Improved molecular diagnosis of dystrophinopathies in an unselected clinical cohort

Dent, Karin M.; Dunn, Diane M.; Niederhausern, Andrew C. von; Aoyagi, A; Kerr, Lynne M.; Bromberg, Mark B.; Hart, Kim; Tuohy, Thérèse M.F.; White, Stefan J.; Dunnen, Johan T. den; Weiss, Robert B.; Flanigan, Kevin M.

doi:10.1002/ajmg.a.30617

Cited by 133 publications

(97 citation statements)

References 18 publications

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“…The exact prevalence of these mutations is unknown, but they may account for many of the 4 to 7% of mutations not detected by genomic mutation analysis methods. 8,9 All three patients we describe carry mutations that result in aberrant mRNA that would be predicted by the reading-frame rule 1 alone to cause DMD. Patient DC0160 has an in-frame pseudoexon in which a premature stop signal is encoded.…”

Section: Discussionmentioning

confidence: 93%

“…6,7 Combining these modern methods of molecular analysis results in detection of about 93 to 96% of mutations via genomic DNA derived from blood samples. 8,9 The availability of detailed genomic mutation anal-ysis has resulted in the increasingly frequent identification of individuals with DMD but no coding region mutations in the DMD gene, and thus to the increasing recognition of a previously difficult to identify category of DMD mutations: intronic point mutations that create novel splice sites, resulting in the inclusion of intronic sequence as a "pseudoexon" within the mRNA. 10 -12 The large size of the DMD introns still precludes direct intronic sequencing as a practical assay.…”

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confidence: 99%

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DMD pseudoexon mutations: splicing efficiency, phenotype, and potential therapy

Gurvich

Tuohy

Howard

et al. 2007

Annals of Neurology

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Objective: The degenerative muscle diseases Duchenne (DMD) and Becker muscular dystrophy result from mutations in the DMD gene, which encodes the dystrophin protein. Recent improvements in mutational analysis techniques have resulted in the increasing identification of deep intronic point mutations, which alter splicing such that intronic sequences are included in the messenger RNA as "pseudoexons." We sought to test the hypothesis that the clinical phenotype correlates with splicing efficiency of these mutations, and to test the feasibility of antisense oligonucleotide (AON)-mediated pseudoexon skipping. Methods: We identified three pseudoexon insertion mutations in dystrophinopathy patients, two of whom had tissue available for further analysis. For these two out-of-frame pseudoexon mutations (one associated with Becker muscular dystrophy and one with DMD), mutation-induced splicing was tested by quantitative reverse transcription polymerase chain reaction; pseudoexon skipping was tested using AONs composed of 2Ј-O-methyl-modified bases on a phosphorothioate backbone to treat cultured primary myoblasts. Results: Variable amounts of pseudoexon inclusion correlates with the severity of the dystrophinopathy phenotype in these two patients. AON treatment directed at the pseudoexon results in the expression of full-length dystrophin in a DMD myoblast line. Interpretation: Both DMD and Becker muscular dystrophy can result from out-of-frame pseudoexons, with the difference in phenotype being due to variable efficiency of the newly generated splicing signal. AON-mediated pseudoexon skipping therapy is a viable approach to these patients and would be predicted to result in increased expression of wild-type dystrophin protein.

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Section: Discussionmentioning

confidence: 93%

mentioning

confidence: 99%

DMD pseudoexon mutations: splicing efficiency, phenotype, and potential therapy

Gurvich

Tuohy

Howard

et al. 2007

Annals of Neurology

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“…46,47) Furthermore, dystrophin gene sequencing is used to analyze single-condition amplification/internal primers and multiplex amplifiable probe hybridization for detecting point mutations or small deletions/insertions if deletion/ duplication testing is negative. 48,49) Full characterisation of the mutation (deletion endpoints or exact position of any point mutation) is helpful to investigate the clinical variability of dystrophinopathy 50,51) and recent trials about mutation-specific treatment.…”

Section: Genetic Testmentioning

confidence: 99%

Female Carriers of Duchenne Muscular Dystrophy

Cho

Choi

2013

J Genet Med

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males are thought to be DMD carriers. Approximately 2.5-7.8% of female DMD carriers have muscle weakness and are categorized as manifesting DMD carriers.1, 2, 4) Therefore, here we reviewed recent studies to meet the need for a better understanding about the characterization of female carriers of DMD. What is dystrophinopathies?Duchenne's description of DMD was published in 1861. He referred to the disease as "hypertrophic paraplegia of infancy due to a cerebral cause". IntroductionDuchenne muscular dystrophy (DMD) is a recessive X-linked form of muscular dystrophy. The milder form of this disease is called Becker muscular dystrophy(BMD).1) The disorder is also called dystrophinopathy because it caused by mutations in the DMD gene, which encodes dystrophin, on Xp21.2) Most heterozygous female carriers of DMD are subclinical. Therefore, identification of dystrophinopathy carriers may be only con sidered on clinical grounds such as clear X-linked family history of muscular dystrophy. However, myopathic muscle biopsy and advanced molecular diagnostic analysis can be used to identify the carrier state of DMD without a positive family history of dystrophinopathy , which is present in 10% of women with hyperCKemia.3) In addition, two-thirds of mothers of affected www.e-kjgm.org Dystrophinopathy, caused by mutations in the DMD gene, presents with variable clinical phenotypes ranging from the severe Duchenne muscular dystrophy (DMD) to the milder Becker muscular dystrophy(BMD) forms. DMD is a recessive X-linked form of muscular dystrophy. Two-thirds of mothers of affected males are thought to be DMD carriers. Approximately 2.5-7.8% of female DMD carriers have muscle weakness and are categorized as manifesting DMD carriers. The symptoms of female carriers of DMD range from mild muscle weakness to severe gait problems. The most commonly presented symptom is mild proximal muscle weakness, which is often asymmetric and progressive, but shows variable clinical spectrum with BMD of more severe DMD-like phenotype. Atypical presentations in manifesting carriers are myalgia or cramps without limb weakness, isolated cardiomyopathy and camptocormia. Multiplex PCR and MLPA analysis are common techniques to identify mutations in the DMD gene. Relationship between X-chromosome inactivation and clinical severity is not clear. Female carriers of DMD are not less common, and they have an important role of birth of a male DMD.

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“…[20][21][22][23] in muscle myofiber membranes, 57 with consequent loss of muscle integrity and generalized muscle weakness. PTC124 treatment of mdx mice and cultured mdx myotubes promotes production of full-length dystrophin (Fig.…”

Section: Suppression Of Nonsense-mediated Genetic Disordersmentioning

confidence: 99%