Coulomb blockade model of permeation and selectivity in biological ion channels

Kaufman, I. Kh.; McClintock, Peter V. E.; Eisenberg, Robert S.

doi:10.1088/1367-2630/17/8/083021

Cited by 58 publications

(122 citation statements)

References 90 publications

(215 reference statements)

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“…It appears to be closely similar to its electronic counterpart in quantum dots [20]. As we have demonstrated earlier [12], strong ICB appears for Ca 2+ ions in model biological channels and manifests itself as an oscillation of the conductance as a function of Q f , divalent blockade, and the anomalous mole fraction effect (AMFE) well-known for calcium channels [21].…”

Section: Introductionsupporting

confidence: 68%

“…The ICB phenomenon manifests itself as multi-ion oscillations (alternating conduction bands and stop bands) in the Ca 2+ conductance and channel occupancy as functions of Q f [10,12]. Figure 2 presents the results of Brownian dynamics simulation of Ca 2+ conduction and occupancy over an extended range of Q f (0 À 10e).…”

Section: Ionic Coulomb Blockade and Concentrationrelated Shiftmentioning

confidence: 99%

“…Conduction and selectivity in calcium/sodium ion channels have recently been described [10][11][12] in terms of ionic Coulomb blockade (ICB) [13,14], a fundamental electrostatic phenomenon based on charge discreteness, an electrostatic exclusion principle, and single-file stochastic ion motion through the channel. Earlier, Von Kitzing had revealed the staircase-like shape of the occupancy vs. site affinity for the charged ion channel [15] (following discussions and suggestions in [16]), and comparable low-barrier ion-exchange transitions had been discovered analytically [17].…”

Section: Introductionmentioning

confidence: 99%

“…Site-directed mutagenesis and patch clamp measurements were used to investigate changes in the ion transport properties of the mutants caused by alterations in Q f . Increasing the value of Q f was expected to lead to stronger divalent blockade following the Langmuir isotherm and to a resonant variation of the divalent current with Q f [12].…”

Section: Introductionmentioning

confidence: 99%

“…Of course, our reduced model represents a significant simplification of the actual electrostatics and dynamics of ions and water molecules within the narrow selectivity filter due to, for example: the application of continuum electrostatics; the use of the implicit solvent model; and the assumption of 1D (i.e., single-file) movement of ions inside the selectivity filter. The validity and range of applicability of this kind of model have been discussed in detail elsewhere [11,12,24].…”

Section: Introductionmentioning

confidence: 99%

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Ionic Coulomb blockade and anomalous mole fraction effect in the NaChBac bacterial ion channel and its charge-varied mutants

Kaufman¹,

Fedorenko²,

Luchinsky³

et al. 2017

EPJ Nonlinear Biomed. Phys.

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Abstract. Background. The selectivity of biological cation channels is defined by a short, narrow selectivity filter, having a negative net fixed charge Q f . Voltage gated bacterial channels (NaChBac and some others) are frequently used in biophysics as simplified models of mammalian calcium and sodium channels. We report an experimental, analytic and numerical study of the effects of Q f and bulk ionic concentrations of Ca 2+ and Na + on conduction and selectivity of NaChBac channels, wild type and Q f -varied mutants. Methods. Site-directed mutagenesis and voltage clamp recordings were used to investigate the Na + /Ca 2+ selectivity, divalent blockade and anomalous mole fraction effect (AMFE) for different NaChBac wild type/ mutants channels and the properties dependence on Q f . Experimental results were compared with Brownian dynamics simulations and with analytic predictions of the ionic Coulomb blockade (ICB) model, which was extended to encompass bulk concentration effects. Results. It was shown that changing of Q f from -4e (for LESWAS wild type) to -8e (for LEDWAS mutant) leads to strong divalent blockade of the Na + current by micromolar amounts of Ca 2+ ions, similar to the effects seen in mammalian calcium channels. The BD simulations revealed a concentration-related logarithmic shift of the conduction bands. These results were shown to be consistent with ICB model predictions. Conclusions. The extended ICB model explains the experimental (divalent blockade and AMFE) and simulated (multi-ion bands and their concentration-related shifts) selectivity phenomena of NaChBac channel and its charge-varied mutants. These results extend the understanding of ion channel selectivity and may also be applicable to biomimetic nanopores with charged walls.

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Section: Introductionsupporting

confidence: 68%

Section: Ionic Coulomb Blockade and Concentrationrelated Shiftmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

See 3 more Smart Citations

Ionic Coulomb blockade and anomalous mole fraction effect in the NaChBac bacterial ion channel and its charge-varied mutants

Kaufman¹,

Fedorenko²,

Luchinsky³

et al. 2017

EPJ Nonlinear Biomed. Phys.

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2D Material Nanofiltration Membranes: From Fundamental Understandings to Rational Design

et al. 2021

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Since the discovery of 2D materials, 2D material nanofiltration (NF) membranes have attracted great attention and are being developed with a tremendously fast pace, due to their energy efficiency and cost effectiveness for water purification. The most attractive aspect for 2D material NF membranes is that, anomalous water and ion permeation phenomena have been constantly observed because of the presence of the severely confined nanocapillaries (<2 nm) in the membrane, leading to its great potential in achieving superior overall performance, e.g., high water flux, high rejection rates of ions, and high resistance to swelling. Hence, fundamental understandings of such water and ion transport behaviors are of great significance for the continuous development of 2D material NF membranes. In this work, the microscopic understandings developed up to date on 2D material NF membranes regarding the abnormal transport phenomena are reviewed, including ultrafast water and ion permeation rates with the magnitude several orders higher than that predicted by conventional diffusion behavior, ion dehydration, ionic Coulomb blockade, ion-ion correlations, etc. The state-of-the-art structural designs for 2D material NF membranes are also reviewed. Discussion and future perspectives are provided highlighting the rational design of 2D material membrane structures in the future.

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