Surface properties of fibrinogen and fibrin

By contact angle measurements on layers of fibrinogen and fibrin, it can be shown that the transformation from fibrinogen to fibrin is accompanied by a change in surface properties from very hydrophilic (fibrinogen) to moderately but definitely hydrophobic (fibrin). It is also shown that, contrary to serum albumin and gamma globulin, fibrinogen does not become more hydrophobic upon drying.     

纤维蛋白单体D区与E区聚合后E区结构的变化

应用纤维蛋白单克隆抗体IF 5 3,观察当纤维蛋白的“A”位点与另一纤维蛋白D区域的“a”位点结合后纤维蛋白E区的变化 .纤维蛋白原Aα链经赖氨酰肽链内切酶消化后 ,应用反相HPLC分离纯化 ;通过ELISA法检测单克隆抗体IF 5 3与纤维蛋白原及其衍生物的反应情况 ;应用放射免疫法检测RGD合成肽抑制纤维蛋白单体与IF 5 3反应的情况 .发现IF 5 3能与纤维蛋白原Aα链的一个片段反应 ,该片段经氨基酸序列分析显示为纤维蛋白原Aα链氨基末端 (1～ 2 9) .该抗体能与酸溶解的纤维蛋白单体和可溶性纤维蛋白及XDP反应 ,但不能与酸化纤维蛋白原或GPRP反应 ,因此IF 5 3的抗原决定簇在Aα 2 0～ 2 9,与凝血酶作用于纤维蛋白肽A ,暴露出的聚合位点“A”(Aα17～19)紧邻 .当GPRP存在于纤维蛋白原溶液时 ,经凝血酶作用产生这种纤维蛋白单体不能与IF 5 3反应 .Aα(93～ 99) (ILRGDFS)合成肽部分抑制纤维蛋白单体与IF 5 3的反应 .实验结果提示 ,当纤维蛋白单体相互聚合 ,或纤维蛋白单体与纤维蛋白原聚合时 ,纤维蛋白单体结构会发生变化 ,其中Aα2 0～ 2 9片段成为新抗原暴露于E区表面 ,并且Aα2 0～ 2 9与纤维蛋白原细胞粘附区域RGD1片段邻近     

Exogenous fibrin matrix precursors stimulate the temporal progress of nerve regeneration within a silicone chamber

The silicone chamber model permits the investigation of the cellular and molecular events underlying successful regeneration of the rat sciatic nerve across a 10 mm gap. When 25 l chambers are implanted prefilled with phosphate-buffered saline (PBS), it takes 5–7 days before sufficient fibrin matrix (derived from plasma precursors) accumulates naturally to form a complete bridge across the chamber gap; at 1 week postimplantation, cellular migration into the matrix from the nerve stumps is just beginning. The temporal progress of regeneration might be stimulated if a fibrin matrix, conductive to cell migration, was provided to the nerve stumps at or shortly after the time of chamber implantation. To test this hypothesis, chambers were prefilled, at the time of implantation, with different preparations of homologous plasma. A solution of 90% platelet-free plasma dialyzed against PBS (DP) formed a fibrin matrix by 24 hours postimplantation that, like the naturally formed matrix, had a predominantly longitudinal orientation. The temporal progress of regeneration was stimulated in the DP-prefilled chambers; at 17 days postimplantation, the extents of Schwann cell migration and axonal elongation were significantly greater than in the control system. In contrast, prefilling chambers with either non-citrated plasma or DP + calcium resulted in the generation of a matrix within 8 minutes that was composed of randomly oriented fibrin polymers. These matrices significantly retarded the progress of regeneration.Special Issue dedicated to Dr. E. M. Shooter and Dr. S. Varon.     

Magnetic alignment of collagen during self-assembly

Magnetically induced birefringence is used to monitor the thermally induced self-assembly of collagen fibrils from a solution of molecules. The magnetic torque alone can, at best, only orient the fibrils into planes normal to the field direction. Nevertheless, the gels formed have a high degree of uniaxial alignment, probably due to the additional ordering effects of surface interactions. Thus magnetic orientation is potentially useful in the study of fibrillogenesis and in the production of highly oriented collagen gels.     

Self-assembly of fibrin monomers and fibrinogen aggregation during ozone oxidation

The mechanism of self-assembly of fibrin monomers and fibrinogen aggregation during ozone oxidation has been studied by the methods of elastic and dynamic light-scattering and viscosimetry. Fibrin obtained from oxidized fibrinogen exhibits higher average fiber mass/length ratio compared with native fibrin. Fibrinogen ozonation sharply reduced the latent period preceding aggregation of protein molecules; however, the mechanism of self-assembly of ozonated and non-ozonated fibrinogen cluster was identical. In both cases flexible polymers are formed and reaching a certain critical length they form densely packed structures and aggregate. Using infrared spectroscopy, it has been shown that free radical oxidation of amino acid residues of fibrinogen polypeptide chains catalyzed by ozone results in formation of carbonyl, hydroxyl, and ether groups. It is concluded that fibrinogen peripheral D-domains are the most sensitive to ozonation, which causes local conformational changes in them. On one hand, these changes inhibit the reaction of longitudinal polymerization of monomeric fibrin molecules; on the other hand, they expose reaction centers responsible for self-assembly of fibrinogen clusters.     

Effect of methylmercuric chloride (MMC) on fibrin polymerization

Methylmercuric chloride (MMC) in concentrations 0.1–10μM reduces the amount of fibrinopeptides released from thrombinactivated human fibrinogen. However, the fibrin clot formation is not discriminated and the turbidity of the fibrin gel is even augmented. MMC does not cause such changes in the process of repolymerization of fibrin monomers. The addition of fibrinopeptides to the fibrin monomers results in a similar increase of turbidity of the repolymerizing sample in the presence of MMC as in the case of fibrinogen clotting. These experiments indicate that MMC modifies the structure of fibrin in the presence of fibrinopeptides.     

Lack of effect of thrombin on fibrin(ogen)-endothelial cell interaction

In the present study we investigate the fibrin(ogen)-endothelial cell binding and the effect of thrombin on the endothelial cells in relation to fibrin(ogen) binding capacity. Endothelial cell fibrinogen binding was concentration and time-dependent, reaching saturation at 1.4 M of added ligand. At equilibrium, the number of fibrinogen molecules bound per endothelial cell in the monolayer was 5.8±0.7×10⁶. When endothelial cells were activated by different concentrations of thrombin (0–0.1 NIH units ml^–1), no increase in fibrinogen binding capacity was observed at all the thrombin concentration tested. Whereas disruption of endothelial cell monolayers was observed at thrombin concentrations higher than 0.05 NIH units ml^–1, no increase in the amount of fibrinogen bound was observed. Therefore, resting and thrombin-activated endothelial cells show the same fibrinogen binding capacity.The adhesion of endothelial cells in suspension on immobilized fibrinogen or fibrin was studied to ascertain whether the behavior of fibrin is similar to that of fibrinogen. The extent of endothelial cell attachment to immobilized fibrinogen and fibrin was similar (4275±130 cells cm^–2 for fibrinogen and 4350±235 cells cm^–2 for fibrin) and represent approximately 40% of the added endothelial cells. However, endothelial cell adhesion to immobilized fibrin was significantly faster than endothelial cell adhesion to immobilized fibrinogen. The maximum binding rate was 66±9 and 46±8 cells cm^–2 min^–1 for fibrin and fibrinogen, respectively. Therefore, the fibrinopeptides released by thrombin from fibrinogen induce qualitative changes which enhance the fibrin interaction with the endothelial cells.     

Growth characteristics of skin fibroblasts and 3T3 cells entrapped by polymerizing fibrin

Summary Skin fibroblasts as well as 3T3 cells were cultured after entrapping freshly prepared cells in medium containing polymerizing fibrin. In contrast to cells grown on plastic substratum, fibrin-clot-cultured cells became highly elongated forming strands of cells. The strands interconnected by lateral cellular protrusions so that horizontal networks of cells were present throughout the clots. Cell growth as well as stretching were dependent upon the concentrations of fibrin. Highest growth rates were obtained with low fibrin concentrations (0.3 mg fibrinogen per ml). As shown by deprivation experiments nutritional limitations appear to be responsible for differences in growth rates observed in fibrin clots of higher density. In this system the fibrin meshwork serves as substratum for adhesion, elongation and multiplication of fibroblasts. The method makes it possible to study single cells in culture and the effects of persistent microenivronmental influences. This work was supported by Deutsche Forschungsgemeinschaft.     

Interaction of fibrinogen with two forms of fibrin differing in the degree of activation by thrombin

The inhibitory effect of fibrinogen in the clotting of two fibrin monomer species--f-desAA and f-desAABB--was studied. The concentration dependence of this effect for two fibrin forms was found to be of the same character. This fact indicates that the modifying influence of fibrinogen proposed earlier in relation to f-desAABB also takes place in the case of f-desAA. However, an equal inhibitory effect is achieved for f-desAA at much higher fibrinogen concentrations than that for f-desAABB. The inhibitory effect of fibrinogen is greater at higher ionic strengths for both fibrin forms, but in the case of f-desAA this effect is more pronounced. The role of fibrin polymerization sites formed after fibrinopeptides B removal in initial fibrin polymerization and in F-f-desAABB interaction is discussed.     

Experimental tests of a geometrical abstraction of fibrin polymerization

By combining measurements of the enzymatic release of fibrinopeptide A (FPA) with measurements of intensity and linewidth of Rayleigh scattering from fibrin polymer solutions prior to gelation, we have systematically tested a variety of predictions that can be made on the basis of a simple geometrical abstraction of fibrin polymerization. The experimental investigations include FPA content of fibrin polymers, aggregation of fibrin with fibrinogen, enzyme kinetics, shift of the chemical equilibrium by adding Gly-Pro-Arg-Pro or fibrinogen to the polymer solution, evolution of the polymerization, and influence of fibrinopeptide B release. Among the considered geometrical abstractions there is only one that survives the experimental tests and at the same time is compatible with the electron micrographs by other authors. The main conclusions that can be drawn are (1) the location of binding sites A must be taken from the structure of the fibrinogen molecule proposed by Hoeprich and Doolittle [Biochemistry (1983) 22 , 2049–2055], (2) The fibrinogen monomer is basically centrosymmetric, (3) the state of polymerization is reversible and corresponds to a chemical equilibrium, and (4) Michaelis–Menten enzyme kinetics can be applied.     

Immunoenzymehistochemical detection of fibrin microthrombi during disseminated intravascular coagulation in rats

Summary In tissue of rats with disseminated intravascular coagulation, fibrin microthrombi can be sensitively detected by immunohistochemical methods, using antisera against rat fibrinogen or fibrin monomer. An indirect immunoperoxidase procedure on paraplast-embedded sections yields best results with regard to the morphology of the thrombi and their localization in the tissue.Only fibrillar immunoreactive material, oriented lengthwise in the vessels, should be regarded as microthrombi formed in vivo.     

Fibrin membrane endowed with biological function. IV. Formation of cross-links between fibrinogen (or fibrin) and ribonuclease by transglutaminase.

Transglutaminase from guinea pig liver catalyzed the formation of cross-links between fibrinogen (or fibrin) and ribonuclease. Using transglutaminase, immoblized ribonuclease was prepared by two separate methods: (1) fibrinogen-ribonuclease conjugates formed by transglutaminase were treated with thrombin to make fibrin membrane bound covalently to the enzyme; (2) fibrin polymer formed from fibrinogen with thrombin was covalently bound to ribonuclease by transglutaminase to make fibrin-ribonuclease conjugates.     

可溶性血纤蛋白促进细胞伸展及其作用机制

可溶性血纤蛋白（ｓｏｌｕｂｌｅｆｉｂｒｉｎ,ＳＦ）为血纤蛋白单体和血纤蛋白原１∶２的复合物．现已知在血液凝固系统被激活的病理状态下,存在于循环血液中,然而它的生理作用仍然不明．首次发现细胞能在固定的ＳＦ上伸展,并能被外源性ＳＦ及精氨酸－甘氨酸－天冬氨酸（ＲＧＤ）合成肽所抑制,但不能被血纤蛋白原和血纤蛋白单体所抑制,提示ＳＦ形成后其结构变化是引起细胞伸展的关键．片段Ｘ（缺乏ＲＧＤ２序列的血纤蛋白原片段）与血纤蛋白单体形成的复合物,使细胞伸展活性明显减低,提示在ＳＦ结构中,血纤蛋白原的ＲＧＤ２序列在细胞伸展中起重要作用．同时发现ＤＩＣ患者血浆中的ＳＦ也具有细胞伸展活性．ＳＦ作为一个粘附分子在体内血栓形成过程中起重要调节作用     

Aggregation of fibrinogen molecules in a solution

Fibrinogen is found to be able to produce highly molecular aggregates in solution. Its maximal quantity aggregates at the temperature of 4 degrees C. The pH dependence of fibrinogen aggregates production is shown. Highly molecular aggregates of fibrinogen are found to be produced mainly due to hydrogen bonds. Electron-microphotography of aggregated fibrinogen is presented. Complementary molecular loci responsible for the formation of ordered aggregates are discussed from the standpoint of their significance in the fibrin polymerization.     

Molecular mechanisms of the polymerization of fibrin and the formation of its three-dimensional network

The results of biochemical, immunochemical, and X-ray studies of the structures of fibrinogen and fibrin molecules were analyzed. The mechanisms of the successive formation of the fibrin three-dimensional network were described: the polymerization of monomeric molecules with the formation of bifilar protofibrils, the lateral association of protofibrils, and the embranchment of the forming fibrils. Data on the electron and confocal microscopy of the polymeric fibrin were considered. The role of the known polymerization centers of fibrin which participated in the formation of protofibrils and their lateral association was discussed. Data on the existence of the previously unknown polymerization centers were given. In particular, the experimental results demonstrated that one of such centers which participated in the formation of protofibrils was located in the Bβ12–46 fragment, and did not require the cleavage of fibrinopeptide B for its functioning. The results of the computer modeling of the spatial structure of the fibrin(ogen) molecule and the intermolecular interactions in the course of the fibrin polymerization were presented. The location of the αC domains in the fibrin(ogen) molecule and their role in the polymerization process were discussed. Information on the structure of the calciumbinding sites of fibrin(ogen) and the functional role of Ca²⁺ in fibrin polymerization was published. The structure of factor XIII(a) and the mechanisms of fibrin stabilization by this factor were briefly described.     

Fibrin‐targeted plasminogen activation by plasminogen activator,PadA, from Streptococcus dysgalactiae

Bacterial plasminogen activators differ from each other in their mechanism of plasminogen activation besides their host specificity. Three‐domain streptokinase (SK) and two‐domain PauA generate nonproteolytic active site center in their cognate partner plasminogen but their binary activator complexes are resistant to α2‐antiplasmin (a2AP) inhibition causing nonspecific plasminogen activation in plasma. In contrast, single‐domain plasminogen activator, staphylokinase (SAK), requires proteolytic cleavage of human plasminogen into plasmin for the active site generation, and this activator complex is inhibited by a2AP. The single‐domain plasminogen activator, PadA, from Streptococcus dysgalatiae, having close sequence and possible structure homology with SAK, was recently reported to activate bovine Pg in a nonproteolytic manner similar to SK. We report hereby that the binary activator complex of PadA with bovine plasminogen is inhibited by a2AP and PadA is recycled from this complex to catalyze the activation of plasminogen in the clot environment, where it is completely protected from a2AP inhibition. Catalytic efficiency of the activator complex formed by PadA and bovine plasminogen is amplified several folds in the presence of cyanogen bromide digested fibrinogen but not by intact fibrinogen indicating that PadA may be highly efficient at the fibrin surface. The present study, thus, demonstrates that PadA is a unique single‐domain plasminogen activator that activates bovine plasminogen in a fibrin‐targeted manner like SAK. The sequence optimization by PadA for acquiring the characteristics of both SK and SAK may be exploited for the development of efficient and fibrin‐specific plasminogen activators for thrombolytic therapy.     

Fibrin protofibril and fibrinogen binding to ADP-stimulated platelets: evidence for a common mechanism

The molecular basis of platelet-fibrin binding has been elucidated by studying interactions between platelets and protofibrils, soluble two-stranded polymers of fibrin which are intermediates on the fibrin assembly pathway. The fibrinogen degradation product, fragment D, has been used to block fibrin assembly, thus enabling the preparation of stable solutions of short protofibrils, composed of fewer than twenty fibrin monomer molecules per polymer. Fibrin protofibrils bound to ADP-activated platelets in a time- and concentration-dependent process which was effectively blocked by excess unlabelled fibrinogen, i.e., the binding was specific and appeared to involve a common receptor. ADP-stimulated cells bound approx. 3 micrograms of fibrin protofibrils/10(8) platelets, compared to 4 micrograms of fibrinogen/10(8) cells, following a 30-min incubation period at room temperature. Binding of both ligands was inhibited by high concentrations of fragment D, further indicating a similar mechanism. The kinetic data obtained were well described by an apparent first-order mechanism in which the rate constant for fibrin protofibril binding was found to be 5-fold slower than that measured for fibrinogen. Two monoclonal antibodies, each directed against the platelet glycoprotein IIb-IIIa complex, inhibited the binding of fibrin protofibrils and fibrinogen in a similar, concentration-dependent manner, providing strong evidence for a common receptor. Binding of GPRP-fibrin (soluble fibrin oligomers formed in the presence of 1 mM Gly-Pro-Arg-Pro) to ADP-stimulated platelets was also inhibited by a monoclonal antibody directed against the GPIIb-IIIa complex. Neither fibrin protofibrils nor fibrinogen bound to Glanzmann's thrombasthenic platelets, which lack normal quantities of functional glycoprotein IIb-IIIa complex, further supporting the hypothesis that fibrinogen and fibrin bind to a common platelet receptor present on the glycoprotein IIb-IIIa complex.     

The Platelet Integrin αIIbβ3 Differentially Interacts with Fibrin Versus Fibrinogen

Fibrinogen binding to the integrin αIIbβ3 mediates platelet aggregation and spreading on fibrinogen-coated surfaces. However, in vivo αIIbβ3 activation and fibrinogen conversion to fibrin occur simultaneously, although the relative contributions of fibrinogen versus fibrin to αIIbβ3-mediated platelet functions are unknown. Here, we compared the interaction of αIIbβ3 with fibrin and fibrinogen to explore their differential effects. A microscopic bead coated with fibrinogen or monomeric fibrin produced by treating the immobilized fibrinogen with thrombin was captured by a laser beam and repeatedly brought into contact with surface-attached purified αIIbβ3. When αIIbβ3-ligand complexes were detected, the rupture forces were measured and displayed as force histograms. Monomeric fibrin displayed a higher probability of interacting with αIIbβ3 and a greater binding strength. αIIbβ3-fibrin interactions were also less sensitive to inhibition by abciximab and eptifibatide. Both fibrinogen- and fibrin-αIIbβ3 interactions were partially inhibited by RGD peptides, suggesting the existence of common RGD-containing binding motifs. This assumption was supported using the fibrin variants αD97E or αD574E with mutated RGD motifs. Fibrin made from a fibrinogen γ′/γ′ variant lacking the γC αIIbβ3-binding motif was more reactive with αIIbβ3 than the parent fibrinogen. These results demonstrate that fibrin is more reactive with αIIbβ3 than fibrinogen. Fibrin is also less sensitive to αIIbβ3 inhibitors, suggesting that fibrin and fibrinogen have distinct binding requirements. In particular, the maintenance of αIIbβ3 binding activity in the absence of the γC-dodecapeptide and the α-chain RGD sequences suggests that the αIIbβ3-binding sites in fibrin are not confined to its known γ-chain and RGD motifs.     

Native fibrin gel networks observed by 3D microscopy, permeation and turbidity

Native fully hydrated fibrin gels formed at different fibrinogen and thrombin concentrations and at different ionic strengths were studied by confocal laser 3D microscopy, liquid permeation and turbidity. The gels were found to be composed of straight rod-like fiber elements that often came together at denser nodes. In gels formed at high fibrinogen concentrations, or with high amounts of thrombin, the spaces between the fibers decreased, indicating a decrease of gel porosity. The fiber strands were also shorter. Gel porosity decreased dramatically in gels formed at the high ionic strengths. Shorter fibers were observed and fiber swelling occurred at ionic strengths above 0.24. Quantitative parameters for gel porosity, fiber mass/length ratio and diameter were also derived by liquid permeation and turbidometric analyses of the gels. Permeation analysis showed that gel porosity (measured as Ks) decreased in gels formed at higher fibrin and thrombin concentrations in agreement with the porosity observed by microscopy. The turbidometric analysis showed good agreement with the permeation data for gels formed at various thrombin concentrations, but supported the permeation data more poorly in gels formed at different fibrinogen concentrations, especially above 2.5 mg/ml. Turbidometric analysis showed that the fiber mass/length ratio and diameter decreased in gels formed at ionic strength up to 0.24, as was seen in the permeation study. However, at higher ionic strengths swelling of the fibers was suggested from the gel turbidity data and this was also indicated by microscopy. These findings are discussed in relation to previous hydrodynamic and electron microscopic studies of fibrin gels.     

Rheological characterization and dissolution kinetics of fibrin gels crosslinked by a microbial transglutaminase

Various fibrin gels were prepared with a microbial transglutaminase under miscellaneous conditions. The gels were characterized through their rheological properties. The influence of fibronectin addition and that of covalent bonding on the viscoelastic characteristics were evaluated. Gel elasticity is proportional to fibrinogen concentration but shows a nonlinear dependence on transglutaminase concentration. Additional crosslink of fibronectin in fibrin gels has no effect on the rheological character of the matrix. Dissolution kinetics in concentrated urea solutions evidences the role of covalent bonds on gel stability. The rheological properties and gel stability are discussed in relation with the enzyme-catalyzed covalent bonding. The microbial enzyme reactions are compared to those of FXIII and tissue transglutaminases.