Title :
Molecular dynamics Simulation approaches to K channels: conformational flexibility and physiological function
Author :
Grottesi, Alessandro ; Domene, Carmen ; Haider, Shozeb ; Sansom, Mark S P
Author_Institution :
Dept. of Biochem., Univ. of Oxford, UK
fDate :
3/1/2005 12:00:00 AM
Abstract :
Molecular modeling and simulations enable extrapolation for the structure of bacterial potassium channels to the function of their mammalian homologues. Molecular dynamics simulations have revealed the concerted single-file motion of potassium ions and water molecules through the selectivity filter of K channels and the role of filter flexibility in ion permeation and in "fast gating." Principal components analysis of extended K channel simulations suggests that hinge-bending of pore-lining M2 (or S6) helices plays a key role in K channel gating. Based on these and other simulations, a molecular model for gating of inward rectifier K channel gating is presented.
Keywords :
bioelectric phenomena; biomembrane transport; microorganisms; molecular configurations; molecular dynamics method; physiological models; potassium; principal component analysis; K; bacterial potassium channels; concerted single-file motion; conformational flexibility; fast channel gating; hinge-bending; ion permeation; molecular dynamics simulation; molecular modeling; physiological function; pore-lining M2 helices; principal components analysis; selectivity filter; water molecules; Analytical models; Biomembranes; Cells (biology); Extrapolation; Filters; Microorganisms; Proteins; Rectifiers; Switches; Voltage; Gating; molecular dynamics; nanopore; potassium channel; Animals; Cell Membrane; Cell Membrane Permeability; Humans; Ion Channel Gating; Kinetics; Membrane Potentials; Models, Biological; Models, Chemical; Motion; Porosity; Potassium Channels; Protein Conformation; Structure-Activity Relationship;
Journal_Title :
NanoBioscience, IEEE Transactions on
DOI :
10.1109/TNB.2004.842473
