Anion Permeability Research Articles

Mineralized Nanofiber Substrates Enabling High-Performance Dually Charged Nanofiltration Membranes with Enhanced Permeability.

Nanofiltration membranes (NFMs) with superior permeability and high rejection of both divalent anions and cations are highly desirable to meet the increasing separation demands of complex systems. Herein, we propose a three-in-one strategy to develop a state-of-the-art dually charged thin-film composite (TFC) nanofiltration membrane consisting of a positively charged electrospun nanofiber substrate (NFS) with surface mineralization and a negatively charged polyamide (PA) selective layer prepared by interfacial polymerization (IP). The highly hydrophilic mineralized nanofiber substrate not only effectively reduces the thickness of the PA selective layer but also crumples its structures by the abundant zirconia nanoparticles on the substrate surface, resulting in excellent water flux (15.0 L m-2 h-1 bar-1) for the TFC NFMs. The relationship between the thickness of the selective layer and substrate is further investigated using dissipative particle dynamics (DPD) simulations. Meanwhile, the dually charged NFM exhibits relatively high rejection for both anions (97.1% for Na2SO4 and 97.9% for MgSO4) and cations (87.9% for MgCl2) in aqueous solutions compared with single-charged membranes, which is attributed to the dual-repulsion effect of the selective layer and the substrate surface bearing opposite charges. Moreover, the prepared NFMs exhibit good stability and excellent antifouling performance. This work may pave the way for the development of highly efficient nanofiltration membranes for the practical separation of comprehensively charged solutes.

An Ala/Glu difference in E1 of Cx26 and Cx30 contributes to their differential anionic permeabilities.

Two closely related connexins, Cx26 and Cx30, share widespread expression in the cochlear cellular networks. Gap junction channels formed by these connexins have been shown to have different permeability profiles, with Cx30 showing a strongly reduced preference for anionic tracers. The pore-forming segment of the first extracellular loop, E1, identified by computational studies of the Cx26 crystal structure to form a parahelix and a narrowed region of the pore, differs at a single residue at position 49. Cx26 contains an Ala and Cx30, a charged Glu at this position, and cysteine scanning in hemichannels identified this position to be pore-lining. To assess whether the Ala/Glu difference affects permeability, we modeled and quantified Lucifer Yellow transfer between HeLa cell pairs expressing WT Cx26 and Cx30 and variants that reciprocally substituted Glu and Ala at position 49. Cx26(A49E) and Cx30(E49A) substitutions essentially reversed the Lucifer Yellow permeability profile when accounting for junctional conductance. Moreover, by using a calcein efflux assay in single cells, we observed a similar reduced anionic preference in undocked Cx30 hemichannels and a reversal with reciprocal Ala/Glu substitutions. Thus, our data indicate that Cx26 and Cx30 gap junction channels and undocked hemichannels retain similar permeability characteristics and that a single residue difference in their E1 domains can largely account for their differential permeabilities to anionic tracers. The higher anionic permeability of Cx26 compared with Cx30 suggests that these connexins may serve distinct signaling functions in the cochlea, perhaps reflected in the vastly higher prevalence of Cx26 mutations in human deafness.

Anion Selectivities in Zwitterion Grafted Nanopores: Effect of Zwitterion Architecture.

The separation of ions of similar charge is a crucial challenge in many applications, from water treatment to precious metal recovery. Membranes with cross-linked zwitterionic amphiphilic copolymer (ZAC-X) selective layers, which feature self-assembled, zwitterion-lined nanodomains for permeation, offer unique permselectivity between monovalent anions (e.g., Cl-/F-). This has motivated studies on the mechanisms of transport and selectivity in this family of materials. In this study, we conducted molecular dynamics simulations of aqueous salt solutions within zwitterion-functionalized nanopores to elucidate the influence of dipole orientation of the ZI ligands on anion diffusivities, partitioning, and permeabilities. Our model compares systems with contrasting ZI organization: surface-cation-anion (S-ZI+-ZI-, Motif A) and surface-anion-cation (S-ZI--ZI+, Motif B). Our results reveal that Motif A exhibits less pronounced ion pairing due to a spatial separation in the radial profiles of cations and anions. Motif B demonstrates prominent ion pairing for smaller anions owing to their overlap with cation distributions. Further, our potential of mean force profiles reveals that anion partitioning increases with anion size in both ligand motifs, whereas Motif B exhibits significantly higher partitioning selectivity toward larger anions compared to Motif A. Our results for ion diffusivities show that the self-diffusivities of both anions and cations are lower for Motif B compared to Motif A. Such trends in anion partitioning and diffusivities can be explained by differences in the interactions and steric hindrance experienced by the anionic species in Motifs A and B. Finally, our results for anion permselectivity, obtained by combining partitioning and diffusivity, indicate that partitioning trends dominate over diffusivity trends. Consequently, anion permeability increases with anion size, and ligand Motif B yields much higher permselectivity toward larger anions compared to ligand Motif A.

Quantitative insights into the mechanism of proton conduction and selectivity for the human voltage-gated proton channel Hv1

Human voltage-gated proton (hHv1) channels are crucial for regulating essential biological processes such as immune cell respiratory burst, sperm capacitation, and cancer cell migration. Despite the significant concentration difference between protons and other ions in physiological conditions, hHv1 demonstrates remarkable proton selectivity. Our calculations of single-proton, cation, and anion permeation free energy profiles quantitatively demonstrate that the proton selectivity of the wild-type channel originates from its strong proton affinity via the titration of the key residues D112 and D174, although the channel imposes similar kinetic blocking effects for protons compared to other ions. A two-proton knock-on model is proposed to mathematically explain the electrophysiological measurements of the pH-dependent proton conductance in the conductive state. Moreover, it is shown that the anion selectivity of the D112N mutant channel is tied to impaired proton transport and substantial anion leakage.

Corrosion resistance and passive film stability of laser direct energy deposited TiVZrNbAl lightweight multi-principal element alloy

This work reports the corrosion behaviour of a novel laser direct energy deposited Ti45V30Zr12Nb12Al1 lightweight multi-principal element alloy (MPEA) in a 0.6 M NaCl solution. The MPEA exhibits superior corrosion resistance to typical titanium alloys, including Ti80. Its excellent corrosion resistance is attributed to a passive film with bipolar semiconducting behaviour and an amorphous structure. This unique feature inhibits anion permeation from the electrolyte and cation dissolution from the passive film. Further analyses revealed that Nb alloying effectively reduces the point defect density in the passive film, enhancing its ability to resist attacks by chloride ions.

Electronic Polarizability Tunes the Function of the Human Bestrophin 1 Cl- Channel.

Mechanisms of anion permeation within ion channels and nanopores remain poorly understood. Recent cryo-electron microscopy structures of the human bestrophin 1 Cl- channel (hBest1) provide an opportunity to evaluate ion interactions predicted by molecular dynamics (MD) simulations against experimental observations. Here, we implement the fully polarizable forcefield AMOEBA in MD simulations on different conformations of hBest1. This forcefield models multipole moments up to the quadrupole; therefore, it captures induced dipole and anion-π interactions. We show that key biophysical properties of the channel can only be simulated when electronic polarization is included in the molecular models and that Cl- permeation through the neck of the pore is achieved through hydrophobic solvation concomitant with partial ion dehydration. Furthermore, we demonstrate how such polarizable simulations can help determine the identity of ion-like densities within high-resolution cryo-EM structures and that neglecting polarization places Cl- at positions that do not correspond with their experimentally resolved location. Overall, our results demonstrate the importance of including electronic polarization in realistic and physically accurate models of biological systems, especially channels and pores that selectively permeate anions.

Insights into CLC-0's Slow-Gating from Intracellular Proton Inhibition.

The opening of the Torpedo CLC-0 chloride (Cl-) channel is known to be regulated by two gating mechanisms: fast gating and slow (common) gating. The structural basis underlying the fast-gating mechanism is better understood than that of the slow-gating mechanism, which is still largely a mystery. Our previous study on the intracellular proton (H+i)-induced inhibition of the CLC-0 anionic current led to the conclusion that the inhibition results from the slow-gate closure (also called inactivation). The conclusion was made based on substantial evidence such as a large temperature dependence of the H+i inhibition similar to that of the channel inactivation, a resistance to the H+i inhibition in the inactivation-suppressed C212S mutant, and a similar voltage dependence between the current recovery from the H+i inhibition and the recovery from the channel inactivation. In this work, we further examine the mechanism of the H+i inhibition of wild-type CLC-0 and several mutants. We observe that an anion efflux through the pore of CLC-0 accelerates the recovery from the H+i-induced inhibition, a process corresponding to the slow-gate opening. Furthermore, various inactivation-suppressed mutants exhibit different current recovery kinetics, suggesting the existence of multiple inactivated states (namely, slow-gate closed states). We speculate that protonation of the pore of CLC-0 increases the binding affinity of permeant anions in the pore, thereby generating a pore blockage of ion flow as the first step of inactivation. Subsequent complex protein conformational changes further transition the CLC-0 channel to deeper inactivated states.

Molecular mechanism of anion permeation through aquaporin 6

Aquaporins (AQPs) are recognized as transmembrane water channels that facilitate selective water permeation through their monomeric pores. Among the AQP family, AQP6 has an intriguing characteristic as an anion channel, which is allosterically controlled by pH conditions and is eliminated by a single amino acid mutation. However, the molecular mechanism of anion permeation through AQP6 remains unclear. Using molecular dynamics simulations in the presence of a transmembrane voltage utilizing an ion concentration gradient, we show that chloride ions permeate through the pore corresponding to the central axis of the AQP6 homotetramer. Under low pH conditions, a subtle opening of the hydrophobic selectivity filter (SF), located near the extracellular part of the central pore, becomes wetted and enables anion permeation. Our simulations also indicate that a single mutation (N63G) in human AQP6, located at the central pore, significantly reduces anion conduction, consistent with experimental data. Moreover, we demonstrate that the pH-sensing mechanism in which the protonation of H184 and H189 under low pH conditions allosterically triggers the gating of the SF region. These results suggest a unique pH-dependent allosteric anion permeation mechanism in AQP6 and could clarify the role of the central pore in some of the AQP tetramers.

A Halogen‐Bond‐Driven Artificial Chloride‐Selective Channel Constructed from 5‐Iodoisophthalamide‐based Molecules

AbstractDespite considerable emphasis on advancing artificial ion channels, progress is constrained by the limited availability of small molecules with the necessary attributes of self‐assembly and ion selectivity. In this study, a library of small molecules based on 5‐haloisophthalamide and a non‐halogenated isophthalamide were examined for their ion transport properties across the lipid bilayer membranes, and the finding demonstrates that the di‐hexyl‐substituted 5‐iodoisophthalamide derivative exhibits the highest level of activity. Furthermore, it was established that the highest active compound facilitates the selective chloride transport that occurs via an antiport‐mediated mechanism. The crystal structure of the compound unveils a distinctive self‐assembly of molecules, forming a zig‐zag channel pore that is well‐suited for the permeation of anions. Planar bilayer conductance measurements proved the formation of chloride selective channels. A molecular dynamics simulation study, relying on the self‐assembled component derived from the crystal structure, affirmed the paramount significance of intermolecular hydrogen bonding in the formation of supramolecular barrel‐rosette structures that span the bilayer. Furthermore, it was demonstrated that the transport of chloride across the lipid bilayer membrane is facilitated by the synergistic effects of halogen bonding and hydrogen bonding within the channel.

A Halogen-Bond-Driven Artificial Chloride-Selective Channel Constructed from 5-Iodoisophthalamide-based Molecules.

Despite considerable emphasis on advancing artificial ion channels, progress is constrained by the limited availability of small molecules with the necessary attributes of self-assembly and ion selectivity. In this study, a library of small molecules based on 5-haloisophthalamide and a non-halogenated isophthalamide were examined for their ion transport properties across the lipid bilayer membranes, and the finding demonstrates that the di-hexyl-substituted 5-iodoisophthalamide derivative exhibits the highest level of activity. Furthermore, it was established that the highest active compound facilitates the selective chloride transport that occurs via an antiport-mediated mechanism. The crystal structure of the compound unveils a distinctive self-assembly of molecules, forming a zig-zag channel pore that is well-suited for the permeation of anions. Planar bilayer conductance measurements proved the formation of chloride selective channels. A molecular dynamics simulation study, relying on the self-assembled component derived from the crystal structure, affirmed the paramount significance of intermolecular hydrogen bonding in the formation of supramolecular barrel-rosette structures that span the bilayer. Furthermore, it was demonstrated that the transport of chloride across the lipid bilayer membrane is facilitated by the synergistic effects of halogen bonding and hydrogen bonding within the channel.

Dual-Channel-Ion Conductor Membrane for Low-Energy Lithium Extraction.

The development of energy-efficient and environmentally friendly lithium extraction techniques is essential to meet the growing global demand for lithium-ion batteries. In this work, a dual-channel ion conductor membrane was designed for a concentration-driven lithium-selective ion diffusion process. The membrane was based on a porous lithium-ion conductor, and its pores were modified with an anion-exchange polymer. Thus, the sintered lithium-ion conductors provided highly selective cation transport channels, and the functionalized nanopores with positive charges enabled the complementary permeation of anions to balance the transmembrane charges. As a result, the dual-channel membrane realized an ultrahigh Li+/Na+ selectivity of ∼1389 with a competitive Li+ flux of 21.6 mmol·m-2·h-1 in a diffusion process of the LiCl/NaCl binary solution, which was capable of further maintaining the high selectivity over 7 days of testing. Therefore, this work demonstrates the great potential of the dual-channel membrane design for high-performing lithium extraction from aqueous resources with low energy consumption and minimal environmental impact.

Oxyanion Removal from Impaired Water by Donnan Dialysis Plug Flow Contactors.

In the last twenty-five years, extensive work has been done on ion exchange membrane bioreactors (IEMB) combining Donnan dialysis and anaerobic reduction to remove trace oxyanions (e.g., perchlorate, nitrate, chlorate, arsenate) from contaminated water sources. Most studies used Donnan dialysis contactors with high recirculation rates on the feed side, so under continuous operation, the effective concentration on the feed side of the membrane is the same as the exit concentration (CSTR mode). We have built, characterized, and modelled a plug flow Donnan dialysis contactor (PFR) that maximizes concentration on the feed side and operated it on feed solutions spiked with perchlorate and nitrate ion using ACS and PCA-100 anion exchange membranes. At identical feed inlet concentrations with the ACS membrane, membrane area loading rates are three-fold greater, and fluxes are more than double in the PFR contactor than in the CSTR contactor. A model based on the nonlinear adsorption of perchlorate in ACS membrane correctly predicted the trace ion concentration as a function of space-time in experiments with ACS. For PCA membrane, a linear flux dependence on feed concentration correctly described trace ion feed concentration as a function of space-time. Anion permeability for PCA-100 was high enough that the overall mass transfer was affected by the film boundary layer resistance. These results provide a basis for efficiently scaling up Donnan dialysis contactors and incorporating them in full-scale IEMB setups.

Zinc Anodes with Electrodeposited Ionomer Protection Layer for Rechargeable Zinc-Air Batteries

Metal air batteries are assembled from a metal anode and a porous cathode in a suitable electrolyte. They combine the design of fuel cells and conventional batteries and have been demonstrated to have large theoretical energy densities higher compared to devices based on Li-ion chemistry, due to the ability to use air at the cathode and to exchange two electrons per zinc atom. ZAB represent a safe, environmentally benign, affordable and simple way to store and deliver electrical energy for a wide variety of devices. However, research efforts are necessary to increase the efficiency of rechargeable ZAB and mitigate obnoxious occurrences that decrease the number of charge-discharge cycles such as zinc dendrite formation, cathode degradation and alkaline electrolyte carbonation.The protection of zinc metal anodes in zinc-air batteries (ZAB) is an efficient way to reduce corrosion and Zn dendrite formation and improve cyclability and overall battery efficiency. The extent of improvement depends on the type and thickness of the protective layer.In this work, we explore an advanced coating of the zinc anode by anion-conducting poly(N-vinylbenzyl, N,N,N trimethylammonium) chloride (PVBTMA) that is electropolymerized directly on the zinc metal. The Zn deposition in presence of quaternary ammonium salts and polyelectrolytes was recently studied to improve the cyclability. The major advances foreseen by this approach are excellent qualities of the metal/ionomer interface, due to the in-situ deposition process, improving the corrosion protection and the selective anion permeability; furthermore, the chosen ionomer presents a high stiffness and strength to resist the formation of zinc dendrites, due to the stiff polystyrene backbone. Moreover, the presence of a polyelectrolyte separator facilitates device miniaturization. The zinc anode protection layer was observed by optical microscopy and scanning electron microscopy (Figure : SEM micrographs of Zn pellet with PVBTMA layer: a) from 0.01 M precursor solution, b) and c) from 0.1 M precursor solution) .and the wettability of the ionomer-coated zinc surface was investigated by contact angle measurements.The resulting ZAB battery with PVBTMA anode coating is analyzed in terms of cyclability in alkaline electrolyte and solid-state configuration using a Whatman paper separator.The goal is to pair metal-free electrode materials with appreciable catalytic activity for oxygen reduction and evolution with a zinc anode that has a protection layer against dendrite formation to maximize efficiency. Figure 1

Structural and functional analysis of human pannexin 2 channel

The pannexin 2 channel (PANX2) participates in multiple physiological processes including skin homeostasis, neuronal development, and ischemia-induced brain injury. However, the molecular basis of PANX2 channel function remains largely unknown. Here, we present a cryo-electron microscopy structure of human PANX2, which reveals pore properties contrasting with those of the intensely studied paralog PANX1. The extracellular selectivity filter, defined by a ring of basic residues, more closely resembles that of the distantly related volume-regulated anion channel (VRAC) LRRC8A, rather than PANX1. Furthermore, we show that PANX2 displays a similar anion permeability sequence as VRAC, and that PANX2 channel activity is inhibited by a commonly used VRAC inhibitor, DCPIB. Thus, the shared channel properties between PANX2 and VRAC may complicate dissection of their cellular functions through pharmacological manipulation. Collectively, our structural and functional analysis provides a framework for development of PANX2-specific reagents that are needed for better understanding of channel physiology and pathophysiology.

Ion permeation pathway within the internal pore of P2X receptor channels.

P2X receptor channels are trimeric ATP-activated ion channels expressed in neuronal and non-neuronal cells that are attractive therapeutic targets for human disorders. Seven subtypes of P2X receptor channels have been identified in mammals that can form both homomeric and heteromeric channels. P2X1-4 and P2X7 receptor channels are cation-selective, whereas P2X5 has been reported to have both cation and anion permeability. P2X receptor channel structures reveal that each subunit is comprised of two transmembrane helices, with both N-and C-termini on the intracellular side of the membrane and a large extracellular domain that contains the ATP binding sites at subunit interfaces. Recent structures of ATP-bound P2X receptors with the activation gate open reveal the unanticipated presence of a cytoplasmic cap over the central ion permeation pathway, leaving lateral fenestrations that may be largely buried within the membrane as potential pathways for ions to permeate the intracellular end of the pore. In the present study, we identify a critical residue within the intracellular lateral fenestrations that is readily accessible to thiol-reactive compounds from both sides of the membrane and where substitutions influence the relative permeability of the channel to cations and anions. Taken together, our results demonstrate that ions can enter or exit the internal pore through lateral fenestrations that play a critical role in determining the ion selectivity of P2X receptor channels.

Pharmacology of P2X3 and P2X2/3 receptors: An automated patch clamp study.

P2X receptors are ligand-gated ion channels activated by extracellular ATP. They are permeable to small monovalent cations, some having significant divalent or anion permeability. The P2X2 and P2X3 subunits are predominantly expressed in primary sensory neurons and have been proposed to play a role in thermal sensation, taste and pain. They form functional hetero- or homotrimers which are activated by αβ-methylene ATP (αβmeATP). The stoichiometry of P2X2/3 heteromers appears to be dependent on the relative abundance of the two subunits. A mixture of P2X2 and P2X3 homomers as well as P2X2/3 heteromers are likely to coexist but can be distinguished through their biophysical and pharmacological properties. The receptors open in response to an increase in extracellular ATP occurring under pathological conditions. The resulting depolarization leads to propagation of the pain signal. Due to its role in nociception and pain signaling, these receptors are important targets for pain management. Here we present data collected on automated patch clamp (APC) systems with ranging throughput from 1 up to 384 cells simultaneously. We show activation and inhibition of P2X2/3 and P2X3 receptors expressed in CHO cells with rapid and brief application of ligand. ATP was applied using the perfusion system of the Port-a-Patch or the pipette(s) of the Patchliner or SyncroPatch 384. The EC50 values for αβmeATP or ATP activation of P2X2/3 receptors were similar across the three devices. The kinetics of currents mediated by homomeric P2X3 receptors were distinctly faster than those of heteromeric receptors. P2X3-mediated currents activated by αβmeATP could be repetitively activated at least 6 times in the same cell with similar peak amplitudes. The P2X3-selective compound A-317491 blocked P2X3-mediated currents activated by αβmeATP with an IC50 of approximately 90 nM and was similar on all three devices.

Elevator transport mechanism in SLC4 transporters: Insights from new inward facing cryo-EM structures of AE1.

The SLC4 transporters are responsible for the transport of various ions, such as HCO3−, CO32−, Cl−, Na+, and NH3+H+, necessary for maintenance of pH, blood pressure and ion homeostasis in the body. Among them, the AE1 transporter protein (Anion Exchanger 1, Band 3, SLC4A1), a Na+-independent Cl−/HCO3− exchanger, has been extensively studied both from theoretical and experimental perspective, due to its peculiarly high rate of transport. An outward facing (OF) open structure of the human AE1 has been previously resolved and substrate binding sites in it have been identified both from computational, functional mutagenesis, and cryoEM studies. However, detailed understanding of the transport mechanism of AE1 and other members of the SLC4 family is hindered by lack of structures of other catalytically relevant states. In the present work we report cryoEM structures of dimers of bovine AE1 (bAE1), which feature inward facing (IF) open monomers. Moreover, mixed dimers where one monomer is in IF and the other - in OF state, were also resolved, indicating independent movement of monomers in the dimers. The new IF and OF states of bAE1 provide unambiguous structural evidence for elevator transport mechanism with a small vertical shift of the core domain with respect to the rigid gate domain. An unexpected elongation of transmembrane helix (TM) 11 and the accompanying reorganization of intracellular loop (IL) 5 from beta-hairpin into alpha-helical geometry is also observed in the IF state. Computational modelling demonstrates different anion dynamics at both sides of the lipid membrane. The small structural reorganization during the OF to IF transition, and the fast anion permeation into the IF and OF cavities of AE1 emerge as possible explanations of the observed high transport rate of this protein.

Ion permeation pathway within the internal pore of P2X receptor channels.

P2X receptor channels are trimeric ATP-activated ion channels expressed in neuronal and non-neuronal cells that are attractive therapeutic targets for human disorders. Each P2X receptor channel subunit consists of two transmembrane helices, a large extracellular domain that contains the ATP binding sites at subunit interfaces, and intracellular N-and C-termini. P2X1-4 and P2X7 receptor channels are cation permeable, whereas P2X5 has been reported to have a significant anion permeability. Recent structures of ATP-bound P2X receptors with the activation gate open reveal the unanticipated presence of a cytoplasmic cap over the central ion permeation pathway, leaving lateral fenestrations that may be largely buried within the membrane as potential pathways for ions to permeate at the intracellular end of the pore. We identified a critical residue within the intracellular lateral fenestrations that is readily accessible to thiol reactive compounds from both sides of the membrane and where substitutions influence the relative permeability of the channel to cations and anions. Taken together, our results demonstrate that ions can enter or exit the internal pore through lateral fenestrations and that these structural elements play a critical role in determining the ion selectivity of P2X receptor channels.

Ion dehydration using magnetic fields and impacts on permeability across RO membranes

Magnetic fields have been used as a mitigation process for controlling mineral scaling in diverse applications, including membrane systems. Changes in scale formation have been attributed, in part, to changes in ion hydration. The objective of this study was to evaluate how passage through a multi-directional magnetic field affected the permeability of relevant cations and anions through a seawater reverse osmosis membrane (SW30HR). Changes in ion permeability were evaluated as a function of flow velocity through the magnetic system and described in terms of changes in the ion hydration and in turn changes in the energy penalty that a given ion must incur to permeate across the RO membrane. Ion permeability across the SW30HR membrane increased after having passed through the magnetic system. Increases in ion permeability became most pronounced once a flow velocity through the magnetic system was ≥35 cm/s and were a function of the ion charge density for ions of the same valence. Increases in ion permeability were attributed to dehydration of the ions by the magnetic system resulting in a reduction in the energy penalty required for the relevant ions to transport across the membrane barrier.

Fabrication of a Cation Exchange Membrane with Largely Reduced Anion Permeability for Advanced Aqueous K-ion Battery in an Alkaline-Neutral Electrolyte Decoupling System.

Herein, an efficient method to prepare sulfonated polyether ether ketone (SPEEK) based cation exchange membranes (CEMs) is developed, where polyethersulfone (PES) is used as an additive. The optimized membrane of 30wt.%PES/SPEEK-M exhibits a rather low anion permeability and a high ionic conductivity of 9.52mScm-1 together with low volume swelling in water. Meanwhile, tensile strength of the membrane is as high as 31.4MPa with a tensile strain of 162%. As separators for aqueous K-ion batteries (AKIBs) with decoupled gel electrolytes (Zn anode in alkaline and Prussian blue (FeHCF) cathode in neutral). Discharge voltage of the AKIB can reach 2.3V. Meanwhile, Zn dendrites can be effectively suppressed in the gel anolyte. Specific capacities of the FeHCF cathode are 116.7mAhg-1 at 0.3Ag-1 (close to its theoretical value), and 95.0mAhg-1 at 1.0Ag-1 , indicating good rate performance. Capacity retention of the cathode is as high as 91.2% after 1000 cycles' cycling owing to the well remained neutral environment of the catholyte. There is almost no pH change for the catholyte after cycling, indicating good anion-blocking or cation-selecting ability of the 30wt.%PES/SPEEK-M, much better than other membranes.