Genetically determined differences in sodium current characteristics modulate conduction disease severity in mice with cardiac sodium channelopathy

Carol Ann Remme; Brendon P. Scicluna; Arie O. Verkerk; Ahmad S. Amin; Sandra Van Brunschot; Leander Beekman; Vera H.M. Deneer; Catherine Chevalier; Fumitaka Oyama; Haruko Miyazaki; Nobuyuki Nukina; Ronald Wilders; Denis Escande; Rémi Houlgatte; Arthur A.M. Wilde; Hanno L. Tan; Marieke W. Veldkamp; Jacques M.T. De Bakker; Connie R. Bezzina

doi:10.1161/CIRCRESAHA.109.194423

Genetically determined differences in sodium current characteristics modulate conduction disease severity in mice with cardiac sodium channelopathy

Carol Ann Remme, Brendon P. Scicluna, Arie O. Verkerk, Ahmad S. Amin, Sandra Van Brunschot, Leander Beekman, Vera H.M. Deneer, Catherine Chevalier, Fumitaka Oyama, Haruko Miyazaki, Nobuyuki Nukina, Ronald Wilders, Denis Escande, Rémi Houlgatte, Arthur A.M. Wilde, Hanno L. Tan, Marieke W. Veldkamp, Jacques M.T. De Bakker, Connie R. Bezzina

Research output: Contribution to journal › Article › peer-review

71 Citations (Scopus)

Abstract

Conduction slowing of the electric impulse that drives the heartbeat may evoke lethal cardiac arrhythmias. Mutations in SCN5A, which encodes the pore-forming cardiac sodium channel α subunit, are associated with familial arrhythmia syndromes based on conduction slowing. However, disease severity among mutation carriers is highly variable. We hypothesized that genetic modifiers underlie the variability in conduction slowing and disease severity. With the aim of identifying such modifiers, we studied the Scn5a mutation in 2 distinct mouse strains, FVB/N and 129P2. In 129P2 mice, the mutation resulted in more severe conduction slowing particularly in the right ventricle (RV) compared to FVB/N. Pan-genomic mRNA expression profiling in the 2 mouse strains uncovered a drastic reduction in mRNA encoding the sodium channel auxiliary subunit β4 (Scn4b) in 129P2 mice compared to FVB/N. This corresponded to low to undetectable β4 protein levels in 129P2 ventricular tissue, whereas abundant β4 protein was detected in FVB/N. Sodium current measurements in isolated myocytes from the 2 mouse strains indicated that sodium channel activation in myocytes from 129P2 mice occurred at more positive potentials compared to FVB/N. Using computer simulations, this difference in activation kinetics was predicted to explain the observed differences in conduction disease severity between the 2 strains. In conclusion, genetically determined differences in sodium current characteristics on the myocyte level modulate disease severity in cardiac sodium channelopathies. In particular, the sodium channel subunit β4 (SCN4B) may constitute a potential genetic modifier of conduction and cardiac sodium channel disease.

Original language	English
Pages (from-to)	1283-1292
Number of pages	10
Journal	Circulation research
Volume	104
Issue number	11
DOIs	https://doi.org/10.1161/CIRCRESAHA.109.194423
Publication status	Published - Jun 5 2009
Externally published	Yes

Keywords

Conduction
Gene expression
Genetics
Mouse mutants
Sodium channels

ASJC Scopus subject areas

Physiology
Cardiology and Cardiovascular Medicine

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10.1161/CIRCRESAHA.109.194423

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Remme, C. A., Scicluna, B. P., Verkerk, A. O., Amin, A. S., Van Brunschot, S., Beekman, L., Deneer, V. H. M., Chevalier, C., Oyama, F., Miyazaki, H., Nukina, N., Wilders, R., Escande, D., Houlgatte, R., Wilde, A. A. M., Tan, H. L., Veldkamp, M. W., De Bakker, J. M. T., & Bezzina, C. R. (2009). Genetically determined differences in sodium current characteristics modulate conduction disease severity in mice with cardiac sodium channelopathy. Circulation research, 104(11), 1283-1292. https://doi.org/10.1161/CIRCRESAHA.109.194423

Remme, CA, Scicluna, BP, Verkerk, AO, Amin, AS, Van Brunschot, S, Beekman, L, Deneer, VHM, Chevalier, C, Oyama, F, Miyazaki, H, Nukina, N, Wilders, R, Escande, D, Houlgatte, R, Wilde, AAM, Tan, HL, Veldkamp, MW, De Bakker, JMT & Bezzina, CR 2009, 'Genetically determined differences in sodium current characteristics modulate conduction disease severity in mice with cardiac sodium channelopathy', Circulation research, vol. 104, no. 11, pp. 1283-1292. https://doi.org/10.1161/CIRCRESAHA.109.194423

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title = "Genetically determined differences in sodium current characteristics modulate conduction disease severity in mice with cardiac sodium channelopathy",

abstract = "Conduction slowing of the electric impulse that drives the heartbeat may evoke lethal cardiac arrhythmias. Mutations in SCN5A, which encodes the pore-forming cardiac sodium channel α subunit, are associated with familial arrhythmia syndromes based on conduction slowing. However, disease severity among mutation carriers is highly variable. We hypothesized that genetic modifiers underlie the variability in conduction slowing and disease severity. With the aim of identifying such modifiers, we studied the Scn5a mutation in 2 distinct mouse strains, FVB/N and 129P2. In 129P2 mice, the mutation resulted in more severe conduction slowing particularly in the right ventricle (RV) compared to FVB/N. Pan-genomic mRNA expression profiling in the 2 mouse strains uncovered a drastic reduction in mRNA encoding the sodium channel auxiliary subunit β4 (Scn4b) in 129P2 mice compared to FVB/N. This corresponded to low to undetectable β4 protein levels in 129P2 ventricular tissue, whereas abundant β4 protein was detected in FVB/N. Sodium current measurements in isolated myocytes from the 2 mouse strains indicated that sodium channel activation in myocytes from 129P2 mice occurred at more positive potentials compared to FVB/N. Using computer simulations, this difference in activation kinetics was predicted to explain the observed differences in conduction disease severity between the 2 strains. In conclusion, genetically determined differences in sodium current characteristics on the myocyte level modulate disease severity in cardiac sodium channelopathies. In particular, the sodium channel subunit β4 (SCN4B) may constitute a potential genetic modifier of conduction and cardiac sodium channel disease.",

keywords = "Conduction, Gene expression, Genetics, Mouse mutants, Sodium channels",

author = "Remme, {Carol Ann} and Scicluna, {Brendon P.} and Verkerk, {Arie O.} and Amin, {Ahmad S.} and {Van Brunschot}, Sandra and Leander Beekman and Deneer, {Vera H.M.} and Catherine Chevalier and Fumitaka Oyama and Haruko Miyazaki and Nobuyuki Nukina and Ronald Wilders and Denis Escande and R{\'e}mi Houlgatte and Wilde, {Arthur A.M.} and Tan, {Hanno L.} and Veldkamp, {Marieke W.} and {De Bakker}, {Jacques M.T.} and Bezzina, {Connie R.}",

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doi = "10.1161/CIRCRESAHA.109.194423",

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T1 - Genetically determined differences in sodium current characteristics modulate conduction disease severity in mice with cardiac sodium channelopathy

AU - Remme, Carol Ann

AU - Scicluna, Brendon P.

AU - Verkerk, Arie O.

AU - Amin, Ahmad S.

AU - Van Brunschot, Sandra

AU - Beekman, Leander

AU - Deneer, Vera H.M.

AU - Chevalier, Catherine

AU - Oyama, Fumitaka

AU - Miyazaki, Haruko

AU - Nukina, Nobuyuki

AU - Wilders, Ronald

AU - Escande, Denis

AU - Houlgatte, Rémi

AU - Wilde, Arthur A.M.

AU - Tan, Hanno L.

AU - Veldkamp, Marieke W.

AU - De Bakker, Jacques M.T.

AU - Bezzina, Connie R.

PY - 2009/6/5

Y1 - 2009/6/5

N2 - Conduction slowing of the electric impulse that drives the heartbeat may evoke lethal cardiac arrhythmias. Mutations in SCN5A, which encodes the pore-forming cardiac sodium channel α subunit, are associated with familial arrhythmia syndromes based on conduction slowing. However, disease severity among mutation carriers is highly variable. We hypothesized that genetic modifiers underlie the variability in conduction slowing and disease severity. With the aim of identifying such modifiers, we studied the Scn5a mutation in 2 distinct mouse strains, FVB/N and 129P2. In 129P2 mice, the mutation resulted in more severe conduction slowing particularly in the right ventricle (RV) compared to FVB/N. Pan-genomic mRNA expression profiling in the 2 mouse strains uncovered a drastic reduction in mRNA encoding the sodium channel auxiliary subunit β4 (Scn4b) in 129P2 mice compared to FVB/N. This corresponded to low to undetectable β4 protein levels in 129P2 ventricular tissue, whereas abundant β4 protein was detected in FVB/N. Sodium current measurements in isolated myocytes from the 2 mouse strains indicated that sodium channel activation in myocytes from 129P2 mice occurred at more positive potentials compared to FVB/N. Using computer simulations, this difference in activation kinetics was predicted to explain the observed differences in conduction disease severity between the 2 strains. In conclusion, genetically determined differences in sodium current characteristics on the myocyte level modulate disease severity in cardiac sodium channelopathies. In particular, the sodium channel subunit β4 (SCN4B) may constitute a potential genetic modifier of conduction and cardiac sodium channel disease.

AB - Conduction slowing of the electric impulse that drives the heartbeat may evoke lethal cardiac arrhythmias. Mutations in SCN5A, which encodes the pore-forming cardiac sodium channel α subunit, are associated with familial arrhythmia syndromes based on conduction slowing. However, disease severity among mutation carriers is highly variable. We hypothesized that genetic modifiers underlie the variability in conduction slowing and disease severity. With the aim of identifying such modifiers, we studied the Scn5a mutation in 2 distinct mouse strains, FVB/N and 129P2. In 129P2 mice, the mutation resulted in more severe conduction slowing particularly in the right ventricle (RV) compared to FVB/N. Pan-genomic mRNA expression profiling in the 2 mouse strains uncovered a drastic reduction in mRNA encoding the sodium channel auxiliary subunit β4 (Scn4b) in 129P2 mice compared to FVB/N. This corresponded to low to undetectable β4 protein levels in 129P2 ventricular tissue, whereas abundant β4 protein was detected in FVB/N. Sodium current measurements in isolated myocytes from the 2 mouse strains indicated that sodium channel activation in myocytes from 129P2 mice occurred at more positive potentials compared to FVB/N. Using computer simulations, this difference in activation kinetics was predicted to explain the observed differences in conduction disease severity between the 2 strains. In conclusion, genetically determined differences in sodium current characteristics on the myocyte level modulate disease severity in cardiac sodium channelopathies. In particular, the sodium channel subunit β4 (SCN4B) may constitute a potential genetic modifier of conduction and cardiac sodium channel disease.

KW - Conduction

KW - Gene expression

KW - Genetics

KW - Mouse mutants

KW - Sodium channels

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Genetically determined differences in sodium current characteristics modulate conduction disease severity in mice with cardiac sodium channelopathy

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