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Author Report for: Griffiths-Jones S

Title: Evolution of genes and genomes on the Drosophila phylogeny
Clark AG, Eisen MB, Smith DR, Bergman CM, Oliver B, Markow TA, Kaufman TC, Kellis M, Gelbart W and MacCallum I <405 more 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 (- 405)
Ref: Nature, 450:203, 2007 : PubMed
Abstract


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

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.



        

Title: The DNA sequence and biological annotation of human chromosome 1
Gregory SG, Barlow KF, McLay KE, Kaul R, Swarbreck D, Dunham A, Scott CE, Howe KL, Woodfine K and Prigmore E <169 more author(s)> Gregory SG, Barlow KF, McLay KE, Kaul R, Swarbreck D, Dunham A, Scott CE, Howe KL, Woodfine K, Spencer CC, Jones MC, Gillson C, Searle S, Zhou Y, Kokocinski F, McDonald L, Evans R, Phillips K, Atkinson A, Cooper R, Jones C, Hall RE, Andrews TD, Lloyd C, Ainscough R, Almeida JP, Ambrose KD, Anderson F, Andrew RW, Ashwell RI, Aubin K, Babbage AK, Bagguley CL, Bailey J, Beasley H, Bethel G, Bird CP, Bray-Allen S, Brown JY, Brown AJ, Buckley D, Burton J, Bye J, Carder C, Chapman JC, Clark SY, Clarke G, Clee C, Cobley V, Collier RE, Corby N, Coville GJ, Davies J, Deadman R, Dunn M, Earthrowl M, Ellington AG, Errington H, Frankish A, Frankland J, French L, Garner P, Garnett J, Gay L, Ghori MR, Gibson R, Gilby LM, Gillett W, Glithero RJ, Grafham DV, Griffiths C, Griffiths-Jones S, Grocock R, Hammond S, Harrison ES, Hart E, Haugen E, Heath PD, Holmes S, Holt K, Howden PJ, Hunt AR, Hunt SE, Hunter G, Isherwood J, James R, Johnson C, Johnson D, Joy A, Kay M, Kershaw JK, Kibukawa M, Kimberley AM, King A, Knights AJ, Lad H, Laird G, Lawlor S, Leongamornlert DA, Lloyd DM, Loveland J, Lovell J, Lush MJ, Lyne R, Martin S, Mashreghi-Mohammadi M, Matthews L, Matthews NS, Mclaren S, Milne S, Mistry S, Moore MJ, Nickerson T, O'Dell CN, Oliver K, Palmeiri A, Palmer SA, Parker A, Patel D, Pearce AV, Peck AI, Pelan S, Phelps K, Phillimore BJ, Plumb R, Rajan J, Raymond C, Rouse G, Saenphimmachak C, Sehra HK, Sheridan E, Shownkeen R, Sims S, Skuce CD, Smith M, Steward C, Subramanian S, Sycamore N, Tracey A, Tromans A, Van Helmond Z, Wall M, Wallis JM, White S, Whitehead SL, Wilkinson JE, Willey DL, Williams H, Wilming L, Wray PW, Wu Z, Coulson A, Vaudin M, Sulston JE, Durbin R, Hubbard T, Wooster R, Dunham I, Carter NP, McVean G, Ross MT, Harrow J, Olson MV, Beck S, Rogers J, Bentley DR, Banerjee R, Bryant SP, Burford DC, Burrill WD, Clegg SM, Dhami P, Dovey O, Faulkner LM, Gribble SM, Langford CF, Pandian RD, Porter KM, Prigmore E (- 169)
Ref: Nature, 441:315, 2006 : PubMed
Abstract


ESTHER: Gregory_2006_Nature_441_315
PubMedSearch: Gregory 2006 Nature 441 315
PubMedID: 16710414
Gene_locus related to this paper: human-LYPLAL1, human-PPT1, human-TMCO4, human-TMEM53

Abstract

The reference sequence for each human chromosome provides the framework for understanding genome function, variation and evolution. Here we report the finished sequence and biological annotation of human chromosome 1. Chromosome 1 is gene-dense, with 3,141 genes and 991 pseudogenes, and many coding sequences overlap. Rearrangements and mutations of chromosome 1 are prevalent in cancer and many other diseases. Patterns of sequence variation reveal signals of recent selection in specific genes that may contribute to human fitness, and also in regions where no function is evident. Fine-scale recombination occurs in hotspots of varying intensity along the sequence, and is enriched near genes. These and other studies of human biology and disease encoded within chromosome 1 are made possible with the highly accurate annotated sequence, as part of the completed set of chromosome sequences that comprise the reference human genome.



        

Title: Sequencing of Aspergillus nidulans and comparative analysis with A. fumigatus and A. oryzae
Galagan JE, Calvo SE, Cuomo C, Ma LJ, Wortman JR, Batzoglou S, Lee SI, Basturkmen M, Spevak CC and Birren BW <40 more author(s)> Galagan JE, Calvo SE, Cuomo C, Ma LJ, Wortman JR, Batzoglou S, Lee SI, Basturkmen M, Spevak CC, Clutterbuck J, Kapitonov V, Jurka J, Scazzocchio C, Farman M, Butler J, Purcell S, Harris S, Braus GH, Draht O, Busch S, d'Enfert C, Bouchier C, Goldman GH, Bell-Pedersen D, Griffiths-Jones S, Doonan JH, Yu J, Vienken K, Pain A, Freitag M, Selker EU, Archer DB, Penalva MA, Oakley BR, Momany M, Tanaka T, Kumagai T, Asai K, Machida M, Nierman WC, Denning DW, Caddick M, Hynes M, Paoletti M, Fischer R, Miller B, Dyer P, Sachs MS, Osmani SA, Birren BW (- 40)
Ref: Nature, 438:1105, 2005 : PubMed
Abstract


ESTHER: Galagan_2005_Nature_438_1105
PubMedSearch: Galagan 2005 Nature 438 1105
PubMedID: 16372000
Gene_locus related to this paper: emeni-axe1, emeni-BST1, emeni-c8vrl3, emeni-CUTI3, emeni-faec, emeni-ppme1, emeni-q5aqv0, emeni-q5ara9, emeni-q5av79, emeni-q5avd3, emeni-q5awc7, emeni-q5awq3, emeni-q5awu9, emeni-q5aww7, emeni-q5ax50, emeni-q5ay37, emeni-q5ay57, emeni-q5ayk9, emeni-q5az32, emeni-q5azl2, emeni-q5azp1, emeni-q5b1v2, emeni-q5b2c1, emeni-q5b3d2, emeni-q5b5j7, emeni-q5b7i6, emeni-q5b8p6, emeni-q5b9e7, emeni-q5b246, emeni-q5b446, emeni-q5b602, emeni-q5b938, emeni-q5ba78, emeni-q5bad3, emeni-q5bar0, emeni-q5bcd1, emeni-q5bcd2, emeni-q5bcf8, emeni-q5bdr0, emeni-q5beh9, emeni-q5bgk7, emeni-q7si80, emeni-q5bdv9, emeni-c8vu15, 9euro-a0a3d8t644, emeni-q5b719, emeni-q5ax97, emeni-tdia, emeni-afoc, emeni-dbae

Abstract

The aspergilli comprise a diverse group of filamentous fungi spanning over 200 million years of evolution. Here we report the genome sequence of the model organism Aspergillus nidulans, and a comparative study with Aspergillus fumigatus, a serious human pathogen, and Aspergillus oryzae, used in the production of sake, miso and soy sauce. Our analysis of genome structure provided a quantitative evaluation of forces driving long-term eukaryotic genome evolution. It also led to an experimentally validated model of mating-type locus evolution, suggesting the potential for sexual reproduction in A. fumigatus and A. oryzae. Our analysis of sequence conservation revealed over 5,000 non-coding regions actively conserved across all three species. Within these regions, we identified potential functional elements including a previously uncharacterized TPP riboswitch and motifs suggesting regulation in filamentous fungi by Puf family genes. We further obtained comparative and experimental evidence indicating widespread translational regulation by upstream open reading frames. These results enhance our understanding of these widely studied fungi as well as provide new insight into eukaryotic genome evolution and gene regulation.



        

Title: Genome of the host-cell transforming parasite Theileria annulata compared with T. parva
Pain A, Renauld H, Berriman M, Murphy L, Yeats CA, Weir W, Kerhornou A, Aslett M, Bishop R and Hall N <40 more author(s)> Pain A, Renauld H, Berriman M, Murphy L, Yeats CA, Weir W, Kerhornou A, Aslett M, Bishop R, Bouchier C, Cochet M, Coulson RM, Cronin A, de Villiers EP, Fraser A, Fosker N, Gardner M, Goble A, Griffiths-Jones S, Harris DE, Katzer F, Larke N, Lord A, Maser P, McKellar S, Mooney P, Morton F, Nene V, O'Neil S, Price C, Quail MA, Rabbinowitsch E, Rawlings ND, Rutter S, Saunders D, Seeger K, Shah T, Squares R, Squares S, Tivey A, Walker AR, Woodward J, Dobbelaere DA, Langsley G, Rajandream MA, McKeever D, Shiels B, Tait A, Barrell B, Hall N (- 40)
Ref: Science, 309:131, 2005 : PubMed
Abstract


ESTHER: Pain_2005_Science_309_131
PubMedSearch: Pain 2005 Science 309 131
PubMedID: 15994557
Gene_locus related to this paper: thean-q4u9u6, thean-q4ub48, thean-q4ubz1, thean-q4uc78, thean-q4uc93, thean-q4uck1, thean-q4udw9, thean-q4ue56, thean-q4uf06, thean-q4ug98, thean-q4uhj9, thepa-q4n349

Abstract

Theileria annulata and T. parva are closely related protozoan parasites that cause lymphoproliferative diseases of cattle. We sequenced the genome of T. annulata and compared it with that of T. parva to understand the mechanisms underlying transformation and tropism. Despite high conservation of gene sequences and synteny, the analysis reveals unequally expanded gene families and species-specific genes. We also identify divergent families of putative secreted polypeptides that may reduce immune recognition, candidate regulators of host-cell transformation, and a Theileria-specific protein domain [frequently associated in Theileria (FAINT)] present in a large number of secreted proteins.



        

Title: The DNA sequence and analysis of human chromosome 13
Dunham A, Matthews LH, Burton J, Ashurst JL, Howe KL, Ashcroft KJ, Beare DM, Burford DC, Hunt SE and Ross MT <116 more author(s)> Dunham A, Matthews LH, Burton J, Ashurst JL, Howe KL, Ashcroft KJ, Beare DM, Burford DC, Hunt SE, Griffiths-Jones S, Jones MC, Keenan SJ, Oliver K, Scott CE, Ainscough R, Almeida JP, Ambrose KD, Andrews DT, Ashwell RI, Babbage AK, Bagguley CL, Bailey J, Bannerjee R, Barlow KF, Bates K, Beasley H, Bird CP, Bray-Allen S, Brown AJ, Brown JY, Burrill W, Carder C, Carter NP, Chapman JC, Clamp ME, Clark SY, Clarke G, Clee CM, Clegg SC, Cobley V, Collins JE, Corby N, Coville GJ, Deloukas P, Dhami P, Dunham I, Dunn M, Earthrowl ME, Ellington AG, Faulkner L, Frankish AG, Frankland J, French L, Garner P, Garnett J, Gilbert JG, Gilson CJ, Ghori J, Grafham DV, Gribble SM, Griffiths C, Hall RE, Hammond S, Harley JL, Hart EA, Heath PD, Howden PJ, Huckle EJ, Hunt PJ, Hunt AR, Johnson C, Johnson D, Kay M, Kimberley AM, King A, Laird GK, Langford CJ, Lawlor S, Leongamornlert DA, Lloyd DM, Lloyd C, Loveland JE, Lovell J, Martin S, Mashreghi-Mohammadi M, McLaren SJ, McMurray A, Milne S, Moore MJ, Nickerson T, Palmer SA, Pearce AV, Peck AI, Pelan S, Phillimore B, Porter KM, Rice CM, Searle S, Sehra HK, Shownkeen R, Skuce CD, Smith M, Steward CA, Sycamore N, Tester J, Thomas DW, Tracey A, Tromans A, Tubby B, Wall M, Wallis JM, West AP, Whitehead SL, Willey DL, Wilming L, Wray PW, Wright MW, Young L, Coulson A, Durbin R, Hubbard T, Sulston JE, Beck S, Bentley DR, Rogers J, Ross MT (- 116)
Ref: Nature, 428:522, 2004 : PubMed
Abstract


ESTHER: Dunham_2004_Nature_428_522
PubMedSearch: Dunham 2004 Nature 428 522
PubMedID: 15057823
Gene_locus related to this paper: human-ESD, human-TEX30

Abstract

Chromosome 13 is the largest acrocentric human chromosome. It carries genes involved in cancer including the breast cancer type 2 (BRCA2) and retinoblastoma (RB1) genes, is frequently rearranged in B-cell chronic lymphocytic leukaemia, and contains the DAOA locus associated with bipolar disorder and schizophrenia. We describe completion and analysis of 95.5 megabases (Mb) of sequence from chromosome 13, which contains 633 genes and 296 pseudogenes. We estimate that more than 95.4% of the protein-coding genes of this chromosome have been identified, on the basis of comparison with other vertebrate genome sequences. Additionally, 105 putative non-coding RNA genes were found. Chromosome 13 has one of the lowest gene densities (6.5 genes per Mb) among human chromosomes, and contains a central region of 38 Mb where the gene density drops to only 3.1 genes per Mb.



        

Title: Sequence and comparative analysis of the chicken genome provide unique perspectives on vertebrate evolution
Hillier LW, Miller W, Birney E, Warren W, Hardison RC, Ponting CP, Bork P, Burt DW, Groenen MA and Wilson RK <164 more author(s)> Hillier LW, Miller W, Birney E, Warren W, Hardison RC, Ponting CP, Bork P, Burt DW, Groenen MA, Delany ME, Dodgson JB, Chinwalla AT, Cliften PF, Clifton SW, Delehaunty KD, Fronick C, Fulton RS, Graves TA, Kremitzki C, Layman D, Magrini V, McPherson JD, Miner TL, Minx P, Nash WE, Nhan MN, Nelson JO, Oddy LG, Pohl CS, Randall-Maher J, Smith SM, Wallis JW, Yang SP, Romanov MN, Rondelli CM, Paton B, Smith J, Morrice D, Daniels L, Tempest HG, Robertson L, Masabanda JS, Griffin DK, Vignal A, Fillon V, Jacobbson L, Kerje S, Andersson L, Crooijmans RP, Aerts J, van der Poel JJ, Ellegren H, Caldwell RB, Hubbard SJ, Grafham DV, Kierzek AM, McLaren SR, Overton IM, Arakawa H, Beattie KJ, Bezzubov Y, Boardman PE, Bonfield JK, Croning MD, Davies RM, Francis MD, Humphray SJ, Scott CE, Taylor RG, Tickle C, Brown WR, Rogers J, Buerstedde JM, Wilson SA, Stubbs L, Ovcharenko I, Gordon L, Lucas S, Miller MM, Inoko H, Shiina T, Kaufman J, Salomonsen J, Skjoedt K, Ka-Shu Wong G, Wang J, Liu B, Yu J, Yang H, Nefedov M, Koriabine M, deJong PJ, Goodstadt L, Webber C, Dickens NJ, Letunic I, Suyama M, Torrents D, von Mering C, Zdobnov EM, Makova K, Nekrutenko A, Elnitski L, Eswara P, King DC, Yang S, Tyekucheva S, Radakrishnan A, Harris RS, Chiaromonte F, Taylor J, He J, Rijnkels M, Griffiths-Jones S, Ureta-Vidal A, Hoffman MM, Severin J, Searle SM, Law AS, Speed D, Waddington D, Cheng Z, Tuzun E, Eichler E, Bao Z, Flicek P, Shteynberg DD, Brent MR, Bye JM, Huckle EJ, Chatterji S, Dewey C, Pachter L, Kouranov A, Mourelatos Z, Hatzigeorgiou AG, Paterson AH, Ivarie R, Brandstrom M, Axelsson E, Backstrom N, Berlin S, Webster MT, Pourquie O, Reymond A, Ucla C, Antonarakis SE, Long M, Emerson JJ, Betran E, Dupanloup I, Kaessmann H, Hinrichs AS, Bejerano G, Furey TS, Harte RA, Raney B, Siepel A, Kent WJ, Haussler D, Eyras E, Castelo R, Abril JF, Castellano S, Camara F, Parra G, Guigo R, Bourque G, Tesler G, Pevzner PA, Smit A, Fulton LA, Mardis ER, Wilson RK (- 164)
Ref: Nature, 432:695, 2004 : PubMed
Abstract


ESTHER: Hillier_2004_Nature_432_695
PubMedSearch: Hillier 2004 Nature 432 695
PubMedID: 15592404
Gene_locus related to this paper: chick-a0a1d5pmd9, chick-b3tzb3, chick-BCHE, chick-cb043, chick-d3wgl5, chick-e1bsm0, chick-e1bvq6, chick-e1bwz0, chick-e1bwz1, chick-e1byn1, chick-e1bz81, chick-e1c0z8, chick-e1c7p7, chick-f1nby4, chick-f1ncz8, chick-f1ndp3, chick-f1nep4, chick-f1nj68, chick-f1njg6, chick-f1njk4, chick-f1njs4, chick-f1njs5, chick-f1nk87, chick-f1nmx9, chick-f1ntp8, chick-f1nvg7, chick-f1nwf2, chick-f1p1l1, chick-f1p3j5, chick-f1p4c6, chick-f1p508, chick-fas, chick-h9l0k6, chick-nlgn1, chick-NLGN3, chick-q5f3h8, chick-q5zhm0, chick-q5zi81, chick-q5zij5, chick-q5zin0, chick-thyro, chick-f1nrq2, chick-e1byd4, chick-e1c2h6, chick-a0a1d5pk92, chick-a0a1d5pzg7, chick-f1nbc2, chick-f1nf25, chick-f1nly5, chick-f1p4h5, chick-f1nzi7, chick-f1p5k3, chick-f1nm35, chick-a0a1d5pl11, chick-a0a1d5pj73, chick-f1nxu6, chick-a0a1d5nwc0, chick-e1bxs8, chick-f1p2g7, chick-f1nd96

Abstract

We present here a draft genome sequence of the red jungle fowl, Gallus gallus. Because the chicken is a modern descendant of the dinosaurs and the first non-mammalian amniote to have its genome sequenced, the draft sequence of its genome--composed of approximately one billion base pairs of sequence and an estimated 20,000-23,000 genes--provides a new perspective on vertebrate genome evolution, while also improving the annotation of mammalian genomes. For example, the evolutionary distance between chicken and human provides high specificity in detecting functional elements, both non-coding and coding. Notably, many conserved non-coding sequences are far from genes and cannot be assigned to defined functional classes. In coding regions the evolutionary dynamics of protein domains and orthologous groups illustrate processes that distinguish the lineages leading to birds and mammals. The distinctive properties of avian microchromosomes, together with the inferred patterns of conserved synteny, provide additional insights into vertebrate chromosome architecture.



        

Title: DNA sequence and analysis of human chromosome 9
Humphray SJ, Oliver K, Hunt AR, Plumb RW, Loveland JE, Howe KL, Andrews TD, Searle S, Hunt SE and Dunham I <138 more author(s)> Humphray SJ, Oliver K, Hunt AR, Plumb RW, Loveland JE, Howe KL, Andrews TD, Searle S, Hunt SE, Scott CE, Jones MC, Ainscough R, Almeida JP, Ambrose KD, Ashwell RI, Babbage AK, Babbage S, Bagguley CL, Bailey J, Banerjee R, Barker DJ, Barlow KF, Bates K, Beasley H, Beasley O, Bird CP, Bray-Allen S, Brown AJ, Brown JY, Burford D, Burrill W, Burton J, Carder C, Carter NP, Chapman JC, Chen Y, Clarke G, Clark SY, Clee CM, Clegg S, Collier RE, Corby N, Crosier M, Cummings AT, Davies J, Dhami P, Dunn M, Dutta I, Dyer LW, Earthrowl ME, Faulkner L, Fleming CJ, Frankish A, Frankland JA, French L, Fricker DG, Garner P, Garnett J, Ghori J, Gilbert JG, Glison C, Grafham DV, Gribble S, Griffiths C, Griffiths-Jones S, Grocock R, Guy J, Hall RE, Hammond S, Harley JL, Harrison ES, Hart EA, Heath PD, Henderson CD, Hopkins BL, Howard PJ, Howden PJ, Huckle E, Johnson C, Johnson D, Joy AA, Kay M, Keenan S, Kershaw JK, Kimberley AM, King A, Knights A, Laird GK, Langford C, Lawlor S, Leongamornlert DA, Leversha M, Lloyd C, Lloyd DM, Lovell J, Martin S, Mashreghi-Mohammadi M, Matthews L, Mclaren S, McLay KE, McMurray A, Milne S, Nickerson T, Nisbett J, Nordsiek G, Pearce AV, Peck AI, Porter KM, Pandian R, Pelan S, Phillimore B, Povey S, Ramsey Y, Rand V, Scharfe M, Sehra HK, Shownkeen R, Sims SK, Skuce CD, Smith M, Steward CA, Swarbreck D, Sycamore N, Tester J, Thorpe A, Tracey A, Tromans A, Thomas DW, Wall M, Wallis JM, West AP, Whitehead SL, Willey DL, Williams SA, Wilming L, Wray PW, Young L, Ashurst JL, Coulson A, Blocker H, Durbin R, Sulston JE, Hubbard T, Jackson MJ, Bentley DR, Beck S, Rogers J, Dunham I (- 138)
Ref: Nature, 429:369, 2004 : PubMed
Abstract


ESTHER: Humphray_2004_Nature_429_369
PubMedSearch: Humphray 2004 Nature 429 369
PubMedID: 15164053
Gene_locus related to this paper: human-CEL

Abstract

Chromosome 9 is highly structurally polymorphic. It contains the largest autosomal block of heterochromatin, which is heteromorphic in 6-8% of humans, whereas pericentric inversions occur in more than 1% of the population. The finished euchromatic sequence of chromosome 9 comprises 109,044,351 base pairs and represents >99.6% of the region. Analysis of the sequence reveals many intra- and interchromosomal duplications, including segmental duplications adjacent to both the centromere and the large heterochromatic block. We have annotated 1,149 genes, including genes implicated in male-to-female sex reversal, cancer and neurodegenerative disease, and 426 pseudogenes. The chromosome contains the largest interferon gene cluster in the human genome. There is also a region of exceptionally high gene and G + C content including genes paralogous to those in the major histocompatibility complex. We have also detected recently duplicated genes that exhibit different rates of sequence divergence, presumably reflecting natural selection.



        

Title: The genome sequence of Caenorhabditis briggsae: a platform for comparative genomics
Stein LD, Bao Z, Blasiar D, Blumenthal T, Brent MR, Chen N, Chinwalla A, Clarke L, Clee C and Waterston RH <26 more author(s)> Stein LD, Bao Z, Blasiar D, Blumenthal T, Brent MR, Chen N, Chinwalla A, Clarke L, Clee C, Coghlan A, Coulson A, D'Eustachio P, Fitch DH, Fulton LA, Fulton RE, Griffiths-Jones S, Harris TW, Hillier LW, Kamath R, Kuwabara PE, Mardis ER, Marra MA, Miner TL, Minx P, Mullikin JC, Plumb RW, Rogers J, Schein JE, Sohrmann M, Spieth J, Stajich JE, Wei C, Willey D, Wilson RK, Durbin R, Waterston RH (- 26)
Ref: PLoS Biol, 1:E45, 2003 : PubMed
Abstract


ESTHER: Stein_2003_PLoS.Biol_1_E45
PubMedSearch: Stein 2003 PLoS.Biol 1 E45
PubMedID: 14624247
Gene_locus related to this paper: caebr-a8wl70, caebr-a8wm66, caebr-a8wny7, caebr-a8wpj6, caebr-a8wpy7.1, caebr-a8wq91, caebr-a8wr10, caebr-A8WSQ5, caebr-a8wta1, caebr-A8WTU9, caebr-a8wux6, caebr-A8WX49, caebr-a8wxx0, caebr-a8wyd4, caebr-a8wye8, caebr-a8wz10, caebr-a8wz31.1, caebr-a8wz31.2, caebr-a8wz31.4, caebr-a8wzp9, caebr-a8wzr9.1, caebr-a8wzr9.2, caebr-a8wzs0, caebr-a8wzs1, caebr-a8x0r9, caebr-a8x0z5, caebr-a8x1l6, caebr-a8x1r6, caebr-a8x3t6, caebr-a8x4h0, caebr-a8x4u8, caebr-a8x4w8, caebr-a8x5l4, caebr-a8x5l5, caebr-a8x5r5, caebr-a8x5s6, caebr-a8x5t4, caebr-a8x6s0, caebr-a8x6s1, caebr-a8x7d1, caebr-a8x7h0, caebr-a8x7v6, caebr-A8X8P2, caebr-a8x8q5, caebr-a8x8y6, caebr-a8x9s4, caebr-a8x324.1, caebr-a8x324.2, caebr-a8x622, caebr-a8xac7, caebr-a8xag5, caebr-a8xb07, caebr-a8xb88, caebr-a8xby0, caebr-a8xdz0, caebr-a8xf42, caebr-a8xfd1, caebr-a8xfe6, caebr-a8xgi0, caebr-a8xgz4, caebr-a8xgz5, caebr-a8xh38, caebr-a8xhp8, caebr-a8xhx9, caebr-a8xjw4, caebr-a8xk02, caebr-a8xk46, caebr-a8xk76, caebr-a8xke1, caebr-A8XLQ2, caebr-a8xns2.1, caebr-a8xns2.2, caebr-a8xq21, caebr-a8xub3, caebr-a8xuc2, caebr-a8xuc8, caebr-a8xug3, caebr-a8xuh6, caebr-a8xui4, caebr-a8xui5, caebr-a8xui6, caebr-a8xui7, caebr-a8xum8, caebr-a8y0h0.1, caebr-a8y0h0.2, caebr-a8y0h1.1, caebr-a8y0h1.2, caebr-a8y1b5, caebr-a8y1r7, caebr-a8y2v4, caebr-a8y3e3, caebr-a8y3i5, caebr-a8y3j9, caebr-a8y4p9, caebr-a8y100, caebr-a8y101, caebr-ACHE1, caebr-ACHE2, caebr-ACHE3, caebr-ACHE4, caebr-b6ii84, caebr-G01D9.5, caebr-ges1e, caebr-a8y4l4, caebr-A8Y1T9, caebr-A8Y168, caebr-A8Y0Z5, caebr-A8XYQ5, caebr-A8XXK4, caebr-A8XWZ8, caebr-A8XUF0, caebr-A8XUB6, caebr-A8XSV2, caebr-A8XJ37, caebr-A8XG15, caebr-A8XFE8, caebr-A8XEY7, caebr-A8XEU8, caebr-A8XDT6, caebr-A8XDV3, caebr-A8XDQ3, caebr-A8XDK8, caebr-A8XBW4, caebr-A8XAG3, caebr-A8X8H5, caebr-A8X6Z9, caebr-A8X6H9, caebr-A8X629, caebr-A8X438, caebr-A8X4G2, caebr-A8X4H8, caebr-A8X4W2, caebr-A8X3P4, caebr-A8X3R1, caebr-A8X2Z4, caebr-A8X0N2, caebr-A8X0B3, caebr-A8WW80, caebr-U483, caebr-A8XPH6, caebr-A8XNJ0, caebr-A8XNA2, caebr-A8XLP0, caebr-A8XK33, caebr-A8WTK6, caebr-A8WU44, caebr-A8WPJ2, caebr-A8WNE5, caebr-A8WMB3, caebr-a8x1r2

Abstract

The soil nematodes Caenorhabditis briggsae and Caenorhabditis elegans diverged from a common ancestor roughly 100 million years ago and yet are almost indistinguishable by eye. They have the same chromosome number and genome sizes, and they occupy the same ecological niche. To explore the basis for this striking conservation of structure and function, we have sequenced the C. briggsae genome to a high-quality draft stage and compared it to the finished C. elegans sequence. We predict approximately 19,500 protein-coding genes in the C. briggsae genome, roughly the same as in C. elegans. Of these, 12,200 have clear C. elegans orthologs, a further 6,500 have one or more clearly detectable C. elegans homologs, and approximately 800 C. briggsae genes have no detectable matches in C. elegans. Almost all of the noncoding RNAs (ncRNAs) known are shared between the two species. The two genomes exhibit extensive colinearity, and the rate of divergence appears to be higher in the chromosomal arms than in the centers. Operons, a distinctive feature of C. elegans, are highly conserved in C. briggsae, with the arrangement of genes being preserved in 96% of cases. The difference in size between the C. briggsae (estimated at approximately 104 Mbp) and C. elegans (100.3 Mbp) genomes is almost entirely due to repetitive sequence, which accounts for 22.4% of the C. briggsae genome in contrast to 16.5% of the C. elegans genome. Few, if any, repeat families are shared, suggesting that most were acquired after the two species diverged or are undergoing rapid evolution. Coclustering the C. elegans and C. briggsae proteins reveals 2,169 protein families of two or more members. Most of these are shared between the two species, but some appear to be expanding or contracting, and there seem to be as many as several hundred novel C. briggsae gene families. The C. briggsae draft sequence will greatly improve the annotation of the C. elegans genome. Based on similarity to C. briggsae, we found strong evidence for 1,300 new C. elegans genes. In addition, comparisons of the two genomes will help to understand the evolutionary forces that mold nematode genomes.