A single NaK channel conformation is not enough for non-selective ion conduction

Shi, Chaowei; He, Yao; Hendriks, Kitty; Groot, Bert L. de; Cai, Xiaoying; Tian, Changlin; Lange, Adam; Sun, Han

doi:10.1038/s41467-018-03179-y

Cited by 56 publications

(111 citation statements)

References 62 publications

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“…These dynamics cause a small widening of the SF on average, and thereby slightly relax the strict geometric constraints for ion transfer, especially at the central ion binding site. Similar findings have recently been reported for the related NaK channel 45 .…”

Section: Strict K + Selectivity Is Coupled To the Exclusion Of Watersupporting

confidence: 91%

“…The diminished K + selectivity of the NaK and NaK2CNG channels has previously been associated with the reduced number of SF ion binding sites 38 , the increased hydration level of ions 22,43,44 , for instance seen in the NaK crystal structure 39,40 , and enhanced structural plasticity of the SF 45 . This led to the conclusion that only channels with four consecutive ion binding sites in the SF can ensure fully K + selective ion permeation.…”

Section: Strict K + Selectivity Is Coupled To the Exclusion Of Watermentioning

confidence: 99%

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Direct knock-on of desolvated ions governs strict ion selectivity in K+ channels

et al. 2018

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The seeming contradiction that K channels conduct K ions at maximal throughput rates while not permeating slightly smaller Na ions has perplexed scientists for decades. Although numerous models have addressed selective permeation in K channels, the combination of conduction efficiency and ion selectivity has not yet been linked through a unified functional model. Here, we investigate the mechanism of ion selectivity through atomistic simulations totalling more than 400 μs in length, which include over 7,000 permeation events. Together with free-energy calculations, our simulations show that both rapid permeation of K and ion selectivity are ultimately based on a single principle: the direct knock-on of completely desolvated ions in the channels' selectivity filter. Herein, the strong interactions between multiple 'naked' ions in the four filter binding sites give rise to a natural exclusion of any competing ions. Our results are in excellent agreement with experimental selectivity data, measured ion interaction energies and recent two-dimensional infrared spectra of filter ion configurations.

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Section: Strict K + Selectivity Is Coupled To the Exclusion Of Watersupporting

confidence: 91%

Section: Strict K + Selectivity Is Coupled To the Exclusion Of Watermentioning

confidence: 99%

Direct knock-on of desolvated ions governs strict ion selectivity in K+ channels

et al. 2018

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“…However, in the case of the life system, the fast transport of ions and molecules is in the ultrafast fluid state, which is caused by a precisely quantized flow. For example, a K + nanochannel from Streptomyces lividans comprises two K + ions with a distance of 7.5 Å, also with a H 2 O molecule in the middle ( Figure a); the NaK nonselective nanochannel only allows one hydrated Na + ion in the channel, each Ca 2+ channel in calmodulin also simultaneously binds two Ca 2+ ions; and the H 2 O channel allows transport of H 2 O molecules in the way of ordered molecular chain (Figure b), etc. Such phenomena demonstrate that the ultrafast transport conducts in a quantum way with single ionic or molecular chain, so we have proposed a concept of QSF to understand this ultrafast fluid .…”

Section: Wettability In 1d Nanochannelsmentioning

confidence: 99%

Wettability and Applications of Nanochannels

2018

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Wettability in nanochannels is of great importance for understanding many challenging problems in interface chemistry and fluid mechanics, and presents versatile applications including mass transport, catalysis, chemical reaction, nanofabrication, batteries, and separation. Recently, both molecular dynamic simulations and experimental measurements have been employed to study wettability in nanochannels. Here, wettability in three types of nanochannels comprising 1D nanochannels, 2D nanochannels, and 3D nanochannels is summarized both theoretically and experimentally. The proposed concept of “quantum‐confined superfluid” for ultrafast mass transport in nanochannels is first introduced, and the mostly studied 1D nanochannels are reviewed from molecular simulation to water wettability, followed by reversible switching of water wettability via external stimuli (temperature and voltage). Liquid transport and two confinement strategies in nanochannels of melt wetting and liquid wetting are also included. Then, molecular simulation, water wettability, liquid transport, and confinement in nanochannels are introduced for 2D nanochannels and 3D nanochannels, respectively. Based on the wettability in nanochannels, broad applications of various nanochannels are presented. Finally, the perspective for future challenges in the wettability and applications of nanochannels is discussed.

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“…[4] However, the fast mass transport in living systems is in an ultrafast liquid state, which stems from a precisely quantized flow. For example, the K + channel from Streptomyces lividans consists of two K + ions about 0.75 nm apart, with one H 2 O molecule in between (Figure 3a); [42,43] the NaK nonselective channel allows only one hydrated Na + ion in the selectivity filter; [44] each Ca 2+ channel in calmodulin binds two Ca 2+ ions simultaneously. [45] These phenomena demonstrate that the ultrafast mass transport in living systems performs in a quantum way with a single ordered ionic or molecular chain.…”

Section: Quantum-confined Superfluidmentioning

confidence: 99%

1D Nanoconfined Ordered‐Assembly Reaction

Liu

Zhang

Jiang

2019

Adv Materials Inter

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1D nanoconfined chemical reactions generally exhibit enhanced performance, as a consequence of nanoconfinement, yet the inherent mechanism of this nanoconfinement‐enhanced performance remains elusive. Here, the authors' perspectives on 1D nanoconfined chemical reactions are first provided, followed by the 1D nanoconfined preassembled reactions. Then, ultrafast mass transport behaviors in biological and artificial nanochannels are discussed and the quantum‐confined superfluid concept is introduced. Inspired by the programmed‐assembly reaction in living organisms, a new concept of ordered‐assembly reaction is proposed through combining quantum‐confined superfluid with frontier molecular orbital theory, to understand the inherent mechanism of high‐performance 1D nanoconfined chemical reactions. Finally, the prospective for future development of the ordered‐assembly reaction concept is presented.

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A single NaK channel conformation is not enough for non-selective ion conduction

Cited by 56 publications

References 62 publications

Direct knock-on of desolvated ions governs strict ion selectivity in K+ channels

Direct knock-on of desolvated ions governs strict ion selectivity in K+ channels

Wettability and Applications of Nanochannels

1D Nanoconfined Ordered‐Assembly Reaction

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