微生物宏蛋白质组——从样品处理、数据采集到数据分析

doi:10.3724/SP.J.1123.2024.02009

摘要/Abstract

摘要：

微生物与人体疾病、健康密切相关,如何理解微生物群落的组成及其发挥的功能是一大亟需研究的问题。近年来,宏蛋白质组学已经成为研究微生物组成与功能的重要技术手段。然而,由于微生物群落样本的复杂性与高度异质性,样品处理、质谱数据采集与数据分析成为宏蛋白质组目前面临的三大挑战。在宏蛋白质组分析中往往需要针对不同类型的样品进行前处理优化,采取不同的微生物分离富集、提取和裂解方案。与单一物种蛋白质组相类似,宏蛋白质组学中的质谱数据采集模式有数据依赖性采集(data-dependent acquisition, DDA)模式和数据非依赖性采集(data-independent acquisition, DIA)模式。DIA数据采集模式可以完整地采集样品的肽段信息,具有很强的发展潜力。但是由于宏蛋白质组样品的复杂性,其DIA数据解析已成为阻碍宏蛋白质组深度覆盖的一大难题。在数据解析方面,最重要的步骤在于蛋白质序列数据库的构建。数据库的大小和完整性不仅对鉴定数量有很大影响,还会影响物种和功能水平上的分析。目前宏蛋白质组数据库构建的金标准是基于宏基因组的蛋白质序列数据库。同时,基于迭代搜库的公共数据库过滤方法也已被证明具有很强的实用价值。从具体的数据解析策略角度,以肽段为中心的DIA数据解析方法占据了绝对的主流。随着深度学习和人工智能的发展,其会极大地推动宏蛋白质组数据解析的准确度、覆盖度与分析速度。在下游生物信息学分析方面,近年来开发了一系列注释工具,可以在蛋白水平、肽段水平、基因水平上进行物种注释来获得微生物群落组成。与其他组学方法相比,微生物群落的功能分析是宏蛋白质组学的一个独特特征。宏蛋白质组已经成为微生物群落多组学分析中的重要组成部分,并且仍在覆盖深度、检测灵敏度、数据解析完整度等方面具有很大的发展潜力。

关键词: 宏蛋白质组学, 样品前处理, 数据库, 数据分析策略

Abstract:

Microorganisms are closely associated with human diseases and health. Understanding the composition and function of microbial communities requires extensive research. Metaproteomics has recently become an important method for throughout and in-depth study of microorganisms. However, major challenges in terms of sample processing, mass spectrometric data acquisition, and data analysis limit the development of metaproteomics owing to the complexity and high heterogeneity of microbial community samples. In metaproteomic analysis, optimizing the preprocessing method for different types of samples and adopting different microbial isolation, enrichment, extraction, and lysis schemes are often necessary. Similar to those for single-species proteomics, the mass spectrometric data acquisition modes for metaproteomics include data-dependent acquisition (DDA) and data-independent acquisition (DIA). DIA can collect comprehensive peptide information from a sample and holds great potential for future development. However, data analysis for DIA is challenged by the complexity of metaproteome samples, which hinders the deeper coverage of metaproteomes. The most important step in data analysis is the construction of a protein sequence database. The size and completeness of the database strongly influence not only the number of identifications, but also analyses at the species and functional levels. The current gold standard for metaproteome database construction is the metagenomic sequencing-based protein sequence database. A public database-filtering method based on an iterative database search has been proven to have strong practical value. The peptide-centric DIA data analysis method is a mainstream data analysis strategy. The development of deep learning and artificial intelligence will greatly promote the accuracy, coverage, and speed of metaproteomic analysis. In terms of downstream bioinformatics analysis, a series of annotation tools that can perform species annotation at the protein, peptide, and gene levels has been developed in recent years to determine the composition of microbial communities. The functional analysis of microbial communities is a unique feature of metaproteomics compared with other omics approaches. Metaproteomics has become an important component of the multi-omics analysis of microbial communities, and has great development potential in terms of depth of coverage, sensitivity of detection, and completeness of data analysis.

Key words: metaproteomics, sample pretreatment, database, data analysis strategy

中图分类号:

O658

吴恩慧, 乔亮. 微生物宏蛋白质组——从样品处理、数据采集到数据分析[J]. 色谱, 2024, 42(7): 658-668.

WU Enhui, QIAO Liang. Microbial metaproteomics——From sample processing to data acquisition and analysis[J]. Chinese Journal of Chromatography, 2024, 42(7): 658-668.

图/表 5

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Reference	Time	Samples	Analysis strategy	MS instrument	MS acquisition mode	Analysis tools	Identification
Rooijers et al.^[17]	2011	fecal sample	iterative search	LTQ-Orbitrap	DDA	OMSSA	over 3000 peptides
Jagtap et al.^[48]	2012	salivary sample	iterative search	LTQ-Orbitrap	DDA	MaxQuant	2176 proteins
Tanca et al.^[49]	2013	synthetic microbial community	metagenomics derived databases	LTQ-Orbitrap	DDA	Proteome Discoverer	10881 peptides
Zhang et al.^[50]	2016	mouse fecal sample; human colonoscopy sample	MetaPro-IQ	Q Exactive	DDA	X! Tandem MaxQuant	30749 proteins; 19011 proteins
May et al.^[51]	2016	ocean microbiome sample	Metapeptide	Q-Exactive-HF	DDA	Comet	6918 peptides
Xiao et al.^[52]	2018	synthetic microbial community; fecal sample	MT	LTQ-Orbitrap	DDA	X! Tandem MaxQuant	11308 peptides; 10932 peptides
Long et al.^[20]	2020	fecal sample	hybrid spectra library-based DIA	Orbitrap Fusion Lumos Tribrid	DIA	PEAKS SpectroMine Spectronaut	91902 peptides; 30062 proteins
Aakko et al.^[21]	2020	synthetic microbial community; fecal sample	DDA spectra library-based DIA	Q Exactive HF	DIA	diatools	14888 peptides; 12804 peptides
Stamboulian et al.^[53]	2021	human colonoscopy sample	HAPiID	LTQ-Orbitrap	DDA	MS-GF+	24962 peptides
Pietilä et al.^[54]	2022	fecal sample	directDIA	Q Exactive HF	DIA	X!Tandem Comet	14691 peptides
Zhao et al.^[55]	2023	synthetic microbial community; fecal sample	directDIA	Orbitrap Fusion Lumos Tribrid	DIA	PEAKS MaxQuant FragPipe	10572 proteins; about 70000 proteins
Gómez-Varela et al.^[47]	2023	mice fecal sample	peptide-centric DIA analysis	timsTOF Pro	DIA	DIA-NN MaxQuant	over 15000 proteins
Wu et al.^[56]	2024	synthetic microbial community; fecal sample	ConDiGA	timsTOF Pro	DDA	PEAKS	13537 proteins; 12630 proteins
Wu et al.^[57]	2024	synthetic microbial community; fecal sample	HAPs-hyblibDIA	timsTOF Pro	DIA	Spectronaut	11770 proteins; 28585 proteins

Reference	Time	Samples	Analysis strategy	MS instrument	MS acquisition mode	Analysis tools	Identification
Rooijers et al.^[17]	2011	fecal sample	iterative search	LTQ-Orbitrap	DDA	OMSSA	over 3000 peptides
Jagtap et al.^[48]	2012	salivary sample	iterative search	LTQ-Orbitrap	DDA	MaxQuant	2176 proteins
Tanca et al.^[49]	2013	synthetic microbial community	metagenomics derived databases	LTQ-Orbitrap	DDA	Proteome Discoverer	10881 peptides
Zhang et al.^[50]	2016	mouse fecal sample; human colonoscopy sample	MetaPro-IQ	Q Exactive	DDA	X! Tandem MaxQuant	30749 proteins; 19011 proteins
May et al.^[51]	2016	ocean microbiome sample	Metapeptide	Q-Exactive-HF	DDA	Comet	6918 peptides
Xiao et al.^[52]	2018	synthetic microbial community; fecal sample	MT	LTQ-Orbitrap	DDA	X! Tandem MaxQuant	11308 peptides; 10932 peptides
Long et al.^[20]	2020	fecal sample	hybrid spectra library-based DIA	Orbitrap Fusion Lumos Tribrid	DIA	PEAKS SpectroMine Spectronaut	91902 peptides; 30062 proteins
Aakko et al.^[21]	2020	synthetic microbial community; fecal sample	DDA spectra library-based DIA	Q Exactive HF	DIA	diatools	14888 peptides; 12804 peptides
Stamboulian et al.^[53]	2021	human colonoscopy sample	HAPiID	LTQ-Orbitrap	DDA	MS-GF+	24962 peptides
Pietilä et al.^[54]	2022	fecal sample	directDIA	Q Exactive HF	DIA	X!Tandem Comet	14691 peptides
Zhao et al.^[55]	2023	synthetic microbial community; fecal sample	directDIA	Orbitrap Fusion Lumos Tribrid	DIA	PEAKS MaxQuant FragPipe	10572 proteins; about 70000 proteins
Gómez-Varela et al.^[47]	2023	mice fecal sample	peptide-centric DIA analysis	timsTOF Pro	DIA	DIA-NN MaxQuant	over 15000 proteins
Wu et al.^[56]	2024	synthetic microbial community; fecal sample	ConDiGA	timsTOF Pro	DDA	PEAKS	13537 proteins; 12630 proteins
Wu et al.^[57]	2024	synthetic microbial community; fecal sample	HAPs-hyblibDIA	timsTOF Pro	DIA	Spectronaut	11770 proteins; 28585 proteins