Exosome Isolation by Ultracentrifugation and Precipitation and Techniques for Downstream Analyses

Q3 Biochemistry, Genetics and Molecular Biology

Current Protocols in Cell Biology Pub Date : 2020-07-07 DOI:10.1002/cpcb.110

Christina Coughlan, Kimberley D. Bruce, Olivier Burgy, Timothy D. Boyd, Cole R. Michel, Josselyn E. Garcia-Perez, Vanesa Adame, Paige Anton, Brianne M. Bettcher, Heidi J. Chial, Melanie Königshoff, Elena W. Y. Hsieh, Michael Graner, Huntington Potter

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引用次数: 81

Abstract

Exosomes are 50- to 150-nm-diameter extracellular vesicles secreted by all mammalian cells except mature red blood cells and contribute to diverse physiological and pathological functions within the body. Many methods have been used to isolate and analyze exosomes, resulting in inconsistencies across experiments and raising questions about how to compare results obtained using different approaches. Questions have also been raised regarding the purity of the various preparations with regard to the sizes and types of vesicles and to the presence of lipoproteins. Thus, investigators often find it challenging to identify the optimal exosome isolation protocol for their experimental needs. Our laboratories have compared ultracentrifugation and commercial precipitation- and column-based exosome isolation kits for exosome preparation. Here, we present protocols for exosome isolation using two of the most commonly used methods, ultracentrifugation and precipitation, followed by downstream analyses. We use NanoSight nanoparticle tracking analysis and flow cytometry (Cytek^®) to determine exosome concentrations and sizes. Imaging flow cytometry can be utilized to both size exosomes and immunophenotype surface markers on exosomes (ImageStream^®). High-performance liquid chromatography followed by nano-flow liquid chromatography–mass spectrometry (LCMS) of the exosome fractions can be used to determine the presence of lipoproteins, with LCMS able to provide a proteomic profile of the exosome preparations. We found that the precipitation method was six times faster and resulted in a ∼2.5-fold higher concentration of exosomes per milliliter compared to ultracentrifugation. Both methods yielded extracellular vesicles in the size range of exosomes, and both preparations included apoproteins. © 2020 Wiley Periodicals LLC.

Basic Protocol 1: Pre-analytic fluid collection and processing

Basic Protocol 2: Exosome isolation by ultracentrifugation

Alternate Protocol 1: Exosome isolation by precipitation

Basic Protocol 3: Analysis of exosomes by NanoSight nanoparticle tracking analysis

Alternate Protocol 2: Analysis of exosomes by flow cytometry and imaging flow cytometry

Basic Protocol 4: Downstream analysis of exosomes using high-performance liquid chromatography

Basic Protocol 5: Downstream analysis of the exosome proteome using nano-flow liquid chromatography–mass spectrometry

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超离心沉淀法分离外泌体及下游分析技术

外泌体是直径50- 150nm的细胞外囊泡，由除成熟红细胞外的所有哺乳动物细胞分泌，在体内具有多种生理和病理功能。许多方法被用于分离和分析外泌体，导致实验之间的不一致性，并提出了如何比较使用不同方法获得的结果的问题。关于各种制剂的纯度，关于囊泡的大小和类型以及脂蛋白的存在，也提出了问题。因此，研究人员经常发现，为他们的实验需要确定最佳的外泌体分离方案是具有挑战性的。我们的实验室已经比较了超离心和商业沉淀和柱基外泌体分离试剂盒制备外泌体。在这里，我们提出了使用两种最常用的方法分离外泌体的方案，即超离心和沉淀，然后进行下游分析。我们使用NanoSight纳米颗粒跟踪分析和流式细胞术(Cytek®)来确定外泌体的浓度和大小。成像流式细胞术可用于测定外泌体的大小和外泌体的免疫表型表面标记(ImageStream®)。外泌体组分的高效液相色谱和纳米流液相色谱-质谱(LCMS)可用于确定脂蛋白的存在，LCMS能够提供外泌体制剂的蛋白质组学特征。我们发现，与超离心相比，沉淀法的速度快6倍，每毫升外泌体的浓度高2.5倍。两种方法都产生了外泌体大小范围内的细胞外囊泡，并且两种制备方法都含有载脂蛋白。©2020 Wiley期刊有限公司基本方案1:分析前流体收集和处理基本方案2:超离心法分离外泌体备用方案1:沉淀法分离外泌体基本方案3:NanoSight纳米颗粒跟踪分析外泌体分析备用方案2:流式细胞术和成像流式细胞术分析外泌体基本方案4:高效液相色谱法下游分析外泌体基本方案5:外泌体蛋白质组的下游分析使用纳米流液相色谱-质谱法

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Current Protocols in Cell Biology Biochemistry, Genetics and Molecular Biology-Cell Biology

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期刊介绍： Developed by leading scientists in the field, Current Protocols in Cell Biology is an essential reference for researchers who study the relationship between specific molecules and genes and their location, function and structure at the cellular level. Updated every three months in all formats, CPCB is constantly evolving to keep pace with the very latest discoveries and developments.