Identification of Factor XIIIa-Reactive Glutamine Acceptor and Lysine Donor Sites within Fibronectin-Binding Protein (FnbA) from Staphylococcus aureus

von Willebrand factor-binding protein (vWbp)-activated factor XIII and transglutaminase 2 (TG2) promote cross-linking between FnBPA from Staphylococcus aureus and fibrinogen

The secreted von Willebrand factor-binding protein (vWbp) from Staphylococcus aureus interacts with the coagulation factors prothrombin and fibrinogen (Fbg), leading to the non-proteolytic transglutaminase activation of Factor XIII (FXIII). In this study we found that vWbp-activated FXIII catalyses the incorporation of amino-donor dansylcadaverine into region A of fibronectin-binding protein A (FnBPA). Incubation of Fbg with recombinant region A of S. aureus Fbg-binding proteins FnBPA, FnBPB, ClfA or ClfB in presence of vWbp-activated FXIII resulted in the formation of high molecular heteropolymers with FnBPA only, suggesting a specificity of the cross-linking reaction between fibrin(ogen) and the staphylococcal surface. As previously observed, cross-linking sites were mapped to the α-chain and the N1 subdomain of fibrin(ogen) and region A of FnBPA, respectively. Comparable results were obtained when tissue tranglutaminase-2 (TG2) was tested for cross-linking of FnBPA and Fbg. Of note, FnBPA-mediated covalent cross-linking promoted by vWbp-activated FXIII was also observed when bacteria were allowed to attach to fibrin(ogen). Together these findings suggest a novel pathogenetic mechanism by which the transglutaminase action of FXIII and/or TG2 contributes to entrapment and persistence of S. aureus in blood and host tissues.

Indwelling catheters and medical implants with FXIIIa inhibitors: A novel approach to the treatment of catheter and medical device-related infections

Central venous catheters (CVCs) are being utilized with increasing frequency in intensive care and general medical wards. In spite of the extensive experience gained in their application, CVCs are related to the long-term risks of catheter sheath formation, infection, and thrombosis (of the catheter or vessel itself) during catheterization. Such CVC-related-complications are associated with increased morbidity, mortality, duration of hospitalization, and medical care cost [1]. The present study incorporates a novel group of Factor XIIIa (FXIIIa, plasma transglutaminase) inhibitors into a lubricious silicone elastomer in order to generate an optimized drug delivery system whereby a secondary sustained drug release profile occurs following an initial burst release for catheters and other medical devices. We propose that the incorporation of FXIIIa inhibitors into catheters, stents, and other medical implant devices would reduce the incidence of catheter sheath formation, thrombotic occlusion, and associated staphylococcal infection. This technique could be used as a local delivery system for extended release with an immediate onset of action for other poorly aqueous soluble compounds.

Molecular mechanism of the interaction between activated factor XIII and its glutamine donor peptide substrate

BACKGROUND

Activated factor XIII (FXIII), a dimer of truncated A-subunits (FXIII-A2*), is a transglutaminase that crosslinks primary amines to peptide-bound glutamine residues. Because in the few natural substrates of FXIII-A2* no consensus sequence could be identified around the reactive glutamine, studying the interaction between individual substrates and FXIII-A2* is of primary importance. Most of the alpha2-plasmin inhibitor (alpha2PI) molecules become truncated by a plasma protease, and the truncated isoform (N1-alpha2PI) is an important substrate of FXIII-A2*. The crosslinking of N1-alpha2PI to fibrin plays a major role in protecting fibrin from fibrinolysis.

METHODS

We studied the interaction of FXIII-A2* with its dodecapeptide glutamine donor substrate, N1-alpha2PI(1-12), the sequence of which corresponds to the N-terminal sequence of N1-alpha2PI. Kinetic parameters for N1-alpha2PI(1-12) and for its truncated or synthetic mutants were determined by a spectrophotometric assay. The interaction of N1-alpha2PI(1-12) with FXIII-A2* was investigated by proton nuclear magnetic resonance (NMR) and saturating transfer difference (STD) NMR.

RESULTS AND CONCLUSIONS

Kinetic experiments with peptides in which the Asn1 residue was either truncated or replaced by alanine and proton NMR analysis of the FXIII-A2*-N1-alpha2PI(1-12) complex demonstrated that Asn1 is essential for effective enzyme-substrate interaction. Experiments with C-terminally truncated peptides proved that amino acids 7-12 are essential for the interaction of N1-alpha2PI(1-12) with the enzyme, and suggested the existence of a secondary binding site on FXIII-A2*. Hydrophobic residues, particularly Leu10 and the C-terminal Lys12, seemed to be especially important in this respect, and direct interaction between hydrophobic C-terminal residues and FXIII-A2* was demonstrated by STD NMR.