This study aims to address the question of the molecular mechanism for the inhibition of ionic conduction through voltage-dependent and neurotransmitter regulated channels by local anesthetics (LA). Specifically, we aim to probe the nature and the site of the blocking action of LA on voltage-dependent sodium channels and nicotinic cholinergic receptors. Our approach is to characterize the action of a series of LA on be single channel properties of synthetic channel peptides in lipid bilayers. The synthetic channel peptides are designed to mimic the channel lining of the mammalian brain voltage-dependent sodium channel with amino acid sequence -- DPWNWLDFTVITFAYVTEFVDL-- and of the nicotinic cholinetic receptor from fish electric organ with the sequence: EKMSTAISVLLAQAVFLLLTSQR. A series of LA well characterized on voltage-gated sodium channels and end-plate channels will be determined. The effect of LA on channel conductance, ionic selec- tivity and saturation will be evaluated. The modification of channel gating kinetics in terms of the number of channel open and closed states or the lifetime of the channel on each of these states will be assessed. The accessibility of the 2 aqueous compartments separated by the bilayer will allows to examine the pH-dependent action of these drugs under symmetric and asymmetric conditions. The concentration dependence, voltage dependence, temperature and calcium dependence of the channel block will be explored. The stereopotency ratio for block will be examined. The results will be compared with data on authentic channels. A salient advantage of this approach is that, by chemical synthesis, an amino acid thought to be crucial for the action of LA can be substituted. The assay of the """"""""analogue"""""""" will establish if such residue is significant. Cases in point are the analogues of the sodium channel peptide in which the acidic residues D7 or E18 (located in the pore lumen), D1 (pore entry) or D21 (pore exit) are substituted or the uncharged amino acids N or Q, respectively. Likewise, for the receptor peptide, the channel activity of analogues in which the polar residues S8 and T5 (located in the pore lumen) are replaced for L and El or K2 (pore entry) are substituted for Q and A, respectively, will be analyzed. This program may lead to identify the molecular structures that determine the pharmacological specificity in the action of LA on channel proteins and will provide information conducive to formulate a common mechanism for the inhibitory action of the clinically important local anesthetics on voltage-dependent channels in neural and cardiac cells.

Agency
National Institute of Health (NIH)
Institute
National Institute of General Medical Sciences (NIGMS)
Type
Research Project (R01)
Project #
5R01GM042340-02
Application #
3300818
Study Section
Neurological Sciences Subcommittee 1 (NLS)
Project Start
1989-04-01
Project End
1992-03-31
Budget Start
1990-04-01
Budget End
1991-03-31
Support Year
2
Fiscal Year
1990
Total Cost
Indirect Cost
Name
University of California San Diego
Department
Type
Schools of Arts and Sciences
DUNS #
077758407
City
La Jolla
State
CA
Country
United States
Zip Code
92093
Iwamoto, T; Grove, A; Montal, M O et al. (1994) Chemical synthesis and characterization of peptides and oligomeric proteins designed to form transmembrane ion channels. Int J Pept Protein Res 43:597-607
Oblatt-Montal, M; Buhler, L K; Iwamoto, T et al. (1993) Synthetic peptides and four-helix bundle proteins as model systems for the pore-forming structure of channel proteins. I. Transmembrane segment M2 of the nicotinic cholinergic receptor channel is a key pore-lining structure. J Biol Chem 268:14601-7
Reddy, G L; Iwamoto, T; Tomich, J M et al. (1993) Synthetic peptides and four-helix bundle proteins as model systems for the pore-forming structure of channel proteins. II. Transmembrane segment M2 of the brain glycine receptor is a plausible candidate for the pore-lining structure. J Biol Chem 268:14608-15
Grove, A; Tomich, J M; Iwamoto, T et al. (1993) Design of a functional calcium channel protein: inferences about an ion channel-forming motif derived from the primary structure of voltage-gated calcium channels. Protein Sci 2:1918-30
Grove, A; Tomich, J M; Montal, M (1992) Molecular design of oligomeric channel proteins. Genet Eng (N Y) 14:163-84
Grove, A; Iwamoto, T; Montal, M S et al. (1992) Synthetic peptides and proteins as models for pore-forming structure of channel proteins. Methods Enzymol 207:510-25
Grove, A; Tomich, J M; Montal, M (1991) A molecular blueprint for the pore-forming structure of voltage-gated calcium channels. Proc Natl Acad Sci U S A 88:6418-22
Montal, M; Montal, M S; Tomich, J M (1990) Synporins--synthetic proteins that emulate the pore structure of biological ionic channels. Proc Natl Acad Sci U S A 87:6929-33
Oiki, S; Madison, V; Montal, M (1990) Bundles of amphipathic transmembrane alpha-helices as a structural motif for ion-conducting channel proteins: studies on sodium channels and acetylcholine receptors. Proteins 8:226-36
Montal, M (1990) Molecular anatomy and molecular design of channel proteins. FASEB J 4:2623-35

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