Congenital Long-QT Syndrome Caused by a Novel Mutation in a Conserved Acidic Domain of the Cardiac Na+ Channel

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Circulation. 1999;99:3165-3171

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(Circulation. 1999;99:3165-3171.)
© 1999 American Heart Association, Inc.

Clinical Investigation and Reports

Congenital Long-QT Syndrome Caused by a Novel Mutation in a Conserved Acidic Domain of the Cardiac Na⁺ Channel

Jian Wei, MD, PhD; Dao W. Wang, MD; Marco Alings, MD, PhD; Frank Fish, MD, PhD; Mark Wathen, MD; Dan M. Roden, MD; Alfred L. George, Jr, MD

From the Departments of Medicine (J.W., D.M.R., A.L.G.), Pharmacology (D.W.W., D.M.R., A.L.G.), and Pediatrics (F.F.), Vanderbilt University School of Medicine, Nashville, Tenn, and the Academic Medical Center, University of Amsterdam, The Netherlands (M.A.).

Correspondence to Alfred L. George, Jr, 452 MRB-II, Vanderbilt University Medical Center, 23rd Ave S at Pierce Ave, Nashville, TN 37232. E-mail al.george{at}mcmail.vanderbilt.edu

Background—Congenital long-QT syndrome (LQTS) is an inheritedcondition of abnormal cardiac excitability characterized clinicallyby an increased risk of ventricular tachyarrhythmias. One form, LQT3,is caused by mutations in the cardiac voltage–dependentsodium channel gene, SCN5A. Only 5 SCN5A mutations have beenassociated with LQTS, and more work is needed to improve correlationsbetween SCN5A genotypes and associated clinical syndromes.

Methods and Results—We researched a 3-generation whitefamily with autosomal dominant LQTS who exhibited a wide clinicalspectrum from mild bradycardia to sudden death. Molecular geneticstudies revealed a single nucleotide substitution in SCN5A exon28 that caused the substitution of Glu1784 by Lys (E1784K).The mutation occurs in a highly conserved domain within theC-terminus of the cardiac sodium channel containing multiple,negatively charged amino acids. Two-electrode voltage-clamprecordings of a recombinant E1784K mutant channel expressedin Xenopus oocytes revealed a defect in fast inactivation characterizedby a small, persistent current during long membrane depolarizations.Coexpression of the mutant with the human sodium channel ß₁-subunitdid not affect the persistent current, even though we did observeshifts in the voltage dependence of steady-state inactivation.Neutralizing multiple, negatively charged residues in the sameregion of the sodium channel C-terminus did not cause a moresevere functional defect.

Conclusions—We characterized the genetics and molecular pathophysiologyof a novel SCN5A sodium channel mutation, E1784K. The functionaldefect exhibited by the mutant channel causes delayed myocardialrepolarization, and our data on the effects of multiple chargeneutralizations in this region of the C-terminus suggest thatthe molecular mechanism of channel dysfunction involves an allostericrather than a direct effect on channel gating.

Key Words: long-QT syndrome • sodium channel • SCN5A • genes • heart defects, congenital

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