Prime编辑技术及其在植物生物学研究中的应用前景。

Q2 Agricultural and Biological Sciences 生物设计研究(英文) Pub Date : 2020-06-26 eCollection Date: 2020-01-01 DOI:10.34133/2020/9350905
Md Mahmudul Hassan, Guoliang Yuan, Jin-Gui Chen, Gerald A Tuskan, Xiaohan Yang
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引用次数: 26

摘要

植物生物学中的许多应用需要准确编辑基因组,包括校正点突变、单核苷酸多态性(SNPs)的掺入以及将多核苷酸插入/缺失(indel)引入基因组中的预定位置。使用现有的基因组编辑技术,如CRISPR-Cas系统,这些类型的修饰是可能的,这需要在靶DNA位点中诱导双链断裂,并提供包含所需编辑序列的供体DNA分子。然而,植物中同源重组的频率低,并且难以递送供体DNA分子,使得这一过程效率极低。另一种被称为基础编辑的技术可以进行精确的编辑;然而,只能获得某些类型的修改,例如C/g-to-T/A和A/T-to-g/C。最近,一种新型的基因组编辑技术被称为“引物编辑”,它可以实现各种类型的编辑,如任何碱基到碱基的转换,包括两种转换(C→T、 G→A、 A→G、 和T→C) 和颠换突变(C→A、 C→G、 G→C、 G→T、 A→C、 A→T、 T→A、 和T→G) 以及不需要在DNA中诱导双链断裂的小茚。由于初级编辑具有广泛的灵活性,可以在基因组中实现不同类型的编辑,因此它在开发用于各种目的的优质作物方面具有巨大的潜力,例如提高产量、提供对各种非生物和生物胁迫的抗性,以及提高植物产品的质量。在这篇综述中,我们描述了原始编辑技术,并讨论了它的局限性和在植物生物学研究中的潜在应用。
本文章由计算机程序翻译,如有差异,请以英文原文为准。

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Prime Editing Technology and Its Prospects for Future Applications in Plant Biology Research.

Many applications in plant biology requires editing genomes accurately including correcting point mutations, incorporation of single-nucleotide polymorphisms (SNPs), and introduction of multinucleotide insertion/deletions (indels) into a predetermined position in the genome. These types of modifications are possible using existing genome-editing technologies such as the CRISPR-Cas systems, which require induction of double-stranded breaks in the target DNA site and the supply of a donor DNA molecule that contains the desired edit sequence. However, low frequency of homologous recombination in plants and difficulty of delivering the donor DNA molecules make this process extremely inefficient. Another kind of technology known as base editing can perform precise editing; however, only certain types of modifications can be obtained, e.g., C/G-to-T/A and A/T-to-G/C. Recently, a new type of genome-editing technology, referred to as "prime editing," has been developed, which can achieve various types of editing such as any base-to-base conversion, including both transitions (C→T, G→A, A→G, and T→C) and transversion mutations (C→A, C→G, G→C, G→T, A→C, A→T, T→A, and T→G), as well as small indels without the requirement for inducing double-stranded break in the DNA. Because prime editing has wide flexibility to achieve different types of edits in the genome, it holds a great potential for developing superior crops for various purposes, such as increasing yield, providing resistance to various abiotic and biotic stresses, and improving quality of plant product. In this review, we describe the prime editing technology and discuss its limitations and potential applications in plant biology research.

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