拟南芥中的萜烯专一性代谢

The arabidopsis book Pub Date : 2011-01-01 Epub Date: 2011-04-06 DOI:10.1199/tab.0143
Dorothea Tholl, Sungbeom Lee
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摘要

萜烯是植物次生(或专一)代谢物中最大的一类,是在植物防御或吸引有益生物方面具有生态功能的化合物。利用生化和遗传方法,几乎所有拟南芥(Arabidopsis thaliana)产生萜烯 5 碳结构单元的核心生物合成途径中的酶都得到了表征,并对调控这些途径的转录和转录后/翻译机制有了更深入的了解。大多数前炔基转移酶(将 C(5)-前体缩合为 10、15 和 20 碳前二磷酸中间体的下游酶)的生化功能已经得到描述,但 C(20)-前炔基转移酶的几种同工酶的功能还不十分清楚。烯丙基二磷酸酯通过萜烯合成酶(TPS)家族的酶转化为各种 C(10)-、C(15)- 和 C(20)-terpene 产品。拟南芥 32 个 TPS 基因的基因组组织表明,萜烯合成酶具有物种特异性分化,其组织和细胞类型特异性表达谱可能是在不同生物体的选择压力下出现的。TPS基因和酶的假基因化、差异表达和亚细胞分离,促成了拟南芥品种(生态型)和物种之间萜烯生物合成的自然变异。拟南芥仍将是研究与萜烯生物活性有关的萜烯专门代谢的代谢组织和分子调控网络的重要模型。
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Terpene Specialized Metabolism in Arabidopsis thaliana.

Terpenes constitute the largest class of plant secondary (or specialized) metabolites, which are compounds of ecological function in plant defense or the attraction of beneficial organisms. Using biochemical and genetic approaches, nearly all Arabidopsis thaliana (Arabidopsis) enzymes of the core biosynthetic pathways producing the 5-carbon building blocks of terpenes have been characterized and closer insight has been gained into the transcriptional and posttranscriptional/translational mechanisms regulating these pathways. The biochemical function of most prenyltransferases, the downstream enzymes that condense the C(5)-precursors into central 10-, 15-, and 20-carbon prenyldiphosphate intermediates, has been described, although the function of several isoforms of C(20)-prenyltranferases is not well understood. Prenyl diphosphates are converted to a variety of C(10)-, C(15)-, and C(20)-terpene products by enzymes of the terpene synthase (TPS) family. Genomic organization of the 32 Arabidopsis TPS genes indicates a species-specific divergence of terpene synthases with tissue- and cell-type specific expression profiles that may have emerged under selection pressures by different organisms. Pseudogenization, differential expression, and subcellular segregation of TPS genes and enzymes contribute to the natural variation of terpene biosynthesis among Arabidopsis accessions (ecotypes) and species. Arabidopsis will remain an important model to investigate the metabolic organization and molecular regulatory networks of terpene specialized metabolism in relation to the biological activities of terpenes.

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