DNA barcoding can successfully identify penaeus monodon, associate life cycle stages, and generate hypotheses of unrecognised diversity

DNA barcoding is the technique of sequencing a short fragment of cytochrome c oxidase subunit I (COI) mtDNA – a ‘DNA barcode’ - from a taxonomically unknown organism. This DNA barcode is then matched against a reference library of barcodes of known species origin to make a species identification. Si...

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Main Authors: John, James Wilson, Kong, Wah Sing
Format: Article
Language:English
Published: Universiti Kebangsaan Malaysia 2013
Online Access:http://journalarticle.ukm.my/6698/1/letter_to_the_editor.pdf
http://journalarticle.ukm.my/6698/
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Institution: Universiti Kebangsaan Malaysia
Language: English
id my-ukm.journal.6698
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institution Universiti Kebangsaan Malaysia
building Perpustakaan Tun Sri Lanang Library
collection Institutional Repository
continent Asia
country Malaysia
content_provider Universiti Kebangsaan Malaysia
content_source UKM Journal Article Repository
url_provider http://journalarticle.ukm.my/
language English
description DNA barcoding is the technique of sequencing a short fragment of cytochrome c oxidase subunit I (COI) mtDNA – a ‘DNA barcode’ - from a taxonomically unknown organism. This DNA barcode is then matched against a reference library of barcodes of known species origin to make a species identification. Since 2004 an international consortium has been promoting DNA barcoding as a global standard for taxonomic identifications (Savolainen et al. 2005). While we applaud Kumar et al. (2012) for bringing DNA barcoding to the attention of researchers in Malaysia, we have concerns about their understanding of the theory and methods of DNA barcoding which we discuss below. One major advantage of DNA barcoding over traditional species identification methods is the ability to correctly identify organisms from any life cycle stage to species. DNA barcoding has this capacity because intraspecific variation in DNA barcodes is generally much lower than interspecific variation between DNA barcodes (Savolainen et al. 2005), and crucially, because an organism’s DNA barcode does not change as the organism progresses from one life stage to the next. The integrity of DNA sequences through replication and organism growth is fundamental to their role as the “blueprint of life” (Hill 2006). Kumar et al. (2012) sequenced DNA barcodes from giant tiger prawns and report the pattern typically seen in DNA barcoding studies: “The average pair-wise distance within the sequences of different stages of P. monodon was two times lesser than the pair-wise distance of the out-group used [sic]”. Given the reported success of DNA barcoding at effectively identifying all individuals to species, the title of the article seems incongruous; what or where is the “Limit”? Kumar et al. (2012)’s conclusion points to the source of this incongruence: “However, it (COI) failed to segregate the different developmental stages to its corresponding life history stages [sic]”. If Kumar et al. (2012) intended to use a molecular technique to segregate individuals of P. monodon into different life stages, as implied in their objectives and conclusion, they took a fundamentally wrong approach; DNA characters are independent of life stage. We suggest instead, they focus on RNA and differential gene expression (e.g. Pérez-Porro et al. 2013). We can state confidently that increasing the sample size will not “reveal the efficiency of COI gene in pinpointing various life history stages of any organism” as Kumar et al. (2012) postulated. It is curious that Kumar et al. (2012) did not comment on the intraspecific distances observed within their P. monodon DNA barcodes (Figure 1(a)). We downloaded the barcodes from GenBank (GQ461913-GQ461918) and discovered the distances were an artefact of poor sequence editing and alignment. After removal of questionable nucleotides at the sequence edges and careful alignment (see Wilson 2012 for details on this procedure), Kimura 2-parameter (K2P) distances between the most distant barcodes were 1.3% (Figure 1(b)). Besides, the values from Kumar et al. (2012) are nonsensical as the “outgroup” sequences are a different fragment of COI and cannot be aligned to the “ingroup” (see alignment file at http://www.ukm.my/jsm/english_journals/vol42num12_2013/pg 1827-1829.html.). ‘Blasting’ the P. monodon barcodes against BOLD (boldsystems.org) revealed two distinct clusters (Figure 1(c)). The second cluster contained barcodes from India and Africa which matched closely with all the barcodes of Kumar et al. (2012). Dendograms of COI sequences (neighbour-joining trees are dendograms not a “phylograms” or “phylogenetic trees”) consistently showed two clusters within P. monodon, separated by K2P distance of >7% (Figure 1(b)-1(c)). Studies of COI variation in crustaceans have considered K2P ‘intraspecific’ distance of >1.3% (Lefebure et al. 2006) to be suggestive of unrecognised species. Lavery et al. (2004) previously suggested the presence of cryptic species within P. monodon based on mtDNA. We suggest that rather than focussing on a misconceived application of DNA barcoding, a more fruitful line of investigation may be sequencing (with careful editing and alignment) of nuclear regions to corroborate the existence of unrecognised species within P. monodon.
format Article
author John, James Wilson
Kong, Wah Sing
spellingShingle John, James Wilson
Kong, Wah Sing
DNA barcoding can successfully identify penaeus monodon, associate life cycle stages, and generate hypotheses of unrecognised diversity
author_facet John, James Wilson
Kong, Wah Sing
author_sort John, James Wilson
title DNA barcoding can successfully identify penaeus monodon, associate life cycle stages, and generate hypotheses of unrecognised diversity
title_short DNA barcoding can successfully identify penaeus monodon, associate life cycle stages, and generate hypotheses of unrecognised diversity
title_full DNA barcoding can successfully identify penaeus monodon, associate life cycle stages, and generate hypotheses of unrecognised diversity
title_fullStr DNA barcoding can successfully identify penaeus monodon, associate life cycle stages, and generate hypotheses of unrecognised diversity
title_full_unstemmed DNA barcoding can successfully identify penaeus monodon, associate life cycle stages, and generate hypotheses of unrecognised diversity
title_sort dna barcoding can successfully identify penaeus monodon, associate life cycle stages, and generate hypotheses of unrecognised diversity
publisher Universiti Kebangsaan Malaysia
publishDate 2013
url http://journalarticle.ukm.my/6698/1/letter_to_the_editor.pdf
http://journalarticle.ukm.my/6698/
http://www.ukm.my/jsm/
_version_ 1643736859921088512
spelling my-ukm.journal.66982016-12-14T06:41:57Z http://journalarticle.ukm.my/6698/ DNA barcoding can successfully identify penaeus monodon, associate life cycle stages, and generate hypotheses of unrecognised diversity John, James Wilson Kong, Wah Sing DNA barcoding is the technique of sequencing a short fragment of cytochrome c oxidase subunit I (COI) mtDNA – a ‘DNA barcode’ - from a taxonomically unknown organism. This DNA barcode is then matched against a reference library of barcodes of known species origin to make a species identification. Since 2004 an international consortium has been promoting DNA barcoding as a global standard for taxonomic identifications (Savolainen et al. 2005). While we applaud Kumar et al. (2012) for bringing DNA barcoding to the attention of researchers in Malaysia, we have concerns about their understanding of the theory and methods of DNA barcoding which we discuss below. One major advantage of DNA barcoding over traditional species identification methods is the ability to correctly identify organisms from any life cycle stage to species. DNA barcoding has this capacity because intraspecific variation in DNA barcodes is generally much lower than interspecific variation between DNA barcodes (Savolainen et al. 2005), and crucially, because an organism’s DNA barcode does not change as the organism progresses from one life stage to the next. The integrity of DNA sequences through replication and organism growth is fundamental to their role as the “blueprint of life” (Hill 2006). Kumar et al. (2012) sequenced DNA barcodes from giant tiger prawns and report the pattern typically seen in DNA barcoding studies: “The average pair-wise distance within the sequences of different stages of P. monodon was two times lesser than the pair-wise distance of the out-group used [sic]”. Given the reported success of DNA barcoding at effectively identifying all individuals to species, the title of the article seems incongruous; what or where is the “Limit”? Kumar et al. (2012)’s conclusion points to the source of this incongruence: “However, it (COI) failed to segregate the different developmental stages to its corresponding life history stages [sic]”. If Kumar et al. (2012) intended to use a molecular technique to segregate individuals of P. monodon into different life stages, as implied in their objectives and conclusion, they took a fundamentally wrong approach; DNA characters are independent of life stage. We suggest instead, they focus on RNA and differential gene expression (e.g. Pérez-Porro et al. 2013). We can state confidently that increasing the sample size will not “reveal the efficiency of COI gene in pinpointing various life history stages of any organism” as Kumar et al. (2012) postulated. It is curious that Kumar et al. (2012) did not comment on the intraspecific distances observed within their P. monodon DNA barcodes (Figure 1(a)). We downloaded the barcodes from GenBank (GQ461913-GQ461918) and discovered the distances were an artefact of poor sequence editing and alignment. After removal of questionable nucleotides at the sequence edges and careful alignment (see Wilson 2012 for details on this procedure), Kimura 2-parameter (K2P) distances between the most distant barcodes were 1.3% (Figure 1(b)). Besides, the values from Kumar et al. (2012) are nonsensical as the “outgroup” sequences are a different fragment of COI and cannot be aligned to the “ingroup” (see alignment file at http://www.ukm.my/jsm/english_journals/vol42num12_2013/pg 1827-1829.html.). ‘Blasting’ the P. monodon barcodes against BOLD (boldsystems.org) revealed two distinct clusters (Figure 1(c)). The second cluster contained barcodes from India and Africa which matched closely with all the barcodes of Kumar et al. (2012). Dendograms of COI sequences (neighbour-joining trees are dendograms not a “phylograms” or “phylogenetic trees”) consistently showed two clusters within P. monodon, separated by K2P distance of >7% (Figure 1(b)-1(c)). Studies of COI variation in crustaceans have considered K2P ‘intraspecific’ distance of >1.3% (Lefebure et al. 2006) to be suggestive of unrecognised species. Lavery et al. (2004) previously suggested the presence of cryptic species within P. monodon based on mtDNA. We suggest that rather than focussing on a misconceived application of DNA barcoding, a more fruitful line of investigation may be sequencing (with careful editing and alignment) of nuclear regions to corroborate the existence of unrecognised species within P. monodon. Universiti Kebangsaan Malaysia 2013-12 Article PeerReviewed application/pdf en http://journalarticle.ukm.my/6698/1/letter_to_the_editor.pdf John, James Wilson and Kong, Wah Sing (2013) DNA barcoding can successfully identify penaeus monodon, associate life cycle stages, and generate hypotheses of unrecognised diversity. Sains Malaysiana, 42 (12). pp. 1827-1829. ISSN 0126-6039 http://www.ukm.my/jsm/