Akihiro Ito, Lei Wang, Ryotaro Notomi, Shigeki Sasaki, Yosuke Taniguchi
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引用次数: 0
摘要
作为一种直接针对双链 DNA 的基因组靶向工具,三重 DNA 的形成引起了人们的极大兴趣。然而,能形成稳定三重 DNA 的目标双链 DNA 序列碱基对的基本限制限制了其应用。最近,我们报道了具有 2′-脱氧新鸟嘌呤骨架的人工核酸衍生物对 CG 和 5mCG 碱基对的识别。因此,我们试图探索对开发可识别 TA 碱基对的新型人工核酸非常重要的基本骨架。在这项研究中,我们重点研究了苯并咪唑骨架,并引入了一个羟基以实现单点氢键。我们合成了在苯并咪唑上带有羟基的人工核苷类似物,并将其酰胺衍生物加入到三重形成寡核苷酸(TFO)中。凝胶转移试验评估了合成的 TFOs 的三重 DNA 形成能力,结果显示,含有羟基苯并咪唑的 TFOs 成功识别了四种不同序列的 TA 碱基对。此外,与含苯并咪唑的 TFOs 的结果相比,这表明羟基上形成了氢键。因此,羟基苯并咪唑将是识别 TA 碱基对的重要人工核酸骨架。
Development of an Artificial Nucleic Acid Skeleton Allowing for Unnatural-Type Triplex DNA Formation with Duplex DNA Having a TA Inversion Site
Triplex DNA formation has generated much interest as a genomic targeting tool that directly targets duplex DNA. However, fundamental limitations in the base pairs of target duplex DNA sequences that can form stable triplex DNA have limited the application. Recently, we have reported on the recognition of CG and 5mCG base pairs by artificial nucleic acid derivatives with a 2′-deoxynebularine skeleton. Therefore, we attempted to explore the basic skeleton that is important for the development of new artificial nucleic acids allowing for the recognition of TA base pairs. In this study, we focused on a benzimidazole skeleton and introduced a hydroxyl group to enable one-point hydrogen bonding. We have synthesized artificial nucleoside analogues with hydroxyl group on the benzimidazole and incorporated their amidite derivatives into triplex forming oligonucleotides (TFOs). The gel shift assay was performed to evaluate the triplex DNA formation ability of synthesized TFOs, and TFOs containing hydroxybenzimidazole were successfully recognized TA base pairs for all four different sequences. Moreover, compared to the results for the TFOs containing benzimidazole, which suggested hydrogen bonding formation at the hydroxyl group. Therefore, hydroxybenzimidazole would be an important artificial nucleic acid skeleton for TA base pair recognition.
期刊介绍:
The CPB covers various chemical topics in the pharmaceutical and health sciences fields dealing with biologically active compounds, natural products, and medicines, while BPB deals with a wide range of biological topics in the pharmaceutical and health sciences fields including scientific research from basic to clinical studies. For details of their respective scopes, please refer to the submission topic categories below.
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