Using CRISPR/ttLbCas12a for in planta Gene Targeting in A. thaliana.

Q1 Agricultural and Biological Sciences
Laura Merker, Patrick Schindele, Holger Puchta
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引用次数: 7

Abstract

CRISPR/Cas systems enable gene editing through the induction of site-specific DNA double-strand breaks (DSB). However, the nature of the induced modification highly depends on the mechanism used for DNA DSB repair. Non-homologous end joining (NHEJ)-mediated targeted mutagenesis induced by CRISPR/Cas is an already standardly applied tool, which can lead to various different kinds of mutations at a specific genomic site. Nevertheless, precise genome modification using homologous donor sequences is still challenging in plants. Applications depending on the less frequent homologous recombination (HR) require further improvements to create an attractive and efficient tool for general application in plants. Focusing on this issue, we developed the in planta gene targeting (ipGT) system, which is based on the simultaneous excision of a stably integrated, homologous donor sequence and the induction of a DSB within the target site. In recent years, several improvements were achieved enhancing gene targeting (GT) frequencies. After the successful application of Streptococcus pyogenes Cas9 (SpCas9) and Staphylococcus aureus Cas9 (SaCas9) for ipGT, we were able to further improve the system using Lachnospiraceae bacterium Cas12a (LbCas12a), which also enables cleavage in T-rich regions. Most recently, we tested an improved, temperature-tolerant version of LbCas12a (ttLbCas12a) for ipGT and were able to further increase GT efficiencies. Here, we describe the experimental procedure of the recently published ipGT system using ttLbCas12a in Arabidopsis thaliana in detail. © 2020 The Authors. Basic Protocol 1: Construction of CRISPR/ttLbCas12a expression vector to analyze ipGT efficiencies Basic Protocol 2: Achieving heritable GT plants.

利用CRISPR/ttLbCas12a在拟南芥中定位植物基因。
CRISPR/Cas系统通过诱导位点特异性DNA双链断裂(DSB)实现基因编辑。然而,诱导修饰的性质在很大程度上取决于用于DNA DSB修复的机制。由CRISPR/Cas诱导的非同源末端连接(NHEJ)介导的靶向诱变已经是一种标准应用的工具,它可以在特定的基因组位点导致各种不同类型的突变。然而,在植物中使用同源供体序列进行精确的基因组修饰仍然具有挑战性。依赖于频率较低的同源重组(HR)的应用需要进一步改进,以创造一个有吸引力和有效的工具,用于植物的普遍应用。针对这一问题,我们开发了植物基因靶向(ipGT)系统,该系统基于同时切除稳定整合的同源供体序列并在目标位点诱导DSB。近年来,在提高基因靶向频率方面取得了一些进展。在将化脓性链球菌Cas9 (SpCas9)和金黄色葡萄球菌Cas9 (SaCas9)成功应用于ipGT后,我们利用毛螺杆菌科细菌Cas12a (LbCas12a)进一步完善了该系统,该系统也能在富含t的区域进行切割。最近,我们测试了一种改进的、耐温版本的LbCas12a (ttLbCas12a)用于ipGT,并能够进一步提高GT效率。本文详细介绍了利用ttLbCas12a在拟南芥中构建ipGT系统的实验过程。©2020作者。基本方案1:构建CRISPR/ttLbCas12a表达载体分析ipGT效率基本方案2:实现可遗传的GT植物
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来源期刊
Current protocols in plant biology
Current protocols in plant biology Agricultural and Biological Sciences-Plant Science
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期刊介绍: Sound and reproducible laboratory methods are the foundation of scientific discovery. Yet nuances that are critical for an experiment''s success are not captured in the primary literature but exist only as part of a lab''s oral tradition. Current Protocols in Plant Biology provides reproducible step-by-step instructions for protocols relevant to plant research. Furthermore, Current Protocols content is thoughtfully organized by topic for optimal usage and to maximize contextual knowledge. Quarterly issues allow Current Protocols in Plant Biology to constantly evolve to keep pace with the newest discoveries and developments. Current Protocols in Plant Biology is the comprehensive source for protocols in the multidisciplinary field of plant biology, providing an extensive range of protocols from basic to cutting edge. Coverage includes: Extraction and analysis of DNA, RNA, proteins Chromosome analysis Transcriptional analysis Protein expression Metabolites Plant enzymology Epigenetics Plant genetic transformation Mutagenesis Arabidopsis, Maize, Poplar, Rice, and Soybean, and more.
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