BACKGROUND: Brugada syndrome is associated with a high risk of sudden cardiac death and is caused by mutations in the cardiac voltage-gated sodium channel gene. Previously, the R282H-SCN5A mutation in the sodium channel gene was identified in patients with Brugada syndrome. In a family carrying the R282H-SCN5A mutation, an asymptomatic individual had a common H558R-SCN5A polymorphism and the mutation on separate chromosomes. Therefore, we hypothesized that the polymorphism could rescue the mutation. METHODS AND RESULTS: In heterologous cells, expression of the mutation alone did not produce sodium current. However, coexpressing the mutation with the polymorphism produced significantly greater current than coexpressing the mutant with the wild-type gene, demonstrating that the polymorphism rescues the mutation. Using immunocytochemistry, we demonstrated that the R282H-SCN5A construct can traffic to the cell membrane only in the presence of the H558R-SCN5A polymorphism. Using fluorescence resonance energy transfer and protein fragments centered on H558R-SCN5A, we demonstrated that cardiac sodium channels preferentially interact when the polymorphism is expressed on one protein but not the other. CONCLUSIONS: This study suggests a mechanism whereby the Brugada syndrome has incomplete penetrance. More importantly, this study suggests that genetic polymorphisms may be a potential target for future therapies aimed at rescuing specific dysfunctional protein channels.
BACKGROUND:Brugada syndrome is associated with a high risk of sudden cardiac death and is caused by mutations in the cardiac voltage-gated sodium channel gene. Previously, the R282H-SCN5A mutation in the sodium channel gene was identified in patients with Brugada syndrome. In a family carrying the R282H-SCN5A mutation, an asymptomatic individual had a common H558R-SCN5A polymorphism and the mutation on separate chromosomes. Therefore, we hypothesized that the polymorphism could rescue the mutation. METHODS AND RESULTS: In heterologous cells, expression of the mutation alone did not produce sodium current. However, coexpressing the mutation with the polymorphism produced significantly greater current than coexpressing the mutant with the wild-type gene, demonstrating that the polymorphism rescues the mutation. Using immunocytochemistry, we demonstrated that the R282H-SCN5A construct can traffic to the cell membrane only in the presence of the H558R-SCN5A polymorphism. Using fluorescence resonance energy transfer and protein fragments centered on H558R-SCN5A, we demonstrated that cardiac sodium channels preferentially interact when the polymorphism is expressed on one protein but not the other. CONCLUSIONS: This study suggests a mechanism whereby the Brugada syndrome has incomplete penetrance. More importantly, this study suggests that genetic polymorphisms may be a potential target for future therapies aimed at rescuing specific dysfunctional protein channels.
Authors: Dan Hu; Sami Viskin; Antonio Oliva; Tabitha Carrier; Jonathan M Cordeiro; Hector Barajas-Martinez; Yuesheng Wu; Elena Burashnikov; Serge Sicouri; Ramon Brugada; Rafael Rosso; Alejandra Guerchicoff; Guido D Pollevick; Charles Antzelevitch Journal: Heart Rhythm Date: 2007-04-10 Impact factor: 6.343
Authors: Arnold E Pfahnl; Prakash C Viswanathan; Raul Weiss; Lijuan L Shang; Shamarendra Sanyal; Vladimir Shusterman; Cari Kornblit; Barry London; Samuel C Dudley Journal: Heart Rhythm Date: 2006-09-28 Impact factor: 6.343
Authors: Dan Hu; Sami Viskin; Antonio Oliva; Jonathan M Cordeiro; Alejandra Guerchicoff; Guido D Pollevick; Charles Antzelevitch Journal: J Electrocardiol Date: 2007 Nov-Dec Impact factor: 1.438
Authors: Jianding Cheng; David W Van Norstrand; Argelia Medeiros-Domingo; Carmen Valdivia; Bi-hua Tan; Bin Ye; Stacie Kroboth; Matteo Vatta; David J Tester; Craig T January; Jonathan C Makielski; Michael J Ackerman Journal: Circ Arrhythm Electrophysiol Date: 2009-12