Quantitative profiling N1-methyladenosine (m1A) RNA methylation from Oxford nanopore direct RNA sequencing data

IF 4.2 3区生物学 Q1 BIOCHEMICAL RESEARCH METHODS

Methods Pub Date : 2024-05-18 DOI:10.1016/j.ymeth.2024.05.009

Shenglun Chen , Jia Meng , Yuxin Zhang

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引用次数: 0

Abstract

With the recent advanced direct RNA sequencing technique that proposed by the Oxford Nanopore Technologies, RNA modifications can be detected and profiled in a simple and straightforward manner. Majority nanopore-based modification studies were devoted to those popular types such as m6A and pseudouridine. To address current limitations on studying the crucial regulator, m1A modification, we conceived this study. We have developed an integrated computational workflow designed for the detection of m1A modifications from direct RNA sequencing data. This workflow comprises a feature extractor responsible for capturing signal characteristics (such as mean, standard deviations, and length of electric signals), a single molecule-level m1A predictor trained with features extracted from the IVT dataset using classical machine learning algorithms, a confident m1A site selector employing the binomial test to identify statistically significant m1A sites, and an m1A modification rate estimator. Our model achieved accurate molecule-level prediction (Average AUC = 0.9689) and reliable m1A site detection and quantification. To show the feasibility of our workflow, we conducted a study on in vivo transcribed human HEK293 cell line, and the results were carefully annotated and compared with other techniques (i.e., Illumina sequencing-based techniques). We believed that this tool will enabling a comprehensive understanding of the m1A modification and its functional mechanisms within cells and organisms.

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从牛津纳米孔直接 RNA 测序数据中定量分析 N1-甲基腺苷 (m1A) RNA 甲基化。

牛津纳米孔技术公司（Oxford Nanopore Technologies）最近提出了先进的直接 RNA 测序技术，可以简单直接地检测和分析 RNA 修饰。大多数基于纳米孔的修饰研究都集中在那些流行的类型上，如 m6A 和伪尿苷。为了解决目前研究关键调节因子 m1A 修饰的局限性，我们构思了这项研究。我们开发了一个综合计算工作流程，旨在从直接 RNA 测序数据中检测 m1A 修饰。该工作流程包括一个负责捕捉信号特征（如电信号的平均值、标准偏差和长度）的特征提取器、一个使用经典机器学习算法从 IVT 数据集中提取的特征训练的单分子级 m1A 预测器、一个使用二项式检验识别具有统计学意义的 m1A 位点的可信 m1A 位点选择器，以及一个 m1A 修饰率估算器。我们的模型实现了精确的分子级预测（平均 AUC = 0.9689）和可靠的 m1A 位点检测和定量。为了证明我们工作流程的可行性，我们对体内转录的人类 HEK293 细胞系进行了研究，并对结果进行了仔细的注释，并与其他技术（如基于 Illumina 测序的技术）进行了比较。我们相信，这一工具将有助于全面了解 m1A 修饰及其在细胞和生物体内的功能机制。

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

Methods 生物-生化研究方法

CiteScore

9.80

自引率

2.10%

发文量

222

审稿时长

11.3 weeks

期刊介绍： Methods focuses on rapidly developing techniques in the experimental biological and medical sciences. Each topical issue, organized by a guest editor who is an expert in the area covered, consists solely of invited quality articles by specialist authors, many of them reviews. Issues are devoted to specific technical approaches with emphasis on clear detailed descriptions of protocols that allow them to be reproduced easily. The background information provided enables researchers to understand the principles underlying the methods; other helpful sections include comparisons of alternative methods giving the advantages and disadvantages of particular methods, guidance on avoiding potential pitfalls, and suggestions for troubleshooting.