[Metabolic engineering of edible plant oils].

植物生理与分子生物学学报 Pub Date : 2007-12-01
Ai-Qin Yue, Xi-Ping Sun, Run-Zhi Li
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Abstract

Plant seed oil is the major source of many fatty acids for human nutrition, and also one of industrial feedstocks. Recent advances in understanding of the basic biochemistry of seed oil biosynthesis, coupled with cloning of the genes encoding the enzymes involved in fatty acid modification and oil accumulation, have set the stage for the metabolic engineering of oilseed crops that produce "designer" plant seed oils with the improved nutritional values for human being. In this review we provide an overview of seed oil biosynthesis/regulation and highlight the key enzymatic steps that are targets for gene manipulation. The strategies of metabolic engineering of fatty acids in oilseeds, including overexpression or suppression of genes encoding single or multi-step biosynthetic pathways and assembling the complete pathway for the synthesis of long-chain polyunsaturated fatty acids (e.g. arachidonic acid, eicosapentaenoic acid and docosahexaenoic acid) are described in detail. The current "bottlenecks" in using common oilseeds as "bioreactors" for commercial production of high-value fatty acids are analyzed. It is also discussed that the future research focuses of oilseed metabolic engineering and the prospects in creating renewable sources and promoting the sustainable development of human society and economy.

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[食用植物油代谢工程]。
植物籽油是人体营养中多种脂肪酸的主要来源,也是工业原料之一。近年来对种子油生物合成的基本生物化学认识的进展,加上脂肪酸修饰和油脂积累酶编码基因的克隆,为油籽作物的代谢工程创造了条件,从而生产出对人类有更高营养价值的“设计”植物种子油。在这篇综述中,我们概述了种子油的生物合成/调控,并强调了关键的酶的步骤是基因操作的目标。详细介绍了油籽脂肪酸代谢工程的策略,包括过表达或抑制编码单步或多步生物合成途径的基因,以及组装长链多不饱和脂肪酸(如花生四烯酸、二十碳五烯酸和二十二碳六烯酸)合成的完整途径。分析了目前使用普通油籽作为商业生产高价值脂肪酸的“生物反应器”的“瓶颈”。展望了油籽代谢工程今后的研究重点和在创造可再生能源、促进人类社会经济可持续发展方面的前景。
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