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1.
Nature ; 632(8024): 451-459, 2024 Aug.
Artículo en Inglés | MEDLINE | ID: mdl-39085604

RESUMEN

Hyperpolarization-activated cyclic nucleotide-gated (HCN) channels1 are essential for pacemaking activity and neural signalling2,3. Drugs inhibiting HCN1 are promising candidates for management of neuropathic pain4 and epileptic seizures5. The general anaesthetic propofol (2,6-di-iso-propylphenol) is a known HCN1 allosteric inhibitor6 with unknown structural basis. Here, using single-particle cryo-electron microscopy and electrophysiology, we show that propofol inhibits HCN1 by binding to a mechanistic hotspot in a groove between the S5 and S6 transmembrane helices. We found that propofol restored voltage-dependent closing in two HCN1 epilepsy-associated polymorphisms that act by destabilizing the channel closed state: M305L, located in the propofol-binding site in S5, and D401H in S6 (refs. 7,8). To understand the mechanism of propofol inhibition and restoration of voltage-gating, we tracked voltage-sensor movement in spHCN channels and found that propofol inhibition is independent of voltage-sensor conformational changes. Mutations at the homologous methionine in spHCN and an adjacent conserved phenylalanine in S6 similarly destabilize closing without disrupting voltage-sensor movements, indicating that voltage-dependent closure requires this interface intact. We propose a model for voltage-dependent gating in which propofol stabilizes coupling between the voltage sensor and pore at this conserved methionine-phenylalanine interface in HCN channels. These findings unlock potential exploitation of this site to design specific drugs targeting HCN channelopathies.


Asunto(s)
Epilepsia , Canales Regulados por Nucleótidos Cíclicos Activados por Hiperpolarización , Activación del Canal Iónico , Mutación , Canales de Potasio , Propofol , Humanos , Sitios de Unión , Microscopía por Crioelectrón , Electrofisiología , Epilepsia/tratamiento farmacológico , Epilepsia/genética , Epilepsia/metabolismo , Células HEK293 , Canales Regulados por Nucleótidos Cíclicos Activados por Hiperpolarización/antagonistas & inhibidores , Canales Regulados por Nucleótidos Cíclicos Activados por Hiperpolarización/química , Canales Regulados por Nucleótidos Cíclicos Activados por Hiperpolarización/genética , Canales Regulados por Nucleótidos Cíclicos Activados por Hiperpolarización/metabolismo , Canales Regulados por Nucleótidos Cíclicos Activados por Hiperpolarización/ultraestructura , Activación del Canal Iónico/efectos de los fármacos , Activación del Canal Iónico/genética , Metionina/genética , Metionina/metabolismo , Modelos Moleculares , Movimiento/efectos de los fármacos , Fenilalanina/genética , Fenilalanina/metabolismo , Polimorfismo Genético , Canales de Potasio/química , Canales de Potasio/genética , Canales de Potasio/metabolismo , Canales de Potasio/ultraestructura , Propofol/farmacología , Propofol/química
2.
Proc Natl Acad Sci U S A ; 119(15): e2104453119, 2022 04 12.
Artículo en Inglés | MEDLINE | ID: mdl-35377790

RESUMEN

Myeloid-derived suppressor cells (MDSC) are a heterogeneous cell population with high immunosuppressive activity that proliferates in infections, inflammation, and tumor microenvironments. In tumors, MDSC exert immunosuppression mainly by producing reactive oxygen species (ROS), a process triggered by the NADPH oxidase 2 (NOX2) activity. NOX2 is functionally coupled with the Hv1 proton channel in certain immune cells to support sustained free-radical production. However, a functional expression of the Hv1 channel in MDSC has not yet been reported. Here, we demonstrate that mouse MDSC express functional Hv1 proton channel by immunofluorescence microscopy, flow cytometry, and Western blot, besides performing a biophysical characterization of its macroscopic currents via patch-clamp technique. Our results show that the immunosuppression by MDSC is conditional to their ability to decrease the proton concentration elevated by the NOX2 activity, rendering Hv1 a potential drug target for cancer treatment.


Asunto(s)
Canales Iónicos , Células Supresoras de Origen Mieloide , Protones , Linfocitos T , Animales , Canales Iónicos/genética , Canales Iónicos/metabolismo , Ratones , Células Supresoras de Origen Mieloide/inmunología , NADPH Oxidasa 2/metabolismo , Especies Reactivas de Oxígeno/metabolismo , Linfocitos T/inmunología
3.
Proc Natl Acad Sci U S A ; 118(37)2021 09 14.
Artículo en Inglés | MEDLINE | ID: mdl-34504015

RESUMEN

Rhythmic activity in pacemaker cells, as in the sino-atrial node in the heart, depends on the activation of hyperpolarization-activated cyclic nucleotide-gated (HCN) channels. As in depolarization-activated K+ channels, the fourth transmembrane segment S4 functions as the voltage sensor in hyperpolarization-activated HCN channels. But how the inward movement of S4 in HCN channels at hyperpolarized voltages couples to channel opening is not understood. Using voltage clamp fluorometry, we found here that S4 in HCN channels moves in two steps in response to hyperpolarizations and that the second S4 step correlates with gate opening. We found a mutation in sea urchin HCN channels that separate the two S4 steps in voltage dependence. The E356A mutation in S4 shifts the main S4 movement to positive voltages, but channel opening remains at negative voltages. In addition, E356A reveals a second S4 movement at negative voltages that correlates with gate opening. Cysteine accessibility and molecular models suggest that the second S4 movement opens up an intracellular crevice between S4 and S5 that would allow radial movement of the intracellular ends of S5 and S6 to open HCN channels.


Asunto(s)
Canales Regulados por Nucleótidos Cíclicos Activados por Hiperpolarización/genética , Canales Regulados por Nucleótidos Cíclicos Activados por Hiperpolarización/metabolismo , Animales , Relojes Biológicos/fisiología , Canales Catiónicos Regulados por Nucleótidos Cíclicos/genética , Canales Catiónicos Regulados por Nucleótidos Cíclicos/metabolismo , Canales Regulados por Nucleótidos Cíclicos Activados por Hiperpolarización/fisiología , Activación del Canal Iónico/fisiología , Potenciales de la Membrana/fisiología , Técnicas de Placa-Clamp/métodos , Canales de Potasio/metabolismo , Erizos de Mar/metabolismo
4.
Proc Natl Acad Sci U S A ; 118(19)2021 05 11.
Artículo en Inglés | MEDLINE | ID: mdl-33941706

RESUMEN

The dissipation of acute acid loads by the voltage-gated proton channel (Hv1) relies on regulating the channel's open probability by the voltage and the ΔpH across the membrane (ΔpH = pHex - pHin). Using monomeric Ciona-Hv1, we asked whether ΔpH-dependent gating is produced during the voltage sensor activation or permeation pathway opening. A leftward shift of the conductance-voltage (G-V) curve was produced at higher ΔpH values in the monomeric channel. Next, we measured the voltage sensor pH dependence in the absence of a functional permeation pathway by recording gating currents in the monomeric nonconducting D160N mutant. Increasing the ΔpH leftward shifted the gating charge-voltage (Q-V) curve, demonstrating that the ΔpH-dependent gating in Hv1 arises by modulating its voltage sensor. We fitted our data to a model that explicitly supposes the Hv1 voltage sensor free energy is a function of both the proton chemical and the electrical potential. The parameters obtained showed that around 60% of the free energy stored in the ΔpH is coupled to the Hv1 voltage sensor activation. Our results suggest that the molecular mechanism underlying the Hv1 ΔpH dependence is produced by protons, which alter the free-energy landscape around the voltage sensor domain. We propose that this alteration is produced by accessibility changes of the protons in the Hv1 voltage sensor during activation.


Asunto(s)
Algoritmos , Activación del Canal Iónico/fisiología , Canales Iónicos/fisiología , Modelos Biológicos , Protones , Secuencia de Aminoácidos , Animales , Femenino , Humanos , Concentración de Iones de Hidrógeno , Activación del Canal Iónico/genética , Canales Iónicos/genética , Canales Iónicos/metabolismo , Potenciales de la Membrana/fisiología , Ratones , Simulación de Dinámica Molecular , Mutación , Oocitos/metabolismo , Oocitos/fisiología , Homología de Secuencia de Aminoácido , Xenopus laevis
5.
Int J Mol Sci ; 25(8)2024 Apr 13.
Artículo en Inglés | MEDLINE | ID: mdl-38673895

RESUMEN

Voltage-gated potassium (Kv) channels and hyperpolarization-activated cyclic nucleotide-gated (HCN) channels share similar structures but have opposite gating polarity. Kv channels have a strong coupling (>109) between the voltage sensor (S4) and the activation gate: when S4s are activated, the gate is open to >80% but, when S4s are deactivated, the gate is open <10-9 of the time. Using noise analysis, we show that the coupling between S4 and the gate is <200 in HCN channels. In addition, using voltage clamp fluorometry, locking the gate open in a Kv channel drastically altered the energetics of S4 movement. In contrast, locking the gate open or decreasing the coupling between S4 and the gate in HCN channels had only minor effects on the energetics of S4 movement, consistent with a weak coupling between S4 and the gate. We propose that this loose coupling is a prerequisite for the reversed voltage gating in HCN channels.


Asunto(s)
Canales Regulados por Nucleótidos Cíclicos Activados por Hiperpolarización , Activación del Canal Iónico , Canales Regulados por Nucleótidos Cíclicos Activados por Hiperpolarización/metabolismo , Canales Regulados por Nucleótidos Cíclicos Activados por Hiperpolarización/genética , Animales , Técnicas de Placa-Clamp , Humanos
6.
Int J Mol Sci ; 24(15)2023 Jul 28.
Artículo en Inglés | MEDLINE | ID: mdl-37569465

RESUMEN

Long QT syndrome (LQTS) can lead to ventricular arrhythmia and sudden cardiac death. The most common congenital cause of LQTS is mutations in the channel subunits generating the cardiac potassium current IKs. Zebrafish (Danio rerio) have been proposed as a powerful system to model human cardiac diseases due to the similar electrical properties of the zebrafish heart and the human heart. We used high-resolution all-optical electrophysiology on ex vivo zebrafish hearts to assess the effects of IKs analogues on the cardiac action potential. We found that chromanol 293B (an IKs inhibitor) prolonged the action potential duration (APD) in the presence of E4031 (an IKr inhibitor applied to drug-induced LQT2), and to a lesser extent, in the absence of E4031. Moreover, we showed that PUFA analogues slightly shortened the APD of the zebrafish heart. However, PUFA analogues failed to reverse the APD prolongation in drug-induced LQT2. However, a more potent IKs activator, ML-277, partially reversed the APD prolongation in drug-induced LQT2 zebrafish hearts. Our results suggest that IKs plays a limited role in ventricular repolarizations in the zebrafish heart under resting conditions, although it plays a more important role when the IKr is compromised, as if the IKs in zebrafish serves as a repolarization reserve as in human hearts. This study shows that potent IKs activators can restore the action potential duration in drug-induced LQT2 in the zebrafish heart.


Asunto(s)
Síndrome de QT Prolongado , Canales de Potasio con Entrada de Voltaje , Animales , Humanos , Antiarrítmicos/farmacología , Pez Cebra , Corazón , Arritmias Cardíacas/tratamiento farmacológico , Arritmias Cardíacas/genética , Síndrome de QT Prolongado/tratamiento farmacológico , Síndrome de QT Prolongado/genética , Potenciales de Acción , Canales de Potasio con Entrada de Voltaje/farmacología
7.
Am J Hum Genet ; 102(3): 505-514, 2018 03 01.
Artículo en Inglés | MEDLINE | ID: mdl-29499166

RESUMEN

Although mutations in more than 90 genes are known to cause CMT, the underlying genetic cause of CMT remains unknown in more than 50% of affected individuals. The discovery of additional genes that harbor CMT2-causing mutations increasingly depends on sharing sequence data on a global level. In this way-by combining data from seven countries on four continents-we were able to define mutations in ATP1A1, which encodes the alpha1 subunit of the Na+,K+-ATPase, as a cause of autosomal-dominant CMT2. Seven missense changes were identified that segregated within individual pedigrees: c.143T>G (p.Leu48Arg), c.1775T>C (p.Ile592Thr), c.1789G>A (p.Ala597Thr), c.1801_1802delinsTT (p.Asp601Phe), c.1798C>G (p.Pro600Ala), c.1798C>A (p.Pro600Thr), and c.2432A>C (p.Asp811Ala). Immunostaining peripheral nerve axons localized ATP1A1 to the axolemma of myelinated sensory and motor axons and to Schmidt-Lanterman incisures of myelin sheaths. Two-electrode voltage clamp measurements on Xenopus oocytes demonstrated significant reduction in Na+ current activity in some, but not all, ouabain-insensitive ATP1A1 mutants, suggesting a loss-of-function defect of the Na+,K+ pump. Five mutants fall into a remarkably narrow motif within the helical linker region that couples the nucleotide-binding and phosphorylation domains. These findings identify a CMT pathway and a potential target for therapy development in degenerative diseases of peripheral nerve axons.


Asunto(s)
Enfermedad de Charcot-Marie-Tooth/genética , Genes Dominantes , Mutación/genética , ATPasa Intercambiadora de Sodio-Potasio/genética , Adulto , Anciano , Anciano de 80 o más Años , Secuencia de Aminoácidos , Niño , Familia , Femenino , Humanos , Masculino , Persona de Mediana Edad , Linaje , ATPasa Intercambiadora de Sodio-Potasio/química , Adulto Joven
8.
Proc Natl Acad Sci U S A ; 115(37): 9240-9245, 2018 09 11.
Artículo en Inglés | MEDLINE | ID: mdl-30127012

RESUMEN

The voltage-gated proton (Hv1) channel, a voltage sensor and a conductive pore contained in one structural module, plays important roles in many physiological processes. Voltage sensor movements can be directly detected by measuring gating currents, and a detailed characterization of Hv1 charge displacements during channel activation can help to understand the function of this channel. We succeeded in detecting gating currents in the monomeric form of the Ciona-Hv1 channel. To decrease proton currents and better separate gating currents from ion currents, we used the low-conducting Hv1 mutant N264R. Isolated ON-gating currents decayed at increasing rates with increasing membrane depolarization, and the amount of gating charges displaced saturates at high voltages. These are two hallmarks of currents arising from the movement of charged elements within the boundaries of the cell membrane. The kinetic analysis of gating currents revealed a complex time course of the ON-gating current characterized by two peaks and a marked Cole-Moore effect. Both features argue that the voltage sensor undergoes several voltage-dependent conformational changes during activation. However, most of the charge is displaced in a single central transition. Upon voltage sensor activation, the charge is trapped, and only a fast component that carries a small percentage of the total charge is observed in the OFF. We hypothesize that trapping is due to the presence of the arginine side chain in position 264, which acts as a blocking ion. We conclude that the movement of the voltage sensor must proceed through at least five states to account for our experimental data satisfactorily.


Asunto(s)
Ciona intestinalis/química , Ciona intestinalis/metabolismo , Activación del Canal Iónico/fisiología , Canales Iónicos/metabolismo , Sustitución de Aminoácidos , Animales , Ciona intestinalis/genética , Canales Iónicos/genética , Transporte Iónico/fisiología , Cinética , Mutación Missense , Xenopus laevis
9.
Proc Natl Acad Sci U S A ; 114(35): E7367-E7376, 2017 08 29.
Artículo en Inglés | MEDLINE | ID: mdl-28808020

RESUMEN

KCNE ß-subunits assemble with and modulate the properties of voltage-gated K+ channels. In the heart, KCNE1 associates with the α-subunit KCNQ1 to generate the slowly activating, voltage-dependent potassium current (IKs) in the heart that controls the repolarization phase of cardiac action potentials. By contrast, in epithelial cells from the colon, stomach, and kidney, KCNE3 coassembles with KCNQ1 to form K+ channels that are voltage-independent K+ channels in the physiological voltage range and important for controlling water and salt secretion and absorption. How KCNE1 and KCNE3 subunits modify KCNQ1 channel gating so differently is largely unknown. Here, we use voltage clamp fluorometry to determine how KCNE1 and KCNE3 affect the voltage sensor and the gate of KCNQ1. By separating S4 movement and gate opening by mutations or phosphatidylinositol 4,5-bisphosphate depletion, we show that KCNE1 affects both the S4 movement and the gate, whereas KCNE3 affects the S4 movement and only affects the gate in KCNQ1 if an intact S4-to-gate coupling is present. Further, we show that a triple mutation in the middle of the transmembrane (TM) segment of KCNE3 introduces KCNE1-like effects on the second S4 movement and the gate. In addition, we show that differences in two residues at the external end of the KCNE TM segments underlie differences in the effects of the different KCNEs on the first S4 movement and the voltage sensor-to-gate coupling.


Asunto(s)
Canal de Potasio KCNQ1/genética , Canales de Potasio con Entrada de Voltaje/metabolismo , Potenciales de Acción , Animales , Humanos , Activación del Canal Iónico/fisiología , Canal de Potasio KCNQ1/metabolismo , Canal de Potasio KCNQ1/fisiología , Potenciales de la Membrana/fisiología , Mutagénesis Sitio-Dirigida/métodos , Oocitos/metabolismo , Técnicas de Placa-Clamp/métodos , Canales de Potasio con Entrada de Voltaje/fisiología , Xenopus laevis/embriología , Xenopus laevis/fisiología
10.
Int J Mol Sci ; 21(24)2020 Dec 11.
Artículo en Inglés | MEDLINE | ID: mdl-33322401

RESUMEN

The delayed rectifier potassium IKs channel is an important regulator of the duration of the ventricular action potential. Hundreds of mutations in the genes (KCNQ1 and KCNE1) encoding the IKs channel cause long QT syndrome (LQTS). LQTS is a heart disorder that can lead to severe cardiac arrhythmias and sudden cardiac death. A better understanding of the IKs channel (here called the KCNQ1/KCNE1 channel) properties and activities is of great importance to find the causes of LQTS and thus potentially treat LQTS. The KCNQ1/KCNE1 channel belongs to the superfamily of voltage-gated potassium channels. The KCNQ1/KCNE1 channel consists of both the pore-forming subunit KCNQ1 and the modulatory subunit KCNE1. KCNE1 regulates the function of the KCNQ1 channel in several ways. This review aims to describe the current structural and functional knowledge about the cardiac KCNQ1/KCNE1 channel. In addition, we focus on the modulation of the KCNQ1/KCNE1 channel and its potential as a target therapeutic of LQTS.


Asunto(s)
Canal de Potasio KCNQ1/metabolismo , Canales de Potasio con Entrada de Voltaje/metabolismo , Animales , Arritmias Cardíacas/metabolismo , Humanos , Canal de Potasio KCNQ1/genética , Síndrome de QT Prolongado/metabolismo , Canales de Potasio con Entrada de Voltaje/genética
11.
Proc Natl Acad Sci U S A ; 113(40): E5962-E5971, 2016 10 04.
Artículo en Inglés | MEDLINE | ID: mdl-27647906

RESUMEN

Voltage-gated proton (Hv1) channels are involved in many physiological processes, such as pH homeostasis and the innate immune response. Zn2+ is an important physiological inhibitor of Hv1. Sperm cells are quiescent in the male reproductive system due to Zn2+ inhibition of Hv1 channels, but become active once introduced into the low-Zn2+-concentration environment of the female reproductive tract. How Zn2+ inhibits Hv1 is not completely understood. In this study, we use the voltage clamp fluorometry technique to identify the molecular mechanism of Zn2+ inhibition of Hv1. We find that Zn2+ binds to both the activated closed and resting closed states of the Hv1 channel, thereby inhibiting both voltage sensor motion and gate opening. Mutations of some Hv1 residues affect only Zn2+ inhibition of the voltage sensor motion, whereas mutations of other residues also affect Zn2+ inhibition of gate opening. These effects are similar in monomeric and dimeric Hv1 channels, suggesting that the Zn2+-binding sites are localized within each subunit of the dimeric Hv1. We propose that Zn2+ binding has two major effects on Hv1: (i) at low concentrations, Zn2+ binds to one site and prevents the opening conformational change of the pore of Hv1, thereby inhibiting proton conduction; and (ii) at high concentrations, Zn2+, in addition, binds to a second site and inhibits the outward movement of the voltage sensor of Hv1. Elucidating the molecular mechanism of how Zn2+ inhibits Hv1 will further our understanding of Hv1 function and might provide valuable information for future drug development for Hv1 channels.


Asunto(s)
Activación del Canal Iónico/genética , Canales Iónicos/genética , Zinc/metabolismo , Animales , Sitios de Unión , Femenino , Fluorometría/métodos , Humanos , Concentración de Iones de Hidrógeno , Inmunidad Innata/genética , Canales Iónicos/metabolismo , Mutación , Técnicas de Placa-Clamp/métodos , Protones , Xenopus laevis/metabolismo , Zinc/química
12.
Proc Natl Acad Sci U S A ; 112(52): E7286-92, 2015 Dec 29.
Artículo en Inglés | MEDLINE | ID: mdl-26668384

RESUMEN

KCNE ß-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.


Asunto(s)
Activación del Canal Iónico/fisiología , Canal de Potasio KCNQ1/fisiología , Oocitos/fisiología , Canales de Potasio con Entrada de Voltaje/fisiología , Animales , Arginina/genética , Arginina/metabolismo , Ácido Aspártico/genética , Ácido Aspártico/metabolismo , Sitios de Unión/genética , Femenino , Humanos , Activación del Canal Iónico/genética , Canal de Potasio KCNQ1/genética , Canal de Potasio KCNQ1/metabolismo , Potenciales de la Membrana , Modelos Biológicos , Mutación , Oocitos/metabolismo , Canales de Potasio con Entrada de Voltaje/genética , Canales de Potasio con Entrada de Voltaje/metabolismo , Unión Proteica , Xenopus laevis
13.
Proc Natl Acad Sci U S A ; 112(18): 5714-9, 2015 May 05.
Artículo en Inglés | MEDLINE | ID: mdl-25901329

RESUMEN

Polyunsaturated fatty acids (PUFAs) affect cardiac excitability. Kv7.1 and the ß-subunit KCNE1 form the cardiac IKs channel that is central for cardiac repolarization. In this study, we explore the prospects of PUFAs as IKs channel modulators. We report that PUFAs open Kv7.1 via an electrostatic mechanism. Both the polyunsaturated acyl tail and the negatively charged carboxyl head group are required for PUFAs to open Kv7.1. We further show that KCNE1 coexpression abolishes the PUFA effect on Kv7.1 by promoting PUFA protonation. PUFA analogs with a decreased pKa value, to preserve their negative charge at neutral pH, restore the sensitivity to open IKs channels. PUFA analogs with a positively charged head group inhibit IKs channels. These different PUFA analogs could be developed into drugs to treat cardiac arrhythmias. In support of this possibility, we show that PUFA analogs act antiarrhythmically in embryonic rat cardiomyocytes and in isolated perfused hearts from guinea pig.


Asunto(s)
Antiarrítmicos/metabolismo , Arritmias Cardíacas/tratamiento farmacológico , Ácidos Grasos Insaturados/metabolismo , Canal de Potasio KCNQ1/química , Mutación , Animales , Conductividad Eléctrica , Femenino , Cobayas , Corazón/efectos de los fármacos , Humanos , Canal de Potasio KCNQ1/genética , Microscopía Electrónica de Rastreo , Miocitos Cardíacos/citología , Miocitos Cardíacos/efectos de los fármacos , Oocitos/metabolismo , Perfusión , Estructura Terciaria de Proteína , Ratas , Ratas Sprague-Dawley , Electricidad Estática , Xenopus laevis
14.
Proc Natl Acad Sci U S A ; 111(2): E273-82, 2014 Jan 14.
Artículo en Inglés | MEDLINE | ID: mdl-24379371

RESUMEN

Voltage-gated proton (Hv1) channels play important roles in the respiratory burst, in pH regulation, in spermatozoa, in apoptosis, and in cancer metastasis. Unlike other voltage-gated cation channels, the Hv1 channel lacks a centrally located pore formed by the assembly of subunits. Instead, the proton permeation pathway in the Hv1 channel is within the voltage-sensing domain of each subunit. The gating mechanism of this pathway is still unclear. Mutagenic and fluorescence studies suggest that the fourth transmembrane (TM) segment (S4) functions as a voltage sensor and that there is an outward movement of S4 during channel activation. Using thermodynamic mutant cycle analysis, we find that the conserved positively charged residues in S4 are stabilized by countercharges in the other TM segments both in the closed and open states. We constructed models of both the closed and open states of Hv1 channels that are consistent with the mutant cycle analysis. These structural models suggest that electrostatic interactions between TM segments in the closed state pull hydrophobic residues together to form a hydrophobic plug in the center of the voltage-sensing domain. Outward S4 movement during channel activation induces conformational changes that remove this hydrophobic plug and instead insert protonatable residues in the center of the channel that, together with water molecules, can form a hydrogen bond chain across the channel for proton permeation. This suggests that salt bridge networks and the hydrophobic plug function as the gate in Hv1 channels and that outward movement of S4 leads to the opening of this gate.


Asunto(s)
Activación del Canal Iónico/fisiología , Canales Iónicos/química , Modelos Moleculares , Conformación Proteica , Secuencia de Bases , Interacciones Hidrofóbicas e Hidrofílicas , Canales Iónicos/metabolismo , Simulación de Dinámica Molecular , Datos de Secuencia Molecular , Mutagénesis Sitio-Dirigida , Técnicas de Placa-Clamp , Unión Proteica , Análisis de Secuencia de ADN , Termodinámica
15.
Proc Natl Acad Sci U S A ; 110(32): 13180-5, 2013 Aug 06.
Artículo en Inglés | MEDLINE | ID: mdl-23861489

RESUMEN

Voltage-gated ion channels generate dynamic ionic currents that are vital to the physiological functions of many tissues. These proteins contain separate voltage-sensing domains, which detect changes in transmembrane voltage, and pore domains, which conduct ions. Coupling of voltage sensing and pore opening is critical to the channel function and has been modeled as a protein-protein interaction between the two domains. Here, we show that coupling in Kv7.1 channels requires the lipid phosphatidylinositol 4,5-bisphosphate (PIP2). We found that voltage-sensing domain activation failed to open the pore in the absence of PIP2. This result is due to loss of coupling because PIP2 was also required for pore opening to affect voltage-sensing domain activation. We identified a critical site for PIP2-dependent coupling at the interface between the voltage-sensing domain and the pore domain. This site is actually a conserved lipid-binding site among different K(+) channels, suggesting that lipids play an important role in coupling in many ion channels.


Asunto(s)
Activación del Canal Iónico/fisiología , Canal de Potasio KCNQ1/metabolismo , Modelos Biológicos , Fosfatidilinositol 4,5-Difosfato/metabolismo , Algoritmos , Secuencia de Aminoácidos , Animales , Sitios de Unión/genética , Western Blotting , Femenino , Humanos , Activación del Canal Iónico/genética , Canal de Potasio KCNQ1/química , Canal de Potasio KCNQ1/genética , Potenciales de la Membrana/genética , Potenciales de la Membrana/fisiología , Modelos Moleculares , Datos de Secuencia Molecular , Mutación , Oocitos/metabolismo , Oocitos/fisiología , Técnicas de Placa-Clamp , Fosfatidilinositol 4,5-Difosfato/química , Unión Proteica , Estructura Terciaria de Proteína , Homología de Secuencia de Aminoácido , Xenopus laevis
16.
J Neurosci ; 34(40): 13472-85, 2014 Oct 01.
Artículo en Inglés | MEDLINE | ID: mdl-25274824

RESUMEN

The EAAT2 glutamate transporter, accounts for >90% of hippocampal glutamate uptake. Although EAAT2 is predominantly expressed in astrocytes, ∼10% of EAAT2 molecules are found in axon terminals. Despite the lower level of EAAT2 expression in glutamatergic terminals, when hippocampal slices are incubated with low concentration of d-aspartate (an EAAT2 substrate), axon terminals accumulate d-aspartate as quickly as astroglia. This implies an unexplained mismatch between the distribution of EAAT2 protein and of EAAT2-mediated transport activity. One hypothesis is that (1) heteroexchange of internal substrate with external substrate is considerably faster than net uptake and (2) terminals favor heteroexchange because of high levels of internal glutamate. However, it is currently unknown whether heteroexchange and uptake have similar or different rates. To address this issue, we used a reconstituted system to compare the relative rates of the two processes in rat and mice. Net uptake was sensitive to changes in the membrane potential and was stimulated by external permeable anions in agreement with the existence of an uncoupled anion conductance. By using the latter, we also demonstrate that the rate of heteroexchange also depends on the membrane potential. Additionally, our data further suggest the presence of a sodium leak in EAAT2. By incorporating the new findings in our previous model of glutamate uptake by EAAT2, we predict that the voltage sensitivity of exchange is caused by the voltage-dependent third Na(+) binding. Further, both our experiments and simulations suggest that the relative rates of net uptake and heteroexchange are comparable in EAAT2.


Asunto(s)
Transportador 2 de Aminoácidos Excitadores/metabolismo , Ácido Glutámico/metabolismo , Liposomas/metabolismo , Aminoácidos/metabolismo , Animales , Encéfalo/efectos de los fármacos , Encéfalo/ultraestructura , Bovinos , Simulación por Computador , Transportador 2 de Aminoácidos Excitadores/genética , Técnicas In Vitro , Ionóforos/farmacología , Potenciales de la Membrana/efectos de los fármacos , Potenciales de la Membrana/genética , Ratones , Ratones Endogámicos C57BL , Ratones Transgénicos , Modelos Biológicos , Potasio/metabolismo , Ratas , Ratas Wistar , Factores de Tiempo , Valinomicina/farmacología
17.
J Physiol ; 593(12): 2605-15, 2015 Jun 15.
Artículo en Inglés | MEDLINE | ID: mdl-25653179

RESUMEN

The KCNQ1 channel (also called Kv7.1 or KvLQT1) belongs to the superfamily of voltage-gated K(+) (Kv) channels. KCNQ1 shares several general features with other Kv channels but also displays a fascinating flexibility in terms of the mechanism of channel gating, which allows KCNQ1 to play different physiological roles in different tissues. This flexibility allows KCNQ1 channels to function as voltage-independent channels in epithelial tissues, whereas KCNQ1 function as voltage-activated channels with very slow kinetics in cardiac tissues. This flexibility is in part provided by the association of KCNQ1 with different accessory KCNE ß-subunits and different modulators, but also seems like an integral part of KCNQ1 itself. The aim of this review is to describe the main mechanisms underlying KCNQ1 flexibility.


Asunto(s)
Canal de Potasio KCNQ1/fisiología , Humanos , Activación del Canal Iónico , Canal de Potasio KCNQ1/química
18.
Proc Natl Acad Sci U S A ; 109(18): 7103-8, 2012 May 01.
Artículo en Inglés | MEDLINE | ID: mdl-22509038

RESUMEN

KCNQ1 (Kv7.1) is a unique member of the superfamily of voltage-gated K(+) channels in that it displays a remarkable range of gating behaviors tuned by coassembly with different ß subunits of the KCNE family of proteins. To better understand the basis for the biophysical diversity of KCNQ1 channels, we here investigate the basis of KCNQ1 gating in the absence of ß subunits using voltage-clamp fluorometry (VCF). In our previous study, we found the kinetics and voltage dependence of voltage-sensor movements are very similar to those of the channel gate, as if multiple voltage-sensor movements are not required to precede gate opening. Here, we have tested two different hypotheses to explain KCNQ1 gating: (i) KCNQ1 voltage sensors undergo a single concerted movement that leads to channel opening, or (ii) individual voltage-sensor movements lead to channel opening before all voltage sensors have moved. Here, we find that KCNQ1 voltage sensors move relatively independently, but that the channel can conduct before all voltage sensors have activated. We explore a KCNQ1 point mutation that causes some channels to transition to the open state even in the absence of voltage-sensor movement. To interpret these results, we adopt an allosteric gating scheme wherein KCNQ1 is able to transition to the open state after zero to four voltage-sensor movements. This model allows for widely varying gating behavior, depending on the relative strength of the opening transition, and suggests how KCNQ1 could be controlled by coassembly with different KCNE family members.


Asunto(s)
Activación del Canal Iónico , Canal de Potasio KCNQ1/metabolismo , Sitio Alostérico , Sustitución de Aminoácidos , Animales , Femenino , Humanos , Técnicas In Vitro , Canal de Potasio KCNQ1/química , Canal de Potasio KCNQ1/genética , Modelos Biológicos , Mutagénesis Sitio-Dirigida , Oocitos/metabolismo , Técnicas de Placa-Clamp , Canales de Potasio con Entrada de Voltaje/química , Canales de Potasio con Entrada de Voltaje/genética , Canales de Potasio con Entrada de Voltaje/metabolismo , Multimerización de Proteína , Proteínas Recombinantes/química , Proteínas Recombinantes/genética , Proteínas Recombinantes/metabolismo , Xenopus laevis
19.
Elife ; 132024 Oct 31.
Artículo en Inglés | MEDLINE | ID: mdl-39480699

RESUMEN

In cardiomyocytes, the KCNQ1/KCNE1 channel complex mediates the slow delayed-rectifier current (IKs), pivotal during the repolarization phase of the ventricular action potential. Mutations in IKs cause long QT syndrome (LQTS), a syndrome with a prolonged QT interval on the ECG, which increases the risk of ventricular arrhythmia and sudden cardiac death. One potential therapeutical intervention for LQTS is based on targeting IKs channels to restore channel function and/or the physiological QT interval. Polyunsaturated fatty acids (PUFAs) are potent activators of KCNQ1 channels and activate IKs channels by binding to two different sites, one in the voltage sensor domain - which shifts the voltage dependence to more negative voltages - and the other in the pore domain - which increases the maximal conductance of the channels (Gmax). However, the mechanism by which PUFAs increase the Gmax of the IKs channels is still poorly understood. In addition, it is unclear why IKs channels have a very small single-channel conductance and a low open probability or whether PUFAs affect any of these properties of IKs channels. Our results suggest that the selectivity filter in KCNQ1 is normally unstable, contributing to the low open probability, and that the PUFA-induced increase in Gmax is caused by a stabilization of the selectivity filter in an open-conductive state.


Travelling through the heart are waves of electrical activity that cause muscle cells to contract and pump blood around the body. The waves are generated by charged ions which flow via tiny channels in and out of the muscle cells. This electrical activity spreads quickly from one cell to the next to make sure all the muscle cells contract at the right time. When these ion channels are compromised, this can lead to heart problems such as long QT syndrome (LQTS). In patients with LQTS, electrical activity in the heart does not follow the typical rhythm, which can result in an irregular heartbeat and lead to cardiac arrest. The most common cause of LQTS is mutations in the channel KCNQ1, which allows potassium ions to flow out of heart muscle cells. This outflux of potassium restores the electrical charge inside the cell so that it is ready to receive another electrical wave and contract at the right time. Current treatments for LQTS do not target KCNQ1 channels directly and have side effects. An alternative approach could be to use a group of molecules called polyunsaturated fatty acids (or PUFAs for short) which increase the flow of ions that pass through KCNQ1. However, it is not fully understood how PUFAs achieve this. Previous research showed that PUFAs activate KCNQ1 via two independent sites: one at the voltage sensor which decides whether the channel is open or closed (Site I), and another at the pore domain ions pass through (Site II). While it is well understood how PUFAs activate the channel at Site I, little is known about the activation mechanism that occurs at Site II. To investigate, Golluscio et al. modified egg cells from the frog Xenopus laevis to express KCNQ1 channels. Experiments investigating the electrical properties of KCNQ1 revealed that the selective filter in the pore domain ­ which permits potassium but no other ions to pass through ­ is usually unstable. However, PUFAs help to stabilize this filter, causing KCNQ1 to stay open more often and allow potassium ions to flow out of muscle cells. The findings of Golluscio et al. suggest that PUFAs could represent an important therapeutic tool to treat LQTS and potentially other cardiac disorders. However, further studies in heart cells, animals and eventually humans will be required to confirm this conclusion.


Asunto(s)
Ácidos Grasos Insaturados , Canal de Potasio KCNQ1 , Canal de Potasio KCNQ1/metabolismo , Canal de Potasio KCNQ1/genética , Ácidos Grasos Insaturados/farmacología , Ácidos Grasos Insaturados/metabolismo , Humanos , Animales , Canales de Potasio con Entrada de Voltaje/metabolismo , Canales de Potasio con Entrada de Voltaje/genética , Potenciales de Acción/efectos de los fármacos , Síndrome de QT Prolongado/metabolismo , Síndrome de QT Prolongado/genética , Activación del Canal Iónico/efectos de los fármacos
20.
J Physiol ; 591(3): 627-40, 2013 Feb 01.
Artículo en Inglés | MEDLINE | ID: mdl-23165764

RESUMEN

The voltage-gated H(+) channel functions as a dimer, a configuration that is different from standard tetrameric voltage-gated channels. Each channel protomer has its own permeation pathway. The C-terminal coiled-coil domain has been shown to be necessary for both dimerization and cooperative gating in the two channel protomers. Here we report the gating cooperativity in trimeric and tetrameric Hv channels engineered by altering the hydrophobic core sequence of the coiled-coil assembly domain. Trimeric and tetrameric channels exhibited more rapid and less sigmoidal kinetics of activation of H(+) permeation than dimeric channels, suggesting that some channel protomers in trimers and tetramers failed to produce gating cooperativity observed in wild-type dimers. Multimerization of trimer and tetramer channels were confirmed by the biochemical analysis of proteins, including crystallography. These findings indicate that the voltage-gated H(+) channel is optimally designed as a dimeric channel on a solid foundation of the sequence pattern of the coiled-coil core, with efficient cooperative gating that ensures sustained and steep voltage-dependent H(+) conductance in blood cells.


Asunto(s)
Activación del Canal Iónico , Canales Iónicos/fisiología , Células HEK293 , Humanos , Canales Iónicos/química , Canales Iónicos/genética , Mutación , Multimerización de Proteína , Estructura Terciaria de Proteína , Subunidades de Proteína
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