Structural basis for the coupling between activation and inactivation gates in K+ channels

The coupled interplay between activation and inactivation gating is a functional hallmark of K+ channels. This coupling has been experimentally demonstrated through ion interaction effects and cysteine accessibility, and is associated with a well defined boundary of energetically coupled residues. The structure of the K+ channel KcsA in its fully open conformation, in addition to four other partial channel openings, richly illustrates the structural basis of activation–inactivation gating. Here, we identify the mechanistic principles by which movements on the inner bundle gate trigger conformational changes at the selectivity filter, leading to the non-conductive C-type inactivated state. Analysis of a series of KcsA open structures suggests that, as a consequence of the hinge-bending and rotation of the TM2 helix, the aromatic ring of Phe 103 tilts towards residues Thr 74 and Thr 75 in the pore-helix and towards Ile 100 in the neighbouring subunit. This allows the network of hydrogen bonds among residues Trp 67, Glu 71 and Asp 80 to destabilize the selectivity filter, allowing entry to its non-conductive conformation. Mutations at position 103 have a size-dependent effect on gating kinetics: small side-chain substitutions F103A and F103C severely impair inactivation kinetics, whereas larger side chains such as F103W have more subtle effects. This suggests that the allosteric coupling between the inner helical bundle and the selectivity filter might rely on straightforward mechanical deformation propagated through a network of steric contacts. Average interactions calculated from molecular dynamics simulations show favourable open-state interaction-energies between Phe 103 and the surrounding residues. We probed similar interactions in the Shaker K+ channel where inactivation was impaired in the mutant I470A. We propose that side-chain rearrangements at position 103 mechanically couple activation and inactivation in KcsA and a variety of other K+ channels.

[1]  L. Kiss,et al.  Contribution of the selectivity filter to inactivation in potassium channels. , 1999, Biophysical journal.

[2]  E. Perozo,et al.  Molecular Architecture of the KvAP Voltage-Dependent K+ Channel in a Lipid Bilayer , 2004, Science.

[3]  R. Aldrich,et al.  Effects of external cations and mutations in the pore region on C-type inactivation of Shaker potassium channels. , 1993, Receptors & channels.

[4]  Benoît Roux,et al.  Dynamics of the Kv1.2 voltage-gated K+ channel in a membrane environment. , 2007, Biophysical journal.

[5]  H. Bayley,et al.  Inactivation of the KcsA potassium channel explored with heterotetramers , 2010, The Journal of general physiology.

[6]  G. Yellen The voltage-gated potassium channels and their relatives , 2002, Nature.

[7]  Ofer Yifrach,et al.  Principles underlying energetic coupling along an allosteric communication trajectory of a voltage-activated K+ channel , 2007, Proceedings of the National Academy of Sciences.

[8]  F. Ashcroft,et al.  Mutations within the P-Loop of Kir6.2 Modulate the Intraburst Kinetics of the Atp-Sensitive Potassium Channel , 2001, The Journal of general physiology.

[9]  R. MacKinnon,et al.  Chemistry of ion coordination and hydration revealed by a K+ channel–Fab complex at 2.0 Å resolution , 2001, Nature.

[10]  E. Perozo,et al.  Molecular Architecture of Full-Length KcsA , 2001, The Journal of general physiology.

[11]  C Kung,et al.  Modified reconstitution method used in patch-clamp studies of Escherichia coli ion channels. , 1989, Biophysical journal.

[12]  C. Armstrong,et al.  K+ channels close more slowly in the presence of external K+ and Rb+ , 1981, Nature.

[13]  Eduardo Perozo,et al.  A Quantitative Description of KcsA Gating I: Macroscopic Currents , 2007, The Journal of general physiology.

[14]  E. Perozo,et al.  Structural dynamics of the Streptomyces lividans K+ channel (SKC1): oligomeric stoichiometry and stability. , 1997, Biochemistry.

[15]  Eduardo Perozo,et al.  Structural mechanism of C-type inactivation in K+ channels , 2010, Nature.

[16]  E. Perozo,et al.  Structural rearrangements underlying K+-channel activation gating. , 1999, Science.

[17]  O. Pongs,et al.  Coupling of activation and inactivation gate in a K+‐channel: potassium and ligand sensitivity , 2009, The EMBO journal.

[18]  J. Ruppersberg,et al.  K+‐dependent gating of Kir1.1 channels is linked to pH gating through a conformational change in the pore , 2001, The Journal of physiology.

[19]  M. Sanguinetti,et al.  Position of aromatic residues in the S6 domain, not inactivation, dictates cisapride sensitivity of HERG and eag potassium channels , 2002, Proceedings of the National Academy of Sciences of the United States of America.

[20]  R J Read,et al.  Crystallography & NMR system: A new software suite for macromolecular structure determination. , 1998, Acta crystallographica. Section D, Biological crystallography.

[21]  G. Yellen,et al.  Gated Access to the Pore of a Voltage-Dependent K+ Channel , 1997, Neuron.

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

[23]  Benoît Roux,et al.  Molecular determinants of gating at the potassium-channel selectivity filter , 2006, Nature Structural &Molecular Biology.

[24]  A. VanDongen,et al.  Allosteric effects of external K+ ions mediated by the aspartate of the GYGD signature sequence in the Kv2.1 K+ channel , 2006, Pflügers Archiv.

[25]  B. Roux,et al.  Molecular dynamics of the KcsA K(+) channel in a bilayer membrane. , 2000, Biophysical journal.

[26]  J. Changeux,et al.  ON THE NATURE OF ALLOSTERIC TRANSITIONS: A PLAUSIBLE MODEL. , 1965, Journal of molecular biology.

[27]  Youxing Jiang,et al.  Crystal structure and mechanism of a calcium-gated potassium channel , 2002, Nature.

[28]  G. Yellen,et al.  Dynamic Rearrangement of the Outer Mouth of a K+ Channel during Gating , 1996, Neuron.

[29]  S. W. Jones A Plausible Model , 1999 .

[30]  E. Perozo,et al.  pH-dependent gating in the Streptomyces lividans K+ channel. , 1998, Biochemistry.

[31]  J. Zou,et al.  Improved methods for building protein models in electron density maps and the location of errors in these models. , 1991, Acta crystallographica. Section A, Foundations of crystallography.

[32]  T Hoshi,et al.  Biophysical and molecular mechanisms of Shaker potassium channel inactivation , 1990, Science.

[33]  F. Bezanilla,et al.  A Conducting State with Properties of a Slow Inactivated State in a Shaker K+ Channel Mutant , 2001, The Journal of general physiology.

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

[35]  M. Karplus,et al.  CHARMM: A program for macromolecular energy, minimization, and dynamics calculations , 1983 .

[36]  C. Armstrong Voltage-Gated K Channels , 2003, Science's STKE.

[37]  C. Deutsch,et al.  Cross Talk between Activation and Slow Inactivation Gates of Shaker Potassium Channels , 2006, The Journal of general physiology.

[38]  G. Yellen,et al.  Use-Dependent Blockers and Exit Rate of the Last Ion from the Multi-Ion Pore of a K+ Channel , 1996, Science.

[39]  Z. Otwinowski,et al.  Processing of X-ray diffraction data collected in oscillation mode. , 1997, Methods in enzymology.

[40]  Roderick MacKinnon,et al.  Energetic optimization of ion conduction rate by the K+ selectivity filter , 2001, Nature.

[41]  Anthony Lewis,et al.  Molecular driving forces determining potassium channel slow inactivation , 2007, Nature Structural &Molecular Biology.

[42]  S. Yesylevskyy,et al.  The pore helix is involved in stabilizing the open state of inwardly rectifying K+ channels. , 2003, Biophysical Journal.

[43]  S. Demo,et al.  Ion effects on gating of the Ca(2+)-activated K+ channel correlate with occupancy of the pore. , 1992, Biophysical journal.

[44]  A tyrosine substitution in the cavity wall of a k channel induces an inverted inactivation. , 2008, Biophysical journal.