Advances in plastid transformation for metabolic engineering in higher plants

IF 4.6 4区 农林科学 Q1 BIOTECHNOLOGY & APPLIED MICROBIOLOGY aBIOTECH Pub Date : 2022-10-01 DOI:10.1007/s42994-022-00083-4
Sheng Yang, Yi Deng, Shengchun Li
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引用次数: 2

Abstract

The plastid (chloroplast) genome of higher plants is an appealing target for metabolic engineering via genetic transformation. Although the bacterial-type plastid genome is small compared with the nuclear genome, it can accommodate large quantities of foreign genes that precisely integrate through homologous recombination. Engineering complex metabolic pathways in plants often requires simultaneous and concerted expression of multiple transgenes, the possibility of stacking several transgenes in synthetic operons makes the transplastomic approach amazing. The potential for extraordinarily high-level transgene expression, absence of epigenetic gene silencing and transgene containment due to the exclusion of plastids from pollen transmission in most angiosperm species further add to the attractiveness of plastid transformation technology. This minireview describes recent advances in expanding the toolboxes for plastid genome engineering, and highlights selected high-value metabolites produced using transplastomic plants, including artemisinin, astaxanthin and paclitaxel.

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高等植物质体转化代谢工程研究进展
高等植物的质体(叶绿体)基因组是通过遗传转化进行代谢工程的一个有吸引力的靶点。尽管细菌型质体基因组与核基因组相比较小,但它可以容纳大量通过同源重组精确整合的外源基因。在植物中设计复杂的代谢途径通常需要同时和协同表达多个转基因,在合成操纵子中堆叠多个转基因的可能性使转基因方法令人惊叹。在大多数被子植物物种中,由于质体被排除在花粉传播之外,转基因表达异常高、缺乏表观遗传基因沉默和转基因抑制的潜力进一步增加了质体转化技术的吸引力。这篇小型综述描述了在扩大质体基因组工程工具箱方面的最新进展,并重点介绍了使用转基因植物产生的高价值代谢产物,包括青蒿素、虾青素和紫杉醇。
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来源期刊
CiteScore
7.70
自引率
2.80%
发文量
0
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