ライフサイエンスコーパス: NCBI

1 tional Center for Biotechnology Information (NCBI).

2 OG (Eukaryotic Orthologous Groups) database (NCBI).

3 tional Center for Biotechnology Information (NCBI).

4 he common software and website (ClustalX and NCBI).

5 tional Center for Biotechnology Information (NCBI).

6 tional Center for Biotechnology Information (NCBI).

7 tional Center for Biotechnology Information (NCBI).

8 uding mitochondrial sequences retrieved from NCBI).

9 ational Center of Biotechnology Information (NCBI).

10 tional Center for Biotechnology Information (NCBI).

11 sequencing consortiums and those provided by NCBI.

12 as Gene Ontology, and other databases within NCBI.

13 may be annotated with gene information from NCBI.

14 ) than to Drosophila proteins/genes (18%) in NCBI.

15 nbank U00096 are transmitted from EcoGene to NCBI.

16 pring are comparable to known sequences from NCBI.

17 is thaliana published in the GEO database of NCBI.

18 will be exchanged with a similar database at NCBI.

19 as Gene Ontology and other databases within NCBI.

20 o 2018 from the Sequence Read Archive at the NCBI.

21 d from public sequence data archives such as NCBI.

22 an accession from the SRA repository at the NCBI.

23 tional 142 strains with genomes available at NCBI.

24 em is integrated with all other databases at NCBI.

25 f 3.7-5.7 kb) which were screened against an NCBI 16S rRNA gene database.

26 Strikingly, one pathogenic mutation T233A (NCBI accession no.

27 raft genome of the bacterium was determined (NCBI accession numbers AHBC01000001 through AHBC01000103

28 Staff scientists at NCBI analyze user-submitted data in the archive, produci

29 wer (SV) to access, analyze, and disseminate NCBI and custom biomedical sequence data.

30 rinciples behind the NCBI Taxonomy Database; NCBI and EBI papers on the recently launched BioSample d

31 es include more explicit reporting about the NCBI and Ensembl annotation releases being compared, new

32 able molecular profiling datasets taken from NCBI and HapMap.

33 files, while public archives such as ENA and NCBI and large international collaborations such as the

34 from 14 apple genotypes were downloaded from NCBI and mapped against a reference EST assembly to iden

35 mproved curation, mapping of genomes to both NCBI and RDP taxonomies, and refined tools for querying

36 es, alongside the Gene Expression Omnibus at NCBI and the DDBJ Omics Archive, supporting peer-reviewe

37 tional Center for Biotechnology Information (NCBI) and Ensembl genome annotation pipelines.

38 tional Center for Biotechnology Information (NCBI) and European Bioinformatics Institute (EBI).

39 anizing hub for many of the resources at the NCBI, and provides a means for clustering elements withi

40 lity between the RCSB Protein Data Bank, the NCBI, and the UniProtKB data resources and visualize int

41 icy for eukaryotic genome annotation via the NCBI annotation pipeline.

42 data access in advance of its deposition at NCBI, as well as browsable tracks of alignments against

43 ination of fasta files, GenBank files and/or NCBI assembly accessions as input and outputs an alignme

44 assemblies have been updated, as recorded by NCBI assembly archive.

45 nces to generate a draft assembly, CHM1_1.1 (NCBI AssemblyDB GCA_000306695.2).

46 owa at dmk-brain.ecn.uiowa.edu/ATGC/ and the NCBI at ftp.ncbi.nlm.nih.gov/pub/kristensen/ATGC/atgc_ho

47 Microbiome Project were aligned against the NCBI bacterial taxonomy database and the Comprehensive A

48 cripts for downloading and parsing data from NCBI BioSample and BioProject into the database.

49 also provides online analysis tools such as NCBI BLAST and Batch BLAST.

50 ) of engineered ZFPs, and direct querying of NCBI BLAST servers for identifying potential off-target

51 , sequence similarity search (e.g. FASTA and NCBI BLAST), multiple sequence alignment (e.g. Clustal O

52 ith a self-contained BLAST module leveraging NCBI Blast+ commands, or via a managed Galaxy instance t

53 ut genomes, invoke third-party tools such as NCBI Blast+, run PanOCT, generate a consensus pan-genome

54 ensitivity as the query-indexed BLAST, i.e., NCBI BLAST, or they can only support nucleotide sequence

55 6-fold end-to-end speedup over multithreaded NCBI BLAST.

56 search, delivers identical hits returned to NCBI BLAST.

57 fold end-to-end speedup over single-threaded NCBI BLAST.

58 LAST produces identical alignment results as NCBI-BLAST and its computational speed is much faster th

59 In comparison to the sequential NCBI-BLAST, the speedups achieved by GPU-BLAST range mos

60 mplementation is based on the source code of NCBI-BLAST, thus maintaining the same input and output i

61 BLAST, an accelerated version of the popular NCBI-BLAST.

62 accelerate BLASTX and BLASTP-basic tools of NCBI-BLAST.

63 putational speed is much faster than that of NCBI-BLAST.

64 accelerates MegaBLAST--the default module of NCBI-BLASTN.

65 Speedups achieved by H-BLAST over sequential NCBI-BLASTP (resp. NCBI-BLASTX) range mostly from 4 to 1

66 y H-BLAST over sequential NCBI-BLASTP (resp. NCBI-BLASTX) range mostly from 4 to 10 (resp. With 2 CPU

67 GPUs, H-BLAST can be faster than 16-threaded NCBI-BLASTX.

68 e Bookshelf data format is XML tagged in the NCBI Book DTD (Document Type Definition), modeled after

69 Mb region (positions 44,394,495-45,364,167; NCBI build 37), we found evidence for at least three ind

70 es in more than 95% of the reference genome (NCBI Build 37).

71 tional Center for Biotechnology Information (NCBI) build-37] and functionally classified using the KO

72 ith other NCBI molecular databases, books at NCBI can be used to provide reference information for bi

73 c regions can also be searched for using the NCBI Clone Finder tool, which accepts queries based on s

74 s an expansion and replacement of the former NCBI Clone Registry and has records for genomic and cell

75 tional Center for Biotechnology Information (NCBI) Clone DB is an integrated resource providing infor

76 The NCBI Conserved Domain Database (CDD) consists of a colle

77 These sets correspond to NCBI Conserved Domain Database alignments, which have be

78 high-throughput RNA-sequencing studies, the NCBI Conserved Domain Database, sequences from pre-genom

79 databases such as Entrez Protein database at NCBI contain information about publications associated w

80 ply accept GSM IDs to automatically download NCBI data or can accept user's private bigwig files as i

81 10,932 novel tissue/cell specific CDS to the NCBI database for this important tick species.

82 e sequences of STEC strains available in the NCBI database indicates that LAA PAI is exclusively pres

83 any previously characterized protein in the NCBI database.

84 tional Center for Biotechnology Information (NCBI) database contained >2 million viral genome sequenc

85 tional Center for Biotechnology Information (NCBI) database records.

86 for SNP genotyping, a remote BLAST window to NCBI databases, and remote sequence retrieval from GenBa

87 phenotype combination, adds value from other NCBI databases, assigns a distinct accession of the form

88 n between the Epigenomics resource and other NCBI databases, including the Gene database and PubMed.

89 Unlike other NCBI databases, such as GenBank and Gene, which have a s

90 ited homology to previous annotations within NCBI databases, such as parvovirus.

91 as and the EGA, as well as from mirroring of NCBI dbGaP data.

92 nother twenty-six reported variants from the NCBI dbSNP database that have yet to be studied to predi

93 chine learning approach for DNorm, using the NCBI disease corpus and the MEDIC vocabulary, which comb

94 erOne achieves high performance on diseases (NCBI Disease corpus, NER f-score: 0.829, normalization f

95 JNLPBA, 94.22% on BC5CDR-chemical, 90.08% on NCBI-disease, 89.24% on LINNAEUS, and 76.33% on Species-

96 four of them (i.e., BC2GM, BC5CDR-chemical, NCBI-disease, and Species-800).

97 more than half were similar to sequences at NCBI (e value < e(-3)).

98 athogen metadata, populate it with data from NCBI, easily query the data, and obtain visual summaries

99 classification of project data submitted to NCBI, EBI and DDBJ databases.

100 ies, and linking to other databases, such as NCBI, Ensembl and Reactome, a wide variety of different

101 enerated by distilling gene predictions from NCBI, Ensembl and VEGA.

102 l and manual genome annotations generated by NCBI, Ensembl and Vega/HAVANA.

103 hat they are consistently represented on the NCBI, Ensembl, and UCSC Genome Browsers.

104 owing number of biological resources such as NCBI, Ensembl, UniProt and Reactome.

105 It is a Java servlet that uses NCBI Entrez (eUtils) web services to interact with PubCh

106 Chem's bioassay data are integrated into the NCBI Entrez information retrieval system, thus making Pu

107 GenBank is accessible through the NCBI Entrez retrieval system that integrates data from t

108 GenBank is accessible through the NCBI Entrez retrieval system, which integrates data from

109 Clone DB is indexed in the NCBI Entrez system and can be queried by fields that inc

110 e than thirty databases available within the NCBI Entrez system.

111 tional Center for Biotechnology Information (NCBI) Entrez retrieval system, which integrates data fro

112 sualization and efficient exploration of any NCBI epigenetic data in any genomic region without need

113 since the initial publication describing the NCBI Epigenomics resource and currently consist of >3700

114 tional Center for Biotechnology Information (NCBI), European Bioinformatics Institute (EBI) and the D

115 a and with wrapper functions for calling the NCBI eUtilities and PubChem PUG web services.

116 nding to host cells) sequence available from NCBI flu database, and showed an overall correspondence

117 Books at NCBI followed the route of journal articles in the PubMe

118 e Gene Expression Omnibus public database at NCBI following MIAME guidelines.

119 iously, there was no centralized approach at NCBI for collecting this information and using it across

120 llecTF entries are periodically submitted to NCBI for integration into RefSeq complete genome records

121 tional Center for Biotechnology Information (NCBI) for functional annotations of single nucleotide po

122 cations of 676 microbial organisms using the NCBI FTP database for the 16S rRNA.

123 all the species and sequences present in the NCBI GenBank and allows for a single step classification

124 Submission of genomic data to NCBI GenBank is a requirement prior to publication and p

125 datasets such as the nucleotide database in NCBI GenBank, metagenomic datasets in Camera, and the ma

126 etrieving all genomic DNA sequences from the NCBI GenBank, over 1 x 10(11) base pairs of 3.3 x 10(6)

127 ge to facilitate virus genome submissions to NCBI GenBank.

128 nd data processing pipelines that transforms NCBI Gene Expression Omnibus (GEO) NGS content into deep

129 large scale of epigenetic data is stored in NCBI Gene Expression Omnibus (GEO).

130 sets from The Cancer Genome Atlas (TCGA) and NCBI Gene Expression Omnibus (NCBI-GEO) and performed mu

131 Public databases such as the NCBI Gene Expression Omnibus contain extensive and expon

132 tted by users and imported directly from the NCBI Gene Expression Omnibus.

133 tional Center for Biotechnology Information (NCBI) Gene database.

134 ces of human genes, comprising 13,464 unique NCBI genes, participating in a wide variety of biologica

135 ing from the current human genome reference (NCBI Genome GRCh37)-a substantial fraction of the human

136 rrent versions of genome assemblies from the NCBI genomes FTP site.

137 NCBI GEO accession numbers: mRNA data (NanoString): GSE1

138 ive datasets that were manually curated from NCBI GEO and the exRNA Atlas, including 66 datasets, 228

139 alysis of The Cancer Genome Atlas (TCGA) and NCBI GEO data sets, which demonstrated inverse changes i

140 ) from various data sets freely available at NCBI GEO database.

141 ubsequently, we analyse a publicly available NCBI GEO gene expression dataset studying tumour bearing

142 prominent examples include ArrayExpress and NCBI GEO.

143 hnology Information Gene Expression Omnibus (NCBI-GEO) a total of 466 quality RNA sequencing (RNA-seq

144 las (TCGA) and NCBI Gene Expression Omnibus (NCBI-GEO) and performed multispectral immunohistochemist

145 lume and complexity of data sets archived at NCBI grow rapidly, so does the need to gather and organi

146 In collaboration with Georgia Tech, NCBI has developed a new approach to genome annotation t

147 tional Center for Biotechnology Information (NCBI), HMMER, and MUSCLE; scaled them to tens of thousan

148 summaries for figures in PubMed Central and NCBI Images.

149 IBIS is the NCBI Inferred Biomolecular Interaction Server.

150 tional Center for Biotechnology Information (NCBI) is a freely available archive for interpretations

151 tional Center for Biotechnology Information (NCBI) is an archive providing free access to a wide rang

152 te at the National Center for Biotechnology (NCBI) is an important resource for searching and alignin

153 tional Center for Biotechnology Information (NCBI) is higher than the complete ones.

154 This article describes Bookshelf at NCBI: its growth, data handling and retrieval and integr

155 tional Center for Biotechnology Information (NCBI) maintains and curates a publicly available databas

156 Through integration with other NCBI molecular databases, books at NCBI can be used to p

157 ertebrate genome assemblies currently in the NCBI (National Center for Biotechnology Information) dat

158 download from the NCBI repository: ftp://ftp.ncbi.nih.gov/genomes/.

159 upplementary data are available at ftp://ftp.ncbi.nih.gov/pub/aravind/UMA/MVB12.html.

160 nd presented on the web and through FTP (ftp.ncbi.nih.gov/pub/GTR/_README.html).

161 ce code freely available for download at ftp.ncbi.nih.gov/pub/wolf/COGs/COGsoft/.

162 and two datasets are available at ftp://ftp.ncbi.nlm.nih.gov/pub/FISHtrees.

163 cer examined here are available at ftp://ftp.ncbi.nlm.nih.gov/pub/FISHtrees.

164 rain.ecn.uiowa.edu/ATGC/ and the NCBI at ftp.ncbi.nlm.nih.gov/pub/kristensen/ATGC/atgc_home.html.

165 stem, is available for download at ftp://ftp.ncbi.nlm.nih.gov/pub/qmbp/qmbp_ms/RAId/RAId_Linux_64Bit

166 stem, is available for download at ftp://ftp.ncbi.nlm.nih.gov/pub/qmbp/qmbp_ms/RAId/RAId_Linux_64Bit.

167 one version can be downloaded from ftp://ftp.ncbi.nlm.nih.gov/pub/qmbpmn/SaddleSum/.

168 in the PubChem BioAssay database (ftp://ftp.ncbi.nlm.nih.gov/pubchem/Bioassay/).

169 tional Center for Biotechnology Information (NCBI) non-redundant protein database approaches 90%.

170 publicly available protein sequences in the NCBI nonredundant (nr) database.

171 e also makes it possible to index the entire NCBI nonredundant nucleotide sequence database (a total

172 dable clusters for several public databases (NCBI NR, Swissprot and PDB) at different identity levels

173 unpublished data (sequence available in the NCBI nucleotide and MIPS Wheat Genome Databases).

174 Data come from two sources (1) the NCBI nucleotide database and (2) unpublished sequencing

175 GenBank is accessible through the NCBI Nucleotide database, which links to related informa

176 tional Center for Biotechnology Information (NCBI) nucleotide and protein databases, the European Mol

177 tional Center for Biotechnology Information (NCBI) nucleotide database, their expression at the prote

178 formation is loaded for nodes annotated with NCBI numbers or UniProt identifiers and (optionally) Pro

179 Comparison with the NCBI Pathogen Detection database revealed extensive Camp

180 tional Center for Biotechnology Information (NCBI) previously made available a tool for validating an

181 35% and 2,704 genes, was annotated using the NCBI Prokaryotic Genomes Automatic Annotation Pipeline.

182 as investigated using a similarity search in NCBI protein BLAST program (BLASTP).

183 tional Center for Biotechnology Information (NCBI) provides a large suite of online resources for bio

184 tional Center for Biotechnology Information (NCBI) provides analysis and retrieval resources for the

185 tional Center for Biotechnology Information (NCBI) provides analysis and retrieval resources for the

186 of the traits on miRNA obtained through the NCBI PubMed database search (adjusted P = 0.024).

187 tional Center for Biotechnology Information (NCBI) ray-finned fish ( Actinopterygii ) database, resul

188 tional Center for Biotechnology Information (NCBI) recently announced '1000 prokaryotic genomes are n

189 ons for human and mouse genes extracted from NCBI Reference Sequence (RefSeq) and Drosophila genes fr

190 NCBI Reference Sequence (RefSeq) genomes for viruses, pr

191 tional Center for Biotechnology Information (NCBI) Reference Sequence (RefSeq) database is a collecti

192 tional Center for Biotechnology Information (NCBI) Reference Sequence (RefSeq) database is a collecti

193 The NCBI RefSeq database is used for this; if a reference se

194 draft bacterial and archaeal genomes in the NCBI RefSeq database reveals that 2250 genomes are conta

195 0 enable regular genome updates based on the NCBI RefSeq database.

196 ularly updated following new releases of the NCBI RefSeq database.

197 , we provide containment estimates for every NCBI RefSeq genome within every SRA metagenome and demon

198 ases, including the clustering of all 54,118 NCBI RefSeq genomes in 33 CPU h; real-time database sear

199 (INSDC) and the assembly represented in the NCBI RefSeq project.

200 ends on an alignment dataset of non-assembly NCBI RefSeq sequences (prefixed NM, NR and NG), as well

201 JGI Phytozome and selected subcollections of NCBI RefSeq.

202 official gene set, Reference Sequences from NCBI (RefSeq), predicted gene models, ESTs and whole-gen

203 tional Center for Biotechnology Information (NCBI) repositories: Gene Expression Omnibus (GEO) and Se

204 his work are available for download from the NCBI repository: ftp://ftp.ncbi.nih.gov/genomes/.

205 tional Center for Biotechnology Information (NCBI) represent a large collection of more than 35,000 a

206 NCBI resources include Entrez, the Entrez Programming Ut

207 NCBI resources include Entrez, the Entrez Programming Ut

208 RefSeq annotation; is integrated with other NCBI resources such as Gene, dbGaP, and BLAST; and provi

209 Results are integrated and linked with other NCBI resources to ensure dissemination of the informatio

210 This has important implications for many NCBI resources, some of which are outlined below.

211 Using NCBI resources, we retrieved PubMed abstracts, PubChem c

212 rotein sequences obtained from UniProtKB and NCBI respectively.

213 51 complete genomes taken from UniProtKB and NCBI respectively.

214 olymorphisms, mapped genetic markers, mapped NCBI Rosaceae genes, gene homologs and association of In

215 rom whole-genome sequencing (WGS) data using NCBI's AMRFinder and custom HMM search.

216 ate and interpret the masses of data held in NCBI's archival repositories.

217 NCBI's CDD, the Conserved Domain Database, enters its 15

218 NCBI's Conserved Domain Database (CDD) aims at annotatin

219 NCBI's Conserved Domain Database (CDD) is a resource for

220 already in the database of interest such as NCBI's dbSNP.

221 ess for ClinVar records is available through NCBI's E-utilities.

222 tation is maintained for proteins tracked by NCBI's Entrez database, and live search services are off

223 e browsing through NCBI's Entrez system, via NCBI's Entrez programming utilities (E-Utilities and Ent

224 e browsing through NCBI's Entrez system, via NCBI's Entrez programming utilities (E-Utilities) and fo

225 d domain annotation for sequences tracked in NCBI's Entrez protein database, which can be retrieved f

226 resentation of structure neighboring data in NCBI's Entrez query and retrieval system.

227 MMDB is tightly integrated with NCBI's Entrez search and retrieval system, and mirrors t

228 s available via interactive browsing through NCBI's Entrez system, via NCBI's Entrez programming util

229 s available via interactive browsing through NCBI's Entrez system, via NCBI's Entrez programming util

230 the mammalian and human subsets, changes to NCBI's eukaryotic annotation pipeline and modifications

231 Recent changes to NCBI's eukaryotic genome annotation pipeline provide hig

232 NCBI's flagship genome browser, Genome Data Viewer (GDV)

233 nto many annotation namespaces, e.g. KEGG or NCBI's GenBank.

234 NCBI's Gene Expression Omnibus (GEO) is a rich community

235 We use data from the NCBI's Gene Expression Omnibus (GEO) public repository t

236 available gene expression data deposited in NCBI's gene expression omnibus (GEO), such as the GEO we

237 o expedite submission of data and results to NCBI's Gene Expression Omnibus following the FAIR (Finda

238 t in discrepancies that complicate analysis. NCBI's genetic variation resources, dbSNP and ClinVar, r

239 Data mining of NCBI's GEO microarrays revealed strong coexpression betw

240 tions of the complete prokaryotic genomes in NCBI's Microbial Genome Project Database and applying st

241 re based on the controlled vocabularies that NCBI's Microbial Genome Project database uses to specify

242 An update on the NCBI's MMDB describes VAST+, an improved tool for protei

243 To this end, NCBI's Molecular Modeling Database (MMDB), which is base

244 Thus, the new NCBI's Prokaryotic Genome Annotation Pipeline (PGAP) rel

245 NCBI's PSI-BLAST utilizes iterative model building in or

246 rtebrate model organisms and integrated into NCBI's Reference Sequence (RefSeq) dataset, resulting in

247 on of curation and automated processing from NCBI's Reference Sequence project (RefSeq), collaboratin

248 ential growth of GenBank and the creation of NCBI's RefSeq database, we have developed a new database

249 or the 15,000+ complete bacterial genomes in NCBI's Refseq library.

250 The NCBI's Sequence Read Archive (SRA) promises great biolog

251 Raw data is available at NCBI's SRA with accession number PRJNA271645.

252 In NCBI's Variation submission portal, submitters upload ba

253 structure-structure alignments obtained from NCBI's VAST+ service.

254 onal Center for Biotechnology Information's (NCBI's) Sequence Read Archive (SRA) via unique persisten

255 tional Center for Biotechnology Information (NCBI)'s database for gene-specific information.

256 tional Center for Biotechnology Information (NCBI)'s Entrez Utilities (E-Utilities or E-Utils) and th

257 a, and unidentified organisms present in the NCBI sequence database.

258 r and from the baboon STLV-1 sequence in the NCBI sequence database.

259 ated on various metagenomic samples from the NCBI Sequence Read Archive, suggesting 2- to 4-fold comp

260 t and primate samples from 884 series in the NCBI Sequence Read Archive.

261 search community can use GDV and the related NCBI Sequence Viewer (SV) to access, analyze, and dissem

262 is 1,571 bp longer (0.1%) than the reference NCBI sequence.

263 ne, sodA, and gyrB data are available at the NCBI, showing that gyrB is superior to 16S gene and sodA

264 q data is freely available for download from NCBI SRA (Accession: PRJNA398984), the assembled and ann

265 Raw reads data are available under the NCBI SRA accession SRP066985.

266 anscriptome data are publically available at NCBI SRA: SRS965087.

267 icroRNA sequencing (miRNA-seq) datasets from NCBI-SRA and calculated expression profiles for differen

268 k genome records that can be modified by the NCBI staff annotators.

269 uences (ISs) compared to 35 in the reference NCBI strain, and these have resulted in the direct delet

270 nBank submissions are made using BankIt, the NCBI Submission Portal, or the tool tbl2asn, and are obt

271 s are made using the web-based BankIt or the NCBI Submission Portal.

272 nformation and Voting theories that uses the NCBI Taxonomic Database hierarchy to assign taxonomy to

273 rees (with ExaML or RAxML-Light) for a given NCBI taxonomic group.

274 functional classifications as well as a GO, NCBI Taxonomy and KEGG Pathway Browser.

275 CBI, PubMed, PubMed Central (PMC), Gene, the NCBI Taxonomy Browser, BLAST, BLAST Link (BLink), Primer

276 bMed, PubMed Central (PMC), Entrez Gene, the NCBI Taxonomy Browser, BLAST, BLAST Link (BLink), Primer

277 The NCBI Taxonomy database is the standard nomenclature and

278 The NCBI Taxonomy Database now includes annotation of type m

279 ological resources, currently comprising the NCBI taxonomy database, IntEnz, GO, Pfam, InterPro, SCOP

280 ch as Pfam, SCOP, CATH, GO, InterPro and the NCBI taxonomy database.

281 l resources, such as GO, EC, UniProt and the NCBI Taxonomy database.

282 led explanation of the principles behind the NCBI Taxonomy Database; NCBI and EBI papers on the recen

283 weight calibration algorithm to consolidate NCBI taxonomy information in concert with unbiased sampl

284 ntities of Biological Interest ontology, the NCBI Taxonomy, the Protein Ontology, the Sequence Ontolo

285 We compared our trees to the NCBI taxonomy, to trees based on concatenated alignments

286 tional Center for Biotechnology Information (NCBI) Taxonomy.

287 tional Center for Biotechnology Information (NCBI), the European Bioinformatics Institute (EBI) and t

288 tional Center for Biotechnology Information (NCBI), the European Bioinformatics Institute (EBI), and

289 tional Center for Biotechnology Information (NCBI), the European Bioinformatics Institute (EMBL-EBI)

290 Members of the collaboration, who are from NCBI, the Wellcome Trust Sanger Institute and the Univer

291 ombination with 225 mitogenomes available on NCBI to investigate decapod mitogenome diversity and phy

292 ons to aggregate variants. One, based on the NCBI Variant Overprecision Correction Algorithm, returns

293 The NCBI Viral Genomes Resource is a reference resource desi

294 Its genome sequence (NCBI) was determined 12 years ago.

295 all prokaryotes and eukaryotes available at NCBI, we observed that physico-chemical properties of di

296 NCBI web services convert representations among HGVS, VC

297 clustering elements within other domains of NCBI web site, for internal linking between domains of t

298 r biological data made available through the NCBI Web site.

299 r biological data made available through the NCBI Website.

300 urated by a small group of scientists at the NCBI who use the current taxonomic literature to maintai