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用于数据非依赖采集的多重定量分析。

Multiplexed quantification for data-independent acquisition.

作者信息

Minogue Catherine E, Hebert Alexander S, Rensvold Jarred W, Westphall Michael S, Pagliarini David J, Coon Joshua J

机构信息

Department of Chemistry, ‡Genome Center of Wisconsin, §Department of Biomolecular Chemistry, and ∥Department of Biochemistry, University of Wisconsin , Madison, Wisconsin 53706, United States.

出版信息

Anal Chem. 2015 Mar 3;87(5):2570-5. doi: 10.1021/ac503593d. Epub 2015 Feb 11.

DOI:10.1021/ac503593d
PMID:25621425
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC4472008/
Abstract

Data-independent acquisition (DIA) strategies provide a sensitive and reproducible alternative to data-dependent acquisition (DDA) methods for large-scale quantitative proteomic analyses. Unfortunately, DIA methods suffer from incompatibility with common multiplexed quantification methods, specifically stable isotope labeling approaches such as isobaric tags and stable isotope labeling of amino acids in cell culture (SILAC). Here we expand the use of neutron-encoded (NeuCode) SILAC to DIA applications (NeuCoDIA), producing a strategy that enables multiplexing within DIA scans without further convoluting the already complex MS(2) spectra. We demonstrate duplex NeuCoDIA analysis of both mixed-ratio (1:1 and 10:1) yeast and mouse embryo myogenesis proteomes. Analysis of the mixed-ratio yeast samples revealed the strong accuracy and precision of our NeuCoDIA method, both of which were comparable to our established MS(1)-based quantification approach. NeuCoDIA also uncovered the dynamic protein changes that occur during myogenic differentiation, demonstrating the feasibility of this methodology for biological applications. We consequently establish DIA quantification of NeuCode SILAC as a useful and practical alternative to DDA-based approaches.

摘要

数据非依赖型采集(DIA)策略为大规模定量蛋白质组分析提供了一种灵敏且可重复的数据依赖型采集(DDA)方法的替代方案。不幸的是,DIA方法与常见的多重定量方法不兼容,特别是与等压标签和细胞培养中氨基酸的稳定同位素标记(SILAC)等稳定同位素标记方法不兼容。在此,我们将中子编码(NeuCode)SILAC的应用扩展到DIA(NeuCoDIA),产生了一种能够在DIA扫描中实现多重分析且不会进一步使本就复杂的二级质谱(MS(2))谱图更加复杂的策略。我们展示了对混合比例(1:1和10:1)的酵母和小鼠胚胎肌生成蛋白质组进行双重NeuCoDIA分析。对混合比例酵母样本的分析揭示了我们的NeuCoDIA方法具有很高的准确性和精密度,二者均与我们已建立的基于一级质谱(MS(1))的定量方法相当。NeuCoDIA还揭示了肌生成分化过程中发生的动态蛋白质变化,证明了该方法在生物学应用中的可行性。因此,我们确立了NeuCode SILAC的DIA定量作为基于DDA方法的一种有用且实用的替代方法。

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