment which did not activate plasminogen, but bound to plasminogen with affinity constants Ka of 4.0 x 10(5) M-1 and 1.4 x 10(7) M-1, respectively (as compared to a Ka of 1.1 x 10(8) M-1 for Sak42D). These results indicate that Lys11 and the COOH-terminal region of staphylokinase play a key role in the activation of plasminogen.

A correlation between thermal stability and structural features of staphylokinase and selected mutants: a Fourier-transform infrared study.

Variants of recombinant staphylokinase (Sak) were investigated by Fourier-transform infrared spectroscopy: Sak (wild type), Sak-M26A, Sak-M26L, and Sak-G34S/R36G/R43H (Sak-B). Estimation of the secondary structure and hydrogen-deuterium exchange experiments revealed the existence of fast-exchanging and strongly solvent-exposed fractions of the helical structures in the two samples Sak and Sak-M26L. These two samples are also thermally less stable with unfolding transition temperatures of 43.7 degrees C (Sak) and 43.5 degrees C (Sak-M26L), respectively. On contrast, Sak-M26A and Sak-G34S/R36G/R43H have a slower hydrogen-deuterium exchange, have a smaller solvent-exposed portion of the helical part, and are more resistant against thermal unfolding; the transition temperatures are 51.7 degrees C and 59.3 degrees C, respectively. The secondary structure analysis was performed by two different approaches, by curve-fitting after band narrowing and by pattern recognition (factor analysis) based upon reference spectra of proteins with known crystal structure. Within the limits of the used methods, we are unable to detect significant differences in the secondary structure of the four variants of Sak. According to the results of the factor analysis, the portions of secondary structure elements were obtained to 16-20% alpha-helix, 28-30% beta-sheet, 23-27% turns, 28-30% irregular (random) and other structure. The sharp differences in the specific plasminogen-activating capacity (Sak, Sak-G34S/R36G/R43H and Sak-M26L are fully active, but Sak-M26A does not form a stable complex with plasminogen) are not reflected in the structural features revealed by the infrared spectra of this study.

Structure-function relationships in staphylokinase as revealed by "clustered charge to alanine" mutagenesis.

Eighteen mutants of recombinant staphylokinase (SakSTAR) in which clusters of two or three charged residues were converted to alanine ("clustered charge-to-alanine scan") were characterized. Fifteen of these mutants had specific plasminogen-activating activities of > 20% of that of wild-type SakSTAR, whereas three mutants, SakSTAR K11A D13A D14A (SakSTAR13), SakSTAR E46A K50A (SakSTAR48), and SakSTAR E65A D69A (SakSTAR67) had specific activities of 3%. SakSTAR13 had an intact affinity for plasminogen and a normal rate of active site exposure in equimolar mixtures with plasminogen. The plasmin-SakSTAR13 complex had a 14-fold reduced catalytic efficiency for plasminogen activation but was 5-fold more efficient for conversion of plasminogen-SakSTAR13 to plasmin-SakSTAR13. SakSTAR48 and SakSTAR67 had a 10-20-fold reduced affinity for plasminogen and a markedly reduced active site exposure; their complexes with plasmin had a more than 20-fold reduced catalytic efficiency toward plasminogen. Thus, plasminogen activation by catalytic amounts of SakSTAR is dependent on complex formation between plasmin(ogen) and SakSTAR, which is deficient with SakSTAR48 and SakSTAR67, but also on the induction of a functional active site configuration in the plasmin-SakSTAR complex, which is deficient with all three mutants. These findings support a mechanism for the activation of plasminogen by SakSTAR involving formation of an equimolar complex of SakSTAR with traces of plasmin, which converts plasminogen to plasmin and, more rapidly, inactive plasminogen-SakSTAR to plasmin-SakSTAR.

The fibrinolytic activity of staphylokinase mutants in the fibrin plate assay.

The fibrinolytic activity of the new plasminogen activator, recombinant staphylokinase, was compared to that of streptokinase and tissue-type plasminogen activator in the fibrin plate assay. The pattern of fibrinolysis by staphylokinase on fibrin plates differs from the other plasminogen activators. A number of mutants of staphylokinase with various amino acids in position 26 substituted for methionine in wild-type staphylokinase were compared with respect to their fibrinolytic potencies. Only the mutants with cysteine or leucine in this position have a fibrinolytic activity comparable to wild-type staphylokinase. The results on the fibrinolytic activities in the fibrin plate assay correlate with those of a plasmin generation assay, the latter is, however, less sensitive.

Characterization of the interaction between plasminogen and staphylokinase.

Binding parameters [association (ka) and dissociation (kd) rate constants, and affinity constants (Ka = ka/kd)] for the interaction between recombinant staphylokinase (SakSTAR) and plasmin(ogen) were determined by real-time biospecific interaction analysis. The Ka value for binding of SakSTAR to native human Glu-plasminogen was 0.93 x 10(8) M-1 as compared to 2.0 x 10(8) M-1 and 1.6 x 10(8) M-1, respectively, for the binding to [S741A]recombinant plasminogen or Lys-[S741A]recombinant plasminogen (intact or proteolytically degraded plasminogen with the active site Ser741 replaced by alanine). Binding of SakSTAR to active plasmin or to active-site blocked plasmin occurred with Ka values of 4.0 x 10(8) M-1 and 8.4 x 10(8) M-1, respectively, whereas active-site blocked LMM-plasmin (a plasmin derivative lacking kringles 1-4) and the plasmin B-chain bound with Ka values of 1.0 x 10(8) M-1 and 0.49 x 10(8) M-1, respectively. Lysine-binding site I (a plasminogen derivative consisting of kringles 1-3) and lysine-binding site II (a plasminogen derivative consisting of kringle 4) bound with much lower affinity (Ka values of 1.2 x 10(5) M-1 and 2.9 x 10(5) M-1, respectively). The binding of these plasminogen derivatives to streptokinase occurred with similar relative Ka values. The Ka values for binding of the plasmin-SakSTAR complex to streptokinase and binding of the plasmin-streptokinase complex to SakSTAR, were, respectively, 44-fold and 30-fold lower than the values for free plasmin. The Ka for binding of plasminogen to the inactive mutants [M26R]Sak42D or [M26A]Sak42D (site-specific mutagenesis of Met26 to arginine or alanine) were 10-20-fold lower than that of native staphylokinase. These results indicate that: (a) the affinity of staphylokinase for Glu-plasminogen and Lys-plasminogen is comparable; (b) the active site in the plasmin molecule is not required for binding; (c) kringle structures 1-4 of plasminogen do not contribute significantly to plasminogen binding of staphylokinase; (d) Met26 in staphylokinase is important for its high-affinity binding to plasminogen; (e) the binding sites on plasmin for staphylokinase and streptokinase overlap at least partially.