Prime editing in mice reveals the essentiality of a single base in driving tissue-specific gene expression.

IF 12.3 1区 生物学 Q1 Agricultural and Biological Sciences Genome Biology Pub Date : 2021-03-16 DOI:10.1186/s13059-021-02304-3
Pan Gao, Qing Lyu, Amr R Ghanam, Cicera R Lazzarotto, Gregory A Newby, Wei Zhang, Mihyun Choi, Orazio J Slivano, Kevin Holden, John A Walker, Anastasia P Kadina, Rob J Munroe, Christian M Abratte, John C Schimenti, David R Liu, Shengdar Q Tsai, Xiaochun Long, Joseph M Miano
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Abstract

Background: Most single nucleotide variants (SNVs) occur in noncoding sequence where millions of transcription factor binding sites (TFBS) reside. Here, a comparative analysis of CRISPR-mediated homology-directed repair (HDR) versus the recently reported prime editing 2 (PE2) system was carried out in mice over a TFBS called a CArG box in the Tspan2 promoter.

Results: Quantitative RT-PCR showed loss of Tspan2 mRNA in aorta and bladder, but not heart or brain, of mice homozygous for an HDR-mediated three base pair substitution in the Tspan2 CArG box. Using the same protospacer, mice homozygous for a PE2-mediated single-base substitution in the Tspan2 CArG box displayed similar cell-specific loss of Tspan2 mRNA; expression of an overlapping long noncoding RNA was also nearly abolished in aorta and bladder. Immuno-RNA fluorescence in situ hybridization validated loss of Tspan2 in vascular smooth muscle cells of HDR and PE2 CArG box mutant mice. Targeted sequencing demonstrated variable frequencies of on-target editing in all PE2 and HDR founders. However, whereas no on-target indels were detected in any of the PE2 founders, all HDR founders showed varying levels of on-target indels. Off-target analysis by targeted sequencing revealed mutations in many HDR founders, but none in PE2 founders.

Conclusions: PE2 directs high-fidelity editing of a single base in a TFBS leading to cell-specific loss in expression of an mRNA/long noncoding RNA gene pair. The PE2 platform expands the genome editing toolbox for modeling and correcting relevant noncoding SNVs in the mouse.

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小鼠的主碱基编辑揭示了单个碱基在驱动组织特异性基因表达中的重要性。
背景:大多数单核苷酸变异(SNV)发生在非编码序列中,而这些序列中存在数百万个转录因子结合位点(TFBS)。在此,我们对 CRISPR 介导的同源定向修复(HDR)与最近报道的质粒编辑 2(PE2)系统进行了比较分析:结果:定量 RT-PCR 显示,在 Tspan2 CArG 框中由 HDR 介导的三个碱基对置换的同源小鼠中,主动脉和膀胱中的 Tspan2 mRNA 丢失,但心脏和大脑中的 Tspan2 mRNA 没有丢失。使用相同的原间隔子,Tspan2 CArG 框中 PE2 介导的单碱基替换的同源小鼠也表现出类似的细胞特异性 Tspan2 mRNA 缺失;在主动脉和膀胱中,重叠的长非编码 RNA 的表达也几乎消失。免疫 RNA 荧光原位杂交验证了 HDR 和 PE2 CArG 盒突变小鼠血管平滑肌细胞中 Tspan2 的缺失。靶向测序显示,在所有 PE2 和 HDR 基因中,靶上编辑的频率各不相同。然而,虽然在所有 PE2 基因中都没有检测到靶上嵌合体,但在所有 HDR 基因中都出现了不同程度的靶上嵌合体。通过靶向测序进行的脱靶分析在许多 HDR 基因发现了突变,但在 PE2 基因中没有发现突变:结论:PE2 可对 TFBS 中的一个碱基进行高保真编辑,导致 mRNA/长非编码 RNA 基因对的细胞特异性表达缺失。PE2 平台扩展了基因组编辑工具箱,可用于建模和校正小鼠的相关非编码 SNV。
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来源期刊
Genome Biology
Genome Biology BIOTECHNOLOGY & APPLIED MICROBIOLOGY-GENETICS & HEREDITY
CiteScore
25.50
自引率
3.30%
发文量
0
审稿时长
14 weeks
期刊介绍: Genome Biology is a leading research journal that focuses on the study of biology and biomedicine from a genomic and post-genomic standpoint. The journal consistently publishes outstanding research across various areas within these fields. With an impressive impact factor of 12.3 (2022), Genome Biology has earned its place as the 3rd highest-ranked research journal in the Genetics and Heredity category, according to Thomson Reuters. Additionally, it is ranked 2nd among research journals in the Biotechnology and Applied Microbiology category. It is important to note that Genome Biology is the top-ranking open access journal in this category. In summary, Genome Biology sets a high standard for scientific publications in the field, showcasing cutting-edge research and earning recognition among its peers.
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