Instances of erroneous DNA barcoding of metazoan invertebrates: Are universal cox1 gene primers too “universal”?

Mioduchowska, Monika; Czyż, Michał; Gołdyn, Bartłomiej; Kur, Jarosław; Sell, Jerzy

doi:10.1371/journal.pone.0199609

Cited by 56 publications

(47 citation statements)

References 68 publications

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“…Regarding other public databases (e.g. GenBank), effort is required to identify sequences with incorrect taxonomic assignment to avoid their use as reference data (Mioduchowska et al., ). (b) Development and validation of detailed and standardizable methods for fieldwork and extraction of the target specimens from their habitat matrix (water, soil, sediment, etc.)…”

Section: Discussionmentioning

confidence: 99%

“…Hausmann et al., ), stronger linkage is forged between traditional taxonomic systems and reference sequences. Barcode campaigns that employ rigorous taxonomic identification of voucher specimens also provide a necessary step forward to identify database sequences that have been incorrectly assigned taxonomically, as it has been shown to occur in the genbank database (Mioduchowska, Jan, Gołdyn, Kur, & Sell, ).…”

Section: Large Coi‐bcr Reference Databases Provide a Powerful Link Tomentioning

confidence: 99%

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Why the COI barcode should be the community DNA metabarcode for the metazoa

et al. 2018

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Metabarcoding of complex metazoan communities is increasingly being used to measure biodiversity in terrestrial, freshwater and marine ecosystems, revolutionizing our ability to observe patterns and infer processes regarding the origin and conservation of biodiversity. A fundamentally important question is which genetic marker to amplify, and although the mitochondrial cytochrome oxidase subunit I (COI) gene is one of the more widely used markers in metabarcoding for the Metazoa, doubts have recently been raised about its suitability. We argue that (a) the extensive coverage of reference sequence databases for COI; (b) the variation it presents; (c) the comparative advantages for denoising protein-coding genes; and (d) recent advances in DNA sequencing protocols argue in favour of standardizing for the use of COI for metazoan community samples. We also highlight where research efforts should focus to maximize the utility of metabarcoding.

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Section: Discussionmentioning

confidence: 99%

Section: Large Coi‐bcr Reference Databases Provide a Powerful Link Tomentioning

confidence: 99%

Why the COI barcode should be the community DNA metabarcode for the metazoa

et al. 2018

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“…However, examination of the loan records at the USNM revealed that the loan of material to Meiklejohn et al contained multiple specimens which were not included in their analyses or mentioned in their article-and among them, two were Strepsiptera (USNM ENT 01248370 and 01248357). Cross-contamination is a well-recognized risk when working with museum specimens so it is standard practice to check for its occurrence [13,14]. While Meiklejohn et al [10] exercised some precautions in their laboratory protocols such as the incorporation of negative controls in PCR, there was no evidence that they considered the possibility that some of their DNA sequences derived from non-target taxa.…”

Section: Factors Responsible For Four 'Errors' In Generic Assignmentmentioning

confidence: 99%

BOLD and GenBank revisited – Do identification errors arise in the lab or in the sequence libraries?

et al. 2020

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Applications of biological knowledge, such as forensics, often require the determination of biological materials to a species level. As such, DNA-based approaches to identification, particularly DNA barcoding, are attracting increased interest. The capacity of DNA barcodes to assign newly encountered specimens to a species relies upon access to informatics platforms, such as BOLD and GenBank, which host libraries of reference sequences and support the comparison of new sequences to them. As parameterization of these libraries expands, DNA barcoding has the potential to make valuable contributions in diverse applied contexts. However, a recent publication called for caution after finding that both platforms performed poorly in identifying specimens of 17 common insect species. This study follows up on this concern by asking if the misidentifications reflected problems in the reference libraries or in the query sequences used to test them. Because this reanalysis revealed that missteps in acquiring and analyzing the query sequences were responsible for most misidentifications, a workflow is described to minimize such errors in future investigations. The present study also revealed the limitations imposed by the lack of a polished species-level taxonomy for many groups. In such cases, applications can be strengthened by mapping the geographic distributions of sequence-based species proxies rather than waiting for the maturation of formal taxonomic systems based on morphology.

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“…Yet, being a public database, it is inevitable that BOLD, as any other similar curation tool, might accrue erroneous data, sometimes signi cantly [2,6]. Taxonomic misidenti cations and/or taxonomic conundrums, cryptic species complexes, delimiting cryptic species, technical faults, such as de cient DNA extraction, PCR-based errors and foreign DNA contaminations, including bacterial sequences, especially COI sequences, are just some of the causes that may unavoidably generate erroneous data and inaccurate sequences [2,[6][7][8][9][10]. The above di culties may affect dramatically the accuracy of barcoding.…”

Section: Introductionmentioning

confidence: 99%

Gap-analysis of DNA barcoding in ERMS reference libraries for ascidians and cnidarians

Paz

Rinkevich

2020

Preprint

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BackgroundAll-inclusive DNA barcoding libraries in the storage and analysis platform of the BOLD (Barcode of Life Data) system are essential for the study of the marine biodiversity and are pertinent for regulatory purposes, including ecosystem monitoring and assessment, such as in the context of the EU Water Framework Directive (WFD) and the Marine Strategy Framework Directive (MSFD). Here we investigate knowledge gaps in the lists of DNA barcoded organisms within two inventories, Cnidaria (Anthozoa and Hydrozoa) and Ascidiacea from the reference libraries of the European Register of Marine Species (ERMS) dataset (402 ascidians and 1200 cnidarian species). ERMS records were checked species by species, against publicly available sequence information and other data stored in BOLD system. As the available COI barcode data adequately covers just a small fraction of the ERMS reference library, it is of importance to employ quality control on existing data, to close the knowledge gaps and purge errors off BOLD. ResultsResults revealed that just 22.9% and 29.2% of the listed ascidians and cnidarians species, respectively, are BOLD barcodes of which, 58.4% and 52.3% of the seemingly barcoded species, respectively, were noted to have complete BOLD pages. Thus, only 11.44% of the tunicate and 17.07% of the cnidarian data in the ERMS lists are of high quality. Deep analyses revealed seven common types of gaps in the list of the barcoded species in addition to a wide range of discrepancies and misidentifications, discordances and errors primarily in the GenBank mined data as with the BINs assignments, among others. ConclusionsGap knowledge in barcoding of important taxonomic marine groups exist and in addition, quality management elements (quality assurance and quality control) were not employed when using the list for national monitoring projects, for regulatory compliance purposes and other purposes. Even though BOLD is the most trustable DNA barcoding reference library, worldwide projects of DNA barcoding are needed to close these gaps of mistakes, verifications, missing data and unreliable sequencing labs. Tight quality control and quality assurance is important to close the knowledge gaps of Barcoding of the European recommended ERMS reference library.

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Instances of erroneous DNA barcoding of metazoan invertebrates: Are universal cox1 gene primers too “universal”?

Cited by 56 publications

References 68 publications

Why the COI barcode should be the community DNA metabarcode for the metazoa

Why the COI barcode should be the community DNA metabarcode for the metazoa

BOLD and GenBank revisited – Do identification errors arise in the lab or in the sequence libraries?

Gap-analysis of DNA barcoding in ERMS reference libraries for ascidians and cnidarians

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