Metabolic Analysis at the Nanoscale with Multi-Isotope Imaging Mass Spectrometry (MIMS)

Q3 Biochemistry, Genetics and Molecular Biology Current Protocols in Cell Biology Pub Date : 2020-07-24 DOI:10.1002/cpcb.111

Derek P. Narendra, Matthew L. Steinhauser

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引用次数: 4

Abstract

Incorporation of a stable-isotope metabolic tracer into cells or tissue can be followed at submicron resolution by multi-isotope imaging mass spectrometry (MIMS), a form of imaging secondary ion microscopy optimized for accurate isotope ratio measurement from microvolumes of sample (as small as ∼30 nm across). In a metabolic MIMS experiment, a cell or animal is metabolically labeled with a tracer containing a stable isotope. Relative accumulation of the heavy isotope in the fixed sample is then measured as an increase over its natural abundance by MIMS. MIMS has been used to measure protein turnover in single organelles, track cellular division in vivo, visualize sphingolipid rafts on the plasma membrane, and measure dopamine incorporation into dense-core vesicles, among other biological applications. In this article, we introduce metabolic analysis using NanoSIMS by focusing on two specific applications: quantifying protein turnover in single organelles of cultured cells and tracking cell replication in mouse tissues in vivo. These examples illustrate the versatility of metabolic analysis with MIMS. © 2020 Wiley Periodicals LLC.

Basic Protocol 1: Metabolic labeling for MIMS

Basic Protocol 2: Embedding of samples for correlative transmission electron microscopy and MIMS with a genetically encoded reporter

Alternate Protocol: Embedding of samples for correlative light microscopy and MIMS

Support Protocol: Preparation of silicon wafers as sample supports for MIMS

Basic Protocol 3: Analysis of MIMS data

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纳米尺度的多同位素成像质谱(MIMS)代谢分析

将稳定同位素代谢示踪剂掺入细胞或组织后，可以通过多同位素成像质谱法(MIMS)在亚微米分辨率下进行，这是一种成像二次离子显微镜，可用于从微体积样品(小至30 nm)精确测量同位素比率。在代谢MIMS实验中，用含有稳定同位素的示踪剂对细胞或动物进行代谢标记。然后，用MIMS测量固定样品中重同位素的相对积累量，以增加其自然丰度。MIMS已被用于测量单个细胞器中的蛋白质周转，跟踪体内细胞分裂，观察质膜上的鞘脂筏，以及测量多巴胺与密核囊泡的结合，以及其他生物学应用。在本文中，我们介绍了利用NanoSIMS的代谢分析，重点介绍了两个特定的应用:定量培养细胞的单个细胞器中的蛋白质周转和跟踪小鼠体内组织中的细胞复制。这些例子说明了使用MIMS进行代谢分析的多功能性。©2020 Wiley期刊有限责任公司基本协议1:代谢标记的MIMS基本协议2:用基因编码的报告器嵌入相关透射电子显微镜和MIMS的样品备用协议:嵌入相关光学显微镜和MIMS的样品支持协议:制备硅片作为MIMS的样品支持基本协议3:MIMS数据分析

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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

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