Your search keyword '"ion permeation"' showing total 10 results

1. Selective Ion Permeation through Stabilized Metal–Phenolic Grafted Graphene Oxide Membranes.

Author

Soyekwo, Faizal, Liu, Changkun, Huang, Wei, and Wen, Hao

Subjects

GRAPHENE oxide, FAST ions, WASTE recycling, OSMOTIC pressure, MEMBRANE separation, ORGANIC dyes

Abstract

The structural stability and high permeability of 2D materials‐based membranes are key research interests for separation membranes. However, the instability of their microstructures due to the aqueous‐induced swelling phenomenon affects their performance. It is highly desirable to explore anti‐swelling approaches able to mitigate this challenge as well as develop 2D lamellar membranes with ion selective capabilities beyond the limits based on size exclusion mechanism. Herein, graphene oxide (GO) laminate membranes covalently anchored and intercalated with metal‐phenolic networks display suppressed swelling durability and resist delamination in aqueous media. The resultant Fe@TA‐GO membrane with confined d‐spacing boasts high water fluxes of up to 15.0 L m−2 h−1 under osmotic pressure (2 m sucrose). Furthermore, the permeation tests reveal that the interaction between the metal ions and the immobilized cation–ligand molecules influences the ion permeances through the functionalized GO membranes conducing to fast ion permeation rates with ion diffusion permselectivity as well as effective selective separation of organic contaminants. These results will help advance the applications of GO membranes for challenging ion separations related to sustainable resource recovery and environmental remediation of organic dye and metal ion contaminated wastewaters. [ABSTRACT FROM AUTHOR]

Published

2021

2. The influence of structure and morphology on ion permeation in commercial silicone hydrogel contact lenses.

Author

Saez‐Martinez, Virginia, Mann, Aisling, Lydon, Fiona, Molock, Frank, Layton, Siân A., Toolan, Daniel T. W., Howse, Jonathan R., Topham, Paul D., and Tighe, Brian J.

Subjects

CONTACT lenses, IONIC structure, HYDROGELS, SMALL-angle X-ray scattering, ELECTRON microscope techniques

Abstract

The importance of the microstzructure of silicone hydrogels is widely appreciated but is poorly understood and minimally investigated. To ensure comfort and eye health, these materials must simultaneously exhibit both high oxygen and high water permeability. In contrast with most conventional hydrogels, the water content and water structuring within silicone hydrogels cannot be solely used to predict permeability. The materials achieve these opposing requirements based on a composite of nanoscale domains of oxygen‐permeable (silicone) and water‐permeable hydrophilic components. This study correlated characteristic ion permeation coefficients of a selection of commercially available silicone hydrogel contact lenses with their morphological structure and chemical composition. Differential scanning calorimetry measured the water structuring properties through subdivision of the freezing water component into polymer‐associated water (loosely bound to the polymer matrix) and ice‐like water (unimpeded with a melting point close to that of pure water). Small‐angle x‐ray scattering, and environmental scanning electron microscopy techniques were used to investigate the structural morphology of the materials over a range of length scales. Significant, and previously unrecognized, differences in morphology between individual materials at nanometer length scales were determined; this will aid the design and performance of the next generation of ocular biomaterials, capable of maintaining ocular homeostasis. [ABSTRACT FROM AUTHOR]

Published

2021

3. The mechanosensitive Piezo1 channel: a three‐bladed propeller‐like structure and a lever‐like mechanogating mechanism.

Author

Zhao, Qiancheng, Zhou, Heng, Li, Xueming, and Xiao, Bailong

Subjects

*BLOOD pressure, *GENETIC disorders, *PROPRIOCEPTION, *ELECTROPHYSIOLOGY

Abstract

The evolutionarily conserved Piezo proteins, including Piezo1 and Piezo2, constitute a bona fide class of mechanosensitive (MS) cation channels, which play critical roles in various mammalian physiologies, including sensation of touch, proprioception and regulation of vascular development, and blood pressure. Furthermore, mutations in Piezos have been linked to various human genetic diseases, validating their potential as therapeutic targets. Thus, it is pivotal to understand how Piezo channels effectively convert mechanical force into selective cation permeation, and therefore precisely control the various mechanotransduction processes. On the basis of our recently determined cryoelectron microscopy structures of the full‐length 2547‐residue mouse Piezo1, structure‐guided mutagenesis, and electrophysiological and pharmacological characterizations, here we focus on reviewing the key structural features and functional components that enable Piezo1 to employ a lever‐like mechanogating mechanism to function as a sophisticated mechanotransduction channel. [ABSTRACT FROM AUTHOR]

Published

2019

4. The mechanosensitive Piezo1 channel: structural features and molecular bases underlying its ion permeation and mechanotransduction.

Author

Wang, Yubo and Xiao, Bailong

Subjects

*MECHANICAL properties of biological membranes, *PROTEIN analysis, *PHYSIOLOGICAL effects of proteins, *BIOMECHANICS, *MAMMAL physiology

Abstract

Abstract: The evolutionarily conserved Piezo family of proteins, including Piezo1 and Piezo2, encodes the long‐sought‐after mammalian mechanosensitive cation channels that play critical roles in various mechanotransduction processes such as touch, pain, proprioception, vascular development and blood pressure regulation. Mammalian Piezo proteins contain over 2500 amino acids with numerous predicted transmembrane segments, and do not bear sequence homology with any known class of ion channels. Thus, it is imperative, but challenging, to understand how they serve as effective mechanotransducers for converting mechanical force into electrochemical signals. Here, we review the recent major breakthroughs in determining the three‐bladed, propeller‐shaped structure of mouse Piezo1 using the state‐of‐the‐art cryo‐electron microscopy (cryo‐EM) and functionally dissecting out the molecular bases that define its ion permeation and mechanotransduction properties, which provide key insights into clarifying its oligomeric status and pore‐forming region. We also discuss the hypothesis that the complex Piezo proteins can be deduced into discrete mechanotransduction and ion‐conducting pore modules, which coordinate to fulfil their specialized function in mechanical sensing and transduction, ion permeation and selection. [ABSTRACT FROM AUTHOR]

Published

2018

5. Water and ion permeability of a claudin model: A computational study.

Author

Laghaei, Rozita, Yu, Alan S. L., and Coalson, Rob D.

Abstract

ABSTRACT At present, the three-dimensional structure of the multimeric paracellular claudin pore is unknown. Using extant biophysical data concerning the size of the pore and permeation of water and cations through it, two three-dimensional models of the pore are constructed in silico. Molecular Dynamics (MD) calculations are then performed to compute water and sodium ion permeation fluxes under the influence of applied hydrostatic pressure. Comparison to experiment is made, under the assumption that the hydrostatic pressure applied in the simulations is equivalent to osmotic pressure induced in experimental measurements of water/ion permeability. One model, in which pore-lining charged is distributed evenly over a selectivity filter section 10-16 Å in length, is found to be generally consistent with experimental data concerning the dependence of water and ion permeation on channel pore diameter, pore length, and the sign and magnitude of pore lining charge. The molecular coupling mechanism between water and ion flow under conditions where hydrostatic pressure is applied is computationally elucidated. Proteins 2016; 84:305-315. © 2016 Wiley Periodicals, Inc. [ABSTRACT FROM AUTHOR]

Published

2016

6. Atomic determinants of state-dependent block of sodium channels by charged local anesthetics and benzocaine

Author

Tikhonov, Denis B., Bruhova, Iva, and Zhorov, Boris S.

Subjects

*SODIUM channels, *LOCAL anesthetics, *ION channels, *ANESTHETICS

Abstract

Abstract: Molecular modeling predicts that a local anesthetic (LA) lidocaine binds to the resting and open Nav1.5 in different modes, interacting with LA-sensing residues known from experiments. Besides the major pathway via the open activation gate, LAs can reach the inner pore via a “sidewalk” between D3S6, D4S6, and D3P. The ammonium group of a cationic LA binds in the focus of the pore-helices macrodipoles, which also stabilize a Na+ ion chelated by two benzocaine molecules. The LA’s cationic group and a Na+ ion in the selectivity filter repel each other suggesting that the Na+ depletion upon slow inactivation would stabilize a LA, while a LA would stabilize slow-inactivated states. [Copyright &y& Elsevier]

Published

2006

7. Sodium channel activators: Model of binding inside the pore and a possible mechanism of action

Author

Tikhonov, Denis B. and Zhorov, Boris S.

Subjects

*SODIUM channels, *SODIUM, *ALLOSTERIC regulation, *PROPERTIES of matter

Abstract

Abstract: Sodium channel activators, batrachotoxin and veratridine, cause sodium channels to activate easier and stay open longer than normal channels. Traditionally, this was explained by an allosteric mechanism. However, increasing evidence suggests that activators can bind inside the pore. Here, we model the open sodium channel with activators and propose a novel mechanism of their action. The activator-bound channel retains a hydrophilic pathway for ions between the ligand and conserved asparagine in segment S6 of repeat II. One end of the activator approaches the selectivity filter, decreasing the channel conductance and selectivity. The opposite end reaches the gate stabilizing it in the open state. [Copyright &y& Elsevier]

Published

2005

8. Mutations in the pore regions of the yeast K+ channel YKC1 affect gating by extracellular K+.

Author

Vergani, Paola, Hamilton, David, Jarvis, Simon, and Blatt, Michael R.

Subjects

*GENETIC mutation, *POTASSIUM channels, *XENOPUS, *SACCHAROMYCES cerevisiae

Abstract

The product of the Saccharomyces cerevisiae K+-channel gene YKC1 includes two pore-loop sequences that are thought to form the hydrophilic lining of the pore. Gating of the channel is promoted by membrane depolarization and is regulated by extracellular K+ concentration ([K+]o) both in the yeast and when expressed in Xenopus oocytes. Analysis of the wildtype current now shows that: (i) [K+]o suppresses a very slowly relaxing component, accelerating activation; (ii) [K+]o slows deactivation in a dose-dependent fashion; and (iii) Rb+, Cs+ and, to a lesser extent, Na+ substitute for K+ in its action on gating. We have identified single residues, L293 and A428, at equivalent positions within the two pore loops that affect the [K+]o sensitivity. Substitution of these residues gave channels with reduced sensitivity to [K+]o in macroscopic current kinetics and voltage dependence, but had only minor effects on selectivity among alkali cations in gating and on single-channel conductance. In some mutants, activation was slowed sufficiently to confer a sigmoidicity to current rise at low [K+]o. The results indicate that these residues are involved in [K+]o sensing. Their situation close to the permeation pathway points to an interaction between gating and permeation. [ABSTRACT FROM AUTHOR]

Published

1998

9. Mutations in the pore regions of the yeast K+ channel YKC1 affect gating by extracellular K+.

Author

Vergani, Paola, Hamilton, David, Jarvis, Simon, and Blatt, Michael R.

Subjects

GENETIC mutation, POTASSIUM channels, XENOPUS, SACCHAROMYCES cerevisiae

Abstract

The product of the Saccharomyces cerevisiae K+-channel gene YKC1 includes two pore-loop sequences that are thought to form the hydrophilic lining of the pore. Gating of the channel is promoted by membrane depolarization and is regulated by extracellular K+ concentration ([K+]o) both in the yeast and when expressed in Xenopus oocytes. Analysis of the wildtype current now shows that: (i) [K+]o suppresses a very slowly relaxing component, accelerating activation; (ii) [K+]o slows deactivation in a dose-dependent fashion; and (iii) Rb+, Cs+ and, to a lesser extent, Na+ substitute for K+ in its action on gating. We have identified single residues, L293 and A428, at equivalent positions within the two pore loops that affect the [K+]o sensitivity. Substitution of these residues gave channels with reduced sensitivity to [K+]o in macroscopic current kinetics and voltage dependence, but had only minor effects on selectivity among alkali cations in gating and on single-channel conductance. In some mutants, activation was slowed sufficiently to confer a sigmoidicity to current rise at low [K+]o. The results indicate that these residues are involved in [K+]o sensing. Their situation close to the permeation pathway points to an interaction between gating and permeation. [ABSTRACT FROM AUTHOR]

Published

1998

10. GLYCINE RECEPTORS: WHAT GETS IN AND WHY?

Author

Barry, Peter H, Schofield, Peter R, Moorhouse, Andrew J, and H, Peter

Subjects

*GLYCINE, *GABA receptors, *GENETIC mutation

Abstract

SUMMARY1. The glycine receptor channel (GlyR), a member of the ligand-gated ion channel superfamily, shares many similar permeation properties with the GABAA receptor channel. 2. The GlyR is anion permeable, with PK/PCl < 0.05, has a 5–6 Å minimum pore diameter and a permeation selectivity sequence dominated by hydration energies. 3. The channels, which display multiple subconductance states, can be multiply occupied. 4. Two positive arginine rings at the ends of the pore region may contribute to the anion selectivity of the GlyR. 5. Mutation of the extracellular charged arginine ring can impair channel function by decreasing the sensitivity of glycine activation, reducing channel conductance, shifting the normal multi-subconductance states to lower values and by decoupling the link between ligand binding and channel gating. 6. These and other site-directed mutagenesis studies of recombinant GlyR, together with studies of native GlyR, are providing further insights into what controls gating and ion permeation and selectivity through this channel. [ABSTRACT FROM AUTHOR]

Published

1999