A single F153Sβ3 mutation causes constitutive integrin αIIbβ3 activation in a variant form of Glanzmann thrombasthenia

This report identifies a novel variant form of the inherited bleeding disorder Glanzmann thrombasthenia, exhibiting only mild bleeding in a physically active individual. The platelets cannot aggregate ex vivo with physiologic agonists of activation, although microfluidic analysis with whole blood displays moderate ex vivo platelet adhesion and aggregation consistent with mild bleeding. Immunocytometry shows reduced expression of αIIbβ3 on quiescent platelets that spontaneously bind/store fibrinogen, and activation-dependent antibodies (ligand-induced binding site-319.4 and PAC-1) report β3 extension suggesting an intrinsic activation phenotype. Genetic analysis reveals a single F153Sβ3 substitution within the βI-domain from a heterozygous T556C nucleotide substitution of ITGB3 exon 4 in conjunction with a previously reported IVS5(+1)G\u3eA splice site mutation with undetectable platelet messenger RNA accounting for hemizygous expression of S153β3. F153 is completely conserved among β3 of several species and all human β-integrin subunits suggesting that it may play a vital role in integrin structure/function. Mutagenesis of αIIb-F153Sβ3 also displays reduced levels of a constitutively activated αIIb-S153β3 on HEK293T cells. The overall structural analysis suggests that a bulky aromatic, nonpolar amino acid (F,W)153β3 is critical for maintaining the resting conformation of α2- and α1-helices of the βI-domain because small amino acid substitutions (S,A) facilitate an unhindered inward movement of the α2- and α1-helices of the βI-domain toward the constitutively active αIIbβ3 conformation, while a bulky aromatic, polar amino acid (Y) hinders such movements and restrains αIIbβ3 activation. The data collectively demonstrate that disruption of F153β3 can significantly alter normal integrin/platelet function, although reduced expression of αIIb-S153β3 may be compensated by a hyperactive conformation that promotes viable hemostasis

First description of an IgM monoclonal antibody causing αIIb β3 integrin activation and acquired Glanzmann thrombasthenia associated with macrothrombocytopenia

BACKGROUND: Acquired Glanzmann thrombasthenia (GT) is a bleeding disorder generally caused by anti-αIIb β3 autoantibodies. OBJECTIVES: We aimed to characterize the molecular mechanism leading to a progressive GT-like phenotype in a patient with chronic immune thrombocytopenia. PATIENT, METHODS AND RESULTS: The patient suffered from repeated episodes of gastrointestinal bleedings and further studies indicated a moderate platelet aggregation defect. Few months later, platelet function showed abolished aggregation using all agonists, but normal agglutination with ristocetin. No platelet-bound antibodies were detected, but the presence of large amounts of an IgM type antibody detected together with αIIb β3 in the patient's permeabilized platelets suggested that this IgM was an autoantibody causing the internalization of the complex. This was confirmed by the fact that the patient's IgM bound to normal platelets but not to platelets from GT type I patients. Moreover, patient's plasma activated αIIb β3 on controls' platelets as evidenced by increased PAC-1 binding. We also demonstrated that the patient's plasma triggered αIIb β3 outside-in signaling, as β3 Tyr773 and FAK were phosphorylated, and increased the rate of actin polymerization in resting platelets reflecting an impairment of cytoskeletal reorganization. As different signs of dysmegakariopoiesis were also observed in our patient, we evaluated the ability of its serum to impair proplatelets formation and showed that it significantly decreased the number of proplatelet-bearing megakaryocytes in controls' bone marrow stem cells culture as compared to normal serum. CONCLUSIONS: We present the case of a patient with a progressive and severely perturbed platelet function associated with the presence of an IgM activating autoantibody directed against αIIb β3 . This article is protected by copyright. All rights reserved

Atrial Fibrillation Mechanisms and Implications for Catheter Ablation

AF is a heterogeneous rhythm disorder that is related to a wide spectrum of etiologies and has broad clinical presentations. Mechanisms underlying AF are complex and remain incompletely understood despite extensive research. They associate interactions between triggers, substrate and modulators including ionic and anatomic remodeling, genetic predisposition and neuro-humoral contributors. The pulmonary veins play a key role in the pathogenesis of AF and their isolation is associated to high rates of AF freedom in patients with paroxysmal AF. However, ablation of persistent AF remains less effective, mainly limited by the difficulty to identify the sources sustaining AF. Many theories were advanced to explain the perpetuation of this form of AF, ranging from a single localized focal and reentrant source to diffuse bi-atrial multiple wavelets. Translating these mechanisms to the clinical practice remains challenging and limited by the spatio-temporal resolution of the mapping techniques. AF is driven by focal or reentrant activities that are initially clustered in a relatively limited atrial surface then disseminate everywhere in both atria. Evidence for structural remodeling, mainly represented by atrial fibrosis suggests that reentrant activities using anatomical substrate are the key mechanism sustaining AF. These reentries can be endocardial, epicardial, and intramural which makes them less accessible for mapping and for ablation. Subsequently, early interventions before irreversible remodeling are of major importance. Circumferential pulmonary vein isolation remains the cornerstone of the treatment of AF, regardless of the AF form and of the AF duration. No ablation strategy consistently demonstrated superiority to pulmonary vein isolation in preventing long term recurrences of atrial arrhythmias. Further research that allows accurate identification of the mechanisms underlying AF and efficient ablation should improve the results of PsAF ablation

Human phenotype ontology annotation and cluster analysis to unravel genetic defects in 707 cases with unexplained bleeding and platelet disorders.

BACKGROUND: Heritable bleeding and platelet disorders (BPD) are heterogeneous and frequently have an unknown genetic basis. The BRIDGE-BPD study aims to discover new causal genes for BPD by high throughput sequencing using cluster analyses based on improved and standardised deep, multi-system phenotyping of cases. METHODS: We report a new approach in which the clinical and laboratory characteristics of BPD cases are annotated with adapted Human Phenotype Ontology (HPO) terms. Cluster analyses are then used to characterise groups of cases with similar HPO terms and variants in the same genes. RESULTS: We show that 60% of index cases with heritable BPD enrolled at 10 European or US centres were annotated with HPO terms indicating abnormalities in organ systems other than blood or blood-forming tissues, particularly the nervous system. Cases within pedigrees clustered closely together on the bases of their HPO-coded phenotypes, as did cases sharing several clinically suspected syndromic disorders. Cases subsequently found to harbour variants in ACTN1 also clustered closely, even though diagnosis of this recently described disorder was not possible using only the clinical and laboratory data available to the enrolling clinician. CONCLUSIONS: These findings validate our novel HPO-based phenotype clustering methodology for known BPD, thus providing a new discovery tool for BPD of unknown genetic basis. This approach will also be relevant for other rare diseases with significant genetic heterogeneity

TaqIB polymorphism in cholesterol ester transfer protein (CETP) gene predicts future cardiovascular death in patients experiencing an acute coronary syndrome

Background: Cholesterol ester transfer protein (CETP) plays a pivotal role in the remodelling of triglyceride (TG)-rich and high-density lipoprotein (HDL) particles. Sequence variations in the CETP gene may interfere with coronary atherosclerosis. However, clinical studies of various CETP polymorphisms have shown controversial data in coronary artery outcome. We aimed to investigate whether TaqIB CETP gene polymorphism could predict clinical outcome in a prospective cohort of patients hospitalized for an acute coronary syndrome (ACS). Methods: Two hundred and seventy consecutive Caucasian patients hospitalized for an ACS, and having a significant coronary artery disease in at least one major vessel (stenosis >50%), were prospectively enrolled and followed for 57 months. The mean age was 65.1±12.5 years, and 77% were males. One hundred and thirty-nine patients (51.5%) suffered from unstable angina at inclusion and 131 patients (48.5%) presented with an acute myocardial infarction (MI). The follow-up data were obtained from questionnaires. The major recurrent events recorded were 32 deaths comprising 28 cardiovascular deaths and 49 combined cardiovascular events (28 cardiovascular deaths, 19 non-fatal ACS and 2 non-fatal strokes). CETP genotyping was performed using a restriction fragment length polymorphism based method. Results: A significant relation was found between B2B2 genotype and combined cardiovascular end-point (p<0.02), mainly driven by a link with cardiovascular death (p<0.05). The hazard risk ratio for cardiovascular death associated with B2B2 genotype was 2.2 [95% confidence interval (CI): 1.01–4.94, p<0.05]. In multivariate analyses, no modification except for a significant interaction with statin therapy was observed by inclusion of potential confounders for the association of B2B2 genotype with cardiovascular death. Conclusions: These results suggest that patients homozygous for the B2 allele and not taking statin had a strong increase of recurrent cardiovascular event after an initial acute coronary event. This cardiovascular risk seems to be corrected with statin therapy. Clin Chem Lab Med 2009;47:1039–46.Peer Reviewe

L’intégrine α

La compréhension des mécanismes moléculaires impliqués dans la formation des plaquettes (mégacaryopoïèse) a beaucoup progressé ces dernières années, grâce notamment à l’étude de certaines maladies génétiques provoquant des anomalies de ce processus physiologique. Parmi les nombreux récepteurs membranaires présents à la surface des plaquettes, l’intégrine αIIbβ3 en est le principal : elle permet aux plaquettes de s’agréger lors de la survenue d’une brèche vasculaire. Pourtant, la présence d’un taux normal de plaquettes chez les patients ayant un déficit constitutionnel en cette protéine a très longtemps fait évoquer que celle-ci n’était pas impliquée dans la mégacaryopoïèse. Récemment, de nouvelles observations cliniques sont venues contredire cette hypothèse en apportant de nouvelles données sur son importance dans la production normale des plaquettes

Founder effect and estimation of the age of the French Gypsy mutation associated with Glanzmann thrombasthenia in Manouche families.

International audienceThe c.1544+1G>A substitution at the 5' splice donor site of intron 15 of the ITGA2B gene, called the French Gypsy mutation, causes Glanzmann thrombasthenia, an inherited hemorrhagic disorder transmitted as an autosomal recessive trait and characterized by an altered synthesis of the platelet αIIbβ3 integrin. So far, this mutation has only been found in affected individuals originating from French Manouche families, strongly suggesting a founder effect. Our goal was to investigate the origin of the French Gypsy mutation. We estimated the age of the mutation by a likelihood-based method that uses the length of the shared haplotypes among a set of patients. For this, we genotyped 23 individuals of Manouche origin; consisting of 9 Glanzmann thrombasthenia patients homozygous for the French Gypsy mutation, 6 heterozygous carriers and 8 homozygous wild-type individuals. They were genotyped for four single-nucleotide polymorphisms using high-resolution melting curve analysis, and for two CA repeats in the BRCA1 and THRA genes at chromosome 17, using fragment analysis gels. We found that a haplotype of five polymorphic loci covering a 4-cM region was strongly associated with the French Gypsy mutation, suggesting a founder effect. The estimated age of this founder mutation was 300-400 years (range 255-552 years). Thus, all carriers of the French Gypsy mutation c.1544+1G>A at intron 15 descended from a common ancestor 300-400 years ago