分析物
蛋白质组
过采样
蛋白质组学
质谱法
定量蛋白质组学
背景(考古学)
计算生物学
单细胞分析
计算机科学
化学
串联质谱法
色谱法
生物
细胞
生物化学
基因
带宽(计算)
古生物学
计算机网络
作者
Marion Pang,Jeff Jones,Ting‐Yu Wang,Baiyi Quan,Nicole J. Kubat,Yanping Qiu,M. L. Roukes,Tsui‐Fen Chou
标识
DOI:10.1021/acs.jproteome.4c00062
摘要
The advancement of sophisticated instrumentation in mass spectrometry has catalyzed an in-depth exploration of complex proteomes. This exploration necessitates a nuanced balance in experimental design, particularly between quantitative precision and the enumeration of analytes detected. In bottom-up proteomics, a key challenge is that oversampling of abundant proteins can adversely affect the identification of a diverse array of unique proteins. This issue is especially pronounced in samples with limited analytes, such as small tissue biopsies or single-cell samples. Methods such as depletion and fractionation are suboptimal to reduce oversampling in single cell samples, and other improvements on LC and mass spectrometry technologies and methods have been developed to address the trade-off between precision and enumeration. We demonstrate that by using a monosubstrate protease for proteomic analysis of single-cell equivalent digest samples, an improvement in quantitative accuracy can be achieved, while maintaining high proteome coverage established by trypsin. This improvement is particularly vital for the field of single-cell proteomics, where single-cell samples with limited number of protein copies, especially in the context of low-abundance proteins, can benefit from considering analyte complexity. Considerations about analyte complexity, alongside chromatographic complexity, integration with data acquisition methods, and other factors such as those involving enzyme kinetics, will be crucial in the design of future single-cell workflows.
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