Cross-linking of plasminogen activator inhibitor 2 and alpha 2-antiplasmin to fibrin(ogen)

In this study, we identified lysine residues in the fibrinogen Aalpha chain that serve as substrates during transglutaminase (TG)-mediated cross-linking of plasminogen activator inhibitor 2 (PAI-2). Comparisons were made with alpha(2)-antiplasmin (alpha(2)-AP), which is known to cross-link to lysine 303 of the Aalpha chain. A 30-residue peptide containing Lys-303 specifically competed with fibrinogen for cross-linking to alpha(2)-AP but not for cross-linking to PAI-2. Further evidence that PAI-2 did not cross-link via Lys-303 was the cross-linking of PAI-2 to I-9 and des-alphaC fibrinogens, which lack 100 and 390 amino acids from the C terminus of the Aalpha chain, respectively. PAI-2 or alpha(2)-AP was cross-linked to fibrinogen and digested with trypsin or endopeptidase Glu-C, and the resulting peptides analyzed by mass spectrometry. Peptides detected were consistent with tissue TG (tTG)-mediated cross-linking of PAI-2 to lysines 148, 176, 183, 457 and factor XIIIa-mediated cross-linking of PAI-2 to lysines 148, 230, and 413 in the Aalpha chain. alpha(2)-AP was cross-linked only to lysine 303. Cross-linking of PAI-2 to fibrinogen did not compete with alpha(2)-AP, and the two proteins utilized different lysines in the Aalpha chain. Therefore, PAI-2 and alpha(2)-AP can cross-link simultaneously to the alpha polymers of a fibrin clot and promote resistance to lysis.     

Cross-linking of alpha 2-plasmin inhibitor to fibrin catalyzed by activated fibrin-stabilizing factor

During blood coagulation alpha 2-plasmin inhibitor (alpha 2PI) is cross-linked with fibrin by an activated fibrin-stabilizing factor (FSFa) plasma transglutaminase, activated coagulation factor XIII). When alpha 2PI was treated with FSFa in the absence of acceptor amino groups, the inhibitor lost more than 90% of its capacity to be cross-linked to fibrin because of hydrolysis of the gamma-carboxamides of FSFa-susceptible glutamine residues. Chemical modifications of the inhibitor's lysine epsilon-amino groups did not affect the cross-linking capacity of the inhibitor with fibrin, whereas the same chemical modifications in fibrinogen resulted in a remarkable loss of cross-linking capacity. These observations suggest that alpha 2PI plays a role as an acyl donor with its FSFa-susceptible glutamine residues in the cross-linking reaction with fibrin, and fibrin serves as an acyl acceptor with its lysine residues. The number of FSFa-susceptible glutamine residues/molecule of the inhibitor was estimated by measuring the maximum incorporation of [3H]histamine into the inhibitor and by analyzing the distribution of radioactivity in a tryptic digest of [14C]histamine-incorporated alpha 2PI.l It was found that each inhibitor molecule has one glutamine residue that is most susceptible to FSFa. When the radioactive histamine-incorporated inhibitor was reacted with excess amounts of plasmin, a small fragment carrying all the released radioactivity was rapidly released from the NH2-terminal part of the inhibitor moiety of the complex. The NH2-terminal amino acid sequence of the inhibitor was analyzed before and after treatment with FSFa or before and after incorporation of radioactive histamine. The glutamine residue at the second position from the NH2-terminal end was converted to a glutamic acid residue when the inhibitor was treated with FSFa. When the radioactive histamine-incorporated inhibitor ws analyzed, the radioactivity was found predominantly at the second position from the NH2-terminal end. These results indicate that the glutamine residue susceptible to FSFa in alpha 2PI is located next to the NH2-terminal residue.     

Reversible cross-linking of alpha 2-plasmin inhibitor to fibrinogen by fibrin-stabilizing factor

alpha 2-Plasmin inhibitor, a primary inhibitor of fibrinolysis, is cross-linked to fibrin by plasma transglutaminase (glutaminyl-peptide:amine gamma-glutamyltransferase, EC 2.3.2.13, activated fibrin-stabilizing factor) when blood coagulation takes place. alpha 2-Plasmin inhibitor was found also to be cross-linked to fibrinogen by plasma transglutaminase. The inhibitor was corss-linked exclusively to the A alpha-chain of fibrinogen, and the cross-linking reaction proceeded very rapidly. The reaction was almost completed before the formation of the gamma-chain dimers of fibrinogen which precedes cross-linking polymerization of the A alpha-chain of fibrinogen. The maximum level of inhibitor cross-linking achieved was approx. 30% of the inhibitor present at the start of the reaction. The level of cross-linking of the inhibitor was not changed when the cross-linking reaction was preceded by dimerization of fibrinogen. The cross-linking reaction was found to be a reversible one, since the cross-linked complex of the inhibitor and fibrinogen was partly dissociated to each of its components when the complex was incubated with plasma transglutaminase. These results suggest that the self-limiting nature of the cross-linking reaction between alpha 2-plasmin inhibitor and fibrin(ogen) is due to the reaction equilibrium favoring dissociation of the complex, and not due to the development of structural hindrance in polymerizing fibrin(ogen).     

The role of gamma A/gamma ' fibrinogen in plasma factor XIII activation

Factor XIII zymogen activation is a complex series of events that involve fibrinogen acting in several different roles. This report focuses on the role of fibrinogen as a cofactor in factor XIII activation by thrombin. We demonstrate that fibrinogen has two distinct activities that lead to an increased rate of factor XIII activation. First, the thrombin proteolytic activity is increased by fibrin. The cleavage rates of both a small chromogenic substrate and the factor XIII activation peptide are increased in the presence of either the major fibrin isoform, gammaA/gammaA fibrin, or a minor variant form, gammaA/gamma' fibrin. This enhancement of thrombin activity by fibrin is independent of fibrin polymerization and requires only cleavage of the fibrinopeptides. Subsequently, gammaA/gamma' fibrinogen accelerates plasma factor XIII activation by a non-proteolytic mechanism. This increased rate of activation results in a slightly more rapid cross-linking of fibrin gammaA and gamma' chains and a significantly more rapid cross-linking of fibrin alpha chain multimers. Together, these results show that although both forms of fibrin increase the rate of activation peptide cleavage by thrombin, gammaA/gamma' fibrinogen also increases the rate of factor XIII activation in a non-proteolytic manner. A revised model of factor XIII activation is presented below.     

Factor XIII binds to the A alpha- and B beta- chains in the D-domain of fibrinogen: an immunoblotting study

The binding sites in fibrinogen for Factor XIII were localized using an immunoblotting technique. Platelet Factor XIII bound to fibrinogen and to plasmin degradation products of fibrin(ogen) including Fragments: X, D1-D3, and D-dimer, but did not bind to Fragment E. Binding of Platelet Factor XIII was independent of calcium ions but could be inhibited by the presence of 0.5 M NaCl. Binding could also be inhibited by preincubating Factor XIII with a 100-fold molar excess of fibrinogen but not by 100-fold molar excess of Fragment E. Binding of Factor XIII to fibrinogen was specific, since several other proteins tested (ovalbumin, bovine serum albumin, alpha 2-macroglobulin, beta-galactosidase, fructose kinase, lactic dehydrogenase, triose phosphate isomerase, fumarase and pyruvate kinase) did not bind Factor XIII. Furthermore, binding was not observed either when Factor XIII was left out or when antiFactor XIII antiserum was substituted with nonimmune serum. When fibrinogen was reduced prior to electrophoresis, Factor XIII bound to the A alpha and B beta chains of fibrinogen and des A,B fibrinogen, the B beta-chain of Fragment X, but not the gamma-chains. Localization of the Factor XIII binding sites to the carboxy terminal segments of the A alpha and B beta chains in the Fragment D-domain of fibrinogen could have important physiological consequences.     

Babesia bovis (argentina): analysis of fibrinogen-like proteins during infection

Fibrinogen and fibrinogen-like proteins (FLP) were isolated from plasma and serum of cattle acutely infected with Babesia bovis. The sizes and chain structures of these proteins were examined and clotting assays performed. The results indicated that the blood was in a hypercoagulable state due mainly to enhanced production of hydrogen bonded fibrin and offset partly by slight inhibition of chain cross-linking. The latter appeared due to a Factor XIII inhibitor. Reduction of A alpha chains of plasma FLP was not evident, nor could lower molecular weight remnants be regularly detected strongly suggesting that fibrin(ogen) lysis rarely occurred. Similarly the size and chain structure of the majority of noncoagulable FLP of serum was consistent with their being the product of coagulation and not fibrinolysis. Only in heavily infected splenectomized cattle were products from lysed cross-linked fibrin detected and these constituted only about 3% of total serum FLP.     

Gly-Pro-Arg-Pro modifies the glutamine residues in the alpha- and gamma-chains of fibrinogen: inhibition of transglutaminase cross-linking

During blood clotting Factor XIIIa, a transglutaminase, catalyzes the formation of covalent bonds between the epsilon-amino group of lysine and the gamma-carboxamide group of peptide-bound glutamine residues between fibrin molecules. We report that glycyl-L-prolyl-L-arginyl-L-proline (GPRP), a tetrapeptide that binds to the fibrin polymerization sites (D-domain) in fibrin(ogen), inhibits transglutaminase cross-linking by modifying the glutamine residues in the alpha- and gamma-chains of fibrinogen. Purified platelet Factor XIIIa, and tissue transglutaminase from adult bovine aortic endothelial cells were used for the cross-linking studies. Gly-Pro (GP) and Gly-Pro-Gly-Gly (GPGG), peptides which do not bind to fibrinogen, had no effect on transglutaminase cross-linking. GPRP inhibited platelet Factor XIIIa-catalyzed cross-linking between the gamma-chains of the following fibrin(ogen) derivatives: fibrin monomers, fibrinogen and polymerized fibrin fibers. GPRP functioned as a reversible, noncompetitive inhibitor of Factor XIIIa-catalyzed incorporation of [3H]putrescine and [14C]methylamine into fibrinogen and Fragment D1. GPRP did not inhibit 125I-Factor XIIIa binding to polymerized fibrin, demonstrating that the Factor XIIIa binding sites on fibrin were not modified. GPRP also had no effect on Factor XIIIa cross-linking of [3H]putrescine to casein. This demonstrates that GPRP specifically modified the glutamine cross-linking sites in fibrinogen, and had no effect on either Factor XIIIa or the lysine residues in fibrinogen. GPRP also inhibited [14C]putrescine incorporation into the alpha- and gamma-chains of fibrinogen without inhibiting beta-chain incorporation, suggesting that the intermolecular cross-linking sites were selectively affected. Furthermore, GPRP inhibited tissue transglutaminase-catalyzed incorporation of [3H]putrescine into both fibrinogen and Fragment D1, without modifying [3H]putrescine incorporation into casein. GPRP also inhibited intermolecular alpha-alpha-chain cross-linking catalyzed by tissue transglutaminase. This demonstrates that the glutamine residues in the alpha-chains involved in intermolecular cross-linking are modified by GPRP. This is the first demonstration that a molecule binding to the fibrin polymerization sites on the D-domain of fibrinogen modifies the glutamine cross-linking sites on the alpha- and gamma-chains of fibrinogen.     

The binding sites on fibrin(ogen) for guinea pig liver transglutaminase are similar to those of blood coagulation factor XIII. Characterization of the binding of liver transglutaminase to fibrin

The present study represents detailed investigations into the nature of interactions between an intracellular "tissue" transglutaminase and a plasma protein, fibrinogen. We demonstrate a specific, saturable, and reversible binding of transglutaminase to fibrin(ogen). The binding was time- and temperature-dependent, was independent of divalent metal ions, did not require the release of either fibrinopeptide A or B, and was partially inhibited by the presence of sodium chloride or plasma proteins, properties similar to Factor XIII binding to fibrin(ogen). Both Factor XIII and liver transglutaminase also shared similar binding sites on fibrinogen, the A alpha- and the B beta-chains. The binding characteristics of liver transglutaminase were thus similar to Factor XIII binding to fibrin, but there were also important differences. Scatchard analyses of the binding data indicated that the affinity of liver transglutaminase (Kd = 4.17 x 10(-7) M) was at least 40-fold weaker compared with the affinity of Factor XIII to fibrinogen. Consequently, a 20-fold molar excess of Factor XIII a-chains specifically and completely inhibited the binding of liver transglutaminase to des-A-fibrinogen. The association between liver transglutaminase and fibrin(ogen) was also critically controlled by the conformational states of the two proteins. Substances capable of altering the conformation of either transglutaminase (such as guanosine 5'-triphosphate) or of fibrinogen (such as the tetrapeptide Gly-Pro-Arg-Pro and Fragment D) disrupted binding. Excess CaCl2 was able to counteract the effects of guanosine 5'-triphosphate on transglutaminase binding to fibrin. In contrast, Factor XIII binding to fibrin was unaffected by either guanosine 5'-triphosphate, CaCl2, or Gly-Pro-Arg-Pro, suggesting a more stable association between the two proteins. The physiologic implications of transglutaminase-fibrin(ogen) interactions are discussed.     

Characterization of the fibrin polymer structure that accelerates thrombin cleavage of plasma factor XIII

The effect of plasmin-derived fibrin(ogen) degradation products on alpha-thrombin cleavage of plasma Factor XIII was studied to identify the fibrin polymer structure that promotes Factor XIIIa formation. Fibrin polymers derived from fibrinogen and Fragment X enhanced the rate of thrombin cleavage of plasma Factor XIII in plasma or buffered solutions. The concentrations of fibrinogen and Fragment X that promoted half-maximal rates of Factor XIIIa formation were 5 and 40 micrograms/ml, respectively. Fragments Y, D, E, D-dimer, and photooxidized fibrinogen did not enhance thrombin cleavage of Factor XIII. Although purified Fragment D1 inhibited fibrin gelation, the soluble protofibrils promoted thrombin activation of Factor XIII. Noncrosslinked fibrin fibers failed to enhance thrombin cleavage of Factor XIII. In conclusion, soluble fibrin oligomers function to promote thrombin cleavage of plasma Factor XIII during blood clotting.     

Probing interactions between the coagulants thrombin, Factor XIII, and fibrin(ogen)

Thrombin cleaves fibrinopeptides A and B from fibrinogen leading to the formation of a fibrin network that is later covalently crosslinked by Factor XIII (FXIII). Thrombin helps activate FXIII by catalyzing hydrolysis of the FXIII activation peptides (AP). In the current work, the role of exosites in the ternary thrombin-FXIII-fibrin(ogen) complex was further explored. Hydrolysis studies indicate that thrombin predominantly utilizes its active site region to bind extended Factor XIII AP (FXIII AP 33-64 and 28-56) leaving the anion-binding exosites for fibrin(ogen) binding. The presence of fibrin-I leads to improvements in the K(m) for hydrolysis of FXIII AP (28-41), whereas peptides based on the cardioprotective FXIII V34L sequence exhibit less reliance on this cofactor. Surface plasmon resonance measurements reveal that d-Phe-Pro-Arg-chloromethylketone-thrombin binds to fibrinogen faster than to FXIII a(2) and dissociates from fibrinogen more slowly than from FXIII a(2). This system of thrombin exosite interactions with differing affinities promotes efficient clot formation.     

Examining thrombin hydrolysis of the factor XIII activation peptide segment leads to a proposal for explaining the cardioprotective effects observed with the factor XIII V34L mutation

In the blood coagulation cascade, thrombin cleaves fibrinopeptides A and B from fibrinogen revealing sites for fibrin polymerization that lead to insoluble clot formation. Factor XIII stabilizes this clot by catalyzing the formation of intermolecular cross-links in the fibrin network. Thrombin activates the Factor XIII a(2) dimer by cleaving the Factor XIII activation peptide segment at the Arg(37)-Gly(38) peptide bond. Using a high performance liquid chromatography assay, the kinetic constants K(m), k(cat), and k(cat)/K(m) were determined for thrombin hydrolysis of fibrinogen Aalpha-(7-20), Factor XIII activation peptide-(28-41), and Factor XIII activation peptide-(28-41) with a Val(34) to Leu substitution. This Val to Leu mutation has been correlated with protection from myocardial infarction. In the absence of fibrin, the Factor XIII activation peptide-(28-41) exhibits a 10-fold lower k(cat)/K(m) value than fibrinogen Aalpha-(7-20). With the Factor XIII V34L mutation, decreases in K(m) and increases in k(cat) produce a 6-fold increase in k(cat)/K(m) relative to the wild-type Factor XIII sequence. A review of the x-ray crystal structures of known substrates and inhibitors of thrombin leads to a hypothesis that the new Leu generates a peptide with more extensive interactions with the surface of thrombin. As a result, the Factor XIII V34L is proposed to be susceptible to wasteful conversion of zymogen to activated enzyme. Premature depletion may provide cardioprotective effects.     

Expression and characterization of pro alpha 2-plasmin inhibitor

alpha s-Plasmin inhibitor (alpha 2PI), one of the serine protease inhibitors in plasma, was expressed in baby hamster kidney (BHK) cell line. The expression vector was constructed with its genomic DNA and cDNA, and was transfected into BHK cells by the calcium phosphate method. The recombinant alpha 2PI which was secreted from the cells was estimated by SDS-PAGE to have a molecular mass of 67 kDa, which is indistinguishable from that of normal plasma alpha 2PI. The leader peptide of 12 amino acids was retained at the amino terminus of the recombinant alpha 2PI. This finding suggests that alpha 2PI has pre-pro type processing and the propeptide of 12 amino acids is not removed in BHK cells. This pro-alpha 2PI shows essentially the same inhibitory activity on plasmin and the same affinity for plasmin(ogen) as those of normal alpha 2PI. However, the cross-linking ability to fibrin is reduced to less than one-third of that of normal alpha 2PI. The cross-linking site is the glutamine residue located at the second position from the amino terminus of normal alpha 2PI. The conformational change of this region caused by the addition of the propeptide may have affected the cross-linking capacity of the inhibitor.     

Identification of respective lysine donor and glutamine acceptor sites involved in factor XIIIa-catalyzed fibrin α chain cross-linking

Factor XIIIa-catalyzed ε-(γ-glutamyl)-lysyl bonds between glutamine and lysine residues on fibrin α and γ chains stabilize the fibrin clot and protect it from mechanical and proteolytic damage. The cross-linking of γ chains is known to involve the reciprocal linkages between Gln(398) and Lys(406). In α chains, however, the respective lysine and glutamine partners remain largely unknown. Traditional biochemical approaches have only identified the possible lysine donor and glutamine acceptor sites but have failed to define the respective relationships between them. Here, a differential mass spectrometry method was implemented to characterize cross-linked α chain peptides originating from native fibrin. Tryptic digests of fibrin that underwent differential cross-linking conditions were analyzed by high resolution Fourier transform mass spectrometry. Differential intensities associated with monoisotopic masses of cross-linked peptides were selected for further characterization. A fit-for-purpose algorithm was developed to assign cross-linked peptide pairs of fibrin α chains to the monoisotopic masses relying on accurate mass measurement as the primary criterion for identification. Equipped with hypothesized sequences, tandem mass spectrometry was then used to confirm the identities of the cross-linked peptides. In addition to the reciprocal cross-links between Gln(398) and Lys(406) on the γ chains of fibrin (the positive control of the study), nine specific cross-links (Gln(223)-Lys(508), Gln(223)-Lys(539), Gln(237)-Lys(418), Gln(237)-Lys(508), Gln(237)-Lys(539), Gln(237)-Lys(556), Gln(366)-Lys(539), Gln(563)-Lys(539), and Gln(563)-Lys(601)) on the α chains of fibrin were newly identified. These findings provide novel structural details with respect to the α chain cross-linking compared with earlier efforts.     

The comparative ability of plasma and tissue transglutaminases to use collagen as a substrate

Heat denatured type I and type III calf skin collagen were found to be substrates for guinea pig liver transglutaminase (R-glutaminyl-peptide:amine gamma-glutamyl-yltransferase, EC 2.3.2.13) but not for active plasma factor XIII (factor XIIIa). Liver transglutaminase was shown to catalyse incorporation of 14C-putrescine into subunits of denatured collagen of both types, cross-linking of the latter into high molecular weight polymers and their co-cross-linking to fibrin and fibrinogen. Factor XIIIa is inactive in these respects. None of these reactions was catalysed by liver transglutaminase and plasma factor XIIIa when nondenatured collagens both soluble or in the forms of reconstituted fibrils served as substrates. Some cross-linking of cleavage products of collagen type I (obtained by treatment with collagenase from human neutrophiles) was induced by liver transglutaminase and factor XIIIa. The results indicate that although appropriate glutamine and lysine residues for a epsilon-(gamma-glutamine) lysine cross-linked formation are present in collagen, the native conformation of collagen prevents the action of liver transglutaminase and factor XIIIa.     

Fibronectin and fibrin gel structure

Plasma fibronectin is covalently incorporated into alpha-chains of fibrin gels in the presence of Factor XIII activated by thrombin (FXIIIaT) but not by Factor XIII activated by the snake venom enzyme batroxobin (FXIIIaB). FXIIIaB catalyzes introduction of gamma-gamma cross-links in fibrin but cross-linked alpha-chains are not formed. In the presence of FXIIIaT, fibrin gels formed by batroxobin incorporated fibronectin and the alpha-chains are cross-linked indicating that FXIIIaB has a different substrate specificity from FXIIIaT. In the presence of FXIIIaT the incorporation of fibronectin approaches 1 mol/340 kDa unit weight of fibrin. Fibronectin when present in a fibrinogen thrombin mixture containing FXIII does not influence the clotting time of the system nor the release of fibrinopeptides. Incorporation of fibronectin is not appreciable before the gel point. This indicates that the polymerization and gelation of fibrinogen is essentially not perturbed by the presence of fibronectin and that fibrin in the gel matrix rather than the fibrin polymers formed prior to gel point is the preferred structure for fibronectin incorporation. Incorporation of fibronectin into fibrin gels during formation leads to an increase in turbidity and a small decrease in Ks (permeability coefficient). This suggests that the width of the strands in the gel increases as a result of fibronectin incorporation. Fibronectin is also incorporated into preformed gels having completely cross-linked gamma- and alpha-chains perhaps indicating that the sites in fibrin involved in fibronectin incorporation are different from those involved in fibrin cross-linking. FXIIIaT appeared to be adsorbed to fibrin gel matrix in the presence but not in the absence of calcium ions.     

Cross-Linking of Fibronectin to C-Terminal Fragments of the Fibrinogen α-Chain by Factor XIIIa

Fibronectin binds specifically to fibrin and is covalently cross-linked to the fibrin α chain by activated factor XIII (XIIIa). This reaction is important for wound healing. Here we investigate XIIIa-catalyzed cross-linking of fibronectin and some of its fragments to a recombinant fragment representing the COOH-terminal 30kDa of the fibrin α chain (αC30K:His 368–Val 610). Only fibronectin and those fragments containing an intact NH₂-terminus were able to form cross-linked complexes. As many as 10 of the 17 lysines in αC30K can serve as amine donors in this reaction. Analysis of the rate of XIIIa-catalyzed cross-linking of fibronectin NH₂-terminal peptides and fragments with αC30K revealed that the presence of the first type I “finger” module accelerates the cross-linking reaction; addition of fingers 2–5 had no further effect.     

Isolation of a fibrin-binding fragment from blood coagulation factor XIII capable of cross-linking fibrin(ogen).

Purified platelet Factor XIII was radioiodinated and then partially degraded by thrombin or trypsin, and a fibrin-binding fragment was identified by autoradiography and immunoblotting following separation by SDS/polyacrylamide-gel electrophoresis. Limited proteolysis of 125I-Factor XIII by thrombin or trypsin produced an 125I-51 kDa fragment and an unlabelled 19 kDa fragment. The 51 kDa fragment was purified by h.p.l.c. on a TSK-125 gel-filtration column. Partial amino acid sequence analysis of the 51 kDa fragment indicated that it was similar in sequence to the Gly38-Lys513 segment in placental Factor XIII a-chain. More than 70% of the 51 kDa fragment bound to fibrin, whereas the 19 kDa fragment did not bind. The active site was localized to the 51 kDa fragment since this fragment expressed transglutaminase activity, cross-linked fibrin and fibrinogen and incorporated iodo[14C]acetamide into the active-site cysteine residue. Isolation of a fibrin-binding fragment expressing transglutaminase activity demonstrates that each a-chain of the dimeric Factor XIIIa could function independently to cross-link fibrin. The fibrin-binding site could play an important role in localizing Factor XIIIa to the fibrin clot.     

Roles of low specificity and cofactor interaction sites on thrombin during factor XIII activation. Competition for cofactor sites on thrombin determines its fate

Factor XIII is activated by thrombin, and this reaction is enhanced by the presence of fibrin(ogen). Using a substrate-based screening assay for factor XIII activity complemented by kinetic analysis of activation peptide cleavage, we show by using thrombin mutants of surface-exposed residues that Arg-178, Arg-180, Asp-183, Glu-229, Arg-233, and Trp-50 of thrombin are necessary for direct activation of factor XIII. These residues define a low specificity site known to be important also for both protein C activation and for inhibition of thrombin by antithrombin. The enhancing effect of fibrinogen occurs as a consequence of its conversion to fibrin and subsequent polymerization. Surface residues of thrombin further involved in high specificity fibrin-enhanced factor XIII activation were identified as His-66, Tyr-71, and Asn-74. These residues represent a distinct interaction site on thrombin (within exosite I) also employed by thrombomodulin in its cofactor-enhanced activation of protein C. In competition experiments, thrombomodulin inhibited fibrin-enhanced factor XIII activation. Based upon these and prior published results, we propose that the polymerization process forms a fibrin cofactor that acts to approximate thrombin and factor XIII bound to separate and complementary domains of fibrinogen. This enables enhanced factor XIII activation to be localized around the fibrin clot. We also conclude that proximity to and competition for cofactor interaction sites primarily directs the fate of thrombin.     

Fibrin(ogen)-alpha M beta 2 interactions regulate leukocyte function and innate immunity in vivo

In addition to its well-characterized role in hemostasis, fibrin(ogen) has been proposed to be a central regulator of the inflammatory response. Multiple in vitro studies have demonstrated that this hemostatic factor can alter leukocyte function, including cell adhesion, migration, cytokine and chemokine expression, degranulation, and other specialized processes. One important link between fibrin(ogen) and leukocyte biology appears to be the integrin receptor alpha(M)beta(2)/Mac-1, which binds to immobilized fibrin(ogen) and regulates leukocyte activities. Although it is well established that fibrin(ogen) is a ligand for alpha(M)beta(2), the precise molecular determinants that govern this interaction are only now becoming clear. A novel line of mice expressing a mutant form of fibrinogen (Fib gamma(390-396A)) has revealed that gamma chain residues 390-396 are important for the high-affinity engagement of fibrinogen by alpha(M)beta(2) and leukocyte function in vivo. Fibrinogen gamma(390-396A) failed to support alpha(M)beta(2)-mediated adhesion of primary neutrophils, monocytes, and macrophages, and mice expressing this fibrinogen variant were found to exhibit a major defect in the host inflammatory response following acute challenges. Most notably, Fib gamma(390-396A) mice display a profound impediment in Staphylococcus aureus elimination by leukocytes following intraperitoneal inoculation. These findings have positively established the physiological importance of fibrin(ogen) as a ligand for alpha(M)beta(2) and illustrate that the fibrin(ogen) gamma chain residues 390-396 constitute a critical feature of the alpha(M)beta(2) binding motif. Finally, the Fib gamma(390-396A) mice represent a valuable system for better defining the contribution of fibrin(ogen) to the inflammatory response in the absence of any confounding alteration in clotting function.     

Factor XIII-mediated cross-linking of NH2-terminal peptide of alpha 2-plasmin inhibitor to fibrin

The NH2-terminal 12-residue peptide of alpha 2-plasmin inhibitor, Asn-Gln-Glu-Gln-Val-Ser-Pro-Leu-Thr-Gly-Leu-Lys-NH2 . AcOH, was found to be a good substrate for plasma transglutaminase (activated blood coagulation factor XIII) and rapidly incorporated into fibrin by the enzyme. A high concentration of the peptide inhibited the enzyme-mediated cross-linking of alpha 2-plasmin inhibitor to fibrin probably by competing with the inhibitor for the same site of fibrin alpha-chain.