Improvements of TKC Technology Accelerate Isolation of Transgene-Free CRISPR/Cas9-Edited Rice Plants 被引量：1

Improvements of TKC Technology Accelerate Isolation of Transgene-Free CRISPR/Cas9-Edited Rice Plants

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摘要 Elimination of the CRISPR/Cas9 constructs in edited plants is a prerequisite for assessing genetic stability, conducting phenotypic characterization, and applying for commercialization of the plants. However, removal of the CRISPR/Cas9 transgenes by genetic segregation and by backcross is laborious and time consuming. We previously reported the development of the transgene killer CRISPR(TKC) technology that uses a pair of suicide genes to trigger self-elimination of the transgenes without compromising gene editing efficiency. The TKC technology enables isolation of transgene-free CRISPR-edited plants within a single generation, greatly accelerating crop improvements. Here, we presented two new TKC vectors that show great efficiency in both editing the target gene and in undergoing self-elimination of the transgenes. The new vectors replaced the CaMV35 S promoter used in our previous TKC vector with two rice promoters to drive one of the suicide genes, providing advantages over our previous TKC vector under certain conditions. The vectors reported here offered more options and flexibility to conduct gene editing experiments in rice. Elimination of the CRISPR/Cas9 constructs in edited plants is a prerequisite for assessing genetic stability, conducting phenotypic characterization, and applying for commercialization of the plants. However, removal of the CRISPR/Cas9 transgenes by genetic segregation and by backcross is laborious and time consuming. We previously reported the development of the transgene killer CRISPR(TKC) technology that uses a pair of suicide genes to trigger self-elimination of the transgenes without compromising gene editing efficiency. The TKC technology enables isolation of transgene-free CRISPR-edited plants within a single generation, greatly accelerating crop improvements. Here, we presented two new TKC vectors that show great efficiency in both editing the target gene and in undergoing self-elimination of the transgenes. The new vectors replaced the CaMV35 S promoter used in our previous TKC vector with two rice promoters to drive one of the suicide genes, providing advantages over our previous TKC vector under certain conditions. The vectors reported here offered more options and flexibility to conduct gene editing experiments in rice.

作者 HE Yubing ZHU Min WANG Lihao WU Junhua WANG Qiaoyan WANG Rongchen ZHAO Yunde

机构地区 National Key Laboratory of Crop Genetic Improvement and National Center of Plant Gene Research (Wuhan) College of Life Science and Technology College of Plant Science & Technology Section of Cell and Developmental Biology

出处《Rice science》 SCIE CSCD 2019年第2期109-117,I0016,I0017,共11页 水稻科学（英文版）

基金 supported by Chinese Ministry of Agriculture and Rural Affairs (Grant No. 2018ZX0801003B) the National Transgenic Science and Technology Program (Grant No. 2016ZX08010002)

关键词 GENOME EDITING SUICIDE gene TRANSGENE KILLER CRISPR Cas9 transgene-free genome editing suicide gene transgene killer CRISPR Cas9 transgene-free

分类号 S [农业科学]

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参考文献11

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同被引文献3

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引证文献1

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