肽浓度和脂质组成对H-Ras脂质锚定簇的可逆影响。

Reversible Effects of Peptide Concentration and Lipid Composition on H-Ras Lipid Anchor Clustering.

作者信息

Lin Xubo, Li Zhenlong, Gorfe Alemayehu A

机构信息

Department of Integrative Biology and Pharmacology, Medical School, The University of Texas Health Science Center at Houston, Houston, Texas.

出版信息

Biophys J. 2015 Dec 15;109(12):2467-2470. doi: 10.1016/j.bpj.2015.11.009.

DOI:10.1016/j.bpj.2015.11.009

PMID:26682805

原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC4699922/

Abstract

Dynamic clusters of lipid-anchored Ras proteins are important for high-fidelity signal transduction in cells. The average size of Ras nanoclusters was reported to be independent of protein expression levels, and cholesterol depletion is commonly used to test the raft-preference of nanoclusters. However, whether protein concentration and membrane domain stability affect Ras clustering in a reversible manner is not well understood. We used coarse-grained molecular dynamics simulations to examine the reversibility of the effects of peptide and cholesterol concentrations as well as a lipid domain-perturbing nanoparticle (C60) on the dynamics and stability of H-Ras lipid-anchor nanoclusters. By comparing results from these simulations with previous observations from the literature, we show that effects of peptide/cholesterol concentrations on the dynamics and stability of H-Ras peptide nanoclusters are reversible. Our results also suggest a correlation between the stabilities of lipid domains and Ras nanoclusters, which is supported by our finding that C60 penetrates into the liquid-disordered domain of the bilayer, destabilizing lipid domains and thereby the stability of the nanoclusters.

摘要

脂质锚定的Ras蛋白动态簇对于细胞中的高保真信号转导至关重要。据报道，Ras纳米簇的平均大小与蛋白质表达水平无关，并且通常使用胆固醇耗竭来测试纳米簇对脂筏的偏好性。然而，蛋白质浓度和膜结构域稳定性是否以可逆方式影响Ras聚集尚未得到很好的理解。我们使用粗粒度分子动力学模拟来研究肽和胆固醇浓度以及脂质结构域扰动纳米颗粒（C60）对H-Ras脂质锚定纳米簇的动力学和稳定性的影响的可逆性。通过将这些模拟结果与文献中先前的观察结果进行比较，我们表明肽/胆固醇浓度对H-Ras肽纳米簇的动力学和稳定性的影响是可逆的。我们的结果还表明脂质结构域和Ras纳米簇的稳定性之间存在相关性，这得到了我们的发现的支持，即C60渗透到双层的液相无序结构域中，破坏脂质结构域，从而破坏纳米簇的稳定性。

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