反相高效液相色谱双梯度洗脱分离肽混合物及质谱分析

复杂肽段混合物的有效分离是高覆盖率地鉴定蛋白质混合物的前提。“鸟枪法”(Shotgun)蛋白质组学研究策略通常采用蛋白酶切、二维液相色谱-串联质谱分析肽段混合物从而鉴定蛋白质,其中高效率地分离肽段混合物是关键步骤之一。本文通过pH梯度结合有机溶剂梯度的反相高效液相色谱(RP-HPLC)进行一维液相色谱分离,按等时间间隔收集馏分并将一个梯度的前段的一个馏分与后段一个馏分混合,然后进行纳升级液相色谱-质谱联用(nanoRPLC-MS/MS)分析。将该方法应用于酵母蛋白质的分离和鉴定,实验结果为: 与常规的强阳离子色谱-反相液相色谱-质谱分离鉴定方法相比,采用pH梯度结合有机相梯度的RP-HPLC-RPLC-MS分离鉴定方法多鉴定到567个酵母蛋白质(簇,含有3035个唯一肽段);其中鉴定到肽段的pI分布范围为3.42～12.01,相对分子质量范围为587.67～3499.79;蛋白质的pI分布范围为3.82～12.19,相对分子质量范围为3446.55～432905。该结果表明这种方法在复杂体系蛋白质组分离鉴定中具有明显的优势,在蛋白质组学研究中有较好的应用前景。     

亲水作用-反相二维液相色谱串联质谱法鉴定水稻蛋白质

建立了亲水作用-反相二维液相色谱串联质谱分析水稻叶片蛋白质组学的方法。利用标准肽段系统分析了液相色谱流动相酸碱度对二维亲水作用-反相色谱系统正交性的影响。结果表明,第一维亲水作用色谱在碱性(pH 9.3)和第二维反相色谱在酸性(pH 3.3)的条件下,正交性最佳(R~2=0.34113)。在此基础上,结合馏分收集技术进一步评价了本测试系统在水稻叶片蛋白质分析中的正交性。结果表明,在所有馏分收集组分中,鉴定次数小于2次的水稻叶片肽段占总肽段数目的 50%以上,且一维液相色谱馏分收集的肽段在第二维色谱及质谱分离分析中,可以较好地分布在不同时间段的洗脱窗口,表明本研究建立的亲水作用-反相二维液相色谱串联质谱结合馏分收集技术在复杂水稻叶片蛋白质分离鉴定中可提供良好的的分离正交性。结合水稻蛋白质数据库检索,共鉴定出207345个肽段,归属于2930个蛋白质簇。     

疑似蛇毒液样品的纳升级超高效液相色谱-高分辨质谱分析鉴定

针对5个疑似蛇毒毒液及其沾染样品,基于纳升级超高效液相色谱-四极杆-静电场轨道阱高分辨质谱（Nano LC-MS/HRMS）技术,结合尺寸排阻色谱分离,建立了一种蛋白质种类及物种归属的严格鉴定方法。5个样品经尺寸排阻色谱分离后均得到3个洗脱峰,分别冻干后以胰蛋白酶进行溶液内酶解处理并进行液相色谱-高分辨质谱分析鉴定。首先采用全扫描-数据依赖型MS/MS（Full MS/dd MS²）采集模式对样品中的肽段信息进行非靶向采集,依次与Swiss-Prot、蛇亚目（Serpentes）、游蛇科（Colubroidea）、眼镜蛇科（Elapidae）、眼镜蛇亚科（Elapinae）、眼镜蛇属（Naja）蛋白质数据库逐级收缩比对;再筛选符合肽谱匹配度、肽段错误发现率小于1%和特征肽段数目大于等于2的蛋白质,共鉴定到32种蛋白质均来自中华眼镜蛇（Naja atra）,可归属于Naja atra的10个家族,主要为三指毒素、金属蛋白酶、磷脂酶A2等。最后,采用平行反应监测模式选取每种蛋白质的两条特征肽段进行靶向验证,当两条特征肽段均满足“至少75%的y⁺和b⁺离子的Δm/z小于5 ppm”时,方认为鉴定到了样品中的某一蛋白质。最终鉴定出5个样品均含有Naja atra蛇毒。此鉴定方法研究系统、严格,可为蛇毒中毒司法鉴定以及毒药物研究等提供有效的技术支持。     

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。     

多维离子交换色谱分离和串联质谱鉴定在小鼠肝脏膜蛋白质组分析中的应用

膜蛋白质在变性剂作用下能够较充分地溶解。根据这一特点,我们试图在变性剂溶液中采用串联离子交换色谱法分离小鼠肝脏膜蛋白质。将小鼠肝脏膜蛋白质溶解于含有4 mol/L尿素,20 mmol/L三羟甲基氨基甲烷(Tris)-盐酸缓冲液(pH 9.0)中,用Q-Sepharose FF和Sephacryl S-200HR树脂组成的色谱柱结合大部分溶解的膜蛋白质,然后采用氯化钠线性梯度洗脱蛋白质,分步收集后采用十二烷基硫酸钠-聚丙烯酰胺凝胶电泳(SDS-PAGE)进一步分离洗脱组分的蛋白质。利用胶内胰蛋白酶消化技术将SDS-PAGE胶内分离的蛋白质降解为相应的肽段,然后以反相高效液相色谱分离和离子阱质谱仪鉴定肽段。根据文献报道和蛋白质的功能分类,在所鉴定的392个蛋白质中有306个可能为膜蛋白质或膜结合蛋白质。蛋白质的疏水性计算表明,GRAVY(grand average of hydropathicity)得分大于或等于0.00的蛋白质有83个。综上所述,我们有理由认为本实验方法基本符合小鼠肝脏膜蛋白质组学研究的要求。     

基于在线二维色谱的不同生长时期鹿茸的比较蛋白质组分析

建立了基于在线二维弱阴离子交换色谱-反相液相色谱(2D-WAX-RPLC)的蛋白质分离系统,并用于不同生长时期鹿茸的比较蛋白质组分析。以5种标准蛋白质的混合物为样品,考察了系统的重现性。通过改变标准蛋白质之间的浓度比,研究了该系统进行蛋白质相对定量的能力。在此基础上,针对4个不同生长时期的鹿茸样品,分别采用5种不同的方法进行蛋白质提取,经2D-WAX-RPLC分离后,收集各生长时期对应蛋白质的峰高最大比超过2的组分。酶解后,采用微柱反相液相色谱-串联质谱(μRPLC-MS/MS)进行肽段的分离鉴定;共从9个差异蛋白质峰中鉴定到了22个差异蛋白质。研究结果表明,利用基于蛋白质水平的在线二维液相色谱分离技术找寻差异蛋白质,具有重现性好、自动化程度高等优点,可用于开展比较蛋白质组学的研究。     

序言

色谱柱是色谱分离分析的“心脏”，液相色谱技术的每一次重大进展都与分离固定相的突破密切相关。如上世纪70年代末期高效液相色谱技术的建立和90年代初期“灌流色谱”（Perfusion Chromatography）的发展都是基于多孔硅胶和“穿透孔”分离固定相的发展。近年来，基于特殊孔结构的1．5～2．0μm高强度复合材料的制备成功地催生了超高效液相色谱（UPLC）分离技术，而整体柱材料作为新一代的分离介质，已成为色谱领域广泛研究的前沿课题之一，并已经在样品预处理、手性分离、生物分离分析等领域获得十分广泛的应用。我国色谱研究工作者在多孔硅胶固定相、手性分离固定相、亲和色谱固定相和整体柱固定相等研究领域都取得了重大的进展，有些方面的研究工作已达到或领先于国际先进水平。     

高效液相色谱-串联质谱法测定肉制品和调味料中7种水产品过敏原

基于高效液相色谱-串联质谱系统建立了食品中水产品过敏原的快速筛查和定量检测方法。样品经蛋白质提取、纯化、胰蛋白酶解后，利用超高效液相色谱-四极杆/静电场轨道阱高分辨质谱（UPLC-Q/Exactive-HRMS）结合ProteinPilot软件，基于母离子和碎片离子谱分析，实现蛋白质和多肽的鉴定。再通过基本局部比对搜索工具（BLAST）与Uniprot数据库对比分析，筛选出南美白虾、大闸蟹、青蟹、金枪鱼、大西洋鲑鱼的7种过敏原蛋白的30个特征肽。利用高效液相色谱-三重四极杆质谱（UPLC-QqQ-MS）系统对特征肽进行验证和多反应监测（MRM）定量研究。结果表明，该方法在5~250 mg/kg范围内线性关系良好，检出限为2~3.5 mg/kg，平均回收率为88.7%~110.2%。该方法重现性好，通量高，可应用于肉制品和调味料中7种过敏原的快速筛查和定量分析。     

多维液相色谱-质谱用于酶解猪血蛋白中活性肽的研究

以强阳离子交换柱（SCX）为一维色谱柱，反相柱（RP）为二维色谱柱，采用在线捕集接口形式，通过10通阀连接一、二维色谱柱，构建了二维液相色谱分离系统。将该系统用于酶解猪血蛋白中对血管紧缩素Ⅰ转移酶（ACE）具有活性抑制作用的肽进行分离、鉴定，共检测出104个组分。收集一维馏分，离线注入LC—MS，鉴定出其中含有SAL、DKF、ESF、STVL及FESF5个小肽。     

基于共价色谱分离的含半胱氨酸肽段富集策略

多维色谱分离、串联质谱分析技术已在蛋白质组研究中得到广泛应用。然而生物样品的蛋白质以及全酶切肽段具有高度的复杂性,这严重干扰了蛋白质高通量、规模化的分析。通过标签肽段富集进行样品预分离可以降低体系的复杂程度。本文建立了一种基于共价色谱技术选择性分离富集含半胱氨酸肽的方法,从而降低了样品体系的复杂程度。首先以牛血清白蛋白(BSA)的酶切肽段为模型,对富集条件进行了优化和考察,并在此基础上通过5种蛋白质酶切肽段混合物的富集对该方法进行了验证。结果证明此方法的重现性好,富集效率高,富集特异性好,能有效地富集鉴定含半胱氨酸肽段。所建立的方法在复杂体系的蛋白质组研究中具有广泛的应用前景,为复杂样品的蛋白质高通量、自动化、规模化鉴定和定量研究提供了实用技术。     

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.     

Ion-pair Reversed-phase×Low-pH Reversed-phase Two-dimensional Liquid Chromatography for In-depth Proteomic Profiling

High-resolution liquid chromatography separation is essential to in-depth proteomic profiling of complex biological samples. Herein, we established an ion-pair reversed-phase×reversed-phase two-dimensional liquid chromatography (IPRP×RP 2DLC) strategy for comprehensive proteomic analysis. Both RPLC separation dimensions were performed at low pH, with trifluoroacetic acid(TFA) and formic acid(FA) as mobile phase addictive, respectively. As the good separation resolution offered by ion-pairing effect of TFA, the fractionation efficiency was greatly improved with 74.0% peptides identified in just one fraction. Comparing with conventional high pH RP fractionation, the overall separation rate of IPRP was about 1.6 times that of high-pH RP, which increased the number of identified peptides by 21%. Further, 2169 proteins and 8540 peptides were confidently identified from crude serum sample by our IPRP×RP 2DLC strategy, exhibiting great potential in clinical proteomics in the future.     

反相高效液相色谱/基质辅助激光解吸电离飞行时间质谱 分离鉴定螺蛳血管紧张素转换酶抑制肽

运用反相高效液相色谱(RP-HPLC)对酶解螺蛳腹足肌得到的血管紧张素转换酶(ACE)抑制肽进行两步分离提纯,第一步主要得到8个组分;选取其中活性最高的组分进一步分离,得到2个组分,其中活性较高组分的ACE半抑制浓度为43.5 μmol/L,基本为单一肽组分。对提纯的组分分别使用高效液相色谱/电喷雾离子质谱法(HPLC/ESI-MS)和基质辅助激光解吸电离飞行时间质谱法(MALDI-TOF MS)进行分析,同时结合氨基酸组成分析结果,最终得到的肽链一级结构为Lys-Glu-Ile-Trp(KEIW),符合已知的高活性ACE抑制肽的结构规律。经过对两种方法分析过程的比较,认为ESI-MS可以得到多方面的信息,但无法确定肽的序列;MALDI-TOF MS可以得到精确的二级质谱图(m/z精确至0.0001),从而可以得到确定的肽的序列。     

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。     

High-efficiency high performance liquid chromatographic analysis of red wine anthocyanins

The analysis of anthocyanins in natural products is of significant relevance in recent times due to the recognised health benefits associated with their consumption. In red grapes and wines in particular, anthocyanins are known to contribute important properties to the sensory (colour and taste), anti-oxidant- and ageing characteristics. However, the detailed investigation of the alteration of these compounds during wine ageing is hampered by the challenges associated with the separation of grape-derived anthocyanins and their derived products. High performance liquid chromatography (HPLC) is primarily used for this purpose, often in combination with mass spectrometric (MS) detection, although conventional HPLC methods provide incomplete resolution. We have previously demonstrated how on-column inter-conversion reactions are responsible for poor chromatographic efficiency in the HPLC analysis of anthocyanins, and how an increase in temperature and decrease in particle size may improve the chromatographic performance. In the current contribution an experimental configuration for the high efficiency analysis of anthocyanins is derived using the kinetic plot method (KPM). Further, it is shown how analysis under optimal conditions, in combination with MS detection, delivers much improved separation and identification of red wine anthocyanins and their derived products. This improved analytical performance holds promise for the in-depth investigation of these influential compounds in wine during ageing.     

Shotgun proteomic analysis of microdissected postmortem human pituitary using complementary two-dimensional liquid chromatography coupled with tandem mass spectrometer

The pituitary is responsible for multiple homeostatic functions including metabolism, growth and reproduction. Proteome analysis offers an efficient approach for a comprehensive analysis of pituitary protein expression. The pituitary is usually acquired from postmortem specimens, which may potentially affect the proteome profile by proteolysis. The aim of this study was to determine whether the postmortem pituitary could be used in proteomic analysis combining with Laser capture microdissection (LCM). Digested peptides from LCM captured prolactin (PRL) cells were separated by two dimensional-nanoscale liquid chromatography (2D-nanoLC/MS) and characterized by tandem mass spectrometry (MS). All MS/MS spectrums were searched by SEQUEST and a proteome of 1660 proteins was identified. Category analysis of the proteome revealed an extensive unbiased access to cell component proteins with diverse functional characteristics. The results demonstrated the ability of using 2D-nanoLC/MS to perform sensitive proteomic analysis on limited protein quantities through microdissection. Detailed comparisons between the proteome in question and the one derived from the prolactinoma controls at peptide and protein levels indicated that the two proteomes had similar characters. Overall, our results revealed for the first time the possibility of use of postmortem human pituitary for proteomic research which is important for further studies on disease biomarker identification and molecular mechanisms of prolactinoma tumorigenesis.     

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。     

Direct ampholyte-free liquid-phase isoelectric peptide focusing: application to the human serum proteome

In this study, we utilized a multidimensional peptide separation strategy combined with tandem mass spectrometry (MS/MS) for the identification of proteins in human serum. After enzymatically digesting serum with trypsin, the peptides were fractionated using liquid-phase isoelectric focusing (IEF) in a novel ampholyte-free format. Twenty IEF fractions were collected and analyzed by reversed-phase microcapillary liquid chromatography (microLC)-MS/MS. Bioinformatic analysis of the raw MS/MS spectra resulted in the identification of 844 unique peptides, corresponding to 437 proteins. This study demonstrates the efficacy of ampholyte-free peptide autofocusing, which alleviates peptide losses in ampholyte removal strategies. The results show that the separation strategy is effective for high-throughput characterization of proteins from complex proteomic mixtures.     

Low‐molecular‐weight color pI markers to monitor on‐line the peptide focusing process in OFFGEL fractionation

High‐throughput mass spectrometry‐based proteomic analysis requires peptide fractionation to simplify complex biological samples and increase proteome coverage. OFFGEL fractionation technology became a common method to separate peptides or proteins using isoelectric focusing in an immobilized pH gradient. However, the OFFGEL focusing process may be further optimized and controlled in terms of separation time and pI resolution. Here we evaluated OFFGEL technology to separate peptides from different samples in the presence of low‐molecular‐weight (LMW) color pI markers to visualize the focusing process. LMW color pI markers covering a large pH range were added to the peptide mixture before OFFGEL fractionation using a 24‐wells device encompassing the pH range 3–10. We also explored the impact of LMW color pI markers on peptide fractionation labeled previously for iTRAQ. Then, fractionated peptides were separated by RP_HPLC prior to MS analysis using MALDI‐TOF/TOF mass spectrometry in MS and MS/MS modes. Here we report the performance of the peptide focusing process in the presence of LMW color pI markers as on‐line trackers during the OFFGEL process and the possibility to use them as pI controls for peptide focusing. This method improves the workflow for peptide fractionation in a bottom‐up proteomic approach with or without iTRAQ labeling.