Add to ORKGMissense mutations in the skeletal muscle Na+ channel alpha subunit occur in several heritable forms of myotonia and periodic paralysis. Distinct phenotypes arise from mutations at two sites within the III-IV cytoplasmic loop: myotonia without weakness due to substitutions at glycine 1306, and myotonia plus weakness caused by a mutation at threonine 1313. Heterologous expression in HEK cells showed that substitutions at either site disrupted inactivation, as reflected by slower inactivation rates, shifts in steady-state inactivation, and larger persistent Na+ currents. For T1313M, however, the changes were an order of magnitude larger than any of three substitutions at G1306, and recovery from inactivation was hastened as well. Model simula...
Ion channels play a vital role by fulfilling distinct biological functions like providing the basis ...
International audienceMutations in Na V 1.4, the skeletal muscle voltage-gated Na + channel, underli...
Muscle fibers from individuals with hyperkalemic periodic paralysis generate repetitive trains of ac...
AbstractOver 20 different missense mutations in the α subunit of the adult skeletal muscle Na channe...
Several heritable forms of myotonia and hyperkalemic periodic paralysis (HyperPP) are caused by miss...
Spectrum of sodium channel disturbances in the nondystrophic myotonias and periodic paralyses. Sever...
In sodium channelopathies, a severe fixed myopathy caused by a dominant mutation is rare. We describ...
In sodium channelopathies, a severe fixed myopathy caused by a dominant mutation is rare. We describ...
BACKGROUND: Mutations in SCN4A may lead to myotonia. METHODS: Presentation of a large family with my...
Item does not contain fulltextIn sodium channelopathies, a severe fixed myopathy caused by a dominan...
Spectrum of sodium channel disturbances in the nondystrophic myotonias and periodic paralyses. Sever...
AbstractAn unusual form of painful congenital myotonia is associated with a novel SCN4A mutation cau...
AbstractOver 20 different missense mutations in the α subunit of the adult skeletal muscle Na channe...
The skeletal muscle sodium channel mutant I1160V cosegregates with a disease phenotype producing myo...
Muscle fibers from individuals with hyperkalemic periodic paralysis generate repetitive trains of ac...
Ion channels play a vital role by fulfilling distinct biological functions like providing the basis ...
International audienceMutations in Na V 1.4, the skeletal muscle voltage-gated Na + channel, underli...
Muscle fibers from individuals with hyperkalemic periodic paralysis generate repetitive trains of ac...
AbstractOver 20 different missense mutations in the α subunit of the adult skeletal muscle Na channe...
Several heritable forms of myotonia and hyperkalemic periodic paralysis (HyperPP) are caused by miss...
Spectrum of sodium channel disturbances in the nondystrophic myotonias and periodic paralyses. Sever...
In sodium channelopathies, a severe fixed myopathy caused by a dominant mutation is rare. We describ...
In sodium channelopathies, a severe fixed myopathy caused by a dominant mutation is rare. We describ...
BACKGROUND: Mutations in SCN4A may lead to myotonia. METHODS: Presentation of a large family with my...
Item does not contain fulltextIn sodium channelopathies, a severe fixed myopathy caused by a dominan...
Spectrum of sodium channel disturbances in the nondystrophic myotonias and periodic paralyses. Sever...
AbstractAn unusual form of painful congenital myotonia is associated with a novel SCN4A mutation cau...
AbstractOver 20 different missense mutations in the α subunit of the adult skeletal muscle Na channe...
The skeletal muscle sodium channel mutant I1160V cosegregates with a disease phenotype producing myo...
Muscle fibers from individuals with hyperkalemic periodic paralysis generate repetitive trains of ac...
Ion channels play a vital role by fulfilling distinct biological functions like providing the basis ...
International audienceMutations in Na V 1.4, the skeletal muscle voltage-gated Na + channel, underli...
Muscle fibers from individuals with hyperkalemic periodic paralysis generate repetitive trains of ac...