多倍体基因的靶向沉默：来自芸薹属-硫苷系统的经验教训。

Targeted silencing of genes in polyploids: lessons learned from Brassica juncea-glucosinolate system.

机构信息

National Institute of Plant Genome Research, Aruna Asaf Ali Marg, New Delhi, 110067, India.

出版信息

Plant Cell Rep. 2019 Jan;38(1):51-57. doi: 10.1007/s00299-018-2348-8. Epub 2018 Oct 10.

Abstract

Intron-spliced hairpin RNAi construct targeting the exonic region of BjuMYB28 driven by the native promoter is the best suited strategy for developing viable low glucosinolate lines in polyploid Brassica juncea. Targeted silencing of specific homolog(s) of a multigene family in polyploids through RNA interference (RNAi) is a challenging effort. Indian oilseed mustard (Brassica juncea), a natural allotetraploid, is expected to have 4-6 copies of every Arabidopsis gene ortholog. In the current study, we have attempted to establish the best gene silencing system suitable for BjuMYB28, a transcription factor gene, with the objective of developing low seed glucosinolate lines in B. juncea. After comparing multiple combinations of BjuMYB28 gene homologs, promoters, target regions (exon and 3' UTR) and silencing strategies (RNAi and antisense), we suggest that the intron-spliced hairpin RNAi construct targeting the specific exonic region of the BjuMYB28 gene under the control of native promoter, whose peak activity synchronises with the highest glucosinolate accumulation phase of the plant, is the best suited strategy for developing viable low glucosinolate lines in polyploid B. juncea.

摘要

利用内源性启动子驱动靶向 BjuMYB28 外显子区域的内含子剪接发夹 RNAi 构建体是在多倍体 Brassica juncea 中开发可行的低硫苷线的最佳策略。通过 RNA 干扰 (RNAi) 靶向多基因家族的特定同源物的靶向沉默是一项具有挑战性的工作。印度芥子油（Brassica juncea），一种天然的异源四倍体，预计每个拟南芥基因同源物有 4-6 个拷贝。在本研究中，我们试图建立最适合转录因子基因 BjuMYB28 的最佳基因沉默系统，目的是在 B. juncea 中开发低种子硫苷线。在比较了 BjuMYB28 基因同源物、启动子、靶区（外显子和 3'UTR）和沉默策略（RNAi 和反义）的多种组合后，我们建议，针对 BjuMYB28 基因的特定外显子区域的内含子剪接发夹 RNAi 构建体在天然启动子的控制下，其峰值活性与植物中硫苷积累阶段的最高阶段同步，是在多倍体 B. juncea 中开发可行的低硫苷线的最佳策略。

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多倍体基因的靶向沉默：来自芸薹属-硫苷系统的经验教训。

Targeted silencing of genes in polyploids: lessons learned from Brassica juncea-glucosinolate system.

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