毛细管电泳-质谱联用技术及其在蛋白质组学中的应用

蛋白质组学研究在生物学、精准医学等方面发挥着重要的作用。然而研究面临的巨大挑战来自生物样品的复杂性,因此在质谱（MS）鉴定技术不断革新的同时,发展分离技术以降低样品复杂度尤为重要。毛细管电泳（CE）技术具有上样体积小、分离效率高、分离速度快等优势,其与质谱的联用在蛋白质组学研究中越来越受到关注。低流速鞘流液和无鞘流液接口的发展及商品化推动了CE-MS技术的发展。目前毛细管区带电泳（CZE）、毛细管等电聚焦（CIEF）、毛细管电色谱（CEC）等分离模式已与质谱联用,其中CZE-MS应用最广泛。目前被广泛采用的蛋白质组学研究策略主要是基于酶解肽段分离鉴定的"自下而上（bottom-up）"策略。首先,CE-MS技术对酶解肽段的检测灵敏度高达1 zmol,已成功应用于单细胞蛋白质组学;其次,毛细管电泳技术与反相液相色谱互补,为疏水性质相近的肽段（尤其是翻译后修饰肽段）的分离鉴定提供了新的途径。基于整体蛋白质分离鉴定的自上而下"top-down"策略可以直接获得更精准、更完整的蛋白质信息。CE技术在蛋白质大分子的分离方面具有分离效率高、回收率高的优势,其与质谱的联用提高了整体蛋白质的鉴定灵敏度和覆盖度。非变性质谱（native MS）是一种在近生理条件下从完整蛋白质复合物水平上进行分析的质谱技术。CE与非变性质谱联用已被尝试用于蛋白质复合体的分离鉴定。该文引用了与CE-MS和蛋白质组学应用相关的93篇文献,综述了以上介绍的CE-MS的研究进展以及在蛋白质组学分析中的应用优势,并总结和展望了其应用前景。     

复杂生物体系中蛋白质高效分离分析技术的新进展

继人类基因组计划完成之后,作为一种新的研究策略,蛋白质组学在生命科学研究中发挥着愈来愈重要的作用。由于生物体系的复杂性和多样性,使得分离效率高、灵敏度高、通量高和动态范围宽的分离分析技术平台的研究和应用已成为蛋白质组学研究的重点和热点之一。着重介绍了近年来应用日益广泛的多维色谱预分离、毛细管液相色谱-质谱联用、毛细管电泳及其与质谱联用等高效分离分析技术在复杂生物体系的蛋白质分析中的最新进展。引用相关文献40篇。     

高通量蛋白质组学分析研究进展

基于质谱的蛋白质组学技术已经日趋成熟,可以对细胞和组织中的成千上万种蛋白质进行全面的定性和定量分析,逐步实现“深度覆盖”。随着生物医学日益增长的大队列蛋白质组学分析需求,如何在保持较为理想的覆盖深度下实现短时间、快速的“高通量”蛋白质组学分析已成为当前亟需解决的关键问题之一。常规的蛋白质组学分析流程通常包括样品前处理、色谱分离、质谱检测和数据分析。该文从以上4个方面展开介绍近10年以来高通量蛋白质组学分析技术取得的一系列研究进展,主要包括:(1)基于高通量、自动化移液工作站的蛋白质组样品前处理方法;(2)基于微升流速液相色谱与质谱联用的高通量蛋白质组检测方法;(3)利用灵敏度高、扫描速度快的质谱仪实现短色谱梯度分离下蛋白质组深度覆盖的分析方法;(4)基于人工智能、深度神经网络、机器学习等的蛋白质组学大数据分析方法。此外,对高通量蛋白质组学面临的挑战及其发展进行展望。总而言之,预期在不久的将来高通量蛋白质组学技术将会逐步“落地转化”,成为大队列蛋白质组学分析的利器。     

基于质谱的蛋白质组学技术在神经退行性疾病生物标志物研究中的应用

蛋白质组学是在整体水平上研究细胞、组织或生物体蛋白质组成及变化规律的科学.与传统的生物学研究相比,蛋白质组学具有快速、灵敏、高通量的优点.神经退行性疾病是一类由神经系统内特定神经细胞的进程性病变或丢失而导致神经功能障碍的疾病,严重危害人类健康.近年来,基于质谱的蛋白质组学技术在神经退行性疾病的研究中得到了广泛应用.本文简要介绍了蛋白质组学在样品分离、多肽定量、质谱检测及生物标志物临床验证等方面的技术发展,并结合实例综述了基于质谱的蛋白质组学在神经退行性疾病生物标志物发现与验证中的研究进展.     

基于质谱的蛋白质组学技术在食品真伪鉴别及品质识别方面的应用

蛋白质组学作为后基因组时代的一个新研究方向,近几年发展迅速,目前已应用于多个领域,在食品品质检测和安全控制方面成为有力的研究工具。蛋白质组学为食品科学的相关研究打开了新思路,不仅可以鉴定蛋白质种类,还可进行蛋白质定量,为分析不同物种、产地、成熟阶段的食品蛋白质组分和含量提供了可能。蛋白质组学研究手段多样,质谱是常用技术之一。该文介绍了蛋白质组学的概念、分类、研究技术以及常见蛋白质数据库,综述了基于质谱的蛋白质组学技术在真伪鉴别和品质检测方面的应用,涉及海鲜、肉制品、奶制品、保健食品及高附加值食品等多种食品,并对蛋白质组学的发展进行了展望。     

肽段化学衍生技术及其在质谱高灵敏度鉴定中的应用进展

鸟枪法串联质谱蛋白质鉴定是蛋白质组学研究中广泛采用的策略。然而,蛋白质组样品的高复杂性、宽动态范围分布使得低丰度肽段以及难于离子化肽段的质谱检测仍然存在着巨大的挑战。为了提高质谱检测灵敏度,通过化学衍生技术在多肽中引入易于离子化的小分子标签的方法获得了广泛关注。本文综述了近年来应用于多肽及其翻译后修饰的化学衍生试剂,侧重其在高灵敏度质谱分析中的应用进展,并展望了化学衍生技术的发展方向及其在蛋白质组学中的应用前景。     

NEWS

单细胞分析是实现生命科学精细化研究重要的技术方法之一。它可以使得我们了解复杂生命过程中细胞与细胞之间的相互作用,更加深入地揭示疾病细胞的分子机理。目前主要的单细胞分析方法包括光学分析和电化学分析。光学分析具有通量高的优点;但需要针对被分析分子设计特定探针实现高选择性的检测,无法构建统一化探针;而电化学分析则可利用氧化酶,转化各种被分析分子成具有电活性的活性氧分子,实现统一化的高时空分析;但该方法存在检测通量低的缺点,难以满足临床检测需求。在基金委重大科研仪器设备研制专项“单细胞时空分辨分子动态分析系统”的支持下,南京大学陈洪渊院士、江德臣副教授课题组系统的发展了单细胞电致化学发光检测平台,将单细胞电化学检测过程产生的电化学信息转化为光信号,从而有效的发挥了电化学检测和光学检测的优点,实现高通量的单细胞分析。该方法避免了传统光学方法需针对特定分子进行独特设计的不足,有望用于临床分析。     

单细胞质谱分析方法研究进展

不同的细胞个体之间具有差异性.为了如实地反映细胞在结构和功能上对生物系统的正常运转所起到的作用,就必须从单细胞水平上对细胞中物质的组成和含量进行分析研究.但是单细胞分析研究却由于细胞的极小体积、极多的物质种类、极少的物质含量以及不同物质间显著的浓度差异而一度受阻.质谱是一种很适合于单细胞分析的检测方法,它具有极高的灵敏度、多物质同时检测的能力以及对所感兴趣的分子进行结构鉴定的能力.不同的离子化方法对取样和前处理过程的要求也不同.从某种意义上来说,不同的离子化方法造就了不同的单细胞质谱分析方法.因此,本文从离子化方法学的角度对单细胞质谱分析方法进行了归纳和总结,并进一步讨论了单细胞质谱分析在未来的发展趋势.     

单细胞化学蛋白质组新方法研究

近年来,从系统生物学角度研究基因、蛋白质和代谢物,即各种组学研究,为发现生命现象的化学基础提供了全新手段。比如时下颇为火热的基因组测序,已经发展到单细胞水平。由于蛋白质组的复杂性,单细胞蛋白质组分析要困难得多。国际上经典的单细胞蛋白质组学研究的方法主要是流式细胞术和化学细胞术两种。前者由美国Nolan小组提出,对于揭示疾病的分子信号通路网络具有重要科学价值,但蛋白质功能性标记方法非常繁琐复杂、且原代细胞的消     

CZE-ESI-MS联用测定小肽混合物的研究

研究肽的分离行为、测定方法及测定条件对蛋白质组学研究具有重要意义 .毛细管电泳 ( CE)作为一种高效、快速的分离方法 ,样品用量少 ,已被广泛应用于生物领域中 ,尤其是小肽和蛋白质的分离分析 .质谱 ( MS)能够进行微量鉴定 ,并提供精确的分子量和结构信息 ,使其成为小肽和蛋白质检测和序列测定的强有力的支撑技术之一 [1～ 3] .其中 ,电喷雾 ( ESI)质谱作为一种软电离技术 ,易与常规的高分辨率分离方法如高效液相色谱、毛细管电泳等实现在线联用 ,具有分离效率高、检测灵敏度高和样品定性方便等特点 ,因而在小肽和蛋白质的测定中得到广…     

基于毛细管电泳技术的高灵敏度蛋白质组学技术发展

近年来,蛋白质组学技术在样品前处理、分离技术和质谱检测技术方面获得了快速发展,已经可以实现在几小时内对上万种蛋白的同时定性和定量分析。然而,目前的主流蛋白质组学技术仍无法满足极微量生物样品,尤其是单细胞样品的组学分析需求。毛细管电泳分离技术具有峰宽窄、柱效高、样品用量少等优势,是与高分辨质谱在线联用的理想选择之一。该文评述了集成化和在线样品前处理以及主流的纳升液相色谱-质谱联用系统在高灵敏度蛋白质组学分析领域的发展现状和挑战,认为该领域的重要技术挑战之一在于目前的纳升液相色谱分离已经无法完全匹配现代高分辨质谱超过40 Hz的超高扫描速度,从而导致质谱使用效率的降低。针对上述技术挑战,该文重点探讨了毛细管电泳-质谱联用技术的独特技术优势和潜在发展机遇,主要包括：（1）面向微量酶解多肽样品的高柱效毛细管电泳分离。通过采用毛细管电色谱可以进一步改善毛细管电泳柱容量不足的局限;（2）面向高灵敏度分析的无鞘液/鞘液接口开发;（3）高效毛细管电泳分离与高扫描速度质谱检测的协同化使用。总之,我们预期毛细管电泳-质谱联用技术的进一步发展有望在针对单细胞等超微量生物学样品的蛋白质组学分析中获得更广泛的应用。     

Use of monolithic supports in proteomics technology

An overview on the utilization of monoliths in proteomics technology will be given. Both silica- and polymer-based monoliths have broad use for microseparation of tryptic peptides in reversed-phase (RP) mode before identification by mass spectrometry (MS) or by MS/MS. For two-dimensional (2D) LC separation of peptides before MS or MS/MS analysis, a combination of ion-exchange, usually cation-exchange (CEX) chromatography with RP chromatography on monolithic supports can be employed. Immobilized metal ion affinity chromatography monoliths with immobilized Fe3+-ions are used for the isolation of phosphopeptides. Monoliths with immobilized affinity ligands are usually applied to the rapid separation of proteins and peptides. Miniaturized reactors with immobilized proteolytic enzymes are utilized for rapid on- or offline digestion of isolated proteins or protein mixtures prior to identification by LC-MS/MS. Monoliths also have broad potential for application in sample preparation, prior to further proteomic analyses. Monolithic supports with large pore sizes can be exploited for the isolation of nanoparticles, such as cells, organelles, viruses and protein aggregates. The potential for further adoption of monolithic supports in protein separation and enrichment of low abundance proteins prior to proteolytic digestion and final LC-MS/MS protein identification will be discussed.     

Novel liquid-chromatography columns for proteomics research

The enormous interest in proteomics research in recent years has inspired many developments in peptide chromatography. Different strategies have been developed to cope with the vast complexity of proteomics samples, trying to provide sufficient degree of separation to be able to exploit fully the potential of protein identification by mass spectrometry (MS). As reversed-phase liquid chromatography (RPLC) coupled to MS is still the method of choice for the analysis of protein digests, many efforts focus on the development of high-efficiency RP methods (e.g., monolithic columns and ultra-high-performance LC). This can also increase the speed and the sensitivity of the analysis of protein digests.As RPLC-MS alone is unlikely to provide sufficient resolution to unravel the composition of highly complex samples comprehensively, multidimensional methods will remain essential in proteome research. In this area, hydrophilic interaction chromatography (HILIC) seems to be a promising alternative to the traditional strong cation-exchange-based methods. Also, HILIC has found application in the analysis of post-translational modifications (e.g., phosphorylation and glycosylation).This review describes recent developments in LC methods for proteomics research, focusing on advances in column technology and the application of novel column materials. Illustrative examples show the possibilities of the new columns in proteomics research.     

基于不同提取方法的水稻叶片蛋白质组的二维液相色谱分离及高分辨质谱分析

建立了酚法提取-二维液相色谱分离-高分辨质谱分析水稻叶片蛋白质组的方法。水稻叶片蛋白质经过酚法提取,酶解肽段脱盐后用离线反相-反相二维液相色谱分离,然后用线性离子阱/静电场轨道阱组合式高分辨质谱分析,共鉴定到2712种蛋白质。比较了液相色谱分离系统（一维液相色谱与二维液相色谱）和水稻叶片蛋白质提取方法（酚法、十二烷基硫酸钠法（SDS法）和三氯乙酸/丙酮法（TCA/丙酮法））对鉴定蛋白质数量的影响,结果表明：在二维液相色谱条件下,酚法、SDS法和TCA/丙酮法鉴定到的蛋白质数目为2712、2415和1914,分别是一维液相色谱条件下鉴定到的蛋白质数目的2.7、2.5和1.9倍。二维液相色谱条件下,酚法鉴定到的蛋白质数目比SDS法和TCA/丙酮法分别多297和798。与SDS法和TCA/丙酮法相比,酚法不但鉴定到的蛋白质数量多,而且能够鉴定到一些极端蛋白质,如酸性、碱性及高等电点的蛋白质。此外,对二维液相色谱条件下3种蛋白质提取方法提取到的蛋白质进行生物学功能分类,发现3种方法鉴定到的蛋白质的功能存在互补性,但酚法鉴定到的蛋白质功能种类最多。该法为水稻蛋白质组学研究提供了技术支撑,同时也为其他作物的蛋白质组学研究技术提供重要的借鉴。     

Capillary electrophoresis-based separation techniques for the analysis of proteins

CE offers the advantages of high speed, great efficiency, as well as the requirement of minimum amounts of sample and buffer for the analysis of proteins. In this review, we summarize the CE-based techniques coupled with absorption, LIF, and MS detection systems for the analysis of proteins mostly within the past 5 years. The basic principle of each technique and its advantages and disadvantages for protein analysis are discussed in brief. Advanced CE techniques, including on-column concentration techniques and high-efficiency multidimensional separation techniques, for high-throughput protein profiling of complex biological samples and/or of single cells are emphasized. Although the developed techniques provide improved peak capacity, they have not become practical tools for proteomics, mainly because of poor reproducibility, low-sample lading capacity, and low throughput due to ineffective interfaces between two separation dimensions and that between separation and MS systems. In order to identify the complexities and dynamics of the proteomes expressed by cells, tissues, or organisms, techniques providing improved analytical sensitivity, throughput, and dynamic ranges are still demanded.     

Proteome profiling of human cerebrospinal fluid: exploring the potential of capillary electrophoresis with surface modified capillaries for analysis of complex biological samples

A bottom-up proteomic approach, based on capillary electrophoresis (CE) in combination with matrix- assisted laser desorption/ionization tandem time-of-flight mass spectrometry (MALDI-ToF/ToF MS), was used to analyze immunoaffinity depleted human cerebrospinal fluid (CSF) and compare it with a non-depleted sample. After enzymatic digestion and desalting, the tryptic peptides were separated by CE using PolyE-323 modified capillaries and fractionated off-line onto MALDI target plates for further analysis by MALDI-MS and MS/MS. The protein profile of the depleted sample was compared with non depleted CSF. Overall, 85 proteins were identified with 95% significance in both samples. The significance scores for proposed biomarkers, such as amyloid-like protein 1 precursor, could be increased up to 12 times after the depletion. Other proteins, often suggested to be related to neurodegenerative diseases, like amyloid beta A4 protein precursor, superoxide dismutase and apolipoprotein E precursor could only be found in the depleted CSF samples. The effect of a derivatization of tryptic peptides with 2- methoxy-4,5-dihydro-1H-imidazole reagent for protein identification with MS was also employed to increase the number of identified proteins and the sequence coverages. The results presented in this study illustrate the benefit of combining a sample pre-fractionation step and a label's ability to enhance the ionization efficiency with the potential of CE using PolyE-323 modified capillaries in the analysis of complex samples. The straight-forward approach that provides speed and simplicity resulting in high-resolution separations and low sample consumption represents an easily applicable separation technique that can serve as a complement to other currently existing analytical approaches needed in modern proteomic analysis of clinically relevant samples.     

Heart‐cut nano‐LC–CZE–MS for the characterization of proteins on the intact level

Multidimensional separation techniques play an increasingly important role in separation science, especially for the analysis of complex samples such as proteins. The combination of reversed‐phase liquid chromatography in the nanoscale and CZE is especially beneficial due to their nearly orthogonal separation mechanism and well‐suited geometries/dimensions. Here, a heart‐cut nano‐LC–CZE–MS setup was developed utilizing for the first time a mechanical 4‐port valve as LC–CE interface. A model protein mixture containing four different protein species was first separated by nano LC followed by a heart‐cut transfer of individual LC peaks and subsequent CZE–MS analysis. In the CZE dimension, various glycoforms of one protein species were separated. Improved separation capabilities were achieved compared to the 1D methods, which was exemplarily shown for ribonuclease B and its different glycosylated forms. LODs in the lower μg/mL range were determined, which are considerably lower compared to traditional CZE–MS. In addition, this study represents the first application of an LC–CE–MS system for intact protein analysis. The nano‐LC–CZE–MS system is expected to be applicable to various other analytical challenges.     

The effect and potential of using a temperature controlled separation column with ultra-high pressure microcapillary liquid chromatography/tandem mass spectrometry on proteomic analysis

The microcapillary liquid chromatography (μLC)/tandem mass spectrometry (MS/MS) system has become a prevailing analytical platform in proteomics. Typical proteomic studies aimed at proteome-wide identification of peptides and proteins rely heavily on producing an accurate and reproducible solvent-composition gradient throughout microcapillary separation columns to improve LC separation. With the recent advent of targeted proteomic approaches utilizing the LC retention time as a physicochemical parameter for peptides, high reproducibility of LC separation additionally becomes an important factor. In this study, column temperature elevation is utilized to improve reproducibility and separation efficiency of the μLC-MS/MS system. The simple incorporation of a semi-rigid gas line heater allowed precise control of the temperature of microcapillary columns longer than 70 cm, up to 60 °C. Tryptic enolase peptides were used as a standard sample to evaluate the effect of the controlled temperature elevation on the peptide separation efficiency and reproducibility. In addition to the increased reproducibility in peptide elution time due to the controlled column temperature, the temperature elevation resulted in a decrease in the column operation pressure, which, in turn, allowed a higher solvent flow-rate to be employed using the same LC pumps, leading to further improvements in the performance of μLC systems.