Antithrombin Antigen Levels Research Articles

Effect of Antithrombin Leakage From Hemodialysis Therapy on Antithrombin Hemodynamics.

Introduction Hemodialysis (HD) therapy is a crucial treatment for patients with renal failure but can impact the hemodynamics of antithrombin (AT), a protein essential for regulating hemostasis and preventing thrombosis. Reduced AT activity can lead to thrombus formation at unusual sites and increase the risk of recurrent venous thromboembolism. The loss of AT during HD or hemodiafiltration (HDF) through leakage or adsorption onto dialysis membranes has not been fully investigated, and its effects on AT hemodynamics remain unclear. We aimed to elucidate the mechanisms underlying AT activity reduction due to dialysis, with the goal of developing dialysis protocols that preserve AT activity and reduce the risk of vascular access-related thrombosis. Methods AT activity and antigen levels were measured before and after dialysis therapy in 24 patients undergoing maintenance dialysis at Itaya Clinic (HD, 12; HDF, 12). AT antigen levels in dialysis effluent were also measured to analyze the effects of dialysis on AT hemodynamics. Additionally, immunofluorescence staining of dialysis membranes was used to semi-quantitatively assess the amount of AT adsorbed onto the membrane. Results AT activity and antigen levels in patients undergoing HD were significantly lower than those in healthy participants but increased following dialysis. A negative correlation was found between dialysis vintage (history of heparin use) and predialysis AT activity. AT leakage and adsorption were significantly greater with HDF than with HD. However, no correlation was observed between AT leakage and activity or antigen levels before and after dialysis. Conclusions AT activity and antigen levels were decreased in patients on HD, with long-term heparin use suggested as a contributing factor. Additionally, AT leakage was observed during HDF therapy, indicating that dialysis-related AT leakage may contribute to decreased AT activity and antigen levels. Therefore, regular measurement of AT activity is recommended for patients with HD. If AT activity decreases, treatment adjustments, such as switching to HD therapies that minimize AT leakage and adsorption, should be considered.

Functional analysis of two abnormal antithrombin proteins with different intracellular kinetics

IntroductionHereditary antithrombin (AT) deficiency type I causes venous thrombosis due to decreased levels of AT antigen in the blood. We identified one novel and one known abnormal variant in two unrelated Japanese families with venous thrombosis. In this study, we analyzed the mechanism by which these abnormal variants cause type I AT deficiency. Materials and methodsWild-type and variant AT expression vectors were constructed and transiently expressed in human embryonic kidney 293 cells, and AT antigen levels and N-glycosylation of cell lysates and culture medium were evaluated by western blot analysis. Subcellular co-localization of AT was also examined using confocal microscopy, and chase experiments with cycloheximide and MG132 were performed to investigate the degradation pathway of AT variants. ResultsGenetic analysis identified a novel variant, c.613delC (p.Leu205Trpfs⁎79), and the known variant c.283T>C (p.Tyr95His). These AT variants exhibited significantly reduced extracellular secretion compared with the wild-type; N-glycosylation of the AT protein was normal. Co-localization analysis suggested that the transport of these abnormal AT proteins to the Golgi apparatus was impaired. The c.613delC variant was degraded early by the proteasome, suggesting that the c.283T>C variant is stored in the endoplasmic reticulum (ER). ConclusionsThe AT variants identified here synthesize abnormal AT proteins that exhibit suppressed secretion and impaired transport from the ER to the Golgi apparatus. These results provide clues that could help elucidate the mechanism of type I AT deficiency and facilitate therapy development.

Antithrombin p.Thr147Ala: The First Founder Mutation in People of African Origin Responsible for Inherited Antithrombin Deficiency.

Hereditary antithrombin deficiency is a rare autosomal-dominant disorder predisposing to recurrent venous thromboembolism (VTE). To date, only two founder mutations have been described. We investigated the antithrombin p.Thr147Ala variant, found in 12 patients of African origin. This variant is known as rs2227606 with minor allele frequency of 0.5% in Africans and absent in Europeans. A possible founder effect was investigated. Phenotypical characterization was established through immunological and functional methods, both under basal and stress conditions. Recombinant antithrombin molecules were constructed by site-directed mutagenesis and expressed in HEK-293T cells. Secreted antithrombin was purified and functionally characterized. Structural modeling was performed to predict the impact of the mutation on protein structure. A novel nanopore sequencing approach was used for haplotype investigation. Ten patients experienced VTE, stroke, or obstetric complications. Antithrombin antigen levels and anti-IIa activity were normal or slightly reduced while anti-Xa activity was reduced with only one commercial assay. On crossed immunoelectrophoresis, an increase of antithrombin fractions with reduced heparin affinity was observed under high ionic strength conditions but not under physiological conditions. The recombinant p.Thr147Ala protein displayed a reduced anti-Xa activity. Structural modeling revealed that residue Thr147 forms three hydrogen bonds that are abolished when mutated to alanine. The investigated patients shared a common haplotype involving 13 SERPINC1 intragenic single nucleotide polymorphisms. Antithrombin p.Thr147Ala, responsible for antithrombin type II heparin binding site deficiency, is the first founder mutation reported in people of African ancestry. This study further emphasizes the limitations of commercial methods to diagnose this specific subtype.

Identification of a new SERPINC1 mutation in a Kazak family that alters the heparin binding capacity of antithrombin

IntroductionGiven its central role in mediating heparin-induced anti-coagulation, antithrombin (AT) gene mutations may result in heparin resistance. This study investigates the relationship between familial AT gene mutations and tolerance to heparin. MethodsThe medical history of a male patient with heparin resistance who received heart surgery and six of his family members was reviewed. Activated partial thromboplastin time (APTT), prothrombin time (PT), fibrinogen (Fib), D-dimer (D=D), and platelet count were determined to assess coagulation function. AT activity and the AT gene were also analyzed. For the newly identified gene mutations, polymorphisms were excluded in 120 healthy Kazak controls. ResultsTwo mutations were identified in exon 7 of the AT gene, SERPINC1: g.1267G>A (p.A391T) found in five participants, including the index patient, and g.1334G>A, a silent mutation, in two family members. The g.1267G>A mutation may alter focal AT protein conformation. Neither of these mutations was observed in the healthy Kazak controls. Although all coagulation parameters and AT activity were within the normal ranges for the index patient and his family members, the platelet levels were significantly lower than that observed for the healthy Kazak controls (p=0.001). There was no significant difference in AT antigen levels between the groups; however, participants with the g.1267G>A mutation had a 44.25% reduction in heparin binding compared to the control group (p<0.001). ConclusionWe identified a novel hereditary mutation, g.1267G>A (p.A391T), in the AT gene, which reduces its heparin binding capacity and might be associated with resistance to heparin.

Clinical presentation and molecular basis of congenital antithrombin deficiency in children: a cohort study

In this study we report the largest descriptive cohort of congenital antithrombin (AT) deficiency in children, its clinical presentation, molecular basis and genotype-phenotype correlation. Paediatric patients diagnosed with AT deficiency at two tertiary care children's hospitals over a 10-year period were retrospectively reviewed. SERPINC1 gene sequencing was offered to subjects who did not already have the test performed. Molecular modelling and stability simulations were performed for the novel mutations identified. Twenty-nine subjects from 18 pedigrees were identified. Mean age (± standard deviation) at diagnosis and mean duration of follow-up were 8.4 (± 6.6 years and 6.6 (± 5.7 years respectively. Most recent mean AT activity and AT antigen levels (n = 20) were 0.5 (± 0.0) iu/ml and 0.6 (± 0.1) iu/ml respectively. Ten subjects were diagnosed secondary to low AT activity measured following venous thrombo-embolism (VTE). All 10 subjects had additional risk factors at the time of VTE. None of the 19 subjects diagnosed with AT deficiency in the setting of positive family history have had VTE with 7.4 (± 5.8) years follow-up. Mutation analysis has been completed on 19 subjects from 16 pedigrees. Nine unique mutations, including 4 novel mutations were identified.

Antithrombin-p.Ala416Pro: The Second Reported Case in Japan

A 42-year-old man was referred to our department due to recurrent deep venous thrombosis. He, his father and his aunt had low antithrombin (AT) heparin cofactor activity and progressive AT activity levels with normal AT antigen levels. A single nucleotide substitution of G to C was found at nucleotide position c.1246 in exon 7 of the patient's AT gene, resulting in a p.Ala416Pro mutation of AT. The same mutation was identified in his father and aunt, but not his sister, who had a normal AT level. These results show that the AT-p.Ala416Pro mutation was responsible for type IIa AT deficiency in this family.

Clinical and Molecular Profile Of Hereditary Antithrombin (AT) Deficiency: A Single Institution Cohort

IntroductionHereditary antithrombin (AT) deficiency is an autosomal dominant thrombophilia. It is classified into type 1 (quantitative) or type 2 (qualitative) deficiency based on the AT antigen and activity levels (Haemophilia 2008:14; 1229). The goal of this study was to correlate clinical phenotype with AT molecular defects. MethodsAfter IRB approval, patients with a diagnosis of hereditary AT deficiency established at the Mayo Clinic, Rochester, were identified from the clinical database (1997-2012). AT activity was assayed by a chromogenic Factor Xa assay and AT antigen level was assayed by latex immunoassay. Peripheral blood leukocyte genomic DNA was extracted using standard methods.PCR-amplification and ABI BigDye Terminator cycle sequencing kit was performed for all SERPINC1 exons, intronic splicing regions and the 3'UTR. SERPINC1 sequence was analyzed using Mutation Surveyor software (SoftGenetics). Clinical data were obtained from patient interview and medical record review. An event was defined as an episode of venous thromboembolism (VTE), including deep vein thrombosis and/or pulmonary embolism; arterial thrombosis, including cerebrovascular event and/or myocardial infarction, and an obstetric event, including miscarriages and/or spontaneous abortions. Statistical analysis was performed with SAS 9.1.3 (SAS Institute Inc. Cary, NC). ResultsOf 30 patients with hereditary AT deficiency; sequence data was available on 22. Twenty-nine (97%) patients were white, and 19 (63%) were females. Six patients (20%) were smokers and 9 (30%) had a body mass index of >30. Based on the AT activity and antigen levels, 18 (81%) had type 1 AT deficiency, while the remainder had type 2. Eleven patients were heterozygous for six novel (all type 1) mutations. One patient was also a homozygous carrier for the Factor V Leiden mutation.The median age at first thrombotic event was 24.4 years (range, 16.2-70.7), and the median age at diagnosis of AT deficiency was 40.7 years (range, 17.8-76). Both, the median ages at first thrombotic event and at diagnosis were comparable in type 1 versus type 2 AT deficiency patients (P=0.52 and 0.97 respectively). Thirteen patients (43%) had unprovoked thrombotic events. Majority had VTE (n=21, 70%), which included one patient each with splanchnic venous thrombosis, and cerebral venous sinus thrombosis. At last follow up, twenty-one patients (70%) were on chronic anticoagulation [17 (81%) were on warfarin, 2 (9.5%) on enoxaparin and 2 (9.5%) were on rivaroxaban]. Median number of events was 1 (range 0-7). Four patients (19%) had bleeding complications from anticoagulation. Only one death was noted in the cohort and cause of death could not be determined. ConclusionsType 1 hereditary AT deficiency is the most clinically prevalent subtype in practice. Of the patients who developed thrombosis; clinical characteristics did not differ between type 1 and type 2 AT deficiency. We report 6 novel mutations in patients with hereditary AT deficiency. Disclosures:No relevant conflicts of interest to declare.

Antithrombin deficiency in three Japanese families: One novel and two reported point mutations in the antithrombin gene

Inherited antithrombin (AT) deficiency is associated with a predisposition to familial venous thromboembolic disease. We analyzed the AT gene in three unrelated patients with an AT deficiency who developed thrombosis. We analyzed the SERPINC1 gene in three patients. Additionally, we expressed the three mutants in the COS-1 cells and compared their secretion rates and levels of AT activity with those of the wild-type (WT). We identified three distinct heterozygous mutations of c.2534C>T: p.56Arginine → Cysteine (R56C), c.13398C>A: p.459Alanine → Aspartic acid (A459D) and c.2703C>G: p.112 Proline → Arginine (P112R). In the in vitro expression experiments, the AT antigen levels in the conditioned media (CM) of the R56C mutant were nearly equal to those of WT. In contrast, the AT antigen levels in the CM of the A459D and P112R mutants were significantly decreased. The AT activity of R56C was decreased in association with a shorter incubation time in a FXa inhibition assay and a thrombin inhibition-based activity test. However, the AT activity of R56C was comparable to that of WT when the incubation time was increased. We concluded that the R56C mutant is responsible for type II HBS deficiency. We considered that the A459D and P112R mutants can be classified as belonging to the type I AT deficiency.

The phenotypic and genetic assessment of antithrombin deficiency

Antithrombin (AT) deficiency is associated with an increased risk of deep vein thrombosis and pulmonary embolism which are major causes of morbidity and death. The incidence of deficiency in healthy populations has been reported to vary from 1/600 to 1/5000, with the variation being due to the different populations studied and detection methods used. When reduced activity levels are identified it is important to measure the AT antigen levels to differentiate type I from type II disorders, as type II defects have varying thrombotic risk. Functional AT assays detect the ability of AT to inactivate thrombin or factor Xa, and AT antigen assays detect the quantity of AT in plasma. In functional assays, reducing the incubation time of sample with enzyme/heparin reagent may increase sensitivity to type II defects. An excess of antigen over activity level suggests the presence of functionally defective AT, which can be characterized further by assaying AT in the absence of heparin, electrophoresis to investigate the ability of heparin to bind to AT, and gene sequencing. Many patients with AT deficiency have a type II defect and these defects may not be detected by all routine diagnostic assays. Assays using human thrombin may lack specificity and assays that use factor Xa may fail to detect the common variant, AT Cambridge II, which can be detected by assays using bovine thrombin, especially if activity is compared to antigen by ratio. Factor Xa based assays may be particularly sensitive to certain heparin binding defects, and sensitivity of assays to both heparin binding and reactive site defects can be improved by shortening the incubation time with enzyme. uAT activity assays are essential for the detection of AT deficiency because type II defects are relatively common in patients with heritable deficiency. No one functional assay can be assumed to detect all forms of AT deficiency, and assays can sometimes be improved by reducing reaction time of AT with thrombin or factor Xa.

A Study on the Molecular Mechanism for Hereditary Type II Antithrombin Deficiency in a Chinese Pedigree.

Objective: To identify the phenotype and study for the genetic mechanism underlying the recurrence of deep vein thrombosis formation in members of a Chinese pedigree caused by antithrombin (AT) deficiency.Methods: AT antigen level (AT:Ag) and AT activity (AT:A) were detected with respectively immuno-nephelometry and chromogenic assay. All the seven exons and the flank regions of AT gene form the propositus were amplified by PCR. The purified PCR products were sequenced directly. After mutation was found, the corresponding gene fragments covering the mutated point from the other members of the pedigree were amplified and sequenced.Results: The plasma level of AT:Ag of the propositus was 29.80mg/dl and those of other 3 members of the kindred ranged from 30.90 to 34.00mg/dl, all were among normal range. The AT:A of the propositus was 56%, and those of the other members were 62% to 68%, all were lower than normal. A heterozygous G13830A missense mutation in exon 6 was identified, which has led to the substitution of histamine (CAT) 393 for arginine (CGT). The sequencing results from the pedigree suggested that all the three other members of the kindred also had the same heterozygous mutation.Conclusion: The R393H mutation in AT which is similar to the AT Glasgow and AT Avranches can cause reactive site injury in AT so that it is not able to inhibit thrombin anymore. The gene mutation found in this pedigree which was unreported in China is the molecular mechanism for recurrent thrombosis events in two members of the kindred.

Characterization of molecular defect of 13387-9delG mutated antithrombin in inherited type I antithrombin deficiency

As a major physiological inhibitor of thrombin and other coagulation proteases, antithrombin (AT) plays an important role in the maintenance of normal hemostasis and its deficiency is associated with a predisposition for familial venous thromboembolic disease. Recently, we found a novel mutation (13387-9delG) in the antithrombin gene that is associated with type I AT deficiency. To examine the molecular pathologic mechanism of this mutation causing type I AT deficiency, the wild-type and the mutant AT constructs were expressed in COS-7 cells or Chinese Hamster Ovary cells. No AT antigen could be detected by enzyme-linked immunosorbent assay in the conditioned media of cells expressing the mutant protein, and the AT antigen level was reduced in cell lysates. The mutant AT-expressing cells did not have less intracellular mRNA levels than the wild-type transfectants as estimated by quantitative reverse transcriptase-polymerase chain reaction. Metabolic and pulse-chase experiments showed the newly synthesized wild-type AT protein was gradually secreted into the media, whereas no labeled mutant AT protein was detected in the media and the total amount of radioactivity was significantly reduced in the cells during the chase periods. By immunofluorescence analysis, the staining of the mutant AT was weaker than that of the wild type, and was predominantly diffuse without perinuclear enhancement. These results indicate that the 13387-9delG mutation, which disrupts the disulfide bridge Cys247-Cys430, impairs the secretion and stability of the truncated AT protein associated with intracellular degradation.

High Levels of Tissue Factor Pathway Inhibitor in Patients with Nephrotic Proteinuria

Acquired deficiency of naturally occurring anticoagulant proteins, due to loss in the urine, has been proposed as one of the major thrombogenic alterations in nephrotic proteinuria. The aim of this study was to investigate if proteinuria may induce deficiency of tissue factor pathway inhibitor (TFPI). TFPI, protein C (PC) and antithrombin (AT) were measured in 31 patients with nephrotic proteinuria, compared with 62 age- and sex-matched controls. Plasma levels of TFPI activity, total TFPI antigen and free TFPI antigen were significantly higher in patients with nephrotic proteinuria than in controls, and none of the patients had TFPI deficiency. Intravenous injection of 7500 IU unfractionated heparin induced a significant further increase of TFPI in two patients with high pre-heparin levels. Also plasma levels of PC were significantly higher in patients than in controls. Mean AT antigen levels were not significantly different between patients and controls, and AT activity was only marginally increased with borderline significance. Three out of 31 patients had substantial acquired AT deficiency. In conclusion, proteinuria is not associated with TFPI deficiency, but with a marked increase of this anticoagulant protein. The acquired thrombophilic diathesis of patients with nephrotic proteinuria can therefore not be attributed to TFPI deficiency.