A Limited 4 Å Radial Displacement of the S4-S5 Linker Is Sufficient for Internal Gate Closing in Kv Channels*

Background: For Kv channels, only crystal structures for the open state are available. Results: Using LRET, we determined the movement of the S4-S5 linker during gating in KvAP channels. Conclusion: A small displacement of the S6 by only 4 Å is sufficient for closing of the Kv channels. Significance: We provide the first Kv channel closed state model based on cytosolic restraints. Voltage-gated ion channels are responsible for the generation of action potentials in our nervous system. Conformational rearrangements in their voltage sensor domains in response to changes of the membrane potential control pore opening and thus ion conduction. Crystal structures of the open channel in combination with a wealth of biophysical data and molecular dynamics simulations led to a consensus on the voltage sensor movement. However, the coupling between voltage sensor movement and pore opening, the electromechanical coupling, occurs at the cytosolic face of the channel, from where no structural information is available yet. In particular, the question how far the cytosolic pore gate has to close to prevent ion conduction remains controversial. In cells, spectroscopic methods are hindered because labeling of internal sites remains difficult, whereas liposomes or detergent solutions containing purified ion channels lack voltage control. Here, to overcome these problems, we controlled the state of the channel by varying the lipid environment. This way, we directly measured the position of the S4-S5 linker in both the open and the closed state of a prokaryotic Kv channel (KvAP) in a lipid environment using Lanthanide-based resonance energy transfer. We were able to reconstruct the movement of the covalent link between the voltage sensor and the pore domain and used this information as restraints for molecular dynamics simulations of the closed state structure. We found that a small decrease of the pore radius of about 3–4 Å is sufficient to prevent ion permeation through the pore.

[1]  E. Liman,et al.  Voltage-sensing residues in the S4 region of a mammalian K+ channel , 1991, Nature.

[2]  Y. Jan,et al.  Alteration of voltage-dependence of Shaker potassium channel by mutations in the S4 sequence , 1991, Nature.

[3]  T Hoshi,et al.  Shaker potassium channel gating. III: Evaluation of kinetic models for activation , 1994, The Journal of general physiology.

[4]  Roderick MacKinnon,et al.  Contribution of the S4 Segment to Gating Charge in the Shaker K+ Channel , 1996, Neuron.

[5]  Francisco Bezanilla,et al.  Voltage-Sensing Residues in the S2 and S4 Segments of the Shaker K+ Channel , 1996, Neuron.

[6]  J. Ruppersberg Ion Channels in Excitable Membranes , 1996 .

[7]  Y. Barenholz,et al.  Electrostatic parameters of cationic liposomes commonly used for gene delivery as determined by 4-heptadecyl-7-hydroxycoumarin. , 1997, Biochimica et biophysica acta.

[8]  Alexander D. MacKerell,et al.  All-atom empirical potential for molecular modeling and dynamics studies of proteins. , 1998, The journal of physical chemistry. B.

[9]  P. Selvin,et al.  Thiol-reactive luminescent chelates of terbium and europium. , 1999, Bioconjugate chemistry.

[10]  Francisco Bezanilla,et al.  Atomic scale movement of the voltage-sensing region in a potassium channel measured via spectroscopy , 1999, Nature.

[11]  F. Ashcroft Voltage-gated K + channels , 2000 .

[12]  Zhe Lu,et al.  Ion conduction pore is conserved among potassium channels , 2001, Nature.

[13]  Eduardo Perozo,et al.  Structure of the KcsA channel intracellular gate in the open state , 2001, Nature Structural Biology.

[14]  K. Brandenburg,et al.  New Insights Into Endotoxin-Induced Activation of Macrophages: Involvement of a K+ Channel in Transmembrane Signaling1 , 2001, The Journal of Immunology.

[15]  Zhe Lu,et al.  Coupling between Voltage Sensors and Activation Gate in Voltage-gated K+ Channels , 2002, The Journal of general physiology.

[16]  Paul R Selvin,et al.  Principles and biophysical applications of lanthanide-based probes. , 2002, Annual review of biophysics and biomolecular structure.

[17]  C. Brooks,et al.  An implicit membrane generalized born theory for the study of structure, stability, and interactions of membrane proteins. , 2003, Biophysical journal.

[18]  P. Selvin,et al.  Thiol-reactive luminescent lanthanide chelates: part 2. , 2003, Bioconjugate chemistry.

[19]  F. Bezanilla,et al.  Detecting rearrangements of shaker and NaChBac in real-time with fluorescence spectroscopy in patch-clamped mammalian cells. , 2004, Biophysical journal.

[20]  Laxmikant V. Kalé,et al.  Scalable molecular dynamics with NAMD , 2005, J. Comput. Chem..

[21]  E. Campbell,et al.  Crystal Structure of a Mammalian Voltage-Dependent Shaker Family K+ Channel , 2005, Science.

[22]  F. Bezanilla,et al.  Small vertical movement of a K+ channel voltage sensor measured with luminescence energy transfer , 2005, Nature.

[23]  A. VanDongen,et al.  K Channel Subconductance Levels Result from Heteromeric Pore Conformations , 2005, The Journal of general physiology.

[24]  E. Campbell,et al.  Voltage Sensor of Kv1.2: Structural Basis of Electromechanical Coupling , 2005, Science.

[25]  Zhe Lu,et al.  Enzymatic activation of voltage-gated potassium channels , 2006, Nature.

[26]  F. Bezanilla,et al.  Distance measurements reveal a common topology of prokaryotic voltage-gated ion channels in the lipid bilayer , 2006, Proceedings of the National Academy of Sciences.

[27]  R. MacKinnon,et al.  Phospholipids and the origin of cationic gating charges in voltage sensors , 2006, Nature.

[28]  Francisco Bezanilla,et al.  Two atomic constraints unambiguously position the S4 segment relative to S1 and S2 segments in the closed state of Shaker K channel , 2007, Proceedings of the National Academy of Sciences.

[29]  Zhe Lu,et al.  Inhibition of CFTR Cl− channel function caused by enzymatic hydrolysis of sphingomyelin , 2007, Proceedings of the National Academy of Sciences.

[30]  E. Campbell,et al.  Atomic structure of a voltage-dependent K+ channel in a lipid membrane-like environment , 2007, Nature.

[31]  Francisco Bezanilla,et al.  In vivo measurement of intramolecular distances using genetically encoded reporters. , 2007, Biophysical journal.

[32]  Zhe Lu,et al.  Removal of phospho-head groups of membrane lipids immobilizes voltage sensors of K+ channels , 2008, Nature.

[33]  Taehoon Kim,et al.  CHARMM‐GUI: A web‐based graphical user interface for CHARMM , 2008, J. Comput. Chem..

[34]  Fredrik Elinder,et al.  Lipoelectric modification of ion channel voltage gating by polyunsaturated fatty acids. , 2008, Biophysical journal.

[35]  M. Sansom,et al.  Kv Channel Gating Requires a Compatible S4-S5 Linker and Bottom Part of S6, Constrained by Non-interacting Residues , 2008, The Journal of general physiology.

[36]  R. MacKinnon,et al.  Voltage-dependent K+ channel gating and voltage sensor toxin sensitivity depend on the mechanical state of the lipid membrane , 2008, Proceedings of the National Academy of Sciences.

[37]  Maria Dahlin,et al.  Polyunsaturated fatty acids and cerebrospinal fluid from children on the ketogenic diet open a voltage-gated K channel: A putative mechanism of antiseizure action , 2008, Epilepsy Research.

[38]  F. Bezanilla,et al.  Fluorescence detection of the movement of single KcsA subunits reveals cooperativity , 2008, Proceedings of the National Academy of Sciences.

[39]  F. Bezanilla,et al.  S4-based voltage sensors have three major conformations , 2008, Proceedings of the National Academy of Sciences.

[40]  Jianpeng Ma,et al.  CHARMM: The biomolecular simulation program , 2009, J. Comput. Chem..

[41]  R. MacKinnon,et al.  A gating model for the archeal voltage-dependent K(+) channel KvAP in DPhPC and POPE:POPG decane lipid bilayers. , 2009, Journal of molecular biology.

[42]  Erik Lindahl,et al.  Conformational Changes and Slow Dynamics through Microsecond Polarized Atomistic Molecular Simulation of an Integral Kv1.2 Ion Channel , 2009, PLoS Comput. Biol..

[43]  R. Bähring,et al.  Dynamic Coupling of Voltage Sensor and Gate Involved in Closed-State Inactivation of Kv4.2 Channels , 2009, The Journal of general physiology.

[44]  Klaus Schulten,et al.  Biophysical Journal, Volume 98 Supporting Material Calculation of the Gating Charge for the Kv1.2 Voltage–activated Potassium Channel , 2022 .

[45]  D. Papazian,et al.  Transfer of ion binding site from ether-à-go-go to Shaker: Mg2+ binds to resting state to modulate channel opening , 2010, The Journal of general physiology.

[46]  R. Blunck,et al.  An Intersubunit Interaction between S4-S5 Linker and S6 Is Responsible for the Slow Off-gating Component in Shaker K+ Channels* , 2010, The Journal of Biological Chemistry.

[47]  R. Blunck,et al.  Mode shift of the voltage sensors in Shaker K+ channels is caused by energetic coupling to the pore domain , 2011, The Journal of general physiology.

[48]  Francisco Bezanilla,et al.  In Search of a Consensus Model of the Resting State of a Voltage-Sensing Domain , 2011, Neuron.

[49]  David Baker,et al.  Structural basis for gating charge movement in the voltage sensor of a sodium channel , 2011, Proceedings of the National Academy of Sciences.

[50]  Weiran Liu,et al.  Lipid-dependent gating of a voltage-gated potassium channel , 2011, Nature communications.

[51]  Fredrik Elinder,et al.  An electrostatic potassium channel opener targeting the final voltage sensor transition , 2011, The Journal of general physiology.

[52]  R. Blunck,et al.  Mechanism of Electromechanical Coupling in Voltage-Gated Potassium Channels , 2012, Front. Pharmacol..

[53]  Ron O. Dror,et al.  Mechanism of Voltage Gating in Potassium Channels , 2012, Science.