Using Direct RNA Nanopore Sequencing to Deconvolute Viral Transcriptomes

Daniel P. Depledge, Angus C. Wilson
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引用次数: 10

Abstract

The genomes of DNA viruses encode deceptively complex transcriptomes evolved to maximize coding potential within the confines of a relatively small genome. Defining the full range of viral RNAs produced during an infection is key to understanding the viral replication cycle and its interactions with the host cell. Traditional short-read (Illumina) sequencing approaches are problematic in this setting due to the difficulty of assigning short reads to individual RNAs in regions of transcript overlap and to the biases introduced by the required recoding and amplification steps. Additionally, different methodologies may be required to analyze the 5′ and 3′ ends of RNAs, which increases both cost and effort. The advent of long-read nanopore sequencing simplifies this approach by providing a single assay that captures and sequences full length RNAs, either in cDNA or native RNA form. The latter is particularly appealing as it reduces known recoding biases whilst allowing more advanced analyses such as estimation of poly(A) tail length and the detection of RNA modifications including N6-methyladenosine. Using herpes simplex virus (HSV)-infected primary fibroblasts as a template, we provide a step-by-step guide to the production of direct RNA sequencing libraries suitable for sequencing using Oxford Nanopore Technologies platforms and provide a simple computational approach to deriving a high-quality annotation of the HSV transcriptome from the resulting sequencing data. © 2020 by John Wiley & Sons, Inc.

Basic Protocol 1: Productive infection of primary fibroblasts with herpes simplex virus

Support Protocol: Cell passage and plating of primary fibroblasts

Basic Protocol 2: Preparation and sequencing of dRNA-seq libraries from virus-infected cells

Basic Protocol 3: Processing, alignment, and analysis of dRNA-seq datasets

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使用直接RNA纳米孔测序解卷积病毒转录组
DNA病毒的基因组编码看似复杂的转录组,进化到在相对较小的基因组范围内最大化编码潜力。确定感染过程中产生的所有病毒rna是理解病毒复制周期及其与宿主细胞相互作用的关键。传统的短读序列(Illumina)测序方法在这种情况下存在问题,因为难以将短读序列分配到转录重叠区域的单个rna上,并且由于所需的重编码和扩增步骤所引入的偏差。此外,可能需要不同的方法来分析rna的5 '和3 '端,这增加了成本和工作量。长读纳米孔测序的出现简化了这种方法,它提供了一种单一的测定方法,可以捕获和测序cDNA或天然RNA形式的全长RNA。后者特别吸引人,因为它减少了已知的编码偏差,同时允许更高级的分析,如poly(A)尾长度的估计和RNA修饰的检测,包括n6 -甲基腺苷。使用单纯疱疹病毒(HSV)感染的原代成纤维细胞作为模板,我们提供了一个循序渐进的指导,以生产直接RNA测序文库,适用于使用牛津纳米孔技术平台测序,并提供了一个简单的计算方法,从由此产生的测序数据中获得HSV转录组的高质量注释。©2020 by John Wiley &基本方案1:单纯疱疹病毒原代成纤维细胞的生产感染;支持方案:原代成纤维细胞的传代和镀膜;基本方案2:从病毒感染的细胞中制备和测序dna -seq文库;基本方案3:处理、排列和分析dna -seq数据集
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来源期刊
Current Protocols in Microbiology
Current Protocols in Microbiology Immunology and Microbiology-Parasitology
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期刊介绍: Current Protocols in Microbiology provides detailed, step-by-step instructions for analyzing bacteria, animal and plant viruses, fungi, protozoans and other microbes. It offers updated coverage of emerging technologies and concepts, such as biofilms, quorum sensing and quantitative PCR, as well as proteomic and genomic methods. It is the first comprehensive source of high-quality microbiology protocols that reflects and incorporates the new mandates and capabilities of this robust and rapidly evolving discipline.
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