DNA Barcoding of Recently Diverged Species: Relative Performance of Matching Methods

Velzen, Robin van; Weitschek, Emanuel; Felici, Giovanni; Bakker, Freek T.

doi:10.1371/journal.pone.0030490

Cited by 146 publications

(159 citation statements)

References 96 publications

(208 reference statements)

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“…The chloroplast ribulose‐1, 5‐bisphosphate carboxylase/oxygenase large subunit gene ( rbcL ) and maturase K gene ( matK ) are the approved barcodes for land plants (CBOL Plant Working Group 2009). However, plant‐plastid barcodes typically have lower resolving power to separate closely related plant species compared to the animal barcode, and in several cases, conspecifics or recently diverged species do not form highly supported, distinct sequence clusters that allow species discrimination (Hollingsworth et al., 2016; van Velzen, Weitschek, Felici, & Bakker, 2012; Zhang et al., 2012). In fact, a uniquely identified species in a given genus is the exception rather than the rule in most plant barcoding studies (Hollingsworth, Graham, & Little, 2011).…”

Section: Introductionmentioning

confidence: 99%

Utility of DNA barcoding to identify rare endemic vascular plant species in Trinidad

Hosein

Austin

Maharaj

et al. 2017

Ecology and Evolution

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The islands of the Caribbean are considered to be a “biodiversity hotspot.” Collectively, a high level of endemism for several plant groups has been reported for this region. Biodiversity conservation should, in part, be informed by taxonomy, population status, and distribution of flora. One taxonomic impediment to species inventory and management is correct identification as conventional morphology‐based assessment is subject to several caveats. DNA barcoding can be a useful tool to quickly and accurately identify species and has the potential to prompt the discovery of new species. In this study, the ability of DNA barcoding to confirm the identities of 14 endangered endemic vascular plant species in Trinidad was assessed using three DNA barcodes (matK, rbcL, and rpoC1). Herbarium identifications were previously made for all species under study. matK, rbcL, and rpoC1 markers were successful in amplifying target regions for seven of the 14 species. rpoC1 sequences required extensive editing and were unusable. rbcL primers resulted in cleanest reads, however, matK appeared to be superior to rbcL based on a number of parameters assessed including level of DNA polymorphism in the sequences, genetic distance, reference library coverage based on BLASTN statistics, direct sequence comparisons within “best match” and “best close match” criteria, and finally, degree of clustering with moderate to strong bootstrap support (>60%) in neighbor‐joining tree‐based comparisons. The performance of both markers seemed to be species‐specific based on the parameters examined. Overall, the Trinidad sequences were accurately identified to the genus level for all endemic plant species successfully amplified and sequenced using both matK and rbcL markers. DNA barcoding can contribute to taxonomic and biodiversity research and will complement efforts to select taxa for various molecular ecology and population genetics studies.

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Section: Introductionmentioning

confidence: 99%

Utility of DNA barcoding to identify rare endemic vascular plant species in Trinidad

Hosein

Austin

Maharaj

et al. 2017

Ecology and Evolution

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“…To test the efficiency of the Encephalartos DNA barcode library, we calculated species discrimination using BRONX version 2.0 (Barcode Recognition Obtained with Nucleotide eXposé's; Little and Stevenson 2007;Little 2011), which is an alignment-free algorithm that relies on the presence/absence of particular characters in the barcode sequences for identification, instead of using them all (Van Velzen et al 2012), thereby accounting for withintaxon variation (Little 2011). For this, a unified reference database was constructed for southern African Encephalartos spp.…”

Section: Encephalartos Dna Barcode Librarymentioning

confidence: 99%

Exposing the illegal trade in cycad species (Cycadophyta:Encephalartos) at two traditional medicine markets in South Africa using DNA barcoding

Williamson

Maurin

Shiba

et al. 2016

Genome

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Species in the cycad genus Encephalartos are listed in CITES Appendix I and as Threatened or Protected Species in terms of South Africa's National Environmental Management: Biodiversity Act (NEM:BA) of 2004. Despite regulations, illegal plant harvesting for medicinal trade has continued in South Africa and resulted in declines in cycad populations and even complete loss of sub-populations. Encephalartos is traded at traditional medicine markets in South Africa in the form of bark strips and stem sections; thus, determining the species traded presents a major challenge due to a lack of characteristic plant parts. Here, a case study is presented on the use of DNA barcoding to identify cycads sold at the Faraday and Warwick traditional medicine markets in Johannesburg and Durban, respectively. Market samples were sequenced for the core DNA barcodes (rbcLa and matK) as well as two additional regions: nrITS and trnH-psbA. The barcoding database for cycads at the University of Johannesburg was utilized to assign query samples to known species. Three approaches were followed: tree-based, similarity-based, and character-based (BRONX) methods. Market samples identified were Encephalartos ferox (Near Threatened), Encephalartos lebomboensis (Endangered), Encephalartos natalensis (Near Threatened), Encephalartos senticosus (Vulnerable), and Encephalartos villosus (Least Concern). Results from this study are crucial for making appropriate assessments and decisions on how to manage these markets.Key words: cycads, core barcoding regions, muthi, nrITS, trnH-psbA. Résumé

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“…This is reflected by the sharing of haplotypes, the nonmonophyly or incomplete clustering of the two taxa, the shallow divergence among them, and the lack of a clear 'barcoding gap'. This pattern is a population-genetic phenomenon, whereby, under coalescent theory, haplotypes of recently separated species (aided by potentially large population sizes) coalesce to a most recent common ancestor (the shared ancestral haplotype in this case) that pre-dates the actual speciation event, causing incomplete lineage sorting (Van Velzen et al 2012). This is then reflected in para-or polyphyly and the lack of a 'barcode gap' (Van Velzen et al 2012), with shallow divergences between taxa reflecting their recent separation and indicating insufficient time for monophyly to be established (Ward et al 2005;Hubert et al 2008).…”

Section: Genetic Analysismentioning

confidence: 99%

“…This pattern is a population-genetic phenomenon, whereby, under coalescent theory, haplotypes of recently separated species (aided by potentially large population sizes) coalesce to a most recent common ancestor (the shared ancestral haplotype in this case) that pre-dates the actual speciation event, causing incomplete lineage sorting (Van Velzen et al 2012). This is then reflected in para-or polyphyly and the lack of a 'barcode gap' (Van Velzen et al 2012), with shallow divergences between taxa reflecting their recent separation and indicating insufficient time for monophyly to be established (Ward et al 2005;Hubert et al 2008). Such a pattern of haplotypes being shared among morphologically valid species is not uncommon (Hubert et al 2008(Hubert et al , 2012Mabragaña et al 2011;Van Velzen et al 2012) and is well documented in reef fishes (Victor 2014).…”

Section: Genetic Analysismentioning

confidence: 99%

Distinction and relatedness – Taxonomic and genetic studies reveal a new species group of goatfishes (Upeneus; Mullidae)

Uiblein

Gouws

2015

Marine Biology Research

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Phenotypic and genetic differentiation among goatfish species of the genus Upeneus which had been formerly included in the so-called 'vittatus group' were examined using a comprehensive alpha-taxonomic and barcoding approach. Four of the five species of this group, U. indicus, U. suahelicus, U. supravittatus and U. vittatus, occur in the Western Indian Ocean (WIO), while U. parvus occurs in the Western Atlantic. An updated diagnosis of the WIO species, followed by detailed inter-and intraspecific comparison, is provided based on a large set of morphological and colour characters obtained from 134 specimens. The phenotypic comparisons among all five species and the evidence obtained from barcoding analyses of four species support the separation of U. parvus and U. vittatus from the other three more similar and closely related species which form the here newly established suahelicus group. An identification key for this species group is provided that should also minimize possible confusion with U. vittatus and species of the U. stenopsis group, two of which also occur in the WIO. New records for Madagascar and Saudi Arabia (U. suahelicus), Iran and Pakistan (U. supravittatus) and Sudan (U. vittatus) are reported. Application of this integrative approach to other species groups and species of Upeneus and the need to uncover intra-and interspecific distribution patterns and diversity more fully within the suahelicus group are outlined.

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DNA Barcoding of Recently Diverged Species: Relative Performance of Matching Methods

Cited by 146 publications

References 96 publications

Utility of DNA barcoding to identify rare endemic vascular plant species in Trinidad

Utility of DNA barcoding to identify rare endemic vascular plant species in Trinidad

Exposing the illegal trade in cycad species (Cycadophyta:Encephalartos) at two traditional medicine markets in South Africa using DNA barcoding

Distinction and relatedness – Taxonomic and genetic studies reveal a new species group of goatfishes (Upeneus; Mullidae)

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