Voltage-dependent, potassium ion selective, membrane proteins exist in virtually all animal cells. The physiological roles of these K channels are diverse and include the maintenance of cell resting potentials, repolarization of cell action potentials, and regulation of rhythmic electrical activity. As a consequence, these channels are involved in various pathologies and are the targets of diverse therapeutic agents including those directed toward diseases of the pancreas and the cardiovascular system. Molecular level knowledge of the structure and function of these channels will be valuable in understanding the pathologies and will lead to the design of improved therapeutic measures. The long-term goal of this research is to provide information for a molecular level view of the conformational change process in voltage- gated K channels. A combination of biochemical, molecular biological, and electrophysiological methods will be used to examine certain specific features of this process in channels of known primary structure. Previous studies of the channel conformational change process have concentrated on control by membrane voltage-ignoring weakly voltage dependent conformational changes. Our past work has implicated a histidine group in some K channels that is involved in a weakly voltage dependent step in channel opening. One specific focus of the research proposed here is to determine the location of this amino acid and confirm its role in channel gating. Another specific goal of this proposal is to identify the region of the channel protein that contains the site for modulation by external divalent cations like Ca2+. Drawing on work in the past grant period, we hypothesize two possible loci which will be tested with site specific mutagenesis and electrophysiological methods. Channel gating is substantially perturbed by divalent cations interacting with an important internal region of these proteins. Another study in this application is designed to provide information on the chemical nature of this region. In all these studies, cloned ion channels will be expressed by RNA injection in Xenopus oocytes. Voltage clamp electrophysiology techniques will be used to assay channel function and will include measurement of macroscopic and single channel currents. The functional properties that are the focus of this research are common to many K channel types in cells as diverse as lymphocytes and heart and brain cells. Thus, the knowledge gained in these studies will be of general utility in revealing the molecular properties of the physiology , pathology, and pharmacology of ion channels.

Agency
National Institute of Health (NIH)
Institute
National Institute of Neurological Disorders and Stroke (NINDS)
Type
Research Project (R01)
Project #
5R01NS014138-17
Application #
2655429
Study Section
Physiology Study Section (PHY)
Program Officer
Talley, Edmund M
Project Start
1977-12-01
Project End
2001-01-31
Budget Start
1998-02-01
Budget End
2001-01-31
Support Year
17
Fiscal Year
1998
Total Cost
Indirect Cost
Name
University of Rochester
Department
Pharmacology
Type
Schools of Dentistry
DUNS #
208469486
City
Rochester
State
NY
Country
United States
Zip Code
14627
Quinn, C C; Begenisich, T (2001) The influence of surface charges on quaternary ammonium block of shaker K+ channels. J Membr Biol 182:233-43
Thompson, J; Begenisich, T (2001) Affinity and location of an internal K+ ion binding site in shaker K channels. J Gen Physiol 117:373-84
Thompson, J; Begenisich, T (2000) Electrostatic interaction between charybdotoxin and a tetrameric mutant of Shaker K(+) channels. Biophys J 78:2382-91
Thompson, J; Begenisich, T (2000) Interaction between quaternary ammonium ions in the pore of potassium channels. Evidence against an electrostatic repulsion mechanism. J Gen Physiol 115:769-82
Perez-Cornejo, P (1999) H+ ion modulation of C-type inactivation of Shaker K+ channels. Pflugers Arch 437:865-70
Perez-Cornejo, P; Stampe, P; Begenisich, T (1998) Proton probing of the charybdotoxin binding site of Shaker K+ channels. J Gen Physiol 111:441-50
Spires, S; Begenisich, T (1995) Voltage-independent gating transitions in squid axon potassium channels. Biophys J 68:491-500
Perez-Cornejo, P; Begenisich, T (1994) The multi-ion nature of the pore in Shaker K+ channels. Biophys J 66:1929-38
Spires, S; Begenisich, T (1994) Modulation of potassium channel gating by external divalent cations. J Gen Physiol 104:675-92
Nealey, T; Spires, S; Eatock, R A et al. (1993) Potassium channels in squid neuron cell bodies: comparison to axonal channels. J Membr Biol 132:13-25

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