Your search keyword '"Voltage-sensing Domain"' showing total 23 results

1. An LQT2-related mutation in the voltage-sensing domain is involved in switching the gating polarity of hERG

Author

Liu, Zhipei, Wang, Feng, Yuan, Hui, Tian, Fuyun, Yang, Chuanyan, Hu, Fei, Liu, Yiyao, Tang, Meiqin, Ping, Meixuan, Kang, Chunlan, Luo, Ting, Yang, Guimei, Hu, Mei, Gao, Zhaobing, and Li, Ping

Published

2024

2. Characterization of two near-infrared genetically encoded voltage indicators.

Author

Chenchen Song, Matlashov, Mikhail E., Shcherbakova, Daria M., Antic, Srdjan D., Verkhusha, Vladislav V., and Knöpfel, Thomas

Subjects

ELECTRIC potential, INTRINSIC optical imaging, WAVELENGTHS, BRAIN imaging, CELL imaging

Abstract

Significance: Efforts starting more than 20 years ago led to increasingly well performing genetically encoded voltage indicators (GEVIs) for optical imaging at wavelengths <600 nm. Although optical imaging in the >600 nm wavelength range has many advantages over shorter wavelength approaches for mesoscopic in vivo monitoring of neuronal activity in the mammalian brain, the availability and evaluation of well performing near-infrared GEVIs are still limited. Aim: Here, we characterized two recent near-infrared GEVIs, Archon1 and nirButterfly, to support interested tool users in selecting a suitable near-infrared GEVI for their specific research question requirements. Approach: We characterized side-by-side the brightness, sensitivity, and kinetics of both near-infrared GEVIs in a setting focused on population imaging. Results: We found that nirButterfly shows seven-fold higher brightness than Archon1 under the same conditions and faster kinetics than Archon1 for population imaging without cellular resolution. But Archon1 showed larger signals than nirButterfly. Conclusions: Neither GEVI characterized here surpasses in all three key parameters (brightness, kinetics, and sensitivity), so there is no unequivocal preference for one of the two. Our side-by-side characterization presented here provides new information for future in vitro and ex vivo experimental designs. [ABSTRACT FROM AUTHOR]

Published

2024

3. Molecular Interactions in the Voltage Sensor Controlling Gating Properties of CaV Calcium Channels

Author

Tuluc, Petronel, Yarov-Yarovoy, Vladimir, Benedetti, Bruno, and Flucher, Bernhard E

Subjects

Biological Sciences, Chemical Sciences, Genetics, Neurosciences, Underpinning research, 1.1 Normal biological development and functioning, Alternative Splicing, Arginine, Aspartic Acid, Calcium Channels, L-Type, Models, Molecular, Mutagenesis, Site-Directed, Point Mutation, Protein Conformation, Ca(V), calcium channel, voltage gating, voltage-sensing domain, Information and Computing Sciences, Biophysics, Biological sciences, Chemical sciences

Abstract

Voltage-gated calcium channels (CaV) regulate numerous vital functions in nerve and muscle cells. To fulfill their diverse functions, the multiple members of the CaV channel family are activated over a wide range of voltages. Voltage sensing in potassium and sodium channels involves the sequential transition of positively charged amino acids across a ring of residues comprising the charge transfer center. In CaV channels, the precise molecular mechanism underlying voltage sensing remains elusive. Here we combined Rosetta structural modeling with site-directed mutagenesis to identify the molecular mechanism responsible for the specific gating properties of two CaV1.1 splice variants. Our data reveal previously unnoticed interactions of S4 arginines with an aspartate (D1196) outside the charge transfer center of the fourth voltage-sensing domain that are regulated by alternative splicing of the S3-S4 linker. These interactions facilitate the final transition into the activated state and critically determine the voltage sensitivity and current amplitude of these CaV channels.

Published

2016

4. Lacosamide Inhibition of NaV1.7 Channels Depends on its Interaction With the Voltage Sensor Domain and the Channel Pore.

Author

Labau, Julie I. R., Alsaloum, Matthew, Estacion, Mark, Tanaka, Brian, Dib-Hajj, Fadia B., Lauria, Giuseppe, Smeets, Hubert J. M., Faber, Catharina G., Dib-Hajj, Sulayman, and Waxman, Stephen G.

Subjects

CONOTOXINS, SODIUM channel blockers, VIMPAT, ANTICONVULSANTS, SODIUM channels, LOCAL anesthetics

Abstract

Lacosamide, developed as an anti-epileptic drug, has been used for the treatment of pain. Unlike typical anticonvulsants and local anesthetics which enhance fast-inactivation and bind within the pore of sodium channels, lacosamide enhances slow-inactivation of these channels, suggesting different binding mechanisms and mode of action. It has been reported that lacosamide's effect on NaV1.5 is sensitive to a mutation in the local anesthetic binding site, and that it binds with slow kinetics to the fast-inactivated state of NaV1.7. We recently showed that the NaV1.7-W1538R mutation in the voltage-sensing domain 4 completely abolishes NaV1.7 inhibition by clinically-achievable concentration of lacosamide. Our molecular docking analysis suggests a role for W1538 and pore residues as high affinity binding sites for lacosamide. Aryl sulfonamide sodium channel blockers are also sensitive to substitutions of the W1538 residue but not of pore residues. To elucidate the mechanism by which lacosamide exerts its effects, we used voltage-clamp recordings and show that lacosamide requires an intact local anesthetic binding site to inhibit NaV1.7 channels. Additionally, the W1538R mutation does not abrogate local anesthetic lidocaine-induced blockade. We also show that the naturally occurring arginine in NaV1.3 (NaV1.3-R1560), which corresponds to NaV1.7-W1538R, is not sufficient to explain the resistance of NaV1.3 to clinically-relevant concentrations of lacosamide. However, the NaV1.7-W1538R mutation conferred sensitivity to the NaV1.3-selective aryl-sulfonamide blocker ICA-121431. Together, the W1538 residue and an intact local anesthetic site are required for lacosamide's block of NaV1.7 at a clinically-achievable concentration. Moreover, the contribution of W1538 to lacosamide inhibitory effects appears to be isoform-specific. [ABSTRACT FROM AUTHOR]

Published

2021

5. Lacosamide Inhibition of NaV1.7 Channels Depends on its Interaction With the Voltage Sensor Domain and the Channel Pore

Author

Julie I. R. Labau, Matthew Alsaloum, Mark Estacion, Brian Tanaka, Fadia B. Dib-Hajj, Giuseppe Lauria, Hubert J. M. Smeets, Catharina G. Faber, Sulayman Dib-Hajj, and Stephen G. Waxman

Subjects

voltage-gated sodium channels, local anesthetics, manual and automated electrophysiolgy, voltage-sensing domain, molecular docking, Therapeutics. Pharmacology, RM1-950

Abstract

Lacosamide, developed as an anti-epileptic drug, has been used for the treatment of pain. Unlike typical anticonvulsants and local anesthetics which enhance fast-inactivation and bind within the pore of sodium channels, lacosamide enhances slow-inactivation of these channels, suggesting different binding mechanisms and mode of action. It has been reported that lacosamide’s effect on NaV1.5 is sensitive to a mutation in the local anesthetic binding site, and that it binds with slow kinetics to the fast-inactivated state of NaV1.7. We recently showed that the NaV1.7-W1538R mutation in the voltage-sensing domain 4 completely abolishes NaV1.7 inhibition by clinically-achievable concentration of lacosamide. Our molecular docking analysis suggests a role for W1538 and pore residues as high affinity binding sites for lacosamide. Aryl sulfonamide sodium channel blockers are also sensitive to substitutions of the W1538 residue but not of pore residues. To elucidate the mechanism by which lacosamide exerts its effects, we used voltage-clamp recordings and show that lacosamide requires an intact local anesthetic binding site to inhibit NaV1.7 channels. Additionally, the W1538R mutation does not abrogate local anesthetic lidocaine-induced blockade. We also show that the naturally occurring arginine in NaV1.3 (NaV1.3-R1560), which corresponds to NaV1.7-W1538R, is not sufficient to explain the resistance of NaV1.3 to clinically-relevant concentrations of lacosamide. However, the NaV1.7-W1538R mutation conferred sensitivity to the NaV1.3-selective aryl-sulfonamide blocker ICA-121431. Together, the W1538 residue and an intact local anesthetic site are required for lacosamide’s block of NaV1.7 at a clinically-achievable concentration. Moreover, the contribution of W1538 to lacosamide inhibitory effects appears to be isoform-specific.

Published

2021

6. Structural basis for inhibition of the lysosomal two-pore channel TPC2 by a small molecule antagonist.

Author

Chi, Gamma, Jaślan, Dawid, Kudrina, Veronika, Böck, Julia, Li, Huanyu, Pike, Ashley C.W., Rautenberg, Susanne, Krogsaeter, Einar, Bohstedt, Tina, Wang, Dong, McKinley, Gavin, Fernandez-Cid, Alejandra, Mukhopadhyay, Shubhashish M.M., Burgess-Brown, Nicola A., Keller, Marco, Bracher, Franz, Grimm, Christian, and Dürr, Katharina L.

Subjects

*VIRUS diseases, *CHINESE medicine, *SMALL molecules, *BIOLOGY, *EBOLA virus disease

Abstract

Two pore channels are lysosomal cation channels with crucial roles in tumor angiogenesis and viral release from endosomes. Inhibition of the two-pore channel 2 (TPC2) has emerged as potential therapeutic strategy for the treatment of cancers and viral infections, including Ebola and COVID-19. Here, we demonstrate that antagonist SG-094, a synthetic analog of the Chinese alkaloid medicine tetrandrine with increased potency and reduced toxicity, induces asymmetrical structural changes leading to a single binding pocket at only one intersubunit interface within the asymmetrical dimer. Supported by functional characterization of mutants by Ca2+ imaging and patch clamp experiments, we identify key residues in S1 and S4 involved in compound binding to the voltage sensing domain II. SG-094 arrests IIS4 in a downward shifted state which prevents pore opening via the IIS4/S5 linker, hence resembling gating modifiers of canonical VGICs. These findings may guide the rational development of new therapeutics antagonizing TPC2 activity. [Display omitted] • Synthetic TPC2 antagonist (S) -SG-094 binds to human TPC2's VSD II domain • (S) -SG-094 inhibits Hs TPC2 by stabilizing VSD II in an induced inactive state • Hs TPC2 has two well-coordinated lipid-binding sites in VSD I domain Two pore channels are lysosomal cation channels, and inhibition of the two-pore channel 2 (TPC2) has emerged as a potential therapeutic strategy for the treatment of cancers and viral infections. Here, Chi et al. demonstrate that its antagonist SG-094 induces asymmetrical structural changes to TPC2, stabilizing it in an inactive state. [ABSTRACT FROM AUTHOR]

Published

2024

7. Hysteretic Behavior in Voltage-Gated Channels

Author

Carlos A. Villalba-Galea and Alvin T. Chiem

Subjects

hysteresis, voltage-gated channels, voltage-sensing domain, voltage-sensitive phosphatases, modal gating, mode shift, Therapeutics. Pharmacology, RM1-950

Abstract

An ever-growing body of evidence has shown that voltage-gated ion channels are likely molecular systems that display hysteresis in their activity. This phenomenon manifests in the form of dynamic changes in both their voltage dependence of activity and their deactivation kinetics. The goal of this review is to provide a clear definition of hysteresis in terms of the behavior of voltage-gated channels. This review will discuss the basic behavior of voltage-gated channel activity and how they make these proteins into systems displaying hysteresis. It will also provide a perspective on putative mechanisms underlying hysteresis and explain its potential physiological relevance. It is uncertain whether all channels display hysteresis in their behavior. However, the suggested notion that ion channels are hysteretic systems directly collides with the well-accepted notion that ion channel activity is stochastic. This is because hysteretic systems are regarded to have “memory” of previous events while stochastic processes are regarded as “memoryless.” This review will address this apparent contradiction, providing arguments for the existence of processes that can be simultaneously hysteretic and stochastic.

Published

2020

8. A family of hyperpolarization-activated channels selective for protons.

Author

Wobig, Lea, Wolfenstetter, Thérèse, Fechner, Sylvia, Bönigk, Wolfgang, Körschen, Heinz G., Jikeli, Jan F., Trötschel, Christian, Feederle, Regina, Kaupp, U. Benjamin, Seifert, Reinhard, and Berger, Thomas K.

Subjects

*PROTONS, *CYCLIC nucleotides

Abstract

Proton (H+) channels are special: They select protons against other ions that are up to a millionfold more abundant. Only a few proton channels have been identified so far. Here, we identify a family of voltage-gated "pacemaker" channels, HCNL1, that are exquisitely selective for protons. HCNL1 activates during hyperpolarization and conducts protons into the cytosol. Surprisingly, protons permeate through the channel's voltage-sensing domain, whereas the pore domain is nonfunctional. Key to proton permeation is a methionine residue that interrupts the series of regularly spaced arginine residues in the S4 voltage sensor. HCNL1 forms a tetramer and thus contains four proton pores. Unlike classic HCN channels, HCNL1 is not gated by cyclic nucleotides. The channel is present in zebrafish sperm and carries a proton inward current that acidifies the cytosol. Our results suggest that protons rather than cyclic nucleotides serve as cellular messengers in zebrafish sperm. Through small modifications in two key functional domains, HCNL1 evolutionarily adapted to a low-Na+ freshwater environment to conserve sperm's ability to depolarize. [ABSTRACT FROM AUTHOR]

Published

2020

9. Characterization of two near-infrared genetically encoded voltage indicators.

Author

Song C, Matlashov ME, Shcherbakova DM, Antic SD, Verkhusha VV, and Knöpfel T

Abstract

Significance: Efforts starting more than 20 years ago led to increasingly well performing genetically encoded voltage indicators (GEVIs) for optical imaging at wavelengths < 600    nm . Although optical imaging in the > 600    nm wavelength range has many advantages over shorter wavelength approaches for mesoscopic in vivo monitoring of neuronal activity in the mammalian brain, the availability and evaluation of well performing near-infrared GEVIs are still limited., Aim: Here, we characterized two recent near-infrared GEVIs, Archon1 and nirButterfly, to support interested tool users in selecting a suitable near-infrared GEVI for their specific research question requirements., Approach: We characterized side-by-side the brightness, sensitivity, and kinetics of both near-infrared GEVIs in a setting focused on population imaging., Results: We found that nirButterfly shows seven-fold higher brightness than Archon1 under the same conditions and faster kinetics than Archon1 for population imaging without cellular resolution. But Archon1 showed larger signals than nirButterfly., Conclusions: Neither GEVI characterized here surpasses in all three key parameters (brightness, kinetics, and sensitivity), so there is no unequivocal preference for one of the two. Our side-by-side characterization presented here provides new information for future in vitro and ex vivo experimental designs., (© 2023 The Authors.)

Published

2024

10. Trp207 regulation of voltage-dependent activation of human H v 1 proton channel.

Author

Zhang L, Wu X, Cao X, Rao K, and Hong L

Subjects

Humans, Protein Domains genetics, Mutation, Ion Channel Gating physiology, Ion Channels chemistry, Ion Channels genetics, Ion Channels metabolism, Tryptophan genetics, Tryptophan metabolism

Abstract

In voltage-gated Na + and K + channels, the hydrophobicity of noncharged residues in the S4 helix has been shown to regulate the S4 movement underlying the process of voltage-sensing domain (VSD) activation. In voltage-gated proton channel H v 1, there is a bulky noncharged tryptophan residue located at the S4 transmembrane segment. This tryptophan remains entirely conserved across all H v 1 members but is not seen in other voltage-gated ion channels, indicating that the tryptophan contributes different roles in VSD activation. The conserved tryptophan of human voltage-gated proton channel H v 1 is Trp207 (W207). Here, we showed that W207 modifies human H v 1 voltage-dependent activation, and small residues replacement at position 207 strongly perturbs H v 1 channel opening and closing, and the size of the side chain instead of the hydrophobic group of W207 regulates the transition between closed and open states of the channel. We conclude that the large side chain of tryptophan controls the energy barrier during the H v 1 VSD transition., Competing Interests: Conflict of interest The authors declare that they have no conflicts of interest with the contents of this article., (Published by Elsevier Inc.)

Published

2024

11. Hydrophobic gasket mutation produces gating pore currents in closed human voltage-gated proton channels.

Author

Banh, Richard, Cherny, Vladimir V., Morgan, Deri, Musset, Boris, Thomas, Sarah, Kulleperuma, Kethika, Smith, Susan M. E., Pomès, Régis, and DeCoursey, Thomas E.

Subjects

*VOLTAGE-gated ion channels, *PROTONS, *GASKETS, *MOLECULAR dynamics

Abstract

The hydrophobic gasket (HG), a ring of hydrophobic amino acids in the voltage-sensing domain of most voltage-gated ion channels, forms a constriction between internal and external aqueous vestibules. Cationic Arg or Lys side chains lining the S4 helix move through this "gating pore" when the channel opens. S4 movement may occur during gating of the human voltage-gated proton channel, hHV1, but proton current flows through the same pore in open channels. Here, we replaced putative HG residues with less hydrophobic residues or acidic Asp. Substitution of individuals, pairs, or all 3 HG positions did not impair proton selectivity. Evidently, the HG does not act as a secondary selectivity filter. However, 2 unexpected functions of the HG in HV1 were discovered. Mutating HG residues independently accelerated channel opening and compromised the closed state. Mutants exhibited open-closed gating, but strikingly, at negative voltages where "normal" gating produces a nonconducting closed state, the channel leaked protons. Closed-channel proton current was smaller than open-channel current and was inhibited by 10 μM Zn2+. Extreme hyperpolarization produced a deeper closed state through a weakly voltagedependent transition. We functionally identify the HG as Val109, Phe150, Val177, and Val178, which play a critical and exclusive role in preventing H+ influx through closed channels. Molecular dynamics simulations revealed enhanced mobility of Arg208 in mutants exhibiting H+ leak. Mutation of HG residues produces gating pore currents reminiscent of several channelopathies. [ABSTRACT FROM AUTHOR]

Published

2019

12. TMEM266 is a functional voltage sensor regulated by extracellular Zn2+

Author

Ferenc Papp, Suvendu Lomash, Orsolya Szilagyi, Erika Babikow, Jaime Smith, Tsg-Hui Chang, Maria Isabel Bahamonde, Gilman Ewan Stephen Toombes, and Kenton Jon Swartz

Subjects

S1-S4 domain, voltage-sensing domain, divalent cations, fluorescence, fluorimetry, Medicine, Science, Biology (General), QH301-705.5

Abstract

Voltage-activated ion channels contain S1-S4 domains that sense membrane voltage and control opening of ion-selective pores, a mechanism that is crucial for electrical signaling. Related S1-S4 domains have been identified in voltage-sensitive phosphatases and voltage-activated proton channels, both of which lack associated pore domains. hTMEM266 is a protein of unknown function that is predicted to contain an S1-S4 domain, along with partially structured cytoplasmic termini. Here we show that hTMEM266 forms oligomers, undergoes both rapid (µs) and slow (ms) structural rearrangements in response to changes in voltage, and contains a Zn2+ binding site that can regulate the slow conformational transition. Our results demonstrate that the S1-S4 domain in hTMEM266 is a functional voltage sensor, motivating future studies to identify cellular processes that may be regulated by the protein. The ability of hTMEM266 to respond to voltage on the µs timescale may be advantageous for designing new genetically encoded voltage indicators.

Published

2019

13. Using voltage-sensor toxins and their molecular targets to investigate NaV1.8 gating.

Author

Gilchrist, John and Bosmans, Frank

Subjects

*ELECTROPHYSIOLOGY, *ION channels, *PHARMACOLOGY, *OPTOGENETICS, *NEUROSCIENCES

Abstract

Voltage-gated sodium(NaV) channel gating is a complex phenomenonwhich involves a distinct contribution of four integral voltage-sensing domains (VSDI,VSDII,VSDIII andVSDIV). Utilizing accrued pharmacological and structural insights, we build on an established chimera approach to introduce animal toxin sensitivity in each VSDof an acceptor channel by transferring in portable S3b-S4 motifs from the four VSDs of a toxin-susceptible donor channel (NaV1.2). By doing so, we observe that in NaV1.8, a relatively unexplored channel subtype with distinctly slow gating kinetics, VSDI-III participate in channel opening whereas VSDIV can regulate opening as well as fast inactivation. These results illustrate the effectiveness of a pharmacological approach to investigate the mechanism underlying gating of a mammalian NaV channel complex. [ABSTRACT FROM AUTHOR]

Published

2018

14. NMR investigation of the isolated second voltage-sensing domain of human Nav1.4 channel.

Author

Paramonov, A.S., Lyukmanova, E.N., Myshkin, M.Yu., Shulepko, M.A., Kulbatskii, D.S., Petrosian, N.S., Chugunov, A.O., Dolgikh, D.A., Kirpichnikov, M.P., Arseniev, A.S., and Shenkarev, Z.O.

Subjects

*SODIUM channels, *NUCLEAR magnetic resonance spectroscopy, *CENTRAL nervous system, *MEMBRANE potential, *AMINO acid residues

Abstract

Voltage-gated Na + channels are essential for the functioning of cardiovascular, muscular, and nervous systems. The α-subunit of eukaryotic Na + channel consists of ~ 2000 amino acid residues and encloses 24 transmembrane (TM) helices, which form five membrane domains: four voltage-sensing (VSD) and one pore domain. The structural complexity significantly impedes recombinant production and structural studies of full-sized Na + channels. Modular organization of voltage-gated channels gives an idea for studying of the isolated second VSD of human skeletal muscle Nav1.4 channel (VSD-II). Several variants of VSD-II (~ 150 a.a., four TM helices) with different N - and C -termini were produced by cell-free expression. Screening of membrane mimetics revealed low stability of VSD-II samples in media containing phospholipids (bicelles, nanodiscs) associated with the aggregation of electrically neutral domain molecules. The almost complete resonance assignment of 13 C, 15 N-labeled VSD-II was obtained in LPPG micelles. The secondary structure of VSD-II showed similarity with the structures of bacterial Na + channels. The fragment of S4 TM helix between the first and second conserved Arg residues probably adopts 3 10 -helical conformation. Water accessibility of S3 helix, observed by the Mn 2 + titration, pointed to the formation of water-filled crevices in the micelle embedded VSD-II. 15 N relaxation data revealed characteristic pattern of μs–ms time scale motions in the VSD-II regions sharing expected interhelical contacts. VSD-II demonstrated enhanced mobility at ps–ns time scale as compared to isolated VSDs of K + channels. These results validate structural studies of isolated VSDs of Na + channels and show possible pitfalls in application of this ‘divide and conquer’ approach. [ABSTRACT FROM AUTHOR]

Published

2017

15. MOLECULAR PATHOPHYSIOLOGY AND PHARMACOLOGY OF THE VOLTAGE-SENSING DOMAIN OF NEURONAL ION CHANNELS

Author

Francesco eMiceli, Maria Virginia eSoldovieri, Paolo eAmbrosino, Michela eDe Maria, Laura eManocchio, Alessandro eMedoro, and Maurizio eTaglialatela

Subjects

mutations, Chanelopathies, Gating modifier, Voltage-sensing domain, io channels, Neurosciences. Biological psychiatry. Neuropsychiatry, RC321-571

Abstract

Voltage-gated ion channels (VGIC) are membrane proteins that switch from a closed to open state in response to changes in membrane potential, thus enabling ion fluxes across the cell membranes. The mechanism that regulate the structural rearrangements occurring in VGIC in response to changes in membrane potential still remains one of the most challenging topic of modern biophysics. Na+, Ca2+ and K+ voltage-gated channels are structurally formed by the assembly of four similar domains, each comprising six transmembrane segments. Each domain can be divided in two main regions: the Pore Module (PM) and the Voltage-Sensing Module (VSM). The PM (helices S5 and S6 and intervening linker) is responsible for gate opening and ion selectivity; by contrast, the VSM, comprising the first four transmembrane helices (S1-S4), undergoes the first conformational changes in response to membrane voltage. In particular, the S4 segment of each domain, which contains several positively charged residues interspersed with hydrophobic amino acids, is located within the membrane electric field and plays an essential role in voltage sensing. In neurons, specific gating properties of each channel subtype underlie a variety of biological events, ranging from the generation and propagation of electrical impulses, to the secretion of neurotransmitters, to the regulation of gene expression. Given the important functional role played by the VSM in neuronal VGICs, it is not surprising that various VSM mutations affecting the gating process of these channels are responsible for human diseases, and that compounds acting on the VSM have emerged as important investigational tools with great therapeutic potential. In the present review we will briefly describe the most recent discoveries concerning how the VSM exerts its function, how genetically inherited diseases caused by mutations occurring in the VSM affects gating in VGICs, and how several classes of drugs and toxins selectively target the VSM.

Published

2015

16. How to study a highly toxic protein to bacteria: A case of voltage sensor domain of mouse sperm-specific sodium/proton exchanger.

Author

Arcos-Hernández, César, Suárez-Delgado, Esteban, Islas, León D., Romero, Francisco, López-González, Ignacio, Ai, Hui-wang, and Nishigaki, Takuya

Subjects

*BACTERIAL proteins, *POISONS, *VOLTAGE, *PROTONS, *MICE, *OLIGOSPERMIA

Abstract

Heterologous expression systems have been used as a powerful experimental strategy to study the function of many proteins, particularly ion transporters. For this experiment, it is fundamental to prepare an expression vector encoding a protein of interest. However, we encountered problems in vector preparation of the voltage sensor domain (VSD) of murine sperm-specific Na+/H+ exchanger (sNHE) due to its severe toxicity to bacteria. We overcame the problems by insertion of an amber stop codon or a synthetic intron into the coding sequence of the VSD in the expression vectors. Both methods allowed us to express the protein of interest in HEK293 cells (combined with a stop codon suppression system for amber codon). The VSD of mouse sNHE generates voltage-dependent outward ionic currents, which is a probable cause of toxicity to bacteria. We propose these two strategies as practical solutions to study the function of any protein toxic to bacteria. • The voltage sensor domain (VSD) of the murine sNHE is toxic to bacteria. • Amber stop codon insertion into the VSD eliminated the toxicity of the VSD. • The VSD was expressed in HEK293 cells using a stop codon suppression system. • Intron insertion also allowed the plasmid preparation and the protein expression. • The VSD produced outward ionic currents, which might cause the toxicity. [ABSTRACT FROM AUTHOR]

Published

2023

17. Early-Onset Epileptic Encephalopathy Caused by Gain-of-Function Mutations in the Voltage Sensor of Kv7.2 and Kv7.3 Potassium Channel Subunits.

Author

Miceli, Francesco, Soldovieri, Maria Virginia, Ambrosino, Paolo, De Maria, Michela, Migliore, Michele, Migliore, Rosanna, and Taglialatela, Maurizio

Subjects

*GAIN-of-function mutations, *POTASSIUM channels, *ANTISENSE DNA, *ELECTROPHYSIOLOGY, *BRAIN diseases, EPILEPSY research

Abstract

Mutations in Kv7.2 (KCNQ2) and Kv7.3 (KCNQ3) genes, encoding for voltage-gated K + channel subunits underlying the neuronal M-current, have been associated with a wide spectrum of early-onset epileptic disorders ranging from benign familial neonatal seizures to severe epileptic encephalopathies. The aim of the present work has been to investigate the molecular mechanisms of channel dysfunction caused by voltage-sensing domain mutations in Kv7.2 (R144Q, R201C, and R201H) or Kv7.3 (R230C) recently found in patients with epileptic encephalopathies and/or intellectual disability. Electrophysiological studies in mammalian cells transfected with human Kv7.2 and/or Kv7.3 cDNAs revealed that each of these four mutations stabilized the activated state of the channel, thereby producing gain-of function effects, which are opposite to the loss-of-function effects produced by previously found mutations. Multistate structural modeling revealed that the R201 residue in Kv7.2, corresponding to R230 in Kv7.3, stabilized the resting and nearby voltage-sensing domain states by forming an intricate network of electrostatic interactions with neighboring negatively charged residues, a result also confirmed by disulfide trapping experiments. Using a realistic model of a feed forward inhibitory microcircuit in the hippocampal CA1 region, an increased excitability of pyramidal neurons was found upon incorporation of the experimentally defined parameters for mutant M-current, suggesting that changes in network interactions rather than in intrinsic cell properties may be responsible for the neuronal hyperexcitability by these gain-of-function mutations. Together, the present results suggest that gain-of-function mutations in Kv7.2/3 currents may cause human epilepsy with a severe clinical course, thus revealing a previously unexplored level of complexity in disease pathogenetic mechanisms. [ABSTRACT FROM AUTHOR]

Published

2015

18. A family of hyperpolarization-activated channels selective for protons

Author

Lea Wobig, Reinhard Seifert, Heinz G. Körschen, Sylvia Fechner, Thomas K. Berger, U. Benjamin Kaupp, Jan F. Jikeli, Regina Feederle, Wolfgang Bönigk, Christian Trötschel, and Thérèse Wolfenstetter

Subjects

Male, Proton, Physiology, HCNL1 channel, Ion, Tetramer, HCN channel, Animals, Nucleotide, Amino Acid Sequence, Zebrafish, chemistry.chemical_classification, Multidisciplinary, biology, Biological Transport, Depolarization, Biological Sciences, Hyperpolarization (biology), Spermatozoa, Biophysics and Computational Biology, Cytosol, chemistry, voltage-sensing domain, Multigene Family, Physical Sciences, biology.protein, Biophysics, proton channel, Protons

Abstract

Significance We discovered a subfamily of voltage-gated ion channels, called HCN-like channels, consisting of two members, HCNL1 and HCNL2. In contrast to classic pacemaker HCN channels in the heart and brain, HCNL1 conducts protons rather than potassium or sodium ions. The pore domain, which exists in most voltage-gated channels, is nonconducting. Instead, protons permeate the channel via the voltage-sensing domain involving the S4 motif. Key to proton conduction is a methionine residue that interrupts the regularly spaced series of arginine residues in S4. We show that fish sperm use this unusual ion pathway to create a hyperpolarization-gated proton influx that counterbalances an alkaline-activated K+ channel., Proton (H+) channels are special: They select protons against other ions that are up to a millionfold more abundant. Only a few proton channels have been identified so far. Here, we identify a family of voltage-gated “pacemaker” channels, HCNL1, that are exquisitely selective for protons. HCNL1 activates during hyperpolarization and conducts protons into the cytosol. Surprisingly, protons permeate through the channel’s voltage-sensing domain, whereas the pore domain is nonfunctional. Key to proton permeation is a methionine residue that interrupts the series of regularly spaced arginine residues in the S4 voltage sensor. HCNL1 forms a tetramer and thus contains four proton pores. Unlike classic HCN channels, HCNL1 is not gated by cyclic nucleotides. The channel is present in zebrafish sperm and carries a proton inward current that acidifies the cytosol. Our results suggest that protons rather than cyclic nucleotides serve as cellular messengers in zebrafish sperm. Through small modifications in two key functional domains, HCNL1 evolutionarily adapted to a low-Na+ freshwater environment to conserve sperm’s ability to depolarize.

Published

2020

19. A family of hyperpolarization-activated channels selective for

Author

Wobig, L., Wolfenstetter, T., Fechner, S., Bönigk, W., Körschen, H.G., Jikeli, J.F., Trötschel, C., Feederle, R., Kaupp, U.B., Seifert, R., and Berger, T.K.

Subjects

Hcnl1 Channel, Proton Channel, Voltage-sensing Domain, Hcn Channel

Abstract

Proton (H + ) channels are special: They select protons against other ions that are up to a millionfold more abundant. Only a few pro- ton channels have been identified so far. Here, we identify a fam- ily of voltage -gated ?pacemaker ? channels, HCNL1, that are exquisitely selective for protons. HCNL1 activates during hyperpo- larization and conducts protons into the cytosol. Surprisingly, pro- tons permeate through the channel ?s voltage -sensing domain, whereas the pore domain is nonfunctional. Key to proton perme- ation is a methionine residue that interrupts the series of regularly spaced arginine residues in the S4 voltage sensor. HCNL1 forms a tetramer and thus contains four proton pores. Unlike classic HCN channels, HCNL1 is not gated by cyclic nucleotides. The channel is present in zebrafish sperm and carries a proton inward current that acidifies the cytosol. Our results suggest that protons rather than cyclic nucleotides serve as cellular messengers in zebrafish sperm. Through small modifications in two key functional do- mains, HCNL1 evolutionarily adapted to a low-Na + freshwater en- vironment to conserve sperm ?s ability to depolarize.

Published

2020

20. TMEM266 is a functional voltage sensor regulated by extracellular Zn2+

Author

Erika Babikow, Orsolya Szilagyi, Jaime Smith, Tsg-Hui Chang, Gilman Ewan Stephen Toombes, Maria Isabel Bahamonde, Ferenc Papp, Kenton J. Swartz, and Suvendu Lomash

Subjects

QH301-705.5, Science, Phosphatase, General Biochemistry, Genetics and Molecular Biology, 03 medical and health sciences, 0302 clinical medicine, Binding site, Biology (General), Ion channel, fluorimetry, 030304 developmental biology, Membrane potential, 0303 health sciences, General Immunology and Microbiology, Chemistry, General Neuroscience, Molecular biophysics, General Medicine, Sense (electronics), divalent cations, Structural biology, voltage-sensing domain, Biophysics, Medicine, fluorescence, 030217 neurology & neurosurgery, Function (biology), S1-S4 domain

Abstract

Voltage-activated ion channels contain S1-S4 domains that sense membrane voltage and control opening of ion-selective pores, a mechanism that is crucial for electrical signaling. Related S1-S4 domains have been identified in voltage-sensitive phosphatases and voltage-activated proton channels, both of which lack associated pore domains. hTMEM266 is a protein of unknown function that is predicted to contain an S1-S4 domain, along with partially structured cytoplasmic termini. Here we show that hTMEM266 forms oligomers, undergoes both rapid (µs) and slow (ms) structural rearrangements in response to changes in voltage, and contains a Zn2+ binding site that can regulate the slow conformational transition. Our results demonstrate that the S1-S4 domain in hTMEM266 is a functional voltage sensor, motivating future studies to identify cellular processes that may be regulated by the protein. The ability of hTMEM266 to respond to voltage on the µs timescale may be advantageous for designing new genetically encoded voltage indicators.

Published

2019

21. TMEM266 is a functional voltage sensor regulated by extracellular Zn

Author

Ferenc, Papp, Suvendu, Lomash, Orsolya, Szilagyi, Erika, Babikow, Jaime, Smith, Tsg-Hui, Chang, Maria Isabel, Bahamonde, Gilman Ewan Stephen, Toombes, and Kenton Jon, Swartz

Subjects

Binding Sites, Cations, Divalent, Protein Conformation, Xenopus, Structural Biology and Molecular Biophysics, divalent cations, Ion Channels, Zinc, HEK293 Cells, Allosteric Regulation, voltage-sensing domain, Oocytes, Animals, Humans, fluorescence, Protein Multimerization, fluorimetry, Protein Binding, Research Article, S1-S4 domain, Human

Abstract

Voltage-activated ion channels contain S1-S4 domains that sense membrane voltage and control opening of ion-selective pores, a mechanism that is crucial for electrical signaling. Related S1-S4 domains have been identified in voltage-sensitive phosphatases and voltage-activated proton channels, both of which lack associated pore domains. hTMEM266 is a protein of unknown function that is predicted to contain an S1-S4 domain, along with partially structured cytoplasmic termini. Here we show that hTMEM266 forms oligomers, undergoes both rapid (µs) and slow (ms) structural rearrangements in response to changes in voltage, and contains a Zn2+ binding site that can regulate the slow conformational transition. Our results demonstrate that the S1-S4 domain in hTMEM266 is a functional voltage sensor, motivating future studies to identify cellular processes that may be regulated by the protein. The ability of hTMEM266 to respond to voltage on the µs timescale may be advantageous for designing new genetically encoded voltage indicators.

Published

2018

22. Hysteretic Behavior in Voltage-Gated Channels.

Author

Villalba-Galea, Carlos A. and Chiem, Alvin T.

Subjects

VOLTAGE-gated ion channels, HYSTERESIS, ION channels, STOCHASTIC processes, DISPLAY systems

Abstract

An ever-growing body of evidence has shown that voltage-gated ion channels are likely molecular systems that display hysteresis in their activity. This phenomenon manifests in the form of dynamic changes in both their voltage dependence of activity and their deactivation kinetics. The goal of this review is to provide a clear definition of hysteresis in terms of the behavior of voltage-gated channels. This review will discuss the basic behavior of voltage-gated channel activity and how they make these proteins into systems displaying hysteresis. It will also provide a perspective on putative mechanisms underlying hysteresis and explain its potential physiological relevance. It is uncertain whether all channels display hysteresis in their behavior. However, the suggested notion that ion channels are hysteretic systems directly collides with the well-accepted notion that ion channel activity is stochastic. This is because hysteretic systems are regarded to have "memory" of previous events while stochastic processes are regarded as "memoryless." This review will address this apparent contradiction, providing arguments for the existence of processes that can be simultaneously hysteretic and stochastic. [ABSTRACT FROM AUTHOR]

Published

2020

23. MOLECULAR PATHOPHYSIOLOGY AND PHARMACOLOGY OF THE VOLTAGE-SENSING DOMAIN OF NEURONAL ION CHANNELS

Author

Alessandro Medoro, Francesco Miceli, Michela De Maria, Laura Manocchio, Paolo Ambrosino, Maria Virginia Soldovieri, Maurizio Taglialatela, Miceli, Francesco, Soldovieri, Maria Virginia, Ambrosino, Paolo, de Maria, Michela, Manocchio, Laura, Medoro, Alessandro, and Taglialatela, Maurizio

Subjects

voltage-sensing module, Gating, Review, Biology, Bioinformatics, Channelopathie, lcsh:RC321-571, Cellular and Molecular Neuroscience, Gating modifier, Voltage-sensing domain, lcsh:Neurosciences. Biological psychiatry. Neuropsychiatry, Ion channel, Chanelopathies, Membrane potential, Voltage-gated ion channel, ion channels, channelopathies, mutations, io channels, Transmembrane protein, Transmembrane domain, Membrane, Membrane protein, Mutation, Biophysics, Neuroscience

Abstract

Voltage-gated ion channels (VGICs) are membrane proteins that switch from a closed to open state in response to changes in membrane potential, thus enabling ion fluxes across the cell membranes. The mechanism that regulate the structural rearrangements occurring in VGICs in response to changes in membrane potential still remains one of the most challenging topic of modern biophysics. Na(+), Ca(2+) and K(+) voltage-gated channels are structurally formed by the assembly of four similar domains, each comprising six transmembrane segments. Each domain can be divided into two main regions: the Pore Module (PM) and the Voltage-Sensing Module (VSM). The PM (helices S5 and S6 and intervening linker) is responsible for gate opening and ion selectivity; by contrast, the VSM, comprising the first four transmembrane helices (S1-S4), undergoes the first conformational changes in response to membrane voltage variations. In particular, the S4 segment of each domain, which contains several positively charged residues interspersed with hydrophobic amino acids, is located within the membrane electric field and plays an essential role in voltage sensing. In neurons, specific gating properties of each channel subtype underlie a variety of biological events, ranging from the generation and propagation of electrical impulses, to the secretion of neurotransmitters and to the regulation of gene expression. Given the important functional role played by the VSM in neuronal VGICs, it is not surprising that various VSM mutations affecting the gating process of these channels are responsible for human diseases, and that compounds acting on the VSM have emerged as important investigational tools with great therapeutic potential. In the present review we will briefly describe the most recent discoveries concerning how the VSM exerts its function, how genetically inherited diseases caused by mutations occurring in the VSM affects gating in VGICs, and how several classes of drugs and toxins selectively target the VSM.

Published

2015