毛细管电泳质谱联用技术测定肽和蛋白质混合物

以血管紧张素Ⅰ、Ⅱ、Ⅲ、P-物质和生长激素抑制剂混合物为测定对象,研究了未涂层柱、线性聚丙烯酰胺(LPA)涂层柱和胺涂层柱对毛细管电泳分离肽类混合物的影响.结果表明:适合质谱测定的缓冲液不能在未涂层柱上有效地分离5种肽类混合物,而pH为5.O和4.5的NH₄Ac缓冲液却能在LPA涂层柱和胺涂层柱上很好地分离上述物质.用CE-ESI-MS法分离鉴定了5种生物活性肽和蛋白质混合物中的肌红蛋白、碳酸酐酶Ⅱ,实测了促红细胞生成素(EPC))的胰酶消解肽图,并对CE-MS联用测定中的影响因素进行了讨论.     

表达蛋白质质谱分析

对基因编码的蛋白质进行系统分析可以为注释基因组信息和研究疾病发生机理提供参考.质谱因其高通量、高灵敏度和高精度等特点成为蛋白质表达谱研究的核心技术.过去10年,质谱技术的发展大大促进了蛋白质表达谱的研究.本文综述了蛋白质表达谱的定性和定量研究进展,并展望了进一步的研究方向.     

基于质谱的DNA序列测定进展

对质谱ＤＮＡ序列测定的各种技术的原理、进展，面临的困难以及发展的前景作了评述。     

电喷雾质谱在寡糖序列分析中的应用

选取具有不同结构特征的N-糖链、硫酸软骨素寡糖、人乳寡糖以及海洋来源的壳寡糖、褐藻胶寡糖、卡拉胶寡糖和硫酸岩藻寡糖等,对电喷雾质谱在寡糖的主链序列、分支位点、硫酸基取代位置确定、单糖组成和聚合度分析等方面的应用技术及碎片离子的断裂规律进行了总结.根据相邻同类碎片离子之间的质荷比差值可初步判断寡糖的单糖组成类型;通过与色谱分离技术联用或衍生化方法可提高寡糖的分辨率和离子化效率,并测得寡糖的分子量及聚合度;借助串联质谱及对寡糖还原端的特异性标记,可获得寡糖的还原端残基和部分序列信息;根据寡糖产生的特征碎片离子及其丰度大小可判断残基的特定位置和类型.另外,寡糖的分支通常作为一个整体发生糖苷键断裂或产生D离子,据此可判断分支点的位置;根据硫酸寡糖产生的特异性跨环断裂碎片,可以确定硫酸基的连接位置.这些规律和方法的总结为未知寡糖的结构和序列的分析提供了启发和指导.     

微柱高效液相色谱-质谱/质谱快速鉴定混合蛋白质新方法

发展了一种混合蛋白质快速鉴定的新方法.将几种蛋白质的混合物于热变性后直接在溶液中酶解,利用微柱高效液相色谱-离子阱串级质谱进行肽谱/氨基酸序列分析,并结合Mascot数据库搜索处理功能,实现了混合蛋白质快速准确的鉴定.     

氢氘交换质谱技术在蛋白质和蛋白复合物结构研究中的应用进展

蛋白质是生命功能的执行者,其功能的发挥受自身结构动态变化、与其他生物分子的相互作用及修饰等因素的调节。因此,对蛋白质及蛋白复合物结构的研究有助于揭示重要生命过程中的分子机理与机制。氢氘交换质谱(Hydrogen deuterium exchange mass spectrometry,HDX-MS)是研究蛋白质结构、动态变化和相互作用的强有力工具,也是传统生物物理手段的重要补充。该文综述了HDX-MS的基本原理、机制、实验方法和研究最新进展,并从蛋白质自身动态变化、蛋白质-小分子相互作用、蛋白质-蛋白质相互作用3个方面介绍了近年来HDX-MS在蛋白及蛋白复合物研究中的应用进展。     

串联飞行时间质谱中亚胺离子的断裂特征及其在肽段鉴定中的作用

基质辅助激光解吸电离-串联飞行时间质谱(MALDI-TOF/TOF)产生的亚胺离子可以提供丰富的肽段组成信息,该方法通常用于基于数据库搜索的蛋白质鉴定,或者结合化学衍生法用于从头测序,因而在一定程度上限制了对亚胺离子的认识及应用。本研究利用239个串联质谱探索MALDI-TOF/TOF中亚胺离子的断裂特征以及它们在肽段鉴定中的应用,发现在高能碰撞诱导解离条件下组氨酸等14种氨基酸可产生较强的亚胺离子信号(>50%阳性率),氨基酸的化学结构、位置效应和氨基酸残基个数是影响碎片离子强度的主要因素。此外,探讨了亚胺离子应用过程中的假阳性问题,提出亚胺离子相对强度的比较可以降低假阳性和提高肽段鉴定确定度,有助于完善目前的数据库搜索算法和辅助从头测序分析。     

利用肽配体库分析蛋清中低丰度蛋白质组

利用肽配体库技术(CPLL)研究了蛋清中的低丰度蛋白质组。考察了盐浓度和洗脱顺序差异对CPLL富集效率的影响。结果表明:盐浓度越高,蛋清蛋白质溶液的离子相互作用越强。利用洗脱溶液解离差异,采用先HOS(有机水溶液)后尿素CHAPS(3-[3-(胆酰胺丙基)二甲氨基]-1-丙磺酸内盐)的洗脱顺序,溶菌酶能够得到高效分离。保持蛋清的原p H 8.8,25 mmol/L KH2PO4,150 mmol/L Na Cl,尿素CHAPS洗脱,是CPLL提供高效富集的前提。通过分析CPLL富集前后的十二烷基硫酸钠-聚丙烯酰胺凝胶电泳(SDSPAGE)条带差异,采用线性离子阱(LTQ)质谱在蛋清中检出45种低丰度蛋白质,其中两种未见报道。对蛋清中低丰度蛋白质亚细胞的定位分析发现,蛋清蛋白质的分泌蛋白居多。研究结果表明,CPLL技术能够实现蛋清中低丰度蛋白质的高效富集,分析深度达到亚细胞水平。     

基于串级质谱信息进行蛋白质数据库搜索的结果可靠性分析

SEQUEST与Mascot为目前蛋白组学分析研究中使用最为广泛的蛋白质库搜索工具.尝试将Mascot与SEQUEST搜索结果进行比较,进而采用不同多变量判别方法对二者的搜索结果进行判别分析,以降低其结果的假阳性率.通过对Mascot与SEQUEST搜索结果进行比较,发现所得结果差异很大;利用多变量判别分析方法对Mascot及SEQUEST搜索结果进行判别分析,可有效提高SEQUEST结果中假阳性结果与正确结果之间的区分能力.对于Mascot搜索结果,采用多变量判别分析方法仍无法显著降低其假阳性结果,利用Decoy库搜索结果进行估计时亦存在导致错误估计的风险.     

质谱技术在蛋白质、多肽化学中的应用

文中介绍了几种新的质谱技术: 快原子轰击质谱(fast atom bombardment-MS, 简称FAB-MS)、串联质谱(tandem mass spectrometry, 简称MS/MS)、电喷雾电离质谱(electrospray ionization-MS, 简称ESI-MS)和基质辅助的激光解吸电离飞行时间质谱(matrix assisted laser desorption ionization time offlight MS, 简称MALDI-TOF-MS), 这几种技术的相互补充使得质谱比较有效地用于蛋白质结构测定。文中例举了几个实例说明了它们在蛋白质的分子量测定,蛋白质和多肽的纯度鉴定, 糖肽的结构测定及特殊的N-端封闭的或一般的蛋白质和多肽的顺序测定中的应用。     

Peptide sequencing through N-terminal phosphonylation and electrospray ionization mass spectrometry

Peptides were phosphonylated at their N-termini by reacting with ethoxyphenylphosphinate in the presence of triethylamine and tetrachloromethane under mild conditions. The phosphonylated peptides were analyzed by tandem electrospray ionization mass spectrometry. N-Terminal phosphonylation selectively increased the intensities of b(n)-type ions relative to other ion types. The resulting simplified mass spectra clearly show the sequential loss of amino acid residues from the C-termini of peptides, providing a convenient and rapid method for peptide sequencing.     

Analysis of food proteins and peptides by mass spectrometry-based techniques

Mass spectrometry has arguably become the core technology for the characterization of food proteins and peptides. The application of mass spectrometry-based techniques for the qualitative and quantitative analysis of the complex protein mixtures contained in most food preparations is playing a decisive role in the understanding of their nature, structure, functional properties and impact on human health. The application of mass spectrometry to protein analysis has been revolutionized in the recent years by the development of soft ionization techniques such as electrospray ionization and matrix assisted laser desorption/ionization, and by the introduction of multi-stage and ‘hybrid’ analyzers able to generate de novo amino acid sequence information. The interfacing of mass spectrometry with protein databases has resulted in entirely new possibilities of protein characterization, including the high sensitivity mapping (femtomole to attomole levels) of post-translational and other chemical modifications, protein conformations and protein–protein and protein–ligand interactions, and in general for proteomic studies, building up the core platform of modern proteomic science. MS-based strategies to food and nutrition proteomics are now capable to address a wide range of analytical questions which include issues related to food quality and safety, certification and traceability of (typical) products, and to the definition of the structure/function relationship of food proteins and peptides. These different aspects are necessarily interconnected and can be effectively understood and elucidated only by use of integrated, up-to-date analytical approaches. In this review, the main aspects of current and perspective applications of mass spectrometry and proteomic technologies to the structural characterization of food proteins are presented, with focus on issues related to their detection, identification, and quantification, relevant for their biochemical, technological and toxicological aspects.     

Size exclusion chromatography coupled to electrospray ionization mass spectrometry for analysis and quantitative characterization of arsenic interactions with peptides and proteins

Arsenic‐binding proteins are of toxicological importance since enzymatic activities can be blocked by arsenic interactions. In the present work, a novel methodology based on size exclusion chromatography coupled to electrospray ionization mass spectrometry (SEC‐ESI‐MS) was developed with special emphasis to preserve the intact proteins and their arsenic bindings. The eluent composition of 25 mM Tris/HCl, pH 7.5, with the addition of 100‐mM NaCl optimized for SEC with UV detection provided the highest SEC separation efficiency, but was not compatible with the ESI‐MS because of the non‐volatility of the buffer substance and of the salt additive. In order to find the best compromise between chromatographic separation and ionization of the arsenic‐binding proteins, buffer type and concentration, pH value, portion of organic solvent in the SEC eluent as well as the flow rate were varied. In the optimized procedure five different arsenic‐binding peptides and proteins (glutathione, oxytocin, aprotinin, α‐lactalbumin, thioredoxin) covering a molar mass range of 0.3–14 kDa could be analyzed using 75% 10‐mM ammonium formate, pH 5.0/25% acetonitrile (v : v) as eluent and a turbo ion spray source operated at 300 °C and 5.5 kV. A complete differentiation of all peptides and proteins involved in the arsenic‐binding studies as well as of their arsenic‐bound forms has become feasible by means of the extracted ion chromatograms (XIC) of the mass spectrometric detection. The new method offered the possibility to estimate equilibrium constants for the reaction of phenylarsine oxide with different thiol‐containing biomolecules by means of the XIC peak areas of reactants and products. Limits of detection in the range of 2–10 µM were obtained by SEC‐ESI‐MS for the individual proteins. Copyright © 2009 John Wiley & Sons, Ltd.     

Identification and sequencing analysis of intact proteins via collision-induced dissociation and quadrupole time-of-flight mass spectrometry

Identifying unknown proteins has become a central focal point for proteomic and biopharmaceutical development laboratories. Our laboratory investigated using quadrupole time-of-flight mass spectrometry (Qq/TOFMS) for the analysis of intact proteins for the purpose of identifying unknowns while limiting the number of sample-handling steps between protein extraction and identification. Eight standard proteins, both unmodified and disulfide-bonded and ranging in mass from 5 to 66 kDa, were analyzed using nanoelectrospray and collision-induced dissociation to generate peptide sequence tags. An MS analysis, followed by MS/MS analyses on two to five individual protein charge states, were obtained to make an identification. Peptide sequence tags were extracted from the MS/MS data and used, in conjunction with molecular mass and source origin, to obtain protein identifications using the web-based search engine ProteinInfo (www.proteometrics.com). All of the proteins were unambiguously identified from the input data, after which, all of the major product ions were identified for structural information. In most cases, N- and/or C-terminal ions, and also stretches of consecutive product ions from the protein interior, were observed. This method was applied to the analysis and identification of an unknown detected via reversed-phase high-performance liquid chromatography.     

Application of micropellicular poly-styrene/divinylbenzene stationary phases for high-performance reversed-phase liquid chromatography electrospray-mass spectrometry of proteins and peptides

Summary Short columns packed with highly crosslinked 2.3 μm poly-styrene/divinylbenzene (PS/DVB) particles were used for rapid and efficient separation of proteins and peptides by reversed-phase high-performance liquid chromatography at elevated temperatures. Enhancement of the diffusivities of the sample components at elevated temperatures together with the short diffusion pathlength with the micropellicular polymeric stationary phases were responsible for high efficiency, high speed of analysis, and short column regeneration times. Underivatized PS/DVB beads as well as PS/DVB microspheres which have been modified with polyvinylalcohol or octadecyl chains on the surface were synthesized, employed, and compared to HY-TACH-C18, a commercially available micropellicular octadecyl-silica stationary phase, for the separation of proteins, octapeptides and tryptic protein digests. Highest performance was obtained with the silica- and PS/DVB-based octadecyl stationary phases, which exhibited similar column efficiencies but different selectivities for proteins and peptides. The minimum detectability at 214 nm and the maximum loading capacity for ribonuclease A using analytical 30×4.6 mm I.D. columns were 10 ng (0.6 pmol) and 1 μg, respectively. Finally, reversed-phase HPLC with a 60×2 mm I.D. narrow-bore column packed with micropellicular octadecyl PS/DVB was coupled successfully to electrospray mass spectrometry at a flow-rate of 0.15 mL min⁻¹ and on-line full-scan mass spectra for molecular mass determination and identification of proteins in the lower picomol range were obtained.     

Bromine isotopic signature facilitates de novo sequencing of peptides in free‐radical‐initiated peptide sequencing (FRIPS) mass spectrometry

We recently showed that free‐radical‐initiated peptide sequencing mass spectrometry (FRIPS MS) assisted by the remarkable thermochemical stability of (2,2,6,6‐tetramethyl‐piperidin‐1‐yl)oxyl (TEMPO) is another attractive radical‐driven peptide fragmentation MS tool. Facile homolytic cleavage of the bond between the benzylic carbon and the oxygen of the TEMPO moiety in o‐TEMPO–Bz–C(O)–peptide and the high reactivity of the benzylic radical species generated in ?Bz–C(O)–peptide are key elements leading to extensive radical‐driven peptide backbone fragmentation. In the present study, we demonstrate that the incorporation of bromine into the benzene ring, i.e. o‐TEMPO–Bz(Br)–C(O)–peptide, allows unambiguous distinction of the N‐terminal peptide fragments from the C‐terminal fragments through the unique bromine doublet isotopic signature. Furthermore, bromine substitution does not alter the overall radical‐driven peptide backbone dissociation pathways of o‐TEMPO–Bz–C(O)–peptide. From a practical perspective, the presence of the bromine isotopic signature in the N‐terminal peptide fragments in TEMPO‐assisted FRIPS MS represents a useful and cost‐effective opportunity for de novo peptide sequencing. Copyright © 2015 John Wiley & Sons, Ltd.