Sequencing-induced artefacts in NGS STR data

IF 3.2 2区医学 Q2 GENETICS & HEREDITY Forensic Science International-Genetics Pub Date : 2024-06-15 DOI:10.1016/j.fsigen.2024.103086

Yao-Yuan Liu , Kevin Cheng , Rebecca Just , Sana Enke , Jo-Anne Bright

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Abstract

Significant progress has been made in recent years in the development of techniques for Next Generation Sequencing (NGS), or Massively Parallel Sequencing (MPS), of forensically relevant short tandem repeat (STR) loci. However, as these technologies are investigated and adopted by forensic laboratories, new challenges unfold that require further scrutiny. In the analysis of DNA profiles generated using the MiSeq FGx sequencing system, we have observed noise sequences with relatively high readcounts that are challenging to distinguish from genuine alleles. These high read count noise sequences appear as allele sequences with one or a few substituted bases compared to a known allele sequence within the profile.

An examination of ForenSeq DNA Signature Prep Kit STR noise sequences revealed that the substituted base of a parent allele can align to the same position on the sequence across noise sequences. This suggests that these substitution events occur at specific positions within the amplicon, resulting in multiple noise reads with substitutions at the same position. Mapping of the noise events onto the original raw read positions revealed a high number of events, or “noise spikes”, occurring at

specific positions within a given sequencing run. These noise spikes affected reads across the entire run, agnostic of locus or sample, while the position, occurrence, and amplitude of the spikes differed across runs. The majority of noise sequences with high read counts in a DNA profile were generated from base changes at these spike positions, and could be classified as “noise spike artefacts”.

In this paper we present evidence of the noise spike artefacts and their genesis during the sequencing process in the sequencing-by-synthesis (SBS) cycles, as well as the methods developed to detect them. The information and methods will assist laboratories with detecting noise spikes in MiSeq FGx sequencing runs, differentiating authentic allele sequences from noise spike artefacts, and developing protocols for analyst review and handling of MiSeq FGx data.

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NGS STR 数据中由测序引起的伪差

近年来，下一代测序（NGS）或大规模并行测序（MPS）法医相关短串联重复（STR）位点技术的开发取得了重大进展。然而，随着法医实验室对这些技术的研究和采用，新的挑战又出现了，需要进一步仔细研究。在分析使用 MiSeq FGx 测序系统生成的 DNA 图谱时，我们观察到读数相对较高的噪声序列，这些噪声序列很难与真正的等位基因区分开来。对 ForenSeq DNA Signature Prep Kit STR 杂讯序列的检测发现，父等位基因的替代碱基可以与杂讯序列上的相同位置对齐。这表明这些置换事件发生在扩增子的特定位置，从而产生了多个在同一位置发生置换的噪声读数。将噪声事件映射到原始原始读数位置后发现，在给定的测序过程中，有大量的事件或 "噪声尖峰 "发生在特定的位置上。这些噪声尖峰影响了整个测序过程中的读数，与位点或样本无关，而不同测序过程中尖峰的位置、发生率和振幅都不相同。在本文中，我们介绍了在合成测序（SBS）循环的测序过程中出现的噪声尖峰伪影及其成因的证据，以及为检测它们而开发的方法。这些信息和方法将有助于实验室检测 MiSeq FGx 测序运行中的噪声尖峰，区分真实等位基因序列和噪声尖峰伪影，以及制定分析师审查和处理 MiSeq FGx 数据的规程。

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

Forensic Science International-Genetics 生物-医学：法

CiteScore

7.50

自引率

32.30%

发文量

132

审稿时长

11.3 weeks

期刊介绍： Forensic Science International: Genetics is the premier journal in the field of Forensic Genetics. This branch of Forensic Science can be defined as the application of genetics to human and non-human material (in the sense of a science with the purpose of studying inherited characteristics for the analysis of inter- and intra-specific variations in populations) for the resolution of legal conflicts. The scope of the journal includes: Forensic applications of human polymorphism. Testing of paternity and other family relationships, immigration cases, typing of biological stains and tissues from criminal casework, identification of human remains by DNA testing methodologies. Description of human polymorphisms of forensic interest, with special interest in DNA polymorphisms. Autosomal DNA polymorphisms, mini- and microsatellites (or short tandem repeats, STRs), single nucleotide polymorphisms (SNPs), X and Y chromosome polymorphisms, mtDNA polymorphisms, and any other type of DNA variation with potential forensic applications. Non-human DNA polymorphisms for crime scene investigation. Population genetics of human polymorphisms of forensic interest. Population data, especially from DNA polymorphisms of interest for the solution of forensic problems. DNA typing methodologies and strategies. Biostatistical methods in forensic genetics. Evaluation of DNA evidence in forensic problems (such as paternity or immigration cases, criminal casework, identification), classical and new statistical approaches. Standards in forensic genetics. Recommendations of regulatory bodies concerning methods, markers, interpretation or strategies or proposals for procedural or technical standards. Quality control. Quality control and quality assurance strategies, proficiency testing for DNA typing methodologies. Criminal DNA databases. Technical, legal and statistical issues. General ethical and legal issues related to forensic genetics.