DNA data bank of Japan (DDBJ) progress report

Mashima, Jun; Kodama, Yuichi; Kosuge, Takehide; Fujisawa, Takatomo; Katayama, Toshiaki; Nagasaki, Hideki; Okuda, Yoshihiro; Kaminuma, Eli; Ogasawara, Osamu; Okubo, Kousaku; Nakamura, Yasukazu; Takagi, Toshihisa

doi:10.1093/nar/gkv1105

Cited by 80 publications

(51 citation statements)

References 27 publications

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“…While our reference library represents a significant advance in plant DNA metabarcoding, our rbcL reference library and the ITS2 reference library of Sickel et al (2015) fall far short of being comprehensive. There are an estimated 450,000 flowering plant species on earth (Pimm (Benson et al, 2015), the DNA Data Bank of Japan (DDBJ; Mashima et al, 2015), and the European Molecular Biology Laboratory (EMBL) Nucleotide Sequence Database (Squizzato et al, 2015), do not require researchers submitting sequences to provide links to voucher specimens or raw sequence data, and may include sequences with incorrect species identification or low-quality sequence data. Other databases, such as the Barcode of Life Database (BOLD; Ratnasingham and Hebert, 2007), have stringent quality control but fewer plant rbcL sequences than the NCBI database, and no plant ITS2 sequences.…”

Section: Discussionmentioning

confidence: 99%

How Many Plant Species are There, Where are They, and at What Rate are They Going Extinct?

Pimm

Joppa

2015

Annals of the Missouri Botanical Garden

178

104

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Section: Discussionmentioning

confidence: 99%

How Many Plant Species are There, Where are They, and at What Rate are They Going Extinct?

Pimm

Joppa

2015

Annals of the Missouri Botanical Garden

178

104

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“…A current compromise is to rely on public sequence databases that may contain high coverage of species for a given habitat. For plants, the largest sources for reference sequencing data are the redundant repositories NCBI (Benson et al 2015), EMBL (Squizzato et al 2015), and DDBJ (Mashima et al 2015). There are over 32 million vascular plant nucleotide sequences deposited, although only a fraction of these represent DNA barcoding markers (see Table 1 for the number of sequences associated with each of the standard DNA barcoding markers).…”

Section: Component 2: Genetic Markersmentioning

confidence: 99%

Pollen DNA barcoding: current applications and future prospects

Bell

Vere

Keller

et al. 2016

Genome

201

170

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Identification of the species origin of pollen has many applications, including assessment of plant-pollinator networks, reconstruction of ancient plant communities, product authentication, allergen monitoring, and forensics. Such applications, however, have previously been limited by microscopy-based identification of pollen, which is slow, has low taxonomic resolution, and has few expert practitioners. One alternative is pollen DNA barcoding, which could overcome these issues. Recent studies demonstrate that both chloroplast and nuclear barcoding markers can be amplified from pollen. These recent validations of pollen metabarcoding indicate that now is the time for researchers in various fields to consider applying these methods to their research programs. In this paper, we review the nascent field of pollen DNA barcoding and discuss potential new applications of this technology, highlighting existing limitations and future research developments that will improve its utility in a wide range of applications.Key words: DNA metabarcoding, metagenomics, pollen, palynology, high-throughput sequencing, next-generation sequencing.Résumé : L'identification de l'espèce à l'origine d'un pollen se prête à de nombreuses applications dont la description des réseaux plante-pollinisateur, la reconstruction de communautés de plantes anciennes, l'authentification de produits, la surveillance des allergènes et les enquêtes médicolégales. Cependant, ces applications ont précédemment été limitées à l'identification du pollen par examen microscopique, un processus lent, à faible résolution taxonomique et qui compte peu de praticiens experts. Une alternative est l'identification du pollen par le recours aux codes à barres de l'ADN, une avenue qui permettrait de surmonter plusieurs de ces limitations. De récentes études ont montré qu'il était possible d'amplifier les marqueurs de codage tant chloroplastiques que nucléaires à partir du pollen. Ces récentes validations du métacodage à barres chez le pollen indiquent qu'il est maintenant opportun pour les chercheurs dans divers domaines de considérer l'emploi de ces méthodes dans leurs programmes de recherche. Dans cet article, les auteurs passent en revue le domaine naissant du codage à barres du pollen et discutent des nouvelles applications potentielles de cette technologie en mettant en lumière les limitations existantes ainsi que de futurs développements qui pourraient accroître son utilité dans un grand nombre d'applications. [Traduit par la Rédaction] Mots-clés : métacodage à barres, métagénomique, pollen, palynologie, séquençage à haut débit, séquençage de nouvelle génération.

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“…Aeromonas , a Gram-negative, facultative anaerobic and rod-shaped bacterium, is ubiquitous in fresh and brackish water [48]. Most Aeromonas species are known to be associated with human diseases.…”

Section: Predicted Exou Homologs In Pseudomonas and Other Gram-negmentioning

confidence: 99%

“…The sequence alignment was made by ClustalW with the BLOSUM protein weight matrix (DNA Data Bank of Japan) [48]. …”

Section: Figurementioning

confidence: 99%

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Pseudomonas aeruginosa Type III Secretory Toxin ExoU and Its Predicted Homologs

Sawa

Hamaoka

Kinoshita

et al. 2016

Toxins

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Pseudomonas aeruginosa ExoU, a type III secretory toxin and major virulence factor with patatin-like phospholipase activity, is responsible for acute lung injury and sepsis in immunocompromised patients. Through use of a recently updated bacterial genome database, protein sequences predicted to be homologous to Ps. aeruginosa ExoU were identified in 17 other Pseudomonas species (Ps. fluorescens, Ps. lundensis, Ps. weihenstephanensis, Ps. marginalis, Ps. rhodesiae, Ps. synxantha, Ps. libanensis, Ps. extremaustralis, Ps. veronii, Ps. simiae, Ps. trivialis, Ps. tolaasii, Ps. orientalis, Ps. taetrolens, Ps. syringae, Ps. viridiflava, and Ps. cannabina) and 8 Gram-negative bacteria from three other genera (Photorhabdus, Aeromonas, and Paludibacterium). In the alignment of the predicted primary amino acid sequences used for the phylogenetic analyses, both highly conserved and nonconserved parts of the toxin were discovered among the various species. Further comparative studies of the predicted ExoU homologs should provide us with more detailed information about the unique characteristics of the Ps. aeruginosa ExoU toxin.

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DNA data bank of Japan (DDBJ) progress report

Cited by 80 publications

References 27 publications

How Many Plant Species are There, Where are They, and at What Rate are They Going Extinct?

How Many Plant Species are There, Where are They, and at What Rate are They Going Extinct?

Pollen DNA barcoding: current applications and future prospects

Pseudomonas aeruginosa Type III Secretory Toxin ExoU and Its Predicted Homologs

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