Julie Winkel Missel , Nina Salustros , Eva Ramos Becares , Jonas Hyld Steffen , Amalie Gerdt Laursen , Angelica Struve Garcia , Maria M. Garcia-Alai , Čeněk Kolar , Pontus Gourdon , Kamil Gotfryd
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引用次数: 1
Abstract
Membrane proteins (MPs) constitute a large fraction of the proteome, but exhibit physicochemical characteristics that impose challenges for successful sample production crucial for subsequent biophysical studies. In particular, MPs have to be extracted from the membranes in a stable form. Reconstitution into detergent micelles represents the most common procedure in recovering MPs for subsequent analysis. n-dodecyl-β-D-maltoside (DDM) remains one of the most popular conventional detergents used in production of MPs. Here we characterize the novel DDM analogue 4-trans-(4-trans-propylcyclohexyl)-cyclohexyl α-maltoside (t-PCCαM), possessing a substantially lower critical micelle concentration (CMC) than the parental compound that represents an attractive feature when handling MPs. Using three different types of MPs of human and prokaryotic origin, i.e., a channel, a primary and a secondary active transporter, expressed in yeast and bacterial host systems, respectively, we investigate the performance of t-PCCαM in solubilization and affinity purification together with its capacity to preserve native fold and activity. Strikingly, t-PCCαM displays favorable behavior in extracting and stabilizing the three selected targets. Importantly, t-PCCαM promoted extraction of properly folded protein, enhanced thermostability and provided negatively-stained electron microscopy samples of promising quality. All-in-all, t-PCCαM emerges as competitive surfactant applicable to a broad portfolio of challenging MPs for downstream structure-function analysis.
膜蛋白(MPs)构成了蛋白质组的很大一部分,但其表现出的物理化学特性给成功的样品生产带来了挑战,这对后续的生物物理研究至关重要。特别是,MPs必须以稳定的形式从膜中提取出来。重组成洗涤剂胶束代表了回收MPs用于后续分析的最常见程序。正十二烷基-β- d -麦芽糖苷(DDM)仍然是生产MPs中最常用的常规洗涤剂之一。在这里,我们描述了新的DDM类似物4-反式-(4-反-丙基环己基)-环己基α-麦芽糖苷(t-PCCαM),具有比母体化合物低得多的临界胶束浓度(CMC),这在处理MPs时代表了一个有吸引力的特征。利用酵母和细菌宿主系统中分别表达的三种不同类型的人源和原核源MPs,即通道、一级和二级活性转运体,我们研究了t-PCCαM在增溶和亲和纯化方面的表现,以及它保持天然折叠和活性的能力。值得注意的是,t-PCCαM在提取和稳定三个选定的靶标方面表现出良好的行为。重要的是,t-PCCαM促进了适当折叠蛋白的提取,增强了热稳定性,并提供了高质量的阴性染色电镜样品。总而言之,t-PCCαM成为具有竞争力的表面活性剂,适用于下游结构功能分析的各种具有挑战性的MPs。
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