纳米孔长读长测序用于16S rRNA物种鉴定的全国多中心研究。

Nationwide multicentre study of Nanopore long-read sequencing for 16S rRNA-species identification.

作者信息

Brunet Sofia, Grankvist Anna, Jaen-Luchoro Daniel, Bergdahl Maria, Tison Jean-Luc, Wester Annica, Elfving Karin, Brandenburg Jule, Gullsby Karolina, Lindsten Christoffer, Arvidsson Lars-Ola, Larsson Helena, Eilers Hinnerk, Strand Anna Söderlund, Lannefors Mimi, Keskitalo Johanna, Rylander Felicia, Welander Jenny, Jungestrom Malin Bergman, Geörg Miriam, Kaden Rene, Karlsson Ida, Linde Anna-Malin, Mernelius Sara, Berglind Linda, Feuk Lars, Kerje Susanne, Karlsson Linda, Sjödin Andreas, Guerra-Blomqvist Lina, Wallin Frans, Fagerström Anna, Vondracek Martin, Mölling Paula, Hallbäck Erika Tång

机构信息

Department of Infectious Diseases, Institute of Biomedicine, Sahlgrenska Academy, University of Gothenburg, Gothenburg, Sweden.

Dept of Clinical Microbiology, Sahlgrenska University Hospital, Gothenburg, Region Västra Götaland, Sweden.

出版信息

Eur J Clin Microbiol Infect Dis. 2025 May 10. doi: 10.1007/s10096-025-05158-w.

DOI:10.1007/s10096-025-05158-w

PMID:40348924

Abstract

PURPOSE

Recent improvements in Nanopore sequencing chemistry has made it a promising platform for long-read 16S rRNA sequencing. This study evaluated its clinical utility in a nationwide collaboration coordinated by Genomic Medicine Sweden.

METHODS

Thirteen mock samples comprised of various bacterial strains and an External Quality Assessment (EQA) panel from QCMD (Quality Control for Molecular Diagnostics) were analysed by 20 microbiological laboratories across Sweden, using the recent v14 chemistry. Most laboratories generated full-length 16S rRNA sequencing libraries using an optimized protocol for the 16S Barcoding Kit 24, while two laboratories employed in-house PCR coupled with the Ligation Sequencing Kit. The commercial 16S bioinformatic pipeline from 1928 Diagnostics (1928-16S) was evaluated and compared with the open-sourced gms_16S pipeline that is based on the EMU classification tool (GMS-16S).

RESULTS

Seventeen out of 20 laboratories successfully sequenced and analysed the samples. Laboratories that used sodium acetate-containing elution buffers faced compatibility issues during library construction, resulting in reduced read count. High bacterial load samples were generally well-characterized, whereas hard-to-lyse bacteria such as Gram-positive strains were detected at lower abundance. The GMS-16S tool provided improved species-level identification compared to the 1928-16S pipeline, particularly for closely related taxa within the Streptococcus and Staphylococcus genera.

CONCLUSION

Nanopore sequencing demonstrated promising potential for bacterial identification in a clinical setting. The results prompt further optimization of the protocol to improve detection of a broader range of species. This multicentre study highlights the feasibility of implementing Nanopore sequencing into clinical microbiological laboratories, for improved national precision diagnostics.

摘要

目的

纳米孔测序技术在化学方面的最新进展使其成为长读长16S rRNA测序的一个有前景的平台。本研究在瑞典基因组医学组织协调的一项全国性合作中评估了其临床应用价值。

方法

瑞典的20个微生物实验室使用最新的v14化学技术，对由多种细菌菌株组成的13个模拟样本以及来自QCMD（分子诊断质量控制）的一个外部质量评估（EQA）面板进行了分析。大多数实验室使用针对16S条形码试剂盒24的优化方案生成全长16S rRNA测序文库，而有两个实验室采用了内部PCR结合连接测序试剂盒的方法。对1928诊断公司的商业16S生物信息学流程（1928 - 16S）进行了评估，并与基于EMU分类工具的开源gms_16S流程（GMS - 16S）进行了比较。

结果

20个实验室中有17个成功对样本进行了测序和分析。使用含醋酸钠洗脱缓冲液的实验室在文库构建过程中遇到了兼容性问题，导致读取计数减少。高细菌载量的样本通常特征良好，而诸如革兰氏阳性菌株等难以裂解的细菌检测到的丰度较低。与1928 - 16S流程相比，GMS - 16S工具在物种水平鉴定方面表现更佳，特别是对于链球菌属和葡萄球菌属内亲缘关系较近的分类群。

结论

纳米孔测序在临床环境中细菌鉴定方面显示出有前景的潜力。这些结果促使对方案进行进一步优化，以提高对更广泛物种的检测能力。这项多中心研究突出了将纳米孔测序应用于临床微生物实验室以提高国家精准诊断的可行性。

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纳米孔长读长测序用于16S rRNA物种鉴定的全国多中心研究。

Nationwide multicentre study of Nanopore long-read sequencing for 16S rRNA-species identification.

作者信息

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出版信息

PURPOSE

METHODS

RESULTS

CONCLUSION

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方法

结果

结论

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