Selectivity of the KcsA potassium channel: Analysis and computation

“…Remember SISBM3 is designed for extremely high ion concentrations motivated by the more efficient packing shown in Figure 1 b. Actually for situations that would give rise to extremely high ion concentrations and make the steric effect not negligible, such as the Stern layer in the electric double layer (EDL) of a charged wall (discussed next) and the selectivity filter of a K channel [ 20 ], there would be ‘locally’ one species only, which is the counter-ion of the local electrostatic environment, since co-ions (and even water) would be totally expelled. Taking the K channel selectivity filter as an example, its extreme narrowness and the strong negative oxygen charges inside it would definitely justify only one species being inside the selectivity filter, which is definitely potassium.…”

Section: Discussionmentioning

confidence: 99%

Review and Modification of Entropy Modeling for Steric Effects in the Poisson-Boltzmann Equation

Horng

2020

Entropy

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The classical Poisson-Boltzmann model can only work when ion concentrations are very dilute, which often does not match the experimental conditions. Researchers have been working on the modification of the model to include the steric effect of ions, which is non-negligible when the ion concentrations are not dilute. Generally the steric effect was modeled to correct the Helmholtz free energy either through its internal energy or entropy, and an overview is given here. The Bikerman model, based on adding solvent entropy to the free energy through the concept of volume exclusion, is a rather popular steric-effect model nowadays. However, ion sizes are treated as identical in the Bikerman model, making an extension of the Bikerman model to include specific ion sizes desirable. Directly replacing the ions of non-specific size by specific ones in the model seems natural and has been accepted by many researchers in this field. However, this straightforward modification does not have a free energy formula to support it. Here modifications of the Bikerman model to include specific ion sizes have been developed iteratively, and such a model is achieved with a guarantee that: (1) it can approach Boltzmann distribution at diluteness; (2) it can reach saturation limit as the reciprocal of specific ion size under extreme electrostatic conditions; (3) its entropy can be derived by mean-field lattice gas model.

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“…The studies [54,55] by Weishi Liu and his group have illustrated the effects of permanent charge on current-voltage relation. With ionic size effect and the permanent charge, saturation phenomenon of current-voltage curves can be modelled as shown in [51].…”

Section: Remarkmentioning

confidence: 99%

“…Following the previous hypothesis of the hydrophobic region, we construct a specific macroscopic model of a bubble within the framework of Poisson-Nernst-Planck (PNP) systems and show how it produces the time course of single K v channels and the ensemble properties, including the Cole-Moore delay. The PNP system and its variants have been found successful in modeling and simulation of many biological processes [50,51,28,52,53,54,55], such as current-voltage curves through ion channels, the selectivity of ion channels, and ion transport processes in the cell and tissue scales. In this work, a bubble is assumed to be present in the pore (or filter) region of the K v channel, due to the properties of the gating sensor and channel walls.…”

Section: Introductionmentioning

confidence: 99%

A Bubble Model for the Gating of Kv Channels

Song¹,

Eisenberg²,

Xu³

et al. 2022

Preprint

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Voltage-gated K v channels play fundamental roles in many biological processes, such as the generation of the action potential. The gating mechanism of K v channels is characterized experimentally by single-channel recordings and ensemble properties of the channel currents. In this work, we propose a bubble model coupled with a Poisson-Nernst-Planck (PNP) system to capture the key characteristics, particularly the delay in the opening of channels. The coupled PNP system is solved numerically by a finite-difference method and the solution is compared with an analytical approximation. We hypothesize that the stochastic behaviour of the gating phenomenon is due to randomness of the bubble and channel sizes. The predicted ensemble average of the currents under various applied voltage across the channels is consistent with experimental observations, and the Cole-Moore delay is captured by varying the holding potential.

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Selectivity of the KcsA potassium channel: Analysis and computation

Cited by 13 publications

References 71 publications

A detailed study of ion transport through the SARS-CoV-2 E protein ion channel

A detailed study of ion transport through the SARS-CoV-2 E protein ion channel

Review and Modification of Entropy Modeling for Steric Effects in the Poisson-Boltzmann Equation

A Bubble Model for the Gating of Kv Channels

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