Abstract

The broad, long-term objectives of this proposal are to (1) characterize the structure-function relationship of the parts of sodium channels that control slow inactivation and to (2) assess the potential contribution of sodium channel slow inactivation in the mechanisms of epilepsy.
The Specific Aims are: 1) to measure the properties of sodium channels during slow inactivation and to measure the voltage sensitivity and kinetics of slow inactivation, 2) to express channels with mutations of the S4 region of repeats M and IV to determine whether that part of the sodium channel molecule controls slow inactivation, and 3) to determine the differences between the F(Vh) curves measured from normal neurons and neurons from spontaneously epileptic (tottering) mice, and to identify anti-epileptic agents that affect the voltage dependence and kinetics of slow inactivation. The health-relatedness of this proposal is its application to epilepsy; a critical factor in neuronal hyperexcitability (that could lead to epilepsy) is a right-shift in the midpoint of the F(Vh) curve which leads to an increase in the number of channels available for activation from resting potential. The kinetics, effective valence, and voltage dependence of the F(Vh) curve in crayfish giant axons will be measured using axial-wire voltage clamp. The effects of anti-epileptic drugs such as diphenyl- hydantoin, carbamasepine and sodium valporate on properties of the F(Vh) curve in crayfish will be studied. Native and mutated sodium channels will be expressed in Xenopus oocytes, and macroscopic currents will be recorded using two-electrode voltage clamp and outside-out patch configuration. Slow inactivation properties will be compared between wild-type channels and those with S4, repeats III and/or IV amino acid replacement and deletion mutations produced by site-directed mutagenesis. Properties controlling slow inactivation will be compared between neurons cultured from non-phenotypic tottering (spontaneously epileptic) mice using patch clamp techniques.

  Funding Agency

Agency
National Institute of Health (NIH)
Institute
National Institute of Neurological Disorders and Stroke (NINDS)
Type
Research Project (R01)
Project #
5R01NS029204-02
Application #
3415974
Study Section
Neurology B Subcommittee 2 (NEUB)
Project Start
1991-09-03
Project End
1994-06-30
Budget Start
1992-07-01
Budget End
1993-06-30
Support Year
2
Fiscal Year
1992
Total Cost
Indirect Cost

  Institution

Name
University of Hawaii
Department
Type
Organized Research Units
DUNS #
121911077
City
Honolulu
State
HI
Country
United States
Zip Code
96822

  Publications

Groome, James R; Dice, Margaret C; Fujimoto, Esther et al. (2007) Charge immobilization of skeletal muscle Na+ channels: role of residues in the inactivation linker. Biophys J 93:1519-33
McCollum, Isabelle J; Vilin, Yuriy Y; Spackman, Elizabeth et al. (2003) Negatively charged residues adjacent to IFM motif in the DIII-DIV linker of hNa(V)1.4 differentially affect slow inactivation. FEBS Lett 552:163-9
Groome, James R; Fujimoto, Esther; Ruben, Peter C (2003) Negative charges in the DIII-DIV linker of human skeletal muscle Na+ channels regulate deactivation gating. J Physiol 548:85-96
Groome, James; Fujimoto, Esther; Walter, Lisa et al. (2002) Outer and central charged residues in DIVS4 of skeletal muscle sodium channels have differing roles in deactivation. Biophys J 82:1293-307
Groome, J R; Fujimoto, E; Ruben, P C (2000) The delay in recovery from fast inactivation in skeletal muscle sodium channels is deactivation. Cell Mol Neurobiol 20:521-7
Vilin, Y Y; Makita, N; George Jr, A L et al. (1999) Structural determinants of slow inactivation in human cardiac and skeletal muscle sodium channels. Biophys J 77:1384-93
Groome, J R; Fujimoto, E; George, A L et al. (1999) Differential effects of homologous S4 mutations in human skeletal muscle sodium channels on deactivation gating from open and inactivated states. J Physiol 516 ( Pt 3):687-98
Richmond, J E; Featherstone, D E; Hartmann, H A et al. (1998) Slow inactivation in human cardiac sodium channels. Biophys J 74:2945-52
Featherstone, D E; Fujimoto, E; Ruben, P C (1998) A defect in skeletal muscle sodium channel deactivation exacerbates hyperexcitability in human paramyotonia congenita. J Physiol 506 ( Pt 3):627-38
Richmond, J E; Featherstone, D E; Ruben, P C (1997) Human Na+ channel fast and slow inactivation in paramyotonia congenita mutants expressed in Xenopus laevis oocytes. J Physiol 499 ( Pt 3):589-600

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