[Analysis of clinical features and genotype in three Chinese pedigrees with Glanzmann thrombasthenia]

OBJECTIVE

To study the clinical feature and alpha II b beta 3 gene mutations of three Glanzmann thrombasthenia (GT) pedigrees.

METHODS

Platelet counts (BPC), blood film, bleeding time, platelet aggregation and flow cytometry were used for phenotype diagnosis of all the patients. All the exons of alpha II b and beta 3 genes were amplified by polymerase chain reaction (PCR) and direct sequencing was performed for mutational screening. One hundred and three healthy blood donors were as normal controls.

RESULTS

Three probands showed normal BPC, defective platelets aggregation, prolonged bleeding time and significantly reduced platelet aggregation to ADP, epinephrine, and collagen, while relatively normal aggregation to ristocetin. Flow cytometry showed platelet surface expressed alpha II b beta 3 was strongly reduced in proband 1 and proband 3 and mildly reduced in the amount of surface expressed alpha II b beta 3 (63%) in proband 2. Sequencing results showed that proband 1 had a G10A homozygous mutation in alpha II b, and a G1412T homozygous mutation in beta3. Compound heterozygous mutations in beta3, G1199A and 1525delC were identified in proband 2. No mutations in alpha II b beta 3 gene were identified in proband 3.

CONCLUSIONS

Compound homozygous mutations, GI0A in alpha II b and G1412T in beta3, lead to GT in proband 1. Compound heterozygous mutations in beta3, G1199A and 1525delC, lead to GT in proband 2. The mutations of G10A, G1412T and 1525delC were reported for the first time in GT patients.

[Novel frame-shift mutation of 540 A deletion in GP IIb gene from a patient with Glanzmann thrombasthenia]

OBJECTIVE

To explore the molecular mechanism of Glanzmann thrombasthenia (GT).

METHODS

All 45 exons of alphaIIb and beta3 subunit genes as well as their splicing sites were amplified by polymerase chain reaction(PCR) with 40 primer pairs, and then the PCR products were used to screen the gene mutation by single strand conformation polymorphism-polyacrylamide gel electrophoresis (SSCP-PAGE). The mutation was further confirmed by direct DNA sequencing.

RESULTS

A DNA band alterated migration was detected after SSCP-PAGE. DNA sequencing showed that a base deletion within the band at the site of 540 in GPIIb gene(540A) was found.

CONCLUSION

The frame-shift mutation caused by the deletion of 540A in GPIIb gene is a novel mutation which is a genetic defect in patients with GT.

Disulfide bond disruption by a beta 3-Cys549Arg mutation in six Jordanian families with Glanzmann thrombasthenia causes diminished production of constitutively active alpha IIb beta 3

Alpha IIb beta 3 integrin mediates platelet aggregation following its activation. Its absence or dysfunction causes Glanzmann thrombasthenia (GT), an inherited bleeding disorder that is rare worldwide but relatively frequent in several populations with high rates of consanguinity, including Arabs in Israel and Jordan. Cysteine residues in the beta 3 epidermal growth factor (EGF) domains are involved in alpha IIb beta 3 formation and activation. In this study we present a novel Cys549Arg mutation in beta 3 identified in six Jordanian families, which in the homozygous state is manifested by severe GT. The mutation is located in EGF-3 of beta 3 predicting disruption of a conserved disulfide bond between Cys549 and Cys558. Haplotype analysis disclosed a common founder whose age estimate was 120-150 years. Flow cytometry revealed 1-14% of normal alpha IIb beta 3 expression at the patients' platelet surface. The Cys549Arg or artificial Cys549Ser mutations were introduced into a beta 3 expression vector. Co-transfection of baby hamster kidney cells with normal or mutant beta 3 along with normal alpha IIb demonstrated reduced surface expression of alpha IIb beta 3 by both mutants. The mutants were constitutively active as demonstrated by 20-fold increased binding of the ligand-mimetic antibody PAC-1. Immunoblotting and immunoprecipitation experiments showed reduced beta 3 and alpha IIb beta 3 expression and a higher than normal ratio of pro-alpha IIb to mature alpha IIb. Immunofluorescence experiments showed that beta 3 and alpha IIb beta 3 were mostly retained in the endoplasmic reticulum. In conclusion, the novel ancestral mutation found in a cluster of Jordanian GT patients disrupts a conserved Cys549-Cys558 bond which results in reduced production of constitutively active alpha IIb beta 3.

Three novel mutations in the glycoprotein IIb gene in a patient with type II Glanzmann thrombasthenia

In the platelets of a type II Glanzmann thrombasthenia patient, the amount of glycoprotein (GP) IIb and IIIa was significantly reduced. Three novel mutations were identified in the GPIIb gene (c.440C->G/p.Leu116Val, c.1772_1773insG/p.Asp560GlyfsX16 and c.2438C->A/p.His782Asn). p.Leu116Val did not represent a causative mutation. The c.1772_1773insG mutation resulted in an early stop codon and non-sense mediated decay of mRNA. When expressed in transfected BHK cells, the truncated protein was unable to form complex with GPIIIa. The p.His782Asn mutation compromised transport of the pro-GPIIb/IIIa complex from the endoplasmic reticulum to the Golgi, hindering its maturation and surface expression.

Characterization of the cDNA Encoding alphaIIb and beta3 in normal horses and two horses with Glanzmann thrombasthenia

Glanzmann thrombasthenia (GT) is an inherited, intrinsic platelet defect characterized by a quantitative or qualitative change in the platelet glycoprotein complex IIb-IIIa (integrin alpha(IIb)beta3). The subunits are encoded by separate genes and both subunits must be expressed for a stable complex to form on the platelet surface; therefore, a defect in either gene can result in GT.

Type II Glanzmann thrombasthenia in a compound heterozygote for the alpha IIb gene. A novel missense mutation in exon 27

BACKGROUND AND OBJECTIVES

Glanzmann thrombasthenia is an autosomal recessive bleeding disorder characterized by a life-long hemorrhagic tendency and absent or severely reduced platelet aggregation in response to agonists, caused by quantitative or qualitative abnormalities in the platelet fibrinogen receptor, integrin alphaIIb beta3. The aim of this study was to identify the molecular genetic defect and determine its functional consequences in a patient with type II Glanzmann thrombasthenia.

DESIGN AND METHODS

The expression of platelet alphaIIb beta3 was determined by flow cytometry and western blotting. Mutations were identified by sequencing both cDNA and genomic DNA. Functional characterization was assessed by exontrap and transient transfection analysis.

RESULTS

Flow cytometry and western blot analysis revealed markedly reduced levels of platelet alphaIIb beta3, which may account for the residual fibrinogen binding detected upon platelet activation. Sequencing of genomic DNA revealed the presence of two mutations in the alphaIIb gene: a C1750T transition in the last codon of exon 17 changing Arg553 to STOP, and a C2829T transition in exon 27 that changes Pro912 to Leu. Sequence analysis of reversely transcribed alphaIIb mRNA did not detect cDNA from the C1750T mutant allele, and revealed a significant increase of the physiological splicing out of exon 28 in the cDNA carrying the C2829T mutation. Transient expression of [912Leu]alphaIIb in CHO-b3 cells showed a marked reduction in the rate of surface expression of alphaIIb beta3.

INTERPRETATION AND CONCLUSIONS

The results suggest that the thrombasthenic phenotype is the result of reduced availability of alphaIIb-mRNA, enhanced expression of exon 28-deleted transcripts, and defective processing of [912Leu]alphaIIb.

Diversity of Glanzmann thrombasthenia in southern India: 10 novel mutations identified among 15 unrelated patients

BACKGROUND

Glanzmann thrombasthenia (GT) is a congenital bleeding disorder caused by either a lack or dysfunction of the platelet integrin alphaIIbbeta3.

OBJECTIVES

To determine the molecular basis of GT in patients from southern India.

PATIENTS

Fifteen unrelated patients whose diagnosis was consistent with GT were evaluated.

RESULTS

Platelet surface expression of alphaIIbbeta3 was < 10%, 10%-50%, and > 50% of controls in five, nine, and one patient(s), respectively. Immunoblotting of the platelet lysates showed no alphaIIb in 14 patients, and no beta3 in 10 patients, although severely reduced in four patients. Platelet fibrinogen was undetectable in 13 patients, and severely reduced in one patient. One patient showed normal surface alphaIIbbeta3 expression, and normal alphaIIb, beta3 and fibrinogen levels in the lysate. Ten novel candidate disease-causing mutations were identified in 11 patients. The missense mutations included Gly128Ser, Ser287Leu, Gly357Ser, Arg520Trp, Leu799Arg in alphaIIb, and Cys575Gly in beta3. We have already shown that Gly128Ser, Ser287Leu, and Gly357Ser mutations variably affect alphaIIbbeta3 surface expression. The Cys575Gly mutation may disrupt the disulphide link with Cys586 to cause the GT phenotype. The molecular pathology of the other missense mutations is not clear. Two nonsense mutations, Trp-16Stop and Glu715Stop in alphaIIb, and a 7-bp deletion (330-336TCCCCAG) in beta3 are predicted to result in truncated proteins. An IVS15(-1)G --> A mutation in alphaIIb induced a cryptic splice site as confirmed by reverse transcription-polymerase chain reaction (RT-PCR) analysis. Thirteen polymorphisms were also identified (five in alphaIIb and eight in beta3), among which five were novel.

CONCLUSIONS

While identifying a significant number of novel mutations causing GT, this study confirms the genetic heterogeneity of the disorder in southern India.

Molecular diversity of Glanzmann thrombasthenia in southern India: new insights into mRNA splicing and structure-function correlations ofαIIbβ3 integrin (ITGA2B, ITGB3)

The molecular basis of Glanzmann thrombasthenia (GT) was studied in 40 families from southern India. Of 23 identified mutations (13 in the alphaIIb (ITGA2B) gene and 10 in the beta3 (ITGB3) gene), 20 were novel and three were described previously. Three mutations in the beta3 gene-p.Leu143Trp (Leu117Trp), p.Tyr307Stop (Tyr281Stop), and p.Arg119Gln (Arg93Gln)-were detected in 12, three, and two families, respectively, with definite founder effects observed for the first two mutations. Alternative splicing was predicted in silico for the normal variant and a missense variant of the beta3 gene, and for 10/11 frameshift or nonsense mutations in alphaIIb or beta3. The prediction was confirmed experimentally for a c.2898_2902dupCCCCT mutation in exon 28 of the alphaIIb gene that induced exon skipping. Seven out of nine missense mutations substituted highly conserved amino acids buried in the proteins' cores, predicting structural abnormalities. Among these, a beta3 substitution, p.Cys39Gly (Cys13Gly) was found to cause intracellular degradation of the beta3 subunit, in contrast to previous findings that mutations at Cys435, the partner of Cys13 in a disulfide bond, cause constitutive activation of alphaIIbbeta3. The two patients with a beta3 Arg93Gln mutation had normal clot retraction, consistent with a recent finding that this substitution is associated with normal surface expression of alphaIIbbeta3. In conclusion, this study demonstrates that a variety of mutations account for GT in southern Indian patients, provides new insights into mRNA splicing, and highlights the role of specific amino acids in structure-function correlations of alphaIIbbeta3.

Three novel beta-propeller mutations causing Glanzmann thrombasthenia result in production of normally stable pro-alphaIIb, but variably impaired progression of pro-alphaIIbbeta3 from endoplasmic reticulum to Golgi

BACKGROUND

Glanzmann thrombasthenia (GT) is an autosomal recessive bleeding disorder characterized by lack of platelet aggregation in response to most physiological agonists and caused by either a lack or dysfunction of the platelet integrin alpha(IIb)beta3 (glycoprotein IIb/IIIa).

OBJECTIVES

To determine the molecular basis of GT and characterize the mutations by in vitro expression studies.

PATIENTS

We studied three unrelated patients from southern India whose diagnosis was consistent with GT.

RESULTS

Immunoprecipitation of the cell lysates and immunoblotting showed no detectable mature alpha(IIb) in the G128S mutant, in contrast to 6% and 33% of the normal amount of mature alpha(IIb) in the S287L and G357S mutants, respectively. Pulse-chase analysis demonstrated pro-alpha(IIb) in the mutants comparable with the normal pro-alpha(IIb), but no conversion to mature alpha(IIb) in the G128S mutant, and only trace conversion to mature alpha(IIb) in the S287L and G357S mutants. The disappearance of pro-alpha(IIb) in the three mutants was similar to that in cells expressing normal alpha(IIb)beta3 or alpha(IIb) only. All three mutants demonstrated pro-alpha(IIb)beta3 complexes and co-localized with an ER marker by immunofluorescence. The G128S mutant showed no co-localization with a Golgi marker, and the other two mutants showed minimal and moderate co-localization with the Golgi marker.

CONCLUSIONS

These three beta-propeller mutations do not affect the production of pro-alpha(IIb), its ability to complex with beta3, or its stability, but do cause variable defects in transport of pro-alpha(IIb)beta3 complexes from the endoplasmic reticulum to the Golgi.

A 13-bp deletion in alpha(IIb) gene is a founder mutation that predominates in Palestinian-Arab patients with Glanzmann thrombasthenia

Glanzmann thrombasthenia (GT) is a rare autosomal recessive bleeding disorder caused by lack or dysfunction of alpha(IIb)beta3 in platelets. GT is relatively frequent in highly inbred populations. We previously identified a 13-bp deletion in the alpha(IIb) gene that causes in-frame deletion of six amino acids in three Palestinian GT patients. In this study, we determined the molecular basis of GT in all known Palestinian patients, examined whether Jordanian patients harbor the same mutations, analyzed whether there is a founder effect for the 13-bp deletion, and determined the mechanism by which the 13-bp deletion abolishes alpha(IIb)beta3 surface expression. Of 11 unrelated Palestinian patients, eight were homozygous for the 13-bp deletion that displayed common ancestry by haplotype analysis, and was estimated to have occurred 300-600 years ago. Expression studies in baby hamster kidney cells showed that substitution of Cys107 or Trp110 located within the deletion caused defective alpha(IIb)beta3 maturation. Substitution of Trp110, but not of Cys107, prevented fibrinogen binding. The other Palestinian patients harbored three novel mutations: G2374 deletion in alpha(IIb) gene, TT1616-7 deletion in beta3 gene, and IVS14: -3C --> G in beta3 gene. The latter mutation caused cryptic splicing predicting an extended cytoplasmic tail of beta3 and was expressed as dysfunctional alpha(IIb)beta(3). None of 15 unrelated Jordanian patients carried any of the described mutations.

Type I Glanzmann thrombasthenia caused by an apparently silent beta3 mutation that results in aberrant splicing and reduced beta3 mRNA

We report a novel genetic defect in a patient with type I Glanzmann thrombasthenia. Flow cytometry analysis revealed undetectable levels of platelet glycoproteins alphaIIb and beta3, although residual amounts of both proteins were detectable in immunoblotting analysis. Sequence analysis of reversely transcribed platelet beta3 mRNA showed a 100-base pair deletion in the 3'-boundary of exon 11, that results in a frame shift and appearance of a premature STOP codon. Analysis of the corresponding genomic DNA fragment revealed the presence of a homozygous C1815T transition in exon 11. The mutation does not change the amino acid residue but it creates an ectopic consensus splice donor site that is used preferentially, causing splicing out of part of exon 11. The parents of the proband, heterozygous for this mutation, were asymptomatic and had reduced platelet content of alphaIIbbeta3. PCR-based relative quantification of beta3 mRNA failed to detect the mutant transcript in the parents and showed a marked reduction in the patient. The results suggest that the thrombasthenic phenotype is, mainly, the result of the reduced availability of beta3-mRNA, most probably due to activation of the nonsense-mediated mRNA decay mechanism. They also show the convenience of analyzing both genomic DNA and mRNA, in order to ascertain the functional consequences of single nucleotide substitutions.

Therapeutic expression of the platelet-specific integrin, alphaIIbbeta3, in a murine model for Glanzmann thrombasthenia

Integrins mediate the adhesion of cells to each other and to the extracellular matrix during development, immunity, metastasis, thrombosis, and wound healing. Molecular defects in either the alpha- or beta-subunit can disrupt integrin synthesis, assembly, and/or binding to adhesive ligands. This is exemplified by the bleeding disorder, Glanzmann thrombasthenia (GT), where abnormalities of the platelet-specific integrin, alphaIIbbeta3, prevent platelet aggregation following vascular injury. We previously used a retrovirus vector containing a cDNA cassette encoding human integrin beta3 to restore integrin alphaIIbbeta3 on the surface of megakaryocytes derived from peripheral blood stem cells of GT patients. In the present study, bone marrow from beta3-deficient (beta3-/-) mice was transduced with the ITGbeta3-cassette to investigate whether the platelet progeny could establish hemostasis in vivo. A lentivirus transfer vector equipped with the human ITGA2B gene promoter confined transgene expression to the platelet lineage. Human beta3 formed a stable complex with murine alphaIIb, effectively restoring platelet function. Mice expressing significant levels of alphaIIbbeta3 on circulating platelets exhibited improved bleeding times. Intravenous immunoglobulin effectively diminished platelet clearance in animals that developed an antibody response to alphaIIbbeta3. These results indicate the feasibility of targeting platelets with genetic therapies for better management of patients with inherited bleeding disorders.

Glanzmann thrombasthenia Frankfurt I is associated with a point mutation Thr176Ile in the N-terminal region of alpha IIb subunit integrin

In this study, we report on the characterization of a patient with Glanzmann thrombasthenia (GT). Immunochemical analysis on platelets from the patient showed that the expression of alpha IIb beta 3 was only 25% of that in normal healthy controls, suggesting a case of GT. Functional analysis revealed a total lack of fibrinogen binding capacity. Molecular genetic analysis of the full-length cDNA sequences of alpha IIb and beta 3 subunits showed a novel point mutation C621T in alpha IIb cDNA, leading to a missense substitution of threonine for isoleucine at position 176. Coexpression of normal beta 3 and mutant alpha IIb(1176) isoform in mammalian cells showed a marked reduction in the expression of alpha IIb beta 3 heterodimer when compared to the wild-type and a decreased intracellular level of alpha IIb. The T176 I mutation is located in the N-terminal region in the W3:1-2 connecting strand of the beta-propeller. These data suggest that the N-terminal alpha IIb domain plays an important structural role in the formation of heterodimer and that it is also involved in fibrinogen binding.

[Genetic profile of Glanzmann's thrombasthenia in south Tunisia. Report of 17 cases (11 families)]

INTRODUCTION

Glanzmann's thrombasthenia (GT) is a rare congenital thrombopathy, with a recessive autosomal transmission. We present here the genealogic study of a series of patients suffering from GT.

PATIENTS AND METHODS

This is a retrospective study about all the GT patients treated in Sfax hematology department during 18 years. Final diagnosis was established by agregometry. Genealogic study was based on clinical history.

RESULTS

17 cases of GT from 11 families from the south of Tunisia wen collected. The disease was paricularly frequent in the region of Moulares-Gafsa (7 patients). The percentage of consanguinity was also very high (82%), with a third degree consanguinity of 86%. Family investigation revealed 6 previously unknown cases, and 10 deaths subsequent to hemorrhagic manifestations.

CONCLUSION

The high rate of consanguinity, the absence of clinical or biological manifestations in the parents, and the ratio of ill to normal subjects in the same family which was about one to four, are suggestive of an autosomal recessive mode of transmission.

Fetal-neonatal alloimmune thrombocytopenia and unexpected Glanzmann thrombasthenia carrier: report of two cases

BACKGROUND

Discrepancy between phenotyping and genotyping during the investigation of maternofetal alloimmunization leads to the identification of defects on genes encoding membrane glycoproteins (GPs) IIb and IIIa.

STUDY DESIGN AND METHODS

Human platelet (PLT) alloantigen (HPA)-1 and -3 PLT phenotypes and genotypes were performed by use of, respectively, the monoclonal antibody-specific immobilization of PLT antigens and the polymerase chain reaction (PCR)-sequence-specific priming techniques for up to 2400 families with thrombocytopenic newborn. When a discrepancy was detected, genomic DNA from the mother was amplified for coding sequences of either the GPIIb or GPIIIa genes. The genetic abnormality responsible for the discrepancy was determined by direct sequencing of the PCR products.

RESULTS

Two cases of discrepancy were identified among 2400 families tested. In the first case, Mother L, serologically assigned as HPA-1b-homozygous, was genotyped HPA-1a/1b. In the second case, Mother S, serogically defined HPA-3b-homozygous, was genotyped HPA-3a/3b. DNA sequence analysis revealed for Mother L a T(1447)-->C a point mutation within exon 10 of the GPIIIa gene and for Mother S a C(480)-->G point mutation within exon 4 of the GPIIb gene. These mutations reported in Glanzmann thrombasthenia (GT) patients account for nonexpression of the implicated allele on the PLT surface. Thus, the mothers are GT carriers. Alloantibodies, hallmarks of immunization, were not detected in the maternal serum samples.

CONCLUSION

Although this situation is rarely encountered, it is important to combine phenotyping and genotyping to avoid false PLT typing assignation and erroneous diagnosis when alloimmunization might occur.

Insertion of a C in the exon 28 of integrin alphaIIb gene leading to a frameshift mutation is responsible for Glanzmann thrombasthenia in a Japanese case

BACKGROUND

Glanzmann thrombasthenia (GT) is a hereditary bleeding disorder caused by a qualitative or quantitative defect in the integrin alphaIIbbeta3.

OBJECTIVE

Our objective is to identify the gene mutation that resulted in GT.

PATIENTS AND METHODS

The patient was a 66-year-old male with a history of frequent bleeding. The expression levels of the integrin proteins in the platelets were determined by flow cytometry and Western blot analysis. The sequences of genomic DNA and mRNA encoding for alphaIIb and beta3 were analyzed by the dye-terminator cycle sequencing method. For transfection experiments, expression vectors encoding for wild-type alphaIIb, mutated alphaIIb, beta3, green fluorescent protein (GFP) fusion wild-type alphaIIb, GFP fusion mutated alphaIIb and DsRed fusion beta3 were constructed. These vectors were transfected to COS-7 cells, and the expression levels were determined.

RESULTS

The alphaIIb protein was remarkably reduced in the patient's platelets, and gene analysis showed that the patient possessed compound heterozygous mutations in the alphaIIb gene. One was a C --> G substitution at the splice acceptor site (- 3) of exon 26 (CAG -->GAG) and the other was the insertion of an additional C at the region including six C bases between 2911 and 2916 in exon 28 (InsC). Transfection experiments using COS-7 cells showed that alphaIIb containing InsC had expressed and formed a complex with beta3, but had not been transported to the Golgi apparatus.

CONCLUSIONS

In the present study the novel mutation InsC, leading to a frameshift that affects the transmembrane domain and the cytoplasmic tail, was found to be responsible for GT.

Mutations in GPIIIa molecule as a cause for Glanzmann thrombasthenia in Indian patients

BACKGROUND

Glanzmann thrombasthenia (GT) results from a quantitative or qualitative defect of GPIIb-IIIa complex, the fibrinogen receptor on platelets, which plays a very important role in platelet aggregation. In this report we describe the molecular studies on 22 patients with Glanzmann Thrombasthenia at our institute.

OBJECTIVES

The main objective was to identify the mutations present in our GT population in order to establish a strategy for genetic counseling and antenatal diagnosis.

METHODS

Twenty-two patients with GT were included in the present study. Complete blood count (CBC), platelet aggregation, flow cytometry, Western blot, single strand conformation polymorphism (SSCP) and denaturing gradient gel electrophoresis (DGGE) were performed in all the patients. The patients showing an abnormal migration pattern in SSCP or DGGE were sequenced further on an automated sequencer.

RESULTS

Of the 22 patients studied, mutations were detected in 12 individuals. Of these, 11 were novel mutations and one mutation Y115C was reported earlier. Flow cytometric analysis showed the absence of receptors in type I GT, highly reduced levels in type II GT and normal levels in type III GT. The DGGE analysis and SSCP analysis of the patients showed different migration patterns. Sequencing was performed in all patients showing an abnormal migration pattern. Of the 22 cases studied mutations could be detected in 12 cases of GT. We could detect six patients with point mutations, four patients with insertions and five patients with deletion mutations. Exon 4 has been found to be the most common site for mutations in our patients.

CONCLUSION

This study has shown a wide array of mutations present in our GT patients which would be extremely useful in genetic counseling and prenatal diagnosis, essential in preventing these disorders in succeeding generations.