Haemophilia A: database of nucleotide substitutions, deletions, insertions and rearrangements of the factor VIII gene, second edition.

A large number of different mutations in the factor VIII (F8) gene have been identified as a cause of haemophilia A. This compilation lists known single base-pair substitutions, deletions and insertions in the F8 gene and reviews the status of the inversional events which account for a substantial proportion of mutations causing severe haemophilia A.     

Haemophilia A: database of nucleotide substitutions, deletions, insertions and rearrangements of the factor VIII gene, second edition.

A large number of different mutations in the factor VIII (F8) gene have been identified as a cause of haemophilia A. This compilation lists known single base-pair substitutions, deletions and insertions in the F8 gene and reviews the status of the inversional events which account for a substantial proportion of mutations causing severe haemophilia A.     

A novel mutation (4040-4045 nt. delA) in exon 14 of the factor VIII gene causing severe hemophilia A

Hemophilia A is an X-linked congenital bleeding disorder caused by Factor VIII deficiency. Different mutations including point mutations, deletions, insertions and inversions have been reported in the FVIII gene, which cause hemophilia A. In the current study, with the use of conformational sensitive gel electrophoresis (CSGE) analysis, we report a novel 1-nt deletion in the A6 sequence at codons 1328-1330 (4040-4045 nt delA) occurring in exon 14 of the FVIII gene in a seven-year-old Iranian boy with severe hemophilia A. This mutation that causes frameshift and premature stop-codon at 1331 has not previously been reported in the F8 Hemophilia A Mutation, Structure, Test and Resource Site (HAMSTeRS) database.     

The treatment of haemophilia A inhibitor with high dose intravenous immunoglobulin

In patients with Haemophilia A, the development of inhibitor is a life-threatening complication of treatment. These patients are at high risk for dangerous bleeding as a result of this acquired resistance to human Factor VIII concentrate. Although treatment of bleeding complications has been improved with the introduction of an activated prothrombin complex preparation, therapy remains unsatisfactory. Two patients with Haemophilia A inhibitor were treated with high dose intravenous immunoglobulin in the expectation of an immunosuppressive effect. A rise in the antibody titre at the same time as the administration of factor VIII concentrate showed that this treatment was ineffective in patients with Haemophilia A inhibitor.     

Restriction endonuclease mapping of six novel deletions of the factor VIII gene in hemophilia A

Summary Hemophilia A is an X-linked disease of blood coagulation caused by deficiency of factor VIII. Using cloned cDNA, genomic and synthetic oligonucleotide factor VIII probes, we have identified six novel partial gene deletions in patients with severe hemophilia A. We have previously reported six other deletions of the factor VIII gene. The number of gross molecular defects (deletions, insertions) in the factor VIII gene in our series of 240 patients is 17 (3 insertions and 2 complicated deletions will be described elsewhere). No association was observed between the size or location of the deletions and the presence of inhibitors to factor VIII. No deletion breakpoint hotspots have been identified by restriction analysis. The parental origin of several of the deletions was determined.     

Characterization of a splicing mutation in the factor VIII gene at the RNA level

Haemophilia A is an X-linked bleeding disorder caused by mutations in the coagulation factor VIII (FVIII) gene. The identification and characterization of naturally occurring disease-producing mutations allows the recognition of new mechanisms of pathogenesis in haemophilia A. Analysis of the illegitimately transcribed FVIII mRNA in a severely affected patient has revealed that the AG transition at position –2 of the acceptor splice site of intron 4 results in the skipping of exon 5 in 90% of the processed pre-mRNA. Another minor mRNA species arising from the skipping of exons 4 and 5 has also been observed. The skipping of exon 5 predicts the removal of the corresponding 13 amino acids from the A1 domain of FVIII. A novel missense mutation, C329S, in exon 8 of FVIII gene has been identified in another patient.     

Genetik und Klinik der Hämophilie A und B

Haemophilia A and B are caused by various mutations in the factor VIII (FVIII) and factor IX (FIX) genes, respectively. The clinical course of the disease is variable, dependent on the severity of the molecular defect. Nowadays, haemophilia patients can excellently be treated by plasma-derived or recombinant clotting factor concentrates. Thus, bleeding and its consequences can be almost completely prevented with nearly normal quality of life and life expectancy. The most severe complication of this treatment is the formation of antibodies (inhibitors) against the substituted clotting factor. The risk of inhibitor formation correlates significantly with specific mutation types that preclude endogenous factor VIII/IX protein synthesis and can be as high as 20–50%. The information on the expected clinical course is at present the most important indication for FVIII/IX gene analysis. Knowledge of the underlying FVIII/IX gene mutation further allows a reliable and fast carrier diagnosis in female relatives of patients with haemophilia.     

Molecular analysis of hemophilia A mutations in the Finnish population

We have examined the Finnish hemophilia A population for factor VIII gene mutations. This study included 83 unrelated patients and revealed 10 mutations associated with hemophilia. Using cloned cDNA, genomic, and oligonucleotide probes, we have identified three classes of mutations: five mutations causing the loss of TaqI restriction sites, a point mutation resulting in a new TaqI site, and four partial gene deletions. Although exons 5 and 6 were involved in three of the four partial gene deletions, the extent of the DNA lost differs in each case. The fourth deletion was located entirely within intron 1 and segregated with the disease in a large hemophilia pedigree. There was no history of hemophilia in eight of the 10 families. The origin of the mutation was determined in six of these pedigrees, two of which showed evidence for maternal mosaicism.     

Large DNA inversions,deletions, and TaqI site mutations in severe haemophilia A

Large DNA inversions caused by an intrachromosomal recombination between homologous regions located in intron 22 and 5 of the factor VIII gene have recently been identified in patients with severe haemophilia A. To evaluate better the prevalence of this large inversion and to estimate the overall sensitivity of the Southern blot/hybridization method we analysed the factor VIII gene of 49 unrelated patients with severe haemophilia A. All patients were screened for the inversion mutation, TaqI site mutations, and deletions. Mutations were identified in 31 (63%) patients, and comprised 24 large inversions, 4 partial deletions, and 3 point mutations. Three different haplotypes were characterised in the patients presenting the inversion mutation, confirming its independent origin. Two novel deletions are reported: a large one spanning from intron 14 to intron 22 and a deletion of 86 bp comprising the 3 region of exon 1 and 39–41 bp of intron 1. DNA sequencing of the deletion junction showed no significant homology between normal 5 and 3 sequences around the breakpoints. A novel missense mutation is also reported: CGAGGA, Arg-2209 to Gly. These results confirm that the inversion mutation is the most common cause of severe haemophilia A and indicate that the Southern blot/hybridization assay should be used as the first method for screening of mutations in severe haemophilia A.     

Exon skipping caused by an intronic insertion of a young Alu Yb9 element leads to severe hemophilia A

Short interspersed elements, such as Alu elements, have propagated to more than one million copies in the human genome. They affect the genome in several ways, caused by retrotransposition, recombination between elements, gene conversion, and alterations in gene expression. These events, including novel insertions into active genes, have been associated with a number of human disorders. Hemophilia A is an X-linked severe bleeding disorder and is caused by mutations in the Factor VIII gene. The spectrum of mutations includes point mutations, rearrangements, insertions, and deletions. Recently, an Alu retrotransposition event in a coding exon has been reported in a family with a severe form of hemophilia A. This was the first report of an Alu insertion in the Factor VIII gene. Here, we report a second Alu insertion event that lies in an intron of the same gene that causes exon skipping and the complete disruption of gene expression.     

The Factor VIII Mutation Database on the World Wide Web: the haemophilia A mutation, search, test and resource site. HAMSTeRS update (version 3.0).

The HAMSTeRS WWW site was set up in 1996 in order to facilitate easy access to, and aid understanding of, the causes of haemophilia A at the molecular level; previously, the first and second text editions of the database have been published in Nucleic Acids Research. This report describes the facilities originally available at the site and the recent additions which we have made to increase its usefulness to clinicians, the molecular genetics community and structural biologists interested in factor VIII. The database (version 3.0) has been completely updated with easy submission of point mutations, deletions and insertions via e-mail of custom-designed forms. The searching of point mutations in the database has been made simpler and more robust, with a concomitantly expanded real-time bioinformatic analysis of the database. A methods section devoted to mutation detection has been added, highlighting issues such as choice of technique and PCR primer sequences. Finally, a FVIII structure section gives access to 3D VRML (Virtual Reality Modelling Language) files for any user-definable residue in a FVIII A domain homology model based on the crystal structure of human caeruloplasmin, together with secondary structural data and a sound+video animation of the model. It is intended that the general availability of this model will assist both in interpretation of causative mutations and selection of candidate residues forin vitromutagenesis. The HAMSTeRS URL is http://europium.mrc.rpms.ac.uk.     

Screening for nonsense mutations in patients with severe hemophilia A can provide rapid,direct carrier detection

Summary Despite marked genetic heterogeneity in families with hemophilic patients, transition mutations in CG dinucleotides occur frequently. Of 71 CG dinucleotides in the factor VIII cDNA, a C-to-T transition in 12 would lead to a new Stop codon (CGA to TGA). Using restriction enzyme digestion of 11 amplified DNA fragments, seven point mutations were localized among 60 patients with severe hemophilia A. Five were detected as loss of a natural or introduced TaqI site at codons -5, 583, 1941, 2116, and 2209 and were confirmed as CGA (Arg) to TGA (Stop) nonsense mutations by DNA sequencing. A novel C-to-T nonsense mutation was detected as loss of the RsaI site at codon 1966 and confirmed by sequence in two unrelated individuals. Two partial gene deletions were detected as selective failure to amplify exon 1 and exons 15–22, respectively. In an additional (61st) patient who was subsequently found to have mild (instead of severe) hemophilia, digests suggested a mutation in codon 1696. Upon sequencing, this codon contained a novel missense mutation, a C-to-G transversion changing CGA (Arg 1696) to GGA (Gly). In four families with women available for testing, carrier status was rapidly determined by direct screening for the point mutation. In two of three with sporadic occurrences, the mother was a carrier as were two of four sisters. In the other family, the mother and a sister were homozygous for the TaqI cleavage site in their amplified exon 24 fragment, indicating a de novo C-to-T transition in codon 2209 in the patient's factor VIII gene. This final patient's sister was a noncarrier even though by linkage analysis she inherited the same factor VIII gene as her brother.These results have already been published in part in abstract form: Reiner AP, Thompson AR (1990) Circulation Research 82:304     

Application of non-radioactive methods of DNA detection in analysis of human genetic disorders

We have applied two non-radioactive methods for detection of unique sequences in human genome: 1 polymerase chain reaction, 2 hybridization with digoxigenin-deoxyuridine 5-triphosphate labeled probes. With the polymerase chain reaction technique we were able to amplify short segments of genes coding for coagulation factors VIII and IX. Electrophoretical analysis of products of polymerase chain reaction enabled us to detect deletions causing hemophilia A or B. To analyse deletions in dystrophin gene, the most frequent cause of Duchenne muscular dystrophy, we have amplified several different fragments of this gene simultaneously. We have studied restriction fragment length polymorphism closely linked to the cystic fibrosis locus with digoxigenin-deoxyuridine 5 -triphosphate labeled probe p3.11 with sensitivity comparable to methods involving the use of radioisotopes.     

A novel missense mutation in the factor VIII gene identified by analysis of amplified hemophilia DNA sequences.

To date the only point mutations demonstrated to cause hemophilia are C to T transitions in TaqI sites. These were detected by screening Southern blots with cloned factor VIII probes. During the development of improved methods for detecting and analyzing mutations in genomic DNA, a novel G to C transversion mutation has been identified. This rare transversion results in a missense mutation, with proline being substituted for arginine in one of the active domains of the factor VIII molecule. The results suggest that the improved methods will be useful for detecting mutations in hemophilia as well as in other genetic disorders. In this method, specific DNA sequences in genomic DNA are amplified using oligonucleotide primers and a heat-resistant DNA polymerase. Mutations are detected and localized in the amplified samples by RNase A cleavage, and the altered region is then sequenced.     

Identification of mutations in the repeated part of the autosomal dominant polycystic kidney disease type 1 gene, PKD1, by long-range PCR.

We have used long-range PCR to identify mutations in the duplicated part of the PKD1 gene. By means of a PKD1-specific primer in intron 1, an approximately 13.6-kb PCR product that includes exons 2-15 of the PKD1 gene has been used to search for mutations, by direct sequence analysis. This region contains the majority of the predicted extracellular domains of the PKD1-gene product, polycystin, including the 16 novel PKD domains that have similarity to immunoglobulin-like domains found in many cell-adhesion molecules and cell-surface receptors. Direct sequence analysis of exons encoding all the 16 PKD domains was performed on PCR products from a group of 24 unrelated patients with autosomal dominant polycystic kidney disease (ADPKD [MIM 173900]). Seven novel mutations were found in a screening of 42% of the PKD1-coding region in each patient, representing a 29% detection rate; these mutations included two deletions (one of 3 kb and the other of 28 bp), one single-base insertion, and four nucleotide substitutions (one splice site, one nonsense, and two missense). Five of these mutations would be predicted to cause a prematurely truncated protein. Two coding and 18 silent polymorphisms were also found. When, for the PKD1 gene, this method is coupled with existing mutation-detection methods, virtually the whole of this large, complex gene can now be screened for mutations.     

A Strategy for the Molecular Diagnosis in Hemophilia A in Chinese Population

Hemophilia A is an x-linked recessive inherited bleeding disorder. So far, more than 1,885 disease-causing mutations of factor VIII gene have been identified. Clinic confers a great challenge for the molecular diagnosis. We aim to make a better strategy for the molecular diagnosis in Hemophilia A. First, factor VIII intron 22 inversion and intron 1 inversion mutations were detected using Inversion-PCR and double-tube multiple PCRs. And then, non-inversion mutations were analyzed by denaturing high performance liquid chromatography and/or direct sequencing. Novel mutations were further analyzed the conservation and 3D structures by a B domain deleted crystallographic model and bioinformatics. Finally, we can indirectly confirm the diagnosis by linkage analysis for the patients with the confusing diagnosis by the techniques mentioned above. Eleven patients with the factor VIII Inv 22 were found, and the remaining 16 patients were found with 11 different mutations, of which 3 was novel mutations affecting A1, B domains and splicing site. Moreover, the prenatal diagnosis was performed on 14 fetuses. Ten fetuses were successfully confirmed to be normal, 1 fetus to be a heterozygote with factor VIII c.3275–3276 ins A and 3 fetuses to be hemizygotes with factor VIII Inv 22 mutation.