非组蛋白甲基化修饰的研究进展

非组蛋白的赖氨酸和精氨酸残基上的甲基化修饰已经被证明是一种普遍的蛋白质翻译后修饰方式,在生命活动中发挥重要作用.甲基化修饰方式的多样性以及它们与其他修饰之间的交互作用(crosstalk)复杂但精细地调控了基因表达、蛋白质活性及稳定性、DNA复制及基因组稳定性、RNA加工等多种功能.本文将对非组蛋白的甲基化修饰特征进行总结,归纳近些年来已报道的甲基化修饰酶、修饰位点及这些位点的生物学功能,并将特别阐述不同蛋白质修饰之间的交互作用,概述鉴定非组蛋白甲基化修饰的方法.     

蛋白质的甲基化研究进展

蛋白质翻译后修饰是调控蛋白质生物学功能的重要步骤之一。甲基化修饰作为蛋白质翻译后修饰的一种重要形式,参与了真核生物和原核生物的多种细胞进程。本文综述了目前蛋白质甲基化的研究进展,包括真核生物、原核生物,组蛋白和非组蛋白,以及多种氨基酸位点的甲基化修饰。这些发现丰富了人们对蛋白质甲基化修饰的认识,对深入了解蛋白质翻译后修饰的功能具有重要意义。     

植物组蛋白赖氨酸甲基化建立过程及其遗传性研究进展

表观遗传学主要包括DNA甲基化、组蛋白修饰和非编码RNA,组蛋白甲基化作为组蛋白修饰中的一种重要修饰,在植物体的发育和环境适应中发挥着重要作用。组蛋白甲基化主要发生在赖氨酸残基上,同时根据不同的赖氨酸位点和每个赖氨酸位点甲基化程度的不同,形成了不同的赖氨酸甲基化修饰。根据对基因的不同功能,通常将组蛋白赖氨酸甲基化修饰分为2大类:(1)能够促进基因表达的,如H3K4me3和H3K36me3;(2)能够抑制基因表达的,如H3K9me2和H3K27me3。不同的组蛋白赖氨酸甲基化去甲基化过程需要相应的阅读(reader)、书写(writer)和擦除(eraser)3种蛋白。同时,组蛋白赖氨酸甲基化的遗传性质目前还不是很清楚。综述了植物中组蛋白赖氨酸甲基化建立与去除过程,以及对组蛋白赖氨酸甲基化可遗传性的探讨。     

甲基转移酶SET7/9介导的底物甲基化修饰及其生理病理学功能的研究进展

赖氨酸的甲基化修饰能够影响蛋白质的稳定性、基因表达、亚细胞定位或酶活性,该过程与多种生理病理现象密切相关。其中,包含SET结构域的组蛋白甲基转移酶7/9(SET domain containing 7/9,SET7/9)是最先被鉴定出来的甲基转移酶,SET7/9参与的组蛋白甲基化修饰是重要的表观遗传修饰方式之一,在多个生物过程如转录激活和抑制、复制及DNA损伤修复中都有重要的作用。SET7/9对非组蛋白的甲基化修饰,不仅影响基因表达、调控、遗传等生理机制,且对于肿瘤等重大疾病的诊断、防治和预后判断有重要意义。本文就甲基转移酶SET7/9通过对组蛋白及非组蛋白底物的甲基化修饰及其生理学功能予以综述。     

组蛋白修饰调节机制的研究进展

表观遗传学涉及到DNA甲基化、组蛋白修饰、染色体重塑和非编码RNA调控等内容,其中组蛋白修饰包括组蛋白的乙酰化、磷酸化、甲基化、泛素化及ADP核糖基化等,这些多样化的修饰以及它们时间和空间上的组合与生物学功能的关系又可作为一种重要的表观标志或语言,因而被称为“组蛋白密码”．相同组蛋白残基的磷酸化与去磷酸化、乙酰化与去乙酰化、甲基化与去甲基化等,以及不同组蛋白残基的磷酸化与乙酰化、泛素化与甲基化、磷酸化与甲基化等组蛋白修 饰之间既相互协同又互相拮抗,形成了一个复杂的调节网络．对组蛋白修饰内在调节机制的研究将丰富“组蛋白密码”的内涵．     

非组蛋白甲基化研究进展

蛋白质的翻译后修饰主要包括磷酸化、乙酰化、泛素化以及甲基化,在调节蛋白质结构和功能上起到重要作用。目前对于蛋白质甲基化研究最多的是组蛋白甲基化。除了组蛋白,赖氨酸、精氨酸甲基化也发生在非组蛋白。近年来,越来越多的非组蛋白甲基化被发现,非组蛋白甲基化在肿瘤发生发展中同样具有重要意义。本文就此方面的进展作简要概述。     

组蛋白甲基化的研究进展

组蛋白甲基化是细胞中一种普遍而重要的表观遗传修饰方式,由组蛋白甲基转移酶完成.对组蛋白甲基化修饰认识已有相当长的时间,但直到最近几年由于组蛋白甲基化修饰酶的发现才使人们逐渐认识到组蛋白甲基化修饰有广泛的生物学功能.本文拟从组蛋白甲基转移酶、组蛋白甲基化的功能以及组蛋白甲基化与DNA甲基化的关系等方面综述这一领域的研究进展.     

组蛋白去甲基化酶与肿瘤发生

组蛋白甲基化修饰是一个可逆的动态的调节过程。甲基化和/或去甲基化状态与表观遗传、转录调控和维持基因组完整性等密切相关。组蛋白甲基化状态异常会直接或间接影响各种生理和病理过程。已知组蛋白去甲基化酶包括赖氨酸特异性去甲基化酶（LSD）家族和含JmjC结构域的JMJD家族。研究发现,两者与肿瘤的发生均有着密切的关系。本文总结了组蛋白去甲基化酶在组蛋白甲基化修饰及肿瘤研究方面的最新进展,为组蛋白修饰的功能及肿瘤诊断、治疗、预后监测等研究提供新思路。在胃癌、乳腺癌、结肠癌等常见肿瘤中,组蛋白去甲基化酶可改变组蛋白的甲基化水平或者直接作用于癌基因,也可调节microRNA或转录因子等,促进或抑制肿瘤的发生发展与影响肿瘤的预后。     

古菌中蛋白甲基化修饰的研究进展

蛋白甲基化修饰是翻译后修饰的主要方式之一,越来越多的报道证实古菌中存在这类蛋白修饰。目前古菌中一些甲基转移酶已经鉴定出来,但对其作用机制还不太清楚。本文对目前古菌中已经发现的蛋白质甲基转移酶和甲基化修饰可能的作用进行了总结。古菌中蛋白的甲基化修饰能够提高蛋白稳定性、影响侧链构象变化及与其他分子的相互作用,涉及DNA损伤修复和应激反应等途径。最后,本文对今后古菌中蛋白甲基化修饰的研究方向进行了展望。     

核小体及染色质修饰的基因组分布模式和染色质状态

染色质是真核DNA的存在方式,可以通过影响DNA的可及性调节基因转录,其基本单元为核小体,系由约147 bp的DNA缠绕在组蛋白八联体上形成的结构,核小体之间以连接DNA相连．核小体组蛋白上能发生甲基化和乙酰化等化学修饰．核小体位置、DNA的甲基化和组蛋白的修饰等对染色质状态(常染色质或异染色质)及基因组之间的长程相互作用有重要影响．近年,基于高通量测序技术,核小体位置和染色质修饰在多种细胞中的基因组分布已被测定．结果显示,这些标记的分布模式具有位点特异、动态变化、相互偶联和高度复杂的特征．本文详细回顾并评述了核小体位置和染色质修饰的分布模式、对应生物学功能、修饰之间的关联、实验测定技术、染色质状态的计算分析等内容．该工作对于深入认识和理解染色质的表观遗传调节机制有重要意义．     

Non-histone protein methylation in Trypanosoma cruzi epimastigotes

Post-translational methylation of proteins, which occurs in arginines and lysines, modulates several biological processes at different levels of cell signaling. Recently, methylation has been demonstrated in the regulation beyond histones, for example, in the dynamics of protein-protein and protein-nucleic acid interactions. However, the presence and role of non-histone methylation in Trypanosoma cruzi, the etiologic agent of Chagas disease, has not yet been elucidated. Here, we applied mass spectrometry-based-proteomics (LC-MS/MS) to profile the methylproteome of T. cruzi epimastigotes, describing a total of 1252 methyl sites in 824 proteins. Functional enrichment and protein-protein interaction analysis show that protein methylation impacts important biological processes of the parasite, such as translation, RNA and DNA binding, amino acid, and carbohydrate metabolism. In addition, 171 of the methylated proteins were previously reported to bear phosphorylation sites in T. cruzi, including flagellar proteins and RNA binding proteins, indicating that there may be an interplay between these different modifications in non-histone proteins. Our results show that a broad spectrum of functions is affected by methylation in T. cruzi, indicating its potential to impact important processes in the biology of the parasite and other trypanosomes.     

SET7/9-dependent methylation of ARTD1 at K508 stimulates poly-ADP-ribose formation after oxidative stress

ADP-ribosyltransferase diphtheria toxin-like 1 (ARTD1, formerly PARP1) is localized in the nucleus, where it ADP-ribosylates specific target proteins. The post-translational modification (PTM) with a single ADP-ribose unit or with polymeric ADP-ribose (PAR) chains regulates protein function as well as protein–protein interactions and is implicated in many biological processes and diseases. SET7/9 (Setd7, KMT7) is a protein methyltransferase that catalyses lysine monomethylation of histones, but also methylates many non-histone target proteins such as p53 or DNMT1. Here, we identify ARTD1 as a new SET7/9 target protein that is methylated at K508 in vitro and in vivo. ARTD1 auto-modification inhibits its methylation by SET7/9, while auto-poly-ADP-ribosylation is not impaired by prior methylation of ARTD1. Moreover, ARTD1 methylation by SET7/9 enhances the synthesis of PAR upon oxidative stress in vivo. Furthermore, laser irradiation-induced PAR formation and ARTD1 recruitment to sites of DNA damage in a SET7/9-dependent manner. Together, these results reveal a novel mechanism for the regulation of cellular ARTD1 activity by SET7/9 to assure efficient PAR formation upon cellular stress.     

Large-scale global identification of protein lysine methylation in vivo

Lysine methylation mediated by methyltransferase enzymes is present on multiple proteins throughout the cell; however, methods to uncover and characterize global protein lysine methylation patterns do not readily exist. Here we developed pan-specific methyl lysine antibodies that we utilized in immunoprecipitation experiments coupled with mass spectrometry to yield one of the first large-scale surveys of protein lysine methylation in vivo. In total, 552 different lysine methylation sites were determined, making this one of the most comprehensive global studies published to date. The large majority of these sites have not been yet reported. These sites showed significantly enriched sequence motifs and resided in proteins that are involved in diverse biological processes, particularly in chromatin organization. Our data provide a comprehensive view of lysine methylation in human cells and a powerful resource to facilitate investigations into the function of lysine methylation on non-histone proteins.     

Emerging Technologies to Map the Protein Methylome

Protein methylation plays an integral role in cellular signaling, most notably by modulating proteins bound at chromatin and increasingly through regulation of non-histone proteins. One central challenge in understanding how methylation acts in signaling is identifying and measuring protein methylation. This includes locus-specific modification of histones, on individual non-histone proteins, and globally across the proteome. Protein methylation has been studied traditionally using candidate approaches such as methylation-specific antibodies, mapping of post-translational modifications by mass spectrometry, and radioactive labeling to characterize methylation on target proteins. Recent developments have provided new approaches to identify methylated proteins, measure methylation levels, identify substrates of methyltransferase enzymes, and match methylated proteins to methyl-specific reader domains. Methyl-binding protein domains and improved antibodies with broad specificity for methylated proteins are being used to characterize the “protein methylome”. They also have the potential to be used in high-throughput assays for inhibitor screens and drug development. These tools are often coupled to improvements in mass spectrometry to quickly identify methylated residues, as well as to protein microarrays, where they can be used to screen for methylated proteins. Finally, new chemical biology strategies are being used to probe the function of methyltransferases, demethylases, and methyl-binding “reader” domains. These tools create a “system-level” understanding of protein methylation and integrate protein methylation into broader signaling processes.     

Epigenetic regulation: methylation of histone and non-histone proteins

Histone methylation is believed to play important roles in epigenetic memory in various biological processes. However, questions like whether the methylation marks themselves are faithfully transmitted into daughter cells and through what mechanisms are currently under active investigation. Previously, methylation was considered to be irreversible, but the recent discovery of histone lysine demethylases revealed a dynamic nature of histone methylation regulation on four of the main sites of methylation on histone H3 and H4 tails (H3K4, H3K9, H3K27 and H3K36). Even so, it is still unclear whether demethylases specific for the remaining two sites, H3K79 and H4K20, exist. Furthermore, besides histone proteins, the lysine methylation and demethylation also occur on non-histone proteins, which are probably subjected to similar regulation as histones. This review discusses recent progresses in protein lysine methylation regulation focusing on the above topics, while referring readers to a number of recent reviews for the biochemistry and biology of these enzymes     

Protein arginine methylation of non-histone proteins and its role in diseases

Protein arginine methyltransferases (PRMTs) are a family of enzymes that can methylate arginine residues on histones and other proteins. PRMTs play a crucial role in influencing various cellular functions, including cellular development and tumorigenesis. Arginine methylation by PRMTs is found on both nuclear and cytoplasmic proteins. Recently, there is increasing evidence regarding post-translational modifications of non-histone proteins by PRMTs, illustrating the previously unknown importance of PRMTs in the regulation of various cellular functions by post-translational modifications. In this review, we present the recent developments in the regulation of non-histone proteins by PRMTs.     

Lysine methylation: beyond histones

Posttranslational modifications (PTMs) of histone proteins, such as acetylation, methylation, phosphorylation, and ubiquitylation, play essential roles in regulating chromatin dynamics. Combinations of different modifications on the histone proteins, termed 'histone code' in many cases, extend the information potential of the genetic code by regulating DNA at the epigenetic level. Many PTMs occur on non-histone proteins as well as histones, regulating protein-protein interactions, stability, localization, and/or enzymatic activities of proteins involved in diverse cellular processes. Although protein phosphorylation, ubiquitylation, and acetylation have been extensively studied, only a few proteins other than histones have been reported that can be modified by lysine methylation. This review summarizes the current progress on lysine methylation of non-histone proteins, and we propose that lysine methylation, like phosphorylation and acetylation, is a common PTM that regulates proteins in diverse cellular processes.