Chromanol 293B Binding in KCNQ1 (Kv7.1) Channels Involves Electrostatic Interactions with a Potassium Ion in the Selectivity Filter

The chromanol 293B (293B, trans-6-cyano-4-(N-ethylsulfonyl-N-methylamino)-3-hydroxy-2,2-dimethyl-chroman) is a lead compound of potential class III antiarrhythmics that inhibit cardiac IKs potassium channels. These channels are formed by the coassembly of KCNQ1 (Kv7.1, KvLQT1) and KCNE1 subunits. Although homomeric KCNQ1 channels are the principal molecular targets, entry of KCNE1 to the channel complex enhances the chromanol block. Because closely related neuronal KCNQ2 potassium channels are insensitive to the drug, we used KCNQ1/KCNQ2 chimeras to identify the binding site of the inhibitor. We localized the putative drug receptor to the H5 selectivity filter and the S6 transmembrane segment. Single residues affecting 293B inhibition were subsequently identified through systematic exchange of amino acids that were either different in KCNQ1 and KCNQ2 or predicted by a docking model of 293B in the open and closed conformation of KCNQ1. Mutant channel proteins T312S, I337V, and F340Y displayed dramatically lowered sensitivity to chromanol block. The predicted drug binding receptor lies in the inner pore vestibule containing the lower part of the selectivity filter, and the S6 transmembrane domain also reported to be important for binding of benzodiazepines. We propose that the block of the ion permeation pathway involves hydrophobic interactions with the S6 transmembrane residues Ile337 and Phe340, and stabilization of chromanol 293B binding through electrostatic interactions of its oxygen atoms with the most internal potassium ion within the selectivity filter.

[1]  U. Singh,et al.  A NEW FORCE FIELD FOR MOLECULAR MECHANICAL SIMULATION OF NUCLEIC ACIDS AND PROTEINS , 1984 .

[2]  T. McDonald,et al.  KCNE1 Binds to the KCNQ1 Pore to Regulate Potassium Channel Activity , 2004, Neuron.

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

[4]  Jacques Barhanin,et al.  KvLQT1 and IsK (minK) proteins associate to form the IKS cardiac potassium current , 1996, Nature.

[5]  S. Nakanishi,et al.  Cloning of a membrane protein that induces a slow voltage-gated potassium current. , 1988, Science.

[6]  V. Ananthanarayanan,et al.  Homology model of dihydropyridine receptor: implications for L-type Ca(2+) channel modulation by agonists and antagonists. , 2001, Archives of biochemistry and biophysics.

[7]  Structural model of a synthetic Ca2+ channel with bound Ca2+ ions and dihydropyridine ligand. , 1996, Biophysical journal.

[8]  K. Tsai,et al.  Characterization of binding site of closed-state KCNQ1 potassium channel by homology modeling, molecular docking, and pharmacophore identification. , 2005, Biochemical and biophysical research communications.

[9]  R. MacKinnon,et al.  Ion binding affinity in the cavity of the KcsA potassium channel. , 2004, Biochemistry.

[10]  Jane Mitchell,et al.  How Batrachotoxin Modifies the Sodium Channel Permeation Pathway: Computer Modeling and Site-Directed Mutagenesis , 2006, Molecular Pharmacology.

[11]  M. Karplus,et al.  Effective energy function for proteins in solution , 1999, Proteins.

[12]  H. Lerche,et al.  Rapid Report , 2003 .

[13]  B Attali,et al.  Molecular impact of MinK on the enantiospecific block of IKs by chromanols , 2000, British journal of pharmacology.

[14]  D. Roden,et al.  Torsade de pointes , 1993, Clinical cardiology.

[15]  Hans-Jochen Lang,et al.  Synthesis and Activity of Novel and Selective IKs-Channel Blockers , 2001 .

[16]  M. Sanguinetti,et al.  Coassembly of KVLQT1 and minK (IsK) proteins to form cardiac IKS potassium channel , 1996, Nature.

[17]  M. Sanguinetti Modulation of potassium channels by antiarrhythmic and antihypertensive drugs. , 1992, Hypertension.

[18]  Iva Bruhova,et al.  Monte Carlo-energy minimization of correolide in the Kv1.3 channel: possible role of potassium ion in ligand-receptor interactions , 2007, BMC Structural Biology.

[19]  M. Sanguinetti,et al.  Coassembly of K(V)LQT1 and minK (IsK) proteins to form cardiac I(Ks) potassium channel. , 1996, Nature.

[20]  M. Sanguinetti,et al.  Voltage‐dependent inactivation of the human K+ channel KvLQT1 is eliminated by association with minimal K+ channel (minK) subunits , 1998, The Journal of physiology.

[21]  M. Sanguinetti,et al.  Physicochemical basis for binding and voltage-dependent block of hERG channels by structurally diverse drugs. , 2005, Novartis Foundation symposium.

[22]  H. Scheraga,et al.  Monte Carlo-minimization approach to the multiple-minima problem in protein folding. , 1987, Proceedings of the National Academy of Sciences of the United States of America.

[23]  H. Lerche,et al.  C-terminal interaction of KCNQ2 and KCNQ3 K+ channels , 2003 .

[24]  A. Wei,et al.  Molecular Cloning and Functional Expression of KCNQ5, a Potassium Channel Subunit That May Contribute to Neuronal M-current Diversity* , 2000, The Journal of Biological Chemistry.

[25]  L. Salkoff,et al.  KCNQ-like Potassium Channels in Caenorhabditis elegans , 2005, Journal of Biological Chemistry.

[26]  B. Zhorov,et al.  KvAP-based model of the pore region of shaker potassium channel is consistent with cadmium- and ligand-binding experiments. , 2005, Biophysical journal.

[27]  A. Brüggemann,et al.  A kinetic study on the stereospecific inhibition of KCNQ1 and IKs by the chromanol 293B , 2001, British journal of pharmacology.

[28]  A E Busch,et al.  Synthesis and activity of novel and selective I(Ks)-channel blockers. , 2001, Journal of medicinal chemistry.

[29]  G. Kaczorowski,et al.  Binding of correolide to the K(v)1.3 potassium channel: characterization of the binding domain by site-directed mutagenesis. , 2001, Biochemistry.

[30]  R. MacKinnon,et al.  The cavity and pore helices in the KcsA K+ channel: electrostatic stabilization of monovalent cations. , 1999, Science.

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

[32]  Ming Zhou,et al.  A mutant KcsA K(+) channel with altered conduction properties and selectivity filter ion distribution. , 2004, Journal of molecular biology.

[33]  G. Kaczorowski,et al.  Binding of Correolide to the Kv1.3 Potassium Channel: Characterization of the Binding Domain by Site-Directed Mutagenesis† , 2001 .

[34]  K. Murray,et al.  Stereoselective interactions of the enantiomers of chromanol 293B with human voltage-gated potassium channels. , 2000, The Journal of pharmacology and experimental therapeutics.

[35]  S Nattel,et al.  Effects of the chromanol 293B, a selective blocker of the slow, component of the delayed rectifier K+ current, on repolarization in human and guinea pig ventricular myocytes. , 1998, Cardiovascular research.

[36]  M. Sanguinetti,et al.  Molecular and Cellular Mechanisms of Cardiac Arrhythmias , 2001, Cell.

[37]  Mark Leppert,et al.  A novel potassium channel gene, KCNQ2, is mutated in an inherited epilepsy of newborns , 1998, Nature Genetics.

[38]  G. Seebohm,et al.  Identification of Specific Pore Residues Mediating KCNQ1 Inactivation , 2001, The Journal of Biological Chemistry.

[39]  A. George,et al.  Mink Subdomains That Mediate Modulation of and Association with Kvlqt1 , 2000, The Journal of general physiology.

[40]  M. Sanguinetti,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.

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

[42]  A. Schömig,et al.  Differential Effect of β‐Adrenergic Stimulation on the Frequency‐Dependent Electrophysiologic Actions of the New Class III Antiarrhythmics Dofetilide, Ambasilide, and Chromanol 293. , 1997 .

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

[44]  H. Scheraga,et al.  Energy parameters in polypeptides. VII. Geometric parameters, partial atomic charges, nonbonded interactions, hydrogen bond interactions, and intrinsic torsional potentials for the naturally occurring amino acids , 1975 .

[45]  Thomas Friedrich,et al.  A carboxy‐terminal domain determines the subunit specificity of KCNQ K+ channel assembly , 2003, EMBO reports.

[46]  B Attali,et al.  A recessive C‐terminal Jervell and Lange‐Nielsen mutation of the KCNQ1 channel impairs subunit assembly , 2000, The EMBO journal.

[47]  A. Schömig,et al.  Differential effect of beta-adrenergic stimulation on the frequency-dependent electrophysiologic actions of the new class III antiarrhythmics dofetilide, ambasilide, and chromanol 293B. , 1997, Journal of cardiovascular electrophysiology.

[48]  M. Sanguinetti,et al.  Pharmacological Activation of Normal and Arrhythmia-Associated Mutant KCNQ1 Potassium Channels , 2003, Circulation research.

[49]  B. Zhorov,et al.  Sodium channel activators: Model of binding inside the pore and a possible mechanism of action , 2005, FEBS letters.

[50]  M. Sanguinetti,et al.  Delayed rectifier outward K+ current is composed of two currents in guinea pig atrial cells. , 1991, The American journal of physiology.

[51]  R. MacKinnon,et al.  The occupancy of ions in the K+ selectivity filter: charge balance and coupling of ion binding to a protein conformational change underlie high conduction rates. , 2003, Journal of molecular biology.

[52]  M. Sanguinetti,et al.  Molecular determinants of KCNQ1 channel block by a benzodiazepine. , 2003, Molecular pharmacology.