Voltage-gated sodium channels (VGSCs) generate and propagate electrical activity in excitable cells. The precise dynamics of VGSC transitions among closed, open, and inactivated states are essential for brain, nerve, heart, and muscle function, as documented by a wide range of clinical sodium channelopathy disorders. While the VGSC alpha subunit in isolation comprises the channel's pore, its voltage sensors, and its inactivation machinery, interaction with fibroblast growth factor homologous factors (FHFs) has large and complex effects on the dynamics of VGSC inactivation. Indeed, FHF mutations are a cause of human spinocerebellar ataxia and cause defects in neuronal intrinsic excitability. While all FHF isoforms bind VGSCs, they differ in their abilities to modulate VGSC fast inactivation and to induce a newly characterized long-term inactivated channel state. This application proposes experiments to expand analysis of FHF neuronal functions and physical mechanisms of FHF- induced VGSC modulation.
AIM I : Our overall biological hypothesis is that differential expression of FHF isoforms in different neurons and their subcellular compartments acts to determine excitation and conduction properties of cells. We will test: (I-A) Does the relative abundance of different long-form FHFs (A-type FHFs, FHF4B) at the axon initial segment specify the excitation properties of a neuron? (I-B) Does somatodendritic membrane localization of A-type FHFs act to limit sodium action potential backpropagation during repetitive firing of neurons? (I-C) Are long-form FHFs not required for, and potentially deleterious to, action potential axonal conduction? AIM II: A clearer understanding of physical mechanisms for VGSC modulation by FHFs will provide further insight into VGSC conformation dynamics and suggest rational approaches for designing therapeutics for managing disorders of hyperexcitability, such as epilepsies and arrhythmias. We will test: (II-A) Does the long- term inactivation particle at the distal N-terminus of A-type FHFs dock within the cytoplasmic cavern of a VGSC? (II-B) Do the cationic residues in the docked A-type FHF inactivation particle act as a shield against sodium ion conduction? (II-C) How does a cationic region near the ?-trefoil core of FHFs modulate VGSC fast inactivation?

Public Health Relevance

Voltage-gated sodium channels (VGSCs) generate and propagate electrical activity in excitable cells. The speed by which VGSCs shuttle among closed, open, and inactive states is modulated by a family of proteins called FHFs. We propose experiments to further determine the roles of FHFs in the control of nerve cell electrical activity and to determine the physical mechanisms exploited by FHFs to modulate VGSC conformational dynamics.

Agency
National Institute of Health (NIH)
Institute
National Institute of General Medical Sciences (NIGMS)
Type
Research Project (R01)
Project #
5R01GM098540-02
Application #
8323375
Study Section
Biophysics of Neural Systems Study Section (BPNS)
Program Officer
Deatherage, James F
Project Start
2011-09-01
Project End
2015-05-31
Budget Start
2012-06-01
Budget End
2013-05-31
Support Year
2
Fiscal Year
2012
Total Cost
$278,616
Indirect Cost
$88,616
Name
Hunter College
Department
Biology
Type
Schools of Arts and Sciences
DUNS #
620127915
City
New York
State
NY
Country
United States
Zip Code
10065
Dover, Katarzyna; Marra, Christopher; Solinas, Sergio et al. (2016) FHF-independent conduction of action potentials along the leak-resistant cerebellar granule cell axon. Nat Commun 7:12895
Park, David S; Shekhar, Akshay; Marra, Christopher et al. (2016) Fhf2 gene deletion causes temperature-sensitive cardiac conduction failure. Nat Commun 7:12966
Siekierska, Aleksandra; Isrie, Mala; Liu, Yue et al. (2016) Gain-of-function FHF1 mutation causes early-onset epileptic encephalopathy with cerebellar atrophy. Neurology 86:2162-70
Venkatesan, Kumar; Liu, Yue; Goldfarb, Mitchell (2014) Fast-onset long-term open-state block of sodium channels by A-type FHFs mediates classical spike accommodation in hippocampal pyramidal neurons. J Neurosci 34:16126-39
Goldfarb, Mitchell (2012) Voltage-gated sodium channel-associated proteins and alternative mechanisms of inactivation and block. Cell Mol Life Sci 69:1067-76