硫氧还蛋白与氧化还原反应

硫氧还蛋白是生物体调节体内氧化还原系统的一种重要蛋白质,它参与了生物体内众多的氧化还原反应,其活性位点是-Cys-Gly-Pro-Cys-,在众多的生命过程中,通过构象的改变行使其调节功能。     

植物硫氧还蛋白系统

硫氧还蛋白是一类催化二硫键氧化还原的小蛋白,它通过调控细胞中氧化还原状态发挥重要的作用。在植物中,硫氧还蛋白系统尤为复杂,参与了植物的新陈代谢、转录翻译调控、信号传导以及植物的抗逆反应等。本文主要通过对植物硫氧还蛋白分类、活性位点、结构以及3种硫氧还蛋白系统研究现状进行概述,并对植物的硫氧还蛋白及系统进行了展望,从而较为全面地综述了植物的硫氧还蛋白系统,为进一步了解硫氧还蛋白在植物体内的作用机制奠定基础,也为今后的相关研究提供参考。     

NADPH依赖性硫氧还蛋白还原酶C在植物质体中的作用

硫氧还蛋白的氧化还原调节作用在生物界中普遍存在。它能够还原目标蛋白的二硫键,而自身的活性位点则被氧化。因此,对于新的催化循环,则需要由相应的还原酶将其再次还原成活性形式。硫氧还蛋白对维持高等植物的光合效率同样具有重要意义。叶绿体中的硫氧还蛋白分别由铁氧还蛋白依赖性硫氧还蛋白还原酶和NADPH依赖性硫氧还蛋白还原酶C(NTRC)两种酶还原。NTRC的本质是一种黄素蛋白,除了具有还原酶活性外,还整合了一个硫氧还蛋白结构域,在叶绿体和淀粉体的氧化还原调节中处于核心地位。这种特殊的双功能酶在卡尔文-本森循环、氧化戊糖磷酸途径、抗过氧化、四吡咯代谢、ATP和淀粉合成、生长素和光周期调控中扮演了多重角色。本综述总结了NTRC的生理功能,并讨论了该蛋白质对植物质体氧化还原稳态的调节机制。     

硫氧还蛋白在凋亡途径中的作用机制

硫氧还蛋白（Trx）是体内广泛存在的氧化还原蛋白,其家族中两种重要的硫氧还蛋白：硫氧还蛋白1（thioredoxin1,Trx1）和硫氧还蛋白2（thioredoxin2,Trx2）都含有保守的-Cys-Gly-Pro-Cys-还原序列。由于Trx具有调节细胞生长增殖和抗凋亡的作用,因此Trx在凋亡途径中的作用机制就成为了对抗肿瘤的研究热点。     

蓝藻的硫氧还蛋白

蓝藻(蓝细菌)是一种分布广泛,结构简单的原核生物。不象其它的光合细菌,蓝藻含有叶绿素a,并且象真核藻和高等植物一样,以分解水作为光合电子传递的电子源。有许多种蓝藻能够固氮。大多数丝状蓝藻具有营养胞和异形胞。异形胞是厌氧的固氮场所。       

谷氧还蛋白系统及其对细胞氧化还原态势的调控

细胞内氧化还原调控主要是由谷氧还蛋白系统和硫氧还蛋白系统完成。谷氧还蛋白属于硫氧还蛋白超家族,广泛分布在各种生物体内。作为一种巯基转移酶,它能够催化巯基．二硫键交换反应或者还原蛋白质谷胱甘肽二硫化物,以维持胞内的氧化还原态势。谷氧蛋白系统参与氧化胁迫、蛋白修饰、信号转导、细胞调亡和细胞分化等多种生物过程。对其体内作用靶蛋白的研究,有助于阐明谷氧还蛋白在整个细胞氧化还原网络的重要调控作用。     

硫氧还蛋白抗体柱的制备

目的:探索硫氧还蛋白(Trx)抗体柱对Trx融合蛋白纯化的可行性。方法与结果:对含有Trx基因的质粒表达载体pTrxFus进行改造,在Trx读框之后加入6×His序列,并在大肠杆菌中表达C端带有6×His标签的Trx,经Ni2+柱亲和纯化后制备多克隆抗体;把经蛋白A纯化后的抗体偶联在溴化氰活化的琼脂糖凝胶上,制成Trx抗体柱;用此抗体柱纯化与Trx融合表达的豇豆胰蛋白酶抑制剂(CpTI),SDS-PAGE结果显示获得了纯度较高的Trx-CpTI。结论:用Trx抗体制成的免疫亲和层析柱可以有效纯化Trx融合蛋白。     

硫氧还蛋白相互作用蛋白在糖尿病及其并发症中的作用

硫氧还蛋白相互作用蛋白(thioredoxin-interacting protein,TXNIP)又称维生素D₃上调蛋白1,因其能够与硫氧还蛋白(thioredoxin,Trx)结合并抑制其活性和表达而得名。本文概述了TXNIP的发现与结构,及其自身通过发挥调节糖脂代谢的作用进而影响糖尿病前期的发生发展。并在此基础上总结了TXNIP参与糖尿病发生发展的2条主要途径:TXNIP通过拮抗Trx的抗凋亡作用来激发细胞凋亡信号导致胰岛细胞凋亡;TXNIP过表达促使胰岛细胞磷酸化,进而使抑癌相关蛋白质表达增加,最终引起胰岛细胞衰老。进一步重点阐述了TXNIP在糖尿病心肌病、糖尿病肾病、糖尿病性视网膜病等糖尿病并发症中的作用:TXNIP能通过各种间接途径干预信号通路,进一步参与氧化应激、细胞凋亡、激活炎症、细胞自噬及糖脂代谢等生理生化过程。TXNIP具有极其重要的生物学功能,深入了解TXNIP在糖尿病及其并发症中的影响机制,对糖尿病及其并发症的治疗具有重要意义。最后对TXNIP的研究进行了展望,未来可进一步着手研究TXNIP基因是如何与其他基因或危险因素协同作用,进而共同参与糖尿病及其并发症的发生发展,且TXNIP单个基因甲基化尚不能全面揭示糖尿病及其并发症发生的分子机制,这些后续的深入研究,将为在糖尿病及其并发症的诊断与治疗中作为靶标分子的应用奠定基础。     

硫氧还蛋白与神经退行性病变

神经退行性病变与胞内氧化还原失衡诱发的神经元损伤,死亡有密切关系,硫氧还原白参与维持胞内氧化还原平衡,在氧化应激中起重要的氧还调节作用,因此成为对抗神经退行性病变的重要蛋白之一。硫氧还蛋白可能通过激活某些有氧还调节功能的酶,清除自由基和调节细胞内分子通道等发挥对神经元的保护作用,对转基因动物的研究,进一步提示硫氧还蛋白在神经退行性病变的防治中可能发挥重要作用。     

硫氧还蛋白系统与高氧肺损伤

动物实验和临床研究表明,长期高浓度供氧可引起新生儿尤其早产儿产生氧化应激性损伤,多数学者认为这种氧化应激损伤在高氧肺损伤发生发展中起关键作用. 高氧时,氧化应激对肺泡Ⅱ型上皮细胞(alveolar epithelial cell type Ⅱ,AECⅡ)的影响包括对肺泡上皮细胞的损伤和对肺泡上皮细胞的保护.AECⅡ存活与凋亡有赖于细胞内的氧化还原状态, 通过改变细胞内的氧化还原状态可干预氧化应激.硫氧还蛋白系统( thioredoxin system )在生物体内通过抗氧化和氧化还原调节, 在基因表达、信号转导、细胞生长、细胞凋亡等方面起重要作用.     

Thioredoxin Selectivity for Thiol-based Redox Regulation of Target Proteins in Chloroplasts

Redox regulation based on the thioredoxin (Trx) system is believed to ensure light-responsive control of various functions in chloroplasts. Five Trx subtypes have been reported to reside in chloroplasts, but their functional diversity in the redox regulation of Trx target proteins remains poorly clarified. To directly address this issue, we studied the Trx-dependent redox shifts of several chloroplast thiol-modulated enzymes in vitro and in vivo. In vitro assays using a series of Arabidopsis recombinant proteins provided new insights into Trx selectivity for the redox regulation as well as the underpinning for previous suggestions. Most notably, by combining the discrimination of thiol status with mass spectrometry and activity measurement, we identified an uncharacterized aspect of the reductive activation of NADP-malate dehydrogenase; two redox-active Cys pairs harbored in this enzyme were reduced via distinct utilization of Trxs even within a single polypeptide. In our in vitro assays, Trx-f was effective in reducing all thiol-modulated enzymes analyzed here. We then investigated the in vivo physiological relevance of these in vitro findings, using Arabidopsis wild-type and Trx-f-deficient plants. Photoreduction of fructose-1,6-bisphosphatase was partially impaired in Trx-f-deficient plants, but the global impact of Trx-f deficiency on the redox behaviors of thiol-modulated enzymes was not as striking as expected from the in vitro data. Our results provide support for the in vivo functionality of the Trx system and also highlight the complexity and plasticity of the chloroplast redox network.     

Cytosolic, Mitochondrial Thioredoxins and Thioredoxin Reductases in Arabidopsis Thaliana

Thioredoxins, by reducing disulfide bridges are one of the main participants that regulate cellular redox balance. In plants, the thioredoxin system is particularly complex. The most well-known thioredoxins are the chloroplastic ones, that participate in the regulation of enzymatic activities during the transition between light and dark phases. The mitochondrial system composed of NADPH-dependent thioredoxin reductase and type o thioredoxin has only recently been described. The type h thioredoxin group is better known. Yeast complementation experiments demonstrated that Arabidopsis thaliana thioredoxins h have divergent functions, at least in Saccharomyces cerevisiae. They have diverse affinities for different target proteins, most probably because of structural differences. However, plant thioredoxin h functions still have to be defined.     

Photosynthetic Regulation of the Cyanobacterium Synechocystis sp. PCC 6803 Thioredoxin System and Functional Analysis of TrxB （Trx x） and TrxQ （Trx y） Thioredoxins

The expression of the genes encoding the ferredoxin-thioredoxin system including the ferredoxin-thioredoxin reductase （FTR） genes ftrC and ftrV and the four different thioredoxin genes trxA （m-type; sir0623）, trxB （x-type; sir1139）, trxC （sll1057） and trxQ （y-type; sir0233） of the cyanobacterium Synechocystis sp. PCC 6803 has been studied according to changes in the photosynthetic conditions. Experiments of light-dark transition indicate that the expression of all these genes except trxQ decreases in the dark in the absence of glucose in the growth medium. The use of two electron transport inhibitors, 3-（3,4-dichlorophenyl）-1,1-dimethylurea （DCMU） and 2,5-dibromo-3-methyl-6-isopropyl-p- benzoquinone （DBMIB）, reveals a differential effect on thioredoxin genes expression being trxC and trxQ almost unaffected, whereas trxA, trxB, and the ftr genes are down-regulated. In the presence of glucose, DCMU does not affect gene expression but DBMIB still does. Analysis of the single TrxB or TrxQ and the double TrxB TrxQ Synechocystis mutant strains reveal different functions for each of these thioredoxins under different growth conditions. Finally, a Synechocystis strain was generated containing a mutated version of TrxB （TrxBC34S）, which was used to identify the potential in-vivo targets of this thioredoxin by a proteomic analysis.     

Proteomics Uncovers Proteins Interacting Electrostatically with Thioredoxin in Chloroplasts

The ability of thioredoxin f to form an electrostatic (non-covalent) complex, earlier found with fructose-1,6-bisphosphatase, was extended to include 27 previously unrecognized proteins functional in 11 processes of chloroplasts. The proteins were identified by combining thioredoxin f affinity chromatography with proteomic analysis using tandem mass spectrometry. The results provide evidence that an association with thioredoxin enables the interacting protein to achieve an optimal conformation, so as to facilitate: (i) the transfer of reducing equivalents from the ferredoxin/ferredoxin-thioredoxin reductase complex to a target protein; (ii) in some cases, to enable the channeling of metabolite substrates; (iii) to function as a subunit in the formation of multienzyme complexes.     

Redox Regulatory Mechanism of Transnitrosylation by Thioredoxin

Transnitrosylation and denitrosylation are emerging as key post-translational modification events in regulating both normal physiology and a wide spectrum of human diseases. Thioredoxin 1 (Trx1) is a conserved antioxidant that functions as a classic disulfide reductase. It also catalyzes the transnitrosylation or denitrosylation of caspase 3 (Casp3), underscoring its central role in determining Casp3 nitrosylation specificity. However, the mechanisms that regulate Trx1 transnitrosylation and denitrosylation of specific targets are unresolved. Here we used an optimized mass spectrometric method to demonstrate that Trx1 is itself nitrosylated by S-nitrosoglutathione at Cys⁷³ only after the formation of a Cys³²-Cys³⁵ disulfide bond upon which the disulfide reductase and denitrosylase activities of Trx1 are attenuated. Following nitrosylation, Trx1 subsequently transnitrosylates Casp3. Overexpression of Trx1^C32S/C35S (a mutant Trx1 with both Cys³² and Cys³⁵ replaced by serine to mimic the disulfide reductase-inactive Trx1) in HeLa cells promoted the nitrosylation of specific target proteins. Using a global proteomics approach, we identified 47 novel Trx1 transnitrosylation target protein candidates. From further bioinformatics analysis of this set of nitrosylated peptides, we identified consensus motifs that are likely to be the determinants of Trx1-mediated transnitrosylation specificity. Among these proteins, we confirmed that Trx1 directly transnitrosylates peroxiredoxin 1 at Cys¹⁷³ and Cys⁸³ and protects it from H₂O₂-induced overoxidation. Functionally, we found that Cys⁷³-mediated Trx1 transnitrosylation of target proteins is important for protecting HeLa cells from apoptosis. These data demonstrate that the ability of Trx1 to transnitrosylate target proteins is regulated by a crucial stepwise oxidative and nitrosative modification of specific cysteines, suggesting that Trx1, as a master regulator of redox signaling, can modulate target proteins via alternating modalities of reduction and nitrosylation.Nitric oxide (NO) is an important second messenger for signal transduction in cells. The production of cGMP by guanylyl cyclase, enabled by the binding of NO onto heme, is considered the primary mechanism responsible for the plethora of functions exerted by NO (1). However, S-nitrosylation, the covalent addition of the NO moiety onto cysteine thiols, is increasingly recognized as an important post-translational modification for regulating protein functions (for reviews, see Refs. 2 and 3). S-Nitrosylation is dynamic, reversible, site-specific, and modulated by selected cellular stimuli (4–7). With improved detection sensitivity, an increasing number of S-nitrosylated proteins have been identified by proteomics technologies (5, 8–13). Among the known modified proteins, nitrosylation occurs only on selected cysteines (4, 6, 14–17). Non-enzymatic mechanisms proposed to determine S-nitrosylation specificity include the availability of specific NO donors and protein microenvironments that stabilize the pK_a of acidic target cysteines (18). Furthermore, several enzymes, including hemoglobin (19, 20), superoxide dismutase 1 (21, 22), S-nitrosoglutathione reductase (23–25), and protein-disulfide isomerase (26), have been shown to possess either transnitrosylase or denitrosylase activities. However, an enzymatic system that governs site-specific transnitrosylation and denitrosylation, analogous to the kinase/phosphatase paradigm for regulating protein phosphorylation, has remained largely uncharacterized.Trx1¹ is an important antioxidant protein with protein reductase activity (27, 28). It has been characterized as an antiapoptotic protein because of its ability to suppress proapoptotic proteins, including apoptosis signal-regulating kinase 1 via disulfide reduction and Casp3 via transnitrosylation of Cys¹⁶³ (14, 29). Conversely, Trx1 can denitrosylate Casp3 at Cys¹⁶³, resulting in Casp3 activation (7). Trx1 appears to govern site-specific reversible nitrosylation of selected protein targets (14, 15), but what are the underlying mechanisms that regulate Trx1 transnitrosylation and denitrosylation activities? Are there additional Trx1-mediated transnitrosylation or denitrosylation targets that have not yet been identified? In this study, we used ESI-Q-TOF mass spectrometry (MS) to analyze the nitrosylation of Trx1 and a Casp3 peptide (Casp3p) under different redox conditions. Because of the labile nature of the S–NO bond, direct identification of S-nitrosylated proteins and their specific nitrosylation sites by MS remains challenging (8). A biotin switch method that is based on the derivatization of protein S–NO with a biotinylating agent is typically used for such analyses (8). However, like any indirect method, both false positive and negative identifications have been reported (30). Recently, we developed a method for direct analysis of protein S-nitrosylation by ESI-Q-TOF MS without prior chemical derivatization (31). Here we applied the same technique to determine the regulation of Trx1 by stepwise oxidative and nitrosative modifications of distinct cysteines and its subsequent ability to transnitrosylate target proteins. Nitrosative modification at Cys⁷³ of Trx1 cannot occur without prior attenuation of the Trx1 disulfide reductase and denitrosylase activities via either disulfide bond formation between Cys³² and Cys³⁵ or their mutation to serines. This is a key observation that has never been previously reported. Consequently, we designed a proteomics approach and discovered over 40 putative Trx1 transnitrosylation target proteins. We further characterized the Trx1 transnitrosylation proteome and identified three consensus motifs surrounding the putative Trx1 transnitrosylation sites, suggesting a protein-protein interaction mechanism for determining transnitrosylation specificity.     

二色补血草硫氧还蛋白(Trx)的克隆和表达分析

从二色补血草cDNA文库中分离出1个硫氧还蛋白基因全长cDNA序列。基因全长1138bp,其中,5’非翻译（UTR）区128bp,3＇非翻译区212bp,开放阅读框（ORF）全长798bp,编码265个氨基酸,编码蛋白的分子量为28．58kDa,理论等电点（pI）为9．68。BlastP分析表明二色补血草Trx与拟南芥Trx序列同源性为52％,与葡萄7h序列同源性为76％,从11个物种的氨基酸多序列比对可以看出Trx氨基酸序列保守性较高。实时定量RT-PCR方法检测低温、NaCl和PEG胁迫不同时间后的基因在二色补血草中表达模式的结果表明,NaCl能诱导Trx基因在二色补血草叶中表达,胁迫24h后达到高峰,而聚乙二醇和低温处理则抑制Trx在二色补血草根和叶的表达。     

硫氧还蛋白-1(Trx1)氧化还原状态的检测

硫氧还蛋白-1(thioredoxin-1,Trx1)是一种广泛存在于生物体内的氧化还原调节蛋白,其氧化还原状态的变化是细胞内发挥氧化还原调控作用的重要过程.本文建立了Trx1氧化还原状态的检测方法—氧化还原蛋白免疫印迹法(redox Western blot),即通过碘乙酸(IAA)标记Trx1,根据蛋白所带负电荷的不同,达到分离蛋白氧化与还原状态的目的,并根据能斯特方程计算出相应的氧化还原电势.本方法是在蛋白免疫印迹(Western blot)的基础上建立的,具有低成本、易操作的特点.实验中分别采用H2O2和DTT处理样本,利用此方法检测了细胞裂解液中、细胞内及过表达Trx1氧化还原电势的变化;并检测了HEK293细胞不同生长时期Trx1的氧化还原状态.     

银杏叶片衰老过程中光合生理特性及叶绿体超微结构的变化

选取自然条件下生长的雌雄银杏植株为实验材料,测定了银杏叶片在衰老过程中部分光合生理指标及叶绿体超微结构的变化。检测结果表明：银杏叶片在衰老过程中净光合速率、叶绿素含量均呈下降趋势,SOD、CAT、APX活性均先上升后下降,MDA含量则一直呈现上升趋势。叶片衰老过程中叶绿体类囊体膜片层逐渐松散,直至膜结构逐渐解体,叶绿体内油脂颗粒增大增多,最终解体。雌雄银杏植株在各项生理指标上差异不显著。