蛋白质翻译后修饰在ABA信号转导中的作用

脱落酸(ABA)是植物生长发育和逆境适应过程中非常关键的植物激素。植物响应ABA信号转导过程由信号识别、转导及响应级联完成, 其中心转导途径由ABA受体RCAR/PYR/PYLs、磷酸酶PP2Cs、激酶SnRK2s、转录因子和离子通道蛋白构成。蛋白磷酸化、泛素化、类泛素化和氧化还原等翻译后修饰在ABA转导途径中起重要作用。该文综述了翻译后修饰在ABA信号转导中的作用。     

泛素化修饰调控脱落酸介导的信号途径

泛素化修饰是一种重要的蛋白质翻译后修饰,通过调节蛋白的活性和稳定性等影响其功能的发挥,在真核生物的生命过程中具有非常重要的作用。泛素化修饰通过精细地调控植物激素脱落酸(abscisic acid, ABA)的合成和信号转导过程的关键因子,影响植物对ABA的响应,参与植物生长发育过程及对干旱、盐和冷胁迫等不良环境的应答。本文概述了植物中泛素化修饰的相关组分(包括泛素连接酶E3、泛素结合酶E2、26S蛋白酶体)和内膜运输相关蛋白,以及这些蛋白调控ABA合成和信号转导过程的最新研究进展,提出该研究领域需要解决的新问题,以期为相关领域的科研人员进一步了解翻译后修饰如何调控激素信号的转导途径提供参考。     

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。     

病原菌调节宿主细胞泛素化途径的研究进展

泛素化是真核生物特有的蛋白质翻译后修饰,广泛地参与宿主细胞各种信号通路和生理过程.病原菌常通过分泌毒性效应蛋白,对泛素和泛素结合酶进行独特的共价修饰,或者利用泛素连接酶和去泛素化酶的酶学活性,调节宿主泛素化过程,从而干扰宿主细胞的信号转导,促进细菌的感染和生存.本文概述了病原菌效应蛋白调节宿主泛素化途径的主要研究进展和最新发现.     

泛素链水解酶的选择性和产生机制

底物蛋白的多聚泛素链修饰参与调节多种生命运动过程(包括蛋白质降解、自噬、DNA损伤修复、细胞周期、信号转导、基因表达、转录调节、炎症免疫等).去泛素化酶通过水解底物蛋白的单泛素和泛素链修饰,对泛素相关过程进行反向调节.人类基因组中约含90余种去泛素化酶,它们通过对自身酶活性和底物识别特异性的调节,实现了对细胞内复杂泛素过程的精密且层次性的调控.本文针对去泛素化酶对不同泛素链的识别选择性,综述目前已知泛素链水解酶的选择性和产生机制.     

泛素化修饰与植物免疫应答

植物暴露在细菌、病毒和真菌等病原微生物环境中,病虫害是限制农作物产量和品质的主要因素,而植物病虫害的防治依赖于对植物抗病机制的深入认识。近年来的研究表明,蛋白质泛素化广泛地参与植物防御调节。蛋白质泛素化是真核生物中重要的翻译后修饰方式之一,在植物中,泛素化修饰在多种信号传导途径中发挥作用,如激素、光、糖应答,发育调节和病原菌防御信号途径等。综述了蛋白质泛素化修饰在植物免疫应答中的调控作用。     

小泛素相关修饰物SUMO研究进展

蛋白质翻译后修饰对改变蛋白功能、活性或定位都起着非常重要的作用,泛素及其相似蛋白的修饰是其中一种重要形式。与其他诸如磷酸化、乙酰化、糖基化等不同的是,泛素及其相似蛋白的修饰基团本身即是一个小的多肽,通过异肽键与靶蛋白Lys侧链ε-NH2相连,其中小泛素相关修饰物(small ubiquitin—related modifier,SUMO)与蛋白的共价连接是一种新的广泛存在的翻译后修饰形式。SUMO是广泛存在于真核生物中高度保守的蛋白家族,在脊椎动物中有三个SUMO基因,称为SUMO-1,-2,-3,与泛素在二级结构上极其相似,且催化修饰过程的酶体系也具有很高的同源性。然而,与泛素化介导的蛋白酶降解途径不同,SUMO化修饰发挥着更为广泛的功能,如核质转运、细胞周期调控、信号转导、转录活性调控等。     

组蛋白泛素化修饰及其在DNA损伤应答中的作用

泛素化修饰是真核生物细胞内重要的翻译后修饰类型,通过调节蛋白质活性、稳定性和亚细胞定位广泛参与细胞内各项信号传导与代谢过程,对维持正常生命活动具有重要意义。组蛋白作为染色质中主要的蛋白成分,与DNA复制转录、修复等行为密切相关,是研究翻译后修饰的热点。DNA损伤后,组蛋白泛素化修饰通过调节核小体结构、激活细胞周期检查点、影响修复因子的招募与装配等诸多途径参与损伤应答。同时,组蛋白泛素化修饰还能调节其他位点翻译后修饰,并通过这种串扰(crosstalk)作用调节DNA损伤应答。本文介绍了组蛋白泛素化修饰的主要位点和相关组分(包括E3连接酶、去泛素化酶与效应分子),以及这些修饰作用共同编译形成的信号网络在DNA损伤应答中的作用,最后总结了目前该领域研究所面临的一些问题,以期为科研人员进一步探索组蛋白密码在DNA损伤应答中的作用提供参考。     

SUMO化修饰在核受体功能调控中的作用

小泛素相关修饰蛋白(small ubiquitin related modifier,SUMO)修饰作用是蛋白质翻译后修饰的重要方式。SUMO化修饰与泛素化作用极为相似,并且在某些靶蛋白上可以与泛素竞争结合位点,从而起到稳定靶蛋白的作用,并参与调节靶蛋白的细胞定位、膜离子通道功能、DNA损伤修复以及转录活性等。核受体是一类在生物体内广泛分布的、配体依赖的转录因子超家族,参与机体生长发育、细胞分化,以及体内许多生理、病理过程中的基因表达调控。最近研究发现,核受体的SU-MO修饰可通过影响核受体的稳定性、转录活性、亚细胞定位等多重途径影响核受体的功能,并影响机体炎症反应及相关疾病的发生发展。本文对核受体的SUMO修饰在核受体功能调控中的作用,以及与机体相关疾病之间的关系做一简要综述。     

炎症反应中的蛋白质翻译后修饰

炎症相关的信号转导蛋白、转录因子、炎性介质、组蛋白等可在炎症发生发展过程中发生磷酸化、乙酰化、泛素化、苏素化、甲基化等一系列翻译后修饰。这些化学修饰可高效调节相关蛋白质的功能活性及基因表达水平,不同化学修饰之间还可相互作用,共同影响炎症的发生、发展与转归;而异常的翻译后修饰与炎症相关性疾病关系密切。     

ABA信号通路的起源与进化

植物激素脱落酸（abscisic acid,ABA）在植物的生长、发育和胁迫反应方面起重要的调控作用,其信号转导通路由4个核心组分共同组成一个双重负调控系统（PYR/PYL/RCAR—| PP2C—| SnRK2—ABF/AREB）,调控ABA应答反应。本文在综述和分析ABA信号通路4个核心组分的起源与进化的基础上,初步提出ABA信号通路的起源与进化路径：A类PP2C、第Ⅲ亚类SnRK2以及转录因子AREB/ABF在水生植物轮藻中已经进化产生,当陆生植物进化产生ABA受体PYR/PYL/RCAR后,即与其它3个组分形成完整的ABA信号通路。在植物进化过程中,ABA信号通路4个核心组分各家族成员的数量（亚类）呈递增趋势。     

保卫细胞中ABA信号调控机制研究进展

脱落酸(ABA)具有调节植物快速响应逆境的重要功能。植物细胞中ABA核心信号通路由ABA受体PYR1/PYLs/RCARs、A类碱性蛋白磷酸酶PP2Cs和Snf1相关蛋白激酶SnRK2s组成。活性氧(ROS)和Ca²⁺是保卫细胞中的重要第二信使,调控ABA诱导的气孔关闭。该文对保卫细胞中核心ABA信号蛋白的调控以及ROS和Ca²⁺介导的ABA信号转导等最新研究成果进行综述,旨在阐明保卫细胞中ABA信号调控机制。     

Structural and functional insights into core ABA signaling

A series of papers in the last year reported major advances in our understanding of abscisic acid (ABA) signaling: the identification of soluble ABA receptors, the elucidation of a core ABA signaling pathway and structural insights into the mechanism of ABA perception and signaling. Here we summarize these advances, which have shown in atomic resolution that the ABA receptors PYR1, PYL1 and PYL2 function as allosteric switches that inhibit type 2C protein phosphatases (PP2Cs) in response to ABA. These receptors function at the apex of a core signaling pathway that regulates ABA responses by controlling SnRK2 kinase activity and the phosphorylation of downstream target proteins such as ABFs, which control nuclear responses, and the ion channel SLAC1, which mediates electrophysiological responses to ABA.     

蛋白激酶组在玉米叶片ABA和H_2O_2诱导抗氧化防护中的作用(英文)

蛋白磷酸化在植物细胞脱落酸(ABA)介导的信号转导中起重要作用。然而,很多参与ABA信号途径的蛋白元件仍不清楚。使用改进的体外激酶试验方法的研究结果表明,在玉米叶片中,ABA和H2O2能够快速活化蛋白激酶总活性和Ca2+依赖型蛋白激酶总活性;ABA诱导的蛋白激酶总活性增加可以被活性氧的抑制剂和清除剂抑制,蛋白激酶抑制剂不仅可以降低ABA和H2O2诱导的激酶活性增加,而且也可以弱化它们对抗氧化防护酶活性的诱导作用;ABA和H2O2引发的蛋白磷酸化作用显著居先于它们诱导的抗氧化防护作用。使用凝胶激酶试验方法进行研究发现,一组分子量分别为66kDa,52kDa,49kDa和35kDa的蛋白激酶可能介导了ABA和H2O2诱导的抗氧化防护反应,并且66kDa和49kDa的蛋白激酶可能在ROS的下游起作用,而52kDa和35kDa的蛋白激酶可能在ABA和ROS的下游起作用。     

The identification of genes involved in the stomatal response to reduced atmospheric relative humidity

Stomatal pores of higher plants close in response to decreases in atmospheric relative humidity (RH). This is believed to be a mechanism that prevents the plant from losing excess water when exposed to a dry atmosphere and as such is likely to have been of evolutionary significance during the colonization of terrestrial environments by the embryophytes. We have conducted a genetic screen, based on infrared thermal imaging, to identify Arabidopsis genes involved in the stomatal response to reduced RH. Here we report the characterization of two genes, identified during this screen, which are involved in the guard cell reduced RH signaling pathway. Both genes encode proteins known to be involved in guard cell ABA signaling. OST1 encodes a protein kinase involved in ABA-mediated stomatal closure while ABA2 encodes an enzyme involved in ABA biosynthesis. These results suggest, in contrast to previously published work, that ABA plays a role in the signal transduction pathway connecting decreases in RH to reductions in stomatal aperture. The identification of OST1 as a component required in stomatal RH and ABA signal transduction supports the proposition that guard cell signaling is organized as a network in which some intracellular signaling proteins are shared among different stimuli.     

Modulation of abscisic acid signaling in vivo by an engineered receptor-insensitive protein phosphatase type 2C allele

The plant hormone abscisic acid (ABA) plays a crucial role in the control of the stress response and the regulation of plant growth and development. ABA binding to PYRABACTIN RESISTANCE1 (PYR1)/PYR1-LIKE (PYL)/REGULATORY COMPONENTS OF ABA RECEPTORS intracellular receptors leads to inhibition of key negative regulators of ABA signaling, i.e. clade A protein phosphatases type 2C (PP2Cs) such as ABA-INSENSITIVE1 and HYPERSENSITIVE TO ABA1 (HAB1), causing the activation of the ABA signaling pathway. To gain further understanding on the mechanism of hormone perception, PP2C inhibition, and its implications for ABA signaling, we have performed a structural and functional analysis of the PYR1-ABA-HAB1 complex. Based on structural data, we generated a gain-of-function mutation in a critical residue of the phosphatase, hab1(W385A), which abolished ABA-dependent receptor-mediated PP2C inhibition without impairing basal PP2C activity. As a result, hab1(W385A) caused constitutive inactivation of the protein kinase OST1 even in the presence of ABA and PYR/PYL proteins, in contrast to the receptor-sensitive HAB1, and therefore hab1(W385A) qualifies as a hypermorphic mutation. Expression of hab1(W385A) in Arabidopsis (Arabidopsis thaliana) plants leads to a strong, dominant ABA insensitivity, which demonstrates that this conserved tryptophan residue can be targeted for the generation of dominant clade A PP2C alleles. Moreover, our data highlight the critical role of molecular interactions mediated by tryptophan-385 equivalent residues for clade A PP2C function in vivo and the mechanism of ABA perception and signaling.     

Interaction between abscisic acid receptor PYL3 and protein phosphatase type 2C in response to ABA signaling in maize

Abscisic acid (ABA) is a ubiquitous hormone that regulates plant growth, development and responses to environmental stresses. In recent researches, pyrabactin resistance 1-like protein (PYL) and protein phosphatase type 2C (PP2C) were identified as the direct receptor and the second component of ABA signaling pathway, respectively. However, a lot of PYL and PP2C members were found in Arabidopsis and several other plants. Some of them were found not to be involved in ABA signaling. Because of the complex diversity of the genome, few documents have been available on the molecular details of the ABA signal perception system in maize. In the present study, we conducted bioinformatics analysis to find out the candidates (ZmPYL3 and ZmPP2C16) of the PYL and PP2C members most probably involved in ABA signaling in maize, cloned their encoding genes (ZmPYL3 and ZmPP2C16), verified the interaction between these two proteins in response to exogenous ABA induction by yeast two-hybrid assay and bimolecular fluorescence complementation, and investigated the expression patterns of these two genes under the induction of exogenous ABA by real-time fluorescence quantitative PCR. The results indicated that the ZmPYL3 and ZmPP2C16 proteins interacted in vitro and in vivo in response to the induction of exogenous ABA. The downregulated expression of the ZmPYL3 gene and the upregulated expression of the ZmPP2C16 gene are responsive to the induction of exogenous ABA. The ZmPYL3 and ZmPP2C16 proteins are the most probable members of the receptors and the second components of ABA signaling pathway, respectively.     

Cis-elements and trans-factors that regulate expression of the maize Cat1 antioxidant gene in response to ABA and osmotic stress: H2O2 is the likely intermediary signaling molecule for the response

The mechanisms by which the maize antioxidant Cat1 gene responds to abscisic acid (ABA) and osmotic stress have been investigated. Results show that during late embryogenesis, Cat1 expression in vivo is independent of endogenous ABA levels. However, exogenously applied ABA significantly enhances Cat1 expression. Transient assays using particle bombardment show that the proximal ABRE2 element on the Cat1 promoter is responsible for the induction of Cat1 expression by ABA. We further show that ABA induces the expression of Cat1 via the interaction between ABRE2 and one of its binding proteins, CBF1 (Cat1 binding factor 1). Using ABA-deficient mutant embryos, we show that osmotic stress induces Cat1 expression through two alternate signal transduction pathways: an ABA signaling pathway leading to the interaction between the ABRE2 motif and CBF1, and a pathway via the interaction of ABRE2 and CBF2 (Cat1 binding factor 2) that is independent of ABA. The data presented clearly suggest that hydrogen peroxide (H2O2) plays an important intermediary role in the ABA signal transduction pathway leading to the induction of the Cat1 gene.