Christine Vinciguerra

Expanding the Mutation Spectrum Affecting αIIbβ3 Integrin in Glanzmann Thrombasthenia: Screening of the ITGA2B and ITGB3 Genes in a Large International Cohort.

We report the largest international study on Glanzmann thrombasthenia (GT), an inherited bleeding disorder where defects of the ITGA2B and ITGB3 genes cause quantitative or qualitative defects of the αIIbβ3 integrin, a key mediator of platelet aggregation. Sequencing of the coding regions and splice sites of both genes in members of 76 affected families identified 78 genetic variants (55 novel) suspected to cause GT. Four large deletions or duplications were found by quantitative real‐time PCR. Families with mutations in either gene were indistinguishable in terms of bleeding severity that varied even among siblings. Families were grouped into type I and the rarer type II or variant forms with residual αIIbβ3 expression. Variant forms helped identify genes encoding proteins mediating integrin activation. Splicing defects and stop codons were common for both ITGA2B and ITGB3 and essentially led to a reduced or absent αIIbβ3 expression; included was a heterozygous c.1440‐13_c.1440‐1del in intron 14 of ITGA2B causing exon skipping in seven unrelated families. Molecular modeling revealed how many missense mutations induced subtle changes in αIIb and β3 domain structure across both subunits, thereby interfering with integrin maturation and/or function. Our study extends knowledge of GT and the pathophysiology of an integrin.

Illegitimate transcription: its use for studying genetic abnormalities in lymphoblastoid cells from patients with Glanzmann thrombasthenia.

Glanzmann thrombasthenia is the most common inherited disorder of platelets that may induce severe bleeding complications. Molecular biology techniques have offered the possibility to assess the basis of this chronic haemorrhagic disease at the molecular level. However, the accessibility of mRNA in platelets is limited by the availability of the patients blood samples and the relatively weak amount of this material in these cells. Taking advantage of the genetic phenomenon of illegitimate transcription, we have demonstrated that glycoprotein IIb and glycoprotein IIIa mRNA could be detected in lymphoblastoid cell lines issued from normal EBV‐transformed lymphoblasts. We further analysed the sequences of the two glycoprotein transcripts in lymphoblastoid cell lines from two previously characterized patients presenting with Glanzmann thrombasthenia. The results showed that illegitimate transcripts presented similar molecular abnormalities to those found in platelets. These data demonstrated that the nucleotide sequences of illegitimate transcripts were identical to tissue‐specific mRNA found in platelets. We applied this methodology to screen for the genetic defect in a new thrombasthenic patient, and found a homozygous nonsense mutation GCA → TGA converting Arg8 to stop in the glycoprotein IIIa gene. This immortalized source of genetic material is therefore particularly useful for molecular genetic studies in inherited platelet disorders, avoiding repetitive and large blood samplings in frequently anaemic patients.

Description of 10 new mutations in platelet glycoprotein IIb (αIIb) and glycoprotein IIIa (β3) genes

In this study we have used denaturing gradient gel electrophoresis (DGGE) for identifying sequence alterations in glycoprotein (GP) IIb and IIIa genes from 20 patients affected by Glanzmanns thrombasthenia. These patients were from 16 different families. Using computer modelling, we divided the promoters, coding sequences and flanking splicing regions, in 31 segments for the GPIIb gene and 19 domains for the GPIIIa gene. We were able to find a mutation potentially affecting GPIIb-IIIa expression or function in 16 patients out of 20. In six patients from three families, the gypsy mutation modifying the splice donor site of intron 15 of the GPIIb gene was detected. In the other patients, 10 novel mutations were characterised, which were located either in the GPIIb gene (nine cases) or in the GPIIIa gene (one case). The type of mutation was nonsense mutation (one case), missense mutation (five cases), small insertion of 1 bp (one case) and splicing modifications (three cases). Among these genetic events, three were directly responsible for Glanzmanns thrombasthenia, four were localised in regions known to be involved in GPIIb-IIIa complex expression and three mutations were potentially responsible for Glanzmanns thrombasthenia.

Characterisation of 96 mutations in 128 unrelated severe haemophilia A patients from France. Description of 62 novel mutations.

Direct sequencing of the coding region of factor VIII (F8) gene was used to determine the mutations responsible for severe haemophilia A (FVIII<1%) in 128 unrelated haemophiliacs A, negative for intron 22 and intron 1 inversions. A mutation was found in 122/128 patients (95%). Ninety-six distinct mutations were identified in this cohort, 62 of these are novel. They consisted of deletions (7 large and 24 small deletions), insertions (n = 9), associations of insertion/deletion (n = 2), association of deletion/substitution (n = 1), and single nucleotide substitutions (53 point mutations consisting of 31 missense, 20 nonsense, and 2 splicing mutations). Twenty-two patients had developed inhibitors, and among this subgroup 3 large deletions, 6 frameshift, 9 nonsense and 4 missense mutations were detected. For 6 patients, among which one developed an anti-FVIII inhibitor, no mutations were detected in the coding and splicing regions of factor VIII gene. Different approaches of molecular modelling were performed in addition to familial linkage analysis to determine the pathophysiological responsibility of these novel missense mutations.

Two novel factor V null mutations associated with activated protein C resistance phenotype/genotype discrepancy.

Summary.  Activated protein C (APC) resistance phenotype/genotype discrepancy is a very rare event. The objective of this study was to characterize the molecular mechanisms in two cases of APC phenotype/genotype discrepancy. An approach using direct sequencing of each exon and splicing junctions of the factor V gene showed that two novel factor V null mutations combined with heterozygous factor V Leiden mutation were responsible for this discrepancy. Our results suggest the necessity to use both phenotypic and genotypic analyses in some cases to determine an accurate diagnosis.

Rapid diagnosis of the French gypsy mutation in Glanzmann thrombasthenia using high-resolution melting analysis

Rapid diagnosis of the French gypsy mutation in Glanzmann thrombasthenia using high-resolution melting analysis -

Differential diagnosis of neonatal alloimmune thrombocytopenia: Type 2B von Willebrand disease

Abstract At birth, severe thrombocytopenia without context of infection should mainly suggest neonatal alloimmune thrombocytopenia (NAIT), especially in case of a platelet count below 20 GL−1. We report two cases of severe neonatal thrombocytopenia, first suspected as being NAIT. Both had a platelet count below 20 GL−1 with platelet clumps. The absence of alloantibodies and failure of platelet transfusion and intravenous immunoglobulins to improve the platelet count led to question the diagnosis and to evoke inherited bleeding disorders. Measurements of Von Willebrand factor (VWF) levels showed a marked reduction of VWF:RCo and a normal VWF:Ag, suggesting a type 2B Von Willebrand disease (VWD2B). Ristocetin-induced platelet aggregation could not be performed because of the very low platelet count. In the first case, after sequencing VWF exon 28, a heterozygous p.Leu1460Pro mutation was found consistent with VWD2B. In the second case, the genetic analysis of VWF exon 28 identified a homozygous mutation: p.Pro1337Leu confirming type VWD2B and also the p.Arg854Gln homozygous mutation in exon 20 confirming type 2N (ratio FVIII/VWF:Ag <0.5). The two cases underline that, even if NAIT remains the most common diagnosis in severe neonatal thrombocytopenia, it should be challenged in the absence of documented incompatibility, chronic evolution, or treatment failure. Diagnosis of VWD2B should be considered in early thrombocytopenia, even without familial history. In the cases presented, genotyping confirmed the subtype of VWD and helped to guide the therapeutic management of bleeding episodes.

Why patients with THBD c.1611C>A (p.Cys537X) nonsense mutation have high levels of soluble thrombomodulin?

Background Recently our group has described a new autosomal dominant bleeding disorder characterized by very high plasma levels of soluble thrombomodulin (TM). The THBD c.1611C>A (p.Cys537X) mutation in heterozygous state was found in the propositus. This mutation leads to the synthesis of a truncated TM which has lost the last three amino-acids of the transmembrane domain and the cytoplasmic tail. Objective We investigated the mechanism responsible for TM shedding in endothelial cells with THBD c.1611C>A mutation. Methods Complementary DNA of TM wild type (TM-WT) was incorporated into a pcDNA3.1 vector for transient transfection in COS-1 cells. Mutagenesis was performed to create the c.1611C<A (TM1-536) mutant and 4 other TM mutants (TM1-515, TM1-525, TM1-533 and TM1-537) with a transmembrane domain having different lengths. The effect of shear stress, metalloprotease inhibitor, certain proteases and reducing agents were tested on TM shedding. Results Western blot and immunofluorescent analysis showed that TM1-536 was produced and a certain amount of TM1-536 was anchored on the cell membrane. A significantly higher levels of soluble TM was observed in the TM1-536 cell medium in comparison with TM-WT (56.3 +/- 5.2 vs 8.8 +/- 1.6 ng/mL, respectively, p = 0.001). The shedding of TM1-536 was 75% decreased in cells cultured in the presence of a metalloprotease inhibitor. No difference was observed between TM1-536 and TM-WT shedding after cell exposure to cathepsin G, elastase, several reducing agents and high shear stress (5000 s-1). Significantly higher levels of soluble TM were observed in the cell media of TM1-533, TM1-525, TM1-515 in comparison with TM-WT (p < 0.05). Conclusion The mechanism responsible for TM shedding is complex and is not completely understood: higher sensitivity of the TM1-536 to the proteolysis by metalloproteases and a defect of synthesis due to the decreased size of the transmembrane domain might explain the high levels of soluble TM in plasma of the carriers.