Nishizawa-Yokoi Ayako, Iida Keiko, Mori Akiko, Toki Seiichi
Institute of Agrobiological Sciences, National Agriculture and Food Research Organization (NARO), Tsukuba, Japan.
Graduate School of Nanobioscience, Yokohama City University, Yokohama, Kanagawa, Japan.
Front Genome Ed. 2025 Aug 28;7:1550308. doi: 10.3389/fgeed.2025.1550308. eCollection 2025.
Prime editing (PE) enables precise genome modification, i.e., all 12 types of base substitution, as well as designed insertion and deletion. Previously, we developed an efficient PE system using a pair of engineered pegRNAs (epegRNAs), appending an RNA pseudoknot sequence to the 3'ends of pegRNAs to enhance stability and prevent degradation of the 3'extension. Using a wild-type nSpCas9-based PE system (PE-wt) recognizing an NGG-protospacer adjacent motif (PAM) in this approach, two NGG-PAMs (NGG and CCN) adjacent to the target site are required for targeting by paired pegRNAs; however, this is not the PAM configuration available at most target sites. Using an nSpCas9-NG variant recognizing NG-PAM in PE (PE-NG) can expand applicability. Here, we compare the PE efficiency of PE-wt with paired epegRNAs targeting a distal NGG-PAM PE-NG with paired epegRNAs targeting NG-PAMs adjacent to the target site. By introducing substitution and designated deletion mutations into target genes via PE-wt and PE-NG with paired epegRNAs, we demonstrated that PE-wt could edit the target site efficiently despite targeting the distal PAM site when either of the paired epegRNAs for PE-NG targets PGC-PAM. If epegRNAs for PE-NG are designed to recognize NGA and NGT-PAM, there is no significant difference in frequency between PE-NG and PE-wt. These findings indicate that PE efficiency via PE-NG is particularly low at the NGC-PAM in rice.
碱基编辑(PE)能够实现精确的基因组修饰,即所有12种类型的碱基替换以及设计好的插入和缺失。此前,我们开发了一种高效的PE系统,该系统使用一对工程化的pegRNA(epegRNA),在pegRNA的3'末端附加一个RNA假结序列,以增强稳定性并防止3'延伸部分降解。在这种方法中,使用基于野生型nSpCas9的PE系统(PE-wt)识别NGG-原间隔相邻基序(PAM),配对的pegRNA靶向需要两个与靶位点相邻的NGG-PAM(NGG和CCN);然而,这并不是大多数靶位点可用的PAM配置。在PE中使用识别NG-PAM的nSpCas9-NG变体(PE-NG)可以扩大适用性。在这里,我们比较了PE-wt与靶向远端NGG-PAM的配对epegRNA的PE效率,以及PE-NG与靶向靶位点相邻NG-PAM的配对epegRNA的PE效率。通过使用PE-wt和PE-NG与配对的epegRNA将替换和指定的缺失突变引入靶基因,我们证明,当PE-NG的配对epegRNA之一靶向PGC-PAM时,尽管靶向远端PAM位点,PE-wt仍能有效地编辑靶位点。如果将PE-NG的epegRNA设计为识别NGA和NGT-PAM,则PE-NG和PE-wt之间的频率没有显著差异。这些发现表明,在水稻中,通过PE-NG的PE效率在NGC-PAM处特别低。
