From soil to sequence: filling the critical gap in genome-resolved metagenomics is essential to the future of soil microbial ecology

Winston E. Anthony; Steven D. Allison; Caitlin M. Broderick; Luciana Chavez Rodriguez; Alicia Clum; Hugh Cross; Emiley Eloe-Fadrosh; Sarah Evans; Dawson Fairbanks; Rachel Gallery; Júlia Brandão Gontijo; Jennifer Jones; Jason McDermott; Jennifer Pett-Ridge; Sydne Record; Jorge Luiz Mazza Rodrigues; William Rodriguez-Reillo; Katherine L. Shek; Tina Takacs-Vesbach; Jeffrey L. Blanchard

doi:10.1186/s40793-024-00599-w

From soil to sequence: filling the critical gap in genome-resolved metagenomics is essential to the future of soil microbial ecology

Winston E. Anthony
, Steven D. Allison
, Caitlin M. Broderick
, Luciana Chavez Rodriguez
, Alicia Clum
, Hugh Cross
, Emiley Eloe-Fadrosh
, Sarah Evans
, Dawson Fairbanks
, Rachel Gallery
, Júlia Brandão Gontijo
, Jennifer Jones
, Jason McDermott
, Jennifer Pett-Ridge
, Sydne Record
, Jorge Luiz Mazza Rodrigues
, William Rodriguez-Reillo
, Katherine L. Shek
, Tina Takacs-Vesbach
, Jeffrey L. Blanchard

Research output: Contribution to journal › Comment/debate › peer-review

14 Scopus citations

Abstract

Soil microbiomes are heterogeneous, complex microbial communities. Metagenomic analysis is generating vast amounts of data, creating immense challenges in sequence assembly and analysis. Although advances in technology have resulted in the ability to easily collect large amounts of sequence data, soil samples containing thousands of unique taxa are often poorly characterized. These challenges reduce the usefulness of genome-resolved metagenomic (GRM) analysis seen in other fields of microbiology, such as the creation of high quality metagenomic assembled genomes and the adoption of genome scale modeling approaches. The absence of these resources restricts the scale of future research, limiting hypothesis generation and the predictive modeling of microbial communities. Creating publicly available databases of soil MAGs, similar to databases produced for other microbiomes, has the potential to transform scientific insights about soil microbiomes without requiring the computational resources and domain expertise for assembly and binning.

Original language	English (US)
Article number	56
Journal	Environmental Microbiome
Volume	19
Issue number	1
DOIs	https://doi.org/10.1186/s40793-024-00599-w
State	Published - Dec 2024

Keywords

FAIR Data Principles
Genome Resolved Metagenomics
Hybrid Assembly
Microbiome Assembled Genomes
Soil Microbiome

ASJC Scopus subject areas

Microbiology
Applied Microbiology and Biotechnology
Genetics

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10.1186/s40793-024-00599-w

Cite this

Anthony, W. E., Allison, S. D., Broderick, C. M., Chavez Rodriguez, L., Clum, A., Cross, H., Eloe-Fadrosh, E., Evans, S., Fairbanks, D., Gallery, R., Gontijo, J. B., Jones, J., McDermott, J., Pett-Ridge, J., Record, S., Rodrigues, J. L. M., Rodriguez-Reillo, W., Shek, K. L., Takacs-Vesbach, T., & Blanchard, J. L. (2024). From soil to sequence: filling the critical gap in genome-resolved metagenomics is essential to the future of soil microbial ecology. Environmental Microbiome, 19(1), Article 56. https://doi.org/10.1186/s40793-024-00599-w

Anthony, WE, Allison, SD, Broderick, CM, Chavez Rodriguez, L, Clum, A, Cross, H, Eloe-Fadrosh, E, Evans, S, Fairbanks, D, Gallery, R, Gontijo, JB, Jones, J, McDermott, J, Pett-Ridge, J, Record, S, Rodrigues, JLM, Rodriguez-Reillo, W, Shek, KL, Takacs-Vesbach, T & Blanchard, JL 2024, 'From soil to sequence: filling the critical gap in genome-resolved metagenomics is essential to the future of soil microbial ecology', Environmental Microbiome, vol. 19, no. 1, 56. https://doi.org/10.1186/s40793-024-00599-w

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title = "From soil to sequence: filling the critical gap in genome-resolved metagenomics is essential to the future of soil microbial ecology",

abstract = "Soil microbiomes are heterogeneous, complex microbial communities. Metagenomic analysis is generating vast amounts of data, creating immense challenges in sequence assembly and analysis. Although advances in technology have resulted in the ability to easily collect large amounts of sequence data, soil samples containing thousands of unique taxa are often poorly characterized. These challenges reduce the usefulness of genome-resolved metagenomic (GRM) analysis seen in other fields of microbiology, such as the creation of high quality metagenomic assembled genomes and the adoption of genome scale modeling approaches. The absence of these resources restricts the scale of future research, limiting hypothesis generation and the predictive modeling of microbial communities. Creating publicly available databases of soil MAGs, similar to databases produced for other microbiomes, has the potential to transform scientific insights about soil microbiomes without requiring the computational resources and domain expertise for assembly and binning.",

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doi = "10.1186/s40793-024-00599-w",

language = "English (US)",

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AU - Anthony, Winston E.

AU - Allison, Steven D.

AU - Broderick, Caitlin M.

AU - Chavez Rodriguez, Luciana

AU - Clum, Alicia

AU - Cross, Hugh

AU - Eloe-Fadrosh, Emiley

AU - Evans, Sarah

AU - Fairbanks, Dawson

AU - Gallery, Rachel

AU - Gontijo, Júlia Brandão

AU - Jones, Jennifer

AU - McDermott, Jason

AU - Pett-Ridge, Jennifer

AU - Record, Sydne

AU - Rodrigues, Jorge Luiz Mazza

AU - Rodriguez-Reillo, William

AU - Shek, Katherine L.

AU - Takacs-Vesbach, Tina

AU - Blanchard, Jeffrey L.

PY - 2024/12

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N2 - Soil microbiomes are heterogeneous, complex microbial communities. Metagenomic analysis is generating vast amounts of data, creating immense challenges in sequence assembly and analysis. Although advances in technology have resulted in the ability to easily collect large amounts of sequence data, soil samples containing thousands of unique taxa are often poorly characterized. These challenges reduce the usefulness of genome-resolved metagenomic (GRM) analysis seen in other fields of microbiology, such as the creation of high quality metagenomic assembled genomes and the adoption of genome scale modeling approaches. The absence of these resources restricts the scale of future research, limiting hypothesis generation and the predictive modeling of microbial communities. Creating publicly available databases of soil MAGs, similar to databases produced for other microbiomes, has the potential to transform scientific insights about soil microbiomes without requiring the computational resources and domain expertise for assembly and binning.

AB - Soil microbiomes are heterogeneous, complex microbial communities. Metagenomic analysis is generating vast amounts of data, creating immense challenges in sequence assembly and analysis. Although advances in technology have resulted in the ability to easily collect large amounts of sequence data, soil samples containing thousands of unique taxa are often poorly characterized. These challenges reduce the usefulness of genome-resolved metagenomic (GRM) analysis seen in other fields of microbiology, such as the creation of high quality metagenomic assembled genomes and the adoption of genome scale modeling approaches. The absence of these resources restricts the scale of future research, limiting hypothesis generation and the predictive modeling of microbial communities. Creating publicly available databases of soil MAGs, similar to databases produced for other microbiomes, has the potential to transform scientific insights about soil microbiomes without requiring the computational resources and domain expertise for assembly and binning.

KW - FAIR Data Principles

KW - Genome Resolved Metagenomics

KW - Hybrid Assembly

KW - Microbiome Assembled Genomes

KW - Soil Microbiome

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DO - 10.1186/s40793-024-00599-w

M3 - Comment/debate

AN - SCOPUS:85200418198

SN - 1944-3277

VL - 19

JO - Environmental Microbiome

JF - Environmental Microbiome

IS - 1

M1 - 56

ER -

From soil to sequence: filling the critical gap in genome-resolved metagenomics is essential to the future of soil microbial ecology

Abstract

Keywords

ASJC Scopus subject areas

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