Leandro Zúñiga

The voltage‐dependent ClC‐2 chloride channel has a dual gating mechanism

Functional and structural studies demonstrate that Cl− channels of the ClC family have a dimeric double‐barrelled structure, with each monomer contributing an identical pore. Single protopore gating is a fast process dependent on Cl− interaction within the selectivity filter and in ClC‐0 has a low temperature coefficient over a 10°C range (Q10). A slow gating process closes both protopores simultaneously, has a high Q10, is facilitated by extracellular Zn2+ and Cd2+ and is abolished or markedly reduced by mutation of a cysteine conserved in ClC‐0, ‐1 and ‐2. In order to test the hypothesis that similar slow and fast gates exist in the widely expressed ClC‐2 Cl− channel we have investigated the effects of these manoeuvres on ClC‐2. We find that the time constants of both components of the double‐exponential hyperpolarization‐dependent activation (and deactivation) processes have a high temperature dependence, with Q10 values of about 4–5, suggesting important conformational changes of the channel. Mutating C256 (equivalent to C212 in ClC‐0) to A, led to a significant fraction of constitutively open channels at all potentials. Activation time constants were not affected but deactivation was slower and significantly less temperature dependent in the C256A mutant. Extracellular Cd2+, that inhibits wild‐type (WT) channels almost fully, inhibited C256A only by 50%. In the WT, the time constants for opening were not affected by Cd2+ but deactivation at positive potentials was accelerated by Cd2+. This effect was absent in the C256A mutant. The effect of intracellular Cl− on channel activation was unchanged in the C256A mutant. Collectively our results strongly support the hypothesis that ClC‐2 possesses a common gate and that part of the current increase induced by hyperpolarization represents an opening of the common gate. In contrast to the gating in ClC‐0, the protopore gate and the common gate of ClC‐2 do not appear to be independent.

Neutralization of a single arginine residue gates open a two-pore domain, alkali-activated K+ channel.

Potassium channels share a common selectivity filter that determines the conduction characteristics of the pore. Diversity in K+ channels is given by how they are gated open. TASK-2, TALK-1, and TALK-2 are two-pore region (2P) KCNK K+ channels gated open by extracellular alkalinization. We have explored the mechanism for this alkalinization-dependent gating using molecular simulation and site-directed mutagenesis followed by functional assay. We show that the side chain of a single arginine residue (R224) near the pore senses pH in TASK-2 with an unusual pKa of 8.0, a shift likely due to its hydrophobic environment. R224 would block the channel through an electrostatic effect on the pore, a situation relieved by its deprotonation by alkalinization. A lysine residue in TALK-2 fulfills the same role but with a largely unchanged pKa, which correlates with an environment that stabilizes its positive charge. In addition to suggesting unified alkaline pH-gating mechanisms within the TALK subfamily of channels, our results illustrate in a physiological context the principle that hydrophobic environment can drastically modulate the pKa of charged amino acids within a protein.

A conserved pore-lining glutamate as a voltage- and chloride-dependent gate in the ClC-2 chloride channel

ClC‐2 is a ubiquitously expressed, two‐pore homodimeric Cl− channel opened by hyperpolarisation. Little is known about its gating mechanisms. Crystallographic and functional studies in other ClC channels suggest that a conserved glutamate residue carboxylate side‐chain can close protopores by interacting with a Cl−‐binding site in the pore. Competition for this site is thought to provide the molecular basis for gating by extracellular Cl−. We now show that ClC‐2 gating depends upon intra‐ but not extracellular Cl− and that neutralisation of E217, the homologous pore glutamate, leads to loss of sensitivity to intracellular Cl− and voltage. Experiments testing for transient activation by extracellular protons demonstrate that E217 is not available for protonation in the closed channel state but becomes so after opening by hyperpolarisation. The results suggest that E217 is a hyperpolarisation‐dependent protopore gate in ClC‐2 and that access of intracellular Cl− to a site normally occupied by its side‐chain in the pore stabilises the open state. A remaining hyperpolarisation‐dependent gate might correspond to that closing both pores simultaneously in other ClC channels.

Removal of gating in voltage-dependent ClC-2 chloride channel by point mutations affecting the pore and C-terminus CBS-2 domain

Functional and structural studies demonstrate that Cl− channels of the ClC family have a dimeric double‐barrelled structure, with each monomer contributing an identical pore. Studies with ClC‐0, the prototype ClC channel, show the presence of independent mechanisms gating the individual pores or both pores simultaneously. A single‐point mutation in the CBS‐2 domain of ClC‐0 has been shown to abolish slow gating. We have taken advantage of the high conservation of CBS domains in ClC channels to test for the presence of a slow gate in ClC‐2 by reproducing this mutation (H811A). ClC‐2‐H811A showed faster opening kinetics and opened at more positive potentials than ClC‐2. There was no difference in [Cl−]i dependence. Additional neutralization of a putative pore gate glutamate side chain (E207V) abolished all gating. Resolving slow and fast gating relaxations, however, revealed that the H811A mutation affected both fast and slow gating processes in ClC‐2. This suggests that slow and fast gating in ClC‐2 are coupled, perhaps with slow gating contributing to the operation of the pore E207 as a protopore gate.

Gating of a pH-sensitive K2P potassium channel by an electrostatic effect of basic sensor residues on the selectivity filter

K+ channels share common selectivity characteristics but exhibit a wide diversity in how they are gated open. Leak K2P K+ channels TASK-2, TALK-1 and TALK-2 are gated open by extracellular alkalinization. The mechanism for this alkalinization-dependent gating has been proposed to be the neutralization of the side chain of a single arginine (lysine in TALK-2) residue near the pore of TASK-2, which occurs with the unusual pKa of 8.0. We now corroborate this hypothesis by transplanting the TASK-2 extracellular pH (pHo) sensor in the background of a pHo-insensitive TASK-3 channel, which leads to the restitution of pHo-gating. Using a concatenated channel approach, we also demonstrate that for TASK-2 to open, pHo sensors must be neutralized in each of the two subunits forming these dimeric channels with no apparent cross-talk between the sensors. These results are consistent with adaptive biasing force analysis of K+ permeation using a model selectivity filter in wild-type and mutated channels. The underlying free-energy profiles confirm that either a doubly or a singly charged pHo sensor is sufficient to abolish ion flow. Atomic detail of the associated mechanism reveals that, rather than a collapse of the pore, as proposed for other K2P channels gated at the selectivity filter, an increased height of the energetic barriers for ion translocation accounts for channel blockade at acid pHo. Our data, therefore, strongly suggest that a cycle of protonation/deprotonation of pHo-sensing arginine 224 side chain gates the TASK-2 channel by electrostatically tuning the conformational stability of its selectivity filter.

Gating of two-pore domain K+ channels by extracellular pH.

Potassium channels have a conserved selectivity filter that is important in determining which ions are conducted and at what rate. Although K+ channels of different conductance characteristics are known, they differ more widely in the way their opening and closing, the gating, is governed. TASK and TALK subfamily proteins are two-pore region KCNK K+ channels gated open by extracellular pH. We discuss the mechanism for this gating in terms of electrostatic effects on the pore changing the occupancy and open probability of the channels in a way reminiscent of C-type inactivation gating at the selectivity filter. Essential to this proposed mechanism is the replacement of two highly conserved aspartate residues at the pore mouth by asparagine or histidine residues in the TALK and TASK channels.

An extracellular ion pathway plays a central role in the cooperative gating of a K(2P) K+ channel by extracellular pH.

Background: TASK-3 is gated cooperatively by extracellular pH. Results: Mutual electrostatic interaction between K+ ions and two pH-sensing histidines occurs in a recently discovered extracellular ion pathway. Conclusion: Channel opening requires neutralization of both sensing histidines, with neutralization of the second sensor becoming favored by an electrostatic effect K+ ions. Significance: The work suggests a central role for the extracellular ion pathway in the gating of K2P K+ channels. Proton-gated TASK-3 K+ channel belongs to the K2P family of proteins that underlie the K+ leak setting the membrane potential in all cells. TASK-3 is under cooperative gating control by extracellular [H+]. Use of recently solved K2P structures allows us to explore the molecular mechanism of TASK-3 cooperative pH gating. Tunnel-like side portals define an extracellular ion pathway to the selectivity filter. We use a combination of molecular modeling and functional assays to show that pH-sensing histidine residues and K+ ions mutually interact electrostatically in the confines of the extracellular ion pathway. K+ ions modulate the pKa of sensing histidine side chains whose charge states in turn determine the open/closed transition of the channel pore. Cooperativity, and therefore steep dependence of TASK-3 K+ channel activity on extracellular pH, is dependent on an effect of the permeant ion on the channel pHo sensors.

Rapid recycling of ClC-2 chloride channels between plasma membrane and endosomes: Role of a tyrosine endocytosis motif in surface retrieval

ClC‐2 chloride channel is present in the brain and some transporting epithelia where its function is poorly understood. We have now demonstrated that the surface channels are rapidly internalised and approximately the 70% of the surface membrane protein recycles after 4‐ to 8‐min internalisation. Endocytosis of ClC‐2 was dependent upon tyrosine 179 located within an endocytic motif. Rapid recycling accompanied by an even faster internalisation could account for the abundant presence of ClC‐2 in intracellular membranous structures. At least a proportion of ClC‐2 resides in lipid rafts. Use of β‐cyclodextrin led to an increase in cell surface channel, but, surprisingly, a decrease in functionally active channels. We suggest that ClC‐2 requires residing in β‐cyclodextrin sensitive clusters with other molecules in order to remain active. Regulation of ClC‐2 trafficking to and within the membrane could be a means of modulating its activity. J. Cell. Physiol. 221: 650–657, 2009.

Understanding the Cap Structure in K2P Channels

The two-pore domain potassium (K2P) channel family is composed by 15 members, identified in the human genome, and also K2P channels have been identified in yeast, plants, zebrafish, nematode and fruitfly (Goldstein et al., 2001). Based on their primary structure and functional properties, K2P channels are grouped into six distinct subfamilies denoted as TREK, TALK, TASK, TWIK, THIK, and TRESK (Goldstein et al., 2001, 2005; Figure ​Figure1A1A).

Cardiovascular Action of Insulin in Health and Disease: Endothelial L-Arginine Transport and Cardiac Voltage-Dependent Potassium Channels

Impairment of insulin signaling on diabetes mellitus has been related to cardiovascular dysfunction, heart failure, and sudden death. In human endothelium, cationic amino acid transporter 1 (hCAT-1) is related to the synthesis of nitric oxide (NO) and insulin has a vascular effect in endothelial cells through a signaling pathway that involves increases in hCAT-1 expression and L-arginine transport. This mechanism is disrupted in diabetes, a phenomenon potentiated by excessive accumulation of reactive oxygen species (ROS), which contribute to lower availability of NO and endothelial dysfunction. On the other hand, electrical remodeling in cardiomyocytes is considered a key factor in heart failure progression associated to diabetes mellitus. This generates a challenge to understand the specific role of insulin and the pathways involved in cardiac function. Studies on isolated mammalian cardiomyocytes have shown prolongated action potential in ventricular repolarization phase that produces a long QT interval, which is well explained by attenuation in the repolarizing potassium currents in cardiac ventricles. Impaired insulin signaling causes specific changes in these currents, such a decrease amplitude of the transient outward K+ (Ito) and the ultra-rapid delayed rectifier (IKur) currents where, together, a reduction of mRNA and protein expression levels of α-subunits (Ito, fast; Kv 4.2 and IKs; Kv 1.5) or β-subunits (KChIP2 and MiRP) of K+ channels involved in these currents in a MAPK mediated pathway process have been described. These results support the hypothesis that lack of insulin signaling can produce an abnormal repolarization in cardiomyocytes. Furthermore, the arrhythmogenic potential due to reduced Ito current can contribute to an increase in the incidence of sudden death in heart failure. This review aims to show, based on pathophysiological models, the regulatory function that would have insulin in vascular system and in cardiac electrophysiology.