Energetics of discrete selectivity bands and mutation-induced transitions in the calcium-sodium ion channels family

TL;DR

This study uses simulations to map the conduction and selectivity bands of calcium-sodium ion channels based on fixed charge, revealing how mutations influence channel behavior and selectivity through electrostatic interactions.

Contribution

It provides a comprehensive pattern of conduction and selectivity bands for calcium-sodium channels and links mutation effects to transitions between these bands.

Findings

Identification of discrete conduction bands for calcium and sodium channels.

Demonstration of electrostatic interactions as key to ion selectivity.

Explanation of mutation-induced channel transformations.

Abstract

We use Brownian dynamics simulations to study the permeation properties of a generic electrostatic model of a biological ion channel as a function of the fixed charge $Q_f$ at its selectivity filter. We reconcile the recently-discovered discrete calcium conduction bands M0 ($Q_f$=1e), M1 (3e), M2 (5e) with the set of sodium conduction bands L0 (0.5-0.7e), L1 (1.5-2e) thereby obtaining a completed pattern of conduction and selectivity bands v $Q_f$ for the sodium-calcium channels family. An increase of $Q_f$ leads to an increase of calcium selectivity: L0 (sodium selective, non-blocking channel) -> M0 (non-selective channel) -> L1 (sodium selective channel with divalent block) -> M1 (calcium selective channel exhibiting the anomalous mole fraction effect). We create a consistent identification scheme where the L0 band is identified with the eukaryotic (DEKA) sodium channel, and L1/L2 (speculatively) with the bacterial NaChBac channel. The scheme created is able to account for the experimentally observed mutation-induced transformations between non-selective channels, sodium-selective channels, and calcium-selective channels, which we interpret as transitions between different rows of the identification table. By considering the potential energy changes during permeation, we show explicitly that the multi-ion conduction bands of calcium and sodium channels arise as the result of resonant barrier-less conduction. Our results confirm the crucial influence of electrostatic interactions on conduction and on the Ca/Na valence selectivity of calcium and sodium ion channels. The model and results could be also applicable to biomimetic nanopores with charged walls.