蛋白质N末端组学研究进展

蛋白质的N末端作为合成的起始,其氨基酸序列组成及翻译后修饰直接影响着蛋白质的活性、稳定性和细胞内定位,调控着细胞内的信号转导,甚至决定了这些蛋白质的命运。对蛋白质N末端组学的系统研究不仅可以揭示N末端区域对整个蛋白质的重要作用,有助于我们深入地了解蛋白质在各种生命活动中所扮演的角色,同时在实现蛋白质组高覆盖、基因组重注释等方面也有着重要的价值。本文结合我们的现有工作,综述了近年来蛋白质N末端组学的研究进展,尤其是一些重要的基于质谱的N末端富集技术和方法。     

基于质谱技术的蛋白质组定量方法

对不同状态下的蛋白质在表达和修饰水平上进行精确定量,对于探索蛋白质的生物功能、发现疾病的生物标志物都具有重要意义,也是当前蛋白质组学的一个重要研究前沿。近年来,各种蛋白质组定量的新技术和新方法不断涌现,但仍面临着巨大挑战。本文就基于质谱技术的多种蛋白质组定量方法的基本原理、近几年的研究进展和应用进行评述。     

基于生物质谱的蛋白质C末端研究进展

蛋白质的C末端在蛋白质进行各项生命活动过程中都起着极其重要的作用。它不仅标志着DNA转录翻译成蛋白质过程的初步完成,更是参与和调控了蛋白质的各种生理功能。研究蛋白质的C末端不仅有利于完整蛋白质的鉴定,对于在分子水平理解蛋白质的信号传导和生化功能是十分必要的。文中结合我们的研究工作,综述了近年来基于生物质谱的蛋白质C末端研究的相关进展,包括了C末端的识别、鉴定以及蛋白质C末端肽段富集的新方法和新技术。     

基于电感耦合等离子体质谱的蛋白质定量技术研究进展

综述了ICP-MS法应用于蛋白质定量技术方面的研究进展.蛋白质定量研究已成为蛋白质组学研究领域的热点,它是解析生物体蛋白质功能的重要途径.基于同位素标记和生物质谱分析技术是蛋白质定量最常用的方法之一,近年来,随着质谱技术的发展,电感耦合等离子体质谱(ICP-MS)技术成为元素测量的重要手段,这使其在蛋白质定量中具一定的应用前景.     

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。     

基于质谱的定量蛋白质组学策略和方法研究进展

定量蛋白质组学已经成为组学领域研究的热点之一.相关实验技术和计算方法的不断创新极大地促进了定量蛋白质组学的飞速发展.常用的定量蛋白质组学策略按照是否需要稳定同位素标记可以分为无标定量和有标定量两大类.每类策略又产生了众多定量方法和工具,它们一方面推动了定量蛋白质组学的深入发展;另一方面,也在实验策略与技术的发展过程中不断更新.因此对这些定量实验策略和方法进行系统总结和归纳将有助于定量蛋白质组学的研究.本文主要从方法学角度全面归纳了目前定量蛋白质组学研究的相关策略和算法,详述了无标定量和有标定量的具体算法流程并比较了各自特点,还对以研究蛋白质绝对丰度为目标的绝对定量算法进行了总结,列举了常用的定量软件和工具,最后概述了定量结果的质量控制方法,对定量蛋白质组学方法发展的前景进行了展望.     

蛋白质质谱分析的无标记定量算法研究进展

作为发现疾病相关生物标志物的重要途径,定量研究已成为蛋白质组学的热点问题.随着实验方法的发展和改进,定量数据处理算法也在不断更新和完善.将现有的无标记定量方法归纳为需要/不需要鉴定结果两类方法,分析比较了两类方法的异同及优缺点,详细讨论了所涉及的主要算法,总结了一些常用的无标记定量软件及对应的网络资源.展望了无标记定量数据分析的未来研究方向.     

糖蛋白质组定量技术进展

蛋白质的糖基化是最重要和最普遍的蛋白质翻译后修饰之一,在生物体内起着极为重要的作用。糖蛋白质的量和（或）糖基化程度的改变以及糖链结构的改变等与许多疾病密切相关,因此定量糖蛋白质组研究已经成为一个新的热点。然而由于糖基化蛋白质所具有的独特特征,其定量面临严峻的挑战。糖蛋白质组学定量方法和技术的发展将为更好地研究糖基化蛋白质生物学功能起到重要作用。综述了基于生物质谱的糖蛋白质组定量研究的技术和方法,及其优缺点和未来的发展趋势。     

蛋白质组研究中的化学"探针"

随着蛋白质组学概念的提出以及诸如血浆蛋白质组等有影响力的计划开展, 蛋白质组研究迅速发展起来, 这门基于分析化学和物理化学的领域也逐渐为广大生物学家所关注, 同时也相应地在细胞生物学、生物化学等领域的研究中崭露头角。蛋白质表达量的变化以及各种各样的修饰无不反映出机体对环境变化的应激和自身功能的需要。因此, 定量蛋白质组和修饰化的蛋白质组成为了目前蛋白质组研究的重要领域之一。文章着重从采用化学标记实现定量和修饰化研究这个角度来介绍近些年来在这方面取得的进展, 希望对生物学领域的研究有所借鉴。     

大肠杆菌N~α-乙酰基转移酶RimI对人胸腺素α原N末端乙酰化修饰的影响

目的:研究大肠杆菌Nα-乙酰基转移酶RimI对人胸腺素α原(ProTα)N末端乙酰化修饰的影响。方法:在大肠杆菌中共表达ProTα与大肠杆菌Nα-乙酰基转移酶RimI,同时设置只表达ProTα的对照菌,分别提取纯化ProTα,利用HPLC检测其发生乙酰化修饰的程度。结果:ProTα的乙酰化修饰发生在翻译后水平,有无RimI的过表达、诱导时间的长短以及这两个因素之间的交叉效应均对ProTα的乙酰化程度有影响,其F值分别为53.8、89.22及16.28,P值均小于0.0001;无论有无RimI过表达,乙酰化的ProTα所占比例在诱导6 h后逐渐升高(P<0.0001);在过表达Ri-mI的菌株中,乙酰化的ProTα在诱导12 h后占37.4%,而在无RimI过表达的菌株中占64.3%;RimI对ProTα乙酰化的抑制作用从诱导6 h后开始显现(P=0.0007)。结论:在大肠杆菌中,过量的Nα-乙酰基转移酶RimI可抑制人胸腺素α原的乙酰化修饰。     

Mass Spectrometry and Proteomics 2018: the Mass Spectrometry Society of Japan,Japanese Proteomics Society,and Asia-Oceania Human Proteome Organization

ABSTRACT

Introduction: The mass spectrometry society of Japan, Japanese proteomics society, and Asia–Oceania human proteome organization held the conference ‘Mass Spectrometry and Proteomics 2018’ in Osaka, Japan, on May 15–18, 2018. This international conference focused on cutting edge technologies and their applications in a variety of research fields such as agriculture, material science, environmental factors, and clinical applications. An overview of the conference and a summary of the major lectures are reported here.

Expert commentary: The meeting will facilitate the development of fundamental technologies and the multi-disciplinary applications of proteomics.     

基于质谱技术的蛋白质互作研究进展

蛋白质作为生命活动的执行者,其功能往往体现在与其他蛋白质的相互作用中,研究蛋白-蛋白相互作用对于人们深入了解和预防传染病、靶向治疗多基因疾病、阐明蛋白质的分子作用机制及各种复杂的生命现象具有重要意义。目前,有多种技术被用来研究蛋白间的相互作用,研究难点在于实时捕获瞬时或弱蛋白质间的相互作用,质谱技术（mass spectrometry, MS）可在某种程度上解决该难点。由于质谱技术可研究简单的蛋白质复合物再到大规模的蛋白质组实验,基于质谱技术研究蛋白质间相互作用被越来越多地应用于科学研究中。综述了蛋白质间相互作用检测方法的研究进展,重点介绍了氢氘交换质谱法和化学交联质谱法研究蛋白质间相互作用的优缺点及其应用,最后对基于质谱技术研究蛋白质间相互作用进行了总结与展望,以期为深入开展相关研究提供借鉴。     

Selected Reaction Monitoring Mass Spectrometry for Absolute Protein Quantification

Absolute quantification of target proteins within complex biological samples is critical to a wide range of research and clinical applications. This protocol provides step-by-step instructions for the development and application of quantitative assays using selected reaction monitoring (SRM) mass spectrometry (MS). First, likely quantotypic target peptides are identified based on numerous criteria. This includes identifying proteotypic peptides, avoiding sites of posttranslational modification, and analyzing the uniqueness of the target peptide to the target protein. Next, crude external peptide standards are synthesized and used to develop SRM assays, and the resulting assays are used to perform qualitative analyses of the biological samples. Finally, purified, quantified, heavy isotope labeled internal peptide standards are prepared and used to perform isotope dilution series SRM assays. Analysis of all of the resulting MS data is presented. This protocol was used to accurately assay the absolute abundance of proteins of the chemotaxis signaling pathway within RAW 264.7 cells (a mouse monocyte/macrophage cell line). The quantification of G_i2 (a heterotrimeric G-protein α-subunit) is described in detail.     

N-Terminal Acetylation of Two Major Latex Proteins from Arabidopsis thaliana Using Electrospray Ionization Tandem Mass Spectrometry

The primary structure of two proteins named major latex protein in Arabidopsis thaliana were characterized by matrix-assisted laser desorption/ionization time of flight mass spectrometer and Nano-electrospray ionization tandem mass spectrometry (nanoESI-MS/MS) after two-dimensional gel electrophoresis separation. We revealed that the two proteins with the same N termini and the N-terminal alanine were acetylated after methionine cleavage by fragmentation of three doubly charged peptides using a quadrupole-time of flight 2 tandem mass spectrometer. It was worth noting that one peptide with sodium addition and acetylation was sequenced. It is usually difficult to analyze the peptide sequence of sodium adduct due to the 22-Da increment. The two proteins are highly homologous, and both their N-terminal and C-terminal peptides were sequenced. Of the two proteins, gi|15236568 (spot A) appears only in the seeding stage and flower organ, but gi|15236566 (spot B) appears throughout the whole life of A. thaliana. The biological mechanism of the two proteins and the function of N-terminal acetylation remain to be elucidated. This study showed that ESI-MS/MS was a powerful tool for the characterization of N-terminal acetylation of proteins.     

N-terminal Acetylation Levels Are Maintained During Acetyl-CoA Deficiency in Saccharomyces cerevisiae

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Highlights

• •First global study on metabolic regulation of Nt-acetylation.
• •Yeast cells maintain global Nt-acetylation levels during prolonged starvation.
• •Nt-acetylation can in some cases be either up- or downregulated by starvation.
• •Naa10/NatA affects the steady-state protein levels of Rsa3 and Rpl7a.

     

Identification and Quantification of Proteoforms by Mass Spectrometry

A proteoform is a defined form of a protein derived from a given gene with a specific amino acid sequence and localized post‐translational modifications. In top‐down proteomic analyses, proteoforms are identified and quantified through mass spectrometric analysis of intact proteins. Recent technological developments have enabled comprehensive proteoform analyses in complex samples, and an increasing number of laboratories are adopting top‐down proteomic workflows. In this review, some recent advances are outlined and current challenges and future directions for the field are discussed.     

Application of Mass Spectrometry in Proteomics

Mass spectrometry has arguably become the core technology in proteomics. The application of mass spectrometry based techniques for the qualitative and quantitative analysis of global proteome samples derived from complex mixtures has had a big impact in the understanding of cellular function. Here, we give a brief introduction to principles of mass spectrometry and instrumentation currently used in proteomics experiments. In addition, recent developments in the application of mass spectrometry in proteomics are summarised. Strategies allowing high-throughput identification of proteins from highly complex mixtures include accurate mass measurement of peptides derived from total proteome digests and multidimensional peptide separations coupled with mass spectrometry. Mass spectrometric analysis of intact proteins permits the characterisation of protein isoforms. Recent developments in stable isotope labelling techniques and chemical tagging allow the mass spectrometry based differential display and quantitation of proteins, and newly established affinity procedures enable the targeted characterisation of post-translationally modified proteins. Finally, advances in mass spectrometric imaging allow the gathering of specific information on the local molecular composition, relative abundance and spatial distribution of peptides and proteins in thin tissue sections.     

N-terminal processing and modifications of caveolin-1 in caveolae from human adipocytes

Caveolin, the principal structural protein of caveolae membrane domains, has a cytosol-exposed N-terminal part that was cleaved off by trypsin treatment of caveolae vesicles isolated from primary human adipocytes. Sequencing of the released tryptic peptides by nanospray quadrupole time-of-flight mass spectrometry revealed that both caveolin-1alpha and caveolin-1beta were processed by excision of the starting methionines. The N-terminus of the mature caveolin-1alpha was acetylated, while caveolin-1beta was found in acetylated as well as in non-acetylated forms. Fractional phosphorylation of serine-36 in the mature caveolin-1alpha and of the homologous serine-5 in caveolin-1beta was identified. This is the first experimental evidence for in vivo phosphorylation of caveolin-1 at the consensus site for phosphorylation by protein kinase C. The phosphorylation was found in both the acetylated and non-acetylated variants of caveolin-1beta. This variability in modifications is consistent with critical involvement of the N-terminal domain of caveolin in the regulation of caveolae.