A CRISPR mis-insertion in the Zic3 5'UTR inhibits in vivo translation and is predicted to result in formation of an mRNA stem-loop hairpin.

IF 1.8 4区生物学 Q3 BIOLOGY

Biology Open Pub Date : 2025-03-15 Epub Date: 2025-03-17 DOI:10.1242/bio.061677

Helen M Bellchambers, Maria B Padua, Stephanie M Ware

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引用次数: 0

Abstract

Zic3 loss of function is associated with a range of congenital defects, including heterotaxy and isolated heart defects in humans, as well as neural tube defects, situs anomalies, and tail kinks in model organisms. Here, we describe a novel Zic3ins5V mouse line generated due to a mis-insertion during the CRISPR genome editing process, which altered the Zic3 5'UTR structure. Mice with this insertion developed similar phenotypes to Zic3LacZ null mice, including heterotaxy, isolated heart defects, neural tube defects and tail kinks. Surprisingly, gene expression analysis revealed that the novel Zic3ins5V line displays higher levels of Zic3 mRNA, but western blot analysis confirmed that levels of ZIC3 were greatly reduced in vivo. RNAfold, an RNA secondary structure prediction tool, showed that this mis-insertion may cause the formation of a large stem-loop hairpin incorporating some of the 5'UTR and first exon of Zic3, and the insertion of similar hairpins in a cell-based assay caused the loss of ZIC3 expression. Thus, this mouse line displays a loss of ZIC3 protein consistent with the inhibitory effects of 5'UTR stem-loop hairpin structures.

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CRISPR在Zic3 5'UTR中的错误插入抑制了体内翻译，并预计会导致mRNA茎环发夹的形成。

Zic3功能丧失与一系列先天性缺陷有关，包括人类的异位性和孤立性心脏缺陷，以及模式生物的神经管缺陷、部位异常和尾巴扭结。在这里，我们描述了一种新的Zic3ins5V小鼠系，这是由于CRISPR基因组编辑过程中的错误插入改变了Zic3 5'UTR结构而产生的。插入Zic3LacZ的小鼠表现出与未插入Zic3LacZ的小鼠相似的表型，包括异位、分离的心脏缺陷、神经管缺陷和尾巴扭结。令人惊讶的是，基因表达分析显示，新的Zic3ins5V系显示出更高水平的Zic3 mRNA，但western blot分析证实，体内Zic3水平大大降低。RNA二级结构预测工具RNAfold显示，这种错误插入可能导致形成一个包含Zic3的一些5'UTR和第一外显子的大茎环发夹，并且在基于细胞的实验中插入类似的发夹导致Zic3的丢失。因此，该小鼠系显示ZIC3蛋白的缺失与5'UTR茎环发夹结构的抑制作用一致。

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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来源期刊

Biology Open BIOLOGY-

CiteScore

3.90

自引率

0.00%

发文量

162

审稿时长

8 weeks

期刊介绍： Biology Open (BiO) is an online Open Access journal that publishes peer-reviewed original research across all aspects of the biological sciences. BiO aims to provide rapid publication for scientifically sound observations and valid conclusions, without a requirement for perceived impact.