OBJECTIVES: To identify the disease-causing mutation and its molecular consequence for a clinically distinct type of myotonic myopathy. BACKGROUND: The authors encountered a unique myotonic disorder of early onset in a 37-year-old man and his 47-year-old sister. METHODS: After examining known loci of inherited myotonic disorders, the authors looked for mutations within the CLCN1 gene using single strand conformation polymorphism and direct sequencing. To investigate the disease mechanism, reverse transcriptase PCR analyses of total RNA were performed. RESULTS: In the proband and his affected sister, two novel mutations comprising a compound heterozygous state in the CLCN1 gene were identified: 1) a base (G) insertion in exon 7 generating a premature termination codon (fs289X) in the D5 domain, and 2) a C-to-T substitution in exon 23 resulting in a missense mutation (P932L). These mutations accompanied a clinical phenotype that is distinguishable from recessive myotonia congenita by progressive generalized muscle weakness, severe distal muscle atrophy, joint contractures, high serum creatine kinase levels, and conspicuous myopathic changes on muscle histopathology. Reverse transcriptase PCR analyses detected only the P932L mutant mRNA in skeletal muscle, suggesting that the fs289X mRNA is degraded rapidly. CONCLUSIONS: These data suggest that fs289X is a null mutation, rendering the patients with the compound heterozygous genotype of fs289X/P932L to exclusively express P932L homomeric channels that may have caused the "dystrophic" phenotype.
OBJECTIVES: To identify the disease-causing mutation and its molecular consequence for a clinically distinct type of myotonic myopathy. BACKGROUND: The authors encountered a unique myotonic disorder of early onset in a 37-year-old man and his 47-year-old sister. METHODS: After examining known loci of inherited myotonic disorders, the authors looked for mutations within the CLCN1 gene using single strand conformation polymorphism and direct sequencing. To investigate the disease mechanism, reverse transcriptase PCR analyses of total RNA were performed. RESULTS: In the proband and his affected sister, two novel mutations comprising a compound heterozygous state in the CLCN1 gene were identified: 1) a base (G) insertion in exon 7 generating a premature termination codon (fs289X) in the D5 domain, and 2) a C-to-T substitution in exon 23 resulting in a missense mutation (P932L). These mutations accompanied a clinical phenotype that is distinguishable from recessive myotonia congenita by progressive generalized muscle weakness, severe distal muscle atrophy, joint contractures, high serum creatine kinase levels, and conspicuous myopathic changes on muscle histopathology. Reverse transcriptase PCR analyses detected only the P932L mutant mRNA in skeletal muscle, suggesting that the fs289X mRNA is degraded rapidly. CONCLUSIONS: These data suggest that fs289X is a null mutation, rendering the patients with the compound heterozygous genotype of fs289X/P932L to exclusively express P932L homomeric channels that may have caused the "dystrophic" phenotype.
Authors: Emma Matthews; James A L Miller; Malcolm R MacLeod; James Ironside; Gareth Ambler; Robin Labrum; Richa Sud; Janice L Holton; Michael G Hanna Journal: Muscle Nerve Date: 2011-06-22 Impact factor: 3.217
Authors: E Matthews; D Fialho; S V Tan; S L Venance; S C Cannon; D Sternberg; B Fontaine; A A Amato; R J Barohn; R C Griggs; M G Hanna Journal: Brain Date: 2009-11-16 Impact factor: 13.501
Authors: María J Macías; Oscar Teijido; Giovanni Zifarelli; Pau Martin; Ximena Ramirez-Espain; Antonio Zorzano; Manuel Palacín; Michael Pusch; Raúl Estévez Journal: Biochem J Date: 2007-04-01 Impact factor: 3.857
Authors: Silvia Corrochano; Roope Männikkö; Peter I Joyce; Philip McGoldrick; Jessica Wettstein; Glenda Lassi; Dipa L Raja Rayan; Gonzalo Blanco; Colin Quinn; Andrianos Liavas; Arimantas Lionikas; Neta Amior; James Dick; Estelle G Healy; Michelle Stewart; Sarah Carter; Marie Hutchinson; Liz Bentley; Pietro Fratta; Andrea Cortese; Roger Cox; Steve D M Brown; Valter Tucci; Henning Wackerhage; Anthony A Amato; Linda Greensmith; Martin Koltzenburg; Michael G Hanna; Abraham Acevedo-Arozena Journal: Brain Date: 2014-10-27 Impact factor: 13.501