scholarly journals Can Shaker Potassium Channels be Locked in the Deactivated State?

2004 ◽  
Vol 124 (2) ◽  
pp. 163-171 ◽  
Author(s):  
Youshan Yang ◽  
Yangyang Yan ◽  
Fred J. Sigworth
Keyword(s):  
Xenopus Oocytes ◽  
Voltage Dependence ◽  
Voltage Sensor ◽  
Structural Studies ◽  
Gating Currents ◽  
Shaker Potassium Channel ◽  
Voltage Sensors ◽  
Voltage Gated ◽  
Gated Channel ◽  
Shaker Potassium Channels

For structural studies it would be useful to constrain the voltage sensor of a voltage-gated channel in its deactivated state. Here we consider one Shaker potassium channel mutant and speculate about others that might allow the channel to remain deactivated at zero membrane potential. Ionic and gating currents of F370C Shaker, expressed in Xenopus oocytes, were recorded in patches with internal application of the methanethiosulfonate reagent MTSET. It appears that the voltage dependence of voltage sensor movement is strongly shifted by reaction with internal MTSET, such that the voltage sensors appear to remain deactivated even at positive potentials. A disadvantage of this construct is that the rate of modification of voltage sensors by MTSET is quite low, ∼0.17 mM−1·s−1 at −80 mV, and is expected to be much lower at depolarized potentials.

Gating kinetics of ShakerK+ channels are differentially modified by general anesthetics

1998 ◽  
Vol 275 (4) ◽  
pp. C1009-C1021 ◽  
Author(s):  
Ana M. Correa
Keyword(s):  
Xenopus Oocytes ◽  
Ionic Currents ◽  
General Anesthetics ◽  
Gating Currents ◽  
Voltage Gated ◽  
Gating Kinetics ◽  
Shaker Channels ◽  
Gated Channel ◽  
Sites Of Action ◽  
Kinetics Of

The ShakerB K+ channel was used as a model voltage-gated channel to probe the interaction of volatile general anesthetics with gating mechanisms. The effects of three anesthetics, chloroform (CHCl3), isoflurane, and halothane, were studied using recombinant native and mutant Shaker channels expressed in Xenopus oocytes. Gating currents and macroscopic ionic currents were recorded with the cut-open oocyte voltage-clamp technique. The effects of CHCl3 and isoflurane on gating kinetics of noninactivating mutants were opposite, whereas halothane had no effect. The effects on ionic currents were also agent dependent: CHCl3 and halothane produced a reduction of the macroscopic conductance, whereas isoflurane increased it. The results indicate that the gating machinery of the channel is mostly insensitive to the anesthetics during activation until near the open state. The effects on the conductance are mainly due to changes in the transitions in and out of the open state. The data give support to direct protein-anesthetic interactions. The magnitude and nature of the effects invite reconsideration of Shaker-like K+ channels as important sites of action of general anesthetics.

scholarly journals Tuning voltage-gated channel activity and cellular excitability with a sphingomyelinase

2013 ◽  
Vol 142 (4) ◽  
pp. 367-380 ◽  
Author(s):  
David J. Combs ◽  
Hyeon-Gyu Shin ◽  
Yanping Xu ◽  
Yajamana Ramu ◽  
Zhe Lu
Keyword(s):  
Membrane Potential ◽  
Mammalian Cells ◽  
Resting Membrane Potential ◽  
Xenopus Laevis Oocytes ◽  
Channel Activity ◽  
Excitable Cells ◽  
Voltage Sensors ◽  
Voltage Gated ◽  
Activated State ◽  
Gated Channel

Voltage-gated ion channels generate action potentials in excitable cells and help set the resting membrane potential in nonexcitable cells like lymphocytes. It has been difficult to investigate what kinds of phospholipids interact with these membrane proteins in their native environments and what functional impacts such interactions create. This problem might be circumvented if we could modify specific lipid types in situ. Using certain voltage-gated K+ (KV) channels heterologously expressed in Xenopus laevis oocytes as a model, our group has shown previously that sphingomyelinase (SMase) D may serve this purpose. SMase D is known to remove the choline group from sphingomyelin, a phospholipid primarily present in the outer leaflet of plasma membranes. This SMase D action lowers the energy required for voltage sensors of a KV channel to enter the activated state, causing a hyperpolarizing shift of the Q-V and G-V curves and thus activating them at more hyperpolarized potentials. Here, we find that this SMase D effect vanishes after removing most of the voltage-sensor paddle sequence, a finding supporting the notion that SMase D modification of sphingomyelin molecules alters these lipids’ interactions with voltage sensors. Then, using SMase D to probe lipid–channel interactions, we find that SMase D not only similarly stimulates voltage-gated Na+ (NaV) and Ca2+ channels but also markedly slows NaV channel inactivation. However, the latter effect is not observed in tested mammalian cells, an observation highlighting the profound impact of the membrane environment on channel function. Finally, we directly demonstrate that SMase D stimulates both native KV1.3 in nonexcitable human T lymphocytes at their typical resting membrane potential and native NaV channels in excitable cells, such that it shifts the action potential threshold in the hyperpolarized direction. These proof-of-concept studies illustrate that the voltage-gated channel activity in both excitable and nonexcitable cells can be tuned by enzymatically modifying lipid head groups.

scholarly journals Mode shift of the voltage sensors in Shaker K+ channels is caused by energetic coupling to the pore domain

2011 ◽  
Vol 137 (5) ◽  
pp. 455-472 ◽  
Author(s):  
Georges A. Haddad ◽  
Rikard Blunck
Keyword(s):  
Conformational Change ◽  
Mechanical Load ◽  
Voltage Sensor ◽  
Charge Movement ◽  
Gating Currents ◽  
Mode Shift ◽  
Voltage Sensors ◽  
Pore Opening ◽  
Voltage Gated Ion Channels ◽  
Pore Domain

The voltage sensors of voltage-gated ion channels undergo a conformational change upon depolarization of the membrane that leads to pore opening. This conformational change can be measured as gating currents and is thought to be transferred to the pore domain via an annealing of the covalent link between voltage sensor and pore (S4-S5 linker) and the C terminus of the pore domain (S6). Upon prolonged depolarizations, the voltage dependence of the charge movement shifts to more hyperpolarized potentials. This mode shift had been linked to C-type inactivation but has recently been suggested to be caused by a relaxation of the voltage sensor itself. In this study, we identified two ShakerIR mutations in the S4-S5 linker (I384N) and S6 (F484G) that, when mutated, completely uncouple voltage sensor movement from pore opening. Using these mutants, we show that the pore transfers energy onto the voltage sensor and that uncoupling the pore from the voltage sensor leads the voltage sensors to be activated at more negative potentials. This uncoupling also eliminates the mode shift occurring during prolonged depolarizations, indicating that the pore influences entry into the mode shift. Using voltage-clamp fluorometry, we identified that the slow conformational change of the S4 previously correlated with the mode shift disappears when uncoupling the pore. The effects can be explained by a mechanical load that is imposed upon the voltage sensors by the pore domain and allosterically modulates its conformation. Mode shift is caused by the stabilization of the open state but leads to a conformational change in the voltage sensor.

scholarly journals Basis for allosteric open-state stabilization of voltage-gated potassium channels by intracellular cations

2012 ◽  
Vol 140 (5) ◽  
pp. 495-511 ◽  
Author(s):  
Samuel J. Goodchild ◽  
Hongjian Xu ◽  
Zeineb Es-Salah-Lamoureux ◽  
Christopher A. Ahern ◽  
David Fedida
Keyword(s):  
Ionic Current ◽  
Structural Features ◽  
Voltage Sensor ◽  
Gating Currents ◽  
Voltage Gated ◽  
Kv Channels ◽  
Deactivation Kinetics ◽  
Channel Opening ◽  
In The Wild ◽  
Pore Closure

The open state of voltage-gated potassium (Kv) channels is associated with an increased stability relative to the pre-open closed states and is reflected by a slowing of OFF gating currents after channel opening. The basis for this stabilization is usually assigned to intrinsic structural features of the open pore. We have studied the gating currents of Kv1.2 channels and found that the stabilization of the open state is instead conferred largely by the presence of cations occupying the inner cavity of the channel. Large impermeant intracellular cations such as N-methyl-d-glucamine (NMG+) and tetraethylammonium cause severe slowing of channel closure and gating currents, whereas the smaller cation, Cs+, displays a more moderate effect on voltage sensor return. A nonconducting mutant also displays significant open state stabilization in the presence of intracellular K+, suggesting that K+ ions in the intracellular cavity also slow pore closure. A mutation in the S6 segment used previously to enlarge the inner cavity (Kv1.2-I402C) relieves the slowing of OFF gating currents in the presence of the large NMG+ ion, suggesting that the interaction site for stabilizing ions resides within the inner cavity and creates an energetic barrier to pore closure. The physiological significance of ionic occupation of the inner cavity is underscored by the threefold slowing of ionic current deactivation in the wild-type channel compared with Kv1.2-I402C. The data suggest that internal ions, including physiological concentrations of K+, allosterically regulate the deactivation kinetics of the Kv1.2 channel by impairing pore closure and limiting the return of voltage sensors. This may represent a primary mechanism by which Kv channel deactivation kinetics is linked to ion permeation and reveals a novel role for channel inner cavity residues to indirectly regulate voltage sensor dynamics.

scholarly journals KCNE3 acts by promoting voltage sensor activation in KCNQ1

2015 ◽  
Vol 112 (52) ◽  
pp. E7286-E7292 ◽  
Author(s):  
Rene Barro-Soria ◽  
Marta E. Perez ◽  
H. Peter Larsson
Keyword(s):  
Electrostatic Interaction ◽  
Voltage Dependence ◽  
Voltage Sensor ◽  
Α Subunit ◽  
Voltage Range ◽  
Voltage Gated ◽  
Gate Opening ◽  
Channel Gate ◽  
Sensor Activation ◽  
Voltage Sensing Domain

KCNE β-subunits assemble with and modulate the properties of voltage-gated K+ channels. In the colon, stomach, and kidney, KCNE3 coassembles with the α-subunit KCNQ1 to form K+ channels important for K+ and Cl− secretion that appear to be voltage-independent. How KCNE3 subunits turn voltage-gated KCNQ1 channels into apparent voltage-independent KCNQ1/KCNE3 channels is not completely understood. Different mechanisms have been proposed to explain the effect of KCNE3 on KCNQ1 channels. Here, we use voltage clamp fluorometry to determine how KCNE3 affects the voltage sensor S4 and the gate of KCNQ1. We find that S4 moves in KCNQ1/KCNE3 channels, and that inward S4 movement closes the channel gate. However, KCNE3 shifts the voltage dependence of S4 movement to extreme hyperpolarized potentials, such that in the physiological voltage range, the channel is constitutively conducting. By separating S4 movement and gate opening, either by a mutation or PIP2 depletion, we show that KCNE3 directly affects the S4 movement in KCNQ1. Two negatively charged residues of KCNE3 (D54 and D55) are found essential for the effect of KCNE3 on KCNQ1 channels, mainly exerting their effects by an electrostatic interaction with R228 in S4. Our results suggest that KCNE3 primarily affects the voltage-sensing domain and only indirectly affects the gate.

scholarly journals The trajectory of discrete gating charges in a voltage-gated potassium channel

2020 ◽  
Author(s):  
Michael F. Priest ◽  
Elizabeth E.L. Lee ◽  
Francisco Bezanilla
Keyword(s):  
Potassium Channel ◽  
Voltage Sensor ◽  
Drive Voltage ◽  
Shaker Potassium Channel ◽  
Voltage Gated ◽  
Charged Amino Acids ◽  
Voltage Gated Ion Channels ◽  
Sensing Membrane ◽  
Positively Charged ◽  
Gating Charges

AbstractPositively-charged amino acids respond to membrane potential changes to drive voltage sensor movement in voltage-gated ion channels, but determining the trajectory of voltage sensor gating charges has proven difficult. We optically tracked the movement of the two most extracellular charged residues (R1, R2) in the Shaker potassium channel voltage sensor using a fluorescent positively-charged bimane derivative (qBBr) that is strongly quenched by tryptophan. By individually mutating residues to tryptophan within the putative trajectory of gating charges, we observed that the charge pathway during activation is a rotation and a tilted translation that differs between R1 and R2 and is distinct from their deactivation pathway. Tryptophan-induced quenching of qBBr also indicates that a crucial residue of the hydrophobic plug is linked to the Cole-Moore shift through its interaction with R1. Finally, we show that this approach extends to additional voltage-sensing membrane proteins using the Ciona intestinalis voltage sensitive phosphatase (CiVSP).

scholarly journals Cryo-EM structure of the KvAP channel reveals a non-domain-swapped voltage sensor topology

eLife ◽  
2019 ◽  
Vol 8 ◽  
Author(s):  
Xiao Tao ◽  
Roderick MacKinnon
Keyword(s):  
Ion Channels ◽  
Conformational Changes ◽  
Voltage Sensor ◽  
Structural Domains ◽  
Structural Class ◽  
Voltage Sensors ◽  
Voltage Gated ◽  
Voltage Dependent ◽  
Voltage Gated Ion Channels ◽  
Gated Ion Channels

Conductance in voltage-gated ion channels is regulated by membrane voltage through structural domains known as voltage sensors. A single structural class of voltage sensor domain exists, but two different modes of voltage sensor attachment to the pore occur in nature: domain-swapped and non-domain-swapped. Since the more thoroughly studied Kv1-7, Nav and Cav channels have domain-swapped voltage sensors, much less is known about non-domain-swapped voltage-gated ion channels. In this paper, using cryo-EM, we show that KvAP from Aeropyrum pernix has non-domain-swapped voltage sensors as well as other unusual features. The new structure, together with previous functional data, suggests that KvAP and the Shaker channel, to which KvAP is most often compared, probably undergo rather different voltage-dependent conformational changes when they open.

scholarly journals Tracking the movement of discrete gating charges in a voltage-gated potassium channel

eLife ◽  
2021 ◽  
Vol 10 ◽  
Author(s):  
Michael F Priest ◽  
Elizabeth EL Lee ◽  
Francisco Bezanilla
Keyword(s):  
Potassium Channel ◽  
Voltage Sensor ◽  
Charge Motion ◽  
Shaker Potassium Channel ◽  
Voltage Gated ◽  
Charged Amino Acids ◽  
Voltage Gated Ion Channels ◽  
Sensing Membrane ◽  
Positively Charged ◽  
Gating Charges

Positively-charged amino acids respond to membrane potential changes to drive voltage sensor movement in voltage-gated ion channels, but determining the displacements of voltage sensor gating charges has proven difficult. We optically tracked the movement of the two most extracellular charged residues (R1, R2) in the Shaker potassium channel voltage sensor using a fluorescent positively-charged bimane derivative (qBBr) that is strongly quenched by tryptophan. By individually mutating residues to tryptophan within the putative pathway of gating charges, we observed that the charge motion during activation is a rotation and a tilted translation that differs between R1 and R2. Tryptophan-induced quenching of qBBr also indicates that a crucial residue of the hydrophobic plug is linked to the Cole-Moore shift through its interaction with R1. Finally, we show that this approach extends to additional voltage-sensing membrane proteins using the Ciona intestinalis voltage sensitive phosphatase (CiVSP) (Murata et al., 2005a).

scholarly journals Histidine Scanning Mutagenesis of Basic Residues of the S4 Segment of the Shaker K+ Channel

2001 ◽  
Vol 117 (5) ◽  
pp. 469-490 ◽  
Author(s):  
Dorine M. Starace ◽  
Francisco Bezanilla
Keyword(s):  
Membrane Potential ◽  
Voltage Sensor ◽  
Internal Exposure ◽  
Bulk Solution ◽  
K Channel ◽  
Gating Currents ◽  
Basic Residue ◽  
Shaker Potassium Channel ◽  
Local Environments ◽  
S4 Segment

The voltage sensor of the Shaker potassium channel is comprised mostly of positively charged residues in the putative fourth transmembrane segment, S4 (Aggarwal, S.K., and R. MacKinnon. 1996. Neuron. 16:1169–1177; Seoh, S.-A., D. Sigg, D.M. Papazian, and F. Bezanilla. 1996. Neuron. 16:1159–1167). Movement of the voltage sensor in response to a change in the membrane potential was examined indirectly by measuring how the accessibilities of residues in and around the sensor change with voltage. Each basic residue in the S4 segment was individually replaced with a histidine. If the histidine tag is part of the voltage sensor, then the gating charge displaced by the voltage sensor will include the histidine charge. Accessibility of the histidine to the bulk solution was therefore monitored as pH-dependent changes in the gating currents evoked by membrane potential pulses. Histidine scanning mutagenesis has several advantages over other similar techniques. Since histidine accessibility is detected by labeling with solution protons, very confined local environments can be resolved and labeling introduces minimal interference of voltage sensor motion. After histidine replacement of either residue K374 or R377, there was no titration of the gating currents with internal or external pH, indicating that these residues do not move in the transmembrane electric field or that they are always inaccessible. Histidine replacement of residues R365, R368, and R371, on the other hand, showed that each of these residues traverses entirely from internal exposure at hyperpolarized potentials to external exposure at depolarized potentials. This translocation enables the histidine to transport protons across the membrane in the presence of a pH gradient. In the case of 371H, depolarization drives the histidine to a position that forms a proton pore. Kinetic models of titrateable voltage sensors that account for proton transport and conduction are presented. Finally, the results presented here are incorporated into existing information to propose a model of voltage sensor movement and structure.

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