Electrodeformation of DMPC vesicle membranes near the main phase transition.

IF 3.1 3区生物学 Q2 BIOPHYSICS

Biophysical journal Pub Date : 2025-09-01 DOI:10.1016/j.bpj.2025.08.023

Simon Fabiunke, Petia M Vlahovska

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Abstract

The physical properties of lipid membranes are essential to cellular function, with membrane fluidity playing a key role in the mobility of embedded biomolecules. Fluidity is governed by the membrane's phase state, which is known to depend on composition and temperature. However, in living cells, the transmembrane electric potential may also influence membrane fluidity. In this study, we use giant unilamellar vesicles composed of dimyristoylphosphatidylcholine to examine the membrane's response to electric fields near its main phase transition temperature. Below the transition temperature, the vesicle remains undeformed, indicating a bilayer in the gel phase. However, near the transition, the vesicle elongates into an ellipsoid, and the evolution of the aspect ratio exhibits a two-step response: an initial rapid increase followed by a slower elongation. Electrodeformation experiments at various temperatures relative to the transition temperature T_m reveal that the duration of the fast step increases as the temperature approaches T_m, and the slow step vanishes for a bilayer the fluid phase. We attribute the initial rapid response to the fluid phase and the subsequent slow response to a thermal expansion induced by Joule heating from the electric field.

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DMPC囊泡膜在主相变附近的电变形。

脂质膜的物理性质对细胞功能至关重要，膜流动性在嵌入的生物分子的流动性中起着关键作用。流动性是由膜的相状态决定的，而相状态是由成分和温度决定的。然而，在活细胞中，跨膜电位也可能影响膜的流动性。在这项研究中，我们使用由二肉豆蔻酰基磷脂酰胆碱（DMPC）组成的巨大单层囊泡来检测膜在其主相变温度附近对电场的响应。低于转变温度，囊泡保持不变，表明在凝胶阶段的双层。然而，在过渡附近，囊泡伸长成椭球，长宽比的演变表现出两步响应：最初的快速增加，随后是较慢的伸长。在相对于转变温度Tm的不同温度下进行的电变形实验表明，随着温度接近Tm，快速步骤的持续时间增加，而对于双层流体相，慢步骤消失。我们将最初的快速响应归因于流体相，随后的缓慢响应归因于电场焦耳加热引起的热膨胀。

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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来源期刊

Biophysical journal 生物-生物物理

CiteScore

6.10

自引率

5.90%

发文量

3090

审稿时长

2 months

期刊介绍： BJ publishes original articles, letters, and perspectives on important problems in modern biophysics. The papers should be written so as to be of interest to a broad community of biophysicists. BJ welcomes experimental studies that employ quantitative physical approaches for the study of biological systems, including or spanning scales from molecule to whole organism. Experimental studies of a purely descriptive or phenomenological nature, with no theoretical or mechanistic underpinning, are not appropriate for publication in BJ. Theoretical studies should offer new insights into the understanding ofexperimental results or suggest new experimentally testable hypotheses. Articles reporting significant methodological or technological advances, which have potential to open new areas of biophysical investigation, are also suitable for publication in BJ. Papers describing improvements in accuracy or speed of existing methods or extra detail within methods described previously are not suitable for BJ.