Trehalose Metabolites in Arabidopsis-elusive, active and central.

The arabidopsis book Pub Date : 2009-01-01 Epub Date: 2009-07-14 DOI:10.1199/tab.0122
Henriette Schluepmann, Matthew Paul
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引用次数: 0

Abstract

Trehalose is an alpha, alpha-1, 1-linked glucose disaccharide. In plants, trehalose is synthesized in two steps. Firstly, trehalose-6-phosphate synthase (TPS) converts UDP-glucose and glucose-6-phosphate to trehalose-6-phosphate (T6P); secondly, T6P-phosphatase (TPP) converts T6P into trehalose and Pi. Trehalose is further cleaved into glucose by trehalase. In extracts of most plants, including Arabidopsis, levels of both trehalose and T6P are low, nearing detection limits, and this has delayed research into their function. Trehalose is transported widely in plants, but transport of T6P is not thought to occur except possibly at the subcellular level. Feeding trehalose to Arabidopsis seedlings alters carbon allocation with massive starch accumulation in cotyledons and leaves and absence of starch and growth in shoot and root apices.The Arabidopsis genome has experienced extensive radiation of genes likely encoding enzymes of T6P metabolism: 4 and 10 genes are found with homology to TPS and TPP respectively and 7 genes are found with homology to both TPS and TPP. Complementation of Saccharomyces cerevisiae mutants has shown that AtTPS1, AtTPPA and AtTPPB are functional enzymes. In contrast just a single gene encoding a protein with trehalase activity has been found. Whilst most TPS proteins appear cytosolic, strikingly, some TPPs appear targeted to chloroplasts; trehalase on the other hand is extracellular. Transporters of trehalose and T6P have yet to be described. Arabidopsis tps1 mutants are embryo lethal and results suggest that T6P is essential for several other steps in development including root growth and floral transition. Accordingly, altering T6P content has a profound effect on plant habitus and impacts metabolite profiles, sugar utilization and photosynthesis. These large effects have hindered dissection of cause and effect. In contrast, plants with large alterations in sucrose-6-phosphate concentrations are indistinguishable from wild type, suggesting very different functions for these compounds. Recently, T6P at low micromolar concentrations has been shown in vitro and in vivo to inhibit SnRK1 of the SNF1/AMPK group of protein kinases. This supports a function for T6P as a sugar signaling molecule integrating metabolism and development in plants in relation to carbon supply.Genetic engineering of Arabidopsis as well as tobacco, potato and rice with TPS or TPS/TPP protein fusions reveals that trehalose metabolism also mediates multiple abiotic stress tolerances. Trehalose applications also mediate biotic stress resistances. Both Escherichia coli and Saccharomyces cerevisiae TPS/TPP protein fusions can be used to engineer stress tolerance suggesting that metabolites rather than proteins of the trehalose pathway are key stress tolerance elicitors. Results underscore the central role of trehalose metabolites in integrating carbon metabolism and stress responses with plant development.

拟南芥中的脱卤糖代谢物--隐性、活性和核心。
曲哈糖是一种α,α-1,1-连接的葡萄糖二糖。在植物体内,三卤糖分两步合成。首先,曲哈糖-6-磷酸合成酶(TPS)将 UDP-葡萄糖和葡萄糖-6-磷酸转化为曲哈糖-6-磷酸(T6P);其次,T6P-磷酸酶(TPP)将 T6P 转化为曲哈糖和 Pi。脱卤糖在脱卤酶的作用下进一步裂解为葡萄糖。在大多数植物(包括拟南芥)的提取物中,脱卤糖和 T6P 的含量都很低,接近检测极限,这也延误了对它们功能的研究。脱卤糖在植物体内的运输范围很广,但 T6P 的运输被认为除了可能在亚细胞水平外不会发生。给拟南芥幼苗喂食三卤糖会改变碳的分配,在子叶和叶片中大量积累淀粉,而在芽和根尖则没有淀粉和生长。拟南芥基因组中可能编码 T6P 代谢酶的基因经历了广泛的辐射:与 TPS 和 TPP 同源的基因分别有 4 个和 10 个,与 TPS 和 TPP 同源的基因有 7 个。对酿酒酵母突变体的补体研究表明,AtTPS1、AtTPPA 和 AtTPPB 是功能性酶。相比之下,只发现了一个编码具有三卤酶活性的蛋白质的基因。虽然大多数 TPS 蛋白都具有细胞膜活性,但令人吃惊的是,一些 TPPs 似乎以叶绿体为目标;而另一方面,trehalase 则具有细胞外活性。三卤糖和 T6P 的转运体尚未被描述。拟南芥的 tps1 突变体是胚胎致死的,结果表明 T6P 对于发育过程中的其他几个步骤(包括根的生长和花的过渡)至关重要。因此,改变 T6P 的含量会对植物的习性产生深远的影响,并影响代谢物的分布、糖的利用和光合作用。这些巨大的影响阻碍了对因果关系的分析。相比之下,蔗糖-6-磷酸浓度发生巨大变化的植物与野生型没有区别,这表明这些化合物具有非常不同的功能。最近,体外和体内研究表明,低微摩尔浓度的 T6P 可抑制 SNF1/AMPK 蛋白激酶组中的 SnRK1。用 TPS 或 TPS/TPP 蛋白融合体对拟南芥、烟草、马铃薯和水稻进行基因工程改造后发现,三卤糖的新陈代谢还介导了多种非生物胁迫耐受性。应用脱卤糖还能介导生物胁迫抗性。大肠杆菌和酿酒酵母的 TPS/TPP 蛋白融合都可用于设计应激耐受性,这表明三卤糖途径的代谢物而不是蛋白质是关键的应激耐受性诱导物。研究结果强调了三卤糖代谢产物在将碳代谢和胁迫响应与植物生长过程相结合方面的核心作用。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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