Réka Gindele

Founder effect is responsible for the p.Leu131Phe heparin-binding-site antithrombin mutation common in Hungary: phenotype analysis in a large cohort

Essentials Antithrombin Budapest3 (ATBp3; p.Leu131Phe) causing heparin‐binding‐site defect is common. We studied the clinical and laboratory phenotype of a large Hungarian ATBp3 cohort (n = 102). Founder effect of ATBp3 was confirmed by 12 genetic markers; anti‐FXa AT assay was 100% sensitive. The spectrum of thrombotic symptoms was wide in ATBp3 patients including arterial thrombosis.

The superiority of anti-FXa assay over anti-FIIa assay in detecting heparin-binding site antithrombin deficiency.

OBJECTIVES Antithrombin is a progressive inhibitor of active factor X (FXa) and thrombin (FIIa). Its effect is 500- to 1,000-fold accelerated by heparin or heparan sulfate. Heterozygous type I (quantitative) and most type II (qualitative) antithrombin deficiencies highly increase the risk of venous thromboembolism (VTE), while homozygous mutations are lethal. The functional defect affecting the heparin-binding site confers moderate risk of VTE to heterozygous and high risk of VTE to homozygous individuals. METHODS Antithrombin activity assays based on the inhibition of FIIa and FXa were compared for their efficiency in detecting heparin-binding site defects. RESULTS With a single exception, in heterozygotes for heparin-binding site defects (n = 20), anti-FIIa activities remained in the reference interval, while anti-FXa activities were uniformly decreased. In individuals who were homozygous for heparin-binding site mutations (n = 9), anti-FIIa activities were in the range of 48% to 80%; the range of anti-FXa activities was 9% to 25%. Anti-FIIa and anti-FXa activities in type I deficiencies and type II pleiotropic deficiency did not differ significantly. CONCLUSIONS Anti-FXa antithrombin assay is recommended as a first-line test to detect type II heparin-binding site antithrombin deficiency.

Factor XIII B Subunit Polymorphisms and the Risk of Coronary Artery Disease

The aim of the case-control study was to explore the effect of coagulation factor XIII (FXIII) B subunit (FXIII-B) polymorphisms on the risk of coronary artery disease, and on FXIII levels. In the study, 687 patients admitted for coronary angiography to investigate suspected coronary artery disease and 994 individuals representing the Hungarian population were enrolled. The patients were classified according to the presence of significant coronary atherosclerosis (CAS) and history of myocardial infarction (MI). The F13B gene was genotyped for p.His95Arg and for intron K nt29756 C>G polymorphisms; the latter results in the replacement of 10 C-terminal amino acids by 25 novel amino acids. The p.His95Arg polymorphism did not influence the risk of CAS or MI. The FXIII-B intron K nt29756 G allele provided significant protection against CAS and MI in patients with a fibrinogen level in the upper tertile. However, this effect prevailed only in the presence of the FXIII-A Leu34 allele, and a synergism between the two polymorphisms was revealed. Carriers of the intron K nt29756 G allele had significantly lower FXIII levels, and FXIII levels in the lower tertile provided significant protection against MI. It is suggested that the protective effect of the combined polymorphisms is related to decreased FXIII levels.

Molecular characterization of p.Asp77Gly and the novel p.Ala163Val and p.Ala163Glu mutations causing protein C deficiency

INTRODUCTION Protein C (PC) is a major anticoagulant and numerous distinct mutations in its coding gene result in quantitative or qualitative PC deficiency with high thrombosis risk. Homozygous or compound heterozygous PC deficiency usually leads to life-threatening thrombosis in neonates. PATIENTS AND METHODS The molecular consequences of 3 different missense mutations of two patients have been investigated. The first patient suffered from neonatal purpura fulminans and was a compound heterozygote for p.Asp77Gly and p.Ala163Glu mutations. The second patient had severe deep venous thrombosis in young adulthood and carried the p.Ala163Val mutation. The fate of mutant proteins expressed in HEK cells was monitored by ELISA, by Western blotting, by investigation of polyubiquitination and by functional assays. Their intracellular localization was examined by immunostaining and confocal laser scanning microscopy. Molecular modeling and dynamics simulations were also carried out. RESULTS AND CONCLUSIONS The 163Val and 163Glu mutants had undetectable levels in the culture media, showed intracellular co-localization with the 26S proteasome and were polyubiquitinated. The 77Gly mutant was secreted to the media showing similar activity as the wild type. There was no difference among intracellular PC levels of wild type and mutant proteins. The 163Val and 163Glu mutations caused significant changes in the relative positions of the EGF2 domains suggesting misfolding with the consequence of secretion defect. No major structural alteration was observed in case of 77Gly mutant; it might influence the stability of protein complexes in which PC participates and may have an impact on the clearance of PC requiring further research.

Progressive chromogenic anti-factor Xa assay and its use in the classification of antithrombin deficiencies.

Abstract Background: Antithrombin (AT) is a slow-acting progressive inhibitor of activated clotting factors, particularly thrombin and activated factor X (FXa). However, the presence of heparin or heparan sulfate accelerates its effect by several magnitudes. AT deficiency, a severe thrombophilia, is classified as type I (quantitative) and type II (qualitative) deficiency. In the latter case mutations may influence the reactive site, the heparin binding-site (HBS) and exert pleiotropic effect. Heterozygous type II-HBS deficiency is a less severe thrombophilia than other heterozygous subtypes. However, as opposed to other subtypes, it also exists in homozygous form which represents a very high risk of venous thromboembolism. Methods: A modified anti-FXa chromogenic AT assay was developed which determines both the progressive (p) and the heparin cofactor (hc) activities, in parallel. The method was evaluated and reference intervals were established. The usefulness of the assay in detecting type II-HBS AT deficiency was tested on 78 AT deficient patients including 51 type II-HBS heterozygotes and 18 homozygotes. Results: Both p-anti-FXa and hc-anti-FXa assays showed excellent reproducibility and were not influenced by high concentrations of triglyceride, bilirubin and hemoglobin. Reference intervals for p-anti-FXa and hc-anti-FXa AT activities were 84%–117% and 81%–117%, respectively. Type II-HBS deficient patients demonstrated low (heterozygotes) or very low (homozygotes) hc-anti-FXa activity with normal or slightly decreased p-anti-FXa activity. The p/hc ratio clearly distinguished wild type controls, type II-HBS heterozygotes and homozygotes. Conclusions: Concomitant determination of p-anti-FXa and hc-anti-FXa activities provides a reliable, clinically important diagnosis of type II-HBS AT deficiency and distinguishes between homozygotes and heterozygotes.

Antithrombin Debrecen (p.Leu205Pro) – Clinical and molecular characterization of a novel mutation associated with severe thrombotic tendency

INTRODUCTION Hereditary antithrombin (AT) deficiency is a rare thrombophilic disorder with heterogeneous genetic background and various clinical presentations. In this study we identified a novel AT mutation. Genotype-phenotype correlations, molecular characteristics and thrombotic manifestations of the mutation were investigated. MATERIALS AND METHODS Thirty-one members of a single family were included. Clinical data was collected regarding thrombotic history. The mutation was identified by direct sequencing of the SERPINC1 gene. HEK293 cells were transfected with wild type and mutant SERPINC1 plasmids. Western blotting, ELISA and functional amidolytic assay were used to detect wild type and mutant AT. After double immunostaining, confocal laser scanning microscopy was used to localize mutant AT in the cells. Molecular modeling was carried out to study the structural-functional consequences of the mutation. RESULTS Unprovoked venous thrombotic events at early age, fatal first episodes and recurrences were observed in the affected individuals. The median AT activity was 59%. Genetic analysis revealed heterozygous form of the novel mutation p.Leu205Pro (AT Debrecen). The mutant AT was expressed and synthesized in HEK293 cells but only a small amount was secreted. The majority was trapped intracellularly in the trans‑Golgi and 26S proteasome. The mutation is suspected to cause considerable structural distortion of the protein. The low specific activity of the mutant AT suggested functional abnormality. CONCLUSIONS AT Debrecen was associated with very severe thrombotic tendency. The mutation led to misfolded AT, impaired secretion and altered function. Detailed clinical and molecular characterization of a pathogenic mutation might provide valuable information for individualized management.

Clinical and laboratory characteristics of antithrombin deficiencies: A large cohort study from a single diagnostic center

INTRODUCTION Inherited antithrombin (AT) deficiency is a heterogeneous disease. Due to low prevalence, only a few studies are available concerning genotype-phenotype associations. The aim was to describe the clinical, laboratory and genetic characteristics of AT deficiency in a large cohort including children and to add further laboratory data on the different sensitivity of functional AT assays. PATIENTS AND METHODS Non-related AT deficient patients (n=156) and their family members (total n=246) were recruited. Clinical and laboratory data were collected, the mutation spectrum of SERPINC1 was described. Three different AT functional assays were explored. RESULTS Thirty-one SERPINC1 mutations including 11 novel ones and high mutation detection rate (98%) were detected. Heparin binding site deficiency (type IIHBS) was the most frequent (75.6%) including AT Budapest3 (ATBp3), AT Padua I and AT Basel (86%, 9% and 4% of type IIHBS, respectively). Clinical and laboratory phenotypes of IIHBS were heterogeneous and dependent on the specific mutation. Arterial thrombosis and pregnancy complications were the most frequent in AT Basel and AT Padua I, respectively. Median age at the time of thrombosis was the lowest in ATBp3 homozygotes. The functional assay with high heparin concentration and pH7.4 as assay conditions had low (44%) sensitivity for ATBp3 and it was insensitive for AT Basel and Padua I. CONCLUSION Type IIHBS deficiencies behave differently in clinical and laboratory phenotypes from each other and from other AT deficiencies. Heparin concentration and pH seem to be the key factors influencing the sensitivity of AT functional assays to IIHBS.

Evidence for the founder effect of a novel ACVRL1 splice-site mutation in Hungarian hereditary hemorrhagic telangiectasia families

Fig. 1. Pedigree of HHT families sharing the ACVRL1 c.625+1 G>C mutation. (a) The correspondent haplotype of all 14 HHT patients at the affected chromosome region. (b) The pedigree of the five families exhibiting the common ancestor. Probands are marked with arrows. Blackened individuals are affected, either by carrying the mutation and/or having definite HHT. In the upper left index †, definite HHT; *, deceased or unavailable patient with epistaxis and telangiectases by hearsay; #, individual presumably affected by the inheritance of HHT. In the upper right index M, ACVRL1 c.625+1 G>C mutation; w, ACVRL1 wild type; u, patient unavailable for genetic screening. Grey symbols represent equivocal HHT status. In Eger, Hungary, recruitment of HHT patients living in our institution’s attendance area (population of 407.000) was started in 2012. Patient recruitment and investigation are described in Appendix S1, Supporting information. So far, we found four different ENG mutations in five families, whereas, only one, yet unpublished, ACVRL1 mutation was observed in five apparently unrelated families. Arguments supporting a possible founder effect of the latter mutation are discussed.