Genome-resolved long-read sequencing expands known microbial diversity across terrestrial habitats

Mantas Sereika; Aaron James Mussig; Chenjing Jiang; Kalinka Sand Knudsen; Thomas Bygh Nymann Jensen; Francesca Petriglieri; Yu Yang; Vibeke Rudkjøbing Jørgensen; Francesco Delogu; Emil Aarre Sørensen; Per Halkjær Nielsen; Caitlin Margaret Singleton; Philip Hugenholtz; Mads Albertsen

doi:10.1038/s41564-025-02062-z

Genome-resolved long-read sequencing expands known microbial diversity across terrestrial habitats

Mantas Sereika, Aaron James Mussig, Chenjing Jiang, Kalinka Sand Knudsen, Thomas Bygh Nymann Jensen, Francesca Petriglieri, Yu Yang, Vibeke Rudkjøbing Jørgensen, Francesco Delogu, Emil Aarre Sørensen, Per Halkjær Nielsen, Caitlin Margaret Singleton, Philip Hugenholtz, Mads Albertsen^*

^*Kontaktforfatter

Publikation: Bidrag til tidsskrift › Tidsskriftartikel › Forskning › peer review

13 Citationer (Scopus)

18 Downloads (Pure)

Abstract

The emergence of high-throughput, long-read DNA sequencing has enabled recovery of microbial genomes from environmental samples at scale. However, expanding the terrestrial microbial genome catalogue has been challenging due to the enormous complexity of these environments. Here we performed deep, long-read Nanopore sequencing of 154 soil and sediment samples collected during the Microflora Danica project, yielding genomes of 15,314 previously undescribed microbial species, recovered using our custom mmlong2 workflow. The recovered microbial genomes span 1,086 previously uncharacterized genera and expand the phylogenetic diversity of the prokaryotic tree of life by 8%. The long-read assemblies also enabled the recovery of thousands of complete ribosomal RNA operons, biosynthetic gene clusters and CRISPR-Cas systems. Furthermore, the incorporation of the recovered genomes into public genomic databases substantially improved species-level classification rates for soil and sediment metagenomic datasets. These findings demonstrate that long-read sequencing allows cost-effective recovery of high-quality microbial genomes from highly complex ecosystems, which remain an untapped source of biodiversity.

Originalsprog	Engelsk
Tidsskrift	Nature Microbiology
Vol/bind	10
Udgave nummer	8
Sider (fra-til)	2018-2030
Antal sider	13
ISSN	2058-5276
DOI	https://doi.org/10.1038/s41564-025-02062-z
Status	Udgivet - aug. 2025

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10.1038/s41564-025-02062-zLicens: CC BY-NC-ND 4.0

Open Access ArticleForlagets udgivne version, 6,46 MBLicens: CC BY-NC-ND 4.0

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1 Afsluttet
2 Igangværende

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Albertsen, M. (PI (principal investigator)), Hose, K. (PI (principal investigator)), Nielsen, T. D. (PI (principal investigator)), Heidelbach, S. (Projektdeltager), Knudsen, K. S. (Projektdeltager), Sereika, M. (Projektdeltager), Corfixen, M. (Projektdeltager), Celikkanat, A. (Projektdeltager), Masegosa, A. (Projektdeltager), Sagi, T. (Projektdeltager), Nissen, J. (Projektdeltager), Heede, T. (Projektdeltager) & Kirkegaard, R. H. (Projektdeltager)
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Albertsen, M. (PI (principal investigator)), Nielsen, P. H. (PI (principal investigator)), Jensen, T. B. N. (Projektdeltager), Sørensen, E. A. (Projektdeltager), Sereika, M. (Projektdeltager), Dottorini, G. (Projektdeltager), Petriglieri, F. (Projektdeltager), Jørgensen, V. R. (Projektdeltager), Kirkegaard, R. H. (Projektdeltager), Yang, Y. (Projektdeltager), Karst, S. M. (Projektdeltager), Giguere, A. T. (Projektdeltager), Knutsson, S. (Projektdeltager), Singleton, C. M. (Projektdeltager), Dueholm, M. K. D. (Projektdeltager), Mølvang Dall, S. (Projektdeltager), Kristensen, J. M. (Projektdeltager), Delogu, F. (Projektdeltager), Rodriguez Rojas, M. (PI (principal investigator)) & Kale, V. (Projektdeltager)
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Citationsformater

Sereika, M., Mussig, A. J., Jiang, C., Knudsen, K. S., Jensen, T. B. N., Petriglieri, F., Yang, Y., Jørgensen, V. R., Delogu, F., Sørensen, E. A., Nielsen, P. H., Singleton, C. M., Hugenholtz, P., & Albertsen, M. (2025). Genome-resolved long-read sequencing expands known microbial diversity across terrestrial habitats. Nature Microbiology, 10(8), 2018-2030. https://doi.org/10.1038/s41564-025-02062-z

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abstract = "The emergence of high-throughput, long-read DNA sequencing has enabled recovery of microbial genomes from environmental samples at scale. However, expanding the terrestrial microbial genome catalogue has been challenging due to the enormous complexity of these environments. Here we performed deep, long-read Nanopore sequencing of 154 soil and sediment samples collected during the Microflora Danica project, yielding genomes of 15,314 previously undescribed microbial species, recovered using our custom mmlong2 workflow. The recovered microbial genomes span 1,086 previously uncharacterized genera and expand the phylogenetic diversity of the prokaryotic tree of life by 8\%. The long-read assemblies also enabled the recovery of thousands of complete ribosomal RNA operons, biosynthetic gene clusters and CRISPR-Cas systems. Furthermore, the incorporation of the recovered genomes into public genomic databases substantially improved species-level classification rates for soil and sediment metagenomic datasets. These findings demonstrate that long-read sequencing allows cost-effective recovery of high-quality microbial genomes from highly complex ecosystems, which remain an untapped source of biodiversity.",

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doi = "10.1038/s41564-025-02062-z",

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Sereika, M, Mussig, AJ, Jiang, C , Knudsen, KS , Jensen, TBN, Petriglieri, F, Yang, Y, Jørgensen, VR, Delogu, F, Sørensen, EA, Nielsen, PH , Singleton, CM, Hugenholtz, P & Albertsen, M 2025, 'Genome-resolved long-read sequencing expands known microbial diversity across terrestrial habitats', Nature Microbiology, bind 10, nr. 8, s. 2018-2030. https://doi.org/10.1038/s41564-025-02062-z

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AU - Sereika, Mantas

AU - Mussig, Aaron James

AU - Jiang, Chenjing

AU - Knudsen, Kalinka Sand

AU - Jensen, Thomas Bygh Nymann

AU - Petriglieri, Francesca

AU - Yang, Yu

AU - Jørgensen, Vibeke Rudkjøbing

AU - Delogu, Francesco

AU - Sørensen, Emil Aarre

AU - Nielsen, Per Halkjær

AU - Singleton, Caitlin Margaret

AU - Hugenholtz, Philip

AU - Albertsen, Mads

PY - 2025/8

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N2 - The emergence of high-throughput, long-read DNA sequencing has enabled recovery of microbial genomes from environmental samples at scale. However, expanding the terrestrial microbial genome catalogue has been challenging due to the enormous complexity of these environments. Here we performed deep, long-read Nanopore sequencing of 154 soil and sediment samples collected during the Microflora Danica project, yielding genomes of 15,314 previously undescribed microbial species, recovered using our custom mmlong2 workflow. The recovered microbial genomes span 1,086 previously uncharacterized genera and expand the phylogenetic diversity of the prokaryotic tree of life by 8%. The long-read assemblies also enabled the recovery of thousands of complete ribosomal RNA operons, biosynthetic gene clusters and CRISPR-Cas systems. Furthermore, the incorporation of the recovered genomes into public genomic databases substantially improved species-level classification rates for soil and sediment metagenomic datasets. These findings demonstrate that long-read sequencing allows cost-effective recovery of high-quality microbial genomes from highly complex ecosystems, which remain an untapped source of biodiversity.

AB - The emergence of high-throughput, long-read DNA sequencing has enabled recovery of microbial genomes from environmental samples at scale. However, expanding the terrestrial microbial genome catalogue has been challenging due to the enormous complexity of these environments. Here we performed deep, long-read Nanopore sequencing of 154 soil and sediment samples collected during the Microflora Danica project, yielding genomes of 15,314 previously undescribed microbial species, recovered using our custom mmlong2 workflow. The recovered microbial genomes span 1,086 previously uncharacterized genera and expand the phylogenetic diversity of the prokaryotic tree of life by 8%. The long-read assemblies also enabled the recovery of thousands of complete ribosomal RNA operons, biosynthetic gene clusters and CRISPR-Cas systems. Furthermore, the incorporation of the recovered genomes into public genomic databases substantially improved species-level classification rates for soil and sediment metagenomic datasets. These findings demonstrate that long-read sequencing allows cost-effective recovery of high-quality microbial genomes from highly complex ecosystems, which remain an untapped source of biodiversity.

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Genome-resolved long-read sequencing expands known microbial diversity across terrestrial habitats

Abstract

Bibliografisk note

Adgang til dokumentet

AUB Link

Andre filer og links

Fingeraftryk

Projekter

NanoEat: Exploiting Nanopore sequencing to discover what microbes eat

DarkScience: Illuminating microbial dark matter through data science

Microflora Danica: The Microbiome of Denmark

Citationsformater