Xudong Liu, Ying Ni, Lianwei Ye, Zhihao Guo, Lu Tan, Jun Li, Mengsu Yang, Sheng Chen, Runsheng Li
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引用次数: 0
Abstract
DNA modifications in bacteria present diverse types and distributions, playing crucial functional roles. Current methods for detecting bacterial DNA modifications via nanopore sequencing typically involve comparing raw current signals to a methylation-free control. In this study, we found that bacterial DNA modification induces errors in nanopore reads. And these errors are found only in one strand but not the other, showing a strand-specific bias. Leveraging this discovery, we developed Hammerhead, a pioneering pipeline designed for de novo methylation discovery that circumvents the necessity of raw signal inference and a methylation-free control. The majority (14 out of 16) of the identified motifs can be validated by raw signal comparison methods or by identifying corresponding methyltransferases in bacteria. Additionally, we included a novel polishing strategy employing duplex reads to correct modification-induced errors in bacterial genome assemblies, achieving a reduction of over 85% in such errors. In summary, Hammerhead enables users to effectively locate bacterial DNA methylation sites from nanopore FASTQ/FASTA reads, thus holds promise as a routine pipeline for a wide range of nanopore sequencing applications, such as genome assembly, metagenomic binning, decontaminating eukaryotic genome assemblies, and functional analysis for DNA modifications.
细菌中的 DNA 修饰具有多种类型和分布,发挥着重要的功能作用。目前通过纳米孔测序检测细菌 DNA 修饰的方法通常是将原始电流信号与无甲基化对照进行比较。在这项研究中,我们发现细菌 DNA 修饰会导致纳米孔读数出现错误。而且这些误差只出现在一条链上,而不是另一条链上,这显示了链特异性偏差。利用这一发现,我们开发了 Hammerhead,这是一种用于从头甲基化发现的开创性流水线,它避免了原始信号推断和无甲基化对照的必要性。大部分(16 个中的 14 个)鉴定出的主题可以通过原始信号比较方法或鉴定细菌中相应的甲基转移酶来验证。此外,我们还采用了一种新颖的抛光策略,利用双链读数纠正细菌基因组组装中由修饰引起的错误,减少了 85% 以上的此类错误。总之,Hammerhead 能让用户从纳米孔 FASTQ/FASTA 读数中有效定位细菌 DNA 甲基化位点,因此有望成为基因组组装、元基因组分选、去污真核基因组组装和 DNA 修饰功能分析等各种纳米孔测序应用的常规管道。
期刊介绍:
Launched in 1995, Genome Research is an international, continuously published, peer-reviewed journal that focuses on research that provides novel insights into the genome biology of all organisms, including advances in genomic medicine.
Among the topics considered by the journal are genome structure and function, comparative genomics, molecular evolution, genome-scale quantitative and population genetics, proteomics, epigenomics, and systems biology. The journal also features exciting gene discoveries and reports of cutting-edge computational biology and high-throughput methodologies.
New data in these areas are published as research papers, or methods and resource reports that provide novel information on technologies or tools that will be of interest to a broad readership. Complete data sets are presented electronically on the journal''s web site where appropriate. The journal also provides Reviews, Perspectives, and Insight/Outlook articles, which present commentary on the latest advances published both here and elsewhere, placing such progress in its broader biological context.