Fibrinopeptide A release is necessary for effective B:b interactions in polymerisation of variant fibrinogens with impaired A:a interactions

Fibrin polymerisation is mediated by interactions between knobs 'A' and 'B' exposed by thrombin cleavage, and holes 'a' and 'b'. We demonstrated markedly delayed thrombin-catalysed fibrin polymerisation, through B:b interactions alone, of recombinant gamma D364H-fibrinogen with impaired hole 'a'. To determine whether recombinant variant fibrinogens with no release of fibrinopeptide A (FpA) polymerise similarly to gamma D364H-fibrinoge, we examined two variant fibrinogens with substitutions altering knob 'A', A alpha 17A- and A alpha 17C-fibrinogen. We examined thrombin- or batroxobin-catalysed fibrinopeptide release by HPLC, fibrin clot formation by turbidity and fibrin clot structure by scanning electron microscopy (SEM) and compared the results of the variants with those for gamma D364H-fibrinogen. Thrombin-catalysed FpA release of A alpha 17A-fibrinogen was substantially delayed and none observed for A alpha 17C-fibrinogen; fibrinopeptide B (FpB) release was delayed for all variants. All variant fibrinogens showed substantially impaired thrombin-catalysed polymerisation; for A alpha 17A-fibrinogen it was delayed less, and for A alpha 17C more than for gamma D364H-fibrinogen. No variants polymerised with batroxobin, which exposed only knob 'A'. The inhibition of variant fibrinogens' polymerisation was dose-dependent on the concentration of either GPRP or GHRP, and both peptides that block holes 'b'. SEM showed that the variant clots from A alpha 17A- and gamma D364H-fibrinogen had uniform, ordered fibres, thicker than normal, whereas A alpha 17C-fibrinogen formed less organised clots with shorter, thinner, and tapered ends. These results demonstrate that FpA release per se is necessary for effective B:b interactions during polymerisation of variant fibrinogens with impaired A:a interactions.ArticleTHROMBOSIS AND HAEMOSTASIS. 109(2):221-228 (2013)journal articl

Nonsense-mediated mRNA decay was demonstrated in two hypofibrinogenemias caused by heterozygous nonsense mutations of FGG, Shizuoka III and Kanazawa II

We report two novel hypofibrinogenemias, Shizuoka III and Kanazawa II, which are caused by heterozygous mutations in FGG. Shizuoka III showed c.147delT and 147_149insACA in FGG exon 3 and a subsequent frameshift mutation, resulting in mature protein γ23X (native protein: γ49X), and Kanazawa II showed c.1205G>A in FGG exon 9, resulting in γ376X (native protein: γ402X). To determine whether the truncated γ-chains, γ23X and γ376X, were synthesized and participated in the assembly of fibrinogen, mutant-type cDNA vectors were transfected into Chinese hamster ovary (CHO) cells. Significant levels of mutant fibrinogen were not detected by ELISA in the culture media and cell lysates. Immunoblot analysis of cell lysates revealed that the mutant γ-chain of γ376X was observed but intact fibrinogen was not. On the other hand, mutant γ-chain was not observed in γ23X-expressing cells. To demonstrate the involvement of the mechanisms of nonsense-mediated mRNA decay (NMD), we cloned wild- and mutant-type mini-genes containing γ23 or γ376 codon and transfected these into CHO cell lines in the absence or presence of cycloheximide as an NMD inhibitor. mRNA levels were determined using real-time quantitative RT-PCR in CHO cells. In the absence of cycloheximide, levels of mRNAs transcribed from the mutant gene were lower than from the wild-type gene whereas, in the presence of cycloheximide, levels of mRNAs transcribed from the mutant gene increased dose-dependently. Finally, these results demonstrated that mRNAs containing γ23X or γ376X are degraded by the NMD system and translation of the truncated γ-chain polypeptide decrease in patients' hepatocytes, resulting in hypofibrinogenemias.ArticleTHROMBOSIS RESEARCH. 132(4):465-470 (2013)journal articl

γD318Y fibrinogen shows no fibrin polymerization due to defective "A-a" and "B-b" interactions, whereas that of γK321E fibrinogen is nearly normal

ArticleThrombosis research. 182: 150-158. (2019)journal articl

Nonsense-mediated mRNA decay was demonstrated in two hypofibrinogenemias caused by heterozygous nonsense mutations of FGG, Shizuoka III and Kanazawa II

We report two novel hypofibrinogenemias, Shizuoka III and Kanazawa II, which are caused by heterozygous mutations in FGG. Shizuoka III showed c.147delT and 147_149insACA in FGG exon 3 and a subsequent frameshift mutation, resulting in mature protein γ23X (native protein: γ49X), and Kanazawa II showed c.1205G>A in FGG exon 9, resulting in γ376X (native protein: γ402X). To determine whether the truncated γ-chains, γ23X and γ376X, were synthesized and participated in the assembly of fibrinogen, mutant-type cDNA vectors were transfected into Chinese hamster ovary (CHO) cells. Significant levels of mutant fibrinogen were not detected by ELISA in the culture media and cell lysates. Immunoblot analysis of cell lysates revealed that the mutant γ-chain of γ376X was observed but intact fibrinogen was not. On the other hand, mutant γ-chain was not observed in γ23X-expressing cells. To demonstrate the involvement of the mechanisms of nonsense-mediated mRNA decay (NMD), we cloned wild- and mutant-type mini-genes containing γ23 or γ376 codon and transfected these into CHO cell lines in the absence or presence of cycloheximide as an NMD inhibitor. mRNA levels were determined using real-time quantitative RT-PCR in CHO cells. In the absence of cycloheximide, levels of mRNAs transcribed from the mutant gene were lower than from the wild-type gene whereas, in the presence of cycloheximide, levels of mRNAs transcribed from the mutant gene increased dose-dependently. Finally, these results demonstrated that mRNAs containing γ23X or γ376X are degraded by the NMD system and translation of the truncated γ-chain polypeptide decrease in patients' hepatocytes, resulting in hypofibrinogenemias.ArticleTHROMBOSIS RESEARCH. 132(4):465-470 (2013)journal articl

Screening method for congenital dysfibrinogenemia using clot waveform analysis with the Clauss method

ArticleInternational journal of laboratory hematology. 43(2): 281-289(2021)journal articl

siRNA down-regulation of FGA mRNA in HepG2 cells demonstrated that heterozygous abnormality of the A alpha-chain gene does not affect the plasma fibrinogen level

Introduction: We encountered two afibrinogenemia patients with homozygous and compound heterozygous FGA mutation. Of interest, the patients' parents, who are heterozygous, had normal levels of plasma fibrinogen; thus, we hypothesized that liver FGA mRNA levels were higher than those of FGB and/or FGG mRNA. Materials and Methods: To test the hypothesis, we quantitated mRNA levels of a normal liver and a human hepatocyte cell line, HepG2 cells, and performed siRNA-mediated down-regulation of the fibrinogen gene in HepG2 cells. mRNA levels were determined using real-time quantitative RT-PCR for three normal livers and HepG2 cells. Down-regulation of FGA, FGB, or FGG in HepG2 cells was performed by the addition of siRNA corresponding to each of the three genes, and the mRNA levels determined in the cells and the secreted fibrinogen concentration in media. Results: The mRNA level of normal human liver was FGA=FGB>FGG and the FGG mRNA level was about 2-fold lower than the others, that of HepG2 cells was FGA>FGG>FGB and FGA mRNA was approximately 2- or 4-fold higher than FGG mRNA and FGB mRNA. When FGA, FGB, or FGG mRNA expression levels were down-regulated by nearby 50%, fibrinogen concentrations in media were 78%, 49%, or 57% of the control, respectively. Conclusions: Our results suggest that FGG mRNA levels limit fibrinogen expression in normal liver and HepG2 cells and that 50% reduction of FGA mRNA levels would not limit fibrinogen expression in normal liver and HepG2 cells.ArticleTHROMBOSIS RESEARCH. 131(4):342-348 (2013)journal articl

Fibrin monomers derived from thrombogenic dysfibrinogenemia, Naples-type variant (BβAla68Thr), showed almost entirely normal polymerization

ArticleTHROMBOSIS RESEARCH.172:1-3(2018)journal articl

Recombinant γY278H Fibrinogen Showed Normal Secretion from CHO Cells, but a Corresponding Heterozygous Patient Showed Hypofibrinogenemia

ArticleInternational journal of molecular sciences. 22(10): 5218(2021)journal articl

Heterozygous Variant Fibrinogen γA289V (Kanazawa III) Was Confirmed as Hypodysfibrinogenemia by Plasma and Recombinant Fibrinogens

Introduction: Congenital fibrinogen disorders are classified as afibrinogenemia, hypofibrinogenemia, dysfibrinogenemia, and hypodysfibrinogenemia. However, difficulties are associated with discriminating between dysfibrinogenemia, hypofibrinogenemia, and hypodysfibrinogenemia using routine analyses. We previously reported a heterozygous variant fibrinogen (γA289V; Kanazawa III) as hypodysfibrinogenemia; however, the same variant had previously been described as hypofibrinogenemia. To clarify the production of γA289V fibrinogen, we expressed recombinant γA289V (r-γA289V) fibrinogen and compared it with wild-type (WT) and adjacent recombinant variant fibrinogens. Methods: Target mutations were introduced into a fibrinogen γ-chain expression vector by site-directed mutagenesis, and the vector was then transfected into Chinese hamster ovary cells to produce recombinant fibrinogen. Fibrinogen was purified from the plasma of the proposita, and culture media and fibrinogen functions were analyzed using fibrin polymerization, plasmin protection, and FXIIIa-catalyzed fibrinogen cross-linking. Results: The fibrinogen concentration ratio of the culture media to cell lysates was markedly lower for r-γA289V fibrinogen than for WT. Because the secretion of recombinant γF290L (r-γF290L) fibrinogen was similar to WT, we compared r-γF290L fibrinogen functions with WT. The fibrin polymerization of Kanazawa III plasma (K-III) fibrinogen was significantly weaker than normal plasma fibrinogen. Moreover, K-III fibrinogen showed a markedly reduced “D:D” interaction. However, all functions of r-γF290L fibrinogen were similar to WT. An in silico analysis confirmed the above results. Conclusion: The present results demonstrated that γA289 is crucial for the γ-module structure, and the γA289V substitution markedly reduced fibrinogen secretion. Moreover, K-III fibrinogen showed markedly reduced fibrin polymerization and “D:D” interactions. γA289V fibrinogen was confirmed as hypodysfibrinogenemia.ArticleINTERNATIONAL JOURNAL OF LABORATORY HEMATOLOGY.42(2):190-197(2020)journal articl

A novel frameshift mutation in the fibrinogen γC terminal region, FGG c.1169_1170 del AT, leading to hypofibrinogenemia

ArticleTHROMBOSIS RESEARCH.159:82-85(2017)journal articl