Professor
Department of Physiology and Biophysics
UCD at Fitzsimons
RC-1 North Tower PO Box 6511
Email rock.levinson@UCHSC.edu
Rock's Curriculum vitae
SUMMARY
Molecular Structure,
Function, and Regulation of Ion Channels
Ion channels are a diverse class of membrane transport systems that are essential
for electrical signalling in the nervous system. Our group studies the
molecular mechanisms that allow these ion channels to function, as well as the
means used by the cell to regulate the number, distribution, and properties of
ion channels. We focus on the voltage-gated sodium channel, having purified the
molecule from the electric organ of the electric eel.
In characterizing the purified molecule, we have
found that the sodium channel is comprised of a single large polypeptide that
is highly glycosylated and modified by fatty acids. These extensive nonprotein
domains are added to the channel structure posttranslationally, and there are
strong indications that they may form part of the molecular mechanisms of
voltage-sensing and ion conduction. In particular, we have found that removal
of some of the large number of negatively charged sialic sugars greatly reduces
the sensitivity of the channel to voltage changes. In addition, the complex
opening/closing transitions of the channel are affected by the membrane lipid
composition that surrounds the channel. Thus, we suggest that nonprotein
domains must be considered as part of the functional apparatus of the sodium
channel.
We are
also studying the biosynthesis of channels during development and pathological
degeneration. For example, one project investigates changes in sodium channel
distributions that occur during demyelination of nerves; the results obtained
suggest that increased sodium channel synthesis may explain remissions
experienced by patients suffering from multiple sclerosis. Other projects focus
on the ways in which sodium channels are transported from nerve cell bodies to
the remote domains on axons where they are needed for impulse conduction. An
unusual aspect of this work concerns the role that glial cell-axon interactions
play in controlling channel biosynthesis and localization at the nodes of
Ranvier in myelinated nerves (as seen in orange bands in figure at right) .
Lastly, we have found that different types of sodium channels ("isoforms")
are differentially distributed in the nervous system. For example, unmyelinated
pain fibers appear to have different channels than do myelinated fibers. These
findings may be important in the development of drugs to control chronic pain.
In our studies we employ a variety of approaches, including protein
biochemistry, recombinant DNA/molecular biology, immunology, and
electrophysiology.
REPRESENTATIVE PUBLICATIONS
- Kao, C.Y. and Levinson, S.R. (1986), eds. "Tetrodotoxin, Saxitoxin, and the molecular biology of the sodium channel." Annals of the New York Academy of Sciences, volume 479.
- Recio-Pinto, E., Duch, D.S., Levinson, S.R. and Urban, B.W. (1987). Purified and unpurified sodium channels from eel electroplax in planar lipid bilayers. J. Gen. Physiol. 90:375-395.
- Thornhill, W.B. and Levinson, S.R. (1987). Biosynthesis of electroplax sodium channels in eel electrocytes and Xenopus Oocytes. Biochemistry 26:4381-4388.
- Recio-Pinto, E., Duch, D.S., Urban, B.W., Thornhill, W.B. and Levinson, S.R. (1990). Neuraminidase treatment modifies the function of eel sodium channels reconstituted in planar lipid bilayers. Neuron 5:675-684.
- Levinson, S.R., Thornhill, W.B., Duch, D.S., Recio-Pinto, E., and Urban, B.W. (1990) The role of nonprotein domains in the function and synthesis of voltage-gated sodium channels.Ion Channels, Vol II. T. Narahashi, ed., Plenum Publishing, pp 33-64
- Ivey, S., Thornhill, W.B.,
and Levinson, S.R. (1991) Monoclonal antibodies raised against
posttranslational domains of the electroplax sodium channel. J.Membr.
Biol. 121:215-222
- Levinson, S.R., and Thornhill, W.B.(1992), Use of cell-free translation systems and pulse labeling methods to study ion channel biosynthesis and trafficking", Methods in Enzymology 207: 659-670
- Levinson, S.R., (1995) The structure and mechanism of voltage-gated ion ion channels, Invited chapter, Principles of Physiology and Biophysics, N. Sperelakis, ed., Academic Press
- Turner, R.W., Maler, L., Deerinck, Levinson, S.R., and Ellisman, M.H., TTX-sensitive sodium channels underlie oscillatory discharge in a vertebrate sensory neuron. (1994) J. Neuroscience 14: 6453-6471
- Dugandzija-Novakovic, S., Koszowski, A. G., Levinson, S.R., and Shrager, P. (1995) Clustering of Na+ channels and node of Ranvier formation in remyelinating axons. J. Neuroscience 15:492-503
- Tzoumaka, E-E.,
- Vabnick,
- Bennett, E., Urcan, M.S., Tinkle, S.S., Koszowski, A.G., and Levinson, S.R. (1997) Contribution of sialic acid to the voltage-depndence of sodium channel gating: A possible electrostatic mechanism. J. Gen. Physiol. 109:327-343
- Toledo-Aral, J.J., Moss,
B.L., He, Z-J., Koszowski, A.G., Whisenand, W., Levinson, S.R., Wolf,
J.J., Silos Santiago, I., Halegoua, S., and Mandel, G. (1997)
Identification of PN1, a predominant voltage-dependent sodium channel expressed
principally in peripheral neurons. Proc. Natl. Acad. Sci. (
- Deerinck, T.J., Levinson, S.R., Bennett, G.V., and Ellisman, M.H. (1997) Clustering of voltage-sensitive sodium channels on axons is independent of direct Schwann cell contact in the dystrophic mouse. J. Neurosci. 17:5080-5088
- Kaplan, M.R., Meyer-Franke, A., Lambert, S., Bennett, V., Duncan, I.D., Levinson, S.R., and Barres, B.A. (1997) A new role for oligodendrocytes: induction of axonal sodium channel clustering. Nature 386:724-728
- Koszowski, A.G., Owens, G.C., and Levinson, S.R. (1998) The effect of the mouse mutation claw paw on myelination and nodal frequency in sciatic nerves. J. Neurosci. 18:5859-5868
- Levinson, S.R. (1998) The structure and mechanism of voltage-gated ion channels. In Cell Physiology Source Book, 2nd edition, N. Sperelakis, ed., Academic Press, NY
- Vabnick,
- Rasband, M.N., Trimmer, J.S., Schwarz, T.L., Levinson, S.R., Ellisman, M.H., Schachner, M., and Shrager, P. (1998) Potassium channel distribution, clustering, and function in remyelinating rat axons. J. Neurosci. 18:36-47.
- Gee, S.H., Madhaven, R.,
Levinson, S.R.,
- Vabnick,
- Gould, H.J. III, Gould, T.N.,
Paul, D.,
- Ching, W., Zanazzi, G., Levinson, S.R., and Salzer, J.L., (1999) Clustering of neuronal sodium channels requires contact with myelinating Schwann cells. J. Neurocytol. 28:295-301
- Weber, P. Bartsch, U., Rasband, M.N., Czaniera, R., Lang, Y., Bluethmann, H., Margolis, R.U., Levinson, S.R., Shrager, P., Montag, D., and Schachner, M. (1999) Mice deficient for tenascin-R display alterations of the extracellular matrix and decreased axonal conduction velocities in the CNS. J. Neurosci. 19:4245-4262
- Rasband, M.N., Peles, E.,
Trimmer, J.S., Levinson, S.R., Lux, S.E., and Shrager, P. (1999)
Dependence of nodal sodium channel clustering on paranodal axoglial
contact in the developing CNS. J.
Neurosci. 19:7516-7528
- Levinson, S.R. and W.A.
Sather, (2001) The structure and mechanism of voltage-gated ion ion
channels, in Cell Physiology Source
Book, 3nd edition, pp 455-477, N. Sperelakis, ed., Academic Press, NY
- Boiko T., Rasband, M.N.,
Levinson, S.R.,
- Kaplan, M.R., Cho, M-H., Ullian, E.M., Isom, L.L., Levinson, S.R., and Barres, B.A., (2001) Differential control of clustering of the sodium channels Nav1.2 and Nav1.6 at developing CNS nodes of Ranvier. Neuron 30: 105-119
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