Walenz B

References (8)

Title : The bonobo genome compared with the chimpanzee and human genomes - Prufer_2012_Nature_486_527
Author(s) : Prufer K , Munch K , Hellmann I , Akagi K , Miller JR , Walenz B , Koren S , Sutton G , Kodira C , Winer R , Knight JR , Mullikin JC , Meader SJ , Ponting CP , Lunter G , Higashino S , Hobolth A , Dutheil J , Karakoc E , Alkan C , Sajjadian S , Catacchio CR , Ventura M , Marques-Bonet T , Eichler EE , Andre C , Atencia R , Mugisha L , Junhold J , Patterson N , Siebauer M , Good JM , Fischer A , Ptak SE , Lachmann M , Symer DE , Mailund T , Schierup MH , Andres AM , Kelso J , Paabo S
Ref : Nature , 486 :527 , 2012
Abstract : Two African apes are the closest living relatives of humans: the chimpanzee (Pan troglodytes) and the bonobo (Pan paniscus). Although they are similar in many respects, bonobos and chimpanzees differ strikingly in key social and sexual behaviours, and for some of these traits they show more similarity with humans than with each other. Here we report the sequencing and assembly of the bonobo genome to study its evolutionary relationship with the chimpanzee and human genomes. We find that more than three per cent of the human genome is more closely related to either the bonobo or the chimpanzee genome than these are to each other. These regions allow various aspects of the ancestry of the two ape species to be reconstructed. In addition, many of the regions that overlap genes may eventually help us understand the genetic basis of phenotypes that humans share with one of the two apes to the exclusion of the other.
ESTHER : Prufer_2012_Nature_486_527
PubMedSearch : Prufer_2012_Nature_486_527
PubMedID: 22722832
Gene_locus related to this paper: panpa-a0a2r8z5s1 , panpa-a0a2r8zh05 , panpa-a0a2r9a219 , panpa-a0a2r9cp60 , panpa-a0a2r8zm37 , panpa-a0a2r8ztc4 , panpa-a0a2r9b1a7 , panpa-a0a2r9bxk5 , panpa-a0a2r8zr38 , panpa-a0a2r8zvr0 , panpa-a0a2r9bln0 , panpa-a0a2r9acy6 , panpa-a0a2r8ztx2 , panpa-a0a2r9clu7 , panpa-a0a2r9c6z8 , panpa-a0a2r9cay0 , panpa-a0a2r9aqi9 , panpa-a0a2r9aqr5 , panpa-a0a2r9bpf0 , panpa-a0a2r9cj39

Title : Genetic diversity and population structure of the endangered marsupial Sarcophilus harrisii (Tasmanian devil) - Miller_2011_Proc.Natl.Acad.Sci.U.S.A_108_12348
Author(s) : Miller W , Hayes VM , Ratan A , Petersen DC , Wittekindt NE , Miller J , Walenz B , Knight J , Qi J , Zhao F , Wang Q , Bedoya-Reina OC , Katiyar N , Tomsho LP , Kasson LM , Hardie RA , Woodbridge P , Tindall EA , Bertelsen MF , Dixon D , Pyecroft S , Helgen KM , Lesk AM , Pringle TH , Patterson N , Zhang Y , Kreiss A , Woods GM , Jones ME , Schuster SC
Ref : Proc Natl Acad Sci U S A , 108 :12348 , 2011
Abstract : The Tasmanian devil (Sarcophilus harrisii) is threatened with extinction because of a contagious cancer known as Devil Facial Tumor Disease. The inability to mount an immune response and to reject these tumors might be caused by a lack of genetic diversity within a dwindling population. Here we report a whole-genome analysis of two animals originating from extreme northwest and southeast Tasmania, the maximal geographic spread, together with the genome from a tumor taken from one of them. A 3.3-Gb de novo assembly of the sequence data from two complementary next-generation sequencing platforms was used to identify 1 million polymorphic genomic positions, roughly one-quarter of the number observed between two genetically distant human genomes. Analysis of 14 complete mitochondrial genomes from current and museum specimens, as well as mitochondrial and nuclear SNP markers in 175 animals, suggests that the observed low genetic diversity in today's population preceded the Devil Facial Tumor Disease disease outbreak by at least 100 y. Using a genetically characterized breeding stock based on the genome sequence will enable preservation of the extant genetic diversity in future Tasmanian devil populations.
ESTHER : Miller_2011_Proc.Natl.Acad.Sci.U.S.A_108_12348
PubMedSearch : Miller_2011_Proc.Natl.Acad.Sci.U.S.A_108_12348
PubMedID: 21709235
Gene_locus related to this paper: sarha-g3vcc9 , sarha-g3vfe5 , sarha-g3vfr7 , sarha-g3vgt0 , sarha-g3vix0 , sarha-g3vqx7 , sarha-g3vrx3 , sarha-g3vsl6 , sarha-g3vvi8 , sarha-g3vyq6 , sarha-g3vz51 , sarha-g3vze3 , sarha-g3vzx8 , sarha-g3w1a9 , sarha-g3w685 , sarha-g3wfj3 , sarha-g3wg02 , sarha-g3wuz4 , sarha-g3x0l1 , sarha-g3whf8 , sarha-g3w6u4 , sarha-g3wrd7 , sarha-g3vun8 , sarha-g3vyu7 , sarha-g3wmk1 , sarha-g3w4n0 , sarha-g3x182 , sarha-g3wyt9 , sarha-g3vdz2 , sarha-g3vft8 , sarha-g3vtk1 , sarha-g3w6i3 , sarha-g3wy72 , sarha-g3vv12 , sarha-g3vv13 , sarha-g3vl97 , sarha-g3wzy4 , sarha-g3vcj1 , sarha-g3w1u8 , sarha-g3vik5 , sarha-g3wtu4 , sarha-g3wl42 , sarha-g3w041 , sarha-g3vyg5 , sarha-g3w5l6 , sarha-g3whf6

Title : The dynamic genome of Hydra - Chapman_2010_Nature_464_592
Author(s) : Chapman JA , Kirkness EF , Simakov O , Hampson SE , Mitros T , Weinmaier T , Rattei T , Balasubramanian PG , Borman J , Busam D , Disbennett K , Pfannkoch C , Sumin N , Sutton GG , Viswanathan LD , Walenz B , Goodstein DM , Hellsten U , Kawashima T , Prochnik SE , Putnam NH , Shu S , Blumberg B , Dana CE , Gee L , Kibler DF , Law L , Lindgens D , Martinez DE , Peng J , Wigge PA , Bertulat B , Guder C , Nakamura Y , Ozbek S , Watanabe H , Khalturin K , Hemmrich G , Franke A , Augustin R , Fraune S , Hayakawa E , Hayakawa S , Hirose M , Hwang JS , Ikeo K , Nishimiya-Fujisawa C , Ogura A , Takahashi T , Steinmetz PR , Zhang X , Aufschnaiter R , Eder MK , Gorny AK , Salvenmoser W , Heimberg AM , Wheeler BM , Peterson KJ , Bottger A , Tischler P , Wolf A , Gojobori T , Remington KA , Strausberg RL , Venter JC , Technau U , Hobmayer B , Bosch TC , Holstein TW , Fujisawa T , Bode HR , David CN , Rokhsar DS , Steele RE
Ref : Nature , 464 :592 , 2010
Abstract : The freshwater cnidarian Hydra was first described in 1702 and has been the object of study for 300 years. Experimental studies of Hydra between 1736 and 1744 culminated in the discovery of asexual reproduction of an animal by budding, the first description of regeneration in an animal, and successful transplantation of tissue between animals. Today, Hydra is an important model for studies of axial patterning, stem cell biology and regeneration. Here we report the genome of Hydra magnipapillata and compare it to the genomes of the anthozoan Nematostella vectensis and other animals. The Hydra genome has been shaped by bursts of transposable element expansion, horizontal gene transfer, trans-splicing, and simplification of gene structure and gene content that parallel simplification of the Hydra life cycle. We also report the sequence of the genome of a novel bacterium stably associated with H. magnipapillata. Comparisons of the Hydra genome to the genomes of other animals shed light on the evolution of epithelia, contractile tissues, developmentally regulated transcription factors, the Spemann-Mangold organizer, pluripotency genes and the neuromuscular junction.
ESTHER : Chapman_2010_Nature_464_592
PubMedSearch : Chapman_2010_Nature_464_592
PubMedID: 20228792
Gene_locus related to this paper: 9burk-c9y6c0 , 9burk-c9y8q9 , 9burk-c9y9d4 , 9burk-c9ya28 , 9burk-c9yb37 , 9burk-c9ycr9 , 9burk-c9ydq0 , 9burk-c9ydr2 , 9burk-c9yew1 , 9burk-c9yf78 , 9burk-c9ygh2 , 9burk-c9y7j2

Title : Genome sequences of the human body louse and its primary endosymbiont provide insights into the permanent parasitic lifestyle - Kirkness_2010_Proc.Natl.Acad.Sci.U.S.A_107_12168
Author(s) : Kirkness EF , Haas BJ , Sun W , Braig HR , Perotti MA , Clark JM , Lee SH , Robertson HM , Kennedy RC , Elhaik E , Gerlach D , Kriventseva EV , Elsik CG , Graur D , Hill CA , Veenstra JA , Walenz B , Tubio JM , Ribeiro JM , Rozas J , Johnston JS , Reese JT , Popadic A , Tojo M , Raoult D , Reed DL , Tomoyasu Y , Kraus E , Mittapalli O , Margam VM , Li HM , Meyer JM , Johnson RM , Romero-Severson J , Vanzee JP , Alvarez-Ponce D , Vieira FG , Aguade M , Guirao-Rico S , Anzola JM , Yoon KS , Strycharz JP , Unger MF , Christley S , Lobo NF , Seufferheld MJ , Wang N , Dasch GA , Struchiner CJ , Madey G , Hannick LI , Bidwell S , Joardar V , Caler E , Shao R , Barker SC , Cameron S , Bruggner RV , Regier A , Johnson J , Viswanathan L , Utterback TR , Sutton GG , Lawson D , Waterhouse RM , Venter JC , Strausberg RL , Berenbaum MR , Collins FH , Zdobnov EM , Pittendrigh BR
Ref : Proc Natl Acad Sci U S A , 107 :12168 , 2010
Abstract : As an obligatory parasite of humans, the body louse (Pediculus humanus humanus) is an important vector for human diseases, including epidemic typhus, relapsing fever, and trench fever. Here, we present genome sequences of the body louse and its primary bacterial endosymbiont Candidatus Riesia pediculicola. The body louse has the smallest known insect genome, spanning 108 Mb. Despite its status as an obligate parasite, it retains a remarkably complete basal insect repertoire of 10,773 protein-coding genes and 57 microRNAs. Representing hemimetabolous insects, the genome of the body louse thus provides a reference for studies of holometabolous insects. Compared with other insect genomes, the body louse genome contains significantly fewer genes associated with environmental sensing and response, including odorant and gustatory receptors and detoxifying enzymes. The unique architecture of the 18 minicircular mitochondrial chromosomes of the body louse may be linked to the loss of the gene encoding the mitochondrial single-stranded DNA binding protein. The genome of the obligatory louse endosymbiont Candidatus Riesia pediculicola encodes less than 600 genes on a short, linear chromosome and a circular plasmid. The plasmid harbors a unique arrangement of genes required for the synthesis of pantothenate, an essential vitamin deficient in the louse diet. The human body louse, its primary endosymbiont, and the bacterial pathogens that it vectors all possess genomes reduced in size compared with their free-living close relatives. Thus, the body louse genome project offers unique information and tools to use in advancing understanding of coevolution among vectors, symbionts, and pathogens.
ESTHER : Kirkness_2010_Proc.Natl.Acad.Sci.U.S.A_107_12168
PubMedSearch : Kirkness_2010_Proc.Natl.Acad.Sci.U.S.A_107_12168
PubMedID: 20566863
Gene_locus related to this paper: pedhb-ACHE1 , pedhb-ACHE2 , pedhc-e0v9b5 , pedhc-e0v9b6 , pedhc-e0v9b7 , pedhc-e0vbv5 , pedhc-e0vcd0 , pedhc-e0vcl7 , pedhc-e0vd69 , pedhc-e0ve50 , pedhc-e0vel6 , pedhc-e0vel7 , pedhc-e0vf98 , pedhc-e0vfs8 , pedhc-e0vfv0 , pedhc-e0vg01 , pedhc-e0vha2 , pedhc-e0vha4 , pedhc-e0vi52 , pedhc-e0vp42 , pedhc-e0vqu6 , pedhc-e0vuj9 , pedhc-e0vup6 , pedhc-e0vv55 , pedhc-e0vwv3 , pedhc-e0vxf7 , pedhc-e0vxg1 , pedhc-e0w4a6 , pedhc-e0w4c8 , pedhc-e0w271 , pedhc-e0w444 , pedhc-e0vym0 , pedhc-e0vdk9 , pedhc-e0vk10 , pedhc-e0vgw4 , pedhc-e0vgw7 , pedhc-e0vga1 , pedhc-e0w3s1 , pedhc-e0vzt2

Title : Evolution of genes and genomes on the Drosophila phylogeny - Clark_2007_Nature_450_203
Author(s) : Clark AG , Eisen MB , Smith DR , Bergman CM , Oliver B , Markow TA , Kaufman TC , Kellis M , Gelbart W , Iyer VN , Pollard DA , Sackton TB , Larracuente AM , Singh ND , Abad JP , Abt DN , Adryan B , Aguade M , Akashi H , Anderson WW , Aquadro CF , Ardell DH , Arguello R , Artieri CG , Barbash DA , Barker D , Barsanti P , Batterham P , Batzoglou S , Begun D , Bhutkar A , Blanco E , Bosak SA , Bradley RK , Brand AD , Brent MR , Brooks AN , Brown RH , Butlin RK , Caggese C , Calvi BR , Bernardo de Carvalho A , Caspi A , Castrezana S , Celniker SE , Chang JL , Chapple C , Chatterji S , Chinwalla A , Civetta A , Clifton SW , Comeron JM , Costello JC , Coyne JA , Daub J , David RG , Delcher AL , Delehaunty K , Do CB , Ebling H , Edwards K , Eickbush T , Evans JD , Filipski A , Findeiss S , Freyhult E , Fulton L , Fulton R , Garcia AC , Gardiner A , Garfield DA , Garvin BE , Gibson G , Gilbert D , Gnerre S , Godfrey J , Good R , Gotea V , Gravely B , Greenberg AJ , Griffiths-Jones S , Gross S , Guigo R , Gustafson EA , Haerty W , Hahn MW , Halligan DL , Halpern AL , Halter GM , Han MV , Heger A , Hillier L , Hinrichs AS , Holmes I , Hoskins RA , Hubisz MJ , Hultmark D , Huntley MA , Jaffe DB , Jagadeeshan S , Jeck WR , Johnson J , Jones CD , Jordan WC , Karpen GH , Kataoka E , Keightley PD , Kheradpour P , Kirkness EF , Koerich LB , Kristiansen K , Kudrna D , Kulathinal RJ , Kumar S , Kwok R , Lander E , Langley CH , Lapoint R , Lazzaro BP , Lee SJ , Levesque L , Li R , Lin CF , Lin MF , Lindblad-Toh K , Llopart A , Long M , Low L , Lozovsky E , Lu J , Luo M , Machado CA , Makalowski W , Marzo M , Matsuda M , Matzkin L , McAllister B , McBride CS , McKernan B , McKernan K , Mendez-Lago M , Minx P , Mollenhauer MU , Montooth K , Mount SM , Mu X , Myers E , Negre B , Newfeld S , Nielsen R , Noor MA , O'Grady P , Pachter L , Papaceit M , Parisi MJ , Parisi M , Parts L , Pedersen JS , Pesole G , Phillippy AM , Ponting CP , Pop M , Porcelli D , Powell JR , Prohaska S , Pruitt K , Puig M , Quesneville H , Ram KR , Rand D , Rasmussen MD , Reed LK , Reenan R , Reily A , Remington KA , Rieger TT , Ritchie MG , Robin C , Rogers YH , Rohde C , Rozas J , Rubenfield MJ , Ruiz A , Russo S , Salzberg SL , Sanchez-Gracia A , Saranga DJ , Sato H , Schaeffer SW , Schatz MC , Schlenke T , Schwartz R , Segarra C , Singh RS , Sirot L , Sirota M , Sisneros NB , Smith CD , Smith TF , Spieth J , Stage DE , Stark A , Stephan W , Strausberg RL , Strempel S , Sturgill D , Sutton G , Sutton GG , Tao W , Teichmann S , Tobari YN , Tomimura Y , Tsolas JM , Valente VL , Venter E , Venter JC , Vicario S , Vieira FG , Vilella AJ , Villasante A , Walenz B , Wang J , Wasserman M , Watts T , Wilson D , Wilson RK , Wing RA , Wolfner MF , Wong A , Wong GK , Wu CI , Wu G , Yamamoto D , Yang HP , Yang SP , Yorke JA , Yoshida K , Zdobnov E , Zhang P , Zhang Y , Zimin AV , Baldwin J , Abdouelleil A , Abdulkadir J , Abebe A , Abera B , Abreu J , Acer SC , Aftuck L , Alexander A , An P , Anderson E , Anderson S , Arachi H , Azer M , Bachantsang P , Barry A , Bayul T , Berlin A , Bessette D , Bloom T , Blye J , Boguslavskiy L , Bonnet C , Boukhgalter B , Bourzgui I , Brown A , Cahill P , Channer S , Cheshatsang Y , Chuda L , Citroen M , Collymore A , Cooke P , Costello M , D'Aco K , Daza R , De Haan G , DeGray S , DeMaso C , Dhargay N , Dooley K , Dooley E , Doricent M , Dorje P , Dorjee K , Dupes A , Elong R , Falk J , Farina A , Faro S , Ferguson D , Fisher S , Foley CD , Franke A , Friedrich D , Gadbois L , Gearin G , Gearin CR , Giannoukos G , Goode T , Graham J , Grandbois E , Grewal S , Gyaltsen K , Hafez N , Hagos B , Hall J , Henson C , Hollinger A , Honan T , Huard MD , Hughes L , Hurhula B , Husby ME , Kamat A , Kanga B , Kashin S , Khazanovich D , Kisner P , Lance K , Lara M , Lee W , Lennon N , Letendre F , LeVine R , Lipovsky A , Liu X , Liu J , Liu S , Lokyitsang T , Lokyitsang Y , Lubonja R , Lui A , Macdonald P , Magnisalis V , Maru K , Matthews C , McCusker W , McDonough S , Mehta T , Meldrim J , Meneus L , Mihai O , Mihalev A , Mihova T , Mittelman R , Mlenga V , Montmayeur A , Mulrain L , Navidi A , Naylor J , Negash T , Nguyen T , Nguyen N , Nicol R , Norbu C , Norbu N , Novod N , O'Neill B , Osman S , Markiewicz E , Oyono OL , Patti C , Phunkhang P , Pierre F , Priest M , Raghuraman S , Rege F , Reyes R , Rise C , Rogov P , Ross K , Ryan E , Settipalli S , Shea T , Sherpa N , Shi L , Shih D , Sparrow T , Spaulding J , Stalker J , Stange-Thomann N , Stavropoulos S , Stone C , Strader C , Tesfaye S , Thomson T , Thoulutsang Y , Thoulutsang D , Topham K , Topping I , Tsamla T , Vassiliev H , Vo A , Wangchuk T , Wangdi T , Weiand M , Wilkinson J , Wilson A , Yadav S , Young G , Yu Q , Zembek L , Zhong D , Zimmer A , Zwirko Z , Alvarez P , Brockman W , Butler J , Chin C , Grabherr M , Kleber M , Mauceli E , MacCallum I
Ref : Nature , 450 :203 , 2007
Abstract : Comparative analysis of multiple genomes in a phylogenetic framework dramatically improves the precision and sensitivity of evolutionary inference, producing more robust results than single-genome analyses can provide. The genomes of 12 Drosophila species, ten of which are presented here for the first time (sechellia, simulans, yakuba, erecta, ananassae, persimilis, willistoni, mojavensis, virilis and grimshawi), illustrate how rates and patterns of sequence divergence across taxa can illuminate evolutionary processes on a genomic scale. These genome sequences augment the formidable genetic tools that have made Drosophila melanogaster a pre-eminent model for animal genetics, and will further catalyse fundamental research on mechanisms of development, cell biology, genetics, disease, neurobiology, behaviour, physiology and evolution. Despite remarkable similarities among these Drosophila species, we identified many putatively non-neutral changes in protein-coding genes, non-coding RNA genes, and cis-regulatory regions. These may prove to underlie differences in the ecology and behaviour of these diverse species.
ESTHER : Clark_2007_Nature_450_203
PubMedSearch : Clark_2007_Nature_450_203
PubMedID: 17994087
Gene_locus related to this paper: droan-ACHE , droan-b3lx10 , droan-b3lx75 , droan-b3lxv7 , droan-b3ly87 , droan-b3lyh4 , droan-b3lyh5 , droan-b3lyh7 , droan-b3lyh9 , droan-b3lyi0 , droan-b3lyi2 , droan-b3lyi3 , droan-b3lyi4 , droan-b3lyj8 , droan-b3lyj9 , droan-b3lyx4 , droan-b3lyx5 , droan-b3lyx6 , droan-b3lyx7 , droan-b3lyx9 , droan-b3lz72 , droan-b3m1x3 , droan-b3m2d4 , droan-b3m3d9 , droan-b3m4e3 , droan-b3m5w1 , droan-b3m6i7 , droan-b3m7v2 , droan-b3m9a5 , droan-b3m9f4 , droan-b3m9p3 , droan-b3m254 , droan-b3m259 , droan-b3m260 , droan-b3m262 , droan-b3m524 , droan-b3m635 , droan-b3m845 , droan-b3m846 , droan-b3md01 , droan-b3mdh7 , droan-b3mdm6 , droan-b3mdw8 , droan-b3mee1 , droan-b3mf47 , droan-b3mf48 , droan-b3mg94 , droan-b3mgk2 , droan-b3mgn6 , droan-b3mii3 , droan-b3mjk2 , droan-b3mjk3 , droan-b3mjk4 , droan-b3mjk5 , droan-b3mjl2 , droan-b3mjl4 , droan-b3mjl7 , droan-b3mjl9 , droan-b3mjm8 , droan-b3mjm9 , droan-b3mjs6 , droan-b3mkr0 , droan-b3ml20 , droan-b3mly4 , droan-b3mly5 , droan-b3mly6 , droan-b3mmm8 , droan-b3mnb5 , droan-b3mny9 , droan-b3mtj5 , droan-b3muw4 , droan-b3muw8 , droan-b3n0e7 , droan-b3n2j7 , droan-b3n247 , droan-c5idb2 , droer-ACHE , droer-b3n5c7 , droer-b3n5d0 , droer-b3n5d8 , droer-b3n5d9 , droer-b3n5t7 , droer-b3n5y4 , droer-b3n7d2 , droer-b3n7d3 , droer-b3n7d4 , droer-b3n7k8 , droer-b3n8e4 , droer-b3n8f7 , droer-b3n8f8 , droer-b3n9e1 , droer-b3n319 , droer-b3n547 , droer-b3n549 , droer-b3n558 , droer-b3n560 , droer-b3n577 , droer-b3n612 , droer-b3nar5 , droer-b3nb91 , droer-b3nct9 , droer-b3nd53 , droer-b3ndh9 , droer-b3ndq8 , droer-b3ne66 , droer-b3ne67 , droer-b3ne97 , droer-b3nfk3 , droer-b3nfq9 , droer-b3nim7 , droer-b3nkn2 , droer-b3nm11 , droer-b3nmh4 , droer-b3nmy2 , droer-b3npx2 , droer-b3npx3 , droer-b3nq76 , droer-b3nqg9 , droer-b3nqm8 , droer-b3nr28 , droer-b3nrd3 , droer-b3nst4 , droer-b3nwa7 , droer-b3nyp5.1 , droer-b3nyp5.2 , droer-b3nyp6 , droer-b3nyp7 , droer-b3nyp8 , droer-b3nyp9 , droer-b3nyq3 , droer-b3nz06 , droer-b3nz14 , droer-b3nzj0 , droer-b3p0c0 , droer-b3p0c1 , droer-b3p0c2 , droer-b3p2x6 , droer-b3p2x7 , droer-b3p2x9 , droer-b3p2y1 , droer-b3p2y2 , droer-b3p6d4 , droer-b3p6d5 , droer-b3p6w3 , droer-b3p7b4 , droer-b3p7h9 , droer-b3p152 , droer-b3p486 , droer-b3p487 , droer-b3p488 , droer-b3p489 , droer-EST6 , droer-q670j5 , drogr-ACHE , drogr-b4iwp3 , drogr-b4iww3 , drogr-b4iwy3 , drogr-b4ixf7 , drogr-b4ixh4 , drogr-b4iyz5 , drogr-b4j2s2 , drogr-b4j2u8 , drogr-b4j3u1 , drogr-b4j3v3 , drogr-b4j4g7 , drogr-b4j4x9 , drogr-b4j6e6 , drogr-b4j9c9 , drogr-b4j9y4 , drogr-b4j156 , drogr-b4j384 , drogr-b4j605 , drogr-b4j685 , drogr-b4ja76 , drogr-b4jay5 , drogr-b4jcf0 , drogr-b4jcf1 , drogr-b4jdg6 , drogr-b4jdg7 , drogr-b4jdh6 , drogr-b4jdz1 , drogr-b4jdz2 , drogr-b4jdz4 , drogr-b4je66 , drogr-b4je79 , drogr-b4je82 , drogr-b4je88 , drogr-b4je89 , drogr-b4je90 , drogr-b4je91 , drogr-b4jf76 , drogr-b4jf79 , drogr-b4jf80 , drogr-b4jf81 , drogr-b4jf82 , drogr-b4jf83 , drogr-b4jf84 , drogr-b4jf85 , drogr-b4jf87 , drogr-b4jf91 , drogr-b4jf92 , drogr-b4jg66 , drogr-b4jgh0 , drogr-b4jgh1 , drogr-b4jgr9 , drogr-b4ji67 , drogr-b4jls2 , drogr-b4jnh9 , drogr-b4jpc6 , drogr-b4jpq3 , drogr-b4jpx9 , drogr-b4jql2 , drogr-b4jrh5 , drogr-b4jsb2 , drogr-b4jth3 , drogr-b4jti1 , drogr-b4jul5 , drogr-b4jur4 , drogr-b4jvh3 , drogr-b4jz00 , drogr-b4jz03 , drogr-b4jz04 , drogr-b4jz05 , drogr-b4jzh2 , drogr-b4k0u2 , drogr-b4k2r1 , drogr-b4k234 , drogr-b4k235 , drome-BEM46 , drome-CG3734 , drome-CG9953 , drome-CG11626 , drome-GH02439 , dromo-ACHE , dromo-b4k6a7 , dromo-b4k6a8 , dromo-b4k6q8 , dromo-b4k6q9 , dromo-b4k6r1 , dromo-b4k6r3 , dromo-b4k6r4 , dromo-b4k6r5 , dromo-b4k6r6 , dromo-b4k6r7 , dromo-b4k6r8 , dromo-b4k6r9 , dromo-b4k6s0 , dromo-b4k6s1 , dromo-b4k6s2 , dromo-b4k9c7 , dromo-b4k9d3 , dromo-b4k571 , dromo-b4k721 , dromo-b4ka74 , dromo-b4ka89 , dromo-b4kaj4 , dromo-b4kc20 , dromo-b4kcl2 , dromo-b4kcl3 , dromo-b4kd55.1 , dromo-b4kd55.2 , dromo-b4kd56 , dromo-b4kd57 , dromo-b4kde1 , dromo-b4kdg2 , dromo-b4kdh4 , dromo-b4kdh5 , dromo-b4kdh6 , dromo-A0A0Q9XDF2 , dromo-b4kdh8.1 , dromo-b4kdh8.2 , dromo-b4kg04 , dromo-b4kg05 , dromo-b4kg06 , dromo-b4kg16 , dromo-b4kg44 , dromo-b4kg90 , dromo-b4kh20 , dromo-b4kh21 , dromo-b4kht7 , dromo-b4kid3 , dromo-b4kik0 , dromo-b4kjx0 , dromo-b4kki1 , dromo-b4kkp6 , dromo-b4kkp8 , dromo-b4kkq8 , dromo-b4kkr0 , dromo-b4kkr3 , dromo-b4kkr4 , dromo-b4kks0 , dromo-b4kks1 , dromo-b4kks2 , dromo-b4kla1 , dromo-b4klv8 , dromo-b4knt4 , dromo-b4kp08 , dromo-b4kp16 , dromo-b4kqa6 , dromo-b4kqa7 , dromo-b4kqa8 , dromo-b4kqh1 , dromo-b4kst4 , dromo-b4ksy6 , dromo-b4kt84 , dromo-b4ktf5 , dromo-b4ktf6 , dromo-b4kvl3 , dromo-b4kvw2 , dromo-b4kwv4 , dromo-b4kwv5 , dromo-b4kxz6 , dromo-b4ky12 , dromo-b4ky36 , dromo-b4ky44 , dromo-b4kzu7 , dromo-b4l0n8 , dromo-b4l4u5 , dromo-b4l6l9 , dromo-b4l084 , drope-ACHE , drope-b4g3s6 , drope-b4g4p7 , drope-b4g6v4 , drope-b4g8m0 , drope-b4g8n6 , drope-b4g8n7 , drope-b4g9p2 , drope-b4g815 , drope-b4g816 , drope-b4gat7 , drope-b4gav5 , drope-b4gb05 , drope-b4gc08 , drope-b4gcr3 , drope-b4gdk2 , drope-b4gdl9 , drope-b4gdv9 , drope-b4gei8 , drope-b4gei9 , drope-b4gej0 , drope-b4ghz9 , drope-b4gj62 , drope-b4gj64 , drope-b4gj74 , drope-b4gkf4 , drope-b4gkv2 , drope-b4gky9 , drope-b4gl76 , drope-b4glf3 , drope-b4gmt3 , drope-b4gmt7 , drope-b4gmt9 , drope-b4gmu2 , drope-b4gmu3 , drope-b4gmu4 , drope-b4gmu5 , drope-b4gmu6 , drope-b4gmu7 , drope-b4gmv1 , drope-b4gn08 , drope-b4gpa7 , drope-b4gq13 , drope-b4grh7 , drope-b4gsf9 , drope-b4gsw4 , drope-b4gsw5 , drope-b4gsx2 , drope-b4gsx7 , drope-b4gsy6 , drope-b4gsy7 , drope-b4guj8 , drope-b4gw36 , drope-b4gzc2 , drope-b4gzc6 , drope-b4gzc7 , drope-b4h4p9 , drope-b4h5l3 , drope-b4h6a0 , drope-b4h6a8 , drope-b4h6a9 , drope-b4h6b0 , drope-b4h7m7 , drope-b4h462 , drope-b4h601 , drope-b4h602 , drope-b4hay1 , drope-b4hb18 , drope-est5a , drope-est5b , drope-est5c , drops-ACHE , drops-b5dhd2 , drops-b5dk96 , drops-b5dpe3 , drops-b5drp9 , drops-b5dwa7 , drops-b5dwa8 , drops-b5dz85 , drops-b5dz86 , drops-est5a , drops-est5b , drops-q29bq2 , drops-q29dd7 , drops-q29ew0 , drops-q291d5 , drops-q291e8 , drops-q293n1 , drops-q293n4 , drops-q293n5 , drops-q293n6 , drops-q294n6 , drops-q294n7 , drops-q294n9 , drops-q294p4 , drose-b4he97 , drose-b4hfu2 , drose-b4hg54 , drose-b4hga0 , drose-b4hgu9 , drose-b4hgv0 , drose-b4hgv3 , drose-b4hgv4 , drose-b4hhm8 , drose-b4hhs6 , drose-b4hie4 , drose-b4him9 , drose-b4hk63 , drose-b4hkj5 , drose-b4hr07 , drose-b4hr81 , drose-b4hre7 , drose-b4hs13 , drose-b4hsj9 , drose-b4hsk0 , drose-b4hsm8 , drose-b4hvr5 , drose-b4hwr7 , drose-b4hwr8 , drose-b4hwr9 , drose-b4hws6 , drose-b4hws7 , drose-b4hwt0 , drose-b4hwt2 , drose-b4hwu1 , drose-b4hwu2 , drose-b4hxs9 , drose-b4hxu4 , drose-b4hxz1 , drose-b4hyp8 , drose-b4hyp9 , drose-b4hyq0 , drose-b4hyz4 , drose-b4hyz5 , drose-b4i1k8 , drose-b4i2f3 , drose-b4i2w5 , drose-b4i4u3 , drose-b4i4u7 , drose-b4i4u9 , drose-b4i4v0 , drose-b4i4v1 , drose-b4i4v4 , drose-b4i4v5 , drose-b4i4v6 , drose-b4i4v7 , drose-b4i4v8 , drose-b4i4w0 , drose-b4i7s6 , drose-b4i133 , drose-b4i857 , drose-b4iam7 , drose-b4iam9 , drose-b4iaq6 , drose-b4icf6 , drose-b4icf7 , drose-b4id80 , drose-b4ifc5 , drose-b4ihv9 , drose-b4iie9 , drose-b4ilj8 , drose-b4in13 , drose-b4inj9 , drosi-ACHE , drosi-aes04a , drosi-b4nsh8 , drosi-b4q3d7 , drosi-b4q4w5 , drosi-b4q4y7 , drosi-b4q6h6 , drosi-b4q7u2 , drosi-b4q7u3 , drosi-b4q9c6 , drosi-b4q9c7 , drosi-b4q9d3 , drosi-b4q9d4 , drosi-b4q9r0 , drosi-b4q9r1 , drosi-b4q9r3 , drosi-b4q9s2 , drosi-b4q9s3 , drosi-b4q429 , drosi-b4q530 , drosi-b4q734 , drosi-b4q782 , drosi-b4q783 , drosi-b4q942 , drosi-b4qet1 , drosi-b4qfv6 , drosi-b4qge5 , drosi-b4qgh5 , drosi-b4qgs5 , drosi-b4qhf3 , drosi-b4qhf4 , drosi-b4qhi5 , drosi-b4qjr2 , drosi-b4qjr3 , drosi-b4qjv6 , drosi-b4qk23 , drosi-b4qk51 , drosi-b4qlt1 , drosi-b4qlz9 , drosi-b4qmn9 , drosi-b4qrq7 , drosi-b4qs01 , drosi-b4qs57 , drosi-b4qs82 , drosi-b4qs83 , drosi-b4qs84 , drosi-b4qs85 , drosi-b4qs86 , drosi-b4qsq1 , drosi-b4quk6 , drosi-b4qvg5 , drosi-b4qvg6 , drosi-b4qzn2 , drosi-b4qzn3 , drosi-b4qzn5 , drosi-b4qzn7 , drosi-b4qzn8 , drosi-b4qzp2 , drosi-b4qzp3 , drosi-b4qzp4 , drosi-b4qzp5 , drosi-b4qzp6 , drosi-b4qzp7 , drosi-b4r1a4 , drosi-b4r025 , drosi-b4r207 , drosi-b4r662 , drosi-este6 , drosi-q670k8 , drovi-ACHE , drovi-b4lev2 , drovi-b4lf33 , drovi-b4lf51 , drovi-b4lg54 , drovi-b4lg72 , drovi-b4lgc6 , drovi-b4lgd5 , drovi-b4lgg0 , drovi-b4lgk5 , drovi-b4lgn2 , drovi-b4lh17 , drovi-b4lh18 , drovi-b4lk43 , drovi-b4ll59 , drovi-b4ll60 , drovi-b4llm5 , drovi-b4lln3 , drovi-b4lmk4 , drovi-b4lmp0 , drovi-b4lnr4 , drovi-b4lp47 , drovi-b4lpd0 , drovi-b4lps0 , drovi-b4lqc6 , drovi-b4lr00 , drovi-b4lrp6 , drovi-b4lrw2 , drovi-b4lse7 , drovi-b4lse9 , drovi-b4lsf0 , drovi-b4lsn0 , drovi-b4lsq5 , drovi-b4lt32 , drovi-b4ltr1 , drovi-b4lui7 , drovi-b4lui9 , drovi-b4luj8 , drovi-b4luk0 , drovi-b4luk3 , drovi-b4luk8 , drovi-b4luk9 , drovi-b4lul0 , drovi-b4lve2 , drovi-b4lxi9 , drovi-b4lxj8 , drovi-b4lyf3 , drovi-b4lyq2 , drovi-b4lyq3 , drovi-b4lz07 , drovi-b4lz13 , drovi-b4lz14 , drovi-b4lz15 , drovi-b4m0j7 , drovi-b4m0s0 , drovi-b4m2b6 , drovi-b4m4h7 , drovi-b4m4h8 , drovi-b4m4i0 , drovi-b4m4i2 , drovi-b4m4i3.A , drovi-b4m4i3.B , drovi-b4m4i4 , drovi-b4m4i5 , drovi-b4m4i6 , drovi-b4m4i7 , drovi-b4m4i8 , drovi-b4m4i9 , drovi-b4m4j2 , drovi-b4m5a0 , drovi-b4m5a1 , drovi-b4m5a2 , drovi-b4m6b9 , drovi-b4m7k9 , drovi-b4m9g9 , drovi-b4m9h0 , drovi-b4m564 , drovi-b4m599 , drovi-b4m918 , drovi-b4mb87 , drovi-b4mc71 , drovi-b4mfa4 , drowi-ACHE , drowi-b4mjb9 , drowi-b4mkt7 , drowi-b4mlc1 , drowi-b4mp68 , drowi-b4mqe9 , drowi-b4mqf0.2 , drowi-b4mqf1 , drowi-b4mqf3 , drowi-b4mqf4 , drowi-b4mqf5 , drowi-b4mqq6 , drowi-b4mrd1 , drowi-b4mrk3 , drowi-b4mtl5 , drowi-b4mug2 , drowi-b4muj8 , drowi-b4mv18 , drowi-b4mw32 , drowi-b4mw85 , drowi-b4mwp2 , drowi-b4mwp6 , drowi-b4mwq5 , drowi-b4mwr0 , drowi-b4mwr8 , drowi-b4mwr9 , drowi-b4mwt1 , drowi-b4mwz7 , drowi-b4mxn5 , drowi-b4my54 , drowi-b4myg1 , drowi-b4myh5 , drowi-b4n0d4 , drowi-b4n1a7 , drowi-b4n1c8 , drowi-b4n3s9 , drowi-b4n3x7 , drowi-b4n4x9 , drowi-b4n4y0 , drowi-b4n6m1 , drowi-b4n6n0 , drowi-b4n6n7 , drowi-b4n6u6 , drowi-b4n7s6 , drowi-b4n7s7 , drowi-b4n7s8 , drowi-b4n899.1 , drowi-b4n8a1 , drowi-b4n8a2 , drowi-b4n8a3 , drowi-b4n8a4 , drowi-b4n8a9 , drowi-b4n023 , drowi-b4n075 , drowi-b4n543 , drowi-b4n888 , drowi-b4n889 , drowi-b4n891 , drowi-b4n893 , drowi-b4n895 , drowi-b4n897 , drowi-b4n898 , drowi-b4n899.2 , drowi-b4nae3 , drowi-b4ner8 , drowi-b4ng76 , drowi-b4nga7 , drowi-b4ngb5 , drowi-b4nhz9 , drowi-b4nj18 , drowi-b4nj19 , drowi-b4nja7 , drowi-b4nja8 , drowi-b4nja9 , drowi-b4njk8 , drowi-b4nkc8 , drowi-b4nky0 , drowi-b4nl36 , drowi-b4nm27 , drowi-b4nn59 , drowi-b4nnc1 , drowi-b4nng1 , drowi-b4nng2 , droya-ACHE , droya-aes04 , droya-b4itg2 , droya-b4itg6 , droya-b4itu9 , droya-b4iuv4 , droya-b4iuv5 , droya-b4nxe6 , droya-b4nxg5 , droya-b4nxg6 , droya-b4nxg8 , droya-b4nxw4 , droya-b4ny57 , droya-b4ny58 , droya-b4ny86 , droya-b4nzz8 , droya-b4p0b5 , droya-b4p0q9 , droya-b4p0r0 , droya-b4p0r7 , droya-b4p0r8 , droya-b4p0r9 , droya-b4p0s0 , droya-b4p0s2 , droya-b4p0t0 , droya-b4p0t1 , droya-b4p3h4 , droya-b4p3x8 , droya-b4p5g8 , droya-b4p6c9 , droya-b4p6l9 , droya-b4p6r1 , droya-b4p6r2 , droya-b4p7u4 , droya-b4p8w7 , droya-b4p023 , droya-b4p241 , droya-b4p774 , droya-b4pat9 , droya-b4pbl1 , droya-b4pd22 , droya-b4pd70 , droya-b4pdm8 , droya-b4pet9 , droya-b4pff9 , droya-b4pga7 , droya-b4pgu0 , droya-b4pig3 , droya-b4pjt8 , droya-b4pka2 , droya-b4plh2 , droya-b4pma3 , droya-b4pmv3 , droya-b4pmv4 , droya-b4pmv5 , droya-b4pn92 , droya-b4pp65 , droya-b4ppc5 , droya-b4ppc6 , droya-b4ppc7 , droya-b4ppc8 , droya-b4pq03 , droya-b4prg6B , droya-b4prg9 , droya-b4prh3 , droya-b4prh4 , droya-b4prh6 , droya-b4prh7 , droya-b4psz8 , droya-b4psz9 , droya-b4pv22 , droya-b4q0g5 , droya-b4q246 , droya-EST6 , droya-q71d76 , drowi-b4n7m9 , drope-b4gkk1 , droer-b3n5s3 , drose-b4i1w5 , drowi-a0a0q9x0t3 , drogr-b4jvm7 , dromo-b4ku70 , drovi-b4mcn9 , drovi-b4lty2 , drogr-b4jdu1 , drovi-a0a0q9wiq8 , dromo-b4kf70 , drosi-b2zi86 , droya-b4p2y4 , drose-b2zic5 , droer-b3n895

Title : Gene and alternative splicing annotation with AIR - Florea_2005_Genome.Res_15_54
Author(s) : Florea L , Di Francesco V , Miller J , Turner R , Yao A , Harris M , Walenz B , Mobarry C , Merkulov GV , Charlab R , Dew I , Deng Z , Istrail S , Li P , Sutton G
Ref : Genome Res , 15 :54 , 2005
Abstract : Designing effective and accurate tools for identifying the functional and structural elements in a genome remains at the frontier of genome annotation owing to incompleteness and inaccuracy of the data, limitations in the computational models, and shifting paradigms in genomics, such as alternative splicing. We present a methodology for the automated annotation of genes and their alternatively spliced mRNA transcripts based on existing cDNA and protein sequence evidence from the same species or projected from a related species using syntenic mapping information. At the core of the method is the splice graph, a compact representation of a gene, its exons, introns, and alternatively spliced isoforms. The putative transcripts are enumerated from the graph and assigned confidence scores based on the strength of sequence evidence, and a subset of the high-scoring candidates are selected and promoted into the annotation. The method is highly selective, eliminating the unlikely candidates while retaining 98% of the high-quality mRNA evidence in well-formed transcripts, and produces annotation that is measurably more accurate than some evidence-based gene sets. The process is fast, accurate, and fully automated, and combines the traditionally distinct gene annotation and alternative splicing detection processes in a comprehensive and systematic way, thus considerably aiding in the ensuing manual curation efforts.
ESTHER : Florea_2005_Genome.Res_15_54
PubMedSearch : Florea_2005_Genome.Res_15_54
PubMedID: 15632090
Gene_locus related to this paper: mouse-Ppgb , rat-d3zaw4 , rat-dpp9 , rat-d3zhq1 , rat-d3zxw8 , rat-d4a4w4 , rat-d4a7w1 , rat-d4a071 , rat-Tex30 , ratno-1plip , ratno-3plip , ratno-ABH15 , ratno-balip , ratno-Ces1d , ratno-d3zxq0 , ratno-est8 , ratno-pbcxe , ratno-phebest , ratno-q6mg55 , ratno-thyro , rat-m0rc77 , rat-d3zba8 , rat-f1lvg7 , rat-b5den3 , rat-d4a1b6 , rat-d3zmg4

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 : 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