Cytochrome C Oxidase I Barcode Research Articles

Identification of bird species and their prey using DNA barcode on feces from Korean traditional village groves and forests (maeulsoop)

A DNA barcode based on 648 bp of cytochrome c oxidase I (COI) gene aims to build species-specific libraries for animal groups. However, it is hard to recover full-length (648 bp) barcode gene from environmental fecal samples due to DNA degradation. In this study, we designed a new primer set (K_Bird), which amplifies a 226 bp fragment targeted an inner position of full-length COI barcode based on 102 species of Korean birds to improve amplification success, and we attempted to identify bird species from 39 avian fecal samples collected during 4 months from Jinan, South Korea. Simultaneously, we conducted a dietary analysis using a universal DNA mini-barcode (Uni_Minibar) from same fecal samples. In silico analysis on newly designed mini-barcode represented that genetic distances were 0.5% in species and 9.1% in genera. Intraspecific variations of 149 species out of 174 species (86%) between Korea and North America were within the threshold (5.3% threshold in this study). From environmental fecal samples collected in Jinan, we identified seven avian species, which have high similarity (99–100%) with registered COI sequences in GenBank. Eight kinds of prey species, such as moth, spider, fly, and dragonfly, were identified in dietary analysis. We suppose that our strategy applying mini-barcode for environmental fecal samples, might be a useful and convenient tool for species identification and dietary analysis for birds.

DNA barcoding of the leaf-mining moth subgenus Ectoedemia s. str. (Lepidoptera: Nepticulidae) with COI and EF1-α: two are better than one in recognising cryptic species

We sequenced 665bp of the Cytochrome C Oxidase I (COI) barcoding marker for 257 specimens and 482bp of Elongation Factor 1-α (EF1-α) for 237 specimens belonging to the leafmining subgenus Ectoedemia (Ectoedemia) in the basal Lepidopteran family Nepticulidae. The dataset includes 45 out of 48 West Palearctic Ectoedemia s. str. species and several species from Africa, North America and Asia. Both COI and EF1-α proved reliable as an alternative to conventional species identification for the majority of species and the combination of both markers can aid in species validation. A clear barcode gap is not present, and in some species large K2P intraspecific pairwise differences are found, up to 6.85% in COI and 2.9% in EF1-α. In the Ectoedemia rubivora species complex, the species E. rubivora, E. arcuatella and E. atricollis share COI barcodes and could only be distinguished by EF1-α. Diagnostic base positions, usually third codon positions, are in this and other cases a useful addition to species delimitation, in addition to distance methods. Ectoedemia albifasciella COI barcodes fall into two distinct clusters not related to other characters, whereas these clusters are absent in EF1-α, possibly caused by mtDNA anomalies or hybridisation. In the Ectoedemia subbimaculella complex, both sequences fail to unequivocally distinguish the species E. heringi, E. liechtensteini, E. phyllotomella and one population of E. subbimaculella. DNA barcodes confirm that North American Ectoedemia argyropeza are derived from a European introduction. We strongly advocate the use of a nuclear marker in addition to the universal COI barcode marker for better identifying species, including cryptic ones.

Diagnosis of Liposcelis entomophila (Insecta: Psocodea: Liposcelididae) based on morphological characteristics and DNA barcodes

Liposcelis entomophila infests stored grain and is one of the most important psocid species worldwide. Six geographically isolated strains of L. entomophila from Asia, Europe, and United States of America (USA) were compared based on morphological attributes and by molecular methods. Decisive characters of morphological diagnosis were studied using body size measurements and Scanning Electron Microscopy (SEM). Molecular identification of the six strains was performed via identification of DNA sequence similarities and phylogenetic analyses based on a 655-bp fragment from the 5′ end of the standard mitochondrial gene cytochrome c oxidase I (COI) barcode region. The results showed that both morphological and molecular approaches were able to accurately identify this species. Kimura-2-Parameter (K2P) divergence between geographically isolated strains was on average 1.75% for the COI sequence. Phylogenetic analyses revealed that sequences of L. entomophila strains' COI barcodes formed clusters with tight cohesion that were clearly distinct from those of allied species.

Identification of insect pests as food foreign materials using DNA barcodes

Insect foreign materials in food are of great economic and hygienic significance. However, identifying these species with any certainty requires an expert taxonomist and can be a time consuming process. Furthermore, insects are found as body parts or they are immature specimens that cannot be identified by conventional means. For these reasons, a reference database and efficient means of identification by non‐specialists are necessary to control insect pests.In this study, we chose 15 important insect pest species, because they had a higher probability of being included in human foods. We tested the utility of the cytochrome c oxidase I (COI) DNA barcodes for the identification. A 658‐bp fragment of the COI gene was sequenced, aligned, and a sequence data bank was constructed. As a result, the COI barcode sequence was suitable for identifying insect pests as food foreign materials. Photographs of morphological key characters by stereoscopic microscope and a pictorial key of the species are provided.

Taxonomic assessment of Lumbricidae (Oligochaeta) earthworm genera using DNA barcodes

The family Lumbricidae accounts for the most abundant earthworms in grasslands and agricultural ecosystems in the Paleartic region. Therefore, they are commonly used as model organisms in studies of soil ecology, biodiversity, biogeography, evolution, conservation, soil contamination and ecotoxicology. Despite their biological and economic importance, the taxonomic status and evolutionary relationships of several Lumbricidae genera are still under discussion. Previous studies have shown that cytochrome c oxidase I (COI) barcode phylogenies are informative at the intrageneric level. Here we generated 19 new COI barcodes for selected Aporrectodea specimens in Pérez-Losada et al. [1] including nine species and 17 populations, and combined them with all the COI sequences available in Genbank and Briones et al. [2] for Lumbricidae (435 sequences) and seven other Lumbricina families (480 sequences). Our maximum likelihood and Bayesian trees indicate that the genera Aporrectodea, Allolobophora, Eisenia and Dendrobaena (Lumbricidae) and Diplocardia, Metaphire and Amynthas (Megascolecidae) are polyphyletic and so invalid as currently defined. Our results also confirm that COI barcodes are a good proxy for estimating intrageneric phylogenetic diversity and relationships in earthworms.

Establishment of a mitochondrial DNA sequence database for the identification of fish species commercially available in South Africa

The limitations intrinsic to morphology-based identification systems have created an urgent need for reliable genetic methods that enable the unequivocal recognition of fish species, particularly those that are prone to overexploitation and/or market substitution. The aim of this study was to develop a comprehensive reference library of DNA sequence data to allow the explicit identification of 53 commercially available fish species in South Africa, most of which were locally caught marine species. Sequences of approximately 655 base pairs were generated for all species from the cytochrome c oxidase I (COI) gene, the region widely adopted for DNA barcoding. Specimens of the genus Thunnus were examined in further detail, employing additional mitochondrial DNA control region sequencing. Cumulative analysis of the sequences from the COI region revealed mean conspecific, congeneric and confamilial Kimura 2-parameter distances of 0.10%, 4.58% and 15.43%, respectively. The results showed that the vast majority (98%) of fish species examined could be readily differentiated by their COI barcodes, but that supplementary control region sequencing was more useful for the discrimination of three Thunnus species. Additionally, the analysis of COI data raised the prospect that Thyrsites atun (snoek) could constitute a species pair. The present study has established the necessary genetic information to permit the unambiguous identification of 53 commonly marketed fish species in South Africa, the applications of which hold a plethora of benefits relating to ecology research, fisheries management and control of commercial practices.

COI barcoding of true bugs (Insecta, Heteroptera)

Several recent studies have proposed that partial DNA sequences of the cytochrome c oxidase I (COI) mitochondrial gene might serve as DNA barcodes for identifying and differentiating between animal species, such as birds, fish and insects. In this study, we tested the effectiveness of a COI barcode to identify true bugs from 139 species collected from Korea and adjacent regions (Japan, Northeastern China and Fareast Russia). All the species had a unique COI barcode sequence except for the genus Apolygus (Miridae), and the average interspecific genetic distance between closely related species was about 16 times higher than the average intraspecific genetic distance. DNA barcoding identified one probable new species of true bug and revealed identical or very recently divergent species that were clearly distinguished by morphological characteristics. Therefore, our results suggest that COI barcodes can reveal new cryptic true bug species and are able to contribute for the exact identification of the true bugs.

Recovery of the mitochondrial COI barcode region in diverse Hexapoda through tRNA-based primers

BackgroundDNA barcoding uses a 650 bp segment of the mitochondrial cytochrome c oxidase I (COI) gene as the basis for an identification system for members of the animal kingdom and some other groups of eukaryotes. PCR amplification of the barcode region is a key step in the analytical chain, but it sometimes fails because of a lack of homology between the standard primer sets and target DNA.ResultsTwo forward PCR primers were developed following analysis of all known arthropod mitochondrial genome arrangements and sequence alignment of the tRNA-W gene which was usually located within 200 bp upstream of the COI gene. These two primers were combined with a standard reverse primer (LepR1) to produce a cocktail which generated a barcode amplicon from 125 of 141 species that included representatives of 121 different families of Hexapoda. High quality sequences were recovered from 79% of the species including groups, such as scale insects, that invariably fail to amplify with standard primers.ConclusionsA cocktail of two tRNA-W forward primers coupled with a standard reverse primer amplifies COI for most hexapods, allowing characterization of the standard barcode primer binding region in COI 5' as well as the barcode segment. The current results show that primers designed to bind to highly conserved gene regions upstream of COI will aid the amplification of this gene region in species where standard primers fail and provide valuable information to design a primer for problem groups.

DNA barcoding on subsets of three families in Aves

Background and aims. Previous studies carried out with DNA barcoding, based on regional groups, have shown that a standard mitochondrial gene could be used to identify birds. In the present study, we present an additional DNA barcoding survey of birds, using taxonomic groups instead of regional groups to verify the effectiveness of DNA barcoding on distinguishing species and to test whether the intraspecific clusters of species are associated with geographical discontinuities.Materials and methods. Taxonomic groups of three avian families—Phasianidae, Accipitridae, and Strigidae—were included in the study. The cytochrome c oxidase I (COI) sequences of 49 individuals were determined. Together with 122 sequences from previous studies, a total of 171 sequences from 66 bird species were analyzed.Results and conclusion. Results showed that all 66 species investigated had unique COI sequences and no sequences were shared between the species. Our results were congruent with previous studies suggesting that the COI barcode permits distinguishing most of the closely related species. Furthermore, by using geographically distinct clusters, diagnostic characters, and threshold levels, deep genetic splits (>1.5%) were observed in three species, and we therefore suggest treating them as evolutionary significant units.

Molecular species identification of Central European ground beetles (Coleoptera: Carabidae) using nuclear rDNA expansion segments and DNA barcodes

BackgroundThe identification of vast numbers of unknown organisms using DNA sequences becomes more and more important in ecological and biodiversity studies. In this context, a fragment of the mitochondrial cytochrome c oxidase I (COI) gene has been proposed as standard DNA barcoding marker for the identification of organisms. Limitations of the COI barcoding approach can arise from its single-locus identification system, the effect of introgression events, incomplete lineage sorting, numts, heteroplasmy and maternal inheritance of intracellular endosymbionts. Consequently, the analysis of a supplementary nuclear marker system could be advantageous.ResultsWe tested the effectiveness of the COI barcoding region and of three nuclear ribosomal expansion segments in discriminating ground beetles of Central Europe, a diverse and well-studied invertebrate taxon. As nuclear markers we determined the 18S rDNA: V4, 18S rDNA: V7 and 28S rDNA: D3 expansion segments for 344 specimens of 75 species. Seventy-three species (97%) of the analysed species could be accurately identified using COI, while the combined approach of all three nuclear markers provided resolution among 71 (95%) of the studied Carabidae.ConclusionOur results confirm that the analysed nuclear ribosomal expansion segments in combination constitute a valuable and efficient supplement for classical DNA barcoding to avoid potential pitfalls when only mitochondrial data are being used. We also demonstrate the high potential of COI barcodes for the identification of even closely related carabid species.

Filling the gap - COI barcode resolution in eastern Palearctic birds

BackgroundThe Palearctic region supports relatively few avian species, yet recent molecular studies have revealed that cryptic lineages likely still persist unrecognized. A broad survey of cytochrome c oxidase I (COI) sequences, or DNA barcodes, can aid on this front by providing molecular diagnostics for species assignment. Barcodes have already been extensively surveyed in the Nearctic, which provides an interesting comparison to this region; faunal interchange between these regions has been very dynamic. We explored COI sequence divergence within and between species of Palearctic birds, including samples from Russia, Kazakhstan, and Mongolia. As of yet, there is no consensus on the best method to analyze barcode data. We used this opportunity to compare and contrast three different methods routinely employed in barcoding studies: clustering-based, distance-based, and character-based methods.ResultsWe produced COI sequences from 1,674 specimens representing 398 Palearctic species. These were merged with published COI sequences from North American congeners, creating a final dataset of 2,523 sequences for 599 species. Ninety-six percent of the species analyzed could be accurately identified using one or a combination of the methods employed. Most species could be rapidly assigned using the cluster-based or distance-based approach alone. For a few select groups of species, the character-based method offered an additional level of resolution. Of the five groups of indistinguishable species, most were pairs, save for a larger group comprising the herring gull complex. Up to 44 species exhibited deep intraspecific divergences, many of which corresponded to previously described phylogeographic patterns and endemism hotspots.ConclusionCOI sequence divergence within eastern Palearctic birds is largely consistent with that observed in birds from other temperate regions. Sequence variation is primarily congruent with taxonomic boundaries; deviations from this trend reveal overlooked biological patterns, and in some cases, overlooked species. More research is needed to further refine the taxonomic status of some Palearctic birds, but large genetic surveys such as this may facilitate this effort. DNA barcodes are a practical means for rapid species assignment, although efficient analytical methods will likely require a two-tiered approach to differentiate closely related pairs of species.

Biological identifications through DNA barcodes: the case of the Crustacea

The ability of a 650 base pair section of the mitochondrial cytochrome c oxidase I (COI) gene to provide species-level identifications has been demonstrated for large taxonomic assemblages of animals such as insects, birds, and fishes, but not for the subphylum Crustacea, one of the most diverse groups of arthropods. In this study, we test the ability of COI to provide identifications in this group, examining two disparate levels in the taxonomic hierarchy — orders and species. The first phase of our study involved the development of a sequence profile for 23 dominant crustacean orders, based upon the analysis of 150 species, each belonging to a different family. The COI amino acid data placed these taxa into cohesive assemblages whose membership coincided with currently accepted boundaries at the order, superorder, and subclass levels. Species-level resolution was subsequently examined in an assemblage of Decapoda and in representatives of the genera Daphnia (Cladocera) and Gammarus (Amphipoda). These studies revealed that levels of nucleotide sequence divergence were from 19 to 48 times greater between congeneric species than between individuals of a species. We conclude that sequence variation in the COI barcode region will be very effective for discriminating species of Crustacea.

A first approach to the usefulness of cytochrome c oxidase I barcodes in the identification of closely related delphinid cetacean species

The DNA barcode initiative has gained particular popularity as a promising tool to assist in species identification by using a single mitochondrial gene, cytochrome c oxidase I (COI). In some animal groups, COI barcodes have proved efficient in separating closely related taxa. However, several issues remain for discussion, namely how efficient this tool will be in animal groups with an unresolved taxonomy. Here, we examined COI sequences in delphinid cetaceans, a group where taxonomic uncertainty still exists. We analysed species belonging to the genera Stenella, Tursiops and Delphinus in the North-east Atlantic using cytochrome b gene sequences for comparison. We obtained values of COI interspecific genetic divergence ranging from 1.47% to 2.45%, which suggests a recent separation of the analysed taxa. S. coeruleoalba and D. delphis were the most similar species, with COI phylogenetic trees failing to separate them. On the other hand, the phylogenetic tree obtained with cytochrome b sequences correctly clustered species with high bootstrap support values. We thus consider that the application of COI barcodes in delphinid cetaceans should be done with caution; not only has the cytochrome b gene been shown to be phylogenetically more informative, but relying only on mitochondrial DNA genes alone may be problematic.

Is a Large-Scale DNA-Based Inventory of Ancient Life Possible?

A complete DNA-based inventory of the Earth's present biota using large-scale high-throughput DNA sequencing of signature region(s) (DNA barcoding) is an ambitious proposal rivaling the Human Genome Project. We examine whether this approach will also enable us to assess the past diversity of the earth's biota. To test this, we sequenced the 5' terminus of the mitochondrial cytochrome c oxidase I (COI) gene of individuals belonging to a group of extinct ratite birds, the moa of New Zealand. Moa comprised a large number of taxa that radiated in isolation on this oceanic landmass. Using a phylogenetic approach based on a large data set including protein coding and 12S DNA sequences as well as morphology, we now have precise information about the number of moa species that once existed. We show that each of the moa species detected using this extensive data set has a unique COI barcode(s) and that they all show low levels of within-species COI variation. Consequently, we conclude that COI sequences accurately identify the species discovered using the larger data set. Hence, more generally, this study suggests that DNA barcoding might also help us detect other extinct animal species and that a large-scale inventory of ancient life is possible.

Identification of Birds through DNA Barcodes.

Short DNA sequences from a standardized region of the genome provide a DNA barcode for identifying species. Compiling a public library of DNA barcodes linked to named specimens could provide a new master key for identifying species, one whose power will rise with increased taxon coverage and with faster, cheaper sequencing. Recent work suggests that sequence diversity in a 648-bp region of the mitochondrial gene, cytochrome c oxidase I (COI), might serve as a DNA barcode for the identification of animal species. This study tested the effectiveness of a COI barcode in discriminating bird species, one of the largest and best-studied vertebrate groups. We determined COI barcodes for 260 species of North American birds and found that distinguishing species was generally straightforward. All species had a different COI barcode(s), and the differences between closely related species were, on average, 18 times higher than the differences within species. Our results identified four probable new species of North American birds, suggesting that a global survey will lead to the recognition of many additional bird species. The finding of large COI sequence differences between, as compared to small differences within, species confirms the effectiveness of COI barcodes for the identification of bird species. This result plus those from other groups of animals imply that a standard screening threshold of sequence difference (10× average intraspecific difference) could speed the discovery of new animal species. The growing evidence for the effectiveness of DNA barcodes as a basis for species identification supports an international exercise that has recently begun to assemble a comprehensive library of COI sequences linked to named specimens.