Mutant channels contribute <50% to Na+ current in paramyotonia congenita muscle

doi:10.1093/brain/122.6.1085

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Brain, Vol. 122, No. 6, 1085-1092, June 1999
© 1999 Oxford University Press

Mutant channels contribute <50% to Na⁺ current in paramyotonia congenita muscle

Nenad Mitrovic¹^,3, Alfred L. George, Jr⁴, Reinhardt Rüdel², Frank Lehmann-Horn¹ and Holger Lerche¹^,3

¹ Departments of Applied and ² General Physiology and ³ Neurology, University of Ulm, Germany and ⁴ Departments of Medicine and Pharmacology, Vanderbilt University, Nashville, Tenn., USA

Correspondence to: Dr Nenad Mitrovic, Department of Applied Physiology/Neurology, University of Ulm, D-89069 Ulm, Germany E-mail: nenad.mitrovic{at}medizin.uni-ulm.de

An important question in the pathophysiology of dominantly inheriteddiseases, such as channelopathies, is the level of expressionof the mutant protein. In our study, we address this issue bycomparing the gating defects of two human muscle Na⁺ channelmutants (R1448C and R1448P) causing paramyotonia congenita innative muscle specimens from two patients with those of thesame mutant recombinant channels expressed in human embryonickidney (HEK-293) cells. Patch-clamp recordings of transfectedHEK-293 cells revealed a pronounced slowing of the Na⁺ currentdecay, a left-shifted and decreased voltage dependence of steady-stateinactivation, and an increased frequency of channel reopeningsfor mutant compared with wild-type channels. For R1448P channels,inactivation was almost six-fold and for R1448C it was three-foldslower than for wild-type channels. The same defects, thoughless pronounced, as expected for a disorder with dominant inheritance,were observed for muscle specimens from paramyotonia congenitapatients carrying these mutations. Quantitative kinetic analysisof Na⁺ channel inactivation in the paramyotonic muscle specimensseparating wild-type from mutant channels suggested that nomore than 38% of the channels in the paramyotonia congenitamuscle specimen were of the mutant type. Our data raise thepossibility that variability in the ratio of mutant to wild-typeNa⁺ channels in the muscle membrane has an impact on the clinicalseverity of the phenotype.

Na⁺ channel; inactivation; channelopathies; patch-clamp; human skeletal muscle

I_SS/I_PEAK = relative persistent Na⁺ current

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