蛋白质SUMO化修饰与肿瘤调控

SUMO化修饰是一种重要的蛋白质翻译后修饰方式,在细胞周期调控、细胞代谢、基因转录、DNA损伤和修复等众多细胞生物学过程中,对底物蛋白质的表达、定位和活性进行调控。蛋白质SUMO化修饰是动态可逆的过程,去SUMO化修饰由SUMO特异性蛋白酶(SENPs)家族成员所催化。由于受到SUMO化修饰的底物蛋白种类众多、功能多样,SUMO化修饰能够在整体和特定蛋白质修饰层面,参与调控肿瘤的发生发展,并且这种调控机制非常复杂,比如调控细胞周期的进程、DNA损伤和基因组不稳定性、肿瘤代谢与生长、抗肿瘤免疫等。SENPs家族成员是底物蛋白质SUMO化修饰程度的决定者,该研究团队对SENPs家族成员在肿瘤中的作用开展了系列研究,因此该文也将以SENP1和SENP3为例,对SENPs在肿瘤进程中的作用及其作用机制展开介绍。     

植物SUMO化修饰研究进展

SUMO化修饰是一种高度保守的蛋白质翻译后修饰。在SUMO化酶系统的协同作用下,成熟的SUMO分子以异肽键的方式结合到靶蛋白上,调控靶蛋白稳定性、活性、定位等。同时,发生SUMO化修饰的蛋白在SUMO特异蛋白酶的作用下发生去SUMO化反应,使SUMO重新进入循环过程。已知SUMO化修饰参与了植物胁迫响应、生长发育、开花等重要生理过程的调控。本文主要介绍了植物SUMO化修饰途径及其调控的生物学过程,并讨论蛋白组学方法在SUMO化修饰底物鉴定的进展及问题。     

植物蛋白质SUMO化修饰体外高效检测系统

蛋白质SUMO化修饰是一种调控蛋白命运的关键修饰方式, 广泛参与植物生长发育及逆境胁迫响应。SUMO化修饰过程主要由激活酶(E1)-结合酶(E2)-连接酶(E3)组成的级联酶促反应催化, 其关键酶组分将SUMO分子缀合至底物蛋白的赖氨酸残基, 形成共价异肽键以完成SUMO化修饰过程。该文报道了1种植物蛋白质SUMO化修饰体外高效检测系统, 通过在大肠杆菌(Escherichia coli)中构建拟南芥(Arabidopsis thaliana) SUMO化修饰的关键通路实现对底物蛋白的SUMO化修饰, 结果可通过免疫印迹进行检测。该系统可以简化植物蛋白质SUMO化修饰的检测流程, 为植物细胞SUMO化修饰的功能研究提供了有力工具。     

泛素化和SUMO化对DEC1的拮抗调控作用

分化的胚软骨表达蛋白1(differentiated embryo-chondrocyte expressed gene 1,DEC1)作为一种时钟蛋白,除了在周期节律的调控中发挥转录抑制作用外,还在能量代谢以及多种肿瘤相关的信号通路的调控中发挥重要作用。此外,蛋白质的翻译后修饰是实现蛋白质功能精细调控的一种重要方式。目前发现,DEC1主要可被两种翻译后修饰,即泛素化和SUMO化修饰。尽管泛素化和SUMO化是两种过程非常类似的蛋白质翻译后修饰方式,但是它们对目的蛋白功能的调控却截然不同。由于泛素化和SUMO化与底物的作用靶点都是赖氨酸(Lys),因此在多数情况下,泛素化和SUMO化以拮抗性的方式调控底物蛋白的功能。鉴于此,该文旨在阐述泛素化和SUMO化修饰对DEC1功能的拮抗调节过程,为了解时钟蛋白DEC1对多种信号通路的调控过程中的分子机制提供新的思路。     

SUMO E3连接酶在植物适应非生物胁迫中的作用研究进展

SUMO化(Sumoylation)作为一种广泛存在于真核生物的重要翻译后修饰,在调控植物生长、发育和逆境应答等方面发挥着重要作用。SUMO E3连接酶具有底物识别和选择的作用,直接促进SUMO蛋白与靶蛋白的结合。目前,在植物中已经鉴定出多种SUMO E3连接酶。综述了SUMO E3连接酶在植物适应干旱、盐害、高/低温、营养元素匮缺和重金属毒害等非生物胁迫过程中的作用,并展望了未来植物SUMO化研究的方向,以期为今后植物SUMO化方面的研究提供参考。     

SUMO E3连接酶在植物生长发育中的功能研究进展

SUMO化是真核生物中一种重要的蛋白质翻译后修饰。SUMO E3连接酶具有对底物特异的识别功能, 可以促进SUMO化反应, 是SUMO化修饰过程中的重要组成部分。目前, 在植物中已经鉴定出多种SUMO E3连接酶, 它们参与植物重要器官的发育调控。该文对植物SUMO E3连接酶在根系发育、开花途径、配子发育和光形态建成中的作用及其调节机制进行综述。     

植物蛋白SUMO化修饰检测方法

SUMO化是一种重要的蛋白质翻译后修饰,对植物正常生长发育不可或缺。到目前为止已筛选到上千个可能的SUMO底物,但由于SUMO化修饰水平普遍很低,其生物学功能研究相对较少。该文详细描述了检测蛋白SUMO化修饰的常用方法,包括体外和体内SUMO化实验,以及SUMO化修饰位点的检测方法,旨在为深入研究植物蛋白SUMO化修饰提供技术支持。     

蛋白质UFM化修饰

泛素折叠修饰因子1(ubiquitin-fold modifier 1,UFM1)是类泛素蛋白(ubiquitin-like modifier,UBL)家族的一员,存在于几乎所有的真核细胞中。UFM1对底物的修饰过程与泛素相似,即依次通过UBA5、UFC1和UFL1催化,共价接合在底物的赖氨酸残基上。而UFSP则负责切割UFM1的C端使之成熟,以及去除底物的UFM1修饰。UFM化修饰参与了内质网应激介导的细胞凋亡过程,对其具体作用机制的阐明需要鉴定到UFM1的修饰底物,但目前已经鉴定到UFM1的底物很少。大量研究尚聚焦于UFM修饰酶上。通过对UFM修饰酶和少量修饰底物的研究发现,UFM化修饰参与非酒精性肝病、细胞生成障碍性贫血、髋关节发育不良和神经系统疾病等的发生,以及乳腺癌细胞的增殖与转移和寄生虫的生长发育。本文将对UFM化修饰相关酶和修饰底物进行综述,总结UFM化修饰的生物学功能和在疾病发生发展中的作用。     

一种新型SUMO E3连接酶CBX4的化学修饰作用

多梳蛋白家族（polycomb group proteins,PcG）是一类在染色质水平上通过表观遗传修饰抑制靶基因转录的调节因子,它在调节细胞周期、DNA修复、细胞分化、衰老和死亡中起到重要作用。CBX4作为PcG家族中唯一具有SUMO E3 连接酶活性的成员,可以作用于多种底物,包括HIPK2、SIP1、CtBP、CTCF、Dnmt3a和HIF-1α等。底物的SUMO化修饰依赖于特定的结构基础,而且SUMO化的底物功能也会相应发生改变。同时,CBX4还可以被其它分子,如HIPK2, SENP2等进行磷酸化以及去SUMO化等修饰。本篇综述详细阐述了CBX4对底物的SUMO化修饰、自身被修饰及其生物学功能的变化。     

SUMO化和磷酸化的相互作用与共同修饰

翻译后修饰如磷酸化、乙酰化、甲基化、泛素化和SUMO化调节不同蛋白质的不同功能。磷酸化可能是最常见的修饰之一,蛋白质磷酸化通过一系列的激酶和磷酸酶催化,从而改变蛋白质功能。SUMO修饰是一种类泛素化修饰。SUMO修饰包括活化、结合、连接和解离,涉及多个酶多个步骤的催化过程。SUMO化可调节蛋白质相互作用、亚细胞定位、蛋白质稳定性和转录活性。关于磷酸化和SUMO化的蛋白质翻译后修饰,已有广泛研究报道。但很少关注于磷酸化和SUMO化之间的相互作用,以及它们对蛋白质的共同修饰。本文综述了蛋白质磷酸化和SUMO化之间的相互作用,以及共同修饰对细胞生理和肿瘤的影响。     

A genome-wide analysis of sumoylation-related biological processes and functions in human nucleus

Protein sumoylation is an important reversible post-translational modification of proteins in the nucleus, and it orchestrates a variety of the cellular processes. Genome-wide analysis of functional abundance and distribution of Small Ubiquitin-related MOdifier (SUMO) substrates may shed a light on how sumoylation is involved in nuclear biological processes and functions. Two interesting questions about sumoylation have emerged: (1) how many SUMO substrates exist in mammalian proteomes, such as human and mouse, (2) and what are their functions and how are they involved in a variety of biological processes? To address these two questions,we present an in silico genome-scale analysis for SUMO substrates in human. Based on the pattern recognition and phylogenetic conservation, we retrieved a list of 2683 potential SUMO substrates conserved in both human and mouse. Then, by functional enrichment analysis, we surveyed the over-represented GO terms and functional domains of them against the whole human proteome. Besides the consistence between our analyses and in vivo or in vitro work, the in silico predicted candidates also point to several potential roles of sumoylation, e.g., perception of sound. These potential SUMO substrates in human are of great value for further in vivo or in vitro experimental analysis.     

SUMO protein modification

SUMO (small ubiquitin-related modifier) family proteins are not only structurally but also mechanistically related to ubiquitin in that they are posttranslationally attached to other proteins. As ubiquitin, SUMO is covalently linked to its substrates via amide (isopeptide) bonds formed between its C-terminal glycine residue and the epsilon-amino group of internal lysine residues. The enzymes involved in the reversible conjugation of SUMO are similar to those mediating the ubiquitin conjugation. Since its discovery in 1996, SUMO has received a high degree of attention because of its intriguing and essential functions, and because its substrates include a variety of biomedically important proteins such as tumor suppressor p53, c-jun, PML and huntingtin. SUMO modification appears to play important roles in diverse processes such as chromosome segregation and cell division, DNA replication and repair, nuclear protein import, protein targeting to and formation of certain subnuclear structures, and the regulation of a variety of processes including the inflammatory response in mammals and the regulation of flowering time in plants.     

SUMO-specific proteases: a twist in the tail

The small ubiquitin-like modifier (SUMO) is involved in many cellular processes and is required for normal growth and development in all eukaryotes. Whereas lower eukaryotes have a single version of SUMO, higher eukaryotes have three versions: SUMO-1, -2 and -3. Similarly to most other ubiquitin-like proteins, the primary translation products of the SUMO genes need to be proteolytically processed to expose the C-terminal glycine that will be linked to lysine side chains in substrates. Processing of SUMO precursors is mediated by SUMO-specific proteases that also remove SUMO from modified proteins and depolymerise poly-SUMO chains.     

Ubiquitin-dependent proteolytic control of SUMO conjugates

Posttranslational protein modification with small ubiquitin-related modifier (SUMO) is an important regulatory mechanism implicated in many cellular processes, including several of biomedical relevance. We report that inhibition of the proteasome leads to accumulation of proteins that are simultaneously conjugated to both SUMO and ubiquitin in yeast and in human cells. A similar accumulation of such conjugates was detected in Saccharomyces cerevisiae ubc4 ubc5 cells as well as in mutants lacking two RING finger proteins, Ris1 and Hex3/Slx5-Slx8, that bind to SUMO as well as to the ubiquitin-conjugating enzyme Ubc4. In vitro, Hex3-Slx8 complexes promote Ubc4-dependent ubiquitylation. Together these data identify a previously unrecognized pathway that mediates the proteolytic down-regulation of sumoylated proteins. Formation of substrate-linked SUMO chains promotes targeting of SUMO-modified substrates for ubiquitin-mediated proteolysis. Genetic and biochemical evidence indicates that SUMO conjugation can ultimately lead to inactivation of sumoylated substrates by polysumoylation and/or ubiquitin-dependent degradation. Simultaneous inhibition of both mechanisms leads to severe phenotypic defects.     

Identification and molecular properties of SUMO-binding proteins in Arabidopsis

Reversible conjugation of the small ubiquitin modifier (SUMO) peptide to proteins (SUMOylation) plays important roles in cellular processes in animals and yeasts. However, little is known about plant SUMO targets. To identify SUMO substrates in Arabidopsis and to probe for biological functions of SUMO proteins, we constructed 6xHis-3xFLAG fused AtSUMO1 (HFAtSUMO1) controlled by the CaMV35S promoter for transformation into Arabidopsis Col-0. After heat treatment, an increased sumoylation pattern was detected in the transgenic plants. SUMO1-modified proteins were selected after two-dimensional gel electrophoresis (2-DE) image analysis and identified using matrix-assisted laser-desorption ionization time-of-flight mass spectrometry (MALDI-TOF MS). We identified 27 proteins involved in a variety of processes such as nucleic acid metabolism, signaling, metabolism, and including proteins of unknown functions. Binding and sumoylation patterns were confirmed independently. Surprisingly, MCM3 (At5G46280), a DNA replication licensing factor, only interacted with and became sumoylated by AtSUMO1, but not by SUMO1ΔGG or AtSUMO3. The results suggest specific interactions between sumoylation targets and particular sumoylation enzymes.