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短杆菌肽A对平面脂质双层的吸附作用。

Alamethicin adsorption to a planar lipid bilayer.

作者信息

Vodyanoy I, Hall J E, Vodyanoy V

机构信息

Department of Physiology and Biophysics, University of California, Irvine 92717.

出版信息

Biophys J. 1988 May;53(5):649-58. doi: 10.1016/S0006-3495(88)83145-X.

Abstract

The effect of alamethicin and its derivatives on the voltage-dependent capacitance of phosphatidylethanolamine (squalane) membranes was measured using two different methods: lock-in detection and voltage pulse. Alamethicin and its derivatives modulate the voltage-dependent capacitance at voltages lower than the voltage at which alamethicin-induced conductance is detected. The magnitude and sign of this alamethicin-induced capacitance change depends on the aqueous alamethicin concentration and the kind of alamethicin used. Our experimental data can be interpreted as a potential-dependent pseudocapacitance associated with adsorbed alamethicin. Pseudocapacitance is expressed as a function of alamethicin charge, its concentration in the bathing solution and the applied electric field. The theory describes the dependence of the capacitance on applied voltage and alamethicin concentration. When alamethicin is neutral the theory predicts no change of the voltage-dependent capacitance with either sign of applied voltage. Experimental data are consistent with the model in which alamethicin molecules interact with each other while being adsorbed to the membrane surface. The energy of this interaction depends on the alamethicin concentration.

摘要

使用两种不同方法测量了阿拉霉素及其衍生物对磷脂酰乙醇胺(角鲨烷)膜电压依赖性电容的影响:锁相检测法和电压脉冲法。阿拉霉素及其衍生物在低于检测到阿拉霉素诱导电导的电压下调节电压依赖性电容。这种阿拉霉素诱导的电容变化的幅度和符号取决于阿拉霉素在水溶液中的浓度以及所用阿拉霉素的种类。我们的实验数据可以解释为与吸附的阿拉霉素相关的电位依赖性赝电容。赝电容表示为阿拉霉素电荷、其在浴液中的浓度以及施加电场的函数。该理论描述了电容对施加电压和阿拉霉素浓度的依赖性。当阿拉霉素呈中性时,该理论预测无论施加电压的符号如何,电压依赖性电容都不会改变。实验数据与阿拉霉素分子在吸附到膜表面时相互作用的模型一致。这种相互作用的能量取决于阿拉霉素的浓度。

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本文引用的文献

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