完整糖基化肽段的富集与质谱解析新技术研究进展

doi:10.3724/SP.J.1123.2021.06011

摘要/Abstract

摘要：

蛋白质糖基化是生物体内最重要的翻译后修饰之一,在蛋白质稳定性、细胞内和细胞间信号转导、激素活化或失活和免疫调节等生理过程和病理进程中发挥重要作用。而异常的蛋白质糖基化往往和多种疾病的发生发展密切相关,目前应用于临床检测的多种肿瘤生物标志物大多属于糖蛋白或者糖抗原。因此在组学层次系统分析蛋白质糖基化的变化对阐明生物体内糖基化修饰的调控机理和发现新型疾病标志物都非常重要。基于质谱的蛋白质组学技术为全面分析蛋白质及其修饰提供了有效的分析手段。在自下而上的蛋白质组学研究中,由于完整糖基化肽段同时存在性质各异的肽段骨架和糖链结构、糖肽的相对丰度和离子化效率较低以及糖基化修饰有高度异质性等特点,完整糖肽的分析比其他翻译后修饰更加困难。近年来,为了更全面、系统地分析蛋白质糖基化,研究人员发展了一些新技术,包括完整糖肽的富集技术、质谱的碎裂模式和数据采集模式、质谱数据的解析方法和定量策略等等,大力推进了该领域的研究水平,也为研究蛋白质糖基化相关的生物标志物提供了技术支持。该篇综述主要关注近年来基于质谱的糖蛋白质组学研究中的新进展,重点介绍针对完整N-和O-糖基化肽段的富集新技术和谱图解析新方法,并讨论其在肿瘤早期诊断方面的应用潜力。

关键词: 蛋白质糖基化, 完整糖肽富集, 质谱分析, 谱图解析

Abstract:

Protein glycosylation is one of the most important post-translational modifications (PTMs). The glycosylation is crucial in a variety of physiological and pathological processes that include protein stability, intracellular and intercellular signal transduction, hormone activation or inactivation, and immune regulation. Protein glycosylation is generated by complex biosynthetic pathways comprising hundreds of glycosyltransferases, glycosidases, transcriptional factors, transporters, and protein backbones. Abnormal protein glycosylation is closely associated with the occurrence and development of diseases. Many disease biomarkers in clinical screening are glycoproteins (alfa fetoprotein for liver cancer, carbohydrate antigen 125 for ovarian cancer, carcinoembryonic antigen for colon cancer, prostate-specific antigen for prostate cancer, etc.), and glycan antigens (carbohydrate antigen 19-9 for gastrointestinal cancer and pancreatic cancer, etc.). Glycoproteomics research and technological developments are important to elucidate the mechanism of protein glycosylation in vivo. Mass spectrometry (MS)-based proteomics provides an excellent approach for the comprehensive analysis of proteins and their modifications. In bottom-up proteomics, glycoproteomic analysis is more difficult than other PTMs because intact glycopeptides have diverse peptide backbones and glycan chains, relatively low abundance and ionization efficiency, and pronounced heterogeneity. In recent years, glycoproteomic methodologies such as intact glycopeptide enrichment methods, MS fragmentation and acquisition approaches, MS data interpretation tools and software, and quantification strategies have been appreciably improved. These methodologies have driven in-depth glycoproteomics research. This review focuses on the recent advances in MS-based glycoproteomics. New enrichment methods and spectral interpretation approaches of intact N- and O-glycopeptides are discussed. Their applications in answering various questions in complex biological systems are also considered.
The new enrichment methods for intact glycopeptides are mostly based on existing principles. Some properties of the materials, such as hydrophilicity and electrophilicity, have been optimized to improve the enrichment performance. For example, dual-functional Ti(IV)-IMAC materials have been used for the separation of glycopeptides and phosphopeptides. Considering the clinical applications, some glycoproteomics methods integrate enrichment processing into automated workflows to reduce errors caused by manual operations and to increase the experimental reproducibility and efficiency. For example, an automated glycopeptide enrichment method consisting of a liquid chromatograph equipped with a hydrophilic interaction chromatography column has been shown capable of highly reproducible analyses of site-specific glycopeptides in complex biological samples. These methods are more suitable for the discovery of newly glycosylation-related biomarkers as well as for the physiopathological studies of human diseases.
With the optimization of glycopeptide enrichment methods and the innovation of MS technologies in the past decade, MS analysis of intact glycopeptides has begun to yield a wealth of glycopeptide fragment ions and plentiful high-quality MS data. This review introduces several effective fragmentation methods for intact glycopeptides. These include collision-induced dissociation, high-energy collision dissociation, electron capture dissociation, electron-transfer dissociation, and electron-transfer/higher-energy collision dissociation. Automated analysis of MS data of intact N- and O-glycopeptides requires interpretation approaches and corresponding software tools with high sensitivity and reliability. Finally, we highlight the utility of several spectral interpretation approaches and their corresponding popular search software, including ArMone, Byonic, GPQuest, pGlyco, O-search, MSFragger-Glyco, and O-Pair Search. In addition, MS data acquisition modes, such as data-dependent acquisition, data-independent acquisition, multiple reaction monitoring technology, and parallel reaction monitoring technology, have great application prospects in glycoproteomics research. With the improvements in enrichment methods, MS technologies, and spectral interpretation approaches for intact N- and O-glycopeptides, comprehensive and systematic glycoproteomics analysis has tremendously expanded the knowledge of protein glycosylation. These glycoproteomic technologies have a wide range of applications that include exploring the molecular mechanisms of protein glycosylation and discovering the new biomarkers of human diseases.

Key words: protein glycosylation, intact glycopeptide enrichment, mass spectrometric analysis, spectral interpretation

中图分类号:

O658

刘璐瑶, 秦洪强, 叶明亮. 完整糖基化肽段的富集与质谱解析新技术研究进展[J]. 色谱, 2021, 39(10): 1045-1054.

LIU Luyao, QIN Hongqiang, YE Mingliang. Recent advances in glycopeptide enrichment and mass spectrometry data interpretation approaches for glycoproteomics analyses[J]. Chinese Journal of Chromatography, 2021, 39(10): 1045-1054.

图/表 4

图1 基于亲水作用色谱法的自动化完整糖肽富集平台[11]

Fig. 1 An HILIC-based automated intact glycopeptide enrichment platform[11]

图2 双功能Ti(IV)-IMAC材料[15,16]

Fig. 2 Dual-functional Ti(IV)-IMAC materials[15,16] a. for the separation of glycopeptides, phosphopeptides and M6P glycopeptides[15]; b. for the enrichment of intact O-glycopeptides[16].

图3 pGlyco 2.0检索策略用于解析完整N-糖肽HCD谱图[31]

Fig. 3 Searching strategy of pGlyco 2.0 for the interpretation of intact N-glycopeptide HCD spectra[31]

图4 O-search检索策略用于解析完整O-糖肽HCD谱图[37]

Fig. 4 Searching strategy of O-search for the interpretation of intact O-glycopeptide HCD spectra[37]

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