一种模块化的 XNAzyme 在生理条件下切割长的、结构的 RNA，并能够实现等位基因特异性基因沉默。

A modular XNAzyme cleaves long, structured RNAs under physiological conditions and enables allele-specific gene silencing.

机构信息

Cambridge Institute of Therapeutic Immunology & Infectious Disease (CITIID), University of Cambridge, Cambridge, UK.

MRC Laboratory of Molecular Biology, Cambridge, UK.

出版信息

Nat Chem. 2022 Nov;14(11):1295-1305. doi: 10.1038/s41557-022-01021-z. Epub 2022 Sep 5.

DOI:10.1038/s41557-022-01021-z

PMID:36064973

原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC7613789/

Abstract

Nucleic-acid catalysts (ribozymes, DNA- and XNAzymes) cleave target (m)RNAs with high specificity but have shown limited efficacy in clinical applications. Here we report on the in vitro evolution and engineering of a highly specific modular RNA endonuclease XNAzyme, FR6_1, composed of 2'-deoxy-2'-fluoro-β-D-arabino nucleic acid (FANA). FR6_1 overcomes the activity limitations of previous DNA- and XNAzymes and can be retargeted to cleave highly structured full-length (>5 kb) BRAF and KRAS mRNAs at physiological Mg concentrations with allelic selectivity for tumour-associated (BRAF V600E and KRAS G12D) mutations. Phosphorothioate-FANA modification enhances FR6_1 biostability and enables rapid KRAS mRNA knockdown in cultured human adenocarcinoma cells with a G12D-allele-specific component provided by in vivo XNAzyme cleavage activity. These results provide a starting point for the development of improved gene-silencing agents based on FANA or other XNA chemistries.

摘要

核酸催化剂（核酶、DNA 和 XNA 酶）具有高度特异性地切割靶标 (m)RNAs，但在临床应用中显示出有限的疗效。在这里，我们报告了一种高度特异性的模块化 RNA 内切酶 XNAzyme FR6_1 的体外进化和工程改造，它由 2'-脱氧-2'-氟-β-D-阿拉伯核酸 (FANA) 组成。FR6_1 克服了以前 DNA 和 XNA 酶的活性限制，可以在生理 Mg 浓度下靶向切割高度结构化的全长 (>5 kb) BRAF 和 KRAS mRNAs，并对肿瘤相关 (BRAF V600E 和 KRAS G12D) 突变具有等位基因选择性。硫代磷酸酯-FANA 修饰增强了 FR6_1 的生物稳定性，并能够在具有 G12D 等位基因特异性成分的培养的人类腺癌细胞中快速敲低 KRAS mRNA，该成分由体内 XNA 酶切割活性提供。这些结果为基于 FANA 或其他 XNA 化学的改进基因沉默剂的开发提供了起点。

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一种模块化的 XNAzyme 在生理条件下切割长的、结构的 RNA，并能够实现等位基因特异性基因沉默。

A modular XNAzyme cleaves long, structured RNAs under physiological conditions and enables allele-specific gene silencing.

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