Facile purification of fibrinogen fragments using a computer-based model with general applicability to the generation of salt gradients

Histidine-rich glycoprotein binds fibrin(ogen) with high affinity and competes with thrombin for binding to the gamma'-chain

Histidine-rich glycoprotein (HRG) is an abundant protein that binds fibrinogen and other plasma proteins in a Zn(2+)-dependent fashion but whose function is unclear. HRG has antimicrobial activity, and its incorporation into fibrin clots facilitates bacterial entrapment and killing and promotes inflammation. Although these findings suggest that HRG contributes to innate immunity and inflammation, little is known about the HRG-fibrin(ogen) interaction. By immunoassay, HRG-fibrinogen complexes were detected in Zn(2+)-supplemented human plasma, a finding consistent with a high affinity interaction. Surface plasmon resonance determinations support this concept and show that in the presence of Zn(2+), HRG binds the predominant γ(A)/γ(A)-fibrinogen and the γ-chain elongated isoform, γ(A)/γ'-fibrinogen, with K(d) values of 9 nm. Likewise, (125)I-labeled HRG binds γ(A)/γ(A)- or γ(A)/γ'-fibrin clots with similar K(d) values when Zn(2+) is present. There are multiple HRG binding sites on fibrin(ogen) because HRG binds immobilized fibrinogen fragment D or E and γ'-peptide, an analog of the COOH terminus of the γ'-chain that mediates the high affinity interaction of thrombin with γ(A)/γ'-fibrin. Thrombin competes with HRG for γ'-peptide binding and displaces (125)I-HRG from γ(A)/γ'-fibrin clots and vice versa. Taken together, these data suggest that (a) HRG circulates in complex with fibrinogen and that the complex persists upon fibrin formation, and (b) by competing with thrombin for γ(A)/γ'-fibrin binding, HRG may modulate coagulation. Therefore, the HRG-fibrin interaction may provide a novel link between coagulation, innate immunity, and inflammation.

Fibrin Fragment Induction of Plasminogen Activator Inhibitor Transcription Is Mediated by Activator Protein-1 Through a Highly Conserved Element

Plasminogen activator inhibitor type-1 (PAI-1), a serine protease inhibitor, affects the processes of fibrinolysis, wound healing, and vascular remodeling. We have demonstrated that PAI-1 transcription is induced by D dimer, a plasmin proteolytic fragment of fibrin, supporting its role in negative feedback on peri-cellular proteolysis. The focus of this study was to define the mechanism of D dimer’s effects on PAI-1 transcription. D dimer increased the binding activity of the transcription factor activator protein-1 components c-fos/junD and c-fos mRNA levels in a time- and concentration-dependent manner to a greater extent than fibrinogen. Both basal and D dimer-induced PAI-1 transcriptional activity were entirely dependent on elements within the −161 to −48 bp region of the PAI-1 gene in fibroblasts. Mutations within the AP-1–like element (−59 to −52 bp) in the PAI-1 gene affected D dimer-induced transcriptional activity, c-fos/junD DNA binding, and basal and c-fos inducible PAI-1 transcriptional activity. Furthermore, expression of either wild-type or mutant c-fos proteins augmented or diminished the response of the PAI-1 promoter (−161 to +26 bp) to D dimer, respectively. D dimer-induced binding of c-fos/junD to the highly conserved and unique AP-1 like element in the PAI-1 gene provides a mechanism whereby specific fibrin fragments control fibrin persistence at sites of inflammation, fibrosis, and neoplasia.

Fibrin Fragment Induction of Plasminogen Activator Inhibitor Transcription Is Mediated by Activator Protein-1 Through a Highly Conserved Element

Plasminogen activator inhibitor type-1 (PAI-1), a serine protease inhibitor, affects the processes of fibrinolysis, wound healing, and vascular remodeling. We have demonstrated that PAI-1 transcription is induced by D dimer, a plasmin proteolytic fragment of fibrin, supporting its role in negative feedback on peri-cellular proteolysis. The focus of this study was to define the mechanism of D dimer’s effects on PAI-1 transcription. D dimer increased the binding activity of the transcription factor activator protein-1 components c-fos/junD and c-fos mRNA levels in a time- and concentration-dependent manner to a greater extent than fibrinogen. Both basal and D dimer-induced PAI-1 transcriptional activity were entirely dependent on elements within the −161 to −48 bp region of the PAI-1 gene in fibroblasts. Mutations within the AP-1–like element (−59 to −52 bp) in the PAI-1 gene affected D dimer-induced transcriptional activity, c-fos/junD DNA binding, and basal and c-fos inducible PAI-1 transcriptional activity. Furthermore, expression of either wild-type or mutant c-fos proteins augmented or diminished the response of the PAI-1 promoter (−161 to +26 bp) to D dimer, respectively. D dimer-induced binding of c-fos/junD to the highly conserved and unique AP-1 like element in the PAI-1 gene provides a mechanism whereby specific fibrin fragments control fibrin persistence at sites of inflammation, fibrosis, and neoplasia.