Hall J

References (7)

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 : Genome sequence, comparative analysis and haplotype structure of the domestic dog - Lindblad-Toh_2005_Nature_438_803
Author(s) : Lindblad-Toh K , Wade CM , Mikkelsen TS , Karlsson EK , Jaffe DB , Kamal M , Clamp M , Chang JL , Kulbokas EJ, 3rd , Zody MC , Mauceli E , Xie X , Breen M , Wayne RK , Ostrander EA , Ponting CP , Galibert F , Smith DR , deJong PJ , Kirkness E , Alvarez P , Biagi T , Brockman W , Butler J , Chin CW , Cook A , Cuff J , Daly MJ , Decaprio D , Gnerre S , Grabherr M , Kellis M , Kleber M , Bardeleben C , Goodstadt L , Heger A , Hitte C , Kim L , Koepfli KP , Parker HG , Pollinger JP , Searle SM , Sutter NB , Thomas R , Webber C , Baldwin J , Abebe A , Abouelleil A , Aftuck L , Ait-Zahra M , Aldredge T , Allen N , An P , Anderson S , Antoine C , Arachchi H , Aslam A , Ayotte L , Bachantsang P , Barry A , Bayul T , Benamara M , Berlin A , Bessette D , Blitshteyn B , Bloom T , Blye J , Boguslavskiy L , Bonnet C , Boukhgalter B , Brown A , Cahill P , Calixte N , Camarata J , Cheshatsang Y , Chu J , Citroen M , Collymore A , Cooke P , Dawoe T , Daza R , Decktor K , DeGray S , Dhargay N , Dooley K , Dorje P , Dorjee K , Dorris L , Duffey N , Dupes A , Egbiremolen O , Elong R , Falk J , Farina A , Faro S , Ferguson D , Ferreira P , Fisher S , FitzGerald M , Foley K , Foley C , Franke A , Friedrich D , Gage D , Garber M , Gearin G , Giannoukos G , Goode T , Goyette A , Graham J , Grandbois E , Gyaltsen K , Hafez N , Hagopian D , Hagos B , Hall J , Healy C , Hegarty R , Honan T , Horn A , Houde N , Hughes L , Hunnicutt L , Husby M , Jester B , Jones C , Kamat A , Kanga B , Kells C , Khazanovich D , Kieu AC , Kisner P , Kumar M , Lance K , Landers T , Lara M , Lee W , Leger JP , Lennon N , Leuper L , LeVine S , Liu J , Liu X , Lokyitsang Y , Lokyitsang T , Lui A , MacDonald J , Major J , Marabella R , Maru K , Matthews C , McDonough S , Mehta T , Meldrim J , Melnikov A , Meneus L , Mihalev A , Mihova T , Miller K , Mittelman R , Mlenga V , Mulrain L , Munson G , Navidi A , Naylor J , Nguyen T , Nguyen N , Nguyen C , Nicol R , Norbu N , Norbu C , Novod N , Nyima T , Olandt P , O'Neill B , O'Neill K , Osman S , Oyono L , Patti C , Perrin D , Phunkhang P , Pierre F , Priest M , Rachupka A , Raghuraman S , Rameau R , Ray V , Raymond C , Rege F , Rise C , Rogers J , Rogov P , Sahalie J , Settipalli S , Sharpe T , Shea T , Sheehan M , Sherpa N , Shi J , Shih D , Sloan J , Smith C , Sparrow T , Stalker J , Stange-Thomann N , Stavropoulos S , Stone C , Stone S , Sykes S , Tchuinga P , Tenzing P , Tesfaye S , Thoulutsang D , Thoulutsang Y , Topham K , Topping I , Tsamla T , Vassiliev H , Venkataraman V , Vo A , Wangchuk T , Wangdi T , Weiand M , Wilkinson J , Wilson A , Yadav S , Yang S , Yang X , Young G , Yu Q , Zainoun J , Zembek L , Zimmer A , Lander ES
Ref : Nature , 438 :803 , 2005
Abstract : Here we report a high-quality draft genome sequence of the domestic dog (Canis familiaris), together with a dense map of single nucleotide polymorphisms (SNPs) across breeds. The dog is of particular interest because it provides important evolutionary information and because existing breeds show great phenotypic diversity for morphological, physiological and behavioural traits. We use sequence comparison with the primate and rodent lineages to shed light on the structure and evolution of genomes and genes. Notably, the majority of the most highly conserved non-coding sequences in mammalian genomes are clustered near a small subset of genes with important roles in development. Analysis of SNPs reveals long-range haplotypes across the entire dog genome, and defines the nature of genetic diversity within and across breeds. The current SNP map now makes it possible for genome-wide association studies to identify genes responsible for diseases and traits, with important consequences for human and companion animal health.
ESTHER : Lindblad-Toh_2005_Nature_438_803
PubMedSearch : Lindblad-Toh_2005_Nature_438_803
PubMedID: 16341006
Gene_locus related to this paper: canfa-1lipg , canfa-2neur , canfa-3neur , canfa-ACHE , canfa-BCHE , canfa-cauxin , canfa-CESDD1 , canfa-e2qsb1 , canfa-e2qsl3 , canfa-e2qsz2 , canfa-e2qvk3 , canfa-e2qw15 , canfa-e2qxs8 , canfa-e2qzs6 , canfa-e2r5t3 , canfa-e2r6f6 , canfa-e2r7e8 , canfa-e2r8v9 , canfa-e2r8z1 , canfa-e2r9h4 , canfa-e2r455 , canfa-e2rb70 , canfa-e2rcq9 , canfa-e2rd94 , canfa-e2rgi0 , canfa-e2rkq0 , canfa-e2rlz9 , canfa-e2rm00 , canfa-e2rqf1 , canfa-e2rss9 , canfa-f1p6w8 , canfa-f1p8b6 , canfa-f1p9d8 , canfa-f1p683 , canfa-f1pb79 , canfa-f1pgw0 , canfa-f1phd0 , canfa-f1phx2 , canfa-f1pke8 , canfa-f1pp08 , canfa-f1ppp9 , canfa-f1ps07 , canfa-f1ptf1 , canfa-f1pvp4 , canfa-f1pw93 , canfa-f1pwk3 , canfa-pafa , canfa-q1ert3 , canfa-q5jzr0 , canfa-e2rmb9 , canlf-f6v865 , canlf-e2rjg6 , canlf-e2r2h2 , canlf-f1p648 , canlf-f1pw90 , canlf-j9p8v6 , canlf-f1pcc4 , canlf-e2qxh0 , canlf-e2r774 , canlf-f1pf96 , canlf-e2rq56 , canlf-j9nwb1 , canlf-f1ptw2 , canlf-j9p8h1 , canlf-e2ree2 , canlf-f1prs1 , canlf-j9nus1 , canlf-e2rf91 , canlf-f1pg57 , canlf-f1q111

Title : Genome sequence of Halobacterium species NRC-1 - Ng_2000_Proc.Natl.Acad.Sci.U.S.A_97_12176
Author(s) : Ng WV , Kennedy SP , Mahairas GG , Berquist B , Pan M , Shukla HD , Lasky SR , Baliga NS , Thorsson V , Sbrogna J , Swartzell S , Weir D , Hall J , Dahl TA , Welti R , Goo YA , Leithauser B , Keller K , Cruz R , Danson MJ , Hough DW , Maddocks DG , Jablonski PE , Krebs MP , Angevine CM , Dale H , Isenbarger TA , Peck RF , Pohlschroder M , Spudich JL , Jung KW , Alam M , Freitas T , Hou S , Daniels CJ , Dennis PP , Omer AD , Ebhardt H , Lowe TM , Liang P , Riley M , Hood L , DasSarma S
Ref : Proc Natl Acad Sci U S A , 97 :12176 , 2000
Abstract : We report the complete sequence of an extreme halophile, Halobacterium sp. NRC-1, harboring a dynamic 2,571,010-bp genome containing 91 insertion sequences representing 12 families and organized into a large chromosome and 2 related minichromosomes. The Halobacterium NRC-1 genome codes for 2,630 predicted proteins, 36% of which are unrelated to any previously reported. Analysis of the genome sequence shows the presence of pathways for uptake and utilization of amino acids, active sodium-proton antiporter and potassium uptake systems, sophisticated photosensory and signal transduction pathways, and DNA replication, transcription, and translation systems resembling more complex eukaryotic organisms. Whole proteome comparisons show the definite archaeal nature of this halophile with additional similarities to the Gram-positive Bacillus subtilis and other bacteria. The ease of culturing Halobacterium and the availability of methods for its genetic manipulation in the laboratory, including construction of gene knockouts and replacements, indicate this halophile can serve as an excellent model system among the archaea.
ESTHER : Ng_2000_Proc.Natl.Acad.Sci.U.S.A_97_12176
PubMedSearch : Ng_2000_Proc.Natl.Acad.Sci.U.S.A_97_12176
PubMedID: 11016950
Gene_locus related to this paper: halsp-est , halsp-metx , halsp-VNG0492H , halsp-VNG0675C , halsp-VNG1418C , halsp-VNG1833C , halsp-Vng6296c , halsp-YUXL

Title : Large scale identification of genes involved in cell surface biosynthesis and architecture in Saccharomyces cerevisiae - Lussier_1997_Genetics_147_435
Author(s) : Lussier M , White AM , Sheraton J , di Paolo T , Treadwell J , Southard SB , Horenstein CI , Chen-Weiner J , Ram AF , Kapteyn JC , Roemer TW , Vo DH , Bondoc DC , Hall J , Zhong WW , Sdicu AM , Davies J , Klis FM , Robbins PW , Bussey H
Ref : Genetics , 147 :435 , 1997
Abstract : The sequenced yeast genome offers a unique resource for the analysis of eukaryotic cell function and enables genome-wide screens for genes involved in cellular processes. We have identified genes involved in cell surface assembly by screening transposon-mutagenized cells for altered sensitivity to calcofluor white, followed by supplementary screens to further characterize mutant phenotypes. The mutated genes were directly retrieved from genomic DNA and then matched uniquely to a gene in the yeast genome database. Eighty-two genes with apparent perturbation of the cell surface were identified, with mutations in 65 of them displaying at least one further cell surface phenotype in addition to their modified sensitivity to calcofluor. Fifty of these genes were previously known, 17 encoded proteins whose function could be anticipated through sequence homology or previously recognized phenotypes and 15 genes had no previously known phenotype.
ESTHER : Lussier_1997_Genetics_147_435
PubMedSearch : Lussier_1997_Genetics_147_435
PubMedID: 9335584
Gene_locus related to this paper: yeast-ECM18

Title : The nucleotide sequence of Saccharomyces cerevisiae chromosome XVI - Bussey_1997_Nature_387_103
Author(s) : Bussey H , Storms RK , Ahmed A , Albermann K , Allen E , Ansorge W , Araujo R , Aparicio A , Barrell B , Badcock K , Benes V , Botstein D , Bowman S , Bruckner M , Carpenter J , Cherry JM , Chung E , Churcher C , Coster F , Davis K , Davis RW , Dietrich FS , Delius H , DiPaolo T , Dubois E , Dusterhoft A , Duncan M , Floeth M , Fortin N , Friesen JD , Fritz C , Goffeau A , Hall J , Hebling U , Heumann K , Hilbert H , Hillier L , Hunicke-Smith S , Hyman R , Johnston M , Kalman S , Kleine K , Komp C , Kurdi O , Lashkari D , Lew H , Lin A , Lin D , Louis EJ , Marathe R , Messenguy F , Mewes HW , Mirtipati S , Moestl D , Muller-Auer S , Namath A , Nentwich U , Oefner P , Pearson D , Petel FX , Pohl TM , Purnelle B , Rajandream MA , Rechmann S , Rieger M , Riles L , Roberts D , Schafer M , Scharfe M , Scherens B , Schramm S , Schroder M , Sdicu AM , Tettelin H , Urrestarazu LA , Ushinsky S , Vierendeels F , Vissers S , Voss H , Walsh SV , Wambutt R , Wang Y , Wedler E , Wedler H , Winnett E , Zhong WW , Zollner A , Vo DH , Hani J
Ref : Nature , 387 :103 , 1997
Abstract : The nucleotide sequence of the 948,061 base pairs of chromosome XVI has been determined, completing the sequence of the yeast genome. Chromosome XVI was the last yeast chromosome identified, and some of the genes mapped early to it, such as GAL4, PEP4 and RAD1 (ref. 2) have played important roles in the development of yeast biology. The architecture of this final chromosome seems to be typical of the large yeast chromosomes, and shows large duplications with other yeast chromosomes. Chromosome XVI contains 487 potential protein-encoding genes, 17 tRNA genes and two small nuclear RNA genes; 27% of the genes have significant similarities to human gene products, and 48% are new and of unknown biological function. Systematic efforts to explore gene function have begun.
ESTHER : Bussey_1997_Nature_387_103
PubMedSearch : Bussey_1997_Nature_387_103
PubMedID: 9169875
Gene_locus related to this paper: yeast-MCFS1 , yeast-YPR147C

Title : Evidence for a general role for non-catalytic thermostabilizing domains in xylanases from thermophilic bacteria. - Fontes_1995_Biochem.J_307_151
Author(s) : Fontes CM , Hazelwood GP , Morag E , Hall J , Hirst BH , Gilbert HJ
Ref : Biochemical Journal , 307 :151 , 1995
Abstract : A genomic library of Clostridium thermocellum DNA constructed in lambda ZAPII was screened for xylanase-expressing clones. Cross-hybridization experiments revealed a new xylanase gene isolated from the gene library, which was designated xyn Y. The encoded enzyme, xylanase Y (XYLY), displayed features characteristic of an endo-beta1,4-xylanase: the enzyme rapidly hydrolysed oat spelt, wheat and rye arabinoxylans and was active against methyl-umbelliferyl-beta-D-cellobioside, but did not hydrolyse any cellulosic substrates. The pH and temperature optima of the enzyme were 6.8 and 75 degrees C respectively, and the recombinant XYLY, expressed by Escherichia coli had a maximum Mr of 116000. The nucleotide sequence of xyn Y contained an open reading frame of 3228 bp encoding a protein of predicted Mr 120 105. The encoded enzyme contained a typical N-terminal 26-residue signal peptide, followed by a 164 amino acid sequence, designated domain A, that was not essential for catalytic activity. Downstream of domain A was a 351-residue xylanase Family F catalytic domain, followed by a 180-residue sequence that exhibited 28% sequence identity with a thermostable domain of Thermoanaerobacterium saccharolyticum xylanase A. The C-terminal portion of XYLY comprised the 23-residue duplicated docking sequence found in all other C. thermocellum plant cell wall hydrolases that are constituents of the bacterium's multienzyme complex, termed the cellulosome, followed by a 286-residue domain which exhibited 32% sequence identity with the N-terminal region of C. thermocellum xylanase Z. The enzyme did not contain linker sequences found in other C. thermocellum plant cell wall hydrolases. Analysis of truncated forms of XYLY and hybrid proteins, comprising segments of XYLY fused to the E. coli maltose binding domain, confirmed that XYLY contained a central catalytic domain and an adjacent thermostable domain. The C-terminal domain did not bind to cellulose or xylan. Western blot analysis using antiserum raised against XYLY showed that the xylanase was located in the cellulosome and did not appear to be extensively glycosylated. The non-catalytic domains of XYLY are discussed in relation to the general stability of thermophilic xylanases.
ESTHER : Fontes_1995_Biochem.J_307_151
PubMedSearch : Fontes_1995_Biochem.J_307_151
PubMedID: 7717969
Gene_locus related to this paper: clotm-xyny

Title : The nucleotide sequence of chromosome I from Saccharomyces cerevisiae - Bussey_1995_Proc.Natl.Acad.Sci.U.S.A_92_3809
Author(s) : Bussey H , Kaback DB , Zhong W , Vo DT , Clark MW , Fortin N , Hall J , Ouellette BF , Keng T , Barton AB , et al.
Ref : Proc Natl Acad Sci U S A , 92 :3809 , 1995
Abstract : Chromosome I from the yeast Saccharomyces cerevisiae contains a DNA molecule of approximately 231 kbp and is the smallest naturally occurring functional eukaryotic nuclear chromosome so far characterized. The nucleotide sequence of this chromosome has been determined as part of an international collaboration to sequence the entire yeast genome. The chromosome contains 89 open reading frames and 4 tRNA genes. The central 165 kbp of the chromosome resembles other large sequenced regions of the yeast genome in both its high density and distribution of genes. In contrast, the remaining sequences flanking this DNA that comprise the two ends of the chromosome and make up more than 25% of the DNA molecule have a much lower gene density, are largely not transcribed, contain no genes essential for vegetative growth, and contain several apparent pseudogenes and a 15-kbp redundant sequence. These terminally repetitive regions consist of a telomeric repeat called W', flanked by DNA closely related to the yeast FLO1 gene. The low gene density, presence of pseudogenes, and lack of expression are consistent with the idea that these terminal regions represent the yeast equivalent of heterochromatin. The occurrence of such a high proportion of DNA with so little information suggests that its presence gives this chromosome the critical length required for proper function.
ESTHER : Bussey_1995_Proc.Natl.Acad.Sci.U.S.A_92_3809
PubMedSearch : Bussey_1995_Proc.Natl.Acad.Sci.U.S.A_92_3809
PubMedID: 7731988
Gene_locus related to this paper: yeast-AIM2