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鏻阳离子和双阳离子在水合POPC磷脂双层中的吸收:一项计算研究。

Absorption of Phosphonium Cations and Dications into a Hydrated POPC Phospholipid Bilayer: A Computational Study.

作者信息

Pillai V V S, Kumari P, Benedetto A, Gobbo D, Ballone P

机构信息

School of Physics, University College Dublin, Dublin 4, Ireland.

Conway Institute for Biomolecular and Biomedical Research, University College Dublin, Dublin 4, Ireland.

出版信息

J Phys Chem B. 2022 Jun 6;126(23):4272-88. doi: 10.1021/acs.jpcb.2c02212.

DOI:10.1021/acs.jpcb.2c02212
PMID:35666883
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC9207913/
Abstract

Molecular dynamics (MD) based on an empirical force field is applied to investigate the effect of phosphonium cations ([P]) and geminal dications ([DxC10]) inserted at = 300 K into the hydration layer separating planar POPC phospholipid bilayers. Up to high concentration, nearly every added cation and dication becomes absorbed into the lipid phase. Absorption takes place during several microseconds and is virtually irreversible. The neutralizing counterions ([Cl], in the present simulation) remain dissolved in water, giving origin to the charge separation and the strong electrostatic double layer at the water/lipid interface. Incorporation of cations and dications changes the properties of the lipid bilayer such as diffusion, viscosity, and the electrostatic pattern. At high ionic concentration, the bilayer acquires a long-wavelength standing undulation, corresponding to a change of phase from fluid planar to ripple. All these changes are potentially able to affect processes relevant in the context of cell biology. The major difference between cations and dications concerns the kinetics of absorption, which takes place nearly two times faster in the [P] case, and for [DxC10] dications displays a marked separation into two-stages, corresponding to the easy absorption of the first phosphonium head of the dication and the somewhat more activated absorption of the second phosphonium head of each dication.

摘要

基于经验力场的分子动力学(MD)被用于研究在300K时,插入分隔平面POPC磷脂双层水合层中的鏻阳离子([P])和偕二阳离子([DxC10])的影响。直至高浓度时,几乎每个添加的阳离子和二价阳离子都会被吸收到脂质相中。吸收过程持续数微秒,且几乎是不可逆的。中和抗衡离子(在本模拟中为[Cl])仍溶解在水中,导致电荷分离以及水/脂质界面处强烈的静电双层。阳离子和二价阳离子的掺入改变了脂质双层的性质,如扩散、粘度和静电模式。在高离子浓度下,双层呈现出长波长的驻波起伏,这对应于从流体平面相到波纹相的相变。所有这些变化都有可能影响细胞生物学背景下的相关过程。阳离子和二价阳离子之间的主要差异在于吸收动力学,在[P]的情况下吸收速度快近两倍,而对于[DxC10]二价阳离子,吸收过程明显分为两个阶段,分别对应于二价阳离子的第一个鏻头的容易吸收以及每个二价阳离子的第二个鏻头的吸收略有激活。

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