The ability of a nerve or muscle cell to fire an impulse is a result of the properties of a particular membrane protein, the voltage-gated sodium channel. These channels are water filled pores through the cell membrane which open transiently in response to a decrease in the membrane voltage, allowing sodium ions to flow into the cell. An important goal of modern neurobiology is to understand the molecular mechanisms by which this channel changes its conformational state in response to the membrane voltage. The elucidation of this voltage-dependent gating mechanism is important to our understanding our understanding of the basic cellular mechanisms of the nervous system and their dysfunction during pathological conditions, such as epilepsy. This proposal focuses upon the gating of sodium channels. Two approaches will be combined: the recording of currents through individual sodium channels, and the use of agents which alter the normal channel kinetics. Single-channel recording is a powerful technique, allowing one to monitor openings and closings of an individual channel under conditions where the membrane voltage is held constant. The study of single molecules yields much more information about channel kinetics than traditional voltage-clamp experiments which are performed on large populations of channels. The pharmacological modification of channel gating has been an important tool in multi-channel (macroscopic) voltage-clamp studies of sodium channel gating. A number of agents have been found that remove the ability of the channel to turn off, or inactivate, during a maintained voltage step. The increased resolution of single-channel recording allows the examination of the mechanism of action of these agents in much greater detail than before. Two of these agents, N-bromoacetamide and Chloramine-T, will be used in these studies. The following questions will be addressed: Are the effects of these drugs simply to reduce the accesible states of the channel? Are the inactivation of open channels and those that have not opened similarly affected? Do agents that work from the outside of the membrane have different effects than those that work from the inside. Experiments will be carried out on both normal and modified channels in order to construct a kinetic model which accounts for the normal behavior of the channel and the mechanisms of modification. The ultimate goal is to find the number of possible kinetic states of the channel, the rate constants for transitions between them, the voltage dependence of each of these rate constants, and their pharmacological modification.

Agency
National Institute of Health (NIH)
Institute
National Institute of Neurological Disorders and Stroke (NINDS)
Type
Research Project (R01)
Project #
5R01NS023294-02
Application #
3406586
Study Section
Physiology Study Section (PHY)
Project Start
1985-07-01
Project End
1987-06-30
Budget Start
1986-07-01
Budget End
1987-06-30
Support Year
2
Fiscal Year
1986
Total Cost
Indirect Cost
Name
Stanford University
Department
Type
Schools of Medicine
DUNS #
800771545
City
Stanford
State
CA
Country
United States
Zip Code
94305
Brenner, R; Jegla, T J; Wickenden, A et al. (2000) Cloning and functional characterization of novel large conductance calcium-activated potassium channel beta subunits, hKCNMB3 and hKCNMB4. J Biol Chem 275:6453-61
Middendorf, T R; Aldrich, R W; Baylor, D A (2000) Modification of cyclic nucleotide-gated ion channels by ultraviolet light. J Gen Physiol 116:227-52
Middendorf, T R; Aldrich, R W (2000) Effects of ultraviolet modification on the gating energetics of cyclic nucleotide-gated channels. J Gen Physiol 116:253-82
Horrigan, F T; Aldrich, R W (1999) Allosteric voltage gating of potassium channels II. Mslo channel gating charge movement in the absence of Ca(2+). J Gen Physiol 114:305-36
Kanevsky, M; Aldrich, R W (1999) Determinants of voltage-dependent gating and open-state stability in the S5 segment of Shaker potassium channels. J Gen Physiol 114:215-42
Ledwell, J L; Aldrich, R W (1999) Mutations in the S4 region isolate the final voltage-dependent cooperative step in potassium channel activation. J Gen Physiol 113:389-414
Ogielska, E M; Aldrich, R W (1999) Functional consequences of a decreased potassium affinity in a potassium channel pore. Ion interactions and C-type inactivation. J Gen Physiol 113:347-58
Horrigan, F T; Cui, J; Aldrich, R W (1999) Allosteric voltage gating of potassium channels I. Mslo ionic currents in the absence of Ca(2+). J Gen Physiol 114:277-304
Smith-Maxwell, C J; Ledwell, J L; Aldrich, R W (1998) Uncharged S4 residues and cooperativity in voltage-dependent potassium channel activation. J Gen Physiol 111:421-39
Ogielska, E M; Aldrich, R W (1998) A mutation in S6 of Shaker potassium channels decreases the K+ affinity of an ion binding site revealing ion-ion interactions in the pore. J Gen Physiol 112:243-57

Showing the most recent 10 out of 42 publications