Mauceli E

References (16)

Title : A high-resolution map of human evolutionary constraint using 29 mammals - Lindblad-Toh_2011_Nature_478_476
Author(s) : Lindblad-Toh K , Garber M , Zuk O , Lin MF , Parker BJ , Washietl S , Kheradpour P , Ernst J , Jordan G , Mauceli E , Ward LD , Lowe CB , Holloway AK , Clamp M , Gnerre S , Alfoldi J , Beal K , Chang J , Clawson H , Cuff J , Di Palma F , Fitzgerald S , Flicek P , Guttman M , Hubisz MJ , Jaffe DB , Jungreis I , Kent WJ , Kostka D , Lara M , Martins AL , Massingham T , Moltke I , Raney BJ , Rasmussen MD , Robinson J , Stark A , Vilella AJ , Wen J , Xie X , Zody MC , Baldwin J , Bloom T , Chin CW , Heiman D , Nicol R , Nusbaum C , Young S , Wilkinson J , Worley KC , Kovar CL , Muzny DM , Gibbs RA , Cree A , Dihn HH , Fowler G , Jhangiani S , Joshi V , Lee S , Lewis LR , Nazareth LV , Okwuonu G , Santibanez J , Warren WC , Mardis ER , Weinstock GM , Wilson RK , Delehaunty K , Dooling D , Fronik C , Fulton L , Fulton B , Graves T , Minx P , Sodergren E , Birney E , Margulies EH , Herrero J , Green ED , Haussler D , Siepel A , Goldman N , Pollard KS , Pedersen JS , Lander ES , Kellis M
Ref : Nature , 478 :476 , 2011
Abstract : The comparison of related genomes has emerged as a powerful lens for genome interpretation. Here we report the sequencing and comparative analysis of 29 eutherian genomes. We confirm that at least 5.5% of the human genome has undergone purifying selection, and locate constrained elements covering approximately 4.2% of the genome. We use evolutionary signatures and comparisons with experimental data sets to suggest candidate functions for approximately 60% of constrained bases. These elements reveal a small number of new coding exons, candidate stop codon readthrough events and over 10,000 regions of overlapping synonymous constraint within protein-coding exons. We find 220 candidate RNA structural families, and nearly a million elements overlapping potential promoter, enhancer and insulator regions. We report specific amino acid residues that have undergone positive selection, 280,000 non-coding elements exapted from mobile elements and more than 1,000 primate- and human-accelerated elements. Overlap with disease-associated variants indicates that our findings will be relevant for studies of human biology, health and disease.
ESTHER : Lindblad-Toh_2011_Nature_478_476
PubMedSearch : Lindblad-Toh_2011_Nature_478_476
PubMedID: 21993624
Gene_locus related to this paper: cavpo-1plip , cavpo-2plrp , cavpo-h0v1b7 , cavpo-h0v5v8 , cavpo-h0vj36 , cavpo-lipli , rabit-1hlip , rabit-1plip , rabit-g1t6x7 , rabit-LIPH , myolu-l7n1c2 , myolu-g1pqd9 , cavpo-h0uyz6 , cavpo-h0vi56 , rabit-g1tbj4 , myolu-g1p5c0 , rabit-g1sds3 , rabit-g1sye0 , cavpo-h0v0r2 , cavpo-h0v7s5 , rabit-g1sp43 , myolu-g1p4p3 , cavpo-h0vw09 , rabit-g1ssu3 , myolu-g1pds0 , rabit-g1sic4 , cavpo-h0v2c4 , myolu-g1pg61 , myolu-g1pnb1 , myolu-g1pu06 , myolu-g1qa15 , myolu-g1qfu0 , rabit-g1sn99 , rabit-g1snq9 , rabit-g1sns7 , rabit-g1tuu8 , rabit-g1tzq7 , cavpo-h0v2i2 , cavpo-h0v2j0 , cavpo-h0vsf5 , cavpo-a0a286x8d3 , cavpo-a0a286xbr3 , cavpo-a0a286y0i8 , cavpo-a0a286y4p3 , myolu-g1q2n9 , cavpo-h0v1p4 , myolu-g1pan8 , myolu-g1paq0 , myolu-g1par4 , myolu-g1prn3 , myolu-g1q3i0 , myolu-g1q463 , myolu-g1pat6 , myolu-g1q859 , rabit-g1sul9 , rabit-g1sun0 , rabit-g1sup0 , myolu-l7n125 , myolu-g1pan2 , rabit-g1sxd0 , cavpo-h0v8j4 , rabit-d5fit0 , rabit-g1tkr5 , myolu-g1nty6 , myolu-g1p1p3 , cavpo-h0vdd5 , myolu-g1pdp2 , rabit-g1tmm5 , cavpo-h0vhq3 , myolu-g1nth4 , cavpo-h0vqx6 , rabit-g1tqr7 , myolu-g1p1e9 , cavpo-h0v8y6 , rabit-g1skt3 , myolu-g1nzg3 , cavpo-h0v5z0 , rabit-g1sgz5 , myolu-g1pkg5 , rabit-g1tmw5 , rabit-g1t134 , cavpo-a0a286x9v5 , myolu-g1qc57 , myolu-g1q061 , rabit-g1tnp4 , rabit-g1tyf7 , cavpo-h0w2w1 , rabit-g1ta36 , cavpo-h0w342 , myolu-g1q4e3 , rabit-g1sqa1 , cavpo-h0uxk7 , myolu-g1p353 , cavpo-h0vpm0 , rabit-a0a5f9cru6 , cavpo-a0a286xtc0

Title : The genome of the green anole lizard and a comparative analysis with birds and mammals - Alfoldi_2011_Nature_477_587
Author(s) : Alfoldi J , Di Palma F , Grabherr M , Williams C , Kong L , Mauceli E , Russell P , Lowe CB , Glor RE , Jaffe JD , Ray DA , Boissinot S , Shedlock AM , Botka C , Castoe TA , Colbourne JK , Fujita MK , Moreno RG , ten Hallers BF , Haussler D , Heger A , Heiman D , Janes DE , Johnson J , de Jong PJ , Koriabine MY , Lara M , Novick PA , Organ CL , Peach SE , Poe S , Pollock DD , de Queiroz K , Sanger T , Searle S , Smith JD , Smith Z , Swofford R , Turner-Maier J , Wade J , Young S , Zadissa A , Edwards SV , Glenn TC , Schneider CJ , Losos JB , Lander ES , Breen M , Ponting CP , Lindblad-Toh K
Ref : Nature , 477 :587 , 2011
Abstract : The evolution of the amniotic egg was one of the great evolutionary innovations in the history of life, freeing vertebrates from an obligatory connection to water and thus permitting the conquest of terrestrial environments. Among amniotes, genome sequences are available for mammals and birds, but not for non-avian reptiles. Here we report the genome sequence of the North American green anole lizard, Anolis carolinensis. We find that A. carolinensis microchromosomes are highly syntenic with chicken microchromosomes, yet do not exhibit the high GC and low repeat content that are characteristic of avian microchromosomes. Also, A. carolinensis mobile elements are very young and diverse-more so than in any other sequenced amniote genome. The GC content of this lizard genome is also unusual in its homogeneity, unlike the regionally variable GC content found in mammals and birds. We describe and assign sequence to the previously unknown A. carolinensis X chromosome. Comparative gene analysis shows that amniote egg proteins have evolved significantly more rapidly than other proteins. An anole phylogeny resolves basal branches to illuminate the history of their repeated adaptive radiations.
ESTHER : Alfoldi_2011_Nature_477_587
PubMedSearch : Alfoldi_2011_Nature_477_587
PubMedID: 21881562
Gene_locus related to this paper: anoca-h9g670 , anoca-h9g675 , anoca-h9g680 , anoca-h9gbf2 , anoca-h9gl37 , anoca-h9gq07 , anoca-h9gqa2 , anoca-h9gqv4 , anoca-h9gr08 , anoca-h9glr3 , anoca-h9gfq0 , anoca-h9gfy1 , anoca-h9g7n4 , anoca-h9gpa2 , anoca-h9g3p8

Title : Genomic analysis of the necrotrophic fungal pathogens Sclerotinia sclerotiorum and Botrytis cinerea - Amselem_2011_PLoS.Genet_7_e1002230
Author(s) : Amselem J , Cuomo CA , van Kan JA , Viaud M , Benito EP , Couloux A , Coutinho PM , de Vries RP , Dyer PS , Fillinger S , Fournier E , Gout L , Hahn M , Kohn L , Lapalu N , Plummer KM , Pradier JM , Quevillon E , Sharon A , Simon A , ten Have A , Tudzynski B , Tudzynski P , Wincker P , Andrew M , Anthouard V , Beever RE , Beffa R , Benoit I , Bouzid O , Brault B , Chen Z , Choquer M , Collemare J , Cotton P , Danchin EG , Da Silva C , Gautier A , Giraud C , Giraud T , Gonzalez C , Grossetete S , Guldener U , Henrissat B , Howlett BJ , Kodira C , Kretschmer M , Lappartient A , Leroch M , Levis C , Mauceli E , Neuveglise C , Oeser B , Pearson M , Poulain J , Poussereau N , Quesneville H , Rascle C , Schumacher J , Segurens B , Sexton A , Silva E , Sirven C , Soanes DM , Talbot NJ , Templeton M , Yandava C , Yarden O , Zeng Q , Rollins JA , Lebrun MH , Dickman M
Ref : PLoS Genet , 7 :e1002230 , 2011
Abstract : Sclerotinia sclerotiorum and Botrytis cinerea are closely related necrotrophic plant pathogenic fungi notable for their wide host ranges and environmental persistence. These attributes have made these species models for understanding the complexity of necrotrophic, broad host-range pathogenicity. Despite their similarities, the two species differ in mating behaviour and the ability to produce asexual spores. We have sequenced the genomes of one strain of S. sclerotiorum and two strains of B. cinerea. The comparative analysis of these genomes relative to one another and to other sequenced fungal genomes is provided here. Their 38-39 Mb genomes include 11,860-14,270 predicted genes, which share 83% amino acid identity on average between the two species. We have mapped the S. sclerotiorum assembly to 16 chromosomes and found large-scale co-linearity with the B. cinerea genomes. Seven percent of the S. sclerotiorum genome comprises transposable elements compared to <1% of B. cinerea. The arsenal of genes associated with necrotrophic processes is similar between the species, including genes involved in plant cell wall degradation and oxalic acid production. Analysis of secondary metabolism gene clusters revealed an expansion in number and diversity of B. cinerea-specific secondary metabolites relative to S. sclerotiorum. The potential diversity in secondary metabolism might be involved in adaptation to specific ecological niches. Comparative genome analysis revealed the basis of differing sexual mating compatibility systems between S. sclerotiorum and B. cinerea. The organization of the mating-type loci differs, and their structures provide evidence for the evolution of heterothallism from homothallism. These data shed light on the evolutionary and mechanistic bases of the genetically complex traits of necrotrophic pathogenicity and sexual mating. This resource should facilitate the functional studies designed to better understand what makes these fungi such successful and persistent pathogens of agronomic crops.
ESTHER : Amselem_2011_PLoS.Genet_7_e1002230
PubMedSearch : Amselem_2011_PLoS.Genet_7_e1002230
PubMedID: 21876677
Gene_locus related to this paper: botci-cutas , botci-q6rki2 , botf4-g2y7k8 , botfb-dapb , botfu-g2xyd8 , botfu-g2ynh8 , scls1-a7e814 , scls1-a7edc9 , scls1-a7edh1 , scls1-a7emm0 , scls1-a7eti8 , scls1-a7eu48 , scls1-a7f208 , scls1-dapb , botf4-g2xqp7 , scls1-a7eqq8 , botf4-g2xqc6 , scls1-a7ebs4 , botf4-g2xn51 , scls1-a7f5m9 , botf4-g2xti4 , botf4-g2xtu7 , botf4-g2yfp1 , scls1-a7f534 , botf4-g2yys3 , scls1-a7erz9 , botf4-g2y037 , botf4-g2y0e1 , scls1-a7f706 , scls1-a7ewt6 , botf4-g2yuj6 , botf1-m7u3d1 , botf1-m7u430 , botf1-m7tei8 , botf1-m7u0w9 , botf1-m7tij6 , botf1-m7u819 , botf1-m7u6d8 , botf1-m7tzd4 , botf1-m7tqd7 , botf1-m7tyz9 , botf1-m7unl9 , botf1-m7u429 , botf1-m7u4s5 , botf1-m7ul92 , botf1-m7tx42 , botf1-m7u9h4 , botf1-m7u187 , botf1-m7uz64 , botf1-m7u4q4 , botf1-m7u2f6 , botf1-m7tt59 , botf1-m7v3h2 , botf1-m7u6c9 , botf1-m7tud9 , botf1-m7u309 , scls1-a7et87 , botf4-g2ylt4 , scls1-a7f5a0 , scls1-a7f900 , botf4-g2yib9 , scls1-a7f3m9 , scls1-a7er46 , botf4-g2y3y4 , botf4-g2xyy5 , botf1-m7uct5 , scls1-a7ea78 , scls1-kex1 , scls1-cbpya , botfb-cbpya , scls1-a7ecx1

Title : Obligate biotrophy features unraveled by the genomic analysis of rust fungi - Duplessis_2011_Proc.Natl.Acad.Sci.U.S.A_108_9166
Author(s) : Duplessis S , Cuomo CA , Lin YC , Aerts A , Tisserant E , Veneault-Fourrey C , Joly DL , Hacquard S , Amselem J , Cantarel BL , Chiu R , Coutinho PM , Feau N , Field M , Frey P , Gelhaye E , Goldberg J , Grabherr MG , Kodira CD , Kohler A , Kues U , Lindquist EA , Lucas SM , Mago R , Mauceli E , Morin E , Murat C , Pangilinan JL , Park R , Pearson M , Quesneville H , Rouhier N , Sakthikumar S , Salamov AA , Schmutz J , Selles B , Shapiro H , Tanguay P , Tuskan GA , Henrissat B , Van de Peer Y , Rouze P , Ellis JG , Dodds PN , Schein JE , Zhong S , Hamelin RC , Grigoriev IV , Szabo LJ , Martin F
Ref : Proc Natl Acad Sci U S A , 108 :9166 , 2011
Abstract : Rust fungi are some of the most devastating pathogens of crop plants. They are obligate biotrophs, which extract nutrients only from living plant tissues and cannot grow apart from their hosts. Their lifestyle has slowed the dissection of molecular mechanisms underlying host invasion and avoidance or suppression of plant innate immunity. We sequenced the 101-Mb genome of Melampsora larici-populina, the causal agent of poplar leaf rust, and the 89-Mb genome of Puccinia graminis f. sp. tritici, the causal agent of wheat and barley stem rust. We then compared the 16,399 predicted proteins of M. larici-populina with the 17,773 predicted proteins of P. graminis f. sp tritici. Genomic features related to their obligate biotrophic lifestyle include expanded lineage-specific gene families, a large repertoire of effector-like small secreted proteins, impaired nitrogen and sulfur assimilation pathways, and expanded families of amino acid and oligopeptide membrane transporters. The dramatic up-regulation of transcripts coding for small secreted proteins, secreted hydrolytic enzymes, and transporters in planta suggests that they play a role in host infection and nutrient acquisition. Some of these genomic hallmarks are mirrored in the genomes of other microbial eukaryotes that have independently evolved to infect plants, indicating convergent adaptation to a biotrophic existence inside plant cells.
ESTHER : Duplessis_2011_Proc.Natl.Acad.Sci.U.S.A_108_9166
PubMedSearch : Duplessis_2011_Proc.Natl.Acad.Sci.U.S.A_108_9166
PubMedID: 21536894
Gene_locus related to this paper: pucgt-e3k840 , pucgt-e3kaq6 , pucgt-e3kw59 , pucgt-e3kz16 , pucgt-e3l9v6 , pucgt-e3l279 , pucgt-h6qt25 , mellp-f4reh4 , mellp-f4rhc8 , mellp-f4reh2 , mellp-f4r3y0 , mellp-f4rz15 , mellp-f4rz64 , mellp-f4rl14 , mellp-f4rz66 , mellp-f4s751 , mellp-f4s2g6 , pucgt-e3l1z7 , pucgt-e3l803 , pucgt-e3kst2 , pucgt-e3kst5 , mellp-f4ru03 , pucgt-e3l1z8 , pucgt-e3ktz7 , pucgt-e3jun4 , mellp-f4rl65 , mellp-f4rz16 , mellp-f4ru02 , mellp-f4sav4 , mellp-f4sav3 , mellp-f4s1j0 , mellp-f4rkp0 , mellp-f4s483 , pucgt-e3kzu5 , pucgt-h6qtq8 , mellp-f4r5l5 , pucgt-e3krw7 , pucgt-e3l7w5 , pucgt-e3k2w6 , pucgt-e3kfg2 , pucgt-kex1

Title : Genome sequence, comparative analysis, and population genetics of the domestic horse - Wade_2009_Science_326_865
Author(s) : Wade CM , Giulotto E , Sigurdsson S , Zoli M , Gnerre S , Imsland F , Lear TL , Adelson DL , Bailey E , Bellone RR , Blocker H , Distl O , Edgar RC , Garber M , Leeb T , Mauceli E , MacLeod JN , Penedo MC , Raison JM , Sharpe T , Vogel J , Andersson L , Antczak DF , Biagi T , Binns MM , Chowdhary BP , Coleman SJ , Della Valle G , Fryc S , Guerin G , Hasegawa T , Hill EW , Jurka J , Kiialainen A , Lindgren G , Liu J , Magnani E , Mickelson JR , Murray J , Nergadze SG , Onofrio R , Pedroni S , Piras MF , Raudsepp T , Rocchi M , Roed KH , Ryder OA , Searle S , Skow L , Swinburne JE , Syvanen AC , Tozaki T , Valberg SJ , Vaudin M , White JR , Zody MC , Lander ES , Lindblad-Toh K
Ref : Science , 326 :865 , 2009
Abstract : We report a high-quality draft sequence of the genome of the horse (Equus caballus). The genome is relatively repetitive but has little segmental duplication. Chromosomes appear to have undergone few historical rearrangements: 53% of equine chromosomes show conserved synteny to a single human chromosome. Equine chromosome 11 is shown to have an evolutionary new centromere devoid of centromeric satellite DNA, suggesting that centromeric function may arise before satellite repeat accumulation. Linkage disequilibrium, showing the influences of early domestication of large herds of female horses, is intermediate in length between dog and human, and there is long-range haplotype sharing among breeds.
ESTHER : Wade_2009_Science_326_865
PubMedSearch : Wade_2009_Science_326_865
PubMedID: 19892987
Gene_locus related to this paper: horse-1plip , horse-2plrp , horse-ACHE , horse-BCHE , horse-f6pri5 , horse-f6qlk6 , horse-f6qsc5 , horse-f6r958 , horse-f6sfg0 , horse-f6uif6 , horse-f6un85 , horse-f6vxp7 , horse-f6wfs9 , horse-f6wzv8 , horse-f6x0i7 , horse-f6x5e5 , horse-f6zmg7 , horse-f7afw6 , horse-f7agv7 , horse-f7bj10 , horse-f7bk45 , horse-f7bvl6 , horse-f7c7a8 , horse-f7cdt1 , horse-f7cxj0 , horse-f6ut17 , horse-f6svq9 , horse-f6xgj6 , horse-f6s101 , horse-f6wfa7 , horse-f7cpx3 , horse-f7adj7 , horse-f6r609 , horse-f6y0j2 , horse-f6zvb2 , horse-f7e4g0 , horse-f6ti02 , horse-f6re01 , horse-f6xmp6 , horse-f6vts1 , horse-f6quf7 , horse-f6tn81 , horse-f7bm46 , horse-f6q1u3 , horse-f6zna7 , horse-f6q208 , horse-f7cuh0 , horse-f6tq73 , horse-f6xa70 , horse-f6qj19 , horse-f6wgf3 , horse-f7d8t6 , horse-f6ul42 , horse-f7am73 , horse-f7dme2

Title : Genome of the marsupial Monodelphis domestica reveals innovation in non-coding sequences - Mikkelsen_2007_Nature_447_167
Author(s) : Mikkelsen TS , Wakefield MJ , Aken B , Amemiya CT , Chang JL , Duke S , Garber M , Gentles AJ , Goodstadt L , Heger A , Jurka J , Kamal M , Mauceli E , Searle SM , Sharpe T , Baker ML , Batzer MA , Benos PV , Belov K , Clamp M , Cook A , Cuff J , Das R , Davidow L , Deakin JE , Fazzari MJ , Glass JL , Grabherr M , Greally JM , Gu W , Hore TA , Huttley GA , Kleber M , Jirtle RL , Koina E , Lee JT , Mahony S , Marra MA , Miller RD , Nicholls RD , Oda M , Papenfuss AT , Parra ZE , Pollock DD , Ray DA , Schein JE , Speed TP , Thompson K , Vandeberg JL , Wade CM , Walker JA , Waters PD , Webber C , Weidman JR , Xie X , Zody MC , Graves JA , Ponting CP , Breen M , Samollow PB , Lander ES , Lindblad-Toh K
Ref : Nature , 447 :167 , 2007
Abstract : We report a high-quality draft of the genome sequence of the grey, short-tailed opossum (Monodelphis domestica). As the first metatherian ('marsupial') species to be sequenced, the opossum provides a unique perspective on the organization and evolution of mammalian genomes. Distinctive features of the opossum chromosomes provide support for recent theories about genome evolution and function, including a strong influence of biased gene conversion on nucleotide sequence composition, and a relationship between chromosomal characteristics and X chromosome inactivation. Comparison of opossum and eutherian genomes also reveals a sharp difference in evolutionary innovation between protein-coding and non-coding functional elements. True innovation in protein-coding genes seems to be relatively rare, with lineage-specific differences being largely due to diversification and rapid turnover in gene families involved in environmental interactions. In contrast, about 20% of eutherian conserved non-coding elements (CNEs) are recent inventions that postdate the divergence of Eutheria and Metatheria. A substantial proportion of these eutherian-specific CNEs arose from sequence inserted by transposable elements, pointing to transposons as a major creative force in the evolution of mammalian gene regulation.
ESTHER : Mikkelsen_2007_Nature_447_167
PubMedSearch : Mikkelsen_2007_Nature_447_167
PubMedID: 17495919
Gene_locus related to this paper: mondo-ACHE , mondo-b2bsf5 , mondo-b2bsz5 , mondo-BCHE , mondo-d2x2i6 , mondo-d2x2i8 , mondo-f6slk2 , mondo-f6wu00 , mondo-f6wuf2 , mondo-f6xfj4 , mondo-f6yt13 , mondo-f7c7p0 , mondo-f7ckd0 , mondo-f7cvq8 , mondo-f7cvr5 , mondo-f7eil6 , mondo-f7ez13 , mondo-f7f0i7 , mondo-f7fg16 , mondo-f7gcv7 , mondo-f7gep4 , mondo-f7gly2 , mondo-f6u7q2 , mondo-f7fw54 , mondo-f7dpf6 , mondo-f6pgj5 , mondo-f6yg68 , mondo-f7g8u4 , mondo-f7eyv1 , mondo-f6pq73 , mondo-f7cre0 , mondo-f7fdj0 , mondo-f7fdj5 , mondo-f7ft63 , mondo-f7ge99 , mondo-f7gea2 , mondo-f6pxq2 , mondo-f7awc1 , mondo-f7c412 , mondo-f7ev24 , mondo-f7b6s6 , mondo-f6vcx0 , mondo-f7g148 , mondo-f6tlv9 , mondo-f6tdm5 , mondo-f7f3w0 , mondo-f7fg39 , mondo-f7d6c2 , mondo-f6sdn0 , mondo-f7gi08 , mondo-f6xss6 , mondo-f6sa37 , mondo-f7gd97 , mondo-f6z6x9

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 : The Fusarium graminearum genome reveals a link between localized polymorphism and pathogen specialization - Cuomo_2007_Science_317_1400
Author(s) : Cuomo CA , Guldener U , Xu JR , Trail F , Turgeon BG , Di Pietro A , Walton JD , Ma LJ , Baker SE , Rep M , Adam G , Antoniw J , Baldwin T , Calvo S , Chang YL , Decaprio D , Gale LR , Gnerre S , Goswami RS , Hammond-Kosack K , Harris LJ , Hilburn K , Kennell JC , Kroken S , Magnuson JK , Mannhaupt G , Mauceli E , Mewes HW , Mitterbauer R , Muehlbauer G , Munsterkotter M , Nelson D , O'Donnell K , Ouellet T , Qi W , Quesneville H , Roncero MI , Seong KY , Tetko IV , Urban M , Waalwijk C , Ward TJ , Yao J , Birren BW , Kistler HC
Ref : Science , 317 :1400 , 2007
Abstract : We sequenced and annotated the genome of the filamentous fungus Fusarium graminearum, a major pathogen of cultivated cereals. Very few repetitive sequences were detected, and the process of repeat-induced point mutation, in which duplicated sequences are subject to extensive mutation, may partially account for the reduced repeat content and apparent low number of paralogous (ancestrally duplicated) genes. A second strain of F. graminearum contained more than 10,000 single-nucleotide polymorphisms, which were frequently located near telomeres and within other discrete chromosomal segments. Many highly polymorphic regions contained sets of genes implicated in plant-fungus interactions and were unusually divergent, with higher rates of recombination. These regions of genome innovation may result from selection due to interactions of F. graminearum with its plant hosts.
ESTHER : Cuomo_2007_Science_317_1400
PubMedSearch : Cuomo_2007_Science_317_1400
PubMedID: 17823352
Gene_locus related to this paper: fusof-f9fxz4 , gibze-a8w610 , gibze-b1pdn0 , gibze-i1r9e6 , gibze-i1rda9 , gibze-i1rdk7 , gibze-i1rec8 , gibze-i1rgs0 , gibze-i1rgy0 , gibze-i1rh52 , gibze-i1rhi8 , gibze-i1rig9 , gibze-i1rip5 , gibze-i1rpg6 , gibze-i1rsg2 , gibze-i1rv36 , gibze-i1rxm5 , gibze-i1rxp8 , gibze-i1rxv5 , gibze-i1s1u3 , gibze-i1s3j9 , gibze-i1s6l7 , gibze-i1s8i8 , gibze-i1s9x4 , gibze-ppme1 , gibze-q4huy1 , gibze-i1rg17 , gibze-i1rb76 , gibze-i1s1m7 , gibze-i1s3z6 , gibze-i1rd78 , gibze-i1rgl9 , gibze-i1rjp7 , gibze-i1s1q6 , gibze-i1ri35 , gibze-i1rf76 , gibze-i1rhp3 , gibza-a0a016pda4 , gibza-a0a016pl96 , gibze-i1rjb5 , gibze-i1rkc4 , gibze-a0a1c3ylb1 , gibze-gra11 , gibze-fsl2

Title : Genome sequence of Aedes aegypti, a major arbovirus vector - Nene_2007_Science_316_1718
Author(s) : Nene V , Wortman JR , Lawson D , Haas B , Kodira C , Tu ZJ , Loftus B , Xi Z , Megy K , Grabherr M , Ren Q , Zdobnov EM , Lobo NF , Campbell KS , Brown SE , Bonaldo MF , Zhu J , Sinkins SP , Hogenkamp DG , Amedeo P , Arensburger P , Atkinson PW , Bidwell S , Biedler J , Birney E , Bruggner RV , Costas J , Coy MR , Crabtree J , Crawford M , Debruyn B , Decaprio D , Eiglmeier K , Eisenstadt E , El-Dorry H , Gelbart WM , Gomes SL , Hammond M , Hannick LI , Hogan JR , Holmes MH , Jaffe D , Johnston JS , Kennedy RC , Koo H , Kravitz S , Kriventseva EV , Kulp D , LaButti K , Lee E , Li S , Lovin DD , Mao C , Mauceli E , Menck CF , Miller JR , Montgomery P , Mori A , Nascimento AL , Naveira HF , Nusbaum C , O'Leary S , Orvis J , Pertea M , Quesneville H , Reidenbach KR , Rogers YH , Roth CW , Schneider JR , Schatz M , Shumway M , Stanke M , Stinson EO , Tubio JM , Vanzee JP , Verjovski-Almeida S , Werner D , White O , Wyder S , Zeng Q , Zhao Q , Zhao Y , Hill CA , Raikhel AS , Soares MB , Knudson DL , Lee NH , Galagan J , Salzberg SL , Paulsen IT , Dimopoulos G , Collins FH , Birren B , Fraser-Liggett CM , Severson DW
Ref : Science , 316 :1718 , 2007
Abstract : We present a draft sequence of the genome of Aedes aegypti, the primary vector for yellow fever and dengue fever, which at approximately 1376 million base pairs is about 5 times the size of the genome of the malaria vector Anopheles gambiae. Nearly 50% of the Ae. aegypti genome consists of transposable elements. These contribute to a factor of approximately 4 to 6 increase in average gene length and in sizes of intergenic regions relative to An. gambiae and Drosophila melanogaster. Nonetheless, chromosomal synteny is generally maintained among all three insects, although conservation of orthologous gene order is higher (by a factor of approximately 2) between the mosquito species than between either of them and the fruit fly. An increase in genes encoding odorant binding, cytochrome P450, and cuticle domains relative to An. gambiae suggests that members of these protein families underpin some of the biological differences between the two mosquito species.
ESTHER : Nene_2007_Science_316_1718
PubMedSearch : Nene_2007_Science_316_1718
PubMedID: 17510324
Gene_locus related to this paper: aedae-ACHE , aedae-ACHE1 , aedae-glita , aedae-q0iea6 , aedae-q0iev6 , aedae-q0ifn6 , aedae-q0ifn8 , aedae-q0ifn9 , aedae-q0ifp0 , aedae-q0ig41 , aedae-q1dgl0 , aedae-q1dh03 , aedae-q1dh19 , aedae-q1hqe6 , aedae-Q8ITU8 , aedae-Q8MMJ6 , aedae-Q8T9V6 , aedae-q16e91 , aedae-q16f04 , aedae-q16f25 , aedae-q16f26 , aedae-q16f28 , aedae-q16f29 , aedae-q16f30 , aedae-q16gq5 , aedae-q16iq5 , aedae-q16je0 , aedae-q16je1 , aedae-q16je2 , aedae-q16ks8 , aedae-q16lf2 , aedae-q16lv6 , aedae-q16m61 , aedae-q16mc1 , aedae-q16mc6 , aedae-q16mc7 , aedae-q16md1 , aedae-q16ms7 , aedae-q16nk5 , aedae-q16rl5 , aedae-q16rz9 , aedae-q16si8 , aedae-q16t49 , aedae-q16wf1 , aedae-q16x18 , aedae-q16xp8 , aedae-q16xu6 , aedae-q16xw5 , aedae-q16xw6 , aedae-q16y04 , aedae-q16y05 , aedae-q16y06 , aedae-q16y07 , aedae-q16y39 , aedae-q16y40 , aedae-q16yg4 , aedae-q16z03 , aedae-q17aa7 , aedae-q17av1 , aedae-q17av2 , aedae-q17av3 , aedae-q17av4 , aedae-q17b28 , aedae-q17b29 , aedae-q17b30 , aedae-q17b31 , aedae-q17b32 , aedae-q17bm3 , aedae-q17bm4 , aedae-q17bv7 , aedae-q17c44 , aedae-q17cz1 , aedae-q17d32 , aedae-q17g39 , aedae-q17g40 , aedae-q17g41 , aedae-q17g42 , aedae-q17g43 , aedae-q17g44 , aedae-q17gb8 , aedae-q17gr3 , aedae-q17if7 , aedae-q17if9 , aedae-q17ig1 , aedae-q17ig2 , aedae-q17is4 , aedae-q17l09 , aedae-q17m26 , aedae-q17mg9 , aedae-q17mv4 , aedae-q17mv5 , aedae-q17mv6 , aedae-q17mv7 , aedae-q17mw8 , aedae-q17mw9 , aedae-q17nw5 , aedae-q17nx5 , aedae-q17pa4 , aedae-q17q69 , aedae-q170k7 , aedae-q171y4 , aedae-q172e0 , aedae-q176i8 , aedae-q176j0 , aedae-q177k1 , aedae-q177k2 , aedae-q177l9 , aedae-j9hic3 , aedae-q179r9 , aedae-u483 , aedae-j9hj23 , aedae-q17d68 , aedae-q177c7 , aedae-q0ifp1 , aedae-a0a1s4fx83 , aedae-a0a1s4g2m0 , aedae-q1hr49

Title : DNA sequence of human chromosome 17 and analysis of rearrangement in the human lineage - Zody_2006_Nature_440_1045
Author(s) : Zody MC , Garber M , Adams DJ , Sharpe T , Harrow J , Lupski JR , Nicholson C , Searle SM , Wilming L , Young SK , Abouelleil A , Allen NR , Bi W , Bloom T , Borowsky ML , Bugalter BE , Butler J , Chang JL , Chen CK , Cook A , Corum B , Cuomo CA , de Jong PJ , Decaprio D , Dewar K , FitzGerald M , Gilbert J , Gibson R , Gnerre S , Goldstein S , Grafham DV , Grocock R , Hafez N , Hagopian DS , Hart E , Norman CH , Humphray S , Jaffe DB , Jones M , Kamal M , Khodiyar VK , LaButti K , Laird G , Lehoczky J , Liu X , Lokyitsang T , Loveland J , Lui A , Macdonald P , Major JE , Matthews L , Mauceli E , McCarroll SA , Mihalev AH , Mudge J , Nguyen C , Nicol R , O'Leary SB , Osoegawa K , Schwartz DC , Shaw-Smith C , Stankiewicz P , Steward C , Swarbreck D , Venkataraman V , Whittaker CA , Yang X , Zimmer AR , Bradley A , Hubbard T , Birren BW , Rogers J , Lander ES , Nusbaum C
Ref : Nature , 440 :1045 , 2006
Abstract : Chromosome 17 is unusual among the human chromosomes in many respects. It is the largest human autosome with orthology to only a single mouse chromosome, mapping entirely to the distal half of mouse chromosome 11. Chromosome 17 is rich in protein-coding genes, having the second highest gene density in the genome. It is also enriched in segmental duplications, ranking third in density among the autosomes. Here we report a finished sequence for human chromosome 17, as well as a structural comparison with the finished sequence for mouse chromosome 11, the first finished mouse chromosome. Comparison of the orthologous regions reveals striking differences. In contrast to the typical pattern seen in mammalian evolution, the human sequence has undergone extensive intrachromosomal rearrangement, whereas the mouse sequence has been remarkably stable. Moreover, although the human sequence has a high density of segmental duplication, the mouse sequence has a very low density. Notably, these segmental duplications correspond closely to the sites of structural rearrangement, demonstrating a link between duplication and rearrangement. Examination of the main classes of duplicated segments provides insight into the dynamics underlying expansion of chromosome-specific, low-copy repeats in the human genome.
ESTHER : Zody_2006_Nature_440_1045
PubMedSearch : Zody_2006_Nature_440_1045
PubMedID: 16625196
Gene_locus related to this paper: human-NLGN2 , human-NOTUM

Title : Analysis of the DNA sequence and duplication history of human chromosome 15 - Zody_2006_Nature_440_671
Author(s) : Zody MC , Garber M , Sharpe T , Young SK , Rowen L , O'Neill K , Whittaker CA , Kamal M , Chang JL , Cuomo CA , Dewar K , Fitzgerald MG , Kodira CD , Madan A , Qin S , Yang X , Abbasi N , Abouelleil A , Arachchi HM , Baradarani L , Birditt B , Bloom S , Bloom T , Borowsky ML , Burke J , Butler J , Cook A , DeArellano K , Decaprio D , Dorris L, 3rd , Dors M , Eichler EE , Engels R , Fahey J , Fleetwood P , Friedman C , Gearin G , Hall JL , Hensley G , Johnson E , Jones C , Kamat A , Kaur A , Locke DP , Munson G , Jaffe DB , Lui A , Macdonald P , Mauceli E , Naylor JW , Nesbitt R , Nicol R , O'Leary SB , Ratcliffe A , Rounsley S , She X , Sneddon KM , Stewart S , Sougnez C , Stone SM , Topham K , Vincent D , Wang S , Zimmer AR , Birren BW , Hood L , Lander ES , Nusbaum C
Ref : Nature , 440 :671 , 2006
Abstract : Here we present a finished sequence of human chromosome 15, together with a high-quality gene catalogue. As chromosome 15 is one of seven human chromosomes with a high rate of segmental duplication, we have carried out a detailed analysis of the duplication structure of the chromosome. Segmental duplications in chromosome 15 are largely clustered in two regions, on proximal and distal 15q; the proximal region is notable because recombination among the segmental duplications can result in deletions causing Prader-Willi and Angelman syndromes. Sequence analysis shows that the proximal and distal regions of 15q share extensive ancient similarity. Using a simple approach, we have been able to reconstruct many of the events by which the current duplication structure arose. We find that most of the intrachromosomal duplications seem to share a common ancestry. Finally, we demonstrate that some remaining gaps in the genome sequence are probably due to structural polymorphisms between haplotypes; this may explain a significant fraction of the gaps remaining in the human genome.
ESTHER : Zody_2006_Nature_440_671
PubMedSearch : Zody_2006_Nature_440_671
PubMedID: 16572171
Gene_locus related to this paper: human-DPP8 , human-LIPC , human-SPG21

Title : DNA sequence and analysis of human chromosome 8 - Nusbaum_2006_Nature_439_331
Author(s) : Nusbaum C , Mikkelsen TS , Zody MC , Asakawa S , Taudien S , Garber M , Kodira CD , Schueler MG , Shimizu A , Whittaker CA , Chang JL , Cuomo CA , Dewar K , Fitzgerald MG , Yang X , Allen NR , Anderson S , Asakawa T , Blechschmidt K , Bloom T , Borowsky ML , Butler J , Cook A , Corum B , DeArellano K , Decaprio D , Dooley KT , Dorris L, 3rd , Engels R , Glockner G , Hafez N , Hagopian DS , Hall JL , Ishikawa SK , Jaffe DB , Kamat A , Kudoh J , Lehmann R , Lokitsang T , Macdonald P , Major JE , Matthews CD , Mauceli E , Menzel U , Mihalev AH , Minoshima S , Murayama Y , Naylor JW , Nicol R , Nguyen C , O'Leary SB , O'Neill K , Parker SC , Polley A , Raymond CK , Reichwald K , Rodriguez J , Sasaki T , Schilhabel M , Siddiqui R , Smith CL , Sneddon TP , Talamas JA , Tenzin P , Topham K , Venkataraman V , Wen G , Yamazaki S , Young SK , Zeng Q , Zimmer AR , Rosenthal A , Birren BW , Platzer M , Shimizu N , Lander ES
Ref : Nature , 439 :331 , 2006
Abstract : The International Human Genome Sequencing Consortium (IHGSC) recently completed a sequence of the human genome. As part of this project, we have focused on chromosome 8. Although some chromosomes exhibit extreme characteristics in terms of length, gene content, repeat content and fraction segmentally duplicated, chromosome 8 is distinctly typical in character, being very close to the genome median in each of these aspects. This work describes a finished sequence and gene catalogue for the chromosome, which represents just over 5% of the euchromatic human genome. A unique feature of the chromosome is a vast region of approximately 15 megabases on distal 8p that appears to have a strikingly high mutation rate, which has accelerated in the hominids relative to other sequenced mammals. This fast-evolving region contains a number of genes related to innate immunity and the nervous system, including loci that appear to be under positive selection--these include the major defensin (DEF) gene cluster and MCPH1, a gene that may have contributed to the evolution of expanded brain size in the great apes. The data from chromosome 8 should allow a better understanding of both normal and disease biology and genome evolution.
ESTHER : Nusbaum_2006_Nature_439_331
PubMedSearch : Nusbaum_2006_Nature_439_331
PubMedID: 16421571
Gene_locus related to this paper: human-TG

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 : DNA sequence and analysis of human chromosome 18 - Nusbaum_2005_Nature_437_551
Author(s) : Nusbaum C , Zody MC , Borowsky ML , Kamal M , Kodira CD , Taylor TD , Whittaker CA , Chang JL , Cuomo CA , Dewar K , Fitzgerald MG , Yang X , Abouelleil A , Allen NR , Anderson S , Bloom T , Bugalter B , Butler J , Cook A , Decaprio D , Engels R , Garber M , Gnirke A , Hafez N , Hall JL , Norman CH , Itoh T , Jaffe DB , Kuroki Y , Lehoczky J , Lui A , Macdonald P , Mauceli E , Mikkelsen TS , Naylor JW , Nicol R , Nguyen C , Noguchi H , O'Leary SB , O'Neill K , Piqani B , Smith CL , Talamas JA , Topham K , Totoki Y , Toyoda A , Wain HM , Young SK , Zeng Q , Zimmer AR , Fujiyama A , Hattori M , Birren BW , Sakaki Y , Lander ES
Ref : Nature , 437 :551 , 2005
Abstract : Chromosome 18 appears to have the lowest gene density of any human chromosome and is one of only three chromosomes for which trisomic individuals survive to term. There are also a number of genetic disorders stemming from chromosome 18 trisomy and aneuploidy. Here we report the finished sequence and gene annotation of human chromosome 18, which will allow a better understanding of the normal and disease biology of this chromosome. Despite the low density of protein-coding genes on chromosome 18, we find that the proportion of non-protein-coding sequences evolutionarily conserved among mammals is close to the genome-wide average. Extending this analysis to the entire human genome, we find that the density of conserved non-protein-coding sequences is largely uncorrelated with gene density. This has important implications for the nature and roles of non-protein-coding sequence elements.
ESTHER : Nusbaum_2005_Nature_437_551
PubMedSearch : Nusbaum_2005_Nature_437_551
PubMedID: 16177791
Gene_locus related to this paper: human-LIPG

Title : Genome duplication in the teleost fish Tetraodon nigroviridis reveals the early vertebrate proto-karyotype - Jaillon_2004_Nature_431_946
Author(s) : Jaillon O , Aury JM , Brunet F , Petit JL , Stange-Thomann N , Mauceli E , Bouneau L , Fischer C , Ozouf-Costaz C , Bernot A , Nicaud S , Jaffe D , Fisher S , Lutfalla G , Dossat C , Segurens B , Dasilva C , Salanoubat M , Levy M , Boudet N , Castellano S , Anthouard V , Jubin C , Castelli V , Katinka M , Vacherie B , Biemont C , Skalli Z , Cattolico L , Poulain J , de Berardinis V , Cruaud C , Duprat S , Brottier P , Coutanceau JP , Gouzy J , Parra G , Lardier G , Chapple C , McKernan KJ , McEwan P , Bosak S , Kellis M , Volff JN , Guigo R , Zody MC , Mesirov J , Lindblad-Toh K , Birren B , Nusbaum C , Kahn D , Robinson-Rechavi M , Laudet V , Schachter V , Quetier F , Saurin W , Scarpelli C , Wincker P , Lander ES , Weissenbach J , Roest Crollius H
Ref : Nature , 431 :946 , 2004
Abstract : Tetraodon nigroviridis is a freshwater puffer fish with the smallest known vertebrate genome. Here, we report a draft genome sequence with long-range linkage and substantial anchoring to the 21 Tetraodon chromosomes. Genome analysis provides a greatly improved fish gene catalogue, including identifying key genes previously thought to be absent in fish. Comparison with other vertebrates and a urochordate indicates that fish proteins have diverged markedly faster than their mammalian homologues. Comparison with the human genome suggests approximately 900 previously unannotated human genes. Analysis of the Tetraodon and human genomes shows that whole-genome duplication occurred in the teleost fish lineage, subsequent to its divergence from mammals. The analysis also makes it possible to infer the basic structure of the ancestral bony vertebrate genome, which was composed of 12 chromosomes, and to reconstruct much of the evolutionary history of ancient and recent chromosome rearrangements leading to the modern human karyotype.
ESTHER : Jaillon_2004_Nature_431_946
PubMedSearch : Jaillon_2004_Nature_431_946
PubMedID: 15496914
Gene_locus related to this paper: tetng-3neur , tetng-4neur , tetng-ACHE , tetng-BCHE , tetng-h3cfz4 , tetng-h3ci57 , tetng-h3cl30 , tetng-h3cnh2 , tetng-nlgn2b , tetng-h3czr1 , tetng-h3dbr5 , tetng-nlgn2a , tetng-nlgn3b , tetng-q4ref8 , tetng-q4rjp3 , tetng-q4rjy3 , tetng-q4rk53 , tetng-q4rk63 , tetng-q4rk66 , tetng-q4rkk3 , tetng-q4rli3 , tetng-q4rn09 , tetng-q4rqj4 , tetng-q4rqz6 , tetng-q4rr22 , tetng-q4rru9 , tetng-q4rtq6 , tetng-q4rvf8 , tetng-q4rwa0 , tetng-q4rx90 , tetng-q4ryv8 , tetng-q4ryz3 , tetng-q4s0h8 , tetng-q4s5x0 , tetng-q4s6r1 , tetng-q4s6t6 , tetng-q4s7e3 , tetng-q4s7x6 , tetng-q4s8t5 , tetng-q4s9w9 , tetng-q4s050 , tetng-q4s091 , tetng-q4s144 , tetng-q4s309 , tetng-q4s578 , tetng-q4sal4 , tetng-q4sbm6 , tetng-q4sbp0 , tetng-q4sbu0 , tetng-q4sd49 , tetng-q4ser6 , tetng-q4sfm7 , tetng-q4sgm5 , tetng-q4sgv2 , tetng-q4sh74 , tetng-q4shl7 , tetng-q4si60 , tetng-q4sie5 , tetng-q4sku6 , tetng-q4smu0 , tetng-q4smy3 , tetng-q4snp0 , tetng-q4snq3 , tetng-q4spa7 , tetng-q4spq0 , tetng-q4sqr3 , tetng-q4sty0 , tetng-q4suu2 , tetng-q4suz1 , tetng-q4sxh3 , tetng-q4syn6 , tetng-q4szk0 , tetng-q4szy0 , tetng-q4t3m9 , tetng-q4t4a1 , tetng-q4t6m1 , tetng-q4t7r6 , tetng-q4t173 , tetng-q4t826 , tetng-q4t920 , tetng-q4ta33 , tetng-q4tab8 , tetng-q4tb62 , tetng-q4tbe2 , tetng-h3dbw2 , tetng-h3cpc8 , tetng-h3cjy0 , tetng-h3d966 , tetng-h3d3e3 , tetng-h3d961 , tetng-h3ctg6 , tetng-h3dde8 , tetng-h3dde9 , tetng-h3det9 , tetng-h3cre8 , tetng-h3dfb4 , tetng-h3clj8

Title : The genome sequence of the filamentous fungus Neurospora crassa - Galagan_2003_Nature_422_859
Author(s) : Galagan JE , Calvo SE , Borkovich KA , Selker EU , Read ND , Jaffe D , FitzHugh W , Ma LJ , Smirnov S , Purcell S , Rehman B , Elkins T , Engels R , Wang S , Nielsen CB , Butler J , Endrizzi M , Qui D , Ianakiev P , Bell-Pedersen D , Nelson MA , Werner-Washburne M , Selitrennikoff CP , Kinsey JA , Braun EL , Zelter A , Schulte U , Kothe GO , Jedd G , Mewes W , Staben C , Marcotte E , Greenberg D , Roy A , Foley K , Naylor J , Stange-Thomann N , Barrett R , Gnerre S , Kamal M , Kamvysselis M , Mauceli E , Bielke C , Rudd S , Frishman D , Krystofova S , Rasmussen C , Metzenberg RL , Perkins DD , Kroken S , Cogoni C , Macino G , Catcheside D , Li W , Pratt RJ , Osmani SA , DeSouza CP , Glass L , Orbach MJ , Berglund JA , Voelker R , Yarden O , Plamann M , Seiler S , Dunlap J , Radford A , Aramayo R , Natvig DO , Alex LA , Mannhaupt G , Ebbole DJ , Freitag M , Paulsen I , Sachs MS , Lander ES , Nusbaum C , Birren B
Ref : Nature , 422 :859 , 2003
Abstract : Neurospora crassa is a central organism in the history of twentieth-century genetics, biochemistry and molecular biology. Here, we report a high-quality draft sequence of the N. crassa genome. The approximately 40-megabase genome encodes about 10,000 protein-coding genes--more than twice as many as in the fission yeast Schizosaccharomyces pombe and only about 25% fewer than in the fruitfly Drosophila melanogaster. Analysis of the gene set yields insights into unexpected aspects of Neurospora biology including the identification of genes potentially associated with red light photobiology, genes implicated in secondary metabolism, and important differences in Ca2+ signalling as compared with plants and animals. Neurospora possesses the widest array of genome defence mechanisms known for any eukaryotic organism, including a process unique to fungi called repeat-induced point mutation (RIP). Genome analysis suggests that RIP has had a profound impact on genome evolution, greatly slowing the creation of new genes through genomic duplication and resulting in a genome with an unusually low proportion of closely related genes.
ESTHER : Galagan_2003_Nature_422_859
PubMedSearch : Galagan_2003_Nature_422_859
PubMedID: 12712197
Gene_locus related to this paper: neucr-5E6.090 , neucr-64C2.080 , neucr-90C4.300 , neucr-a7uw78 , neucr-a7uwh6 , neucr-a7uwy7 , neucr-apth1 , neucr-ATG15 , neucr-B7H23.190 , neucr-B11O8.160 , neucr-B13B3.090 , neucr-B14D6.130 , neucr-B18E6.050 , neucr-B19A17.360 , neucr-B23G1.090 , neucr-CBPYA , neucr-MET5 , neucr-NCU00292.1 , neucr-NCU00350.1 , neucr-NCU00536.1 , neucr-NCU00825.1 , neucr-NCU02148.1 , neucr-NCU02679.1 , neucr-NCU02904.1 , neucr-NCU02924.1 , neucr-NCU03158.1 , neucr-NCU04930.1 , neucr-NCU06332.1 , neucr-NCU06573.1 , neucr-NCU07081.1 , neucr-NCU07415.1 , neucr-NCU07909.1 , neucr-NCU08752.1 , neucr-NCU09575.1 , neucr-NCU10022.1 , neucr-ppme1 , neucr-q6mfs7 , neucr-q7rxb4 , neucr-q7rxv5 , neucr-q7ry06 , neucr-q7ryd2 , neucr-q7rzk2 , neucr-q7s0g7 , neucr-q7s1x0 , neucr-q7s2b3 , neucr-q7s2c5 , neucr-q7s2p4 , neucr-q7s2u9 , neucr-q7s3c6 , neucr-q7s3c8 , neucr-q7s3m2 , neucr-q7s4e3 , neucr-q7s4f8 , neucr-q7s4j4 , neucr-q7s5d6 , neucr-q7s5m2 , neucr-q7s5v8 , neucr-q7s6c5 , neucr-q7s8h2 , neucr-q7s070 , neucr-q7s082 , neucr-q7s134 , neucr-q7s216 , neucr-q7s259 , neucr-q7s260 , neucr-q7s283 , neucr-q7s512 , neucr-q7s736 , neucr-q7s828 , neucr-q7s897 , neucr-q7sbf9 , neucr-q7sbn0 , neucr-q7scr4 , neucr-q7sdw5 , neucr-q7sdx9 , neucr-q7se51 , neucr-q7sea3 , neucr-q7sez8 , neucr-q7sff7 , neucr-q7sga3 , neucr-q7sgj0 , neucr-q7sgp3 , neucr-q7sha3 , neucr-q7sha5 , neucr-q7shu8 , neucr-q9p6a7 , neucr-q872l1 , neucr-f5hbr2 , neucr-q7ry64