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细胞代谢过程中的酶促糖基化及其功能 总被引:1,自引:0,他引:1
细胞代谢过程中多样的生化修饰反应能够精细调控细胞的活力与功能。其中,酶促糖基化是细胞代谢调控过程中普遍存在的一种分子修饰,对维持和调节细胞功能具有重要影响。糖基转移酶通过将糖基供体的糖基转移至相应的受体分子来实现糖基化修饰。受体分子经过糖基化修饰会改变其在细胞内的稳定性、溶解性和区域定位等特性,并在调节细胞周期、信号转导、蛋白质表达调控、应答反应和清除细胞异物等诸多生物过程中起着重要作用。简要介绍了细胞代谢过程中糖基转移酶超家族的分类、命名和催化机制。重点阐述细胞中蛋白质类生物大分子和小分子化合物的糖基化反应及其在细胞代谢过程中的功能。展望了细胞中糖基化反应及糖基转移酶在人类健康、医药产品、工业催化、食品和农业等领域的应用前景。 相似文献
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蛋白质的O-GlcNAc糖基化现象发现迄今已有30多年历史.动物中,O-GlcNAc糖基化在调控细胞信号转导、基因转录、表观遗传和新陈代谢等方面发挥重要作用.而植物中,O-GlcNAc糖基化在近几年才得到关注并进行初步研究.本文对植物中O-GlcNAc修饰的糖供体合成途径、O-GlcNAc修饰关键酶、O-GlcNAc修饰蛋白的检测及功能等方面的研究工作进行归纳总结,发现O-GlcNAc糖基化在植物的生长发育、激素网络调控、信号转导、植物病毒侵染等过程均发挥重要作用,为进一步研究植物中O-GlcNAc糖基化的生物学功能提供参考. 相似文献
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糖基转移酶(glycosyltransferases,GTs)将糖基从活化的供体转移到糖、脂、蛋白质和核酸等受体,其参与的蛋白质糖基化是最重要的翻译后修饰(post-translational modifications,PTMs)之一。近年来越来越多的研究证明,糖基转移酶与致病菌毒力密切相关,在致病菌的黏附、免疫逃逸和定殖等生物学过程中发挥关键作用。目前,已鉴定的糖基转移酶根据其蛋白质三维结构特征分为3种类型GT-A、GT-B和GT-C,其中常见的是GT-A和GT-B型。在致病菌中发挥黏附功能的糖基转移酶,在结构上属于GT-B或GT-C型,对致病菌表面蛋白质(黏附蛋白、自转运蛋白等)进行糖基化修饰,在致病菌黏附、生物被膜的形成和毒力机制发挥具有重要作用。糖基转移酶不仅参与致病菌黏附这一感染初始过程,其中属于GT-A型的一类致病菌糖基转移酶会进入宿主细胞,通过糖基化宿主蛋白质影响宿主信号传导、蛋白翻译和免疫应答等生物学功能。本文就常见致病菌糖基转移酶的结构及其糖基化在致病机制中的作用进行综述,着重介绍了特异性糖基化高分子量(high-molecular-weight,HMW)黏附蛋白的糖基转移酶、针对富丝氨酸重复蛋白(serine-rich repeat proteins,SRRP)糖基化修饰的糖基转移酶、细菌自转运蛋白庚糖基转移酶(bacterial autotransporter heptosyltransferase,BAHT)家族、N-糖基化蛋白质系统和进入宿主细胞发挥毒力作用的大型梭菌细胞毒素、军团菌(Legionella)葡萄糖基转移酶以及肠杆菌科的效应子NleB。为揭示致病菌中糖基转移酶致病机制的系统性研究提供参考,为未来致病菌的诊断、药物设计研发以及疫苗开发等提供科学依据和思路。 相似文献
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《生物化学与生物物理进展》2017,(10)
蛋白质的O-GlcNAc糖基化现象发现迄今已有30多年历史.动物中,O-GlcNAc糖基化在调控细胞信号转导、基因转录、表观遗传和新陈代谢等方面发挥重要作用.而植物中,O-GlcNAc糖基化在近几年才得到关注并进行初步研究.本文对植物中O-GlcNAc修饰的糖供体合成途径、O-GlcNAc修饰关键酶、O-GlcNAc修饰蛋白的检测及功能等方面的研究工作进行归纳总结,发现O-GlcNAc糖基化在植物的生长发育、激素网络调控、信号转导、植物病毒侵染等过程均发挥重要作用,为进一步研究植物中O-GlcNAc糖基化的生物学功能提供参考. 相似文献
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黄酮糖苷类天然产物是植物中黄酮类化合物的主要存在形式,通过糖基化修饰,可以改变其水溶性、稳定性等,赋予其新的生物活性和功能。黄酮类化合物的糖基化修饰通常由植物源或微生物源的糖基转移酶催化,根据糖基的位置、类型和数量的不同,可形成多种类型的黄酮糖苷类产物。随着合成生物学和代谢工程的快速发展,在微生物中合成植物源黄酮糖苷类天然产物取得了重要进展。综述了糖基转移酶的聚类分析及糖基供体的途径改造,并对代谢工程优化黄酮糖苷类天然产物的微生物合成进行了分析讨论,并对其发展前景进行了展望。 相似文献
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阿拉伯半乳聚糖蛋白(arabinogalactan-proteins,AGPs)是一类高度糖基化的富含羟脯氨酸(hydroxyproline,Hyp)的糖蛋白,广泛分布于植物的细胞壁、质膜和胞外分泌物中,在植物生长和发育的多个过程中发挥重要作用。主要进行两种翻译后修饰,首先通过脯氨酸羟化酶催化的脯氨酸羟基化,随后在一些羟脯氨酸的羟基上添加阿拉伯半乳聚糖(arabinogalactan,AG),以AG为主的多糖可占到AGP分子量的90%,这意味着多糖链主要决定着AGP与其他分子间的相互作用进而影响其功能。从2010年2个能特异糖基化AGP的糖基转移酶At FUT4和At FUT6被鉴定以来,越来越多参与AGP多糖合成的糖基转移酶被鉴定。本文综述了近10年来参与AGP多糖链合成的糖基转移酶的研究进展,并结合棉纤维中AGP研究,讨论了多糖合成的机制及亟待解决的问题,展望了其发展趋势。 相似文献
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糖基转移酶(glycosyltransferases,GT;EC 2.4.x.y)是一个多成员的基因家族,根据其底物特异性和催化特异性被分为99个不同的家族。糖基化反应是由GT催化的一些糖类或非糖类生物分子附加糖基形成共价结合的过程。家族1糖基转移酶一般以尿苷二磷酸-糖(UDP-糖)作为糖基供体,催化糖分子转移到受体分子上,从而调节受体分子生物活性,水溶性和稳定性等。在调节植物激素平衡、内外源物质的解毒以及防御反应和次生代谢产物的修饰方面发挥着重要作用。本综述对UDP-糖基转移酶的分类、命名、功能以及进化进行综述,以期为糖基转移酶相关研究提供一定参考。 相似文献
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苦荞糖基转移酶基因的克隆及活性鉴定 总被引:1,自引:0,他引:1
糖基化修饰在调控各种小分子的溶解度、稳定性及生物活性中具有重要的作用。该研究基于苦荞转录组数据,克隆获得2条糖基转移酶基因(FtUFGT4和FtUFGT5),并对其在大肠杆菌中的表达产物进行酶催活性鉴定。结果表明:(1)获得的苦荞糖基转移酶基因cDNA分别为1 434和1 470 bp,其编码蛋白同属于拟南芥糖基转移酶E类群,可能参与黄酮类化合物的糖基化。(2)多重序列比对表明,FtUFGT4和FtUFGT5蛋白C端都具有PSPG框,其催化活性位点分别是H17和H16;FtUFGT4和FtUFGT5都是典型的植物糖基转移酶GT B结构,二者的蛋白模型能与矢车菊素和UDP进行分子对接。(3)FtUFGT4和FtUFGT5在大肠杆菌中获得了可溶性表达,薄层层析实验表明二者均具有催化矢车菊素糖基化为矢车菊素 3 O 葡萄糖苷的活性。 相似文献
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Glycosyltransferases are members of the multigene superfamily in plants that can transfer single or multiple activated sugars
to a range of plant molecules, resulting in the glycosylation of plant compounds. Although the activities of many glycosyltransferases
and their products have been recognized for a long time, only in recent years were some glycosyltransferase genes identified
and a few functionally characterized in detail. Glycosylation is thought to be one of the most important modification reactions
towards plant secondary metabolites, and plays a key role in maintaining cell homeostasis, thus likely participating in the
regulation of plant growth, development and in defense responses to stress environments. With advances in plant genome projects
and the development of novel technologies in analyzing gene function, significant progress could be made in gaining new insights
into the properties and precise biological roles of plant secondary product glycosyltransferases, and the new knowledge will
have extensive application prospects in the catalytic synthesis of glycoconjugates and metabolic engineering of crops. In
this review, we summarize the current research, highlighting the possible biological roles, of plant secondary metabolite
glycosyltransferases and discuss their potential applications as well as aspects to be further studied in the near future. 相似文献
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Glycosyltransferases are members of the multigene superfamily in plants that can transfer single or multiple activated sugars to a range of plant molecules,resulting in the glycosylation of plant compounds.Although the activities of many glycosyltransferases and their products have been recognized for a long time,only in recent years were some glycosyltransferase genes identified and a few functionally characterized in detail.Glycosylation is thought to be one of the most important modification reactions towards plant secondary metabolites,and plays a key role in maintaining cell homeostasis,thus likely participating in the regulation of plant growth,development and in defense responses to stress environments.With advances in plant genome projects and the development of novel technologies in analyzing gene function,significant progress could be made in gaining new insights into the properties and precise biological roles of plant secondary product glycosyltransferases,and the new knowledge will have extensive application prospects in the catalytic synthesis of glycoconjugates and metabolic engineering of crops.In this review,we summarize the current research,highlighting the possible biological roles,of plant secondary metabolite glycosyltransferases and discuss their potential applications as well as aspects to be further studied in the near future. 相似文献
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Pathological hormone imbalances 总被引:7,自引:0,他引:7
Plant hormones play important roles in regulating developmental processes and signalling networks involved in plant responses to a wide range of biotic and abiotic stresses. Salicylic acid (SA), jasmonates (JA) and ethylene (ET) are well known to play crucial roles in plant disease and pest resistance. However, the roles of other hormones such as abscisic acid (ABA), auxin, gibberellin (GA), cytokinin (CK) and brassinosteroid (BL) in plant defence are less well known. Much progress has been made in understanding plant hormone signalling and plant disease resistance. However, these studies have mostly proceeded independently of each other, and there is limited knowledge regarding interactions between plant hormone-mediated signalling and responses to various pathogens. Here, we review the roles of hormones other than SA, JA and ET in plant defence and the interactions between hormone-mediated signalling, plant defence and pathogen virulence. We propose that these hormones may influence disease outcomes through their effect on SA or JA signalling. 相似文献
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Many small lipophilic compounds in living cells can be modified by glycosylation. These processes can regulate the bioactivity of the compounds, their intracellular location and their metabolism. The glycosyltransferases involved in biotransformations of small molecules have been grouped into Family 1 of the 69 families that are classified on the basis of substrate recognition and sequence relatedness. In plants, these transfer reactions generally use UDP-glucose with acceptors that include hormones such as auxins and cytokinins, secondary metabolites such as flavonoids, and foreign compounds including herbicides and pesticides. In mammalian organisms, UDP-glucuronic acid is typically used in the transfer reactions to endogenous acceptors, such as steroid and thyroid hormones, bile acids and retinoids, and to xenobiotics, including nonsteroidal anti-inflammatory drugs and dietary metabolites. There is widespread interest in this class of enzyme since they are known to function both in the regulation of cellular homeostasis and in detoxification pathways. This review outlines current knowledge of these glycosyltransferases drawing on information gained from studies of plant and mammalian enzymes. 相似文献
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Zhiqiang Jiang Hongwei Guo Laboratory of Protein Engineering Plant Genetic Engineering College of Life Sciences Peking University Beijing China 《Acta Genetica Sinica》2010,(4)
Plant hormones are small molecules that play important roles throughout the life span of a plant,known as auxin,gibberellin,cyto-kinin,abscisic acid,ethylene,jasmonic acid,salicylic acid,and brassinosteroid.Genetic and molecular studies in the model organism Arabidopsis thaliana have revealed the individual pathways of various plant hormone responses.In this study,we selected 479 genes that were convincingly associated with various hormone actions based on genetic evidence.By using these 479 genes as querie... 相似文献
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R. Wang M. Yu J. Xia Z. Ren J. Xing C. Li Q. Xu J. Cang D. Zhang 《Plant biology (Stuttgart, Germany)》2023,25(2):308-321
- Low temperatures limit the geographic distribution and yield of plants. Hormones play an important role in coordinating the growth and development of plants and their tolerance to low temperatures. However, the mechanisms by which hormones affect plant resistance to extreme cold stress in the natural environment are still unclear.
- In this study, two winter wheat varieties with different cold resistances, Dn1 and J22, were used to conduct targeted plant hormone metabolome analysis on the tillering nodes of winter wheat at 5 °C, −10 °C and −25 °C using an LC–ESI–MS/MS system. We screened 39 hormones from 88 plant hormone metabolites and constructed a partial regulatory network of auxin, jasmonic acid and cytokinin.
- GO analysis and enrichment of KEGG pathways in different metabolites showed that the ‘plant hormone signal transduction’ pathway was the most common. Our study showed that extreme low temperature increased the most levels of auxin, cytokinin and salicylic acid, and decreased levels of jasmonic acid and abscisic acid, and that levels of auxin, jasmonic acid and cytokinin in Dn1 were higher than those in J22. These changes in hormone levels were associated with changes in gene expression in synthesis, catabolism, transport and signal transduction pathways. These results differ from the previous hormone regulation mechanisms, which were mostly obtained at 4 °C.
- Our results provide a basis for further understanding the molecular mechanisms by which plant endogenous hormones regulate plant freezing stress tolerance.
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The asparagine-linked oligosaccharides on the pituitary glycoprotein hormones lutropin (LH), follitropin (FSH), and thyrotropin (TSH) consist of a heterogeneous array of neutral, sulfated, sialylated, and sulfated/sialylated structures. In the accompanying paper (Green, E.D., and Baenziger, J.U. (1987) J. Biol. Chem. 262, 25-35), we elucidated the structures of the anionic asparagine-linked oligosaccharides found on the bovine, ovine, and human pituitary glycoprotein hormones. In this study, we determined the relative quantities of the various asparagine-linked oligosaccharides on LH, FSH, and TSH from these three animal species. The proportions of sulfated versus sialylated oligosaccharides varied markedly among the different hormones. Both hormone- and animal species-specific differences in the types and distributions of sulfated, sialylated, and sulfated/sialylated structures were evident. In particular, LH and FSH, which are synthesized in the same pituitary cell and bear alpha-subunits with the identical amino acid sequence, contained significantly different distributions of sulfated and sialylated oligosaccharides. For all three animal species, the ratio of sialylated to sulfated oligosaccharides differed by greater than 10-fold for LH and FSH, with sulfated structures dominating on LH and sialylated structures on FSH. Sialylated oligosaccharides were also heterogeneous with respect to sialic acid linkage (alpha 2,3 versus alpha 2,6). In addition to differences in the proportion of sulfated and sialylated structures on LH and FSH, there were site-specific variations in the amount of mono- and disulfated oligosaccharides at different glycosylation sites on LH alpha-beta dimers. The differences in oligosaccharide structures among the various pituitary glycoprotein hormones as well as among the various glycosylation sites within a single hormone support the hypothesis that glycosylation may serve important functional roles in the expression and/or regulation of hormone bioactivity. 相似文献
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Zhu F Erlandsen H Ding L Li J Huang Y Zhou M Liang X Ma J Wu H 《The Journal of biological chemistry》2011,286(30):27048-27057
Serine-rich repeat glycoproteins (SRRPs) are a growing family of bacterial adhesins found in many streptococci and staphylococci; they play important roles in bacterial biofilm formation and pathogenesis. Glycosylation of this family of adhesins is essential for their biogenesis. A glucosyltransferase (Gtf3) catalyzes the second step of glycosylation of a SRRP (Fap1) from an oral streptococcus, Streptococcus parasanguinis. Although Gtf3 homologs are highly conserved in SRRP-containing streptococci, they share minimal homology with functionally known glycosyltransferases. We report here the 2.3 ? crystal structure of Gtf3. The structural analysis indicates that Gtf3 forms a tetramer and shares significant structural homology with glycosyltransferases from GT4, GT5, and GT20 subfamilies. Combining crystal structural analysis with site-directed mutagenesis and in vitro glycosyltransferase assays, we identified residues that are required for UDP- or UDP-glucose binding and for oligomerization of Gtf3 and determined their contribution to the enzymatic activity of Gtf3. Further in vivo studies revealed that the critical amino acid residues identified by the structural analysis are crucial for Fap1 glycosylation in S. parasanguinis in vivo. Moreover, Gtf3 homologs from other streptococci were able to rescue the gtf3 knock-out mutant of S. parasanguinis in vivo and catalyze the sugar transfer to the modified SRRP substrate in vitro, demonstrating the importance and conservation of the Gtf3 homologs in glycosylation of SRRPs. As the Gtf3 homologs only exist in SRRP-containing streptococci, we conclude that the Gtf3 homologs represent a unique subfamily of glycosyltransferases. 相似文献