Further analysis of counterion permeation through anion-selective glycine receptor channels

Barry, Peter H.; Sugiharto, Silas; Lewis, T.

doi:10.4161/chan.4.3.11020

Cited by 5 publications

(3 citation statements)

References 9 publications

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“…A possible reason is that many channels are selective for a specific ion (typically a cation), and counterions do not seem vital to the conduction mechanism. A few exceptions to this paradigm are available, including the chloride channel, the OmpF porin, the KAT1 channel (a voltage-gated K + channel from Arabidopsis thaliana ), and the glycine receptor, − as well as synthetic cation-selective nanotubes mimicking a biological ion channel . Among these few examples, the permeability of counterions has been partially characterized, suggesting a possible functional role.…”

Section: Introductionmentioning

confidence: 99%

Counterion-Assisted Cation Transport in a Biological Calcium Channel

2014

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How ions pass through the lumen of an ion channel is a key question underlying cellular communication. The effects of water and pore-lining residues (channel design) have been extensively explored. However, the role of counterions is less well understood. The pore subunit of the calcium release-activated calcium channel, Orai, provides a useful model to explore the effect of anions on the permeation of cations. Herein, we employ computer simulations molecular dynamics (MD) to explore ion permeation through the V174A Orai mutant, a constitutively open pore, in a phospholipid membrane hydrated by a 150 mM NaCl solution. When an external voltage is applied in the MD simulations, it induces only a moderate conformational change to the channel, which facilitates the passage of ions. Infrequent sodium permeation is observed on the microsecond time scale, which is consistent with experiment. In contrast, the chloride counterions exhibit higher mobility in the channel and are actively involved in sodium transport. The anion-assisted cation permeation identified here likely highlights a more general functional role for counterions, especially in ion channels with medium pore-size. Experiments with a variety of counterions might further illuminate the nature of their active role.

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Section: Introductionmentioning

confidence: 99%

Counterion-Assisted Cation Transport in a Biological Calcium Channel

2014

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“…Once inside the nanotube these resident chloride ions act to ferry, or chaperone, sodium ions from the entrance to the exit of the nanotube. This artificial channel resembles that of the mutant glycine receptor 38 in which anions act to chaperone sodium ions 40,41 with a conductance of 17 pS.…”

Section: Resultsmentioning

confidence: 99%

Synthetic cation-selective nanotube: Permeant cations chaperoned by anions

Hilder

Gordon

Chung

2011

The Journal of Chemical Physics

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The ability to design ion-selective, synthetic nanotubes which mimic biological ion channels may have significant implications for the future treatment of bacteria, diseases, and as ultrasensitive biosensors. We present the design of a synthetic nanotube made from carbon atoms that selectively allows monovalent cations to move across and rejects all anions. The cation-selective nanotube mimics some of the salient properties of biological ion channels. Before practical nanodevices are successfully fabricated it is vital that proof-of-concept computational studies are performed. With this in mind we use molecular and stochastic dynamics simulations to characterize the dynamics of ion permeation across a single-walled (10, 10), 36 Å long, carbon nanotube terminated with carboxylic acid with an effective radius of 5.08 Å. Although cations encounter a high energy barrier of 7 kT, its height is drastically reduced by a chloride ion in the nanotube. The presence of a chloride ion near the pore entrance thus enables a cation to enter the pore and, once in the pore, it is chaperoned by the resident counterion across the narrow pore. The moment the chaperoned cation transits the pore, the counterion moves back to the entrance to ferry another ion. The synthetic nanotube has a high sodium conductance of 124 pS and shows linear current-voltage and current-concentration profiles. The cation-anion selectivity ratio ranges from 8 to 25, depending on the ionic concentrations in the reservoirs.

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“…This includes several articles in the area of Stim/Orai, 1,2 which interestingly are among the highest cited Channels articles. Other areas covered in channels included ligand-gated channels, [3][4][5][6][7] potassium channels, [8][9][10][11] voltage-gated calcium and sodium channels, 12-15 and transporters, [16][17][18][19] among many others too numerous to list here. While a number of articles dealt with structure, function and regulation of ion channels and transporters, many papers were focused on the role of ion channels in mammalian physiology such as neurological and cardiovascular disorders.…”

Section: Channelsmentioning

confidence: 99%

Channels: The first five years

Zamponi¹

2011

Channels

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Further analysis of counterion permeation through anion-selective glycine receptor channels

Cited by 5 publications

References 9 publications

Counterion-Assisted Cation Transport in a Biological Calcium Channel

Counterion-Assisted Cation Transport in a Biological Calcium Channel

Synthetic cation-selective nanotube: Permeant cations chaperoned by anions

Channels: The first five years

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