植物 Prime 编辑系统的开发用于精确基因组编辑。

Development of Plant Prime-Editing Systems for Precise Genome Editing.

机构信息

Key Laboratory of Rice Genetics & Breeding, Institute of Rice Research, Anhui Academy of Agricultural Science, Hefei 230031, China.

出版信息

Plant Commun. 2020 Apr 8;1(3):100043. doi: 10.1016/j.xplc.2020.100043. eCollection 2020 May 11.

DOI:10.1016/j.xplc.2020.100043

PMID:33367239

原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC7747961/

Abstract

Prime-editing systems have the capability to perform efficient and precise genome editing in human cells. In this study, we first developed a plant prime editor 2 (pPE2) system and test its activity by generating a targeted mutation on an HPT reporter in rice. Our results showed that the pPE2 system could induce programmable editing at different genome sites. In transgenic T plants, pPE2-generated mutants occurred with 0%-31.3% frequency, suggesting that the efficiency of pPE2 varied greatly at different genomic sites and with prime-editing guide RNAs of diverse structures. To optimize editing efficiency, guide RNAs were introduced into the pPE2 system following the PE3 and PE3b strategy in human cells. However, at the genomic sites tested in this study, pPE3 systems generated only comparable or even lower editing frequencies. Furthemore, we developed a surrogate pPE2 system by incorporating the HPT reporter to enrich the prime-edited cells. The nucleotide editing was easily detected in the resistant calli transformed with the surrogate pPE2 system, presumably due to the enhanced screening efficiency of edited cells. Taken together, our results indicate that plant prime-editing systems we developed could provide versatile and flexible editing in rice genome.

摘要

碱基编辑系统具备在人类细胞中进行高效且精准基因组编辑的能力。在本研究中，我们首先开发了一种植物碱基编辑器 2（pPE2）系统，并通过在水稻中的 HPT 报告基因上产生靶向突变来测试其活性。结果表明，pPE2 系统可在不同的基因组位点诱导可编程编辑。在转基因 T 植株中，pPE2 产生的突变体频率为 0%-31.3%，这表明 pPE2 在不同的基因组位点和具有不同结构的碱基编辑向导 RNA 下的效率差异很大。为了优化编辑效率，我们按照人类细胞中的 PE3 和 PE3b 策略将向导 RNA 引入 pPE2 系统。然而，在本研究中测试的基因组位点上，pPE3 系统仅产生可比甚至更低的编辑频率。此外，我们通过将 HPT 报告基因整合到 pPE2 系统中开发了一种替代 pPE2 系统，以富集碱基编辑的细胞。在转化了替代 pPE2 系统的抗性愈伤组织中，很容易检测到核苷酸编辑，这可能是由于编辑细胞的筛选效率得到了提高。总之，我们的研究结果表明，我们开发的植物碱基编辑系统可为水稻基因组提供多功能且灵活的编辑。

https://cdn.ncbi.nlm.nih.gov/pmc/blobs/dbeb/7747961/bef3b526524b/gr1.jpg

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植物 Prime 编辑系统的开发用于精确基因组编辑。

Development of Plant Prime-Editing Systems for Precise Genome Editing.

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