Studies on the basis for the properties of fibrin produced from fibrinogen-containing gamma' chains

Human fibrinogen 1 is homodimeric with respect to its gamma chains (gammaA-gammaA'), whereas fibrinogen 2 molecules each contain one gammaA (gammaA1-411V) and one gamma' chain, which differ by containing a unique C-terminal sequence from gamma'408 to 427L that binds thrombin and factor XIII. We investigated the structural and functional features of these fibrins and made several observations. First, thrombin-treated fibrinogen 2 produced finer, more branched clot networks than did fibrin 1. These known differences in network structure were attributable to delayed release of fibrinopeptide (FP) A from fibrinogen 2 by thrombin, which in turn was likely caused by allosteric changes at the thrombin catalytic site induced by thrombin exosite 2 binding to the gamma' chains. Second, cross-linking of fibrin gamma chains was virtually the same for both types of fibrin. Third, the acceleratory effect of fibrin on thrombin-mediated XIII activation was more prominent with fibrin 1 than with fibrin 2, and this was also attributable to allosteric changes at the catalytic site induced by thrombin binding to gamma' chains. Fourth, fibrinolysis of fibrin 2 was delayed compared with fibrin 1. Altogether, differences between the structure and function of fibrins 1 and 2 are attributable to the effects of thrombin binding to gamma' chains.     

Platelets interact with fibrin only after activation

Interactions between platelets and fibrin have been visualized by phase contrast, epifluorescence, and scanning electron microscope examination of clots formed with dansylcadaverine-labeled fibrin and gel-filtered platelets. After thrombin activation, the platelets appeared as fluorescent aggregates with bridging strands of fibrin; formaldehyde- fixed platelets were not fluorescent under the same experimental conditions. Scanning electron micrographs demonstrated that thrombin- activated cells had numerous pseudopods to which the fibrin strands adhered; fixed platelets exhibited a smooth discoid appearance and did not interact with the clot. Platelets trapped in clots formed with Batroxobin (Pentapharm) (platelets are not activated by Batroxobin as confirmed by light-scattering aggregometry measurements) remained as nonfluorescent, discoid cells, whereas platelets first activated by adenosine diphosphate formed brightly fluorescent aggregates. Light- scattering data of thrombin activation (0.2 U/mL) indicated that preincubation of platelets with 0.1 mmol/L prostaglandin E1 (PGE1) prior to addition of thrombin decreased the extent and rate of platelet shape change and resulted in 100-fold slower aggregation. Clots formed in the presence of PGE1 revealed decreased fluorescence intensity and fewer platelet-fibrin contacts. Gly-Pro-Arg-Pro, which blocks fibrinogen binding and fibrin assembly, was also effective in blocking platelet-fibrin interactions. These results indicate that platelet activation is a prerequisite for attachment of platelets to fibrin.     

Thrombin interaction with platelet glycoprotein Ib: effect of glycocalicin on thrombin specificity.

We describe here the alteration of thrombin specificity induced by its interaction with glycocalicin. Glycocalicin is the external part of platelet glycoprotein Ib alpha (GPIb alpha) and contains binding sites for von Willebrand factor and thrombin. Taking advantage of its solubility, we have used glycocalicin in competition assays on various thrombin activities. Glycocalicin did not inhibit chromogenic substrate hydrolysis nor diisopropylfluorophosphate iPr2 (PF) incorporation, indicating that thrombin binding to GPIb does not alter access to or the conformation of the thrombin catalytic site. Glycocalicin competitively inhibited thrombin binding to fibrin (Ki = 0.1 mumol/L) and blocked fibrinogen clotting activity of thrombin. Glycocalicin also inhibited thrombin binding to thrombomodulin in a competitive manner (Ki = 3 to 5 mumol/L), but failed to prevent thrombin interaction with protein C in the absence of thrombomodulin. Previous results have indicated that GPIb binds to thrombin within the anion binding exosite masked by the carboxy-terminal hirudin peptide 54-65. The present results confirm the implication of the anion binding exosite in GPIb recognition, and further indicate that the thrombin binding site for GPIb overlaps with the thrombin binding sites for fibrin and thrombomodulin, whereas it is distinct from the thrombin binding site for protein C. Some of the structural requirements for thrombin binding to GPIb appear to be very similar to those reported for binding to its platelet receptor. However, thrombin-GPIb interaction does not appear to compete with receptor hydrolysis but rather increases the sensitivity and the rate of platelet responses elicited by the receptor.     

Hereditary dysfibrinogenemia in a patient with thrombotic disease

A new case of congenital dysfibrinogenemia, in which the patient has severe thrombotic disease, is reported. The abnormal fibrinogen molecules are characterized by normal fibrinopeptide release with thrombin and defective polymerization in the formation of fibrin. Clotting times with ancrod and reptilase are significantly prolonged. All other coagulation tests (except those for fibrinogen function) are normal, and the patient has no other underlying disease. The apparent paradox of defective fibrinogen, which clots abnormally and is yet associated with thrombotic disease, can be explained by further analysis of the patient's fibrinogen. The two important functional properties of this fibrinogen are: (1) it forms fibrin gels that are extremely rigid, and (2) the fibrin is highly resistant to lysis by plasmin. Thus, although the abnormal fibrinogen forms defective clots, the fibrin that is formed cannot be removed by the fibrinolytic system. These results provide a molecular explanation for the thrombotic disease in this patient. This abnormal fibrinogen appears to have unique characteristics and has been designated as fibrinogen Chapel Hill Ill.     

Thrombin generation and fibrin clot structure

Generation of a hemostatic clot requires thrombin-mediated conversion of fibrinogen to fibrin. Previous in vitro studies have demonstrated that the thrombin concentration present at the time of gelation profoundly influences fibrin clot structure. Clots formed in the presence of low thrombin concentrations are composed of thick fibrin fibers and are highly susceptible to fibrinolysis; while, clots formed in the presence of high thrombin concentrations are composed of thin fibers and are relatively resistant to fibrinolysis. While most studies of clot formation have been performed by adding a fixed amount of purified thrombin to fibrinogen, clot formation in vivo occurs in a context of continuous, dynamic changes in thrombin concentration. These changes depend on the local concentrations of pro- and anti-coagulants and cellular activities. Recent studies suggest that patterns of abnormal thrombin generation produce clots with altered fibrin structure and that these changes are associated with an increased risk of bleeding or thrombosis. Furthermore, it is likely that clot structure also contributes to cellular events during wound healing. These findings suggest that studies explicitly evaluating fibrin formation during in situ thrombin generation are warranted to explain and fully appreciate mechanisms of normal and abnormal fibrin clot formation in vivo.     

Fluid phase coagulation events have minimal impact on plasma fibrin structure

Reports of altered fibrin structure in clots formed from factor VIII-deficient plasma have raised the possibility that plasma clots mediated by activation of the fluid phase coagulation system might differ from clots formed by the direct addition of thrombin to plasma. In this study, turbidity measurements were used to compare the assembly and structure of clots formed from platelet-poor plasma by either the addition of thrombin or the exposure of recalcified plasma to glass. When clotted by recalcification, the lag phase before initial increase in turbidity was 10 to 25 times longer than when clotted by the addition of thrombin. Decreasing the ionic strength or increasing the calcium concentration shortened the lag phase. At high calcium concentrations (greater than 25 mM) polymerization was delayed and precipitation was noted. pH had a minimal impact over the range of 7.0 to 7.4. Fibrin fiber mass-length ratios for plasma gels formed by activation of the intrinsic cascade were virtually identical to those in gels formed by the direct addition of thrombin. These studies indicate that fluid phase coagulation events before the production of thrombin have a minimal impact on plasma fibrin structure.     

The roles of fibrinogen and fibrin in hemostasis and thrombosis.

Proteolytic conversion of fibrinogen to fibrin results in self-assembly to form a clot matrix that subsequently becomes cross-linked by fXIIIa to form the main structural element of the thrombus in vivo. Fibrin formation and assembly lead to new properties that regulate the rate and extent of clotting, cross-linking, and fibrinolysis. These are brought about by the ability of fibrin (1) to bind thrombin at a nonsubstrate site, thus limiting its diffusability but at the same time preserving its catalytic potential; (2) to bind fXIII, regulate its activation to fXIIIa, and limit further activation of fXIII once fibrin cross-linking has occurred; and (3) to bind alpha 2-PI, t-PA, and plasminogen and regulate the initiation and propagation of fibrinolysis. Fibrinogen and fibrin contain several potential platelet binding sites that interact with platelet GPIIb/IIIa receptors, and thus promote their participation in the hemostatic process. Additional, less well-defined interactions, not covered in detail here, such as those between fibrinogen or fibrin and other plasma proteins, cells, or tissue matrix components, suggest other functions that, along with those detailed above, will further define its multiple roles in modulating hemostasis, inflammation, and the wound healing process.     

Homophenotypic Aalpha R16H fibrinogen (Kingsport): uniquely altered polymerization associated with slower fibrinopeptide A than fibrinopeptide B release.

We detail for the first time the uniquely altered fibrin polymerization of homophenotypic Aalpha R16H dysfibrinogen. By polymerase chain reaction amplification and DNA sequencing, our new proposita's genotype consisted of a G>A transition encoding for Aalpha R16H, and an 11 kb Aalpha gene deletion. High-performance liquid chromatography disclosed fibrinopeptide A release approximately six times slower than its fibrinopeptide B. Turbidimetric analyses revealed unimpaired fibrin repolymerization, and abnormal thrombin-induced polymerization (1-7 mumol/l fibrinogen, > 96% coagulable), consisting of a prolonged lag time, slow rate, and abnormal clot turbidity maxima, all varying with thrombin concentration. For example, at 0.2-3 U/ml, the resulting turbidity maxima ranged from lower to higher than normal control values. By scanning electron microscopy, clots formed by 0.3 and 3 thrombin U/ml displayed mean fibril diameters 42 and 254% of the respective control values (n = 400). Virtually no such differences from control values were demonstrable, however, when clots formed in the presence of high ionic strength (micro = 0.30) or of monoclonal antibeta(15-42)IgG. The latter also prolonged the thrombin clotting time approximately three-fold. Additionally, thrombin-induced clots displayed decreased elastic moduli, with G' values of clots induced by 0.3, 0.7 and 3 thrombin U/ml corresponding to 11, 34, and 45% of control values. The results are consistent with increased des-BB fibrin monomer generation preceding and during polymerization. This limited the inherent gelation delay, decreased the clot stiffness, and enabled a progressively coarser, rather than finer, network induced by increasing thrombin concentrations. We hypothesize that during normal polymerization these constitutive des-BB fibrin monomer properties attenuate their des-AA fibrin counterparts.     

Concentration effects of platelets, fibrinogen and thrombin on platelet aggregation and fibrin clotting

The effects of varying concentrations of platelets, fibrinogen and thrombin on platelet aggregation and on fibrin clotting were investigated. The results indicated that a threshold thrombin to platelet concentration ratio may be required to cause platelet activation. Above the threshold ratio, platelets exhibited properties which enhanced thrombin action in causing aggregation and fibrin clotting. At T/P ratios below the threshold level, the presence of platelets reduced thrombin activity, in other words, platelets exerted an antithrombin action. Fibrinogen at low concentrations (0.02-1.5 mg/ml) enhanced platelet aggregation induced by thrombin; whereas, at high concentrations of fibrinogen (2.0-4.0 mg/ml), aggregation was markedly inhibited. Continuous mixing of samples of paltelets and fibrinogen at physiological concentrations with thrombin at low concentrations (less than 2.0 U/ml) resulted in platelet aggregation. On the other hand, fibrin clots formed in samples without mixing or with high thrombin concentrations (greater than or equal to 5.0 U/ml). These results suggested that the quantitative relationships between platelets, fibrinogen and thrombin, and the presence or absence of cell contact may be important factors in determining the overall hemostasis.     

Evidence for four different polymerization sites involved in human fibrin formation.

The mechanism of association and the organization of human fibrin were studied by using affinity chromatography. Insolubilized fibrinogen, fibrin monomer, and crosslinked fibrin were used to localize the binding sites on fibrinogen and fibrin derivatives. Four different polymerization sites have been distinguished. A binding site ("a"), available without thrombin action, is present on the fibrinogen fragment D domain. The complementary ("A") is inoperative in fibrinogen and requires thrombin for activation; it is located on the fibrinogen NH2-terminal domain. A third polymerization site ("b") appears to be formed by the alignment of the fragment D domains on two fibrin monomer molecules upon polymerization; this site functions without thrombin mediation and the alignment is stabilized by the Factor XIIIa-catalyzed crosslink bonds. The "b" site is complementary to another thrombin-activated site ("B") on the fibrinogen NH2-terminal domain. The two thrombin activable sites, "A" and "B", are distinguishable, although they are located in the same fibrinogen domain.     

Accessibility of epitopes on fibrin clots and fibrinogen gels.

Radiolabeled antibodies were perfused into fibrin clots and fibrinogen gels formed in vitro to assess the reactivity of selected epitopes. An antifibrinogen monoclonal antibody (MoAb) (antibody 1D4/xl-f), directed against an epitope in the A alpha-chain C-terminal region (A alpha 241-476), bound to 35% of the epitope in crosslinked fibrin clots and 37% of the same epitope in factor XIII-induced fibrinogen gel networks. A different MoAb (4-2/xl-f, anti gamma 392-406) bound to only 7% of the epitope in both fibrin and fibrinogen gels. As expected, an antifibrin MoAb (antibody T2G1, antiB beta 15-21) did not bind to fibrinogen gels, but bound to fibrin, although to only 14% of the available T2G1-reactive epitopes. An antibody that does not recognize fibrin (antibody 1-8C6, antiB beta 1-21) predictably did not bind to fibrin clots and bound to 35% of the 1-8C6 epitopes present in fibrinogen gels, a level of binding also observed with antibody T2G1 and fibrinogen gels only after the latter were treated with thrombin. T2G1 epitope expression was affected much more than 1D4/xl-f epitope expression in clots formed in buffers of high or low ionic strength, conditions known to influence clot structure. Studies on the availability, in quantitative terms, of the T2G1-reactive epitope in fibrin clots is of particular importance because this antibody is currently being used in clinical trials as a clot imaging agent.     

Studies on the ultrastructure of fibrin lacking fibrinopeptide B (beta- fibrin)

Release of fibrinopeptide B from fibrinogen by copperhead venom procoagulant enzyme results in a form of fibrin (beta-fibrin) with weaker self-aggregation characteristics than the normal product (alpha beta-fibrin) produced by release of fibrinopeptides A (FPA) and B (FPB) by thrombin. We investigated the ultrastructure of these two types of fibrin as well as that of beta-fibrin prepared from fibrinogen Metz (A alpha 16 Arg----Cys), a homozygous dysfibrinogenemic mutant that does not release FPA. At 14 degrees C and physiologic solvent conditions (0.15 mol/L of NaCl, 0.015 mol/L of Tris buffer pH 7.4), the turbidity (350 nm) of rapidly polymerizing alpha beta-fibrin (thrombin 1 to 2 U/mL) plateaued in less than 6 min and formed a "coarse" matrix consisting of anastomosing fiber bundles (mean diameter 92 nm). More slowly polymerizing alpha beta-fibrin (thrombin 0.01 and 0.001 U/mL) surpassed this turbidity after greater than or equal to 60 minutes and concomitantly developed a network of thicker fiber bundles (mean diameters 118 and 186 nm, respectively). Such matrices also contained networks of highly branched, twisting, "fine" fibrils (fiber diameters 7 to 30 nm) that are usually characteristic of matrices formed at high ionic strength and pH. Slowly polymerizing beta-fibrin, like slowly polymerizing alpha beta-fibrin, displayed considerable quantities of fine matrix in addition to an underlying thick cable network (mean fiber diameter 135 nm), whereas rapidly polymerizing beta-fibrin monomer was comprised almost exclusively of wide, poorly anastomosed, striated cables (mean diameter 212 nm). Metz beta-fibrin clots were more fragile than those of normal beta-fibrin and were comprised almost entirely of a fine network. Metz fibrin could be induced, however, to form thick fiber bundles (mean diameter 76 nm) in the presence of albumin at a concentration (500 mumol/L) in the physiologic range and resembled a Metz plasma fibrin clot in that regard. The diminished capacity of Metz beta-fibrin to form thick fiber bundles may be due to impaired use or occupancy of a polymerization site exposed by FPB release. Our results indicate that twisting fibrils are an inherent structural feature of all forms of assembling fibrin, and suggest that mature beta-fibrin or alpha beta-fibrin clots develop from networks of thin fibrils that have the ability to coalesce to form thicker fiber bundles.     

Incorporation of fibrin molecules containing fibrinopeptide A alters clot ultrastructure and decreases permeability

Previous studies have shown that a heterozygous mutation in the fibrinogen Aalpha chain gene, which results in an Aalpha R16C substitution, causes fibrinolytic resistance in the fibrin clot. This mutation prevents thrombin cleavage of fibrinopeptide A from mutant Aalpha R16C chains, but not from wild-type Aalpha chains. However, the mechanism underlying the fibrinolytic resistance is unclear. Therefore, this study investigated the biophysical properties of the mutant fibrin that contribute to fibrinolytic resistance. Fibrin clots made from the mutant fibrinogen incorporated molecules containing fibrinopeptide A into the polymerised clot, which resulted in a 'spiky' clot ultrastructure with barbed fibrin strands. The clots were less stiff than normal fibrin and were cross-linked slower by activated FXIII, but had an increased average fiber diameter, were more dense, had smaller pores and were less permeable. Protein sequencing showed that unclottable fibrinogen remaining in the supernatant consisted entirely of homodimeric Aalpha R16C fibrinogen, whereas both cleaved wild-type alpha chains and uncleaved Aalpha R16C chains were in the fibrin clot. Therefore, fibrinolytic resistance of the mutant clots is probably a result of altered clot ultrastructure caused by the incorporation of fibrin molecules containing fibrinopeptide A, resulting in larger diameter fibers and decreased permeability to fibrinolytic enzymes.     

Regulation of plasma factor XIII binding to fibrin in vitro

The binding of plasma factor XIII to fibrinogen or fibrin that has been chemically or enzymatically induced to polymerize was studied. Factor XIII binding was assayed using a 3H-putrescine incorporation assay and an 125I-plasma factor XIII binding assay. More than 80% of the native and radiolabeled plasma factor XIII was bound to fibrin I formed by reptilase in EDTA, citrate, or heparin anticoagulated plasma. Plasma factor XIII and 125I-factor XIII was bound (89.6% to 92.5%) to fibrin II formed by thrombin in either citrate or EDTA anticoagulated plasma. Sodium dodecyl sulfate-polyacrylamide gel electrophoresis (SDS-PAGE) of 125I-plasma factor XIII bound to fibrin I or fibrin II formed by reptilase or thrombin in the presence of EDTA demonstrated the b2-subunit remained bound to the a-chains or thrombin-cleaved a-chains. In the presence of calcium chloride and thrombin, the b2-subunit dissociated and factor XIIIa was bound. Protamine sulfate caused fibrinogen polymerization in the absence of divalent cations and reduced both plasma factor XIII and immunologic fibrinogen levels. Fibrinogen polymerized by protamine sulfate bound plasma factor XIII and the a2-subunit of 125I-platelet factor XIII. Plasma factor XIII was also bound to sonicated non-cross-linked fibrin II in either normal plasma or afibrinogenemic plasma. Plasma levels of several coagulation proteins were unchanged after the addition of reptilase, protamine sulfate, or sonicated fibrin to plasma. These results demonstrate that a specific binding site for the a2-subunit of plasma factor XIII is present on polymerized fibrinogen, fibrin I, and fibrin II. Furthermore, the presence of divalent cations, thrombin-cleavage of plasma factor XIII, and release of fibrinopeptides A or B are not required for plasma factor XIII binding to polymerized fibrinogen and fibrin.     

Determination of human fibrinopeptide A by radioimmunoassay in purified systems and in the blood.

The formation of fibrin clots or circulating soluble fibrin is accompanied by the appearance of fibrinopeptides. Measurement of the fibrinopeptide concentration in plasma can provide important information on the rate of conversion of fibrinogen to fibrin by thrombin. This rate varies under different physiologic and pathologic conditions. Fibrinopeptide A is a better molecular marker of the conversion than fibrinopeptide B since it is the first peptide to be cleaved by thrombin. A radioimmunoassay technique has been developed for the quantitative determination of human fibrinopeptide A. The procedure detects human fibrinopeptide A at a concentration of approximately 0.05 ng/ml. The variation of fibrinopeptide A content in normal persons may reflect its rapid formation and catabolism. A significantly increased concentration of this peptide was found in a patient during defibrination therapy with a purified enzyme from the venom of Agkistrodon rhodostoma and in patients suffering from retinal vascular occlusions.     

Role of plasminogen activator inhibitor-1 in promoting fibrin deposition in rabbits infused with ancrod or thrombin

The role of defective fibrinolysis caused by elevated activity of plasminogen activator inhibitor-1 (PAI-1) in promoting fibrin deposition in vivo has not been well established. The present study compared the efficacy of thrombin or ancrod, a venom-derived enzyme that clots fibrinogen, to induce fibrin formation in rabbits with elevated PAI-1 levels. One set of male New Zealand rabbits received intravenous endotoxin to increase endogenous PAI-1 activity followed by a 1-hour infusion of ancrod or thrombin; another set of normal rabbits received intravenous human recombinant PAI-1 (rPAI-1) during an infusion of ancrod or thrombin. Thirty minutes after the end of the infusion, renal fibrin deposition was assessed by histopathology. Animals receiving endotoxin, rPAI-1, ancrod, or thrombin alone did not develop renal thrombi. All endotoxin-treated rabbits developed fibrin deposition when infused with ancrod (n = 4) or thrombin (n = 6). Fibrin deposition occurred in 7 of 7 rabbits receiving both rPAI-1 and ancrod and in only 1 of 6 receiving rPAI-1 and thrombin (P < .01). In vitro, thrombin but not ancrod was inactivated by normal rabbit plasma and by purified antithrombin III or thrombomodulin. The data indicate that elevated levels of PAI-1 promote fibrin deposition in rabbits infused with ancrod but not with thrombin. In endotoxin-treated rabbits, fibrin deposition that occurs with thrombin infusion may be caused by decreased inhibition of procoagulant activity and not increased PAI-1 activity.     

Autoantibody to plasma fibrinopeptide A in a patient with a severe acquired haemorrhagic syndrome.

We describe a 50-year-old man with a severe acquired haemorrhagic syndrome. He had slightly prolonged clotting times using bovine thrombin, human thrombin and reptilase. His plasma contained a polyclonal IgG which interfered with the generation of fibrin monomers without inhibiting the aggregation of preformed monomers. The inhibitor delayed thrombin-induced fibrinopeptide A release. The IgG bound to insolubilized synthetic fibrinopeptide A (one binding site per molecule) and, with higher affinity, to fibrinogen (two binding sites per molecule). It did not bind to insolubilized fibrin monomers. The IgG did not impair the catalytic activity of thrombin toward a small synthetic substrate but inhibited the binding of thrombin to fibrinogen without binding to thrombin. The binding of the anti-fibrinopeptide A autoantibody to fibrinogen might have impaired thrombin-induced fibrinogen to fibrin conversion in vivo. This may have favoured the reported haemorrhagic syndrome which was associated with severe chronic renal insufficiency.     

Crystal structure of the complex between thrombin and the central "E" region of fibrin

Nonsubstrate interactions of thrombin with fibrin play an important role in modulating its procoagulant activity. To establish the structural basis for these interactions, we crystallized d-Phe-Pro-Arg-chloromethyl ketone-inhibited human thrombin in complex with a fragment, E(ht), corresponding to the central region of human fibrin, and solved its structure at 3.65-A resolution. The structure revealed that the complex consists of two thrombin molecules bound to opposite sides of the central part of E(ht) in a way that seems to provide proper orientation of their catalytic triads for cleavage of fibrinogen fibrinopeptides. As expected, binding occurs through thrombin's anion-binding exosite I. However, only part of it is involved in forming an interface with the complementary negatively charged surface of E(ht). Among residues constituting the interface, Phe-34, Ser-36A, Leu-65, Tyr-76, Arg-77A, Ile-82, and Lys-110 of thrombin and the A alpha chain Trp-33, Phe-35, Asp-38, Glu-39, the B beta chain Ala-68 and Asp-69, and the gamma chain Asp-27 and Ser-30 of E(ht) form a net of polar contacts surrounding a well defined hydrophobic interior. Thus, despite the highly charged nature of the interacting surfaces, hydrophobic contacts make a substantial contribution to the interaction.     

Polyphosphate enhances fibrin clot structure

Polyphosphate, a linear polymer of inorganic phosphate, is present in platelet dense granules and is secreted on platelet activation. We recently reported that polyphosphate is a potent hemostatic regulator, serving to activate the contact pathway of blood clotting and accelerate factor V activation. Because polyphosphate did not alter thrombin clotting times, it appeared to exert all its procoagulant actions upstream of thrombin. We now report that polyphosphate enhances fibrin clot structure in a calcium-dependent manner. Fibrin clots formed in the presence of polyphosphate had up to 3-fold higher turbidity, had higher mass-length ratios, and exhibited thicker fibers in scanning electron micrographs. The ability of polyphosphate to enhance fibrin clot turbidity was independent of factor XIIIa activity. When plasmin or a combination of plasminogen and tissue plasminogen activators were included in clotting reactions, fibrin clots formed in the presence of polyphosphate exhibited prolonged clot lysis times. Release of polyphosphate from activated platelets or infectious microorganisms may play an important role in modulating fibrin clot structure and increasing its resistance to fibrinolysis. Polyphosphate may also be useful in enhancing the structure of surgical fibrin sealants.     

Age dependency of the sialic acid content of fibrinogen. Consequences for erythrocyte aggregation

Sialic acid (SA) content of plasma proteins and fibrinogen was investigated in 60 persons of different age and health status. SA/mg fibrin rose with age and morbidity in plasma, rinsed clots of fibrin from plasma and after prothrombin adsorption as well as in fibrin clots prepared from purified fibrinogen. The higher plasma SA is caused by increasing concentrations of glycoproteins like fibrinogen, but also by a higher content of SA/mg protein, as has been shown for fibrinogen. SA is considered to be an unspecific marker of acute phase reactions. Changing SA content of glycoproteins may have functional consequences. An increased red cell aggregation with fibrinogen of healthy elderly correlated with its SA content, but SA is most probably only indicating an altered protein heterogeneity in the aged and not a causative factor that influences erythrocyte aggregation.