Myers EW

References (7)

Title : Heterochromatic sequences in a Drosophila whole-genome shotgun assembly - Hoskins_2002_Genome.Biol_3_RESEARCH0085
Author(s) : Hoskins RA , Smith CD , Carlson JW , Carvalho AB , Halpern A , Kaminker JS , Kennedy C , Mungall CJ , Sullivan BA , Sutton GG , Yasuhara JC , Wakimoto BT , Myers EW , Celniker SE , Rubin GM , Karpen GH
Ref : Genome Biol , 3 :RESEARCH0085 , 2002
Abstract : BACKGROUND: Most eukaryotic genomes include a substantial repeat-rich fraction termed heterochromatin, which is concentrated in centric and telomeric regions. The repetitive nature of heterochromatic sequence makes it difficult to assemble and analyze. To better understand the heterochromatic component of the Drosophila melanogaster genome, we characterized and annotated portions of a whole-genome shotgun sequence assembly.
RESULTS: WGS3, an improved whole-genome shotgun assembly, includes 20.7 Mb of draft-quality sequence not represented in the Release 3 sequence spanning the euchromatin. We annotated this sequence using the methods employed in the re-annotation of the Release 3 euchromatic sequence. This analysis predicted 297 protein-coding genes and six non-protein-coding genes, including known heterochromatic genes, and regions of similarity to known transposable elements. Bacterial artificial chromosome (BAC)-based fluorescence in situ hybridization analysis was used to correlate the genomic sequence with the cytogenetic map in order to refine the genomic definition of the centric heterochromatin; on the basis of our cytological definition, the annotated Release 3 euchromatic sequence extends into the centric heterochromatin on each chromosome arm.
CONCLUSIONS: Whole-genome shotgun assembly produced a reliable draft-quality sequence of a significant part of the Drosophila heterochromatin. Annotation of this sequence defined the intron-exon structures of 30 known protein-coding genes and 267 protein-coding gene models. The cytogenetic mapping suggests that an additional 150 predicted genes are located in heterochromatin at the base of the Release 3 euchromatic sequence. Our analysis suggests strategies for improving the sequence and annotation of the heterochromatic portions of the Drosophila and other complex genomes.
ESTHER : Hoskins_2002_Genome.Biol_3_RESEARCH0085
PubMedSearch : Hoskins_2002_Genome.Biol_3_RESEARCH0085
PubMedID: 12537574
Gene_locus related to this paper: drome-CG9542 , drome-CG11309 , drome-CG17097 , drome-CG17374 , drome-KRAKEN

Title : The genome sequence of the malaria mosquito Anopheles gambiae - Holt_2002_Science_298_129
Author(s) : Holt RA , Subramanian GM , Halpern A , Sutton GG , Charlab R , Nusskern DR , Wincker P , Clark AG , Ribeiro JM , Wides R , Salzberg SL , Loftus B , Yandell M , Majoros WH , Rusch DB , Lai Z , Kraft CL , Abril JF , Anthouard V , Arensburger P , Atkinson PW , Baden H , de Berardinis V , Baldwin D , Benes V , Biedler J , Blass C , Bolanos R , Boscus D , Barnstead M , Cai S , Center A , Chaturverdi K , Christophides GK , Chrystal MA , Clamp M , Cravchik A , Curwen V , Dana A , Delcher A , Dew I , Evans CA , Flanigan M , Grundschober-Freimoser A , Friedli L , Gu Z , Guan P , Guigo R , Hillenmeyer ME , Hladun SL , Hogan JR , Hong YS , Hoover J , Jaillon O , Ke Z , Kodira C , Kokoza E , Koutsos A , Letunic I , Levitsky A , Liang Y , Lin JJ , Lobo NF , Lopez JR , Malek JA , McIntosh TC , Meister S , Miller J , Mobarry C , Mongin E , Murphy SD , O'Brochta DA , Pfannkoch C , Qi R , Regier MA , Remington K , Shao H , Sharakhova MV , Sitter CD , Shetty J , Smith TJ , Strong R , Sun J , Thomasova D , Ton LQ , Topalis P , Tu Z , Unger MF , Walenz B , Wang A , Wang J , Wang M , Wang X , Woodford KJ , Wortman JR , Wu M , Yao A , Zdobnov EM , Zhang H , Zhao Q , Zhao S , Zhu SC , Zhimulev I , Coluzzi M , della Torre A , Roth CW , Louis C , Kalush F , Mural RJ , Myers EW , Adams MD , Smith HO , Broder S , Gardner MJ , Fraser CM , Birney E , Bork P , Brey PT , Venter JC , Weissenbach J , Kafatos FC , Collins FH , Hoffman SL
Ref : Science , 298 :129 , 2002
Abstract : Anopheles gambiae is the principal vector of malaria, a disease that afflicts more than 500 million people and causes more than 1 million deaths each year. Tenfold shotgun sequence coverage was obtained from the PEST strain of A. gambiae and assembled into scaffolds that span 278 million base pairs. A total of 91% of the genome was organized in 303 scaffolds; the largest scaffold was 23.1 million base pairs. There was substantial genetic variation within this strain, and the apparent existence of two haplotypes of approximately equal frequency ("dual haplotypes") in a substantial fraction of the genome likely reflects the outbred nature of the PEST strain. The sequence produced a conservative inference of more than 400,000 single-nucleotide polymorphisms that showed a markedly bimodal density distribution. Analysis of the genome sequence revealed strong evidence for about 14,000 protein-encoding transcripts. Prominent expansions in specific families of proteins likely involved in cell adhesion and immunity were noted. An expressed sequence tag analysis of genes regulated by blood feeding provided insights into the physiological adaptations of a hematophagous insect.
ESTHER : Holt_2002_Science_298_129
PubMedSearch : Holt_2002_Science_298_129
PubMedID: 12364791
Gene_locus related to this paper: anoga-a0nb77 , anoga-a0nbp6 , anoga-a0neb7 , anoga-a0nei9 , anoga-a0nej0 , anoga-a0ngj1 , anoga-a7ut12 , anoga-a7uuz9 , anoga-ACHE1 , anoga-ACHE2 , anoga-agCG44620 , anoga-agCG44666 , anoga-agCG45273 , anoga-agCG45279 , anoga-agCG45511 , anoga-agCG46741 , anoga-agCG47651 , anoga-agCG47655 , anoga-agCG47661 , anoga-agCG47690 , anoga-agCG48797 , anoga-AGCG49362 , anoga-agCG49462 , anoga-agCG49870 , anoga-agCG49872 , anoga-agCG49876 , anoga-agCG50851 , anoga-agCG51879 , anoga-agCG52383 , anoga-agCG54954 , anoga-AGCG55021 , anoga-agCG55401 , anoga-agCG55408 , anoga-agCG56978 , anoga-ebiG239 , anoga-ebiG2660 , anoga-ebiG5718 , anoga-ebiG5974 , anoga-ebiG8504 , anoga-ebiG8742 , anoga-glita , anoga-nrtac , anoga-q5tpv0 , anoga-Q5TVS6 , anoga-q7pm39 , anoga-q7ppw9 , anoga-q7pq17 , anoga-Q7PQT0 , anoga-q7q8m4 , anoga-q7q626 , anoga-q7qa14 , anoga-q7qa52 , anoga-q7qal7 , anoga-q7qbj0 , anoga-f5hl20 , anoga-q7qkh2 , anoga-a0a1s4h1y7 , anoga-q7q887

Title : A comparison of whole-genome shotgun-derived mouse chromosome 16 and the human genome - Mural_2002_Science_296_1661
Author(s) : Mural RJ , Adams MD , Myers EW , Smith HO , Miklos GL , Wides R , Halpern A , Li PW , Sutton GG , Nadeau J , Salzberg SL , Holt RA , Kodira CD , Lu F , Chen L , Deng Z , Evangelista CC , Gan W , Heiman TJ , Li J , Li Z , Merkulov GV , Milshina NV , Naik AK , Qi R , Shue BC , Wang A , Wang J , Wang X , Yan X , Ye J , Yooseph S , Zhao Q , Zheng L , Zhu SC , Biddick K , Bolanos R , Delcher AL , Dew IM , Fasulo D , Flanigan MJ , Huson DH , Kravitz SA , Miller JR , Mobarry CM , Reinert K , Remington KA , Zhang Q , Zheng XH , Nusskern DR , Lai Z , Lei Y , Zhong W , Yao A , Guan P , Ji RR , Gu Z , Wang ZY , Zhong F , Xiao C , Chiang CC , Yandell M , Wortman JR , Amanatides PG , Hladun SL , Pratts EC , Johnson JE , Dodson KL , Woodford KJ , Evans CA , Gropman B , Rusch DB , Venter E , Wang M , Smith TJ , Houck JT , Tompkins DE , Haynes C , Jacob D , Chin SH , Allen DR , Dahlke CE , Sanders R , Li K , Liu X , Levitsky AA , Majoros WH , Chen Q , Xia AC , Lopez JR , Donnelly MT , Newman MH , Glodek A , Kraft CL , Nodell M , Ali F , An HJ , Baldwin-Pitts D , Beeson KY , Cai S , Carnes M , Carver A , Caulk PM , Center A , Chen YH , Cheng ML , Coyne MD , Crowder M , Danaher S , Davenport LB , Desilets R , Dietz SM , Doup L , Dullaghan P , Ferriera S , Fosler CR , Gire HC , Gluecksmann A , Gocayne JD , Gray J , Hart B , Haynes J , Hoover J , Howland T , Ibegwam C , Jalali M , Johns D , Kline L , Ma DS , MacCawley S , Magoon A , Mann F , May D , McIntosh TC , Mehta S , Moy L , Moy MC , Murphy BJ , Murphy SD , Nelson KA , Nuri Z , Parker KA , Prudhomme AC , Puri VN , Qureshi H , Raley JC , Reardon MS , Regier MA , Rogers YH , Romblad DL , Schutz J , Scott JL , Scott R , Sitter CD , Smallwood M , Sprague AC , Stewart E , Strong RV , Suh E , Sylvester K , Thomas R , Tint NN , Tsonis C , Wang G , Williams MS , Williams SM , Windsor SM , Wolfe K , Wu MM , Zaveri J , Chaturvedi K , Gabrielian AE , Ke Z , Sun J , Subramanian G , Venter JC , Pfannkoch CM , Barnstead M , Stephenson LD
Ref : Science , 296 :1661 , 2002
Abstract : The high degree of similarity between the mouse and human genomes is demonstrated through analysis of the sequence of mouse chromosome 16 (Mmu 16), which was obtained as part of a whole-genome shotgun assembly of the mouse genome. The mouse genome is about 10% smaller than the human genome, owing to a lower repetitive DNA content. Comparison of the structure and protein-coding potential of Mmu 16 with that of the homologous segments of the human genome identifies regions of conserved synteny with human chromosomes (Hsa) 3, 8, 12, 16, 21, and 22. Gene content and order are highly conserved between Mmu 16 and the syntenic blocks of the human genome. Of the 731 predicted genes on Mmu 16, 509 align with orthologs on the corresponding portions of the human genome, 44 are likely paralogous to these genes, and 164 genes have homologs elsewhere in the human genome; there are 14 genes for which we could find no human counterpart.
ESTHER : Mural_2002_Science_296_1661
PubMedSearch : Mural_2002_Science_296_1661
PubMedID: 12040188
Gene_locus related to this paper: mouse-ABH15 , mouse-Ces3b , mouse-Ces4a , mouse-dpp4 , mouse-FAP , mouse-Lipg , mouse-Q8C1A9 , mouse-rbbp9 , mouse-SERHL , mouse-SPG21 , mouse-w4vsp6

Title : Finishing a whole-genome shotgun: release 3 of the Drosophila melanogaster euchromatic genome sequence - Celniker_2002_Genome.Biol_3_RESEARCH0079
Author(s) : Celniker SE , Wheeler DA , Kronmiller B , Carlson JW , Halpern A , Patel S , Adams M , Champe M , Dugan SP , Frise E , Hodgson A , George RA , Hoskins RA , Laverty T , Muzny DM , Nelson CR , Pacleb JM , Park S , Pfeiffer BD , Richards S , Sodergren EJ , Svirskas R , Tabor PE , Wan K , Stapleton M , Sutton GG , Venter C , Weinstock G , Scherer SE , Myers EW , Gibbs RA , Rubin GM
Ref : Genome Biol , 3 :RESEARCH0079 , 2002
Abstract : BACKGROUND: The Drosophila melanogaster genome was the first metazoan genome to have been sequenced by the whole-genome shotgun (WGS) method. Two issues relating to this achievement were widely debated in the genomics community: how correct is the sequence with respect to base-pair (bp) accuracy and frequency of assembly errors? And, how difficult is it to bring a WGS sequence to the accepted standard for finished sequence? We are now in a position to answer these questions.
RESULTS: Our finishing process was designed to close gaps, improve sequence quality and validate the assembly. Sequence traces derived from the WGS and draft sequencing of individual bacterial artificial chromosomes (BACs) were assembled into BAC-sized segments. These segments were brought to high quality, and then joined to constitute the sequence of each chromosome arm. Overall assembly was verified by comparison to a physical map of fingerprinted BAC clones. In the current version of the 116.9 Mb euchromatic genome, called Release 3, the six euchromatic chromosome arms are represented by 13 scaffolds with a total of 37 sequence gaps. We compared Release 3 to Release 2; in autosomal regions of unique sequence, the error rate of Release 2 was one in 20,000 bp.
CONCLUSIONS: The WGS strategy can efficiently produce a high-quality sequence of a metazoan genome while generating the reagents required for sequence finishing. However, the initial method of repeat assembly was flawed. The sequence we report here, Release 3, is a reliable resource for molecular genetic experimentation and computational analysis.
ESTHER : Celniker_2002_Genome.Biol_3_RESEARCH0079
PubMedSearch : Celniker_2002_Genome.Biol_3_RESEARCH0079
PubMedID: 12537568
Gene_locus related to this paper: drome-CG8058 , drome-CG9542 , drome-CG11309 , drome-CG11406 , drome-CG17097 , drome-CG17374 , drome-glita , drome-KRAKEN

Title : The sequence of the human genome - Venter_2001_Science_291_1304
Author(s) : Venter JC , Adams MD , Myers EW , Li PW , Mural RJ , Sutton GG , Smith HO , Yandell M , Evans CA , Holt RA , Gocayne JD , Amanatides P , Ballew RM , Huson DH , Wortman JR , Zhang Q , Kodira CD , Zheng XH , Chen L , Skupski M , Subramanian G , Thomas PD , Zhang J , Gabor Miklos GL , Nelson C , Broder S , Clark AG , Nadeau J , McKusick VA , Zinder N , Levine AJ , Roberts RJ , Simon M , Slayman C , Hunkapiller M , Bolanos R , Delcher A , Dew I , Fasulo D , Flanigan M , Florea L , Halpern A , Hannenhalli S , Kravitz S , Levy S , Mobarry C , Reinert K , Remington K , Abu-Threideh J , Beasley E , Biddick K , Bonazzi V , Brandon R , Cargill M , Chandramouliswaran I , Charlab R , Chaturvedi K , Deng Z , Di Francesco V , Dunn P , Eilbeck K , Evangelista C , Gabrielian AE , Gan W , Ge W , Gong F , Gu Z , Guan P , Heiman TJ , Higgins ME , Ji RR , Ke Z , Ketchum KA , Lai Z , Lei Y , Li Z , Li J , Liang Y , Lin X , Lu F , Merkulov GV , Milshina N , Moore HM , Naik AK , Narayan VA , Neelam B , Nusskern D , Rusch DB , Salzberg S , Shao W , Shue B , Sun J , Wang Z , Wang A , Wang X , Wang J , Wei M , Wides R , Xiao C , Yan C , Yao A , Ye J , Zhan M , Zhang W , Zhang H , Zhao Q , Zheng L , Zhong F , Zhong W , Zhu S , Zhao S , Gilbert D , Baumhueter S , Spier G , Carter C , Cravchik A , Woodage T , Ali F , An H , Awe A , Baldwin D , Baden H , Barnstead M , Barrow I , Beeson K , Busam D , Carver A , Center A , Cheng ML , Curry L , Danaher S , Davenport L , Desilets R , Dietz S , Dodson K , Doup L , Ferriera S , Garg N , Gluecksmann A , Hart B , Haynes J , Haynes C , Heiner C , Hladun S , Hostin D , Houck J , Howland T , Ibegwam C , Johnson J , Kalush F , Kline L , Koduru S , Love A , Mann F , May D , McCawley S , McIntosh T , McMullen I , Moy M , Moy L , Murphy B , Nelson K , Pfannkoch C , Pratts E , Puri V , Qureshi H , Reardon M , Rodriguez R , Rogers YH , Romblad D , Ruhfel B , Scott R , Sitter C , Smallwood M , Stewart E , Strong R , Suh E , Thomas R , Tint NN , Tse S , Vech C , Wang G , Wetter J , Williams S , Williams M , Windsor S , Winn-Deen E , Wolfe K , Zaveri J , Zaveri K , Abril JF , Guigo R , Campbell MJ , Sjolander KV , Karlak B , Kejariwal A , Mi H , Lazareva B , Hatton T , Narechania A , Diemer K , Muruganujan A , Guo N , Sato S , Bafna V , Istrail S , Lippert R , Schwartz R , Walenz B , Yooseph S , Allen D , Basu A , Baxendale J , Blick L , Caminha M , Carnes-Stine J , Caulk P , Chiang YH , Coyne M , Dahlke C , Mays A , Dombroski M , Donnelly M , Ely D , Esparham S , Fosler C , Gire H , Glanowski S , Glasser K , Glodek A , Gorokhov M , Graham K , Gropman B , Harris M , Heil J , Henderson S , Hoover J , Jennings D , Jordan C , Jordan J , Kasha J , Kagan L , Kraft C , Levitsky A , Lewis M , Liu X , Lopez J , Ma D , Majoros W , McDaniel J , Murphy S , Newman M , Nguyen T , Nguyen N , Nodell M , Pan S , Peck J , Peterson M , Rowe W , Sanders R , Scott J , Simpson M , Smith T , Sprague A , Stockwell T , Turner R , Venter E , Wang M , Wen M , Wu D , Wu M , Xia A , Zandieh A , Zhu X
Ref : Science , 291 :1304 , 2001
Abstract : A 2.91-billion base pair (bp) consensus sequence of the euchromatic portion of the human genome was generated by the whole-genome shotgun sequencing method. The 14.8-billion bp DNA sequence was generated over 9 months from 27,271,853 high-quality sequence reads (5.11-fold coverage of the genome) from both ends of plasmid clones made from the DNA of five individuals. Two assembly strategies-a whole-genome assembly and a regional chromosome assembly-were used, each combining sequence data from Celera and the publicly funded genome effort. The public data were shredded into 550-bp segments to create a 2.9-fold coverage of those genome regions that had been sequenced, without including biases inherent in the cloning and assembly procedure used by the publicly funded group. This brought the effective coverage in the assemblies to eightfold, reducing the number and size of gaps in the final assembly over what would be obtained with 5.11-fold coverage. The two assembly strategies yielded very similar results that largely agree with independent mapping data. The assemblies effectively cover the euchromatic regions of the human chromosomes. More than 90% of the genome is in scaffold assemblies of 100,000 bp or more, and 25% of the genome is in scaffolds of 10 million bp or larger. Analysis of the genome sequence revealed 26,588 protein-encoding transcripts for which there was strong corroborating evidence and an additional approximately 12,000 computationally derived genes with mouse matches or other weak supporting evidence. Although gene-dense clusters are obvious, almost half the genes are dispersed in low G+C sequence separated by large tracts of apparently noncoding sequence. Only 1.1% of the genome is spanned by exons, whereas 24% is in introns, with 75% of the genome being intergenic DNA. Duplications of segmental blocks, ranging in size up to chromosomal lengths, are abundant throughout the genome and reveal a complex evolutionary history. Comparative genomic analysis indicates vertebrate expansions of genes associated with neuronal function, with tissue-specific developmental regulation, and with the hemostasis and immune systems. DNA sequence comparisons between the consensus sequence and publicly funded genome data provided locations of 2.1 million single-nucleotide polymorphisms (SNPs). A random pair of human haploid genomes differed at a rate of 1 bp per 1250 on average, but there was marked heterogeneity in the level of polymorphism across the genome. Less than 1% of all SNPs resulted in variation in proteins, but the task of determining which SNPs have functional consequences remains an open challenge.
ESTHER : Venter_2001_Science_291_1304
PubMedSearch : Venter_2001_Science_291_1304
PubMedID: 11181995
Gene_locus related to this paper: human-AADAC , human-ABHD1 , human-ABHD10 , human-ABHD11 , human-ACHE , human-BCHE , human-LDAH , human-ABHD18 , human-CMBL , human-ABHD17A , human-KANSL3 , human-LIPA , human-LYPLAL1 , human-NDRG2 , human-NLGN3 , human-NLGN4X , human-NLGN4Y , human-PAFAH2 , human-PREPL , human-RBBP9 , human-SPG21

Title : A whole-genome assembly of Drosophila - Myers_2000_Science_287_2196
Author(s) : Myers EW , Sutton GG , Delcher AL , Dew IM , Fasulo DP , Flanigan MJ , Kravitz SA , Mobarry CM , Reinert KH , Remington KA , Anson EL , Bolanos RA , Chou HH , Jordan CM , Halpern AL , Lonardi S , Beasley EM , Brandon RC , Chen L , Dunn PJ , Lai Z , Liang Y , Nusskern DR , Zhan M , Zhang Q , Zheng X , Rubin GM , Adams MD , Venter JC
Ref : Science , 287 :2196 , 2000
Abstract : We report on the quality of a whole-genome assembly of Drosophila melanogaster and the nature of the computer algorithms that accomplished it. Three independent external data sources essentially agree with and support the assembly's sequence and ordering of contigs across the euchromatic portion of the genome. In addition, there are isolated contigs that we believe represent nonrepetitive pockets within the heterochromatin of the centromeres. Comparison with a previously sequenced 2.9- megabase region indicates that sequencing accuracy within nonrepetitive segments is greater than 99. 99% without manual curation. As such, this initial reconstruction of the Drosophila sequence should be of substantial value to the scientific community.
ESTHER : Myers_2000_Science_287_2196
PubMedSearch : Myers_2000_Science_287_2196
PubMedID: 10731133

Title : The genome sequence of Drosophila melanogaster - Adams_2000_Science_287_2185
Author(s) : Adams MD , Celniker SE , Holt RA , Evans CA , Gocayne JD , Amanatides PG , Scherer SE , Li PW , Hoskins RA , Galle RF , George RA , Lewis SE , Richards S , Ashburner M , Henderson SN , Sutton GG , Wortman JR , Yandell MD , Zhang Q , Chen LX , Brandon RC , Rogers YH , Blazej RG , Champe M , Pfeiffer BD , Wan KH , Doyle C , Baxter EG , Helt G , Nelson CR , Gabor GL , Abril JF , Agbayani A , An HJ , Andrews-Pfannkoch C , Baldwin D , Ballew RM , Basu A , Baxendale J , Bayraktaroglu L , Beasley EM , Beeson KY , Benos PV , Berman BP , Bhandari D , Bolshakov S , Borkova D , Botchan MR , Bouck J , Brokstein P , Brottier P , Burtis KC , Busam DA , Butler H , Cadieu E , Center A , Chandra I , Cherry JM , Cawley S , Dahlke C , Davenport LB , Davies P , de Pablos B , Delcher A , Deng Z , Mays AD , Dew I , Dietz SM , Dodson K , Doup LE , Downes M , Dugan-Rocha S , Dunkov BC , Dunn P , Durbin KJ , Evangelista CC , Ferraz C , Ferriera S , Fleischmann W , Fosler C , Gabrielian AE , Garg NS , Gelbart WM , Glasser K , Glodek A , Gong F , Gorrell JH , Gu Z , Guan P , Harris M , Harris NL , Harvey D , Heiman TJ , Hernandez JR , Houck J , Hostin D , Houston KA , Howland TJ , Wei MH , Ibegwam C , Jalali M , Kalush F , Karpen GH , Ke Z , Kennison JA , Ketchum KA , Kimmel BE , Kodira CD , Kraft C , Kravitz S , Kulp D , Lai Z , Lasko P , Lei Y , Levitsky AA , Li J , Li Z , Liang Y , Lin X , Liu X , Mattei B , McIntosh TC , McLeod MP , McPherson D , Merkulov G , Milshina NV , Mobarry C , Morris J , Moshrefi A , Mount SM , Moy M , Murphy B , Murphy L , Muzny DM , Nelson DL , Nelson DR , Nelson KA , Nixon K , Nusskern DR , Pacleb JM , Palazzolo M , Pittman GS , Pan S , Pollard J , Puri V , Reese MG , Reinert K , Remington K , Saunders RD , Scheeler F , Shen H , Shue BC , Siden-Kiamos I , Simpson M , Skupski MP , Smith T , Spier E , Spradling AC , Stapleton M , Strong R , Sun E , Svirskas R , Tector C , Turner R , Venter E , Wang AH , Wang X , Wang ZY , Wassarman DA , Weinstock GM , Weissenbach J , Williams SM , WoodageT , Worley KC , Wu D , Yang S , Yao QA , Ye J , Yeh RF , Zaveri JS , Zhan M , Zhang G , Zhao Q , Zheng L , Zheng XH , Zhong FN , Zhong W , Zhou X , Zhu S , Zhu X , Smith HO , Gibbs RA , Myers EW , Rubin GM , Venter JC
Ref : Science , 287 :2185 , 2000
Abstract : The fly Drosophila melanogaster is one of the most intensively studied organisms in biology and serves as a model system for the investigation of many developmental and cellular processes common to higher eukaryotes, including humans. We have determined the nucleotide sequence of nearly all of the approximately 120-megabase euchromatic portion of the Drosophila genome using a whole-genome shotgun sequencing strategy supported by extensive clone-based sequence and a high-quality bacterial artificial chromosome physical map. Efforts are under way to close the remaining gaps; however, the sequence is of sufficient accuracy and contiguity to be declared substantially complete and to support an initial analysis of genome structure and preliminary gene annotation and interpretation. The genome encodes approximately 13,600 genes, somewhat fewer than the smaller Caenorhabditis elegans genome, but with comparable functional diversity.
ESTHER : Adams_2000_Science_287_2185
PubMedSearch : Adams_2000_Science_287_2185
PubMedID: 10731132
Gene_locus related to this paper: drome-1vite , drome-2vite , drome-3vite , drome-a1z6g9 , drome-abhd2 , drome-ACHE , drome-b6idz4 , drome-BEM46 , drome-CG5707 , drome-CG5704 , drome-CG1309 , drome-CG1882 , drome-CG1986 , drome-CG2059 , drome-CG2493 , drome-CG2528 , drome-CG2772 , drome-CG3160 , drome-CG3344 , drome-CG3523 , drome-CG3524 , drome-CG3734 , drome-CG3739 , drome-CG3744 , drome-CG3841 , drome-CG4267 , drome-CG4382 , drome-CG4390 , drome-CG4572 , drome-CG4582 , drome-CG4851 , drome-CG4979 , drome-CG5068 , drome-CG5162 , drome-CG5355 , drome-CG5377 , drome-CG5397 , drome-CG5412 , drome-CG5665 , drome-CG5932 , drome-CG5966 , drome-CG6018 , drome-CG6113 , drome-CG6271 , drome-CG6283 , drome-CG6295 , drome-CG6296 , drome-CG6414 , drome-CG6431 , drome-CG6472 , drome-CG6567 , drome-CG6675 , drome-CG6753 , drome-CG6847 , drome-CG7329 , drome-CG7367 , drome-CG7529 , drome-CG7632 , drome-CG8058 , drome-CG8093 , drome-CG8233 , drome-CG8424 , drome-CG8425 , drome-CG9059 , drome-CG9186 , drome-CG9287 , drome-CG9289 , drome-CG9542 , drome-CG9858 , drome-CG9953 , drome-CG9966 , drome-CG10116 , drome-CG10163 , drome-CG10175 , drome-CG10339 , drome-CG10357 , drome-CG10982 , drome-CG11034 , drome-CG11055 , drome-CG11309 , drome-CG11319 , drome-CG11406 , drome-CG11598 , drome-CG11600 , drome-CG11608 , drome-CG11626 , drome-CG11935 , drome-CG12108 , drome-CG12869 , drome-CG13282 , drome-CG13562 , drome-CG13772 , drome-CG14034 , drome-nlg3 , drome-CG14717 , drome-CG15101 , drome-CG15102 , drome-CG15106 , drome-CG15111 , drome-CG15820 , drome-CG15821 , drome-CG15879 , drome-CG17097 , drome-CG17099 , drome-CG17101 , drome-CG17191 , drome-CG17192 , drome-CG17292 , drome-CG18258 , drome-CG18284 , drome-CG18301 , drome-CG18302 , drome-CG18493 , drome-CG18530 , drome-CG18641 , drome-CG18815 , drome-CG31089 , drome-CG31091 , drome-CG32333 , drome-CG32483 , drome-CG33174 , drome-dnlg1 , drome-este4 , drome-este6 , drome-GH02384 , drome-GH02439 , drome-glita , drome-KRAKEN , drome-lip1 , drome-LIP2 , drome-lip3 , drome-MESK2 , drome-nrtac , drome-OME , drome-q7k274 , drome-Q9VJN0 , drome-Q8IP31 , drome-q9vux3