Abstract

Voltage-dependent sodium channels mediate the propagating action potential of nerve and muscle. Molecularly, sodium channels from a number of tissues are comprised of single large polypeptide that is heavily modified by carbohydrate and hydrophobic domains inferred to be lipid. This application proposes to continue investigations into the role of these nonprotein domains in the molecular mechanisms that underlie voltage-sensitive gating and ion conductance. There is strong preliminary evidence from reconstitution studies that negatively charged sialic acid residues attached to the channel significantly affect the local electrical field near an activation gating sensor. If so, then biosynthetic attachment of sialic acid residues may represent an adaptive mechanism that allows certain cells to determine channel gating characteristics appropriate to the membrane properties and functional requirements of that cell type. this hypothesis will be addressed using a complementary interdisciplinary approach in which channel carbohydrate compositions will be manipulated in the following ways: 1) through removal of sugars from channels expressed at the cell surface using neuraminidases; 2) inhibition of glycosylation during biosynthesis using selective metabolic inhibitors; 3) expression of channels in mutant cell lines lacking various elements of the glycosylation machinery, and 4) mutagenesis of cloned channel cDNAs to modify, move or eliminate glycosylation sites. In these studies channel cDNAs will be transfected into cell lines and the affect of the above manipulations on channel synthesis, expression, and function will be studied using biochemical, immunological, and biophysical recording techniques. Further insight into the roles of glycosylation will be obtained by comparing the results from similar studies performed on channels expressed in Xenopus oocytes and mammalian muscle fibers. Overall, the studies in this application will address the question of how channel function may be modified at the posttranslational level. Such information has applications to the understanding of sodium channel roles in degenerative and developmental disorders of the neuromuscular system and in the design of more affective drugs for use in anesthesia and cardiac arrhythmias.

  Funding Agency

Agency
National Institute of Health (NIH)
Institute
National Institute of Neurological Disorders and Stroke (NINDS)
Type
Research Project (R01)
Project #
5R01NS015879-16
Application #
2262902
Study Section
General Medicine B Study Section (GMB)
Project Start
1993-07-01
Project End
1997-06-30
Budget Start
1995-07-01
Budget End
1996-06-30
Support Year
16
Fiscal Year
1995
Total Cost
Indirect Cost

  Institution

Name
University of Colorado Denver
Department
Physiology
Type
Schools of Medicine
DUNS #
065391526
City
Aurora
State
CO
Country
United States
Zip Code
80045

  Publications

Wang, Ze-Jun; Snell, Lawrence D; Tabakoff, Boris et al. (2002) Inhibition of neuronal Na+ channels by the novel antiepileptic compound DCUKA: identification of the diphenylureido moiety as an inactivation modifier. Exp Neurol 178:129-38
Martinez, A M (1999) Distribution of sodium and potassium channels as well as myelin associated glycoprotein (MAG) during the early stages of Wallerian degeneration. J Submicrosc Cytol Pathol 31:73-81
Novakovic, S D; Levinson, S R; Schachner, M et al. (1998) Disruption and reorganization of sodium channels in experimental allergic neuritis. Muscle Nerve 21:1019-32
Vabnick, I; Messing, A; Chiu, S Y et al. (1997) Sodium channel distribution in axons of hypomyelinated and MAG null mutant mice. J Neurosci Res 50:321-36
Bennett, E; Urcan, M S; Tinkle, S S et al. (1997) Contribution of sialic acid to the voltage dependence of sodium channel gating. A possible electrostatic mechanism. J Gen Physiol 109:327-43
Deerinck, T J; Levinson, S R; Bennett, G V et al. (1997) Clustering of voltage-sensitive sodium channels on axons is independent of direct Schwann cell contact in the dystrophic mouse. J Neurosci 17:5080-8
Wu, B Q; Yang, L; Kao, C Y et al. (1996) 11-Oxo-tetrodotoxin and a specifically labelled 3H-tetrodotoxin. Toxicon 34:407-16
Novakovic, S D; Deerinck, T J; Levinson, S R et al. (1996) Clusters of axonal Na+ channels adjacent to remyelinating Schwann cells. J Neurocytol 25:403-12
England, J D; Happel, L T; Kline, D G et al. (1996) Sodium channel accumulation in humans with painful neuromas. Neurology 47:272-6
England, J D; Levinson, S R; Shrager, P (1996) Immunocytochemical investigations of sodium channels along nodal and internodal portions of demyelinated axons. Microsc Res Tech 34:445-51

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