scholarly journals Replacing voltage sensor arginines with citrulline provides mechanistic insight into charge versus shape

2018 ◽  
Vol 150 (7) ◽  
pp. 1017-1024 ◽  
Author(s):  
Daniel T. Infield ◽  
Elizabeth E.L. Lee ◽  
Jason D. Galpin ◽  
Grace D. Galles ◽  
Francisco Bezanilla ◽  
...  
Keyword(s):  
Positive Charge ◽  
Voltage Sensor ◽  
Nonsense Suppression ◽  
Side Chain ◽  
Voltage Sensitivity ◽  
Shaker Potassium Channel ◽  
Voltage Dependent ◽  
Arginine Residues ◽  
Kinetics Of

Voltage-dependent activation of voltage-gated cation channels results from the outward movement of arginine-bearing helices within proteinaceous voltage sensors. The voltage-sensing residues in potassium channels have been extensively characterized, but current functional approaches do not allow a distinction between the electrostatic and steric contributions of the arginine side chain. Here we use chemical misacylation and in vivo nonsense suppression to encode citrulline, a neutral and nearly isosteric analogue of arginine, into the voltage sensor of the Shaker potassium channel. We functionally characterize the engineered channels and compare them with those bearing conventional mutations at the same positions. We observe effects on both voltage sensitivity and gating kinetics, enabling dissection of the roles of residue structure versus positive charge in channel function. In some positions, substitution with citrulline causes mild effects on channel activation compared with natural mutations. In contrast, substitution of the fourth S4 arginine with citrulline causes substantial changes in the conductance–voltage relationship and the kinetics of the channel, which suggests that a positive charge is required at this position for efficient voltage sensor deactivation and channel closure. The encoding of citrulline is expected to enable enhanced precision for the study of arginine residues located in crowded transmembrane environments in other membrane proteins. In addition, the method may facilitate the study of citrullination in vivo.

Role of S4 positively charged residues in the regulation of Kv4.3 inactivation and recovery

2007 ◽  
Vol 293 (3) ◽  
pp. C906-C914 ◽  
Author(s):  
Matthew R. Skerritt ◽  
Donald L. Campbell
Keyword(s):  
Positive Charge ◽  
Voltage Sensitivity ◽  
Shaker Channels ◽  
Recovery From Inactivation ◽  
Kv4 Channels ◽  
Charged Residues ◽  
Arginine Residues ◽  
Voltage Sensing Domain ◽  
Positively Charged

The molecular and biophysical mechanisms by which voltage-sensitive K+ (Kv)4 channels inactivate and recover from inactivation are presently unresolved. There is a general consensus, however, that Shaker-like N- and P/C-type mechanisms are likely not involved. Kv4 channels also display prominent inactivation from preactivated closed states [closed-state inactivation (CSI)], a process that appears to be absent in Shaker channels. As in Shaker channels, voltage sensitivity in Kv4 channels is thought to be conferred by positively charged residues localized to the fourth transmembrane segment (S4) of the voltage-sensing domain. To investigate the role of S4 positive charge in Kv4.3 gating transitions, we analyzed the effects of charge elimination at each positively charged arginine (R) residue by mutation to the uncharged residue alanine (A). We first demonstrated that R290A, R293A, R296A, and R302A mutants each alter basic activation characteristics consistent with positive charge removal. We then found strong evidence that recovery from inactivation is coupled to deactivation, showed that the precise location of the arginine residues within S4 plays an important role in the degree of development of CSI and recovery from CSI, and demonstrated that the development of CSI can be sequentially uncoupled from activation by R296A, specifically. Taken together, these results extend our current understanding of Kv4.3 gating transitions.

scholarly journals Structural and Functional Role of the Extracellular S5-P Linker in the HERG Potassium Channel

2002 ◽  
Vol 120 (5) ◽  
pp. 723-737 ◽  
Author(s):  
Jie Liu ◽  
Mei Zhang ◽  
Min Jiang ◽  
Gea-Ny Tseng
Keyword(s):  
Functional Role ◽  
Function Analysis ◽  
Voltage Sensor ◽  
Herg Channel ◽  
Side Chain ◽  
Voltage Sensitivity ◽  
Fast Kinetics ◽  
Channel Function ◽  
Outer Vestibule

C-type inactivation in the HERG channel is unique among voltage-gated K channels in having extremely fast kinetics and strong voltage sensitivity. This suggests that HERG may have a unique outer mouth structure (where conformational changes underlie C-type inactivation), and/or a unique communication between the outer mouth and the voltage sensor. We use cysteine-scanning mutagenesis and thiol-modifying reagents to probe the structural and functional role of the S5-P (residues 571–613) and P-S6 (residues 631–638) linkers of HERG that line the outer vestibule of the channel. Disulfide formation involving introduced cysteine side chains or modification of side chain properties at “high-impact” positions produces a common mutant phenotype: disruption of C-type inactivation, reduction of K+ selectivity, and hyperpolarizing shift in the voltage-dependence of activation. In particular, we identify 15 consecutive positions in the middle of the S5-P linker (583–597) where side chain modification has marked impact on channel function. Analysis of the degrees of mutation-induced perturbation in channel function along 583–597 reveals an α-helical periodicity. Furthermore, the effects of MTS modification suggest that the NH2-terminal of this segment (position 584) may be very close to the pore entrance. We propose a structural model for the outer vestibule of the HERG channel, in which the 583–597 segment forms an α-helix. With the NH2 terminus of this helix sitting at the edge of the pore entrance, the length of the helix (∼20 Å) allows its other end to reach and interact with the voltage-sensing domain. Therefore, the “583–597 helix” in the S5-P linker of the HERG channel serves as a bridge of communication between the outer mouth and the voltage sensor, that may make important contribution to the unique C-type inactivation phenotype.

scholarly journals R1 in the Shaker S4 occupies the gating charge transfer center in the resting state

2011 ◽  
Vol 138 (2) ◽  
pp. 155-163 ◽  
Author(s):  
Meng-chin A. Lin ◽  
Jui-Yi Hsieh ◽  
Allan F. Mock ◽  
Diane M. Papazian
Keyword(s):  
Charge Transfer ◽  
Binding Site ◽  
Resting State ◽  
Slow Component ◽  
Maximum Amplitude ◽  
Voltage Sensor ◽  
Shaker Channels ◽  
Gating Charge ◽  
Voltage Dependent ◽  
Arginine Residues

During voltage-dependent activation in Shaker channels, four arginine residues in the S4 segment (R1–R4) cross the transmembrane electric field. It has been proposed that R1–R4 movement is facilitated by a “gating charge transfer center” comprising a phenylalanine (F290) in S2 plus two acidic residues, one each in S2 and S3. According to this proposal, R1 occupies the charge transfer center in the resting state, defined as the conformation in which S4 is maximally retracted toward the cytoplasm. However, other evidence suggests that R1 is located extracellular to the charge transfer center, near I287 in S2, in the resting state. To investigate the resting position of R1, we mutated I287 to histidine (I287H), paired it with histidine mutations of key voltage sensor residues, and determined the effect of extracellular Zn2+ on channel activity. In I287H+R1H, Zn2+ generated a slow component of activation with a maximum amplitude (Aslow,max) of ∼56%, indicating that only a fraction of voltage sensors can bind Zn2+ at a holding potential of −80 mV. Aslow,max decreased after applying either depolarizing or hyperpolarizing prepulses from −80 mV. The decline of Aslow,max after negative prepulses indicates that R1 moves inward to abolish ion binding, going beyond the point where reorientation of the I287H and R1H side chains would reestablish a binding site. These data support the proposal that R1 occupies the charge transfer center upon hyperpolarization. Consistent with this, pairing I287H with A359H in the S3–S4 loop generated a Zn2+-binding site. At saturating concentrations, Aslow,max reached 100%, indicating that Zn2+ traps the I287H+A359H voltage sensor in an absorbing conformation. Transferring I287H+A359H into a mutant background that stabilizes the resting state significantly enhanced Zn2+ binding at −80 mV. Our results strongly support the conclusion that R1 occupies the gating charge transfer center in the resting conformation.

scholarly journals Shaker potassium channel gating. I: Transitions near the open state.

1994 ◽  
Vol 103 (2) ◽  
pp. 249-278 ◽  
Author(s):  
T Hoshi ◽  
W N Zagotta ◽  
R W Aldrich
Keyword(s):  
Time Course ◽  
Single Channel ◽  
Activation Process ◽  
Time Data ◽  
Shaker Potassium Channel ◽  
Voltage Dependent ◽  
Average Current ◽  
Shaker Potassium Channels ◽  
Kinetics Of ◽  
Deactivation Process

Kinetics of single voltage-dependent Shaker potassium channels expressed in Xenopus oocytes were studied in the absence of fast N-type inactivation. Comparison of the single-channel first latency distribution and the time course of the ensemble average current showed that the activation time course and its voltage dependence are largely determined by the transitions before first opening. The open dwell time data are consistent with a single kinetically distinguishable open state. Once the channel opens, it can enter at least two closed states which are not traversed frequently during the activation process. The rate constants for the transitions among these closed states and the open state are nearly voltage-independent at depolarized voltages (> -30 mV). During the deactivation process at more negative voltages, the channel can close directly to a closed state in the activation pathway in a voltage-dependent fashion.

scholarly journals The BK channel gating ring is strongly coupled to the voltage sensor

2018 ◽  
Author(s):  
Pablo Miranda ◽  
Miguel Holmgren ◽  
Teresa Giraldez
Keyword(s):  
Conformational Changes ◽  
Bk Channels ◽  
Bk Channel ◽  
Voltage Sensor ◽  
Voltage Sensitivity ◽  
Divalent Ions ◽  
Gating Currents ◽  
Open Probability ◽  
Voltage Dependent ◽  
Tightly Coupled

ABSTRACTThe open probability of large conductance voltage- and calcium-dependent potassium (BK) channels is regulated allosterically by changes in the transmembrane voltage and intracellular concentration of divalent ions (Ca2+ and Mg2+). The divalent cation sensors reside within the gating ring formed by eight Regulator of Conductance of Potassium (RCK) domains, two from each of the four channel subunits. Overall, the gating ring contains 12 sites that can bind Ca2+ with different affinities. Using patch-clamp fluorometry, we have shown robust changes in FRET signals within the gating ring in response to divalent ions and voltage, which do not directly track open probability. Only the conformational changes triggered through the RCK1 binding site are voltage-dependent in presence of Ca2+. Because the gating ring is outside the electric field, it must gain voltage sensitivity from coupling to the voltage-dependent channel opening, the voltage sensor or both. Here we demonstrate that alterations of voltage sensor dynamics known to shift gating currents produce a cognate shift in the gating ring voltage dependence, whereas changing BK channels’ relative probability of opening had little effect. These results strongly suggest that the conformational changes of the RCK1 domain of the gating ring are tightly coupled to the voltage sensor function, and this interaction is central to the allosteric modulation of BK channels.

scholarly journals Voltage Sensing in Bacterial Protein Translocation

Biomolecules ◽  
2020 ◽  
Vol 10 (1) ◽  
pp. 78 ◽  
Author(s):  
Denis G. Knyazev ◽  
Roland Kuttner ◽  
Ana-Nicoleta Bondar ◽  
Mirjam Zimmerman ◽  
Christine Siligan ◽  
...  
Keyword(s):  
Protein Translocation ◽  
Voltage Sensor ◽  
Voltage Sensitivity ◽  
Bacterial Protein ◽  
Voltage Sensing ◽  
Voltage Dependent ◽  
Membrane Spanning ◽  
Dipolar Orientation ◽  
Polypeptide Chains ◽  
Gating Charges

The bacterial channel SecYEG efficiently translocates both hydrophobic and hydrophilic proteins across the plasma membrane. Translocating polypeptide chains may dislodge the plug, a half helix that blocks the permeation of small molecules, from its position in the middle of the aqueous translocation channel. Instead of the plug, six isoleucines in the middle of the membrane supposedly seal the channel, by forming a gasket around the translocating polypeptide. However, this hypothesis does not explain how the tightness of the gasket may depend on membrane potential. Here, we demonstrate voltage-dependent closings of the purified and reconstituted channel in the presence of ligands, suggesting that voltage sensitivity may be conferred by motor protein SecA, ribosomes, signal peptides, and/or translocating peptides. Yet, the presence of a voltage sensor intrinsic to SecYEG was indicated by voltage driven closure of pores that were forced-open either by crosslinking the plug to SecE or by plug deletion. We tested the involvement of SecY’s half-helix 2b (TM2b) in voltage sensing, since clearly identifiable gating charges are missing. The mutation L80D accelerated voltage driven closings by reversing TM2b’s dipolar orientation. In contrast, the L80K mutation decelerated voltage induced closings by increasing TM2b’s dipole moment. The observations suggest that TM2b is part of a larger voltage sensor. By partly aligning the combined dipole of this sensor with the orientation of the membrane-spanning electric field, voltage may drive channel closure.

scholarly journals Nonsensing residues in S3–S4 linker’s C terminus affect the voltage sensor set point in K+ channels

2018 ◽  
Vol 150 (2) ◽  
pp. 307-321 ◽  
Author(s):  
Joao L. Carvalho-de-Souza ◽  
Francisco Bezanilla
Keyword(s):  
Intermediate State ◽  
Voltage Dependence ◽  
State Model ◽  
Voltage Sensitivity ◽  
Voltage Sensing ◽  
K Channels ◽  
C Terminus ◽  
Voltage Dependent ◽  
Arginine Residues ◽  
Three State Model

Voltage sensitivity in ion channels is a function of highly conserved arginine residues in their voltage-sensing domains (VSDs), but this conservation does not explain the diversity in voltage dependence among different K+ channels. Here we study the non–voltage-sensing residues 353 to 361 in Shaker K+ channels and find that residues 358 and 361 strongly modulate the voltage dependence of the channel. We mutate these two residues into all possible remaining amino acids (AAs) and obtain Q-V and G-V curves. We introduced the nonconducting W434F mutation to record sensing currents in all mutants except L361R, which requires K+ depletion because it is affected by W434F. By fitting Q-Vs with a sequential three-state model for two voltage dependence–related parameters (V0, the voltage-dependent transition from the resting to intermediate state and V1, from the latter to the active state) and G-Vs with a two-state model for the voltage dependence of the pore domain parameter (V1/2), Spearman’s coefficients denoting variable relationships with hydrophobicity, available area, length, width, and volume of the AAs in 358 and 361 positions could be calculated. We find that mutations in residue 358 shift Q-Vs and G-Vs along the voltage axis by affecting V0, V1, and V1/2 according to the hydrophobicity of the AA. Mutations in residue 361 also shift both curves, but V0 is affected by the hydrophobicity of the AA in position 361, whereas V1 and V1/2 are affected by size-related AA indices. Small-to-tiny AAs have opposite effects on V1 and V1/2 in position 358 compared with 361. We hypothesize possible coordination points in the protein that residues 358 and 361 would temporarily and differently interact with in an intermediate state of VSD activation. Our data contribute to the accumulating knowledge of voltage-dependent ion channel activation by adding functional information about the effects of so-called non–voltage-sensing residues on VSD dynamics.

scholarly journals The distinct role of the four voltage sensors of the skeletal CaV1.1 channel in voltage-dependent activation

2021 ◽  
Vol 153 (11) ◽  
Author(s):  
Nicoletta Savalli ◽  
Marina Angelini ◽  
Federica Steccanella ◽  
Julian Wier ◽  
Fenfen Wu ◽  
...  
Keyword(s):  
Critical Role ◽  
Ionic Current ◽  
Voltage Sensor ◽  
The Other ◽  
Voltage Sensitivity ◽  
Voltage Sensing ◽  
Voltage Sensors ◽  
Voltage Dependent ◽  
Rapid Activation

Initiation of skeletal muscle contraction is triggered by rapid activation of RYR1 channels in response to sarcolemmal depolarization. RYR1 is intracellular and has no voltage-sensing structures, but it is coupled with the voltage-sensing apparatus of CaV1.1 channels to inherit voltage sensitivity. Using an opto-electrophysiological approach, we resolved the excitation-driven molecular events controlling both CaV1.1 and RYR1 activations, reported as fluorescence changes. We discovered that each of the four human CaV1.1 voltage-sensing domains (VSDs) exhibits unique biophysical properties: VSD-I time-dependent properties were similar to ionic current activation kinetics, suggesting a critical role of this voltage sensor in CaV1.1 activation; VSD-II, VSD-III, and VSD-IV displayed faster activation, compatible with kinetics of sarcoplasmic reticulum Ca2+ release. The prominent role of VSD-I in governing CaV1.1 activation was also confirmed using a naturally occurring, charge-neutralizing mutation in VSD-I (R174W). This mutation abolished CaV1.1 current at physiological membrane potentials by impairing VSD-I activation without affecting the other VSDs. Using a structurally relevant allosteric model of CaV activation, which accounted for both time- and voltage-dependent properties of CaV1.1, to predict VSD-pore coupling energies, we found that VSD-I contributed the most energy (~75 meV or ∼3 kT) toward the stabilization of the open states of the channel, with smaller (VSD-IV) or negligible (VSDs II and III) energetic contribution from the other voltage sensors (<25 meV or ∼1 kT). This study settles the longstanding question of how CaV1.1, a slowly activating channel, can trigger RYR1 rapid activation, and reveals a new mechanism for voltage-dependent activation in ion channels, whereby pore opening of human CaV1.1 channels is primarily driven by the activation of one voltage sensor, a mechanism distinct from that of all other voltage-gated channels.

scholarly journals Voltage-dependent dynamics of the BK channel cytosolic gating ring are coupled to the membrane-embedded voltage sensor

eLife ◽  
2018 ◽  
Vol 7 ◽  
Author(s):  
Pablo Miranda ◽  
Miguel Holmgren ◽  
Teresa Giraldez
Keyword(s):  
Conformational Changes ◽  
Bk Channels ◽  
Bk Channel ◽  
Voltage Sensor ◽  
Cation Binding ◽  
Voltage Sensitivity ◽  
Open Probability ◽  
Calcium Dependent ◽  
Transmembrane Voltage ◽  
Voltage Dependent

In humans, large conductance voltage- and calcium-dependent potassium (BK) channels are regulated allosterically by transmembrane voltage and intracellular Ca2+. Divalent cation binding sites reside within the gating ring formed by two Regulator of Conductance of Potassium (RCK) domains per subunit. Using patch-clamp fluorometry, we show that Ca2+ binding to the RCK1 domain triggers gating ring rearrangements that depend on transmembrane voltage. Because the gating ring is outside the electric field, this voltage sensitivity must originate from coupling to the voltage-dependent channel opening, the voltage sensor or both. Here we demonstrate that alterations of the voltage sensor, either by mutagenesis or regulation by auxiliary subunits, are paralleled by changes in the voltage dependence of the gating ring movements, whereas modifications of the relative open probability are not. These results strongly suggest that conformational changes of RCK1 domains are specifically coupled to the voltage sensor function during allosteric modulation of BK channels.

scholarly journals Ion permeation and block of the gating pore in the voltage sensor of NaV1.4 channels with hypokalemic periodic paralysis mutations

2010 ◽  
Vol 136 (2) ◽  
pp. 225-236 ◽  
Author(s):  
Stanislav Sokolov ◽  
Todd Scheuer ◽  
William A. Catterall
Keyword(s):  
Divalent Cations ◽  
Periodic Paralysis ◽  
Voltage Sensor ◽  
Dependent Manner ◽  
Hypokalemic Periodic Paralysis ◽  
Independent Manner ◽  
Apparent Dissociation Constant ◽  
Voltage Dependent ◽  
Arginine Residues ◽  
Trivalent Cations

Hypokalemic periodic paralysis and normokalemic periodic paralysis are caused by mutations of the gating charge–carrying arginine residues in skeletal muscle NaV1.4 channels, which induce gating pore current through the mutant voltage sensor domains. Inward sodium currents through the gating pore of mutant R666G are only ∼1% of central pore current, but substitution of guanidine for sodium in the extracellular solution increases their size by 13- ± 2-fold. Ethylguanidine is permeant through the R666G gating pore at physiological membrane potentials but blocks the gating pore at hyperpolarized potentials. Guanidine is also highly permeant through the proton-selective gating pore formed by the mutant R666H. Gating pore current conducted by the R666G mutant is blocked by divalent cations such as Ba2+ and Zn2+ in a voltage-dependent manner. The affinity for voltage-dependent block of gating pore current by Ba2+ and Zn2+ is increased at more negative holding potentials. The apparent dissociation constant (Kd) values for Zn2+ block for test pulses to −160 mV are 650 ± 150 µM, 360 ± 70 µM, and 95.6 ± 11 µM at holding potentials of 0 mV, −80 mV, and −120 mV, respectively. Gating pore current is blocked by trivalent cations, but in a nearly voltage-independent manner, with an apparent Kd for Gd3+ of 238 ± 14 µM at −80 mV. To test whether these periodic paralyses might be treated by blocking gating pore current, we screened several aromatic and aliphatic guanidine derivatives and found that 1-(2,4-xylyl)guanidinium can block gating pore current in the millimolar concentration range without affecting normal NaV1.4 channel function. Together, our results demonstrate unique permeability of guanidine through NaV1.4 gating pores, define voltage-dependent and voltage-independent block by divalent and trivalent cations, respectively, and provide initial support for the concept that guanidine-based gating pore blockers could be therapeutically useful.

Sign in / Sign up

Export Citation Format

Share Document