Free-energy relationships in ion channels activated by voltage and ligand

Many ion channels are modulated by multiple stimuli, which allow them to integrate a variety of cellular signals and precisely respond to physiological needs. Understanding how these different signaling pathways interact has been a challenge in part because of the complexity of underlying models. In this study, we analyzed the energetic relationships in polymodal ion channels using linkage principles. We first show that in proteins dually modulated by voltage and ligand, the net free-energy change can be obtained by measuring the charge-voltage (Q-V) relationship in zero ligand condition and the ligand binding curve at highly depolarizing membrane voltages. Next, we show that the voltage-dependent changes in ligand occupancy of the protein can be directly obtained by measuring the Q-V curves at multiple ligand concentrations. When a single reference ligand binding curve is available, this relationship allows us to reconstruct ligand binding curves at different voltages. More significantly, we establish that the shift of the Q-V curve between zero and saturating ligand concentration is a direct estimate of the interaction energy between the ligand- and voltage-dependent pathway. These free-energy relationships were tested by numerical simulations of a detailed gating model of the BK channel. Furthermore, as a proof of principle, we estimate the interaction energy between the ligand binding and voltage-dependent pathways for HCN2 channels whose ligand binding curves at various voltages are available. These emerging principles will be useful for high-throughput mutagenesis studies aimed at identifying interaction pathways between various regulatory domains in a polymodal ion channel.

[1]  J. Wyman,et al.  Generalized binding phenomena in an allosteric macromolecule. , 1985, Biophysical chemistry.

[2]  T. Zimmer,et al.  Interdependence of Receptor Activation and Ligand Binding in HCN2 Pacemaker Channels , 2010, Neuron.

[3]  R. Aldrich,et al.  Allosteric Voltage Gating of Potassium Channels II: Mslo Channel Gating Charge Movement in the Absence of Ca2+ , 1999 .

[4]  J. Qin,et al.  Mechanism of magnesium activation of calcium-activated potassium channels , 2002, Nature.

[5]  Fred J. Sigworth,et al.  Cryo-EM structure of the BK potassium channel in a lipid membrane , 2009, Nature.

[6]  David Julius,et al.  Molecular Basis for Species-Specific Sensitivity to “Hot” Chili Peppers , 2002, Cell.

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

[8]  S J Gill,et al.  Binding capacity: cooperativity and buffering in biopolymers. , 1988, Proceedings of the National Academy of Sciences of the United States of America.

[9]  K. Magleby,et al.  Stepwise contribution of each subunit to the cooperative activation of BK channels by Ca2+ , 2002, Proceedings of the National Academy of Sciences of the United States of America.

[10]  D. H. Cox,et al.  Intrinsic Voltage Dependence and Ca2+ Regulation of mslo Large Conductance Ca-activated K+ Channels , 1997, The Journal of general physiology.

[11]  Bernd Nilius,et al.  The principle of temperature-dependent gating in cold- and heat-sensitive TRP channels , 2004, Nature.

[12]  Baron Chanda,et al.  Estimating the voltage-dependent free energy change of ion channels using the median voltage for activation , 2012, The Journal of general physiology.

[13]  S. Siegelbaum,et al.  Voltage Sensor Movement and cAMP Binding Allosterically Regulate an Inherently Voltage-independent Closed−Open Transition in HCN Channels , 2007, The Journal of general physiology.

[14]  Zhongming Ma,et al.  Role of Charged Residues in the S1–S4 Voltage Sensor of BK Channels , 2006, The Journal of general physiology.

[15]  D. H. Cox,et al.  Elimination of the BK Ca Channel’s High-Affinity Ca 2 (cid:2) Sensitivity , 2002 .

[16]  D. Julius,et al.  The capsaicin receptor: a heat-activated ion channel in the pain pathway , 1997, Nature.

[17]  L. Stanciu,et al.  Structure of TRPV1 channel revealed by electron cryomicroscopy , 2008, Proceedings of the National Academy of Sciences.

[18]  K. Magleby,et al.  Suggests that the Gating Includes Transitions through Intermediate or Secondary States A Mechanism for Flickers , 1998 .

[19]  P. Blumberg,et al.  The cloned rat vanilloid receptor VR1 mediates both R-type binding and C-type calcium response in dorsal root ganglion neurons. , 1999, Molecular pharmacology.

[20]  H. Lester,et al.  Long-range coupling in an allosteric receptor revealed by mutant cycle analysis. , 2009, Biophysical journal.

[21]  R. Dolmetsch Excitation-Transcription Coupling: Signaling by Ion Channels to the Nucleus , 2003, Science's STKE.

[22]  W. N. Zagotta,et al.  CNG and HCN channels: two peas, one pod. , 2006, Annual review of physiology.

[23]  T. Zimmer,et al.  Thermodynamics of activation gating in olfactory-type cyclic nucleotide-gated (CNGA2) channels. , 2008, Biophysical journal.

[24]  B. Chanda,et al.  Deconstructing thermodynamic parameters of a coupled system from site-specific observables , 2010, Proceedings of the National Academy of Sciences.

[25]  D. Colquhoun,et al.  Binding, gating, affinity and efficacy: The interpretation of structure‐activity relationships for agonists and of the effects of mutating receptors , 1998, British journal of pharmacology.

[26]  W. N. Zagotta,et al.  Salt Bridges and Gating in the COOH-terminal Region of HCN2 and CNGA1 Channels , 2004, The Journal of General Physiology.

[27]  M. Muir Physical Chemistry , 1888, Nature.

[28]  K. Magleby,et al.  Voltage and Ca2+ Activation of Single Large-Conductance Ca2+-Activated K+ Channels Described by a Two-Tiered Allosteric Gating Mechanism , 2000, The Journal of general physiology.

[29]  R. Aldrich,et al.  Complex voltage-dependent behavior of single unliganded calcium-sensitive potassium channels. , 2000, Biophysical journal.

[30]  J. Wyman,et al.  LINKED FUNCTIONS AND RECIPROCAL EFFECTS IN HEMOGLOBIN: A SECOND LOOK. , 1964, Advances in protein chemistry.

[31]  A. Marty,et al.  Ca-dependent K channels with large unitary conductance in chromaffin cell membranes , 1981, Nature.

[32]  David E. Clapham,et al.  TRP channels as cellular sensors , 2003, Nature.

[33]  J. Houtman,et al.  Basis of substrate binding and conservation of selectivity in the CLC family of channels and transporters , 2009, Nature Structural &Molecular Biology.

[34]  R. Aldrich,et al.  Allosteric linkage between voltage and Ca(2+)-dependent activation of BK-type mslo1 K(+) channels. , 2000, Biochemistry.

[35]  F. Elinder,et al.  Hysteresis in the Voltage Dependence of HCN Channels , 2005, The Journal of general physiology.

[36]  F. Bezanilla,et al.  Gating currents from Kv7 channels carrying neuronal hyperexcitability mutations in the voltage-sensing domain. , 2012, Biophysical journal.

[37]  Brad S Rothberg,et al.  Inactivation in HCN Channels Results from Reclosure of the Activation Gate Desensitization to Voltage , 2004, Neuron.

[38]  T. Lohman,et al.  Review of Wyman and Gill, Binding and Linkage: Functional Chemistry of Biological Macromolecules , 1993 .

[39]  R. Olcese,et al.  The RCK1 domain of the human BKCa channel transduces Ca2+ binding into structural rearrangements , 2010, The Journal of general physiology.

[40]  S. Siegelbaum,et al.  Regulation of Hyperpolarization-Activated HCN Channels by cAMP through a Gating Switch in Binding Domain Symmetry , 2003, Neuron.

[41]  R. Aldrich,et al.  Allosteric Voltage Gating of Potassium Channels I: Mslo Ionic Currents in the Absence of Ca2+ , 1999 .

[42]  K. Chandy,et al.  Voltage-gated K+ channels in human T lymphocytes: a role in mitogenesis? , 1984, Nature.

[43]  Harini Krishnamurthy,et al.  Neurotransmitter/sodium symporter orthologue LeuT has a single high–affinity substrate site , 2010, Nature.

[44]  D. H. Cox,et al.  Measurements of the BKCa Channel's High-Affinity Ca2+ Binding Constants: Effects of Membrane Voltage , 2008, The Journal of general physiology.

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

[46]  K. Benndorf,et al.  Relating ligand binding to activation gating in CNGA2 channels , 2007, Nature.

[47]  M. Tanouye,et al.  The size of gating charge in wild-type and mutant Shaker potassium channels. , 1992, Science.

[48]  K. Magleby,et al.  Kinetic Structure of Large-Conductance Ca2+-activated K+ Channels Suggests that the Gating Includes Transitions through Intermediate or Secondary States , 1998, The Journal of general physiology.

[49]  W. Catterall,et al.  THE CRYSTAL STRUCTURE OF A VOLTAGE-GATED SODIUM CHANNEL , 2011, Nature.

[50]  B. Hille,et al.  Ionic channels of excitable membranes , 2001 .

[51]  S. Pickering,et al.  Cell-cycle control of a large-conductance K+ channel in mouse early embryos , 1993, Nature.

[52]  Dario DiFrancesco,et al.  Integrated Allosteric Model of Voltage Gating of Hcn Channels , 2001, The Journal of general physiology.

[53]  D. H. Cox,et al.  Elimination of the BKCa Channel's High-Affinity Ca2+ Sensitivity , 2002, The Journal of general physiology.

[54]  F. Elinder,et al.  Voltage-sensing mechanism is conserved among ion channels gated by opposite voltages , 2002, Nature.

[55]  D. H. Cox,et al.  Allosteric Gating of a Large Conductance Ca-activated K Ϩ Channel , 2022 .

[56]  J. Wyman,et al.  Linkage graphs: a study in the thermodynamics of macromolecules , 1984, Quarterly Reviews of Biophysics.

[57]  C. Lingle,et al.  Barium ions selectively activate BK channels via the Ca2+-bowl site , 2012, Proceedings of the National Academy of Sciences.

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

[59]  Richard W. Aldrich,et al.  Coupling between Voltage Sensor Activation, Ca2+ Binding and Channel Opening in Large Conductance (BK) Potassium Channels , 2002, The Journal of general physiology.

[60]  G. Yellen,et al.  Charge movement in gating-locked HCN channels reveals weak coupling of voltage sensors and gate , 2012, The Journal of general physiology.

[61]  Klaus Benndorf,et al.  How subunits cooperate in cAMP-induced activation of homotetrameric HCN2 channels. , 2012, Nature chemical biology.

[62]  C. Lingle,et al.  Multiple regulatory sites in large-conductance calcium-activated potassium channels , 2002, Nature.

[63]  K. Magleby Gating Mechanism of BK (Slo1) Channels , 2003, The Journal of general physiology.