The maintenance of high affinity plasminogen binding by group A streptococcal plasminogen-binding M-like protein is mediated by arginine and histidine residues within the a1 and a2 repeat domains

Subversion of the plasminogen activation system is implicated in the virulence of group A streptococci (GAS). GAS displays receptors for the human zymogen plasminogen on the cell surface, one of which is the plasminogen-binding group A streptococcal M-like protein (PAM). The plasminogen binding domain of PAM is highly variable, and this variation has been linked to host selective immune pressure. Site-directed mutagenesis of full-length PAM protein from an invasive GAS isolate was undertaken to assess the contribution of residues in the a1 and a2 repeat domains to plasminogen binding function. Mutagenesis to alanine of key plasminogen binding lysine residues in the a1 and a2 repeats (Lys98 and Lys111) did not abrogate plasminogen binding by PAM nor did additional mutagenesis of Arg101 and His102 and Glu104, which have previously been implicated in plasminogen binding. Plasminogen binding was only abolished with the additional mutagenesis of Arg114 and His115 to alanine. Furthermore, mutagenesis of both arginine (Arg101 and Arg114) and histidine (His102 and His115) residues abolished interaction with plasminogen despite the presence of Lys98 and Lys111 in the binding repeats. This study shows for the first time that residues Arg101, Arg114, His102, and His115 in both the a1 and a2 repeat domains of PAM can mediate high affinity plasminogen binding. These data suggest that highly conserved arginine and histidine residues may compensate for variation elsewhere in the a1 and a2 plasminogen binding repeats, and may explain the maintenance of high affinity plasminogen binding by naturally occurring variants of PAM.     

The plasminogen-binding group A streptococcal M protein-related protein Prp binds plasminogen via arginine and histidine residues

The migration of the human pathogen Streptococcus pyogenes (group A streptococcus) from localized to deep tissue sites may result in severe invasive disease, and sequestration of the host zymogen plasminogen appears crucial for virulence. Here, we describe a novel plasminogen-binding M protein, the plasminogen-binding group A streptococcal M protein (PAM)-related protein (Prp). Prp is phylogenetically distinct from previously described plasminogen-binding M proteins of group A, C, and G streptococci. While competition experiments indicate that Prp binds plasminogen with a lower affinity than PAM (50% effective concentration = 0.34 microM), Prp nonetheless binds plasminogen with high affinity and at physiologically relevant concentrations of plasminogen (K(d) = 7.8 nM). Site-directed mutagenesis of the putative plasminogen binding site indicates that unlike the majority of plasminogen receptors, Prp does not interact with plasminogen exclusively via lysine residues. Mutagenesis to alanine of lysine residues Lys(96) and Lys(101) reduced but did not abrogate plasminogen binding by Prp. Plasminogen binding was abolished only with the additional mutagenesis of Arg(107) and His(108) to alanine. Furthermore, mutagenesis of Arg(107) and His(108) abolished plasminogen binding by Prp despite the presence of Lys(96) and Lys(101) in the binding site. Thus, binding to plasminogen via arginine and histidine residues appears to be a conserved mechanism among plasminogen-binding M proteins.     

Natural selection and evolution of streptococcal virulence genes involved in tissue-specific adaptations

The molecular mechanisms underlying niche adaptation in bacteria are not fully understood. Primary infection by the pathogen group A streptococcus (GAS) takes place at either the throat or the skin of its human host, and GAS strains differ in tissue site preference. Many skin-tropic strains bind host plasminogen via the plasminogen-binding group A streptococcal M protein (PAM) present on the cell surface; inactivation of genes encoding either PAM or streptokinase (a plasminogen activator) leads to loss of virulence at the skin. Unlike PAM, which is present in only a subset of GAS strains, the gene encoding streptokinase (ska) is present in all GAS isolates. In this study, the evolution of the virulence genes known to be involved in skin infection was examined. Most genetic diversity within ska genes was localized to a region encoding the plasminogen-docking domain (beta-domain). The gene encoding PAM displayed strong linkage disequilibrium (P < 0.01) with a distinct phylogenetic cluster of the ska beta-domain-encoding region. Yet, ska alleles of distant taxa showed a history of intragenic recombination, and high intrinsic levels of recombination were found among GAS strains having different tissue tropisms. The data suggest that tissue-specific adaptations arise from epistatic coselection of bacterial virulence genes. Additional analysis of ska genes showed that approximately 4% of the codons underwent strong diversifying selection. Horizontal acquisition of one ska lineage from a commensal Streptococcus donor species was also evident. Together, the data suggest that new phenotypes can be acquired through interspecies recombination between orthologous genes, while constrained functions can be preserved; in this way, orthologous genes may provide a rich and ready source for new phenotypes and thereby play a facilitating role in the emergence of new niche adaptations in bacteria.     

Group A streptococcal phagocytosis resistance is independent of complement factor H and factor H-like protein 1 binding

Factor H (FH) and factor H-like protein 1 (FHL-1) regulate complement activation through the alternative pathway. Several extracellular bacterial pathogens, prime targets for the complement system, bind FH and FHL-1, thereby acquiring a potential mechanism for minimizing complement deposition on their surface. For group A streptococci (GAS), surface-bound antiphagocytic M proteins mediate the interaction. To study the role of the FH-FHL-1 interaction for complement deposition and opsonophagocytosis of GAS, we first constructed a set of truncated M5 protein variants and expressed them on the surface of a homologous M-negative GAS strain. Binding experiments with the resulting strains demonstrated that the major FH-FHL-1 binding is located in a 42-amino-acid region within the N-terminal third of M5. Measurement of bacteria-bound complement factor C3 after incubation in plasma showed that the presence of this region had little impact upon complement deposition through the alternative pathway. Moreover, streptococci expressing M5 proteins lacking the major FH and FHL-1 binding sequence resisted phagocytosis in human blood as efficiently as bacteria expressing the wild-type protein. Consequently, the data suggest that the binding of the regulators of the alternative pathway is of limited importance for GAS phagocytosis resistance.     

The β-domain of cluster 2b streptokinase is a major determinant for the regulation of its plasminogen activation activity by cellular plasminogen receptors

Cluster 2b streptokinase (SK2b), secreted by invasive skin-trophic strains of Streptococcus pyogenes (GAS), is a human plasminogen (hPg) activator that optimally functions when human plasma hPg is bound, via its kringle-2 domain, to cognizant bacterial cells through the a1a2 domain of the major cellular hPg receptor, Plasminogen-binding group A streptococcal M-like protein (PAM). Another class of streptokinases (SK1), secreted primarily by GAS strains that possess affinity for pharyngeal infections, does not require PAM-bound hPg for optimal activity. We find herein that replacement of the central β-domain of SK2b with the same module from SK1 reduces the dependency of SK2b on PAM, and the converse is true when the β-domain of SK1 is replaced with this same region of SK2b. These data suggest that simple evolutionary shuttling of protein domains in GAS can be employed by GAS to rapidly generate strains that differ in tissue tropism and invasive capability and allow the bacteria to survive different challenges by the host.     

Haemophilus influenzae uses the surface protein E to acquire human plasminogen and to evade innate immunity

Pathogenic microbes acquire the human plasma protein plasminogen to their surface. In this article, we characterize binding of this important coagulation regulator to the respiratory pathogen nontypeable Haemophilus influenzae and identify the Haemophilus surface protein E (PE) as a new plasminogen-binding protein. Plasminogen binds dose dependently to intact bacteria and to purified PE. The plasminogen-PE interaction is mediated by lysine residues and is also affected by ionic strength. The H. influenzae PE knockout strain (nontypeable H. influenzae 3655Δpe) bound plasminogen with ～65% lower intensity as compared with the wild-type, PE-expressing strain. In addition, PE expressed ectopically on the surface of Escherichia coli also bound plasminogen. Plasminogen, either attached to intact H. influenzae or bound to PE, was accessible for urokinase plasminogen activator. The converted active plasmin cleaved the synthetic substrate S-2251, and the natural substrates fibrinogen and C3b. Using synthetic peptides that cover the complete sequence of the PE protein, the major plasminogen-binding region was localized to a linear 28-aa-long N-terminal peptide, which represents aa 41-68. PE binds plasminogen and also vitronectin, and the two human plasma proteins compete for PE binding. Thus, PE is a major plasminogen-binding protein of the Gram-negative bacterium H. influenzae, and when converted to plasmin, PE-bound plasmin aids in immune evasion and contributes to bacterial virulence.     

Enhancement through mutagenesis of the binding of the isolated kringle 2 domain of human plasminogen to omega-amino acid ligands and to an internal sequence of a Streptococcal surface protein.

In the background of the recombinant K2 module of human plasminogen (K2(Pg)), a triple mutant, K2(Pg)[C4G/E56D/L72Y], was generated and expressed in Pichia pastoris cells in yields exceeding 100 mg/liter. The binding affinities of a series of lysine analogs, viz. 4-aminobutyric acid, 5-aminopentanoic acid, epsilon-aminocaproic acid, 7-aminoheptanoic acid, and t-4-aminomethylcyclohexane-1-carboxylic acid, to this mutant were measured and showed up to a 15-fold tighter interaction, as compared with wild-type K2(Pg) (K2(Pg)[C4G]). The variant, K2(Pg)[C4G/E56D], afforded up to a 4-fold increase in the binding affinity to these same ligands, whereas the K2(Pg)[C4G/L72Y] mutant decreased the same affinities up to 5-fold, as compared with K2(Pg)[C4G]. The thermal stability of K2(Pg)[C4G/E56D/L72Y] was increased by approximately 13 degrees C, as compared with K2(Pg)[C4G]. The functional consequence of up-regulating the lysine binding property of K2(Pg) was explored, as reflected by its ability to interact with an internal sequence of a plasminogen-binding protein (PAM) on the surface of group A streptococci. A 30-mer peptide of PAM, containing its K2(Pg)-specific binding region, was synthesized, and its binding to each mutant of K2(Pg) was assessed. Only a slight enhancement in peptide binding was observed for K2(Pg)[C4G/E56D], compared with K2(Pg)[C4G] (K(d) = 460 nM). A 5-fold decrease in binding affinity was observed for K2(Pg)[C4G/L72Y] (K(d) = 2200 nM). However, a 12-fold enhancement in binding to this peptide was observed for K2(Pg)[C4G/E56D/L72Y] (K(d) = 37 nM). Results of these PAM peptide binding studies parallel results of omega-amino acid binding to these K2(Pg) mutants, indicating that the high affinity PAM binding by plasminogen, mediated exclusively through K2(Pg), occurs through its lysine-binding site. This conclusion is supported by the 100-fold decrease in PAM peptide binding to K2(Pg)[C4G/E56D/L72Y] in the presence of 50 mM 6-aminohexanoic acid. Finally, a thermodynamic analysis of PAM peptide binding to each of these mutants reveals that the positions Asp(56) and Tyr(72) in the K2(Pg)[C4G/E56D/L72Y] mutant are synergistically coupled in terms of their contribution to the enhancement of PAM peptide binding.     

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.     

The lack of binding of VEK-30, an internal peptide from the group A streptococcal M-like protein, PAM, to murine plasminogen is due to two amino acid replacements in the plasminogen kringle-2 domain

VEK-30, a 30-amino acid internal peptide present within a streptococcal M-like plasminogen (Pg)-binding protein (PAM) from Gram-positive group-A streptococci (GAS), represents an epitope within PAM that shows high affinity for the lysine binding site (LBS) of the kringle-2 (K2) domain of human (h)Pg. VEK-30 does not interact with this same region of mouse (m)Pg, despite the high conservation of the mK2- and hK2-LBS. To identify the molecular basis for the species specificity of this interaction, hPg and mPg variants were generated, including an hPg chimera with the mK2 sequence and an mPg chimera containing the hK2 sequence. The binding of synthetic VEK-30 to these variants was studied by surface plasmon resonance. The data revealed that, in otherwise intact Pg, the species specificity of VEK-30 binding in these two cases is entirely dictated by two K2 residues that are different between hPg and mPg, namely, Arg-220 of hPg, which is a Gly in mPg, and Leu-222 of hPg, which is a Pro in mPg, neither of which are members of the canonical K2-LBS. Neither the activation of hPg, nor the enzymatic activity of its activated product, plasmin (hPm), are compromised by replacing these two amino acids by their murine counterparts. It is also demonstrated that hPg is more susceptible to activation to hPm after complexation with VEK-30 and that this property is greatly reduced as a result of the R220G and L222P replacements in hPg. These mechanisms for accumulation of protease activity on GAS likely contribute to the virulence of PAM(+)-GAS strains and identify targets for new therapeutic interventions.     

Binding of the low-density lipoprotein by streptococcal collagen-like protein Scl1 of Streptococcus pyogenes

Several bacterial genera express proteins that contain collagen-like regions, which are associated with variable (V) non-collagenous regions. The streptococcal collagen-like proteins, Scl1 and Scl2, of group A Streptococcus (GAS) are members of this 'prokaryotic collagen' family, and they too contain an amino-terminal non-collagenous V region of unknown function. Here, we use recombinant rScl constructs, derived from several Scl1 and Scl2 variants, and affinity chromatography to identify Scl ligands present in human plasma. First, we show that Scl1, but not Scl2, proteins from different GAS serotypes bind the same ligand identified as apolipoprotein B (ApoB100), which is a major component of the low-density lipoprotein (LDL). Scl1 binding to purified ApoB100 and LDL is specific and concentration-dependent. Furthermore, the non-collagenous V region of the Scl1 protein is responsible for LDL/ApoB100 binding because only those rScls, constructed by domain swapping, which contain the V region from Scl1 proteins, were able to bind to ApoB100 and LDL ligands, and this binding was inhibited by antibodies directed against the Scl1-V region. Electron microscopy images of Scl1-LDL complexes showed that the globular V domain of Scl1 interacted with spherical particles of LDL. Importantly, live M28-type GAS cells absorbed plasma LDL on the cell surface and this binding depended on the surface expression of the Scl1.28, but not Scl2.28, protein. Phylogenetic analysis showed that the non-collagenous globular domains of Scl1 and Scl2 evolved independently to form separate lineages, which differ in amino acid sequence, and these differences may account for the variations in binding patterns of Scl1 and Scl2 proteins. Present studies provide insight into the structure-function relationship of the Scl proteins and also underline the importance of lipoprotein binding by GAS.     

Characterization of Streptokinases from Group A Streptococci Reveals a Strong Functional Relationship That Supports the Coinheritance of Plasminogen-binding M Protein and Cluster 2b Streptokinase

Group A streptococcus (GAS) strains secrete the protein streptokinase (SK), which functions by activating host human plasminogen (hPg) to plasmin (hPm), thus providing a proteolytic framework for invasive GAS strains. The types of SK secreted by GAS have been grouped into two clusters (SK1 and SK2) and one subcluster (SK2a and SK2b). SKs from cluster 1 (SK1) and cluster 2b (SK2b) display significant evolutionary and functional differences, and attempts to relate these properties to GAS skin or pharynx tropism and invasiveness are of great interest. In this study, using four purified SKs from each cluster, new relationships between plasminogen-binding group A streptococcal M (PAM) protein and SK2b have been revealed. All SK1 proteins efficiently activated hPg, whereas all subclass SK2b proteins only weakly activated hPg in the absence of PAM. Surface plasmon resonance studies revealed that the lower affinity of SK2b to hPg served as the basis for the attenuated activation of hPg by SK2b. Binding of hPg to either human fibrinogen (hFg) or PAM greatly enhanced activation of hPg by SK2b but minimally influenced the already effective activation of hPg by SK1. Activation of hPg in the presence of GAS cells containing PAM demonstrated that PAM is the only factor on the surface of SK2b-expressing cells that enabled the direct activation of hPg by SK2b. As the binding of hPg to PAM is necessary for hPg activation by SK2b, this dependence explains the coinherant relationship between PAM and SK2b and the ability of these particular strains to generate the proteolytic activity that disrupts the innate barriers that limit invasiveness.     

M41型A群链球菌的Ⅰ型胶原样蛋白与人低密度脂蛋白的相互作用

【目的】检测M41型A群链球菌(GAS)ATCC12373中Ⅰ型胶原样蛋白(Scl1)与人低密度脂蛋白(LDL)的相互作用。【方法】克隆了M41型GAS ATCC12373的Ⅰ型胶原样蛋白(Scl1)及其V区(Scl1-V)基因,并表达、纯化重组蛋白rScl1(C176)和rScl1-V(C176V)。通过重组蛋白与人血浆的亲和色谱层析、Western blot及酶联免疫吸附试验(ELISA)检测C176、C176V与LDL的相互作用;通过GAS与LDL的ELISA试验和人血浆与GAS的共孵育试验,检测GAS与LDL的相互作用。【结果】结果证明C176和C176V可以与LDL特异性结合;表达Scl1的M41型GAS可以与LDL相结合。【结论】M41型GAS的Scl1可以与LDL特异性结合。     

Streptokinase variants from Streptococcus pyogenes isolates display altered plasminogen activation characteristics – implications for pathogenesis

Streptococcus pyogenes (group A streptococcus, GAS) secretes streptokinase, a potent plasminogen activating protein. Among GAS isolates, streptokinase gene sequences (ska) are polymorphic and can be grouped into two distinct sequence clusters (termed cluster type‐1 and cluster type‐2) with cluster type‐2 being further divided into sub‐clusters type‐2a and type‐2b. In this study, far‐UV circular dichroism spectroscopy indicated that purified streptokinase variants of each type displayed similar secondary structure. Type‐2b streptokinase variants could not generate an active site in Glu‐plasminogen through non‐proteolytic mechanisms while all other variants had this capability. Furthermore, when compared with other streptokinase variants, type‐2b variants displayed a 29‐ to 35‐fold reduction in affinity for Glu‐plasminogen. All SK variants could activate Glu‐plasminogen when an activator complex was preformed with plasmin; however, type‐2b and type‐1 complexes were inhibited by α₂‐antiplasmin. Exchanging ska_type‐2a in the M1T1 GAS strain 5448 with ska_type‐2b caused a reduction in virulence while exchanging ska_type‐2a with ska_type‐1 into 5448 produced an increase in virulence when using a mouse model of invasive disease. These findings suggest that streptokinase variants produced by GAS isolates utilize distinct plasminogen activation pathways, which directly affects the pathogenesis of this organism.     

The Group A Streptococcus serotype M2 pilus plays a role in host cell adhesion and immune evasion

Group A Streptococcus (GAS), or Streptococcus pyogenes, is a human pathogen that causes diseases ranging from skin and soft tissue infections to severe invasive diseases, such as toxic shock syndrome. Each GAS strain carries a particular pilus type encoded in the variable f ibronectin‐binding, c ollagen‐binding, T antigen (FCT) genomic region. Here, we describe the functional analysis of the serotype M2 pilus encoded in the FCT‐6 region. We found that, in contrast to other investigated GAS pili, the ancillary pilin 1 lacks adhesive properties. Instead, the backbone pilin is important for host cell adhesion and binds several host factors, including fibronectin and fibrinogen. Using a panel of recombinant pilus proteins, GAS gene deletion mutants and Lactococcus lactis gain‐of‐function mutants we show that, unlike other GAS pili, the FCT‐6 pilus also contributes to immune evasion. This was demonstrated by a delay in blood clotting, increased intracellular survival of the bacteria in macrophages, higher bacterial survival rates in human whole blood and greater virulence in a Galleria mellonella infection model in the presence of fully assembled FCT‐6 pili.     

Complement factor H allotype 402H is associated with increased C3b opsonization and phagocytosis of Streptococcus pyogenes

The main virulence factor of group A streptococcus (GAS), M protein, binds plasma complement regulators factor H (FH) and FH-like protein 1 (FHL-1) leading to decreased opsonization. The M protein binding site on FH is within domain 7 in which also the age-related macular degeneration (AMD)-associated polymorphism Y402H is located. We studied if FH allotypes 402H and 402Y have different binding affinities to GAS. Plasma-derived FH allotype 402H and its recombinant fragment FH5-7(402H) showed decreased binding to several GAS strains. Growth of GAS in human blood taken from FH(402H) homozygous individuals was decreased when compared with blood taken from FH(402Y) homozygous individuals. The effect of the allotype 402H can be explained by combining the previous M protein mutagenesis data and the recently published crystal structure of FH6-8. In conclusion the data indicate that the AMD-associated allotype 402H leads to diminished binding of FH to GAS and increased opsonophagocytosis of the bacteria in blood. These results suggest that the homozygous presence of the allele 402H could be associated with decreased risk for severe GAS infections offering an explanation for the high frequency of the allele despite its association with visual impairment.     

FbaA- and M protein-based multi-epitope vaccine elicits strong protective immune responses against group A streptococcus in mouse model

We report the construction of a recombinant multivalent vaccine against group A streptococcus (GAS), designated F7M5. It contains seven predominant epitopes of FbaA identified by phage display technology, five non-tissue cross-reactive M protein fragments expressed on four selected serotypes prevalent in China, a Trojan antigen (TA) and a poly-alanine DR epitope (PADRE). BALB/c mice were immunized subcutaneously with F7M5 formulated with Freund's adjuvant, using recombinant FbaA and M protein in parallel as control. Using enzyme-linked immunosorbent assay (ELISA), mouse immune sera were assayed for IgG titers, IgG subclasses, and binding of F7M5 with M1GAS. Results indicated that the multivalent vaccine was highly immunogenic and elicited a balanced IgG1/IgG2a response. We also tested the reactivity of F7M5 to antistreptolysin O (ASO) antibodies in sera of GAS-infected patients and found a 95.8% positive rate, indicating that the epitopes of the vaccine were widely expressed in the prevalent serotypes of GAS. More importantly, the F7M5 vaccine elicited strong protective immune responses against lethal-dose challenge with a survival rate of 90%, but induced no cross-reactions or pathological lesions in mouse model, suggesting that F7M5 can be further developed as an effective and safe anti-GAS vaccine.     

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.     

Beta(Leu121-Lys122) segment of fibrinogen is in a region essential for plasminogen binding by fibrin fragment E

It was shown previously that two sequentially nonidentical regions of human fibrin(ogen), present in fragments D and E, carry specific plasminogen-binding sites [V aradi , A., & Patthy , L. (1983) Biochemistry 22, 2440-2446]. Comparison of the affinity of a variety of fragment E species for immobilized Lys-plasminogen revealed that fragment E3e [(alpha 20/24-78, beta 54-122, gamma 1-53)2] possesses a strong plasminogen-binding site, whereas fragment E3t [(alpha 20/24-78, beta 54-120, gamma 1-53)2] has 30-fold lower affinity for the affinant . Since the two fragments differ only in the beta ( Leu121 - Lys122 ) segment, this suggests that residues beta ( Leu121 - Lys122 ), present in the triple-helical connector region of fibrin(ogen), are essential for plasminogen binding by fragment E. Reduction and alkylation of fragment E3e lead to the destruction of the plasminogen-binding site, indicating that none of the separated, alkylated polypeptide chains of the fragment are able to bind to plasminogen and probably the coiled-coil superstructure of the connector region is necessary for the maintenance of the plasminogen-binding site of fragment E.     

Phospholipid-associated annexin A2-S100A10 heterotetramer and its subunits: characterization of the interaction with tissue plasminogen activator,plasminogen, and plasmin

Annexin A2 (p36) is a highly alpha-helical molecule that consists of two opposing sides, a convex side that contains the phospholipid-binding sites and a concave side, which faces the extracellular milieu and contains multiple ligand-binding sites. The amino-terminal region of annexin A2 extends along the concave side of the protein and contains the binding site for the S100A10 (p11) subunit. The interaction of these subunits results in the formation of the heterotetrameric form of the protein, annexin A2-S100A10 heterotetramer (AIIt). To simulate the orientation of AIIt on the plasma membrane we bound AIIt to a phospholipid bilayer that was immobilized on a BIAcore biosensor chip. Surface plasmon resonance was used to observe in real time the molecular interactions between phospholipid-associated AIIt or its annexin A2 subunit and the ligands, tissue-type plasminogen activator (t-PA), plasminogen, and plasmin. AIIt bound t-PA (Kd = 0.68 microm), plasminogen (Kd = 0.11 microm), and plasmin (Kd = 75 nm) with moderate affinity. Contrary to previous reports, the phospholipid-associated annexin A2 subunit failed to bind t-PA or plasminogen but bound plasmin (Kd = 0.78 microm). The S100A10 subunit bound t-PA (Kd = 0.45 microm), plasminogen (Kd = 1.81 microm), and plasmin (Kd = 0.36 microm). Removal of the carboxyl-terminal lysines from the S100A10 subunit attenuated t-PA and plasminogen binding to AIIt. These results show that the carboxyl-terminal lysines of S100A10 form t-PA and plasminogen-binding sites. In contrast, annexin A2 and S100A10 contain distinct binding sites for plasmin.