Metagenomic binning with assembly graph embeddings

Andre Lamurias; Mantas Sereika; Mads Albertsen; Katja Hose; Thomas Dyhre Nielsen

doi:10.1093/bioinformatics/btac557

Metagenomic binning with assembly graph embeddings

Andre Lamurias, Mantas Sereika, Mads Albertsen, Katja Hose, Thomas Dyhre Nielsen

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

20 Citationer (Scopus)

122 Downloads (Pure)

Abstract

MOTIVATION: Despite recent advancements in sequencing technologies and assembly methods, obtaining high-quality microbial genomes from metagenomic samples is still not a trivial task. Current metagenomic binners do not take full advantage of assembly graphs and are not optimized for long-read assemblies. Deep graph learning algorithms have been proposed in other fields to deal with complex graph data structures. The graph structure generated during the assembly process could be integrated with contig features to obtain better bins with deep learning.

RESULTS: We propose GraphMB, which uses graph neural networks to incorporate the assembly graph into the binning process. We test GraphMB on long-read datasets of different complexities, and compare the performance with other binners in terms of the number of High Quality (HQ) genome bins obtained. With our approach, we were able to obtain unique bins on all real datasets, and obtain more bins on most datasets. In particular, we obtained on average 17.5% more HQ bins when compared with state-of-the-art binners and 13.7% when aggregating the results of our binner with the others. These results indicate that a deep learning model can integrate contig-specific and graph-structure information to improve metagenomic binning.

AVAILABILITY AND IMPLEMENTATION: GraphMB is available from https://github.com/MicrobialDarkMatter/GraphMB.

SUPPLEMENTARY INFORMATION: Supplementary data are available at Bioinformatics online.

Originalsprog	Engelsk
Tidsskrift	Bioinformatics
Vol/bind	38
Udgave nummer	19
Sider (fra-til)	4481-4487
Antal sider	7
ISSN	1367-4803
DOI	https://doi.org/10.1093/bioinformatics/btac557
Status	Udgivet - okt. 2022

Bibliografisk note

FN’s Verdensmål

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Adgang til dokumentet

10.1093/bioinformatics/btac557Licens: CC BY 4.0

Open Access articleForlagets udgivne version, 466 KBLicens: CC BY 4.0

https://www.biorxiv.org/content/10.1101/2022.02.25.481923v1

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1 Afsluttet
2 Igangværende

Poul Due Jensen Professorate in Big Data and Artificial Intelligence
Hose, K. (PI (principal investigator)), Jendal, T. E. (Projektdeltager) & Hansen, E. R. (Projektdeltager)
01/11/2019 → 31/12/2025
Projekter: Projekt › Forskning
Microflora Danica: The Microbiome of Denmark
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)
Poul Due Jensens Fond
01/01/2019 → 31/12/2025
Projekter: Projekt › Forskning
Data Science meets Microbial Dark Matter
Albertsen, M. (PI (principal investigator)), Hose, K. (PI (principal investigator)), Nielsen, T. D. (PI (principal investigator)), Lamurias, A. (Projektdeltager) & Mølvang Dall, S. (Projektdeltager)
Danish E-infrastructure Cooperation, Villum Fonden
01/01/2021 → 31/12/2023
Projekter: Projekt › Forskning

Citationsformater

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title = "Metagenomic binning with assembly graph embeddings",

abstract = "MOTIVATION: Despite recent advancements in sequencing technologies and assembly methods, obtaining high-quality microbial genomes from metagenomic samples is still not a trivial task. Current metagenomic binners do not take full advantage of assembly graphs and are not optimized for long-read assemblies. Deep graph learning algorithms have been proposed in other fields to deal with complex graph data structures. The graph structure generated during the assembly process could be integrated with contig features to obtain better bins with deep learning.RESULTS: We propose GraphMB, which uses graph neural networks to incorporate the assembly graph into the binning process. We test GraphMB on long-read datasets of different complexities, and compare the performance with other binners in terms of the number of High Quality (HQ) genome bins obtained. With our approach, we were able to obtain unique bins on all real datasets, and obtain more bins on most datasets. In particular, we obtained on average 17.5% more HQ bins when compared with state-of-the-art binners and 13.7% when aggregating the results of our binner with the others. These results indicate that a deep learning model can integrate contig-specific and graph-structure information to improve metagenomic binning.AVAILABILITY AND IMPLEMENTATION: GraphMB is available from https://github.com/MicrobialDarkMatter/GraphMB.SUPPLEMENTARY INFORMATION: Supplementary data are available at Bioinformatics online.",

keywords = "Algorithms, Genome, Microbial, Metagenome, Metagenomics/methods, Sequence Analysis, DNA/methods",

author = "Andre Lamurias and Mantas Sereika and Mads Albertsen and Katja Hose and Nielsen, {Thomas Dyhre}",

note = "{\textcopyright} The Author(s) 2022. Published by Oxford University Press.",

year = "2022",

month = oct,

doi = "10.1093/bioinformatics/btac557",

language = "English",

volume = "38",

pages = "4481--4487",

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issn = "1367-4803",

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T1 - Metagenomic binning with assembly graph embeddings

AU - Lamurias, Andre

AU - Sereika, Mantas

AU - Albertsen, Mads

AU - Hose, Katja

AU - Nielsen, Thomas Dyhre

PY - 2022/10

Y1 - 2022/10

N2 - MOTIVATION: Despite recent advancements in sequencing technologies and assembly methods, obtaining high-quality microbial genomes from metagenomic samples is still not a trivial task. Current metagenomic binners do not take full advantage of assembly graphs and are not optimized for long-read assemblies. Deep graph learning algorithms have been proposed in other fields to deal with complex graph data structures. The graph structure generated during the assembly process could be integrated with contig features to obtain better bins with deep learning.RESULTS: We propose GraphMB, which uses graph neural networks to incorporate the assembly graph into the binning process. We test GraphMB on long-read datasets of different complexities, and compare the performance with other binners in terms of the number of High Quality (HQ) genome bins obtained. With our approach, we were able to obtain unique bins on all real datasets, and obtain more bins on most datasets. In particular, we obtained on average 17.5% more HQ bins when compared with state-of-the-art binners and 13.7% when aggregating the results of our binner with the others. These results indicate that a deep learning model can integrate contig-specific and graph-structure information to improve metagenomic binning.AVAILABILITY AND IMPLEMENTATION: GraphMB is available from https://github.com/MicrobialDarkMatter/GraphMB.SUPPLEMENTARY INFORMATION: Supplementary data are available at Bioinformatics online.

AB - MOTIVATION: Despite recent advancements in sequencing technologies and assembly methods, obtaining high-quality microbial genomes from metagenomic samples is still not a trivial task. Current metagenomic binners do not take full advantage of assembly graphs and are not optimized for long-read assemblies. Deep graph learning algorithms have been proposed in other fields to deal with complex graph data structures. The graph structure generated during the assembly process could be integrated with contig features to obtain better bins with deep learning.RESULTS: We propose GraphMB, which uses graph neural networks to incorporate the assembly graph into the binning process. We test GraphMB on long-read datasets of different complexities, and compare the performance with other binners in terms of the number of High Quality (HQ) genome bins obtained. With our approach, we were able to obtain unique bins on all real datasets, and obtain more bins on most datasets. In particular, we obtained on average 17.5% more HQ bins when compared with state-of-the-art binners and 13.7% when aggregating the results of our binner with the others. These results indicate that a deep learning model can integrate contig-specific and graph-structure information to improve metagenomic binning.AVAILABILITY AND IMPLEMENTATION: GraphMB is available from https://github.com/MicrobialDarkMatter/GraphMB.SUPPLEMENTARY INFORMATION: Supplementary data are available at Bioinformatics online.

KW - Algorithms

KW - Genome, Microbial

KW - Metagenome

KW - Metagenomics/methods

KW - Sequence Analysis, DNA/methods

U2 - 10.1093/bioinformatics/btac557

DO - 10.1093/bioinformatics/btac557

M3 - Journal article

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SN - 1367-4803

VL - 38

SP - 4481

EP - 4487

JO - Bioinformatics

JF - Bioinformatics

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ER -

Metagenomic binning with assembly graph embeddings

Abstract

Bibliografisk note

FN’s Verdensmål

Adgang til dokumentet

AUB Link

Fingeraftryk

Projekter

Poul Due Jensen Professorate in Big Data and Artificial Intelligence

Microflora Danica: The Microbiome of Denmark

Data Science meets Microbial Dark Matter

Citationsformater