Hereditary hemorrhagic telangiectasia is a vascular dysplasia with variable onset and expression. Through identification of a mutation in a proband, mutation testing can be offered to family members. Mutation carriers can receive medical surveillance and treatment before potentially fatal complications arise. In this study, we assessed the significance of clinical evaluations as part of hereditary hemorrhagic telangiectasia diagnostic testing to determine the clinical sensitivity of molecular testing and to report novel mutations. Based on reported clinical symptoms, we classified 142 consecutive cases as affected, suspected, or unlikely affected. We performed temperature gradient capillary electrophoresis and full gene sequencing of both ACVRL1 and ENG genes. We then compared the mutation detection rates between these groups, categorizing sequence variants as mutations, variants of uncertain significance (VUS), or known polymorphisms. Our mutation and VUS detection rate in affected individuals was 74% and 16% in the suspected/unlikely affected group. Sixty-one percent of the mutations and all VUS were novel. The mutation detection rate for temperature gradient capillary electrophoresis was 97%. Our results suggest that a careful clinical evaluation increases the mutation detection rate. We have confirmed the occurrence of de novo mutations in three patients. Our results also show that temperature gradient capillary electrophoresis is an efficient mutation screening method. Hereditary hemorrhagic telangiectasia (HHT) is characterized phenotypically by telangiectases and arteriovenous malformations. These lesions result in hemorrhage, particularly in the nose, gastrointestinal tract, and brain, and complications related to shunting, primarily in the lungs and liver. Complications from this disorder include intracranial hemorrhage secondary to cerebral arteriovenous malformations and embolic stroke and brain abscess secondary to pulmonary arteriovenous malformations. The frequency of HHT is reported to be ϳ1 in 10,000, but it is thought to be underdiagnosed. 1Two genes, endoglin (ENG) and activin receptor-like kinase 1 (ACVRL1), have been reported to cause HHT in an autosomal dominant manner if mutated.2 Molecular diagnosis allows for diagnostic confirmation in symptomatic individuals and significantly improves care for individuals at risk for HHT after identification of a causative mutation. Because the initial clinical presentation of the disorder can be a catastrophic pulmonary or central nervous system event, 3-5 presymptomatic diagnosis for relatives of individuals with HHT offers an opportunity to prevent serious or lethal complications. Individuals shown to be unaffected can be spared unnecessary and costly medical screening. Developing simple and reliable diagnostic approaches has been difficult because of the lack of common mutations.2 Thus, sensitive mutation scanning approaches followed by targeted sequencing might be useful in the clinical setting.To detect mutations many scanning techniques have been ...
High-resolution melting analysis (HRMA) was compared with denaturing high-performance liquid chromatography (dHPLC) for mutation scanning of common mutations in the cystic fibrosis transmembrane conductance regulator gene. We amplified (polymerase chain reaction under conditions optimized for melting analysis or dHPLC) 26 previously genotyped samples with mutations in exons 3, 4, 7, 9, 10, 11, 13, 17b, and 21, including 20 different genotypes. Heterozygous mutations were detected by a change in shape of the melting curve or dHPLC tracing. All 20 samples with heterozygous mutations studied by both techniques were identified correctly by melting (100% sensitivity), and 19 were identified by dHPLC (95% sensitivity). The specificity of both methods also was good, although the dHPLC traces of exon 7 consistently revealed 2 peaks for wild-type samples, risking false-positive interpretation. Homozygous mutations could not be detected using curve shape by either method. However, when the absolute temperatures of HRMA were considered, G542X but not F508del homozygotes could be distinguished from wild type. HRMA easily detected heterozygotes in all single nucleotide polymorphism (SNP) classes (including A/T SNPs) and 1- or 2-base-pair deletions. HRMA had better sensitivity and specificity than dHPLC with the added advantage that some homozygous sequence alterations could be identified. HRMA has great potential for rapid, closed-tube mutation scanning.
Multiplexing genotyping technologies usually require as many probes as genetic variants. Oligonucleotides that span multiple loci--loci spanning probes (LSProbes)--hybridize to two or more noncontiguous DNA sequences present in a template and can be used to analyze multiple variants simultaneously. The intervening template sequence, omitted in the LSProbe, creates a bulge-loop during binding. Melting temperatures of the probe, monitored by fluorescence reading are specific to the presence or absence of the mutations. We previously described LSProbes as a molecular haplotyping tool and apply here the principle to genotype simultaneously three mutations of the beta-globin gene responsible for the corresponding hemoglobinopathies. Analysis with both labeled and unlabeled LSProbes demonstrate that the four possible alleles studied (WT, HbS, HbC, and HbE) are identifiable by the specific melting temperatures of the LSProbes. This demonstrates that, in addition to their haplotyping capabilities, LSProbes are able to genotype in a single step, loci 58 nucleotides apart.
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