Biophysical Investigation of Sodium Channel Interaction with beta-Subunit Variants Associated with Arrhythmias.
Llongueras, J.P., Das, S., De Waele, J., Capulzini, L., Sorgente, A., Van Petegem, F., Bosmans, F.(2020) Bioelectricity 2: 269-278
- PubMed: 34476357 
- DOI: https://doi.org/10.1089/bioe.2020.0030
- Primary Citation of Related Structures:  
6VRR, 6VSV - PubMed Abstract: 
Background: Voltage-gated sodium (Na V ) channels help regulate electrical activity of the plasma membrane. Mutations in associated subunits can result in pathological outcomes. Here we examined the interaction of Na V channels with cardiac arrhythmia-linked mutations in SCN2B and SCN4B , two genes that encode auxiliary β-subunits. Materials and Methods: To investigate changes in SCN2B R137H and SCN4B I80T function, we combined three-dimensional X-ray crystallography with electrophysiological measurements on Na V 1.5, the dominant subtype in the heart. Results: SCN4B I80T alters channel activity, whereas SCN2B R137H does not have an apparent effect. Structurally, the SCN4B I80T perturbation alters hydrophobic packing of the subunit with major structural changes and causes a thermal destabilization of the folding. In contrast, SCN2B R137H leads to structural changes but overall protein stability is unaffected. Conclusion: SCN4B I80T data suggest a functionally important region in the interaction between Na V 1.5 and β4 that, when disrupted, could lead to channel dysfunction. A lack of apparent functional effects of SCN2B R137H on Na V 1.5 suggests an alternative working mechanism, possibly through other Na V channel subtypes present in heart tissue. Indeed, mapping the structural variations of SCN2B R137H onto neuronal Na V channel structures suggests altered interaction patterns.
Organizational Affiliation: 
Department of Physiology, Johns Hopkins University School of Medicine, Baltimore, Maryland, USA.