Structural basis of ion permeation gating in Slo2.1 K+ channels

The activation gate of ion channels controls the transmembrane flux of permeant ions. In voltage-gated K+ channels, the aperture formed by the S6 bundle crossing can widen to open or narrow to close the ion permeation pathway, whereas the selectivity filter gates ion flux in cyclic-nucleotide gated (CNG) and Slo1 channels. Here we explore the structural basis of the activation gate for Slo2.1, a weakly voltage-dependent K+ channel that is activated by intracellular Na+ and Cl−. Slo2.1 channels were heterologously expressed in Xenopus laevis oocytes and activated by elevated [NaCl]i or extracellular application of niflumic acid. In contrast to other voltage-gated channels, Slo2.1 was blocked by verapamil in an activation-independent manner, implying that the S6 bundle crossing does not gate the access of verapamil to its central cavity binding site. The structural basis of Slo2.1 activation was probed by Ala scanning mutagenesis of the S6 segment and by mutation of selected residues in the pore helix and S5 segment. Mutation to Ala of three S6 residues caused reduced trafficking of channels to the cell surface and partial (K256A, I263A, Q273A) or complete loss (E275A) of channel function. P271A Slo2.1 channels trafficked normally, but were nonfunctional. Further mutagenesis and intragenic rescue by second site mutations suggest that Pro271 and Glu275 maintain the inner pore in an open configuration by preventing formation of a tight S6 bundle crossing. Mutation of several residues in S6 and S5 predicted by homology modeling to contact residues in the pore helix induced a gain of channel function. Substitution of the pore helix residue Phe240 with polar residues induced constitutive channel activation. Together these findings suggest that (1) the selectivity filter and not the bundle crossing gates ion permeation and (2) dynamic coupling between the pore helix and the S5 and S6 segments mediates Slo2.1 channel activation.

[1]  M. Sanguinetti,et al.  Structure-Activity Relationship of Fenamates as Slo2.1 Channel Activators , 2012, Molecular Pharmacology.

[2]  F. Sachse,et al.  Tuning of EAG K+ channel inactivation: Molecular determinants of amplification by mutations and a small molecule , 2012, The Journal of general physiology.

[3]  Expression, Purification and Functional Reconstitution of Slack Sodium-Activated Potassium Channels , 2012, The Journal of Membrane Biology.

[4]  T. Begenisich,et al.  Selectivity filter gating in large-conductance Ca2+-activated K+ channels , 2012, The Journal of general physiology.

[5]  L. Salkoff,et al.  Sodium-Activated Potassium Channels Are Functionally Coupled to Persistent Sodium Currents , 2012, The Journal of Neuroscience.

[6]  A. Wojtovich,et al.  SLO-2 Is Cytoprotective and Contributes to Mitochondrial Potassium Transport , 2011, PloS one.

[7]  R. Aldrich,et al.  Charge substitution for a deep-pore residue reveals structural dynamics during BK channel gating , 2011, The Journal of general physiology.

[8]  C. Lingle,et al.  Cysteine scanning and modification reveal major differences between BK channels and Kv channels in the inner pore region , 2011, Proceedings of the National Academy of Sciences.

[9]  M. Sanguinetti,et al.  Activation of Slo2.1 channels by niflumic acid , 2010, The Journal of general physiology.

[10]  A. Bhattacharjee,et al.  NAD+ Activates KNa Channels in Dorsal Root Ganglion Neurons , 2009, The Journal of Neuroscience.

[11]  L. Salkoff,et al.  Na+-activated K+ channels express a large delayed outward current in neurons during normal physiology , 2009, Nature Neuroscience.

[12]  Keehyoung Joo,et al.  Improving physical realism, stereochemistry, and side‐chain accuracy in homology modeling: Four approaches that performed well in CASP8 , 2009, Proteins.

[13]  A Highly Conserved Alanine in the S6 Domain of the hERG1 K+ Channel is Required for Normal Gating , 2008, Cellular Physiology and Biochemistry.

[14]  W. N. Zagotta,et al.  C-terminal Movement during Gating in Cyclic Nucleotide-modulated Channels* , 2008, Journal of Biological Chemistry.

[15]  J. Contreras,et al.  Gating at the selectivity filter in cyclic nucleotide-gated channels , 2008, Proceedings of the National Academy of Sciences.

[16]  A. Bruening-Wright,et al.  Evidence for a Deep Pore Activation Gate in Small Conductance Ca2+-activated K+ Channels , 2007, The Journal of general physiology.

[17]  A. Zou,et al.  Verapamil blocks HERG channel by the helix residue Y652 and F656 in the S6 transmembrane domain , 2007, Acta Pharmacologica Sinica.

[18]  R. Sauvé,et al.  Structural Determinants of the Closed KCa3.1 Channel Pore in Relation to Channel Gating: Results from a Substituted Cysteine Accessibility Analysis , 2007, The Journal of general physiology.

[19]  R. Aldrich,et al.  State-dependent Block of BK Channels by Synthesized Shaker Ball Peptides , 2006, The Journal of general physiology.

[20]  R. Aldrich,et al.  State-independent Block of BK Channels by an Intracellular Quaternary Ammonium , 2006, The Journal of general physiology.

[21]  B. S. Rothberg,et al.  Modulation of MthK Potassium Channel Activity at the Intracellular Entrance to the Pore* , 2006, Journal of Biological Chemistry.

[22]  J. Contreras,et al.  Access of Quaternary Ammonium Blockers to the Internal Pore of Cyclic Nucleotide-gated Channels: Implications for the Location of the Gate , 2006, The Journal of general physiology.

[23]  K. Swartz,et al.  Stabilizing the Closed S6 Gate in the Shaker K v Channel Through Modification of a Hydrophobic Seal , 2004, The Journal of general physiology.

[24]  R. Aldrich,et al.  Unique Inner Pore Properties of BK Channels Revealed by Quaternary Ammonium Block , 2004, The Journal of general physiology.

[25]  M. Sanguinetti,et al.  Molecular Basis for Kv1.5 Channel Block , 2004, Journal of Biological Chemistry.

[26]  H. Lester,et al.  Voltage clamping of Xenopus laevis oocytes utilizing agarose-cushion electrodes , 1994, Pflügers Archiv.

[27]  Sodium-activated potassium current in sensory neurons: a comparison of cell-attached and cell-free single-channel activities , 1992, Pflügers Archiv.

[28]  G. Trube,et al.  Does the organic calcium channel blocker D600 act from inside or outside on the cardiac cell membrane? , 1982, Pflügers Archiv.

[29]  B. Sakmann,et al.  Improved patch-clamp techniques for high-resolution current recording from cells and cell-free membrane patches , 1981, Pflügers Archiv.

[30]  L. Kaczmarek,et al.  Slick (Slo2.1), a Rapidly-Gating Sodium-Activated Potassium Channel Inhibited by ATP , 2003, The Journal of Neuroscience.

[31]  Christopher Miller,et al.  Electrostatic tuning of ion conductance in potassium channels. , 2003, Biochemistry.

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

[33]  L. Kaczmarek,et al.  The Sodium-Activated Potassium Channel Is Encoded by a Member of the Slo Gene Family , 2003, Neuron.

[34]  D. Hackos,et al.  Scanning the Intracellular S6 Activation Gate in the Shaker K+ Channel , 2002, The Journal of general physiology.

[35]  Youxing Jiang,et al.  The open pore conformation of potassium channels , 2002, Nature.

[36]  Gert Vriend,et al.  Increasing the precision of comparative models with YASARA NOVA—a self‐parameterizing force field , 2002, Proteins.

[37]  W. N. Zagotta,et al.  Rotational movement during cyclic nucleotide-gated channel opening , 2001, Nature.

[38]  W. N. Zagotta,et al.  Conformational Changes in S6 Coupled to the Opening of Cyclic Nucleotide-Gated Channels , 2001, Neuron.

[39]  A. Harper,et al.  Verapamil Block of Large-Conductance Ca-Activated K Channels in Rat Aortic Myocytes , 2001, The Journal of Membrane Biology.

[40]  S. Siegelbaum,et al.  Change of Pore Helix Conformational State upon Opening of Cyclic Nucleotide-Gated Channels , 2000, Neuron.

[41]  Jun Chen,et al.  A structural basis for drug-induced long QT syndrome. , 2000, Proceedings of the National Academy of Sciences of the United States of America.

[42]  P. Roncaglia,et al.  Cyclic nucleotide-gated channels: intra- and extracellular accessibility to Cd2+ of substituted cysteine residues within the P-loop , 2000, Pflügers Archiv.

[43]  P. Roncaglia,et al.  Cyclic nucleotide-gated channels: intra- and extracellular accessibility to Cd , 2000 .

[44]  C. January,et al.  Mechanism of block and identification of the verapamil binding domain to HERG potassium channels. , 1999, Circulation research.

[45]  F. Franciolini,et al.  Mechanism of verapamil block of a neuronal delayed rectifier K channel: active form of the blocker and location of its binding domain , 1999, British journal of pharmacology.

[46]  B. Chait,et al.  The structure of the potassium channel: molecular basis of K+ conduction and selectivity. , 1998, Science.

[47]  W. Catterall,et al.  Molecular Determinants of High Affinity Phenylalkylamine Block of l-type Calcium Channels in Transmembrane Segment IIIS6 and the Pore Region of the α1Subunit* , 1997, The Journal of Biological Chemistry.

[48]  B. Ache,et al.  Gating and Conduction Properties of a Sodium-activated Cation Channel from Lobster Olfactory Receptor Neurons , 1997, The Journal of Membrane Biology.

[49]  T. Nagao,et al.  1,5-benzothiazepine binding domain is located on the extracellular side of the cardiac L-type Ca2+ channel. , 1997, Molecular pharmacology.

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

[51]  S. Siegelbaum,et al.  Exposure of Residues in the Cyclic Nucleotide–Gated Channel Pore: P Region Structure and Function in Gating , 1996, Neuron.

[52]  R. Aldrich,et al.  Cooperative subunit interactions in C-type inactivation of K channels. , 1995, Biophysical journal.

[53]  T. DeCoursey Mechanism of K+ channel block by verapamil and related compounds in rat alveolar epithelial cells , 1995, The Journal of general physiology.

[54]  W. Catterall,et al.  Molecular Determinants of High Affinity Phenylalkylamine Block of L-type Calcium Channels (*) , 1995, The Journal of Biological Chemistry.

[55]  S. Dryer Na+-activated K+ channels: a new family of large-conductance ion channels , 1994, Trends in Neurosciences.

[56]  L. Toro,et al.  Potentiation of large conductance KCa channels by niflumic, flufenamic, and mefenamic acids. , 1994, Biophysical journal.

[57]  G. Isenberg,et al.  Microheterogeneity of subsarcolemmal sodium gradients. Electron probe microanalysis in guinea‐pig ventricular myocytes. , 1993, The Journal of physiology.

[58]  R. North,et al.  Calcium-activated potassium channels expressed from cloned complementary DNAs , 1992, Neuron.

[59]  I. Levitan,et al.  Properties and rundown of sodium-activated potassium channels in rat olfactory bulb neurons , 1992, The Journal of neuroscience : the official journal of the Society for Neuroscience.

[60]  W. Stühmer,et al.  Electrophysiological recording from Xenopus oocytes. , 1992, Methods in enzymology.

[61]  A. Noma,et al.  Conductance properties of the Na(+)‐activated K+ channel in guinea‐pig ventricular cells. , 1991, The Journal of physiology.

[62]  A. L. Goldin Expression of ion channels by injection of mRNA into Xenopus oocytes. , 1991, Methods in cell biology.

[63]  R. Chapman,et al.  A sodium‐activated potassium current in intact ventricular myocytes isolated from the guinea‐pig heart , 1990, Experimental physiology.

[64]  C. Bader,et al.  Potassium current activated by intracellular sodium in quail trigeminal ganglion neurons , 1990, The Journal of general physiology.

[65]  M. Sanguinetti Na+1-activated and ATP-sensitive K+ channels in the heart. , 1990, Progress in clinical and biological research.

[66]  C. Bader,et al.  Sodium-activated potassium channel in avian sensory neurons. , 1989, Cell biology international reports.

[67]  H. Scheraga,et al.  Proline‐induced constraints in α‐helices , 1987, Biopolymers.

[68]  T. Steitz,et al.  Identifying nonpolar transbilayer helices in amino acid sequences of membrane proteins. , 1986, Annual review of biophysics and biophysical chemistry.

[69]  C. Bader,et al.  Sodium-activated potassium current in cultured avian neurones , 1985, Nature.

[70]  H. Irisawa,et al.  Intracellular Na+ activates a K+ channel in mammalian cardiac cells , 1984, Nature.

[71]  R. Tsien,et al.  Mechanism of calcium channel blockade by verapamil, D600, diltiazem and nitrendipine in single dialysed heart cells , 1983, Nature.

[72]  M. Levitt A simplified representation of protein conformations for rapid simulation of protein folding. , 1976, Journal of molecular biology.