Haemophilia B, severe childhood obesity and other extra-haematological features associated with similar 4Mb-deletions on Xq27: Clinical findings, molecular insights and literature update.

INTRODUCTION: Haemophilia B (HB) is associated with pathogenic variants in F9. Hemizygous deletions encompassing the entire F9 and proximate genes may express extra-haematological clinical phenotypes. AIM: To analyse the genotype/phenotype correlations in two unrelated boys with severe early childhood obesity (SCO), global developmental delay (GDD) and similar bleeding phenotype associated with comparable Xq27 deletions spanning the entire F9 and proximate genes, and characterise the pathogenic events estimating the most likely mutational mechanism involved. METHODS: Entire F9-deletions were detected in three hemizygous unrelated probands with HB: two cases, C#1/C#2, presented SCO and GDD and a control patient (Co), who only had severe bleeding symptoms. Dense SNP-array and case-specific STS walking scan allowed characterisation of the deletion breakpoints. Extensive use of bioinformatics, statistics and clinical databases allowed the investigation of genotype-phenotype associations. RESULTS: Patients C#1/C#2 and Co resulted in a complete F9 and additional gene deletions of variable extensions on Xq26.3-Xq27.2 (C#1/C#2/Co: 4.3Mb/3.9Mb/160Kb). C#1/C#2 common deleted gene SOX3 is directly associated with SCO, GDD and pituitary hypothyroidism (PH) whilst C#2 extra-deleted gene MAGEC2 indirectly relates to anal atresia (AA). Breakpoint analysis revealed the involvement of the mechanisms of Alu/Alu recombination for the first time in HB and non-homologous or alternative end-joining. CONCLUSION: Our results represent the first report of unrelated patients with HB, SCO and GDD. This study and the literature update expand the spectrum of clinical findings and molecular insights observed in patients with HB caused by complete F9 and nearby SOX3 and MAGEC2 gene deletions, which may configure a contiguous gene syndrome.

Eighteen years of molecular genotyping the hemophilia inversion hotspot: from southern blot to inverse shifting-PCR.

The factor VIII gene (F8) intron 22 inversion (Inv22) is a paradigmatic duplicon-mediated rearrangement, found in about one half of patients with severe hemophilia A worldwide. The identification of this prevalent cause of hemophilia was delayed for nine years after the F8 characterization in 1984. The aim of this review is to present the wide diversity of practical approaches that have been developed for genotyping the Inv22 (and related int22h rearrangements) since discovery in 1993. The sequence- Southern blot, long distance-PCR and inverse shifting-PCR-for Inv22 genotyping is an interesting example of scientific ingenuity and evolution in order to resolve challenging molecular diagnostic problems.

Sixteen novel hemophilia A causative mutations in the first Argentinian series of severe molecular defects.

Hemophilia A (HA) is caused by heterogeneous mutations in the factor VIII gene (F8). This paper reports 16 novel small F8-mutations and rearrangements in a series of 80 Argentinian families with severe-HA. Using an updated scheme for F8-analysis, we found 37 F8-inversions (46%), 10 large deletions (13%), 13 small ins/del (16%), 7 nonsense (9%) and 8 missense mutations (10%), including 4 new ones (p.T233K, p.W1942R, p.L2297P and p.L2301S). The potential changes leading to severe-HA of these latter mutations were suggested by bioinformatics. The F8-mutation was characterised in 76 families (95%). They received genetic counselling and precise information about treatment design.

Homeologous recombination between AluSx-sequences as a cause of hemophilia.

Although large deletions from the coagulation factor VIII gene, F8, are responsible for 5% of severe hemophilia A (seHA), few of them have been fully characterised. A detailed description of a large partial deletion of the F8 caused by unequal recombination between homeologous AluSx-derived sequences is presented. The proband, a case of isolated hemophilia A with a high inhibitor titre (5700 BU), showed a consistent absence of PCR-amplification of exons 4 to 10, EX4_EX10del. Two approaches were used to narrow down the deletion breakpoints: a direct physical analysis based on PCR (that additionally permits carrier detection in the family); and, under the hypothesis that the mutation resulted from homologous recombination, sequence alignments of F8 intron 3 and 10. Both approaches indicate an unequal crossing over (CO) between two Alu-related sequences. Both elements involved were derived from the AluSx-subfamily consensus and demonstrate 86% sequence identity (with only single-base mismatches), with three gaps (of 2, 3 and 14-bases) and two main tracts of perfectly homologous sequence (28 and 24-bp). The short stretch of intron 10 embedded into intron 3 sequence, linked to the CO, represents a typical hallmark of homologous recombination (double-strand break repair model). A detailed description of EX4_EX10del mutation is c.[338+3485delins1687+2223_1687+2225; 338+3551_1687+2291 del]. The common involvement of unequal homologous recombination mediated by repetitive elements allowed us to suggest that our experimental design (based on intron sequence alignments) may be successfully applied to rearrangements involved in other X-linked inherited diseases. Like other Alu-rich genes throughout the human genome, Alu-mediated homologous recombination in F8 may be an important cause of hemophilia by promoting large DNA deletions.

The molecular basis of beta-thalassemia in Argentina. Influence of the pattern of immigration from the Mediterranean Basin.

In order to determine the molecular heterogeneity of the beta-thalassemia gene and to analyze the influence of immigration from the Mediterranean Basin, a total of 254 families (475 subjects) from Argentinean beta-thalassemia patients were investigated using molecular biology techniques. This allowed us to provide a simplified diagnosis and genetic counselling of this disorder in Argentina.

Analysis of factor VIII gene intron 1 inversion in Argentinian families with severe haemophilia A and a review of the literature.

Besides intron 22 factor VIII gene inversion (Inv22), intron 1 inversion (Inv1) has recently been reported as a further recurrent mutation that causes approximately 5% of severe haemophilia A (HA) cases. We analysed the presence of the Inv1 in a group of 64 severe HA-affected families from Argentina, and found only one positive case. This Inv1 patient has not developed a factor VIII inhibitor, and the screening for small mutations in the coding sequences of the factor VIII gene did not detect any additional defect in this case. The Inv1 genotyping was further applied to analyse the haemophilia carrier status of the proband's sister. In addition, we studied the accuracy of the current polymerase chain reaction-based method to investigate the Inv1, and confirmed the absence of amplimer length polymorphisms associated to the Inv1-specific polymerase chain reaction amplifications in 101 X-chromosome haplotypes from unrelated Argentinian healthy males. In order to discuss Inv1 mutation frequency in severe HA and the risk of inhibitor formation, a review of the literature was included. Our data highlight the importance of analysis of the Inv1 in Inv22-negative severe HA cases. This will benefit both genetic counselling and the study of the relationship between genotype and inhibitor development.

Novel mutational mechanism in the thyroglobulin gene: imperfect DNA inversion as a cause for hereditary hypothyroidism.

The objective of this study was to perform genetic analysis in three brothers of Turkish origin born from consanguineus parents and affected by congenital hypothyroidism, goiter and low levels of serum TG. The combination of sequencing of DNA, PCR mapping, quantitative real-time PCR, inverse-PCR (I-PCR), multiplex PCR and bioinformatics analysis were used in order to detect TG mutations. We demonstrated that the three affected siblings are homozygous for a DNA inversion of 16,962bp in the TG gene associated with two deleted regions at both sides of the inversion limits. The inversion region includes the first 9bp of exon 48, 1015bp of intron 47, 191bp of exon 47, 1523bp of intron 46, 135bp of exon 46 and the last 14,089bp of intron 45. The proximal deletion corresponds to 27bp of TG intron 45, while the distal deletion spans the last 230bp of TG exon 48 and the first 588bp of intergenic region downstream TG end. The parents were heterozygous carriers of the complex rearrangement. In conclusion, a novel large imperfect DNA inversion within the TG gene was identified by the strategy of I-PCR. This aberration was not detectable by normal sequencing of the exons and exon/intron boundaries. Remarkably, the finding represents the first description of a TG deficiency disease caused by a DNA inversion.