Mice Lacking Sodium Channel β1 Subunits Display Defects in Neuronal Excitability, Sodium Channel Expression, and Nodal Architecture

• Published in: The Journal of neuroscience Vol. 24; no. 16; pp. 4030 - 4042
• Main Authors: Chen, Chunling, Westenbroek, Ruth E., Xu, Xiaorong, Edwards, Chris A., Sorenson, Dorothy R., Chen, Yuan, McEwen, Dyke P., O'Malley, Heather A., Bharucha, Vandana, Meadows, Laurence S., Knudsen, Gabriel A., Vilaythong, Alex, Noebels, Jeffrey L., Saunders, Thomas L., Scheuer, Todd, Shrager, Peter, Catterall, William A., Isom, Lori L.
• Format: Journal Article
• Language: English
• Published: Society for Neuroscience 21.04.2004
• Subjects: Cellular/Molecular
• ISSN: 0270-6474; 1529-2401
• DOI: 10.1523/JNEUROSCI.4139-03.2004

Sodium channel β1 subunits modulate α subunit gating and cell surface expression and participate in cell adhesive interactions in vitro . β1(-/-) mice appear ataxic and display spontaneous generalized seizures. In the optic nerve, the fastest components of the compound action potential are slowed and the number of mature nodes of Ranvier is reduced, but Na v 1.6, contactin, caspr 1, and K v 1 channels are all localized normally at nodes. At the ultrastructural level, the paranodal septate-like junctions immediately adjacent to the node are missing in a subset of axons, suggesting that β1 may participate in axo-glial communication at the periphery of the nodal gap. Sodium currents in dissociated hippocampal neurons are normal, but Na v 1.1 expression is reduced and Na v 1.3 expression is increased in a subset of pyramidal neurons in the CA2/CA3 region, suggesting a basis for the epileptic phenotype. Our results show that β1 subunits play important roles in the regulation of sodium channel density and localization, are involved in axo-glial communication at nodes of Ranvier, and are required for normal action potential conduction and control of excitability in vivo .