OBJECTIVE: To identify the molecular and physiologic abnormality in familial myotonia with cold sensitivity, hypertrophy, and no weakness. BACKGROUND: Sodium channel mutations were previously identified as the cause of several allelic disorders with varying combinations of myotonia and periodic paralysis. A three-generation family with dominant myotonia aggravated by cooling, but no weakness, was screened for mutations in the skeletal muscle sodium channel alpha-subunit gene (SCN4A). METHODS: Single-strand conformation polymorphism was used to screen all 24 exons of SCN4A and abnormal conformers were sequenced to confirm the presence of mutations. The functional consequence of a SCN4A mutation was explored by recording sodium currents from human embryonic kidney cells transiently transfected with an expression construct that was mutated to reproduce the genetic defect. RESULTS: A three-generation Italian family with myotonia is presented, in which a novel SCN4A mutation (leucine 266 substituted by valine, L266V) is identified. This change removes only a single methylene group from the 1,836-amino-acid protein, and is present in a region of the protein previously not known to be critical for channel function (domain I transmembrane segment 5). Electrophysiologic studies of the L266V mutation showed defects in fast inactivation, consistent with other disease-causing SCN4A mutations studied to date. Slow inactivation was not impaired. CONCLUSIONS: This novel mutation of the sodium channel indicates that a single carbon change in a transmembrane alpha-helix of domain I can alter channel inactivation and cause cold-sensitive myotonia.
OBJECTIVE: To identify the molecular and physiologic abnormality in familial myotonia with cold sensitivity, hypertrophy, and no weakness. BACKGROUND: Sodium channel mutations were previously identified as the cause of several allelic disorders with varying combinations of myotonia and periodic paralysis. A three-generation family with dominant myotonia aggravated by cooling, but no weakness, was screened for mutations in the skeletal muscle sodium channel alpha-subunit gene (SCN4A). METHODS: Single-strand conformation polymorphism was used to screen all 24 exons of SCN4A and abnormal conformers were sequenced to confirm the presence of mutations. The functional consequence of a SCN4A mutation was explored by recording sodium currents from human embryonic kidney cells transiently transfected with an expression construct that was mutated to reproduce the genetic defect. RESULTS: A three-generation Italian family with myotonia is presented, in which a novel SCN4A mutation (leucine 266 substituted by valine, L266V) is identified. This change removes only a single methylene group from the 1,836-amino-acid protein, and is present in a region of the protein previously not known to be critical for channel function (domain I transmembrane segment 5). Electrophysiologic studies of the L266V mutation showed defects in fast inactivation, consistent with other disease-causing SCN4A mutations studied to date. Slow inactivation was not impaired. CONCLUSIONS: This novel mutation of the sodium channel indicates that a single carbon change in a transmembrane alpha-helix of domain I can alter channel inactivation and cause cold-sensitive myotonia.
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: Jaya R Trivedi; Brian Bundy; Jeffrey Statland; Mohammad Salajegheh; Dipa Raja Rayan; Shannon L Venance; Yunxia Wang; Doreen Fialho; Emma Matthews; James Cleland; Nina Gorham; Laura Herbelin; Stephen Cannon; Anthony Amato; Robert C Griggs; Michael G Hanna; Richard J Barohn Journal: Brain Date: 2013-06-13 Impact factor: 13.501
Authors: Serena Pagliarani; Sabrina Lucchiari; Marina Scarlato; Elisa Redaelli; Anna Modoni; Francesca Magri; Barbara Fossati; Stefano C Previtali; Valeria A Sansone; Marzia Lecchi; Mauro Lo Monaco; Giovanni Meola; Giacomo P Comi Journal: Front Neurol Date: 2020-04-29 Impact factor: 4.003