Water between Membranes

Sotiris Samatas, C. Calero, Fausto Martelli, G. Franzese
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引用次数: 2

Abstract

An accurate description of the structure and dynamics of interfacial water is essential for phospholipid membranes, since it determines their function and their interaction with other molecules. Here we consider water confined in stacked membranes with hydration from poor to complete, as observed in a number of biological systems. Experiments show that the dynamics of water slows down dramatically when the hydration level is reduced. All-atom molecular dynamics simulations identify three (inner, hydration and outer) regions, within a distance of approximately 1 nm from the membrane, where water molecules exhibit different degrees of slowing down in the dynamics. The slow-down is a consequence of the robustness of the hydrogen bonds between water and lipids and the long lifetime of the hydrogen bonds between water molecules near the membrane. The interaction with the interface, therefore, induces a structural change in the water that can be emphasized by calculating its intermediate range order. Surprisingly, at distances as far as ~ 2.5 nm from the interface, although the bulk-like dynamics is recovered, the intermediate range order of water is still slightly higher than that in the bulk at the same thermodynamic conditions. Therefore, the water-membrane interface has a structural effect at ambient conditions that propagates further than the often-invoked 1 nm length scale. Membrane fluctuations smear out this effect macroscopically, but an analysis performed by considering local distances and instantaneous configurations is able to reveal it, possibly contributing to our understanding of the role of water at biomembrane interfaces.
膜间水
准确描述界面水的结构和动力学对磷脂膜至关重要,因为它决定了磷脂膜的功能及其与其他分子的相互作用。在这里,我们考虑水被限制在堆叠膜中,水合作用从差到完全,正如在许多生物系统中观察到的那样。实验表明,当水化水平降低时,水的动力学会显著减慢。全原子分子动力学模拟确定了三个区域(内部、水合作用和外部),在距离膜约1nm的距离内,水分子在动力学中表现出不同程度的减速。这种减速是由于水和脂质之间氢键的坚固性以及膜附近水分子之间氢键的长寿命造成的。因此,与界面的相互作用引起了水的结构变化,这种变化可以通过计算其中间范围阶来强调。令人惊讶的是,在距离界面约2.5 nm处,虽然恢复了体态动力学,但在相同热力学条件下,水的中间范围阶数仍略高于体态。因此,水膜界面在环境条件下具有结构效应,其传播范围超过通常调用的1nm长度尺度。膜波动在宏观上抹去了这种效应,但通过考虑局部距离和瞬时配置进行的分析能够揭示它,可能有助于我们理解水在生物膜界面上的作用。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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