序列独立单引物扩增(SISPA)预处理对病毒宏基因组检测的影响。

Oskar Erik Karlsson, Sándor Belák, Fredrik Granberg
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引用次数: 45

摘要

与常规诊断相比,在疫情情况下筛查病原体,无论是否有意释放,都对检测技术提出了要求,不仅要表明已知病原体的存在,还要表明新的和意想不到的病原体的存在。使用无偏高通量测序(HTS)检测病毒病原体的宏基因组方法是一种成熟的方法,具有广泛的检测范围和对不同样品基质的广泛适用性。为制备HTS样品,常见的预测序步骤包括均质化、富集、分离(如磁分离)和扩增。在这项初步研究中,我们探讨了序列独立的核酸单引物扩增(SISPA)预处理的优点和缺点,并将该方法应用于人工样本。更具体地说,合成宏基因组分为2个样本,1个未扩增,1个稀释,并通过SISPA扩增。随后,使用Ion Torrent个人基因组机(PGM)对两个样本进行测序,并通过生物信息学、短读图谱、从头组装、基于blast的分类分类和可视化对结果数据集进行分析。结果表明,尽管SISPA引入了强烈的扩增偏差,使其不适合全基因组测序,但它仍然有助于检测和鉴定病毒。
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The effect of preprocessing by sequence-independent, single-primer amplification (SISPA) on metagenomic detection of viruses.

Compared to routine diagnostics, screening for pathogens in outbreak situations, with or without intentional release, poses demands on the detection technology to not only indicate the presence of already known causative agents but also novel and unexpected pathogens. The metagenomic approach to detecting viral pathogens, using unbiased high-throughput sequencing (HTS), is a well-established methodology with a broad detection range and wide applicability on different sample matrices. To prepare a sample for HTS, the common presequencing steps include homogenization, enrichment, separation (eg, magnetic separation), and amplification. In this initial study, we explored the benefits and drawbacks of preprocessing by sequence-independent, single-primer amplification (SISPA) of nucleic acids by applying the methodology to artificial samples. More specifically, a synthetic metagenome was divided into 2 samples, 1 unamplified and 1 diluted, and amplified by SISPA. Subsequently, both samples were sequenced using the Ion Torrent Personal Genome Machine (PGM), and the resulting datasets were analyzed by using bioinformatics, short read mapping, de novo assembly, BLAST-based taxonomic classification, and visualization. The results indicate that even though SISPA introduces a strong amplification bias, which makes it unsuitable for whole-genome sequencing, it is still useful for detecting and identifying viruses.

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