从细胞条件培养基、血浆、尿液和唾液中分离细胞外小泡的尺寸排除色谱的比较研究

IF 4.1 Q2 MATERIALS SCIENCE, MULTIDISCIPLINARY Frontiers in Nanotechnology Pub Date : 2023-04-05 DOI:10.3389/fnano.2023.1146772
H. Contreras, P. Alarcón-Zapata, E. Nova-Lamperti, V. Ormazábal, M. Varas-Godoy, C. Salomon, F. Zúñiga
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引用次数: 0

摘要

细胞外囊泡(EVs)由所有类型的细胞分泌,并参与蛋白质、代谢物和遗传物质在细胞间的运输。根据其生物发生和物理性质,通常将ev分为小型ev(包括外泌体)或大型ev和大型癌体。用于分离ev的方法多种多样;然而,它们有一些局限性,包括囊泡变形、颗粒产量降低和共分离蛋白质污染物。本文提出了一种优化的、快速、低成本的方法,通过比较两种SEC固定相G200/120和G200/140色谱,从生物液中分离出小型ev (30-150 nm)。方法:考虑的优化参数为:a)固定相的选择;b)洗脱液每组分的体积;c)富集30 ~ 150 nm ev - s组分的选择。通过纳米颗粒跟踪分析(NTA)、流式细胞术、总蛋白定量和Western blot评价各UF/SEC组分的效率和分离谱。结果:两种色谱柱均能从血浆、尿液、唾液和hek293衍生的EV中分离出低蛋白污染物的主要小EV。与G200/120柱相比,G200/ 40柱在EV收集介质中,在30 ~ 150 nm范围内的囊泡富集更为均匀[76.1±4.4%,平均大小为85.9±3.6 nm(模式:72.8 nm)]。根据囊泡-蛋白比估计,G200/40的富集量为1.3 × 1010颗粒/mg蛋白,与G200/120相比,获得了更显著的ev富集。优化后的方法可获得0.8 ml的ev富集产物,每个样品仅需30分钟。在血浆中,优化后的方法对小ev的富集率为70.5±0.18%,平均大小为119.4±6.9 nm(模式为120.3 nm),囊泡分离物的富集量为4.8 × 1011粒/mg蛋白。尿液和唾液- ev样本的平均尺寸分别为147.5±3.4 nm和111.9±2.5 nm。从样品中分离的所有小ev在透射电子显微镜(TEM)下都表现出典型的杯状形态。讨论:本研究表明,这两种方法的结合是分离小型电动汽车的一种稳健、快速和改进的策略。
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Comparative study of size exclusion chromatography for isolation of small extracellular vesicle from cell-conditioned media, plasma, urine, and saliva
Introduction: Extracellular vesicles (EVs) are secreted from all types of cells and are involved in the trafficking of proteins, metabolites, and genetic material from cell to cell. According to their biogenesis and physical properties, EVs are often classified as small EVs (including exosomes) or large EVs, and large oncosomes. A variety of methods are used for isolated EVs; however, they have several limitations, including vesicle deformation, reduced particle yield, and co-isolate protein contaminants. Here we present an optimized fast and low-cost methodology to isolate small EVs (30–150 nm) from biological fluids comparing two SEC stationary phases, G200/120 and G200/140 columns. Methods: The optimization parameters considered were a) the selection of the stationary phase, b) the eluate volume per fraction, and c) the selection of the enriched 30–150 nm EVs-fractions. The efficiency and separation profile of each UF/SEC fraction was evaluated by Nanoparticle tracking analysis (NTA), flow cytometry, total protein quantification, and Western blot. Results: Both columns can isolate predominantly small EVs with low protein contaminants from plasma, urine, saliva, and HEK293-derived EV from collection medium. Column G200/ 40 offers a more homogeneous enrichment of vesicles between 30 and 150 nm than G200/120 [76.1 ± 4.4% with an average size of 85.9 ± 3.6 nm (Mode: 72.8 nm)] in the EV collection medium. The enrichment, estimated as the vesicle-to-protein ratio, was 1.3 × 1010 particles/mg protein for G200/40, obtaining a more significant EVs enrichment compared to G200/120. The optimized method delivers 0.8 ml of an EVs-enriched-outcome, taking only 30 min per sample. Using plasma, the enrichment of small EVs from the optimized method was 70.5 ± 0.18%, with an average size of 119.4 ± 6.9 nm (Mode: 120.3 nm), and the enrichment of the vesicle isolation was 4.8 × 1011 particles/mg protein. The average size of urine and saliva -EVs samples was 147.5 ± 3.4 and 111.9 ± 2.5 nm, respectively. All the small EVs isolated from the samples exhibit the characteristic cup-shaped morphology observed by Transmission electron microscopy (TEM). Discussion: This study suggests that the combination of methods is a robust, fast, and improved strategy for isolating small EVs.
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来源期刊
Frontiers in Nanotechnology
Frontiers in Nanotechnology Engineering-Electrical and Electronic Engineering
CiteScore
7.10
自引率
0.00%
发文量
96
审稿时长
13 weeks
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