肝癌细胞系Hep3B的泛素化蛋白质组学

泛素化修饰是细胞内最重要的翻译后修饰形式之一,对细胞内蛋白质的稳定、降解、定位以及生物活性的调节起到重要作用。但因其在细胞内丰度低、降解周期短等特点而很难被检测。本研究中,制备的泛素结合结构域蛋白(Ubiquitin-binding domains,UBDs)用于富集肝癌细胞系Hep3B中的泛素化蛋白,并通过液相色谱-串联质谱联用的方法对富集的泛素化蛋白进行鉴定。实验共鉴定到1 900个潜在的泛素化蛋白和158个泛素化位点,这些被鉴定到的泛素化位点分属于102个蛋白。生物信息学分析发现泛素化蛋白显著富集的相关通路与肿瘤的发生发展密切相关,此结果暗示肿瘤细胞内泛素化-蛋白酶体的失调与肿瘤细胞的信号传导及细胞外基质的变化等具有较高的关联性。     

翻译后修饰蛋白质组学研究的新技术策略

利用Cell Signaling Technology(CST)公司开发的针对蛋白质翻译后修饰(PTM)基序(motif)抗体,在肽段水平上免疫亲和富集带有不同PTM的肽段,利用液相色谱-串联质谱(LC-MS/MS)进行定量分析,能够快速、准确、高通量地分析多种疾病相关信号通路关键节点蛋白磷酸化、乙酰化、甲基化和泛素化修饰的变化,满足创新性研究、生物标志物鉴定、药物靶点筛选和评价的需求。     

泛素化修饰组学技术及其在疾病研究中的应用

泛素化修饰作为真核细胞内主要的蛋白质翻译后修饰之一，通过泛素-蛋白酶体系统(UPS)介导了细胞内的蛋白质特异性降解，同时广泛参与并调控细胞内基因转录、信号传导、DNA损伤与修复、细胞周期调控、应激反应甚至个体的免疫应答等几乎所有的生命活动过程。泛素-蛋白酶体系统的精确调控构成了稳定而复杂的泛素化信号网络，而其失调通常会造成癌症、神经退行性疾病、代谢性疾病等多种疾病的发生发展。近年来，基于质谱(MS)的蛋白质组学逐渐成熟，并极大促进了泛素化修饰研究的深度与广度。依托于泛素化蛋白质/肽段富集技术的发展以及高通量、高覆盖度和高灵敏度的质谱检测技术平台，蛋白质泛素化修饰组学也得以快速发展，并逐渐应用于人类生理、病理状态的泛素化蛋白质组研究和疾病发生发展的机制探索。本文主要综述了泛素化修饰组学研究中的泛素化蛋白质/肽段富集方法、质谱鉴定技术、定量标记技术和数据处理方法，同时对泛素化修饰组学技术在疾病研究中的应用也进行了系统分析，理清了当前存在的问题与挑战，为泛素化修饰蛋白质的发现与鉴定提供参考，为相关疾病治疗靶点的筛选和药物研发提供思路。     

LUBAC介导RabGEF1的线性泛素化修饰

目的 验证RabGEF1 (Rab guanine nucleotide exchange factor 1)为线性泛素化修饰的新底物。方法 在pEF6/MycHis C载体中克隆人RabGEF1基因。通过免疫共沉淀（Co-IP）实验验证RabGEF1和HOIP的相互作用。利用GST-pulldown实验探索RabGEFl与HOIP相互作用结构域。通过免疫荧光实验验证RabGEF1和HOIP的相互作用与亚细胞定位。应用体内泛素化实验检测RabGEF1的线性泛素化修饰。通过NTA-His泛素化实验进一步明确RabGEF1能够发生线性泛素化修饰。将RabGEF1的泛素化蛋白质样品进行质谱分析，根据质谱结果提示的RabGEF1泛素化位点构建赖氨酸位点突变质粒，进一步在体内泛素化实验中验证RabGEF1的线性泛素化修饰位点。结果 RabGEF1与HOIP存在相互作用，且HOIP通过ZF-NEF结构域与RabGEF1发生直接相互作用。RabGEF1与HOIP共同定位于细胞质。LUBAC介导RabGEF1发生线性泛素化修饰依赖于LUBAC酶活性，RabGEF1泛素化修饰位点为K158。结论 Rab...     

体外重构STUB1介导α-1抗胰蛋白酶突变体Z蛋白泛素化修饰反应体系

α-1抗胰蛋白酶Z型突变体蛋白(α-1 antitrypsin Z-mutant protein, ATZ)是引发α-1抗胰蛋白酶缺陷症(α-1 antitrypsin deficiency, AATD)的主要原因,研究ATZ蛋白的泛素化修饰和降解对于治疗AATD具有重要意义。STUB1是一种重要的E3泛素连接酶,参与调节多种蛋白质的泛素化修饰。然而,STUB1是否参与ATZ的泛素化修饰尚未明确。本研究首先将ATZ和STUB1的编码基因克隆到pET28a质粒,构建了这2个蛋白的表达质粒。随后,将重组质粒转入大肠杆菌表达系统,在优化诱导条件实现了重组蛋白的异源表达。通过金属螯合亲和层析技术纯化得到目的蛋白,并通过蛋白质谱分析验证了其氨基酸序列的准确性。利用纯化的ATZ和STUB1重组蛋白,构建了一个体外泛素化修饰反应体系。实验结果显示,在ATP、E1泛素激活酶和E2泛素结合酶的协同作用下,STUB1成功催化了ATZ的泛素化修饰。本研究提供了一种体外获得Z型突变体ATZ纯化蛋白的方法,并确认了STUB1介导ATZ的泛素化修饰功能,推进了对α-1抗胰蛋白酶Z型突变体蛋白在细胞内降解过程的调控机制的理解。     

翻译后修饰蛋白质组学助力实现精准医疗

与基因组学相比,蛋白质组学能够即时反映病人在疾病状态与正常状态下的蛋白表达和修饰谱,从而进行精准诊断和治疗,因此在临床领域越来越具有应用前景。蛋白质组学早期聚焦于细胞不同发育时期或疾病状态下的蛋白质表达水平变化,然而,许多至关重要的生命进程不仅与蛋白质相对丰度有关,更重要的是被时空特异分布的、可逆的翻译后修饰调控。在蛋白质组学、抗体亲和色谱与质谱分析、生物信息学等跨学科知识基础上发展的PTMScan?技术,在定性、定量分析翻译后修饰蛋白质位点方面具有显著优势。介绍了PTMScan?翻译后修饰蛋白质组学技术,其能够快速、准确、高通量地分析肺癌、黑色素瘤等多种疾病中信号通路关键节点蛋白质磷酸化、乙酰化、甲基化、泛素化和类泛素化等修饰的变化,满足精准医疗与伴随诊断对于疾病生物标志物鉴定、药物靶点筛选、靶向用药指导、疾病预后指示的需求,真正实现精准医疗,将正确的药物在最恰当的时间治疗真正需要的患者。     

O-GlcNAc修饰对蛋白质泛素化降解途径的影响

O-GlcNAc修饰是一种特殊的糖基化修饰,几乎参与生物体内所有细胞过程的调控。该修饰与泛素化作为两种重要的蛋白质翻译后修饰形式,都与2型糖尿病、神经退行性疾病、癌症等疾病密切相关。O-GlcNAc修饰对蛋白质泛素化降解途径的影响主要体现在4个方面:(1)O-GlcNAc修饰能够抑制26S蛋白酶体的ATPase活性;(2)O-GlcNAc修饰会减少某些底物蛋白的泛素化降解;(3)O-GlcNAc修饰泛素化相关酶并调节其功能;(4)某些蛋白质(包括调控因子)发生O-GlcNAc修饰后间接影响蛋白质泛素化。     

泛素蛋白磷酸化修饰的功能与解析

泛素化是存在于真核生物中一种重要的翻译后修饰过程,参与调控包括蛋白质降解在内的多种生命活动。实现这一调控过程需要将一个由76个氨基酸组成的泛素蛋白共价连接到底物蛋白上。同时,泛素本身也存在多种翻译后修饰,包括泛素化、磷酸化、乙酰化等,进一步丰富了泛素的修饰类型,决定了底物蛋白不同的命运。近年来,伴随着第65位丝氨酸磷酸化泛素蛋白参与调控线粒体自噬这一突破性进展,泛素蛋白其余磷酸化位点的功能研究也获得越来越多的关注。本文根据目前已有的国内外研究和报道,总结了泛素蛋白已知的磷酸化修饰位点,梳理了泛素蛋白第12位和66位苏氨酸、第57位和65位丝氨酸等位点的磷酸化修饰对其生物物理特性带来的改变,并对相应修饰位点所涉及的生物学功能调控进行了综述。     

蛋白质泛素化修饰的生物信息学研究进展

泛素-蛋白酶体系统(Ubiquitin-proteasome system, UPS)介导了真核生物80%~85%的蛋白质降解, 该蛋白质降解途径具有依赖ATP、高效、高度选择性的特点。除参与蛋白质降解之外, 泛素化修饰还可以直接影响蛋白质的活性和定位。由于泛素化修饰底物蛋白在细胞中的广泛存在, 泛素化修饰可以调控包括细胞周期、细胞凋亡、转录调控、DNA损伤修复以及免疫应答等在内的多种细胞活动。近年来, 泛素-蛋白酶体系统相关的蛋白质组学数据不断产出, 有效地管理、组织并合理分析这些数据显得尤为必要。文章综述了当前世界范围内针对蛋白质泛素化修饰展开的生物信息学研究, 总结了前人的工作结果, 包括UPS相关蛋白质数据的收录、泛素化修饰网络的构建和分析、泛素化修饰位点的预测及泛素化修饰motif的研究等方面内容, 并对该领域未来的发展方向进行了讨论。     

E3泛素连接酶接头蛋白Keap1的研究进展

Kelch样ECH关联蛋白1(Kelch-like ECH-associated protein 1,Keap1)是E3泛素连接酶的底物识别亚单位,在蛋白质的泛素化修饰中起重要作用.蛋白质的泛素化修饰作为一种重要且复杂的蛋白质翻译后修饰,在自噬和蛋白酶体系统中作为降解信号而被利用.野生型Keap1能够识别、结合多种底物...     

JUMPptm: Integrated software for sensitive identification of post-translational modifications and its application in Alzheimer's disease study

Background : Mass spectrometry (MS)-based proteomic analysis of posttranslational modifications (PTMs) usually requires the pre-enrichment of modified proteins or peptides. However, recent ultra-deep whole proteome profiling generates millions of spectra in a single experiment, leaving many unassigned spectra, some of which may be derived from PTM peptides. Methods : Here we present JUMPptm, an integrative computational pipeline, to extract PTMs from unenriched whole proteome. JUMPptm combines the advantages of JUMP, MSFragger and Comet search engines, and includes de novo tags, customized database search and peptide filtering, which iteratively analyzes each PTM by a multi-stage strategy to improve sensitivity and specificity. Results : We applied JUMPptm to the deep brain proteome of Alzheimer's disease (AD), and identified 34,954 unique peptides with phosphorylation, methylation, acetylation, ubiquitination, and others. The phosphorylated peptides were validated by enriched phosphoproteome from the same sample. TMT-based quantification revealed 482 PTM peptides dysregulated at different stages during AD progression. For example, the acetylation of numerous mitochondrial proteins is significantly decreased in AD. A total of 60 PTM sites are found in the pan-PTM map of the Tau protein. Conclusion : The JUMPptm program is an effective tool for pan-PTM analysis and the resulting AD pan-PTM profile serves as a valuable resource for AD research.     

Site-specific ubiquitination: Deconstructing the degradation tag

Ubiquitin is a small eukaryotic protein so named for its cellular abundance and originally recognized for its role as the posttranslational modification (PTM) “tag” condemning substrates to degradation by the 26S proteasome. Since its discovery in the 1970s, protein ubiquitination has also been identified as a key regulatory feature in dozens of non-degradative cellular processes. This myriad of roles illustrates the versatility of ubiquitin as a PTM; however, understanding the cellular and molecular factors that enable discrimination between degradative versus non-degradative ubiquitination events has been a persistent challenge. Here, we discuss recent advances in uncovering how site-specificity — the exact residue that gets modified — modulates distinct protein fates and cellular outcomes with an emphasis on how ubiquitination site specificity regulates proteasomal degradation. We explore recent advances in structural biology, biophysics, and cell biology that have enabled a broader understanding of the role of ubiquitination in altering the dynamics of the target protein, including implications for the design of targeted protein degradation therapeutics.     

The structural context of posttranslational modifications at a proteome-wide scale

The recent revolution in computational protein structure prediction provides folding models for entire proteomes, which can now be integrated with large-scale experimental data. Mass spectrometry (MS)-based proteomics has identified and quantified tens of thousands of posttranslational modifications (PTMs), most of them of uncertain functional relevance. In this study, we determine the structural context of these PTMs and investigate how this information can be leveraged to pinpoint potential regulatory sites. Our analysis uncovers global patterns of PTM occurrence across folded and intrinsically disordered regions. We found that this information can help to distinguish regulatory PTMs from those marking improperly folded proteins. Interestingly, the human proteome contains thousands of proteins that have large folded domains linked by short, disordered regions that are strongly enriched in regulatory phosphosites. These include well-known kinase activation loops that induce protein conformational changes upon phosphorylation. This regulatory mechanism appears to be widespread in kinases but also occurs in other protein families such as solute carriers. It is not limited to phosphorylation but includes ubiquitination and acetylation sites as well. Furthermore, we performed three-dimensional proximity analysis, which revealed examples of spatial coregulation of different PTM types and potential PTM crosstalk. To enable the community to build upon these first analyses, we provide tools for 3D visualization of proteomics data and PTMs as well as python libraries for data accession and processing.

A combination of the comprehensive structural predictions of AlphaFold2 and large-scale proteomics data on post-translational modifications (PTMs) reveals novel insights into the functional importance of PTMs, based on their structural context.     

Exploring the diversity of plant proteome

The tremendous functional, spatial, and temporal diversity of the plant proteome is regulated by multiple factors that continuously modify protein abundance, modifications, interactions, localization, and activity to meet the dynamic needs of plants. Dissecting the proteome complexity and its underlying genetic variation is attracting increasing research attention. Mass spectrometry (MS)-based proteomics has become a powerful approach in the global study of protein functions and their relationships on a systems level. Here, we review recent breakthroughs and strategies adopted to unravel the diversity of the proteome, with a specific focus on the methods used to analyze posttranslational modifications (PTMs), protein localization, and the organization of proteins into functional modules. We also consider PTM crosstalk and multiple PTMs temporally regulating the life cycle of proteins. Finally, we discuss recent quantitative studies using MS to measure protein turnover rates and examine future directions in the study of the plant proteome.     

Systematic functional prioritization of protein posttranslational modifications

Protein function is often regulated by posttranslational modifications (PTMs), and recent advances in mass spectrometry have resulted in an exponential increase in PTM identification. However, the functional significance of the vast majority of these modifications remains unknown. To address this problem, we compiled nearly 200,000 phosphorylation, acetylation, and ubiquitination sites from 11 eukaryotic species, including 2,500 newly identified ubiquitylation sites for Saccharomyces cerevisiae. We developed methods to prioritize the functional relevance of these PTMs by predicting those that likely participate in cross-regulatory events, regulate domain activity, or mediate protein-protein interactions. PTM conservation within domain families identifies regulatory "hot spots" that overlap with functionally important regions, a concept that we experimentally validated on the HSP70 domain family. Finally, our analysis of the evolution of PTM regulation highlights potential routes for neutral drift in regulatory interactions and suggests that only a fraction of modification sites are likely to have a significant biological role.     

The first identification of lysine malonylation substrates and its regulatory enzyme

Protein post-translational modifications (PTMs) at the lysine residue, such as lysine methylation, acetylation, and ubiquitination, are diverse, abundant, and dynamic. They play a key role in the regulation of diverse cellular physiology. Here we report discovery of a new type of lysine PTM, lysine malonylation (Kmal). Kmal was initially detected by mass spectrometry and protein sequence-database searching. The modification was comprehensively validated by Western blot, tandem MS, and high-performance liquid chromatography of synthetic peptides, isotopic labeling, and identification of multiple Kmal substrate proteins. Kmal is a dynamic and evolutionarily conserved PTM observed in mammalian cells and bacterial cells. In addition, we demonstrate that Sirt5, a member of the class III lysine deacetylases, can catalyze lysine demalonylation and lysine desuccinylation reactions both in vitro and in vivo. This result suggests the possibility of nondeacetylation activity of other class III lysine deacetylases, especially those without obvious acetylation protein substrates. Our results therefore reveal a new type of PTM pathway and identify the first enzyme that can regulate lysine malonylation and lysine succinylation status.     

Signaling functions of ubiquitin in the 17β-estradiol (E2):estrogen receptor (ER) α network

Protein posttranslational modifications (PTMs) are signaling alterations that allow coordinating the cellular responses with the changes in the extracellular environment. In this way, the posttranslationally-modified protein becomes a switch node in the transduction network activated by the specific extracellular stimuli. It is now clear that this is the case also for protein ubiquitination: this extremely versatile PTM controls cell physiology through the modulation of protein stability as well as through the modulation of the dynamics of the intracellular signaling cascades. Recent evidence clearly indicates that such a complex scheme appears to be valid also for the 17β-estradiol (E2):estrogen receptor (ER) α signal transduction pathways. Indeed, beside the long standing notion that ERα ubiquitination is required for the regulation of receptor stability, several laboratories, including our own, have clearly indicated that ERα ubiquitination also serves non-degradative functions. This review will reconsider the role of ubiquitination in E2:ERα signaling by particularly highlighting how the functions of the non-degradative ubiquitination impact on ERα activities and contribute to the modulation of E2-dependent physiological processes.     

Analysis of posttranslational modifications of proteins by tandem mass spectrometry

Protein activity and turnover is tightly and dynamically regulated in living cells. Whereas the three-dimensional protein structure is predominantly determined by the amino acid sequence, posttranslational modification (PTM) of proteins modulates their molecular function and the spatial-temporal distribution in cells and tissues. Most PTMs can be detected by protein and peptide analysis by mass spectrometry (MS), either as a mass increment or a mass deficit relative to the nascent unmodified protein. Tandem mass spectrometry (MS/MS) provides a series of analytical features that are highly useful for the characterization of modified proteins via amino acid sequencing and specific detection of posttranslationally modified amino acid residues. Large-scale, quantitative analysis of proteins by MS/MS is beginning to reveal novel patterns and functions of PTMs in cellular signaling networks and biomolecular structures.