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Field-based species identification in eukaryotes using real-time nanopore sequencing

Field-based species identification in eukaryotes using real-time nanopore sequencing
Field-based species identification in eukaryotes using real-time nanopore sequencing
Advances in DNA sequencing and informatics have revolutionised biology over the past four decades, but technological limitations have left many applications unexplored1,2. Recently, portable, real-time, nanopore sequencing (RTnS) has become available. This offers opportunities to rapidly collect and analyse genomic data anywhere3–5. However, the generation of datasets from large, complex genomes has been constrained to laboratories6,7. The portability and long DNA sequences of RTnS offer great potential for field-based species identification, but the feasibility and accuracy of these technologies for this purpose have not been assessed. Here, we show that a field-based RTnS analysis of closely-related plant species (Arabidopsis spp.)8 has many advantages over laboratory-based high-throughput sequencing (HTS) methods for species level identification-by-sequencing and de novo phylogenomics. Samples were collected and sequenced in a single day by RTnS using a portable, “al fresco” laboratory. Our analyses demonstrate that correctly identifying unknown reads from matches to a reference database with RTnS reads enables rapid and confident species identification. Individually annotated RTnS reads can be used to infer the evolutionary relationships of A. thaliana. Furthermore, hybrid genome assembly with RTnS and HTS reads substantially improved upon a genome assembled from HTS reads alone. Field-based RTnS makes real-time, rapid specimen identification and genome wide analyses possible. These technological advances are set to revolutionise research in the biological sciences9 and have broad implications for conservation, taxonomy, border agencies and citizen science.
bioRxiv
Parker, Joe
979fbb42-5897-4fbe-a32e-06793f9f99ed
Helmstetter, Andrew J.
f7d85b05-2c08-4a12-9793-dcaf60f45c73
Devey, Dion
2f1d5dcf-71bb-4fb2-8e07-4c8ad3ac6ea0
Papadopulos, Alexander S.T.
16661763-8017-490a-9f5c-a040e4e36124
Parker, Joe
979fbb42-5897-4fbe-a32e-06793f9f99ed
Helmstetter, Andrew J.
f7d85b05-2c08-4a12-9793-dcaf60f45c73
Devey, Dion
2f1d5dcf-71bb-4fb2-8e07-4c8ad3ac6ea0
Papadopulos, Alexander S.T.
16661763-8017-490a-9f5c-a040e4e36124

[Unknown type: UNSPECIFIED]

Record type: UNSPECIFIED

Abstract

Advances in DNA sequencing and informatics have revolutionised biology over the past four decades, but technological limitations have left many applications unexplored1,2. Recently, portable, real-time, nanopore sequencing (RTnS) has become available. This offers opportunities to rapidly collect and analyse genomic data anywhere3–5. However, the generation of datasets from large, complex genomes has been constrained to laboratories6,7. The portability and long DNA sequences of RTnS offer great potential for field-based species identification, but the feasibility and accuracy of these technologies for this purpose have not been assessed. Here, we show that a field-based RTnS analysis of closely-related plant species (Arabidopsis spp.)8 has many advantages over laboratory-based high-throughput sequencing (HTS) methods for species level identification-by-sequencing and de novo phylogenomics. Samples were collected and sequenced in a single day by RTnS using a portable, “al fresco” laboratory. Our analyses demonstrate that correctly identifying unknown reads from matches to a reference database with RTnS reads enables rapid and confident species identification. Individually annotated RTnS reads can be used to infer the evolutionary relationships of A. thaliana. Furthermore, hybrid genome assembly with RTnS and HTS reads substantially improved upon a genome assembled from HTS reads alone. Field-based RTnS makes real-time, rapid specimen identification and genome wide analyses possible. These technological advances are set to revolutionise research in the biological sciences9 and have broad implications for conservation, taxonomy, border agencies and citizen science.

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107656v3.full - Author's Original
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Submitted date: 10 February 2017

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Local EPrints ID: 480607
URI: http://eprints.soton.ac.uk/id/eprint/480607
PURE UUID: 8e51b32a-3dd7-4e09-b92c-642b95d8f550
ORCID for Joe Parker: ORCID iD orcid.org/0000-0003-3777-2269

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Date deposited: 07 Aug 2023 16:49
Last modified: 18 Mar 2024 03:50

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Contributors

Author: Joe Parker ORCID iD
Author: Andrew J. Helmstetter
Author: Dion Devey
Author: Alexander S.T. Papadopulos

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