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.     

Fibrinogen Matsumoto II: γ308Asn → Lys (AAT → AAG) mutation associated with bleeding tendency

Fibrinogen Matsumoto II is a hereditary dysfibrinogenaemia identified in a woman with Basedow's disease and a bleeding tendency. Coagulation tests of the patient's plasma revealed a prolonged thrombin time and a decreased fibrinogen level determined by functional method. Release of fibrinopeptide A and B was normal, whereas fibrin monomer polymerization was delayed. Fibrinogen γ-chain gene of the propositus was heterozygous for a missense mutation that resulted in Asn → Lys substitution at codon 308. Though the same amino acid substitution was also attributed to fibrinogen Kyoto I and Bicetre II, fibrinogen Matsumoto II showed different clinical manifestations from them.     

The rate of fibrinopeptide B release modulates the rate of clot formation: a study with an acquired inhibitor to fibrinopeptide B release

An asymptomatic 50-year-old male with a gamma globulin paraprotein was found to have prolonged prothrombin time, activated partial thromboplastin time, and thrombin time but a normal reptilase time. The prolonged clotting times were not the result of a factor deficiency because they were not corrected by the addition of normal plasma. Instead, this patient had an antibody that delayed thrombin-mediated fibrinopeptide B release thereby producing an apparent dysfibrinogenaemia. His isolated IgG prolonged the thrombin clotting time of both normal plasma and fibrinogen. Precincubation of his IgG with fibrinopeptide B, but not with fibrinopeptide A or thrombin, decreased its ability to prolong the thrombin clotting time. The patient's purified IgG but not control IgG delayed thrombin-mediated fibrinopeptide B release from fibrinogen without affecting the release of fibrinopeptide A. These studies define a novel, clinically silent dysfibrinogenaemia due to an antibody that delays thrombin-mediated fibrinopeptide B release from fibrinogen thereby markedly prolonging the clotting times.     

Fibrinogen Saint-Germain I: a case of the heterozygous Aalpha GLY 12 --> VAL fibrinogen variant.

A fibrinogen variant was suspected based on the results of routine coagulation tests in a 2-year-old asymptomatic child. Coagulation studies showed marked prolongation of both the thrombin and reptilase times, and discrepancy was noted between the level of plasma fibrinogen as measured by a kinetic versus immunological determination. Family studies revealed that the father beared the same abnormality. Studies of purified fibrinogen revealed an impaired release of both fibrinopeptides by thrombin. Fibrin monomer polymerization and fibrin stabilization were normal. DNA sequencing revealed a heterozygous G --> T point mutation in exon 2 of the gene coding for the Aalpha chain, which substituted a Gly for Val at position 12. Although the mutation is the same as in fibrinogen Rouen, fibrinogen Saint-Germain I shows a different fibrinopeptide release pattern and a mild factor V deficiency.     

Dysfibrinogenaemia Characterized by Abnormal Fibrin Monomer Polymerization and Normal Fibrinopeptide A Release

S ummary . Routine testing on plasma from a patient due to undergo a coronary artery bypass graft operation revealed a prolonged thrombin clotting time associated with a normal plasma fibrinogen level when this was determined by a method not dependent upon the rate of fibrin formation. Fibrinogen purified from the patient's plasma by precipitation with β-alanine also gave a prolonged thrombin time and this confirmed the presence of a dysfibrinogenaemia. Increasing calcium chloride concentration, addition of protamine sulphate and decreasing ionic strength all produced a partial correction of the clotting defect. Addition of normal plasma to patient's plasma failed to correct the prolonged thrombin clotting time and a pH dependence of the defect was also observed. Kinetic studies of fibrinopeptide release, using a specific radioimmunoassay, demonstrated no delay in the release of patient fibrinopeptide A. The functional defect was localized as an abnormality in the polymerization of fibrin monomers by studying fibrin monomers prepared and isolated from plasma and from purified fibrinogen solution. An electrophoretic examination of the patient's fibrinogen using both agarose and polyacrylamide gels failed to demonstrate any alteration in mobility or any structural defect associated with the polypeptide chains Aα, Bβ and γ. All seven of the living siblings of the propositus and also his daughter showed no abnormality in any clotting assay. However, because the propositus did not suffer from liver disease it has been assumed that the abnormality is genetic in origin.     

Fibrinogen "New York"--an abnormal fibrinogen associated with thromboembolism: functional evaluation.

A 54-yr-old woman presented with a 23-yr history of repeated life-threatening thromboembolism. The presence of a qualitatively abnormal fibrinogen was suggested by the demonstration of delayed and incomplete coagulation of plasma or partially purified fibrinogen by thrombin or Reptilase. Two brothers showed a similar in vitro defect but were clinically not affected. The plasma fibrinogen concentration was 0.50-1.64 mg/ml when estimated by heat turbidity, clottability, or immunologic techniques. The serum contained 80-820 mug/ml of unclottable fibrinogen-related materials even after 24 hr exposure to thrombin. The fibrinogen-related material in the serum showed faster anodal mobility an immunoelectrophoresis than that of normal plasma. Immunodiffusion studies with rabbit antihuman fibrinogen antiserum showed lines of identity between control plasma and the patient's plasma and serum. Studies of the kinetics of thrombin action on fibrinogen demonstrated impaired release of fibrinopeptide A and B and defective polymerization of preformed fibrin monomers. The maximum amount of fibrinopeptide A released by exhaustive treatment with thrombin was similar (per milligram protein) for both the patient's and control fibrinogen. This abnormal fibrinogen varient is tentatively designated fibrinogen "New York"; its possible identity with one of the previously described abnormal fibrinogens has not been excluded.     

Electrospray ionization mass spectrometry identification of fibrinogen Banks Peninsula (γ280Tyr→Cys): a new variant with defective polymerization

Fibrinogen Banks Peninsula was identified in the mother of a patient referred for investigation following recurrent epistaxis. Coagulation tests revealed prolonged thrombin and reptilase times and a decreased functional fibrinogen level. Thrombin-catalysed release of fibrinopeptides A and B was normal, and no abnormalities were detected by DNA sequencing of the regions encoding the thrombin cleavage sites in the Aα and Bβ genes. Reducing SDS-PAGE and reverse-phase HPLC analysis of purified fibrinogen chains were normal, as was electrospray ionization mass spectrometry (ESI-MS) analysis of isolated Aα and Bβ chains. However ESI-MS revealed a mass of 48 345 D for the isolated γ chains, 31 D less than the measured mass of control chains (48 376 D). Since normal and abnormal γ chains were not resolved, this implies a 60–62 D mass decrease in 50% of the molecules. A 60 D decrease was confirmed when DNA sequencing indicated heterozygosity for a mutation of Tyr→Cys at codon 280 of the γ chain gene. Fibrin monomer polymerization revealed a delayed lag phase and reduced final turbidity and although factor XIIIa crosslinking of fibrinogen was normal, it is likely that this delay is due to impaired D:D self association. Recent crystallographic studies show residues γ280 and γ275 make contact across the D:D interface, suggesting a similar mechanism for the polymerization defects in fibrinogens Banks Peninsula and Tokyo II (γ275Arg→Cys).     

An Abnormal Fibrinogen with Delayed Fibrinopeptide A Release

S ummary . Investigation of the family of a patient presenting with haematuria revealed seven cases in three generations showing a prolonged thrombin clotting time. A dysfibrinogenaemia was confirmed when purified fibrinogen from an affected member of the family was shown to also exhibit a prolonged thrombin clotting time. No molecular abnormality could be demonstrated using electrophor-etic and immunological techniques. However, using a specific radioimmunoassay to fibrinopeptide A a major defect has been localized to a delay in the rate of release of this peptide by thrombin when the abnormal fibrinogen is converted to fibrin. This case of dysfibrinogenaemia has been tentatively designated fibrinogen Manchester.     

Fibrinogen kaiserslautern III: a new case of congenital dysfibrinogenemia with aalpha 16 arg-->cys substitution.

An abnormal fibrinogen was identified in a man with suspicious prolonged prothrombin time and a mild bleeding tendency. Coagulation studies showed marked prolonged thrombin and reptilase clotting times and a discrepancy between functional fibrinogen test and fibrinogen antigen. The rate of fibrinopeptide B release by thrombin was slightly delayed while the release of fibrinopeptide A was only half the normal amount. DNA sequencing revealed a heterozygous C to T point mutation in position 1202 of exon 2 of the Aalpha chain, resulting in the substitution of Arg-->Cys at position 16, the thrombin cleavage site. This mutation was found also in his 2 children. Both had a mild bleeding tendency too.     

Two novel fibrinogen variants in the C-terminus of the Bβ-chain: fibrinogen Rokycany and fibrinogen Znojmo

Hereditary dysfibrinogenemia is a rare disorder wherein an inherited abnormality in fibrinogen structure may result in defective fibrin function and/or structure. Congenital hypofibrinogenemia is a rare autosomal bleeding disorder, either recessive or dominant, characterized by a low fibrinogen plasma level. A 28-year-old asymptomatic woman (fibrinogen Rokycany) and a 54-year-old man with thrombosis and pulmonary embolism (fibrinogen Znojmo) were investigated for a suspected fibrinogen mutation after abnormal coagulation tests results were obtained. DNA sequencing showed the heterozygous point mutation Bβ Asn351Lys in fibrinogen Rokycany and the heterozygous point mutation Bβ Arg237Ser in fibrinogen Znojmo, respectively. The kinetics of fibrinopeptide release was found to be normal in both cases. Fibrinolysis was impaired in the Znojmo variant. The average fibril diameters of Znojmo fibrin was slightly increased, but not differing significantly from normal; formed by less fibrils with abrupt fibril terminations. Rheological studies revealed a softer clot. Rokycany fibrin was formed by significantly narrower fibrils than normal fibrin; and the clot was denser than the control clot. Rheological studies revealed a stiffer clot. Impaired fibrinolysis and abnormal clot morphology may be the cause of thrombotic episodes in the patient with Znojmo mutation. New cases of hypofibrinogenemia and dysfibrinogenemia, found by routine coagulation testing, were genetically identified as a novel fibrinogen variants Bβ Asn351Lys (fibrinogen Rokycany) and Bβ Arg237Ser (fibrinogen Znojmo), respectively.     

Fibrinogen Baltimore II: congenital hypodysfibrinogenemia with delayed release of fibrinopeptide B and decreased rate of fibrinogen synthesis.

A congenital hypodysfibrinogenemia, fibrinogen Baltimore II, was found in a young asymptomatic Caucasian female. Prothrombin, partial thromboplastin, and euglobulin lysis times were normal, as were platelet function and coagulation factor assays. Subnormal plasma fibrinogen levels were found using chronometric, rate-independent, and immunologic assay methods. Kinetic analysis of fibrinopeptide release revealed a delay in the thrombin-catalyzed release of fibrinopeptide B from the abnormal protein. Proteolysis of fibrinopeptide A by thrombin or Arvin, fibrin monomer polymerization, and fibrin polymer ligation occurred at normal rates. Catabolism of radiolabeled autologous and homologous fibrinogen was also normal, but the fibrinogen synthetic rate was less than half the normal value. Comparison of the coagulation characteristics of fibrinogen Baltimore II with those of other abnormal fibrinogens indicates that it represents a unique example of hypodysfibrinogenemia.     

An Abnormal Inherited Fibrinogen (Fibrinogen Genova) with Delayed Fibrin Aggregation

A new autosomally inherited dysfibrinogenaemia was recognized in 3 members of an Italian family. No bleeding tendency or thrombotic disease in any of the affected members were demonstrated. Coagulation tests revealed prolonged prothrombin, thrombin and Reptilase times. Plasma fibrinogen levels were normal with immunologic method and slightly reduced with chrono-metric assay: the other blood coagulation factors were normal. In addition, cross-immuno-electrophoresis performed on patients' plasma was indistinguishable from the normal. Dysfibrinogenaemia was confirmed by studying the purified fibrinogen. The fibrin polymerization curve, measured spectrophotometrically, showed a lower slope than the normal. A delay in fibrin monomer aggregation was revealed when compared to the normal at an equal concentration. The release of fibrinopeptides was normal. SDS polyacrylamide gel electrophoresis, isoelectric focusing and cross-immunoelectrophoresis of purified fibrinogen were not able to demonstrate any structural abnormality. The fibrinogen was named fibrinogen Genova.     

Direct analysis of plasma fibrinogen-derived fibrinopeptides by high-performance liquid chromatography: investigation of nine congenital fibrinogen abnormalities

A simple method has been developed for the rapid analysis of fibrinopeptides contained on fibrinogen in small anticoagulated plasma samples. Following incubation with thrombin the plasma is diluted, boiled and then studied by high performance liquid chromatography (HPLC). The three forms of FPA (AP, A, AY) and two forms of FPB (B, des Arg B) can be identified and quantified in samples of less than 200 microliters. Additionally, the FPB peak height can be used to measure the plasma fibrinogen level. This method has been used to screen plasma samples with abnormal clotting times for possible congenital fibrinogen abnormalities. Results of the study of nine unrelated cases are presented. Four cases of congenital dysfibrinogenaemia were diagnosed directly from HPLC analysis alone. Fibrinogen Sheffield and Paris VI were identified as A alpha Arg 16----His substitutions and fibrinogens London VI and Madrid II were found to be heterozygous for an unknown substitution preventing thrombin cleavage at A alpha Arg 16. A case of dysfibrinogenaemia (fibrinogen Ashford) with a normal fibrinopeptide release stoichiometry was confirmed to have a primary polymerization abnormality using purified fibrin monomers. Similarly, a case of hypodysfibrinogenaemia (fibrinogen London V) had normal fibrinopeptides and a fibrin polymerization abnormality. In one case of hypofibrinogenaemia and two cases of afibrinogenaemia, no fibrinopeptide or functional abnormalities could be definitely established. This rapid and simple method of fibrinopeptide analysis is recommended for screening of plasma samples taken from patients suspected of having abnormalities of fibrinogen synthesis.     

Fibrinogen Manchester: identification of an abnormal fibrinopeptide A with a C-terminal arginine→histidine substitution

S ummary . Purified samples of fibrinogen Manchester, a congenital dysfibrinogenaemia with impaired fibrinopeptide A (FPA) release, were digested with thrombin. Amino acid sequencing of the fibrin showed that FPA had been completely released. High performance liquid chromatographic (HPLC) analysis of the clot supernatant showed the presence of a new peptide eluting ahead of the normal FPA. The amino acid composition and sequence of the new peptide established its identity as a variant of FPA containing histidine in position 16 instead of the usual arginine. The chromatograms from both siblings with the defect demonstrated that they were heterozygous for this clotting defect.     

Fibrinogen Milano XII: a dysfunctional variant containing 2 amino acid substitutions, Aalpha R16C and gamma G165R.

Fibrinogen Milano XII was detected in an asymptomatic Italian woman, whose routine coagulation test results revealed a prolonged thrombin time. Fibrinogen levels in functional assays were considerably lower than levels in immunologic assays. Polymerization of purified fibrinogen was strongly impaired in the presence of calcium or ethylenediaminetetraacetic acid (EDTA). Two heterozygous structural defects were detected by DNA analysis: Aalpha R16C and gamma G165R. As seen previously with other heterozygous Aalpha R16C variants, thrombin-catalyzed release of fibrinopeptide A was 50% of normal. Additionally, the release of fibrinopeptide B was delayed. Immunoblotting analysis with antibodies to human serum albumin indicated that albumin is bound to Aalpha 16 C. Sodium dodecyl sulfate-polyacrylamide gel electrophoresis (SDS-PAGE) analysis of plasmin digests of fibrinogen Milano XII in the presence of calcium or EDTA showed both normal and novel D1 and D3 fragments. Further digestion of abnormal D3 fragments by chymotrypsin resulted in degradation products of the same size as the fragments derived from normal fibrinogen. SDS-PAGE analysis under reducing conditions showed no difference between normal fibrinogen and fibrinogen Milano XII or between their plasmic fragments. Circular dichroism analysis revealed a shift in the mean residual ellipticity and a significant reduction of the alpha-helix content in the variant D3 fragment. It is concluded that the Aalpha-chain substitution is mainly responsible for the coagulation abnormalities, whereas the substitution in the gamma-chain induced a conformational change in the D3 fragment.     

A monoclonal antibody, specific for human fibrinogen, fibrinopeptide A- containing fragments and not reacting with free fibrinopeptide A

Spleen cells of BALB/c mice, immunized with fragments Y of normal human fibrinogen, were fused with P3 X 63 Ag 8653 myeloma cells. A clone was found which produces monoclonal antibodies (Mab-Y18) of the IgM kappa type. Mab-Y18 is immunoreactive with normal human fibrinogen, and its fragments X, Y, N-terminal disulphide knot, A alpha-chain, and A alpha stretch 1-51. The immunoreactivity with these same fragments disappears upon treatment with thrombin or arvin. This strongly suggests that fibrinopeptide A is an essential component of the Mab-Y18 epitope. This is supported by the finding that Mab-Y18 prolongs the thrombin and arvin clotting times of human fibrinogen by inhibition of the fibrinopeptide A release. More detailed information about the nature of the Mab-Y18 epitope was obtained from studies with genetic variants of human fibrinogen (especially fibrinogen Metz) and with fibrinogens from other mammalian species. These studies show that amino acid residue A alpha 16 (arginine) of fibrinopeptide A is essential for the Mab-Y18 epitope. Mab-Y18 does not react with free fibrinopeptide A.     

Fibrinogens Bern IV, Bern V and Milano XI: three dysfunctional variants with amino acid substitutions in the thrombin cleavage site of the Aalpha-chain.

Thrombin-induced cleavage of fibrinopeptide A is the initial step in the conversion of fibrinogen to fibrin. Three dysfunctional fibrinogen variants are described with an amino acid substitution at position 16 of the Aalpha-chain: the fibrinogen variants Bern IV and Milano XI having an Arg-->His substitution and the variant Bern V having an Arg-->Cys substitution. Routine coagulation studies revealed prolonged plasma thrombin and reptilase clotting times in all patients, and a discrepancy between the plasma levels of fibrinogen determined by the clotting assay and electroimmunoassay. The defect was localized by high-performance liquid chromatography analysis of fibrinopeptide release and confirmed by polymerase chain reaction and sequencing of exon 2 of the Aalpha-chain. Immunoblotting analysis with a rabbit antiserum against human serum albumin indicated that albumin was linked to the additional sulfhydryl group of fibrinogen Bern V. The assay of tissue-plasminogen-activator-induced plasmic degradation revealed that the fibrinolysis of fibrin Bern V was delayed, whereas fibrin Bern IV was digested in the same way as normal fibrin.     

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.     

Diagnosis,clinical features and molecular assessment of the dysfibrinogenaemias

Summary. Hereditary dysfibrinogenaemia is characterized by the presence of functionally abnormal plasma fibrinogen. Dysfibrinogenaemia is a heterogeneous disorder associated with different mutations throughout the three genes that code for the fibrinogen sub‐units, affecting many different aspects of fibrinogen/fibrin activity. Dysfibrinogenaemia may be discovered during the investigation of individuals who present with bleeding or thombosis, or may be found in individuals during routine coagulation screening. More specialized coagulation tests may confirm the diagnosis of dysfibrinogenaemia but do not reliably distinguish between the different fibrinogen variants and are not usually useful in predicting bleeding or thrombotic risk. Advances in molecular diagnostics have facilitated the investigation of the molecular causes of fibrinogen disorders. Several ‘hot spot’ areas have been identified where mutations causing a high proportion of cases of dysfibrinogenaemia are found (AαArg16 and γArg275). Molecular diagnostics have also shown that many fibrinogen variants share the same causative mutation. There is a discrepancy between the quality of the molecular and functional data available for each mutation and the clinical information on individuals and their family members. However, there are accumulating data that the ‘hot spot’ mutations accounting for 60–80% of cases of dysfibringenaemia are not associated with a significant bleeding or thrombosis in the absence of other risk factors. Rapid screening for these mutations may provide reassurance for patients in the presurgical setting.     

Fibrinogen Milano IV, another case of congenital dysfibrinogenemia with an abnormal fibrinopeptide A release (A alpha 16 Arg----His).

An abnormal fibrinogen, denoted as 'fibrinogen Milano IV', has been found in a 36-year-old woman without any bleeding manifestations or thrombotic tendency. Routine coagulation studies revealed prolonged thrombin and reptilase clotting times, very low plasma fibrinogen concentration determined by the functional assay but a normal fibrinogen concentration measured by the immunologic assay. Turbidity curves, measured following addition of thrombin to purified fibrinogen Milano IV, both in presence of calcium or EDTA, were markedly delayed. Release of fibrinopeptide B by thrombin was normal, whereas only half the normal amount of fibrinopeptide A was cleaved. The fibrinopeptide A peak of fibrinogen was preceded by an abnormal fibrinopeptide A*. Both peaks were collected for amino acid analysis which showed an exchange of arginine by histidine in position 16 of the A alpha chain of the fibrinopeptide A*.