功能化磁性纳米材料在磷酸化肽富集中的应用

蛋白质磷酸化是最重要和最普遍的翻译后修饰之一。基于质谱的技术已成为分析蛋白质磷酸化的重要手段。然而,磷酸化肽固有的低丰度和电离效率以及由非磷酸化肽共存引起的严重抑制使得直接质谱分析仍然是一个挑战。为解决此问题,需在质谱分析前对磷酸化蛋白质进行选择性富集。磁性纳米材料具有良好的磁响应性,可以在外界磁铁的帮助下实现与溶液的迅速分离。功能化磁性纳米材料作为一种新型的分析技术已在蛋白质组学研究中得到广泛的应用。该文就近年来对磁性纳米粒子进行各种功能化修饰以提高其特异性吸附能力的吸附材料在磷酸化肽的富集方面的应用予以综述,并展望了功能化磁性纳米材料在磷酸化肽富集领域的应用前景。     

N-糖基化蛋白质组样品富集策略的研究进展

蛋白质的糖基化是生物体内重要的蛋白质翻译后修饰之一,但其丰度通常较低,糖基化蛋白质酶解肽段中仅有2%~5%为糖基化肽段,因此,为实现糖基化蛋白质组的深度覆盖分析,对糖基化蛋白质/肽段进行富集是非常必要的。该文对糖基化蛋白质组样品不同富集方法的原理、特点以及最新研究进展进行了综述,同时也对N-糖基化蛋白质组学富集策略的发展前景进行了展望。     

Development of core–shell structure Fe3O4@Ta2O5 microspheres for selective enrichment of phosphopeptides for mass spectrometry analysis

Protein phosphorylation is one of the most important post-translational modifications. Due to the dynamic nature and low stoichiometry of the protein phosphorylation, enrichment of phosphopeptides from proteolytic mixtures is often necessary prior to their characterization by mass spectrometry. Many metal oxides such as titanium dioxide and zirconium dioxide have been successfully applied to isolation and enrichment of phosphopeptides. Recently, niobium pentoxide was proved to have the ability for selective enrichment of phosphopeptides. Considering the proximity of tantalum to niobium, we supposed that Ta₂O₅ can be used as affinity probes for phosphopeptide enrichment. In the work, we synthesized Fe₃O₄@Ta₂O₅ magnetic microspheres with core–shell structure for selective enrichment of phosphopeptides. To demonstrate its ability for selective enrichment of phosphopeptides, we applied Fe₃O₄@Ta₂O₅ magnetic microspheres to isolation and enrichment of the phosphopeptides from tryptic digestion of standard proteins and real samples, and then the enriched peptides were analyzed by matrix-assisted laser desorption mass spectrometry analysis (MALDI-MS) or liquid chromatography coupled to electrospray ionization mass spectrometry (LC–ESI-MS). Experiment results demonstrate that Ta₂O₅ coated-magnetic microspheres show the excellent potential for selective enrichment of phosphopeptides.     

Application of polydopamine-coated nylon capillary-channeled polymer fibers as a stationary phase for mass spectrometric phosphopeptide analysis

Capillary-channeled polymer (C-CP) fibers are demonstrated as a selective stationary phase for phosphopeptide analysis via LC–MS. Taking advantage of the oxidative self-polymerization of dopamine under alkaline conditions, a simple system involving a dilute aqueous solution of 0.2% w/v dopamine hydrochloride in 0.15% w/v TRIS buffer, pH 8.5 was utilized to coat polydopamine onto nylon 6 C-CP fibers. Confirmation of the polydopamine coating on the fibers (nylon-PDA) was made through attenuated total reflection-FTIR (ATR-FTIR) analysis. Imaging using SEM was also performed to examine the morphology and topography of the nylon-PDA. Subsequent loading of Fe³⁺ to the nylon-PDA matrix was confirmed by SEM/energy dispersive X-ray spectroscopy (SEM/EDX). The Fe³⁺-bound nylon-PDA fibers packed in a microbore column format were tested in the off-line preconcentration of phosphopeptides from a 1:100 mixture of β-casein/BSA digests for MALDI-TOF analysis. The packed column was also installed onto an HPLC system as a platform for the online sample clean-up and enrichment of phosphopeptides from a 1:1000 mixture of β-casein/BSA protein digests that were determined by subsequent ESI–MS analysis.     

Preparation of magnetic polymer material with phosphate group and its application to the enrichment of phosphopeptides

As one of the most important post-translational modifications (PTM), reversible phosphorylation of protein is involved in many cellular processes. Enrichment and separation of phosphopeptides have become essential for large-scale identification of protein phosphorylation by mass spectrometry. In this work, five magnetic polymer materials with different numbers of phosphate groups were fabricated using a simple polymeric method and their abilities to enrich phosphopeptides were investigated. Our results showed that the enrichment efficiency is closely related to the number of phosphate groups attached to magnetic polymer sorbent. Under optimized condition (3% trifluoroacetic acid and 80% acetonitrile), magnetic polymer-particles with appropriate proportion of phosphate groups (Fe(3)O(4)@p(VPA-EDMA-1)-Zr(4+)) showed high performance for extracting phosphopeptides from complex peptides mixture of standard protein digestion. In this regard, a total of 988 unique phosphopeptides were successfully identified from proteolytic digestion of HeLa cell extracts by employing magnetic polymer-particles combined with nano-RPLC-MS/MS analysis.     

Development of phosphopeptide enrichment techniques for phosphoproteome analysis

Protein phosphorylation is one of the most biologically relevant and ubiquitous post-translational modifications. The analysis of protein phosphorylation is very challenging due to its highly dynamic nature and low stoichiometry. In this article, recent techniques developed for phosphoproteome analysis are reviewed with an emphasis on the new developments in this field in China. To improve the performance of phosphoproteome analysis, many novel methods, either by application of new separation mechanisms or by adoption of new separation materials, were developed to specifically enrich phosphopeptides from complex protein digests. A series of new materials, including nanostructure materials, magnetic materials, and monolithic materials, were applied to prepare immobilized affinity chromatography or metal oxide affinity chromatography to improve the performance of phosphopeptide enrichment. Besides, new software tools were also developed to validate phosphopeptide identification and predict kinase specific phosphorylation sites.     

Affinity and chemical enrichment strategies for mapping low‐abundance protein modifications and protein‐interaction networks

Protein post‐translational modifications and protein interactions are the central research areas in mass‐spectrometry‐based proteomics. Protein post‐translational modifications affect protein structures, stabilities, activities, and all cellular processes are achieved by interactions among proteins and protein complexes. With the continuing advancements of mass spectrometry instrumentations of better sensitivity, speed, and performance, selective enrichment of modifications/interactions of interest from complex cellular matrices during the sample preparation has become the overwhelming bottleneck in the proteomics workflow. Therefore, many strategies have been developed to address this issue by targeting specific modifications/interactions based on their physical properties or chemical reactivities, but only a few have been successfully applied for systematic proteome‐wide study. In this review, we summarized the highlights of recent developments in the affinity enrichment methods focusing mainly on low stoichiometric protein lipidations. Besides, to identify potential glyoxal modified arginines, a small part was added for profiling reactive arginine sites using an enrichment reagent. A detailed section was provided for the enrichment of protein interactions by affinity purification and chemical cross‐linking, to shed light on the potentials of different enrichment strategies, along with the unique challenges in investigating individual protein post‐translational modification or protein interaction network.     

Zirconium arsenate-modified magnetic nanoparticles: preparation, characterization and application to the enrichment of phosphopeptides

Phosphorylation, one of the most important post-translational modifications of protein, plays a crucial role in a large number of biological processes. Large-scale identification of protein phosphorylation by mass spectrometry is still a challenging task because of the low abundance of phosphopeptides and sub-stoichiometry of phosphorylation. In this work, a novel strategy based on the specific affinity of zirconium arsenate to the phosphate group has been developed for the effective enrichment of phosphopeptides. Zirconium arsenate-modified magnetic nanoparticles (ZrAs-Fe(3)O(4)@SiO(2)) were prepared by covalent immobilization of zirconium arsenate on Fe(3)O(4)@SiO(2) magnetic nanoparticles under mild conditions, and characterized by transmission electron microscope (TEM), Fourier transform infrared (FT-IR) spectroscopy, energy dispersive X-ray spectroscopy (EDX) and vibrating sample magnetometer (VSM). The prepared ZrAs-Fe(3)O(4)@SiO(2) was applied for the selective enrichment of phosphopeptides from the digestion mixture of phosphoproteins and bovine serum albumin (BSA). Our results demonstrated that the ZrAs-Fe(3)O(4)@SiO(2) magnetic nanoparticles possess higher selectivity for phosphopeptides and better capture capability towards multiply-phosphorylated peptides than commercial zirconium dioxide (ZrO(2)), which has been widely employed for the enrichment of phosphopeptides. In addition, endogenous phosphopeptides from human serum can be effectively captured by ZrAs-Fe(3)O(4)@SiO(2) magnetic nanoparticles. It is the first report, to the best of our knowledge, in which the zirconium arsenate-modified magnetic nanoparticles were successfully applied to the enrichment of phosphopeptides, which offers the potential application of this new material in phosphoproteomics study.     

Titanium-containing magnetic mesoporous silica spheres: effective enrichment of peptides and simultaneous separation of nonphosphopeptides and phosphopeptides

Protein phosphorylation is a common posttranslational modification, and involved in many cellular processes. Like endogenous peptides, endogenous phosphopeptides contain many biomarkers of preclinical screening and disease diagnosis. In this work, titanium-containing magnetic mesoporous silica spheres were synthesized and applied for effective enrichment of peptides from both tryptic digests of standard proteins and human serum. Besides, the enriched peptides can be further separated into nonphosphopeptides and phosphopeptides by a simple elution. First, titanium-containing magnetic mesoporous silica spheres were synthesized by a sol-gel method and found to have high surface area, narrow pore size distribution, and useful magnetic responsivity. Then, as the prepared material was used for selective capturing of phosphopeptides, it demonstrated to have higher selectivity than commercial titanium dioxide. Moreover, via combination of size-exclusion mechanism, hydrophobic interaction, and affinity chromatography, titanium-containing magnetic mesoporous silica spheres were successfully applied to simultaneously extract and separate nonphosphopeptides and phosphopeptides from standard protein digestion and human serum.     

Sequential Fe3O4/TiO2 enrichment for phosphopeptide analysis by liquid chromatography/tandem mass spectrometry

Protein phosphorylation regulates a wide range of cellular functions and is associated with signaling pathways in cells. Various strategies for enrichment of phosphoproteins or phosphopeptides have been developed. Here, we developed a novel sequential phosphopeptide enrichment method, using magnetic iron oxide (Fe₃O₄) and titanium dioxide (TiO₂) particles, to detect mono‐ and multi‐phosphorylated peptides. In the first step, phosphopeptides were captured on Fe₃O₄ particles. In a subsequent step, any residual phosphopeptides were captured on TiO₂ particles. The particles were eluted and rinsed to yield phosphopeptide‐enriched fractions that were combined and analyzed using liquid chromatography/tandem mass spectrometry (LC/MS/MS). The validity of this sequential Fe₃O₄/TiO₂ enrichment strategy was demonstrated by the successful enrichment of bovine α‐casein phosphopeptides. We then applied the sequential Fe₃O₄/TiO₂ enrichment method to the analysis of phosphopeptides in L6 muscle cell lysates and successfully identified mono‐ and multi‐phosphorylated peptides. Copyright © 2010 John Wiley & Sons, Ltd.     

Desalting of phosphopeptides by tandem polypyrrole-c18 reverse phase micropipette tip (TMTipPPY-C18) based on hybrid electrostatic, Π–Π stacking and hydrophobic interactions for mass spectrometric analysis

Desalting and concentration of peptides using reverse phase (RP) C18 chromatographic material based on hydrophobic interaction is a routine approach used in mass spectrometry (MS)-based proteomics. However, MS detection of small hydrophilic peptides, in particular, phosphopeptides that bear multiple negative charges, is challenging due to the insufficient binding to C18 stationary phase. We described here the development of a new desalting method that takes the unique properties of polypyrrole (PPY). The presence of positively charged nitrogen atoms under acidic conditions and polyunsaturated bonds in polypyrrole provide a prospect for enhanced adsorption of phosphopeptides or hydrophilic peptides through extra electrostatic and Π–Π stacking interactions in addition to hydrophobic interactions. In tandem with reversed phase C18 chromatographic material, the new type of desalting method termed as TMTip_PPY-C18 can significantly improve the MS detection of phosphopeptides with multiple phosphate groups and other small hydrophilic peptides. It has been applied to not only tryptic digest of model proteins but also the analysis of complex lysates of zebrafish eggs. The number of detected phosphate groups on a peptide ranged from 1 to 6. Particularly, polypyrrole based method can also be used in basic condition. Thus it provides a useful means to handle peptides that may not be detectable in acidic condition. It can be envisioned that the TMTip_PPY-C18 should be able to facilitate the exploration of large scale phosphoproteome.     

基于离心式富集装置的酪氨酸磷酸肽分析新方法

酪氨酸磷酸化及其相应激酶活性的研究在抗肿瘤药物靶点的研发中具有重要意义.由于酪氨酸磷酸化仅占蛋白质总磷酸化含量的不足0.1%,因此规模化的酪氨酸磷酸化鉴定面临着重大技术挑战.本研究构建了TiO2串联C18反相填料的离心式富集装置,结合抗体免疫沉淀法,建立了酪氨酸磷酸肽的富集策略.此新型富集装置由吸头、适配器和离心(EP)管组成,将TiO2富集磷酸肽和C18填料反相分离磷酸肽有机结合,以离心的方式进行样品的上样、清洗、洗脱和分离,再通过抗酪氨酸磷酸化抗体进一步特异性富集酪氨酸磷酸肽,从而实现了酪氨酸磷酸肽的高效富集和大规模质谱鉴定.通过离心式富集装置简化了实验步骤,减少了样品损失和人为因素干扰;而且离心式、平行化的样品处理方式可显著提高分析通量.将此策略成功用于小鼠肝脏蛋白质酪氨酸磷酸化肽段的富集和质谱鉴定,在5 mg鼠肝蛋白中共鉴定出967个酪氨酸磷酸化位点,对应545个蛋白质,显示了其在蛋白质组学研究中的应用潜力.     

An integrated procedure of selective injection, sample stacking and fractionation of phosphopeptides for MALDI MS analysis

Protein phosphorylation is one of the most important post-translational modifications (PTM), however, the detection of phosphorylation in proteins using mass spectrometry (MS) remains challenging. This is because many phosphorylated proteins are only present in low abundance, and the ionization of the phosphorylated components in MS is very inefficient compared to the non-phosphorylated counterparts. Recently, we have reported a selective injection technique that can separate phosphopeptides from non-phosphorylated peptides due to the differences in their isoelectric points (pI) [1]. Phosphorylated peptides from α-casein were clearly observed at low femtomole level using MALDI MS. In this work, further developments on selective injection of phosphopeptides are presented to enhance its capability in handling higher sample complexity. The approach is to integrate selective injection with a sample stacking technique used in capillary electrophoresis to enrich the sample concentration, followed by electrophoresis to fractionate the components in preparation for MALDI MS analysis. The effectiveness of the selective injection and stacking was evaluated quantitatively using a synthetic phosphopeptide as sample, with an enrichment factor of up to 600 being recorded. Next, a tryptic digest of α-casein was used to evaluate the separation and fractionation of peptides for MALDI MS analysis. The elution order of phosphopeptides essentially followed the order of decreasing number of phosphates on the peptides. Finally, to illustrate the applicability, the integrated procedure was applied to evaluate the phosphorylation of a highly phosphorylated protein, osteopontin. Up to 41 phosphopeptides were observed, which allowed us to examine the phosphorylation of all 29 possible sites previously reported [2]. A high level of heterogeneity in the phosphorylation of OPN was evident by the multiple-forms of variable phosphorylation detected for a large number of peptides.     

磷酸化蛋白质组学中的分离富集方法研究进展

蛋白质的磷酸化是一种可逆性的翻译后修饰,在细胞的增值、分化、信号转导以及转录与翻译调控、蛋白质复合体的形成、蛋白质降解等方面发挥着极为重要的作用.因此磷酸化蛋白的鉴定成为翻译后修饰研究的重要内容.但由于磷酸化蛋白的丰度较低, 难以用质谱直接检测.为了解决这个问题,改善质谱对磷酸肽的信号响应, 需要对磷酸化蛋白质或磷酸肽进行富集.本文系统地介绍了磷酸化蛋白组学研究中应用较为广泛和最新建立的各种分离富集方法的原理、特点、应用研究进展,包括抗体富集法、激酶特异富集法、亲和富集法、化学修饰法、多种色谱分离富集方法以及MALDI靶盘富集法.     

肽段反相色谱保留时间预测算法及其在蛋白质鉴定中的应用

液相色谱-质谱(LC-MS)联用是当今规模化蛋白质鉴定的主流技术。肽段在反相液相色谱(RPLC)中的保留时间主要是由肽段的理化性质和LC条件(固定相、流动相)决定的。可以通过分析肽段的理化性质,并量化它们对肽段色谱行为的影响来预测保留时间。预测结果可以用于帮助提高蛋白质鉴定的数量和可信度,也可用于肽段的翻译后修饰等研究。现在已有的保留时间预测算法主要有保留系数法和机器学习法两大类,得到的预测保留时间与实际保留时间相关系数可达到0.93。随着色谱和质谱技术的不断发展,肽段色谱行为的稳定性和重现性越来越好,保留时间预测结果也越来越准确。预测肽段保留时间将成为提高蛋白质鉴定结果的重要技术手段之一。     

Enrichment of phosphopeptides using bare magnetic particles

Magnetic iron(II, III) oxide (magnetite, Fe(3)O(4)) nanoparticles were used to selectively enrich phosphopeptides from tryptic digests of bovine beta-casein and from tryptic digest mixtures containing bovine beta-casein, cytochrome c, bovine serum albumin, and horse heart myoglobin. The magnetic property of the particles permits an easy and speedy enrichment process. No enrichment of phosphopeptides was observed from ferric magnetic iron(III) oxide (Fe(2)O(3)) nanoparticles. These data collectively demonstrate that the enrichment of phosphopeptides using magnetic iron(II, III) oxide nanoparticles is a practical method for the selective analysis of phosphopeptides and could be helpful in isolating and analyzing phosphorylated peptides from complex biological samples.     

Phosphate-functionalized magnetic microspheres for immobilization of Zr ions for selective enrichment of the phosphopeptides

In this work, we developed phosphate functionalized magnetic Fe₃O₄@C microspheres to immobilize Zr⁴⁺ ions for selective extraction and concentration of phosphopeptides for mass spectrometry analysis. Firstly, we synthesized Fe₃O₄@C magnetic microspheres as our previous work reported. Then, the microspheres were functionalized with phosphate groups through a simple hydrolysis reaction using 3-(trihydroxysilyl)propyl methylphosphate. And the Zr⁴⁺ ions were immobilized on phosphate-functionalized magnetic microspheres by using phosphate chelator. Finally, we successfully employed Zr⁴⁺-phosphate functionalized magnetic microspheres to selectively isolate the phosphopeptides from tryptic digests of standard protein and real samples including rat brain. All the experimental results demonstrate the enrichment efficiency and selectivity of the method we reported here.     

Use of Sulfonates as Desorption Agents for Phosphopeptide Elution from an Anion-exchange Material

In general, phosphopeptides are specifically adsorbed to the surface of the material at the initial step of phosphopeptide enrichment methods. Thus, nonphosphopeptides can be removed from the media by following the appropriate washing steps. After sufficient washing, the phosphopeptides are eluted from the surface of the material completely for further analysis. Performing the elution of phosphopeptides fully in the enrichment step is very important in terms of determining the whole phosphoproteome profile of a sample by subsequent mass spectrometric analysis. Materials containing anion exchanger groups such as amines on the surface can be used as a selective stationary phase in phosphopeptide enrichment methods. Positively charged groups on the surface of this type of material interact with the phosphate groups of phosphopeptides through electrostatic interactions. Such interactions can be basically manipulated by changing the pH of the medium or replacing the salts present in the solution. Phosphopeptides attached to the surface of anion-exchange materials may be displaced with the addition of highly acidic compounds such as sulfonates to the enrichment medium. Here, we used various sulfonates as desorption agents for the elution of retained phosphopeptides from the surface of an anion-exchange material. We found that differences in the chemical structures and properties of the sulfonates remarkably affected phosphopeptide retrieval from the anion-exchange material.     

Enrichment and desalting of tryptic protein digests and the protein depletion using boron nitride

Sample preparation still remains a great challenge in modern bioanalysis and the interest in new efficient solid phase extraction (SPE) materials still remains high. In this work, hexagonal boron nitride (h-BN) is introduced as a new SPE material for the isolation and enrichment of peptides. The h-BN is isoelectronic and structurally similar to graphite. It has remarkable properties including good thermal conductivity, excellent thermal and chemical stability and a better oxidation resistance than graphite. BN attracts increasing interest because of its wide range of applicability. In the present work, the great potential of h-BN, as a new SPE-material, on the enrichment, preconcentration and desalting of tryptic digest of model proteins is demonstrated. A special attention was dedicated to the efficient enrichment of hydrophilic phosphopeptides. Two elution protocols were developed for the enrichment of peptides compatible for subsequent MALDI-MS and ESI-MS analysis. In addition, the recoveries of 5 peptides and 3 phosphopeptides with wide range of pI values utilizing h-BN materials with different surface areas were investigated. 84–106% recovery rate could be achieved using h-BN materials. The results were compared with those obtained using graphite and silica C18 under the same elution conditions, and lower recoveries were obtained. In addition, h-BN was found to have a capability of protein depletion, which is requisite for the peptide profiling.     

Facile fabrication of hydrophilic PAA-Ti/TiO2 nanocomposite for selective enrichment and detection of phosphopeptides from complex biological samples

Highly selective enrichment of trace phosphorylated proteins or peptides from complex biological samples is of profound significance for the discovery of disease biomarkers in biological systems. In this study, a novel affinity material has been synthesized to improve the enrichment specificity for phosphopeptides by using PAAS as coupling molecule. In the resulting materials, highly abundant titanium is available for selective enrichment of phosphopeptides, with plenty of carboxylate groups that can inhibit nonspecific adsorption. The enrichment results demonstrated that the hydrophilic PAA-Ti/TiO₂ composite possesses excellent selectivity for phosphopeptides even at a very low molar ratio of phosphopeptides/non-phosphopeptides (1:1000), extreme sensitivity (the detection limit was at the fmol level), and high recovery of phosphopeptides (as high as 78%). Moreover, the as-prepared nanocomposite provides effective enrichment of phosphopeptides from real samples (mouse liver), showing great potential in the detection of low-abundance phosphopeptides in biological samples.