基于质谱的单细胞蛋白质组学分析方法及应用

doi:10.3724/SP.J.1123.2020.08030

色谱 ›› 2021, Vol. 39 ›› Issue (2): 142-151.DOI: 10.3724/SP.J.1123.2020.08030

基于质谱的单细胞蛋白质组学分析方法及应用

秦少杰, 白玉^*(), 刘虎威

北京大学化学与分子工程学院, 北京分子科学国家研究中心, 北京 100871

收稿日期:2020-08-31 出版日期:2021-02-08 发布日期:2021-01-14
通讯作者: 白玉
作者简介:白玉: 北京大学副教授,博士生导师。1998年于吉林大学获得理学学士学位,2004年于中科院长春应用化学研究所获得理学博士学位。2008年初结束加拿大多伦多大学博士后工作,受聘于北京大学。一直以色谱和质谱为主要研究手段,开展复杂体系痕量样本的分离与质谱检测研究。发展了高效生物标志物富集新方法,搭建了高通量质谱分析系统,建立了微升血样及单细胞水平生物标志物的超高灵敏分析新方法。近5年以通讯作者在J Am Chem Soc, Angew Chem Int Ed, Chem Sci和Anal Chem等杂志发表SCI论文30余篇,获中国发明专利授权3项,申请PCT国际专利1项;主持国家自然科学基金委优秀青年基金(2013)和多项面上项目;作为课题负责人参加2项国家重大科学仪器重点研发计划和1项北京市自然科学基金重点项目;2017年获聘北京大学博雅青年学者;受邀担任美国质谱学会年会(ASMS2019)临床质谱分会主席、中国物理学会质谱专业委员会理事、中国化学会有机分析专业委员会委员、北京色谱学会副秘书长。现为Sep Sci Plus, Mass Spectrom Lett以及《色谱》《质谱学报》《生命科学仪器》等多种国内外期刊编委和青年编委。* Tel:(010)62758198,E-mail: yu.bai@pku.edu.cn.
基金资助:
国家自然科学基金(21527809);国家自然科学基金(21874003);北京市自然科学基金重点项目(Z170002)

Methods and applications of single-cell proteomics analysis based on mass spectrometry

QIN Shaojie, BAI Yu^*(), LIU Huwei

College of Chemistry and Molecular Engineering, Peking University, Beijing National Laboratory for Molecular Sciences, Beijing 100871, China

Received:2020-08-31 Online:2021-02-08 Published:2021-01-14
Contact: BAI Yu
Supported by:
National Natural Science Foundation of China(21527809);National Natural Science Foundation of China(21874003);Beijing Natural Science Foundation Essential Research Project(Z170002)

摘要/Abstract

摘要：

细胞是生命体的最小组成单位,遗传及外部环境等因素使单细胞异质性广泛存在于众多生物体中。传统的生物学实验获得的结果多是大量细胞的平均测量值,因此在单细胞层面开展研究对于精确理解细胞的生长发育以及疾病的诊断与治疗至关重要。而作为重要的细胞和生命活动的执行者,蛋白质由于其不具备扩增特性,且种类繁多、丰度低、动态分布范围宽,与核酸等其他生物大分子相比,其单细胞组学研究相对滞后。而在所有的检测手段中,荧光检测以及电化学分析方法具有极高的灵敏度,但是囿于其研究通量有限,以及电化学活性依赖,很难成为普适性的单细胞蛋白质组学研究方法。质谱分析作为传统蛋白质组学中最为核心的研究技术,由于其高灵敏、高通量、结构信息丰富等特点,在单细胞蛋白质组学研究中独树一帜。该文综述了近年来基于质谱的单细胞蛋白质组学研究中的代表性方法,根据质谱分析前蛋白质分离方式的差异,将其分为基于毛细管电泳分离、液相色谱分离和无分离手段的直接检测3类方法,在介绍研究现状的同时对这些方法在细胞通量、蛋白质鉴定数目、灵敏度以及方法应用方面进行了总结与比较。最后,基于目前研究中面临的挑战以及发展趋势对基于质谱的单细胞蛋白质组学的研究前景进行了展望。

关键词: 毛细管电泳, 液相色谱, 质谱, 微流控, 蛋白质组学, 单细胞, 综述

Abstract:

The cell is the smallest unit of living organisms. Although cells often assemble to serve a common function, intercellular heterogeneity often exists due to different genetic and environmental effects. Therefore, single-cell analysis has been regarded as an indispensable means to investigate cell heterogeneity, especially when researching cell differentiation, disease diagnosis, and therapy. As the chief factors influencing cell and biological activities, proteins have long been a major concern in biochemistry. However, due to their intrinsic lack of amplification characteristics, wide species variety, low abundance, and wide dynamic range, proteins are scarcely studied in single-cell research when compared with other biological macromolecules. Therefore, ultra-sensitive single-cell proteomics analysis methods are urgently required. Among all general measurement techniques, fluorescence methods possess high sensitivity and a capability of dynamic tracing, but low target numbers impose restrictions on their broad application in real “proteomic” studies. Similarly, electrochemical methods adapt to electrochemically active molecules, which miss the majority of proteins. Mass spectrometry (MS), as the core approach of proteomic studies, provides high-sensitivity and high-throughput analysis of proteins together with abundant structural information, which is unique in all the analytical instruments and has made great progress in single-cell proteomic research. Herein, the representative research methods for single-cell proteomics based on MS are reviewed. According to the different protein separation methods used prior to MS analysis, they are divided into three categories, including capillary electrophoresis (CE), liquid chromatography (LC), and direct infusion without the need for separation. First, CE has been widely used in the separation and analysis of complex biological samples owing to its low cost, high analysis speed, and high separation efficiency. Its unique feature is the extraction and transfer of contents from cellular or subcellular regions using capillaries smaller than a single cell size. This sampling method also offers less substrate interference and negligible oxidative damage to the cells. Nonetheless, single-cell analysis based on CE-MS mainly focuses on proteomic studies of large cells because of the considerable sample loss, interface instability, and reproducibility issues. Compared with CE, LC, especially nanoLC, is more widely used in single-cell proteomic research, which mainly depends on its good reproducibility, nanoliter injection volume, low flow rate, low sample loss, and good compatibility with mass spectrometry. In recent years, it has been increasingly applied in the study of large-volume embryos, germ cells, and even somatic cells. More than 1000 proteins have been identified in single HeLa cells using this state-of-the-art single-cell proteomics method. It is worth noting that the single-cell sampling volume based on LC gradually reduces to the nanoliter level, and that the sample loss can be reduced by integrating a series of proteomic sampling processes into small volumes, setting sealing conditions, and reducing washing steps. However, the adequacy of cell lysis, the completeness and efficiency of protein pretreatment, and the labeling of peptide segments are important factors affecting the number and types of protein identification. Compared with protein separation using CE or LC prior to MS analysis, the direct MS analysis, assisted by labelling and signal transformation, eliminates complicated sample pretreatment and simplifies the operation by reducing enzymatic hydrolysis and separation. It also renders higher resolution as well as multi-omics compatibility. So far, the number of proteins detected using this method is limited due to the complexity of the samples. In conclusion, the aspects of throughput, sensitivity, identified protein species, and applications are summarized for each method mentioned above, and the prospect of single-cell proteomic research based on MS in the future is also discussed.

Key words: capillary electrophoresis (CE), liquid chromatography (LC), mass spectrometry (MS), microfluidic, proteomics, single cell, review

中图分类号:

O658

秦少杰, 白玉, 刘虎威. 基于质谱的单细胞蛋白质组学分析方法及应用[J]. 色谱, 2021, 39(2): 142-151.

QIN Shaojie, BAI Yu, LIU Huwei. Methods and applications of single-cell proteomics analysis based on mass spectrometry[J]. Chinese Journal of Chromatography, 2021, 39(2): 142-151.

图/表 3

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Separation mean	Method	Throughput (cell numbers/ run)	Identified protein number¹⁾	Sensitivity	Application
CE based	microdissection^[22]	1	1630 (label)²⁾	25 amol	differentiation process and subcellular asymme-
	macrosampling^[19]	1	341	700 zmol	try of Xenopus embryo, zebrafish embryos
	RP pre-fractionation^[24]	1	141	260 zmol	mouse hippocampal neurons proteome
LC based	microdissection^[29]	1	1500	-	Xenopus embryo differentiation process and
	microdissection with iTRAQ strategy^[30]	8	~4000 (label)	-	early development
	SCoPE^[31]	~190	767 (label)	zmol	differentiation of mouse embryonic stem cells
	SCoPE2^[33]	>2000	>1000 (label)	zmol	differentiation mechanism of homogeneous monocytes
	OAD chip^[38]	1	51	-	Hela cell proteome
	iPAD-1^[35]	1	126	1.7 zmol	histone profiling in Hela cell cycle
	nanoPOTs^[32]	72	1400 (label)	amol	classification of Epithelial cells and immune cells in mice
	enhanced nanoPOTs^[41]	72	362	<amol	Hela cell proteome
Direct detection	AP-MALDI^[44]	~10⁴-10⁵	220 peptides	-	mice brain tissue imaging
based	SIMS^[52]	~10³-10⁴	<10	-	three-dimensional imaging of cells
	mass cytometry^[57]	~10⁵-10⁶	40	zmol	cellular signaling network changes
	mass cytometry imaging^[4]	~10⁴-10⁵	40	zmol	breast cancer subtyping

Separation mean	Method	Throughput (cell numbers/ run)	Identified protein number¹⁾	Sensitivity	Application
CE based	microdissection^[22]	1	1630 (label)²⁾	25 amol	differentiation process and subcellular asymme-
	macrosampling^[19]	1	341	700 zmol	try of Xenopus embryo, zebrafish embryos
	RP pre-fractionation^[24]	1	141	260 zmol	mouse hippocampal neurons proteome
LC based	microdissection^[29]	1	1500	-	Xenopus embryo differentiation process and
	microdissection with iTRAQ strategy^[30]	8	~4000 (label)	-	early development
	SCoPE^[31]	~190	767 (label)	zmol	differentiation of mouse embryonic stem cells
	SCoPE2^[33]	>2000	>1000 (label)	zmol	differentiation mechanism of homogeneous monocytes
	OAD chip^[38]	1	51	-	Hela cell proteome
	iPAD-1^[35]	1	126	1.7 zmol	histone profiling in Hela cell cycle
	nanoPOTs^[32]	72	1400 (label)	amol	classification of Epithelial cells and immune cells in mice
	enhanced nanoPOTs^[41]	72	362	<amol	Hela cell proteome
Direct detection	AP-MALDI^[44]	~10⁴-10⁵	220 peptides	-	mice brain tissue imaging
based	SIMS^[52]	~10³-10⁴	<10	-	three-dimensional imaging of cells
	mass cytometry^[57]	~10⁵-10⁶	40	zmol	cellular signaling network changes
	mass cytometry imaging^[4]	~10⁴-10⁵	40	zmol	breast cancer subtyping

基于质谱的单细胞蛋白质组学分析方法及应用

Methods and applications of single-cell proteomics analysis based on mass spectrometry

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