High resolution species detection: accurate long read eDNA metabarcoding of North Sea fish using Oxford Nanopore sequencing

Doorenspleet, Karlijn; Jansen, Lara; Oosterbroek, Saskia; Bos, O.G.; Kamermans, P.; Janse, Max; Wurz, Erik; Murk, Albertinka J.; Nijland, Reindert

doi:10.22541/au.163828284.40261296/v1

Cited by 5 publications

(7 citation statements)

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“…One poten al solu on may involve employing longer sequences or even full-length genes in eDNA metabarcoding. Novel metabarcoding approaches targe ng en re gene sequences improve dis nc on among similar species (Deiner et al, 2017, Doorenspleet et al, 2021. Future work will evaluate the impact of longer or full-length sequences on classifier performance and outcomes.…”

Section: Discussionmentioning

confidence: 99%

A comprehensive evaluation of taxonomic classifiers in marine vertebrate eDNA studies

Bayer,

Bennett,

Nester

et al. 2024

Preprint

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Environmental DNA (eDNA) metabarcoding is a widely used tool for surveying marine vertebrate biodiversity. To this end, many computational tools have been released and a plethora of bioinformatic approaches are used for eDNA-based community composition analysis. Simulation studies and careful evaluation of taxonomic classifiers are essential to establish reliable benchmarks to improve accuracy and reproducibility of eDNA-based findings. Here we present a comprehensive evaluation of nine taxonomic classifiers exploring three widely used mitochondrial markers (12S rDNA, 16S rDNA, and COI) in Australian marine vertebrates. Curated reference databases and exclusion database tests were used to simulate diverse species compositions, including three positive control and two negative control datasets. Using these simulated datasets, we were able to identify between 19% to 85% of marine vertebrate species using mitochondrial markers. We show that MMSeqs2 and Metabuli generally outperform BLAST with 10% and 11% higher F1 scores for 12S and 16S rDNA markers, respectively, and that Naive Bayes Classifiers such as Mothur outperform sequence-based classifiers except MMSeqs2 for COI markers by 11%. Database exclusion tests reveal that MMSeqs2 and BLAST are less susceptible to false positives compared to Kraken2 with default parameters. Based on these findings, we recommend that MMSeqs2 is used for taxonomic classification of marine vertebrates given its ability to improve species-level assignments while reducing the number of false positives. Our work contributes to the establishment of best practices in eDNA-based biodiversity analysis to ultimately increase the reliability of this monitoring tool in the context of marine vertebrate conservation.

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Section: Discussionmentioning

confidence: 99%

A comprehensive evaluation of taxonomic classifiers in marine vertebrate eDNA studies

Bayer,

Bennett,

Nester

et al. 2024

Preprint

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“…Several tools for automatic handling of Nanopore amplicon data are available. Examples are NanoRTax (however limited to 16S rRNA amplicons only and intended for taxonomic analysis of microbial community samples, Rodriguez‐Perez et al, 2021) or Decona (for processing data from demultiplexing to consensus calculation, Doorenspleet et al, 2021). However, none of these tools can adequately handle paralogs present in amplified loci.…”

Section: Discussionmentioning

confidence: 99%

Nano‐Strainer: A workflow for the identification of single‐copy nuclear loci for plant systematic studies, using target capture kits and Oxford Nanopore long reads

Scheunert

Lautenschlager

Ott

et al. 2023

Ecology and Evolution

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In modern plant systematics, target enrichment enables simultaneous analysis of hundreds of genes. However, when dealing with reticulate or polyploidization histories, few markers may suffice, but often are required to be single-copy, a condition that is not necessarily met with commercial capture kits. Also, large genome sizes can render target capture ineffective, so that amplicon sequencing would be preferable; however, knowledge about suitable loci is often missing. Here, we present a comprehen-TA B L E 1 Taxa analyzed for the present study, alongside voucher information with localities, collectors and used Oxford Nanopore Technologies (ONT) barcodes.

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“…We benchmark the performance (i.e., the number and taxonomic level of identified zooplankton species) and runtime of PIMENTA with two other existing pipelines, the previous pipeline published by Voorhuijzen-Harink et al [2] as well as Decona [4]. An overview of the procedures, analysis and databases applied in this study is shown in Figure 1.…”

Section: )mentioning

confidence: 99%

“…Metabarcoding data analysis, however, is not yet mainstreamed and many different bioinformatic pipelines have become available over recent years [2,3,4,5,6]. As the sequencing error profile of MinION sequencing differs to that of other sequencing devices such as Illumina sequencers [3,7], analysis pipelines developed with data from other platforms in mind may not perform well on MinION data.…”

Section: Introductionmentioning

confidence: 99%

PIMENTA: PIpeline for MEtabarcoding through Nanopore Technology used for Authentication

van der Vorst,

Thijssen,

Fronen

et al. 2024

Preprint

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DNA metabarcoding has become a cost-effective method to assess species composition of mixed samples. Developments such as advances in sequencing technology and increased species coverage of reference databases can be leveraged to gain more insights from metabarcoding experiments, given suitable tools. To this end, we introduce PIMENTA, a new pipeline that streamlines the analysis of Nanopore DNA metabarcoding sequencing data. PIMENTA consists of four phases: pre-processing, clustering per sample, reclustering of all samples, and taxonomic identification. PIMENTA expands a workflow created by Voorhuijzen-Harink et al. Multiple updates have been made, including parallelization of the analysis of multiple samples with the use of high-performance computing (HPC), implementation of a local taxonomy database, and expansion of the taxonomic results summary. Settings have been optimized to process higher quality nanopore reads, for an increased accuracy of taxonomic identification. We evaluated the pipeline with mock samples of zooplankton species, incorporating COI, 18SV4, and 18SV9 marker sequences. The performance and runtime have been benchmarked against two other existing pipelines. PIMENTA was able to quickly identify species with a high resolution and minimal misidentifications.

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High resolution species detection: accurate long read eDNA metabarcoding of North Sea fish using Oxford Nanopore sequencing

Cited by 5 publications

References 0 publications

A comprehensive evaluation of taxonomic classifiers in marine vertebrate eDNA studies

A comprehensive evaluation of taxonomic classifiers in marine vertebrate eDNA studies

Nano‐Strainer: A workflow for the identification of single‐copy nuclear loci for plant systematic studies, using target capture kits and Oxford Nanopore long reads

PIMENTA: PIpeline for MEtabarcoding through Nanopore Technology used for Authentication

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