iTRAQ多重化学标记串联质谱技术在比较蛋白质组学中的应用

研究不同生理和病理条件下细胞内蛋白质的含量和状态变化是比较蛋白质组学的核心内容。要揭示上述动态过程往往需要进行多个样品的同步比较分析。近年来,在体内和体外同位素标记基础上,用多维液相色谱分离多肽,进而用串联质谱进行相对定量的分析方法已成为高通量比较蛋白质组研究的主要手段之一。该文就目前唯一一种可以进行四重蛋白质样品同步比较的iTRAQ标记-串联质谱分析技术进行综述。     

多维液相色谱分离技术在复杂蛋白质组学样品鉴定中的应用

目的：随着蛋白组学技术的发展,液相色谱-串联质谱的联用技术（液质联用）逐渐成为蛋白组学的主流技术。方法：通过结合各种不同原理的色谱分离类型,多维液相色谱分离技术能够极大的提高分离系统的峰容量,达到有效分离复杂程度很高的蛋白质组学样品的目的。结果：最广泛使用的多维液相色谱分离系统是离子交换色谱（IEX）和反相色谱（RP）的二维结合,近年来又发展出了分离能力更强的三维液相色谱分离系统,并且已经在蛋白质组学研究中得到了应用。结论：本文综述了多种多维液相色谱分离方法,在这些方法中,不同的分离原理的色谱类型被用于肽段或蛋白混合物的预分离中,有效促进了样品的充分分离,极大地提高了复杂样品的蛋白组学鉴定能力。     

稳定同位素标记试剂DiART在蛋白质组中的定量特征研究

等重同位素标记方法,如同位素标记相对和绝对定量(iTRAQ),可以对肽段进行化学标记,之后通过质谱分析得到的报告离子的强度信息而实现对肽段的定量.目前,这种标记技术在定量蛋白质组学研究中有广泛应用.DiART也是一种等重同位素标记方法,且与iTRAQ的定量原理类似,但是其化学结构组成与iTRAQ有所不同,因而其定量特征有其独特表现.本研究通过对DiART标记的简单蛋白样品、复杂蛋白样品以及复杂样品中目标蛋白的定量情况进行了分析,从而对DiART的定量特征进行了研究,并同时与iTRAQ进行了比较.结果表明,DiART方法在定量稳定性、准确性及动态范围方面均更具优势.     

同位素稀释法在绝对定量蛋白质组中的研究进展

绝对定量蛋白质组是指基于蛋白质组学方法对细胞、组织或体液中的蛋白质进行绝对量或浓度测定．目前,常用的绝对定量方法主要有基于同位素稀释法的蛋白质组学绝对定量方法和基于质谱数据统计分析的非标记方法．基于同位素稀释法的绝对定量方法是用已知量的同位素标记物对与其混合的样本蛋白质浓度进行测定．常见的同位素标记物包括：由AQUA法、QconCAT法产生的特异性水解肽段,由PSAQ法、Absolute SILAC法产生的标记蛋白和由PrESTs-SILAC法产生的蛋白抗原表位标签．由于同位素稀释法可以对蛋白质进行准确和精确定量,对于临床疾病的诊断和治疗具有明显的现实意义．本文对同位素稀释法在绝对定量蛋白质组中的研究进展及其优缺点和最新应用进行了评述．     

稳定同位素化学标记结合质谱技术在定量蛋白质组学中的应用

传统的蛋白质组定量策略主要是通过双向凝胶电泳来进行相对定量。由于该方法不能对相对分子质量极高或极低、等电点极酸或极碱和含量低的蛋白质以及膜蛋白质等进行有效分离和检测,所以已不能适应目前蛋白质组研究深入发展的需要。近年来,定量蛋白质组学的发展主要是以同位素亲和标签试剂为代表的、以质谱检测为核心的稳定同位素化学标记方法。稳定同位素化学标记结合质谱技术,使定量蛋白质组的分析更趋简单、准确和快速,具有良好的发展前景。本文对稳定同位素化学标记结合质谱技术在定量蛋白质组学中的研究进展进行了评述。     

高效液相色谱法对重组人甲状旁腺素相关肽的研究

针对重组人甲状旁腺素相关肽在反相柱的高效液相色谱中出现的两个峰,研究两个峰性质并对两个峰是由于一种物质形成了两种构象造成的加以讨论。采用了离子交换柱的高效液相色谱分析、电泳、高效液相色谱和质谱联用分析、SDS破坏小肽高级结构再进行反相柱的高效液相色谱分析、更换反相柱高效液相色谱分析中的流动相等方法,结果表明,从高效液相色谱分析和电泳分析来看,样品为纯品。同时推测两个峰是由于一种物质形成了两种不同的构象造成的,且两种构象可以在有酸性离子对试剂的情况下快速达到动态平衡。     

利用TMT标记结合2DLC-MS/MS技术对水牛卵母细胞体外成熟前后差异蛋白质组的分析

本试验利用TMT标记并结合二维高效液相色谱/串联质谱联用的研究策略对水牛卵母细胞成熟前后差异蛋白质组进行分析。试验首先收集水牛成熟前卵母细胞和成熟后卵母细胞,分别提取卵母细胞这两个时期的蛋白质,酶解蛋白后进行TMT标记,其中TMT-126标记成熟后的肽段,TMT-129标记成熟前的肽段,标记后采用强阳离子交换柱对酶解得到的肽段进行分离,接着进行nano LC分离,质谱分析采用在线连接电喷雾串联Orbitrap的方法,最后使用SEQUEST软件进行数据库搜索,采用生物信息学方法对鉴定得到的差异蛋白质进行初步分析。根据定量差异倍数≥2即认为蛋白表达存在差异,鉴定出卵母细胞成熟前高表达的蛋白有18种,成熟后高表达的蛋白有26种。对这些差异蛋白进行生物信息学分析表明,利用TMT标记并结合二维高效液相色谱/串联质谱联用的研究策略可以有效地分离和鉴定水牛卵母细胞成熟前后的蛋白质。本试验发现可能与水牛卵母细胞成熟相关的标志性蛋白:调控细胞凋亡蛋白(BCL2L10)、胎球蛋白(AHSG)、伴侣蛋白(Erp29),这可能为今后研究水牛卵母细胞成熟前后的蛋白质表达变化规律提供了试验依据。     

iTRAQ结合2D LC-MS/MS技术在草菇不同生长发育时期蛋白质组分析中的应用

【目的】旨在采用iTRAQ标记结合二维液相色谱串联质谱技术对草菇不同生长发育阶段的差异蛋白质组进行研究。【方法】首先将提取的草菇不同生长阶段蛋白样品进行SDS-PAGE分析,其次将经二维液相色谱串联质谱技术获取的串联质谱数据通过MASCOT软件搜库,之后对鉴定蛋白质数据进行了主成分分析(Principal componentanalysis,PCA)、层次聚类(Hierarchy clustering)分析、K-均值(K-means)聚类和GeneOntology(GO)注释分析。【结果】试验结果显示,共计获得2 335个不同肽段,鉴定到1 039个蛋白质,其中1 030个蛋白质具有定量信息。在子实体阶段中显著上调蛋白质64个,下调蛋白质150个。生物信息学分析表明,iTRAQ标记技术结合二维液相色谱串联质谱可对不同生长发育时期的草菇蛋白样品进行有效地分离和鉴定。【结论】这一研究结果为深入研究草菇乃至其他大型担子菌子实体形成和发育的分子机制提供借鉴。     

草菇子实体不同成熟阶段的比较蛋白质组学分析

采用iTRAQ标记结合二维液相色谱串联质谱技术对草菇不同成熟阶段的差异蛋白质组进行研究。首先将提取的草菇不同成熟阶段蛋白样品进行SDS-PAGE分析,其次将经二维液相色谱串联质谱技术获取的串联质谱数据通过MASCOT软件搜库,之后对鉴定蛋白质数据进行了KEGG代谢通路分析。试验共计获得2 335个不同肽段, 鉴定到1 039个蛋白质,其中1 030个蛋白质具有定量信息。与蛋形期相比,在伸长期和成熟期阶段显著上调蛋白质85个,下调蛋白质103个。KEGG代谢通路分析结果显示,草菇不同成熟阶段中的68个差异蛋白质可定位于4种伞菌目模式真菌（灰盖鬼伞、双色蜡蘑、可可丛枝病菌和裂褶菌）的45个不同生物代谢途径,全景展示出草菇成熟阶段差异表达蛋白质定位的代谢网络。结果表明,iTRAQ标记技术结合二维液相色谱串联质谱可对不同生长发育时期的草菇蛋白样品进行有效地分离和鉴定。     

iTRAQ技术及其在蛋白质组学中的应用

近年来随着蛋白质组学的迅速发展,其相应的方法学研究也取得了巨大的进步, 一系列新技术融入了蛋白质组学研究中,极大地促进了这门学科的发展.相对和绝对定量同位素标记(iTRAQ)技术与高度敏感性和准确性的串联质谱及多维液相色谱联用技术已成为蛋白质定性和定量研究的主要工具之一. 该技术可对复杂样本、细胞器、细 胞裂解液等样本进行相对和绝对定量研究,具有较好的定量效果、较高的重复性.由于其能够同时对多达8种样品进行标记分析,故在生命科学的各个领域得到了广泛的应用.本文对iTRAQ的原理、实验流程、优缺点及近几年的应用进展进行综述.     

Mass spectrometry-based glycoproteomic approach involving lysine derivatization for structural characterization of recombinant human erythropoietin

Lysine-containing peptides comprising glycosylation sites derived from recombinant human erythropoietin (rHuEPO) by trypsin or Lys-C and PNGase F dual digestion were derivatized with 2-methoxy-4,5-dihydro-1H-imidazole and its deuterated analogues. In the same reaction, under reducing conditions (beta-mercaptoethanol), cysteines were converted into methyl-cysteines and lysines into Lys-4,5-dihydro-1H-imidazole. Both modifications on cysteines and lysines simplified the CID-MS/MS spectra, while preserving the structural information by yielding y-series ions and improved the mass spectral signal intensity up to 25 times. Moreover, by this approach, the N-glycan occupation sites were unambiguously determined. O-Glycosylation sites as well as O-glycan structures were determined by a LC-MS/MS experiment carried out on dually digested rHuEPO. N-Glycan mixture purified on a graphitized carbon column using a newly developed method that extracted only sialylated carbohydrates was analyzed first using MALDI-TOF in negative linear ion mode with low mass accuracy but without interferences and metastabile ions and then a reflectron with high mass accuracy. After defining the precursor ions, we performed the nanoESI QTOF MS/MS analysis on N-glycans, mainly targeting the distinction between carbohydrates with sialylated antennae and those lacking sialic acid moieties.     

Highly efficient peptide separations in proteomics: Part 2: Bi- and multidimensional liquid-based separation techniques

Multidimensional liquid-based separation techniques are described for maximizing the resolution of the enormous number of peptides generated upon tryptic digestion of proteomes, and hence, reduce the spatial and temporal complexity of the sample to a level that allows successful mass spectrometric analysis. This review complements the previous contribution on unidimensional high performance liquid chromatography (HPLC). Both chromatography and electrophoresis will be discussed albeit with reversed-phase HPLC (RPLC) as the final separation dimension prior to MS analysis.     

HysTag--a novel proteomic quantification tool applied to differential display analysis of membrane proteins from distinct areas of mouse brain

A novel isotopically labeled cysteine-tagging and complexity-reducing reagent, called HysTag, has been synthesized and used for quantitative proteomics of proteins from enriched plasma membrane preparations from mouse fore- and hindbrain. The reagent is a 10-mer derivatized peptide, H(2)N-(His)(6)-Ala-Arg-Ala-Cys(2-thiopyridyl disulfide)-CO(2)H, which consists of four functional elements: i) an affinity ligand (His(6)-tag), ii) a tryptic cleavage site (-Arg-Ala-), iii) Ala-9 residue that contains four (d(4)) or no (d(0)) deuterium atoms, and iv) a thiol-reactive group (2-thiopyridyl disulfide). For differential analysis cysteine residues in the compared samples are modified using either (d(4)) or (d(0)) reagent. The HysTag peptide is preserved in Lys-C digestion of proteins and allows charge-based selection of cysteine-containing peptides, whereas subsequent tryptic digestion reduces the labeling group to a di-peptide, which does not hinder effective fragmentation. Furthermore, we found that tagged peptides containing Ala-d(4) co-elute with their d(0)-labeled counterparts. To demonstrate effectiveness of the reagent, a differential analysis of mouse forebrain versus hindbrain plasma membranes was performed. Enriched plasma membrane fractions were partially denatured, reduced, and reacted with the reagent. Digestion with endoproteinase Lys-C was carried out on nonsolubilized membranes. The membranes were sedimented by ultra centrifugation, and the tagged peptides were isolated by Ni(2+) affinity or cation-exchange chromatography. Finally, the tagged peptides were cleaved with trypsin to release the histidine tag (residues 1-8 of the reagent) followed by liquid chromatography tandem mass spectroscopy for relative protein quantification and identification. A total of 355 unique proteins were identified, among which 281 could be quantified. Among a large majority of proteins with ratios close to one, a few proteins with significant quantitative changes were retrieved. The HysTag offers advantages compared with the isotope-coded affinity tag reagent, because the HysTag reagent is easy to synthesize, economical due to use of deuterium instead of (13)C isotope label, and allows robust purification and flexibility through the affinity tag, which can be extended to different peptide functionalities.     

Linear and accurate quantitation of proenkephalin-derived peptides by isotopic labeling with internal standards and mass spectrometry

Proenkephalin (PE) represents the precursor protein of the active peptide neurotransmitter enkephalin. Quantitative analysis of peptides and proteins is an objective of mass spectrometry-based studies of biological systems and will be important for studying the proteolytic conversion of proproteins to active enkephalin and neuropeptides. The goal of this study was to define and optimize quantitation of different amounts of tryptic peptides derived from PE using light (H4, 4 hydrogens) and heavy (D4, 4 deuteriums) succinic anhydride for isotopic labeling of peptides analyzed by liquid chromatography-tandem mass spectrometry (LC-MS/MS). Comparisons were made between PE-derived peptides with and without internal standards. Importantly, incorporation of internal standards of known amounts of heavy isotope-labeled tryptic peptides of PE provided linear calibration plots with accurate quantitation. In contrast, comparison of light and heavy isotope-labeled peptides without internal standards produced variable and inaccurate nonlinear isotopic ratio comparisons of PE-derived peptides. These results demonstrate that use of internal standards composed of a defined amount(s) of standard peptides (PE-derived tryptic peptides) is necessary for high-quality linear quantitation of peptides by isotopic labeling and MS/MS.     

A metal-coded affinity tag approach to quantitative proteomics

The quantitative analysis of protein mixtures is pivotal for the understanding of variations in the proteome of living systems. Therefore, approaches have been recently devised that generally allow the relative quantitative analysis of peptides and proteins. Here we present proof of concept of the new metal-coded affinity tag (MeCAT) technique, which allowed the quantitative determination of peptides and proteins. A macrocyclic metal chelate complex (1,4,7,10-tetraazacyclododecane-1,4,7,10-tetraacetic acid (DOTA)) loaded with different lanthanides (metal(III) ions) was the essential part of the tag. The combination of DOTA with an affinity anchor for purification and a reactive group for reaction with amino acids constituted a reagent that allowed quantification of peptides and proteins in an absolute fashion. For the quantitative determination, the tagged peptides and proteins were analyzed using flow injection inductively coupled plasma MS, a technique that allowed detection of metals with high precision and low detection limits. The metal chelate complexes were attached to the cysteine residues, and the course of the labeling reaction was followed using SDS-PAGE and MALDI-TOF MS, ESI MS, and inductively coupled plasma MS. To limit the width in isotopic signal spread and to increase the sensitivity for ESI analysis, we used the monoisotopic lanthanide macrocycle complexes. Peptides tagged with the reagent loaded with different metals coelute in liquid chromatography. In first applications with proteins, the calculated detection limit for bovine serum albumin for example was 110 amol, and we have used MeCAT to analyze proteins of the Sus scrofa eye lens as a model system. These data showed that MeCAT allowed quantification not only of peptides but also of proteins in an absolute fashion at low concentrations and in complex mixtures.     

More sensitive and quantitative proteomic measurements using very low flow rate porous silica monolithic LC columns with electrospray ionization-mass spectrometry

The sensitivity of proteomics measurements using liquid chromatography (LC) separations interfaced with electrospray ionization-mass spectrometry (ESI-MS) improves approximately inversely with liquid flow rate (for the columns having the same separation efficiency, linear velocity, and porosity), making attractive the use of smaller inner diameter LC columns. We report the development and initial application of 10 microm i.d. silica-based monolithic LC columns providing more sensitive proteomics measurements. A 50-microm-i.d. micro solid-phase extraction precolumn was used for ease of sample injection and cleanup prior to the reversed-phase LC separation, enabling the sample volume loading speed to be increased by approximately 50-fold. Greater than 10-fold improvement in sensitivity was obtained compared to analyses using more conventional capillary LC, enabling e.g. the identification of >5000 different peptides by MS/MS from 100-ng of a Shewanella oneidensis tryptic digest using an ion trap MS. The low nL/min LC flow rates provide more uniform responses for different peptides, and provided improved quantitative measurements compared to conventional separation systems without the use of internal standards or isotopic labeling. The improved sensitivity allowed LC-MS measurements of immunopurified protein phosphatase 5 that were in good agreement with quantitative Western blot analyses.     

Protein identification assisted by the prediction of retention time in liquid chromatography/tandem mass spectrometry

Two-dimensional liquid chromatography (2D-LC) coupled on-line with electrospray ionization tandem mass spectrometry (2D-LC-ESI-MS/MS) is a new platform for analysis and identification of proteome. Peptides are separated by 2D-LC and then performed MS/MS analysis by tandem MS/MS. The MS/MS data are searched against database for protein identification. In one 2D-LC-ESI-MS/MS run, we obtained not only the structural information of peptides directly from MS/MS, but also the retention time of peptides eluted from LC. Information on the chromatographic behavior of peptides can assist protein identification in the new platform for proteomics. The retention time of the matching peptides of the identified protein was predicted by the hydrophobic contribute of each amino acid on reversed-phase liquid chromatography (RPLC). By using this strategy proteins were identified by four types of information: peptide mass fingerprinting (PMF), sequence query, and MS/MS ions searched and the predicted retention time. This additional information obtained from LC could assist protein identification with no extra experimental cost.     

Membrane protein identifications by mass spectrometry using electrocapture-based separation as part of a two-dimensional fractionation system

A two-dimensional (2D) separation method was used to decrease sample complexity in analysis of tryptic peptides from glomerular membrane proteins by tandem mass spectrometry (MS/MS). The first dimension was carried out by electrocapture (EC), which fractionates peptides according to electrophoretic mobility. The second dimension was reverse-phase liquid chromatography (RP-LC), in which EC fractions were further separated and analyzed online by MS/MS. Using this methodology, we now identify 102 glomerular proteins (57 membrane proteins). Many peptides were possible to observe and select for MS/MS only using the 2D approach. Others were detectable in both one-dimensional (1D, without the EC step) and 2D experiments but were selectable for sequence analysis only from the 2D separations because the decrease in complexity then gives time for the mass analyzer to select the peptide and switch to the MS/MS mode. A minority of the peptides were detectable only in the 1D mode (presumably because of handling losses), but at the end this did not decrease the number of proteins identified by the 2D separation. After a database search, the combination of EC and RP-LC MS/MS versus a 1D RP-LC MS/MS separation resulted in a threefold increase in the number of proteins identified and improved the sequence coverage in the identifications, bringing our proteome-identified glomerular proteins to 282.     

High-pH reversed-phase chromatography with fraction concatenation for 2D proteomic analysis

Orthogonal high-resolution separations are critical for attaining improved analytical dynamic range and protein coverage in proteomic measurements. High-pH reversed-phase liquid chromatography (RPLC), followed by fraction concatenation, affords better peptide analysis than conventional strong cation-exchange chromatography applied for 2D proteomic analysis. For example, concatenated high-pH RPLC increased identification of peptides (by 1.8-fold) and proteins (by 1.6-fold) in shotgun proteomics analyses of a digested human protein sample. Additional advantages of high-pH RPLC with fraction concatenation include improved protein sequence coverage, simplified sample processing and reduced sample losses, making this an attractive alternative to strong cation-exchange chromatography in conjunction with second-dimension low-pH RPLC for 2D proteomics analyses.     

Differential dimethyl labeling of N-termini of peptides after guanidination for proteome analysis

We describe an enabling technique for proteome analysis based on isotope-differential dimethyl labeling of N-termini of tryptic peptides followed by microbore liquid chromatography (LC) matrix-assisted laser desorption and ionization (MALDI) mass spectrometry (MS). In this method, lysine side chains are blocked by guanidination to prevent the incorporation of multiple labels, followed by N-terminal labeling via reductive amination using d(0),(12)C-formaldehyde or d(2),(13)C-formaldehyde. Relative quantification of peptide mixtures is achieved by examining the MALDI mass spectra of the peptide pairs labeled with different isotope tags. A nominal mass difference of 6 Da between the peptide pair allows negligible interference between the two isotopic clusters for quantification of peptides of up to 3000 Da. Since only the N-termini of tryptic peptides are differentially labeled and the a(1) ions are also enhanced in the MALDI MS/MS spectra, interpretation of the fragment ion spectra to obtain sequence information is greatly simplified. It is demonstrated that this technique of N-terminal dimethylation (2ME) after lysine guanidination (GA) or 2MEGA offers several desirable features, including simple experimental procedure, stable products, using inexpensive and commercially available reagents, and negligible isotope effect on reversed-phase separation. LC-MALDI MS combined with this 2MEGA labeling technique was successfully used to identify proteins that included polymorphic variants and low abundance proteins in bovine milk. In addition, by analyzing a mixture of two equal amounts of milk whey fraction as a control, it is shown that the measured average ratio for 56 peptide pairs from 14 different proteins is 1.02, which is very close to the theoretical ratio of 1.00. The calculated percentage error is 2.0% and relative standard deviation is 4.6%.