A frameshift mutation in Exon V of the A alpha-chain gene leading to truncated A alpha-chains in the homozygous dysfibrinogen Milano III.

An inherited dysfunctional fibrinogen variant, denoted as fibrinogen Milano III, was found in a 13-year-old girl suffering from recurrent venous thrombosis. Plasma of the patient exhibited prolonged thrombin time and Reptilase time. Polymerization of fibrin monomers in the presence and absence of calcium ions was strongly impaired. SDS-polyacrylamide gel electrophoresis of reduced fibrinogen showed normal B beta- and gamma-chains, whereas no normal A alpha-chain was detected in the proposita. Immunoblot analysis with the monoclonal antibody Y18, detecting an epitope within the stretch of amino acids A alpha 1-51, revealed an A alpha-chain of about 50 kDa with an intact amino terminus. Immunoblotting with antibodies directed against serum albumin demonstrated the presence of albumin covalently linked to fibrinogen via a disulfide bridge. The structural defect of fibrinogen Milano III was determined by sequence analysis of a single-stranded fragment of genomic DNA amplified by polymerase chain reaction. An insertion of a thymine in the exon V of the A alpha-chain gene after the triplet ATT coding for IleA alpha 451 altered the reading frame and caused premature termination of the protein synthesis (Trp452(TGG)-Ser453(TCC)-Stop454(TGA)). In both parents, normal and mutant alleles were established, leading to duplication of the sequence pattern after the thymine insertion site, whereas the proposita is homozygous for the new mutation in the fibrinogen A alpha-chain gene.

A new substitution, gamma 358 Ser-->Cys, in fibrinogen Milano VII causes defective fibrin polymerization.

Fibrinogen Milano VII is a hereditary fibrinogen variant detected in a woman with no clinical symptoms of bleeding or thrombosis. Thrombin and reptilase clotting times were prolonged in six family members from three generations. Release of fibrinopeptides A and B was normal. Fibrin polymerization was strongly delayed both in the presence and in the absence of calcium. The structural defect was determined by sequence analysis of a 290-bp fragment of genomic DNA amplified by polymerase chain reaction and cloned in M13mp19. The triplet TCT coding for the amino acid residue gamma 358 was found to be replaced by TGT, resulting in the substitution gamma 358 Ser-->Cys. Immunoblot analysis demonstrated the presence of covalently linked fibrinogen albumin and fibrinogen (albumin)2 complexes. Albumin was released from fibrinogen Milano VII by limited reduction with 2-mercaptoethanol. Fibrin polymerization was not normalized after removal of albumin from fibrinogen Milano VII, suggesting that the delayed clot formation is not due to steric hindrance caused by bound albumin but by substitution of gamma 358 Ser by Cys itself. Our results indicate that the residue gamma 358 Ser is essential for normal expression of the carboxy terminal polymerization site on the fibrinogen gamma-chain.

Fibrinogen Milano V: a congenital dysfibrinogenaemia with a gamma 275 Arg-->Cys substitution.

An abnormal fibrinogen was discovered in a clinically asymptomatic woman from Italy. Routine coagulation studies revealed prolonged thrombin and reptilase clotting times and a discrepancy between the plasma fibrinogen levels determined by the clotting assay and electroimmunoassay. Release of fibrinopeptides A and B from fibrinogen Milano V by thrombin was normal. Fibrin polymerization was strongly delayed in the presence of EDTA and was partially corrected at physiological calcium concentration. Normal migration of mercaptolysed polypeptide chains was observed in polyacrylamide gel electrophoresis in the presence of sodium dodecyl sulphate. Moreover, there was no apparent abnormality in the charge of the reduced chains of the variant fibrinogen, as judged by two-dimensional gel electrophoresis. A fragment of the gamma-chain gene coding for the amino acids 259-350 was amplified and cloned. The amino acid gamma 275 arginine was found to be substituted by cysteine. Immunoblotting analysis with a rabbit antiserum against human serum albumin indicated that albumin was not linked to the odd sulphydryl group of fibrinogen Milano V. Treatment of fibrinogen Milano V with cysteamine, that is surmised to convert the mutant cysteine to a positively charged lysine analogue, did not improve the clotting properties of fibrinogen Milano V.

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*.

Fibrinogen Milano. VI: A heterozygous dysfibrinogenemia (A alpha 16 Arg----His) with bleeding tendency.

Congenital heterozygous dysfibrinogenemia was diagnosed in a young woman with bleeding tendency. 3 other asymptomatic members of her family (mother and the 2 sisters) had abnormal fibrinogen. The proposita's plasma exhibited prolonged thrombin and reptilase times. Plasma fibrinogen concentration determined by functional assay was 0.3 g/l, whereas immunologic assay revealed normal fibrinogen levels. Turbidity curves, representing the rate of thrombin-induced fibrin formation, were markedly delayed both in the presence and absence of Ca2+. Isoelectric focusing and SDS electrophoresis of reduced fibrinogen showed normal charge and size of the subunit chains. Release of fibrinopeptide B by thrombin was normal, whereas HPLC elution diagrams of fibrinopeptide A showed an abnormal peak A* with a slightly shorter retention time than the normal fibrinopeptide A. The amino acid analysis showed that the arginine in peak A* is replaced by histidine (A alpha 16 Arg----His).

Fibrinogen Geneva, a new case of A alpha 16 Arg----Cys dysfibrinogenaemia.

A new congenital variant of fibrinogen, from which only half the normal amount of fibrinopeptide A can be released by thrombin, was found in three members of a family having no major bleeding or thrombotic tendency. Following carboxamidomethylation of the reduced fibrinogen chains, an abnormal peptide was cleaved by thrombin from the amino terminus of the A alpha-chain (A* alpha 1-19) and isolated by reversed phase high-performance liquid chromatography. Amino acid analysis indicated the presence of carboxymethyl cysteine in this A alpha-chain fragment which in normal fibrinogen is devoid of cysteine. We conclude that fibrinogen Geneva is another fibrinogen variant with the substitution A alpha 16 Arg----Cys.

Isolation of fibrinogen A alpha-chain by affinity chromatography on concanavalin A-sepharose.

A method was developed for isolation of the A alpha-chain from S-carboxamidomethylated fibrinogen. A mixture of the three constituent polypeptide chains of human fibrinogen was applied onto a column of concanavalin A-Sepharose. While the carbohydrate-free A alpha-chain was not delayed on the affinity chromatography column, both glycosylated subunit chains, B beta- and gamma-chain, were adsorbed to the insolubilized lectin and were quantitatively eluted from the column with 0.2 M methyl-alpha-D-mannoside. SDS-electrophoresis on polyacrylamide gel was employed for analysis of chromatographic fractions. Complete recovery of the A alpha-chain was observed. The described procedure is very simple and permits isolation of large amounts of pure A alpha-chain from S-carboxyamidomethylated fibrinogen.