Water permeation across artificial I-quartet membrane channels: from structure to disorder

Murail, Samuel; Vasiliu, Tudor; Neamţu, Andrei; Barboiu, Mihail; Sterpone, Fabio; Baaden, Marc

doi:10.1039/c8fd00046h

Cited by 30 publications

(68 citation statements)

References 34 publications

(36 reference statements)

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“…Further MD simulations via two different setup procedures suggest that in addition to ordered water wires through the channels, there may be an alternative disordered mechanism of water transport involving perturbations in the surrounding membrane. 287 …”

Section: Nonbiological Nanoporesmentioning

confidence: 99%

Water in Nanopores and Biological Channels: A Molecular Simulation Perspective

2020

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This Review explores the dynamic behavior of water within nanopores and biological channels in lipid bilayer membranes. We focus on molecular simulation studies, alongside selected structural and other experimental investigations. Structures of biological nanopores and channels are reviewed, emphasizing those high-resolution crystal structures, which reveal water molecules within the transmembrane pores, which can be used to aid the interpretation of simulation studies. Different levels of molecular simulations of water within nanopores are described, with a focus on molecular dynamics (MD). In particular, models of water for MD simulations are discussed in detail to provide an evaluation of their use in simulations of water in nanopores. Simulation studies of the behavior of water in idealized models of nanopores have revealed aspects of the organization and dynamics of nanoconfined water, including wetting/dewetting in narrow hydrophobic nanopores. A survey of simulation studies in a range of nonbiological nanopores is presented, including carbon nanotubes, synthetic nanopores, model peptide nanopores, track-etched nanopores in polymer membranes, and hydroxylated and functionalized nanoporous silica. These reveal a complex relationship between pore size/geometry, the nature of the pore lining, and rates of water transport. Wider nanopores with hydrophobic linings favor water flow whereas narrower hydrophobic pores may show dewetting. Simulation studies over the past decade of the behavior of water in a range of biological nanopores are described, including porins and β-barrel protein nanopores, aquaporins and related polar solute pores, and a number of different classes of ion channels. Water is shown to play a key role in proton transport in biological channels and in hydrophobic gating of ion channels. An overall picture emerges, whereby the behavior of water in a nanopore may be predicted as a function of its hydrophobicity and radius. This informs our understanding of the functions of diverse channel structures and will aid the design of novel nanopores. Thus, our current level of understanding allows for the design of a nanopore which promotes wetting over dewetting or vice versa. However, to design a novel nanopore, which enables fast, selective, and gated flow of water de novo would remain challenging, suggesting a need for further detailed simulations alongside experimental evaluation of more complex nanopore systems.

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Section: Nonbiological Nanoporesmentioning

confidence: 99%

Water in Nanopores and Biological Channels: A Molecular Simulation Perspective

2020

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“…This strategy imposes a critical vertical alignment configuration such that exposing the larger channel sides to the salt-rich feed can potentially lower its salt-rejection efficiency. Such alignment issues in unimolecular channels and conformation stability of the self-assembled channels 16 can significantly impede the channel performance. These factors represent a formidable design challenge in synthetic chemistry.…”

Section: Introductionmentioning

confidence: 99%

Porous organic cages as synthetic water channels

et al. 2020

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Nature has protein channels (e.g., aquaporins) that preferentially transport water molecules while rejecting even the smallest hydrated ions. Aspirations to create robust synthetic counterparts have led to the development of a few one-dimensional channels. However, replicating the performance of the protein channels in these synthetic water channels remains a challenge. In addition, the dimensionality of the synthetic water channels also imposes engineering difficulties to align them in membranes. Here we show that zero-dimensional porous organic cages (POCs) with nanoscale pores can effectively reject small cations and anions while allowing fast water permeation (ca. 109 water molecules per second) on the same magnitude as that of aquaporins. Water molecules are found to preferentially flow in single-file, branched chains within the POCs. This work widens the choice of water channel morphologies for water desalination applications.

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“…Important studies of AWCs including molecular dynam ics (MD) simulations have been pioneered by several groups around the world, notably in the USA, China, Singapore, Hong-Kong, etc. Molecular modeling approaches -in particular molecular dynamics in explicit solvent and membrane environments -constitute a pivotal tool to extend the methodology, providing insight at a molecular scale as described in [19][20][21]. Moving up in scales, the development of multi-scale approaches to describe hydrodynamics in molecular systems has the potential to provide new stimulus for water channel modeling [22,23].…”

Section: Origins and Brief Overviewmentioning

confidence: 99%

“…First results may illustrate these ideas. Previous MD simulation studies of dynamic behaviors of the artificial I-quartet water channels and water molecules under confined conditions in a lipid bilayer environment were reported in [19][20][21]. An important aspect to bear in mind from these works is the quantitative correlation be-tween the dipolar orientation of water-wires and their effects on their stability once inserted in the bilayer membranes.…”

Section: Imidazole I-quartet Channelsmentioning

confidence: 99%

Using Computer Simulations and Virtual Reality to Understand, Design and Optimize Artificial Water Channels

Martinez

Hardiagon

Santuz

et al. 2020

Advances in Bionanomaterials II

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In biology, metabolite transport across cell membranes occurs through natural channels and pores. Artificial ion-channel architectures represent potential mimics of natural ionic conduction. Many such systems were produced leading to a remarkable set of alternative artificial ion-channels. Far less advances were achieved in the area of synthetic biomimetic water channels, even though they could improve our understanding of the natural function of protein channels and may provide new strategies to generate highly selective, advanced water purification systems. Most realizations have used the selectivity components of natural protein channels embedded in artificial systems. Such biomolecules provide building blocks to constitute highly selective membrane-spanning water transport architectures. The simplification of such compounds, while preserving the high conduction activity of natural macromolecules, lead to fully synthetic artificial biomimetic channels. These simplified systems offer a particular chance to understand mechanistic and structural behaviors, providing rationales to engineer better artificial water-channels. Here we focus on computer simulations as a tool to complement experiment in understanding the properties of such systems with the aim to rationalize important concepts, design and optimize better compounds. Molecular dynamics simulations combined with advanced visual scrutiny thereof are central to such an approach. Novel technologies such as virtual reality headsets and stereoscopic large-scale display walls offer immersive collaborative insight into the complex mechanisms underlying artificial water channel function.

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Water permeation across artificial I-quartet membrane channels: from structure to disorder

Cited by 30 publications

References 34 publications

Water in Nanopores and Biological Channels: A Molecular Simulation Perspective

Water in Nanopores and Biological Channels: A Molecular Simulation Perspective

Porous organic cages as synthetic water channels

Using Computer Simulations and Virtual Reality to Understand, Design and Optimize Artificial Water Channels

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