Ting Li, Ke Ding, Ziming Bao, Quan Ma, Chenyang Huang, Jie Cao, Xiao Shu, Minsong Gao, Zisheng Luo, Xushen Xiong, Jianzhao Liu
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引用次数: 0
Abstract
The current expansion of RNA epitranscriptomics calls for direct and high-precision mapping tools to characterize the intrinsically low abundant RNA modifications. Here, we developed a strategy, termed Graft-seq, which harnesses specific enzymatic and chemical reactions on an RNA modification site to covalently graft a known RNA branch and further utilizes the branch-to-main-chain or main-chain-to-branch landing/jumping site signal during reverse transcription to determine the locations of RNA modifications at single-base resolution. We developed a matched bioinformatics analysis pipeline for Graft-seq and successfully mapped internal N6-methyladenosine (m6A) and cap N6,2'-O-dimethyladenosine (m6Am), as well as nicotinamide adenine dinucleotide (NAD) on transcriptome-wide mRNAs and/or nuclear non-coding RNAs in different cell lines. Paralleled comparisons of Graft-seq with available techniques confirmed the effectiveness of the RNA grafting strategy. Graft-seq represents a direct and enrichment-free technique for characterizing RNA modifications at base resolution and offers the potential to discover new RNA modifications and RNA-RNA interactions.
当前RNA表转录组学的扩展需要直接和高精度的制图工具来表征本质上低丰度的RNA修饰。在这里,我们开发了一种称为graft -seq的策略,该策略利用RNA修饰位点上的特定酶和化学反应共价嫁接已知的RNA分支,并进一步利用逆转录过程中分支到主链或主链到分支的着陆/跳跃位点信号,以单碱基分辨率确定RNA修饰的位置。我们为Graft-seq开发了一个匹配的生物信息学分析管道,并成功地在不同细胞系的转录组mrna和/或核非编码rna上定位了内部N6-甲基腺苷(m6A)和帽n6,2 '- o -二甲基腺苷(m6Am)以及烟酰胺腺嘌呤二核苷酸(NAD)。Graft-seq与现有技术的平行比较证实了RNA嫁接策略的有效性。Graft-seq代表了一种在碱基分辨率下表征RNA修饰的直接和无富集技术,并提供了发现新的RNA修饰和RNA-RNA相互作用的潜力。
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