Biophysical characterization of fibrinogen Caracas I with an Aalpha-chain truncation at Aalpha-466 Ser: identification of the mutation and biophysical characterization of properties of clots from plasma and purified fibrinogen.

Fibrinogen Caracas I is a dysfibrinogenemia with a mild bleeding tendency; a novel nonsense mutation, in the gene coding the Aalpha-chain, identified in this study as G4731T, giving rise to a new stop codon at Aalpha-Glu 467. Fibrinogen from two family members, the mother and sister of the propositus, both heterozygous for the mutation were studied, analyzing clots made from both plasma and purified fibrinogen. Clot structure and properties were characterized by turbidity, permeation, scanning electron microscopy and rheological studies. Permeation through Caracas I plasma clots was decreased, consistent with the decreased final turbidity. As shown by scanning electron microscopy, plasma clots from the patients were composed of very thin fibers, with increased fibrin density and reduced pore size. Viscoelastic measurements revealed that fibrinogen Caracas I plasma clots were much stiffer and less subject to compaction. These results demonstrate a key role of the carboxyl-terminal alpha chains of fibrin in lateral aggregation during polymerization and reinforce the utility of studying plasma clots. It is important to point out that the biophysical studies with fibrinogen purified by two different methods yielded contradictory results, which can be accounted for by selective purification of certain molecular species as seen by two-dimensional electrophoresis.     

A novel fibrinogen variant--Praha I: hypofibrinogenemia associated with gamma Gly351Ser substitution

OBJECTIVES: A 25-yr-old man from Prague had abnormal bleeding after several surgical operations with low fibrinogen level and hypofibrinogenemia was suspected. PATIENTS AND METHODS: The patient, 25 yr-old male had a low fibrinogen concentration as determined by the thrombin time and immunoturbidimetrical method. His 48-yr-old mother presented with normal coagulation tests, normal fibrinogen level and reported no history of bleeding. To identify the genetic mutation responsible for this hypofibrinogen, genomic DNA extracted from the blood was analyzed. Fibrin polymerization measurement, kinetics of fibrinopeptide release, fibrinogen clottability measurement, mass spectroscopy, and scanning electron microscopy were performed. RESULTS: DNA sequencing showed heterogeneous fibrinogen gammaG351S mutation in the propositus. The mutant chain was found not to be expressed to the circulation by matrix-assisted laser desorption/ionization time of flight mass spectrometry. Scanning electron micrographs of the patient's fibrin clot as well as kinetics of fibrinopeptide release and fibrin polymerization were found to be normal. CONCLUSION: A case of hypofibrinogenemia gammaG351S was found by routine coagulation testing and was genetically identified.     

Functional characterization of fibrinogen Bicêtre II: a gamma 308 Asn-->Lys mutation located near the fibrin D:D interaction sites.

The effects of the gamma-308 Asn-->Lys substitution of fibrinogen Bicêtre II on clot formation, structure and properties were determined to elucidate the role of this part of the molecule in fibrin polymerization. This process was followed by measurement of turbidity, and the structure and biophysical characteristics of the clots were studied by permeation, scanning electron microscopy, and rheological techniques. Turbidity studies revealed an increased lag period and greater final turbidity for fibrin BII clots, indicating impaired oligomer formation. By permeation it was found that BII clots had greater network porosity, four times more than that of the control. The clot architecture visualized by scanning electron microscopy was similar to that of control clots with pore size and fiber diameter slightly increased. BII clots had a stiffness decreased by more than half, and an increased loss tangent, a measure of the inelastic deformation of the clot. All these results suggest a disruption of the proper alignment of fibrin monomers during oligomer formation. Consistent with these results, fibrin cross-linking by adding the physiological concentration of factor XIII to the purified protein showed that gamma and alpha chain cross-linking was impaired in BII clots. This amino acid substitution defines distinctive effects on the surface of the D:D interaction sites that are reflected in the clot structure and functional properties.     

The alphaC domains of fibrinogen affect the structure of the fibrin clot, its physical properties, and its susceptibility to fibrinolysis

The functions of the alphaC domains of fibrinogen in clotting and fibrinolysis, which have long been enigmatic, were determined using recombinant fibrinogen truncated at Aalpha chain residue 251. Scanning electron microscopy and confocal microscopy revealed that the fibers of alpha251 clots were thinner and denser, with more branch points than fibers of control clots. Consistent with these results, the permeability of alpha251 clots was nearly half that of control clots. Together, these results suggest that in normal clot formation, the alphaC domains enhance lateral aggregation to produce thicker fibers. The viscoelastic properties of alpha251 fibrin clots differed markedly from control clots; alpha251 clots were much less stiff and showed more plastic deformation, indicating that interactions between the alphaC domains in normal clots play a major role in determining the clot's mechanical properties. Comparing factor XIIIa cross-linked alpha251 and control clots showed that gamma chain cross-linking had a significant effect on clot stiffness. Plasmin-catalyzed lysis of alpha251 clots, monitored with both macroscopic and microscopic methods, was faster than lysis of control clots. In conclusion, these studies provide the first definitive evidence that the alphaC domains play an important role in determining the structure and biophysical properties of clots and their susceptibility to fibrinolysis.     

Fibrinogen Stony Brook II: partial characterization of a heterozygously transmitted peptide A anomaly

We describe preliminary studies of a new familial dysfibrinogen, fibrinogen Stony Brook II, present in a propositus and his mother. Both presented with a history of unexplained and chronic joint swelling following trauma, and the propositus suffered recurrent knee haemarthroses following arthroscopic surgery. Prolonged plasma thrombin times required a 3-5 fold excess of normal plasma for correction. Isolated fibrinogen displayed prolonged clotting times and delayed onset of clot turbidity. Also, an abnormal peptide could be released by thrombin but not by batroxobin along with approximately half the expected amounts of normal A peptide. Assessed by its thrombin release and by its early HPLC retention position, the abnormal peptide suggests a possible A alpha-16-Arg----His substitution. The data suggests an association in these probands between this heterozygously transmitted anomaly and the apparently impaired healing in hypovascular sites.     

Common variation in the C-terminal region of the fibrinogen beta-chain: effects on fibrin structure, fibrinolysis and clot rigidity

Fibrinogen BbetaArg448Lys is a common polymorphism, positioned within the carboxyl terminus of the Bbeta-chain of the molecule. Studies suggest that it is associated with severity of coronary artery disease and development of stroke. The effects of the amino acid substitution on clot structure remains controversial, and the aim of this study was to investigate the effect(s) of this polymorphism on fibrin clot structure using recombinant techniques. Permeation, turbidity, and scanning electron microscopy showed that recombinant Lys448 fibrin had a significantly more compact structure, with thin fibers and small pores, compared with Arg448. Clot stiffness, measured by means of a novel method using magnetic tweezers, was significantly higher for the Lys448 compared with the Arg448 variant. Clots made from recombinant protein variants had similar lysis rates outside the plasma environment, but when added to fibrinogen-depleted plasma, the fibrinolysis rates for Lys448 were significantly slower compared with Arg448. This study demonstrates for the first time that clots made from recombinant BbetaLys448 fibrinogen are characterized by thin fibers and small pores, show increased stiffness, and appear more resistant to fibrinolysis. Fibrinogen BbetaArg448Lys is a primary example of common genetic variation with a significant phenotypic effect at the molecular level.     

Congenital hypodysfibrinogenemia associated with a novel deletion of three residues (γAla289_Asp291del) in fibrinogen

Hypodysfibrinogenemia is the least frequently reported congenital fibrinogen disorder, characterized by both quantity and quality defects of fibrinogen. In this study, we investigated the molecular basis of hypodysfibrinogenemia in a Chinese family. Functional fibrinogen was measured by Clauss method, and the antigenic fibrinogen was measured by immunoturbidimetry assay. All the exons and exon–intron boundaries of fibrinogen genes (FGA, FGB and FGG) were analysed by direct DNA sequencing. To further evaluate its molecular and functional characterizations, fibrinogen was purified from the plasma of propositus, then SDS-PAGE, fibrin polymerization, clot lysis, and electron microscopy scanning were all performed. The propositus showed a slight decrease of immunologic fibrinogen (1.52 g/L) but dramatically reduced functional fibrinogen (0.3 g/L). DNA sequencing revealed a novel heterozygous CCTTTGATG deletion in the exon 8 of FGG, leading to the deletion of Ala289, Phe290, and Asp291 in fibrinogen γ-chain. The polymerization of the fibrinogen from the propositus was markedly impaired, with prolonged lag period and decreased final turbidity. The fibrinogen clottability showed a reduced fraction of participating clot formation. While the clot lysis showed normal. Scanning electron microscopy revealed that the fibers of the propositus were thicker than normal, with larger pores and curlier meshworks. We conclude that γAla289_Asp291del is responsible for the hypodysfibrinogenemia in this case.     

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.     

Anticoagulant albumin fragments that bind to fibrinogen/fibrin: possible implications.

The present studies describe an inhibitory effect on fibrin polymerization by albumin fragments. When added to blood or plasma, SCMF or unreduced albumin CNBrF delayed clot formation, in sharp contrast to their acceleration of clotting of fibrinogen solutions. CNBrF inhibition was less marked than that of SCMF. The latter consistently prolonged the lag phase and decreased the opacity of fibrin in plasma, effects that could not be abolished by EDTA or by calcium chloride. Clots formed lacked elasticity in that clotting times were undetectable by mechanical probe in the absence of calcium. Estimated by clot free liquor, PRP clots decreased in size at much slower rates than controls and at complete retraction their volume remained at least threefold higher that of controls (n = 6). When fibrinogen was isolated from plasma or fibrinogen (approximately 5 mg/ml) solutions containing SCMF 1 to 5 mg/ml four SCMF coisolated with fibrinogen (n = 3 and n = 4, respectively), assessed by SDS-PAGE, and these could not be dissociated from fibrinogen by size exclusion chromatography (n = 2). Such fibrinogen isolates displayed prolonged clotting times, decreased clot opacity, and similarly abnormal reaggregation of their solubilized fibrin. In other experiments, limited human neutrophil elastase digestion produced large albumin fragments of which, examined unreduced, several fragments also bound to fibrin(ogen) and displayed this anticoagulant property (n = 2). These and related results suggest that the anticoagulant property is attributable at least in part to the largest SCMF.(ABSTRACT TRUNCATED AT 250 WORDS)     

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.     

Myosin: a noncovalent stabilizer of fibrin in the process of clot dissolution

Myosin modulates the fibrinolytic process as a cofactor of the tissue plasminogen activator and as a substrate of plasmin. We report now that myosin is present in arterial thrombi and it forms reversible noncovalent complexes with fibrinogen and fibrin with equilibrium dissociation constants in the micromolar range (1.70 and 0.94 microM, respectively). Competition studies using a peptide inhibitor of fibrin polymerization (glycl-prolyl-arginyl-proline [GPRP]) indicate that myosin interacts with domains common in fibrinogen and fibrin and this interaction is independent of the GPRP-binding polymerization site in the fibrinogen molecule. An association rate constant of 1.81 x 10(2) M(-1) x s(-1) and a dissociation rate constant of 3.07 x 10(-4) s(-1) are determined for the fibrinogen-myosin interaction. Surface plasmon resonance studies indicate that fibrin serves as a matrix core for myosin aggregation. The fibrin clots equilibrated with myosin are stabilized against dissolution initiated by plasminogen and tissue-type plasminogen activator (tPA) or urokinase (at fibrin monomer-myosin molar ratio as high as 30) and by plasmin under static and flow conditions (at fibrin monomer-myosin molar ratio lower than 15). Myosin exerts similar effects on the tPA-induced dissolution of blood plasma clots. Covalent modification involving factor XIIIa does not contribute to this stabilizing effect; myosin is not covalently attached to the clot by the time of complete cross-linking of fibrin. Thus, our in vitro data suggest that myosin detected in arterial thrombi binds to the polymerized fibrin, in the bound form its tPA-cofactor properties are masked, and the myosin fibrin clot is relatively resistant to plasmin.     

A novel fibrinogen variant--Liberec: dysfibrinogenaemia associated with gamma Tyr262Cys substitution

Objective:  A 22-yr-old woman had abnormal preoperative coagulation test results and congenital dysfibrinogenaemia was suspected.
Patients and methods:  The patient from Liberec (Czech Republic) had a low fibrinogen plasma level as determined by Clauss method, normal fibrinogen level as determined by immunoturbidimetrical method, and prolonged thrombin time. To identify the genetic mutation responsible for this dysfibrinogen, genomic DNA extracted from the blood was analysed. Fibrin polymerisation measurement, kinetics of fibrinopeptide release, fibrinogen clottability measurement and scanning electron microscopy were performed.
Results:  DNA sequencing showed the heterozygous fibrinogen γ Y262C mutation. Kinetics of fibrinopeptide release was normal, however fibrin polymerisation was impaired. Fibrinogen clottability measurement showed that only about 45% molecules of fibrinogen are involved in the clot formation. Scanning electron microscopy revealed thicker fibres, which were significantly different from the normal control.
Conclusion:  A case of dysfibrinogenaemia, found by routine coagulation testing, was genetically identified as a novel fibrinogen variant (γ Y262C) that has been named Liberec.     

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.     

Fibrinogen Kaiserslautern (γ 380 Lys to Asn): a new glycosylated fibrinogen variant with delayed polymerization

An adult woman diagnosed with cerebral thrombosis following a caesarean section was found to have severely prolonged thrombin and reptilase times. Five other family members also had prolonged, but variable, thrombin and reptilase times. Analysis of purified fibrinogen on reducing SDS-PAGE revealed an additional band, in all family members, which migrated immediately below the normal Bβ band. Western blotting indicated that this band was a gamma chain and endoglycosidase-F digestion established that it contained an additional oligosaccharide side chain. Partial acid hydrolysis localized the new oligosaccharide to the C-terminus of the gamma chain. Amplification of this region by PCR and subsequent DNA sequencing demonstrated a single base substitution altering the normal 380 Lys (AAG) codon to Asn (AAT), producing a new Asn-Lys-Thr glycosylation site. The propositus and one other family member were homozygous for this mutation but the remaining four family members were heterozygous. The polymerization of purified fibrin monomers from the propositus was grossly abnormal; however, the polymerization curve was almost normalized by the removal of terminal sialic acid residues. This suggests that the polymerization defect was primarily caused by additional negatively charged sialic acid residues present on the new oligosaccharide. Further analysis of the D domain of purified fibrinogen established that calcium binding to the high affinity site remained unaffected by the bulky carbohydrate side chain or negatively charged sialic acid residues.     

Fibrinogen Kaiserslautern (γ 380 Lys to Asn): a new glycosylated fibrinogen variant with delayed polymerization

An adult woman diagnosed with cerebral thrombosis following a caesarean section was found to have severely prolonged thrombin and reptilase times. Five other family members also had prolonged, but variable, thrombin and reptilase times. Analysis of purified fibrinogen on reducing SDS-PAGE revealed an additional band, in all family members, which migrated immediately below the normal Bβ band. Western blotting indicated that this band was a gamma chain and endoglycosidase-F digestion established that it contained an additional oligosaccharide side chain. Partial acid hydrolysis localized the new oligosaccharide to the C-terminus of the gamma chain. Amplification of this region by PCR and subsequent DNA sequencing demonstrated a single base substitution altering the normal 380 Lys (AAG) codon to Asn (AAT), producing a new Asn-Lys-Thr glycosylation site. The propositus and one other family member were homozygous for this mutation but the remaining four family members were heterozygous. The polymerization of purified fibrin monomers from the propositus was grossly abnormal; however, the polymerization curve was almost normalized by the removal of terminal sialic acid residues. This suggests that the polymerization defect was primarily caused by additional negatively charged sialic acid residues present on the new oligosaccharide. Further analysis of the D domain of purified fibrinogen established that calcium binding to the high affinity site remained unaffected by the bulky carbohydrate side chain or negatively charged sialic acid residues.     

Dusart syndrome: a new concept of the relationship between fibrin clot architecture and fibrin clot degradability: hypofibrinolysis related to an abnormal clot structure

Fibrinogen Dusart is a congenital dysfibrinogenemia (A-alpha 554 Arginine-->Cysteine) associated with severe thrombotic disorder, high incidence of thrombotic embolism, and abnormal fibrin polymerization. This thrombotic disorder was attributed to an abnormal clot thrombolysis with reduced plasminogen binding to fibrin and defective plasminogen activation by tissue plasminogen activator. The purpose of this work was to assess whether clot architecture could be involved in the thromboresistance of the fibrin Dusart and the high incidence of embolism. An important change in Dusart fibrin clot structure was identified with dramatic decrease of gel porosity (Ks), fiber diameters (d), and fiber mass-length ratios (mu) derived from permeation analysis. In addition, rigidity of the Dusart clot was found to be greatly increased compared with normal fibrin. We provide evidence that both thrombolysis resistance and abnormal rigidity of the fibrin Dusart are related to this abnormal architecture, which impairs the access of fibrinolytic enzymes to the fibrin and which is responsible for a brittle clot that breaks easily, resulting in a high incidence of embolism. Indeed, when restoring a normal clot structure by adding dextran 40 (30 mg/mL) before coagulation, clot thrombolysis and clot rigidity recovered normal values. This effect was found to be dose- dependent. We conclude that clot architecture is crucial for the propensity of blood clot to be degraded and that abnormal clot structure can be highly thrombogenic in vivo. The alpha-C domains of fibrinogen are determinant in fibrin clot structure.     

Severe hypodysfibrinogenemia in compound heterozygotes of the fibrinogen AalphaIVS4 + 1G>T mutation and an AalphaGln328 truncation (fibrinogen Keokuk)

Two siblings with hypofibrinogenemia have lifelong trauma-related bleeding. Recently, the brother experienced recurrent thrombosis after cryoprecipitate infusions following surgery. The sister had 6 miscarriages. Plasma clots in each were resistant to compression and fibrinolysis and were soluble in 5 M urea. Examination by sodium dodecyl sulfate-polyacrylamide gel electrophoresis (SDS-PAGE) revealed only the presence of crosslinked gamma-gamma fibrin chain dimers without high polymers of alpha n. Fibrin clots contained an abnormal 35-kDa constituent recognized by an antibody to the mature fibrinogen Aalpha-chain residues 241-476 but not by antibodies to Aalpha219-348 or Aalpha349-406. DNA analysis revealed a heterozygous CAA-->TAA mutation at the codon for amino acid 328 of the Aalpha gene in these siblings and 2 asymptomatic family members. The Gln328stop mutation (fibrinogen Keokuk) predicted a 46% truncation and the production of a 35-kDa Aalpha chain. Analysis of purified fibrinogen revealed expression of the abnormal Aalpha chain in 4 family members but found no normal fibrinogen in the 2 hypofibrinogenemic patients. This paradox was resolved when they and their asymptomatic mother were found to be heterozygous for a second Aalpha mutation, a GT-->TT splice site mutation in intron 4 (IVS4 + 1 G> T). However, compound heterozygosity for both mutations was required for the expression of severe hypodysfibrinogenemia and for clinical symptoms.     

Fibrinogen Marburg: a homozygous case of dysfibrinogenemia, lacking amino acids A alpha 461-610 (Lys 461 AAA-->stop TAA).

In the A alpha-chain gene coding for an abnormal fibrinogen (fibrinogen Marburg) we identified a single base substitution (A-->T) that changes the codon A alpha 461 AAA (Lys) to TAA (Stop). The propositus was found to be homozygous for the mutation, whereas the father and five siblings were heterozygous, and three other siblings contained only the normal sequence. The stop codon at position 461 results in the deletion of the carboxyl-terminal segment A alpha 461-610. Purified fibrinogen Marburg contained an A alpha-chain with a relative molecular weight of approximately 47,000. The FpA release by thrombin was not affected by this deletion, whereas the fibrin polymerization was strongly decreased. The binding of endothelial cells to immobilized fibrinogen Marburg was almost completely abolished compared with normal fibrinogen. Fibrinogen Marburg contained a substantial amount of albumin linked to the fibrinogen molecule by disulfide bonds, and these fibrinogen-albumin complexes were also present in plasma. The plasma fibrinogen concentration of the propositus was measured by three different methods: a functional method (< 0.25 mg/mL), an immunologic method using polyclonal antibodies (0.6 mg/mL), and an immunologic method based on two monoclonal antibodies specific for the amino-terminus and carboxyl-terminus of the A alpha-chain (< 0.05 mg/mL). Using the two immunologic methods, it appeared that only 10% to 15% of the plasma fibrinogen of the heterozygous siblings was abnormal.     

A novel fibrinogen variant (fibrinogen Seoul II; AalphaGln328Pro) characterized by impaired fibrin alpha-chain cross-linking

We report a novel fibrinogen variant (fibrinogen Seoul II), which has a heterozygous point mutation from CAA to CCA leading to AalphaGln328Pro. The mutation site is among several glutamine residues that serve as alpha-chain cross-linking acceptor sites. Fibrinogen Seoul II was found in a 51-year-old male patient and his family in Seoul, Korea. The patient was diagnosed with myocardial infarction at age 43. Eight years later he was admitted to the emergency room due to recurrence of the disease, where he expired under treatment with tissue plasminogen activator (t-PA). Fibrin polymerization curves, made using purified fibrinogen from the patient's relatives, showed a decreased final turbidity, suggesting Seoul II fibrin clots are composed of thinner fibers. This supposition was verified using scanning electron microscopy. Alpha-polymer formation by the mutant fibrinogen upon thrombin treatment in the presence of factor XIII and calcium was distinctly impaired. This result confirms that the residue Aalpha328 plays a pivotal role in alpha-chain cross-linking.     

Clot retraction facilitates clot lysis

Platelet facilitation of clot lysis was studied using the dilute clot lysis assay, a standardized assay for fibrinolysis shown to correlate with the development of postoperative deep vein thrombosis. Clots prepared from dilute platelet poor plasma showed prolonged clot lysis when compared with clots prepared in a similar fashion from dilute platelet rich plasma. Since in the presence of platelets clot retraction or contraction occurred, we evaluated a possible direct contribution of retraction to clot lysis. Dilute platelet poor plasma clots were compacted by centrifugation, to a similar extent as that achieved during clot retraction in dilute platelet rich plasma. These clots now lysed at a rate that approached that seen with dilute platelet rich plasma clots. Using an alternate alternate approach, dilute platelet rich plasma clots were treated with cytochalasin B to prevent clot retraction. Such clots now showed prolonged lysis similar to that seen with dilute platelet poor plasma. The prolonged lysis of cytochalasin B treated dilute platelet rich plasma clots was corrected by artificial compaction of the clots. The results suggest that clot retraction markedly facilitates clot lysis, and shows that a major role of platelets to facilitate clot lysis is the effect of these cells to cause clot retraction.