Schein JE

References (9)

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 : The genome sequence of taurine cattle: a window to ruminant biology and evolution - Elsik_2009_Science_324_522
Author(s) : Elsik CG , Tellam RL , Worley KC , Gibbs RA , Muzny DM , Weinstock GM , Adelson DL , Eichler EE , Elnitski L , Guigo R , Hamernik DL , Kappes SM , Lewin HA , Lynn DJ , Nicholas FW , Reymond A , Rijnkels M , Skow LC , Zdobnov EM , Schook L , Womack J , Alioto T , Antonarakis SE , Astashyn A , Chapple CE , Chen HC , Chrast J , Camara F , Ermolaeva O , Henrichsen CN , Hlavina W , Kapustin Y , Kiryutin B , Kitts P , Kokocinski F , Landrum M , Maglott D , Pruitt K , Sapojnikov V , Searle SM , Solovyev V , Souvorov A , Ucla C , Wyss C , Anzola JM , Gerlach D , Elhaik E , Graur D , Reese JT , Edgar RC , McEwan JC , Payne GM , Raison JM , Junier T , Kriventseva EV , Eyras E , Plass M , Donthu R , Larkin DM , Reecy J , Yang MQ , Chen L , Cheng Z , Chitko-McKown CG , Liu GE , Matukumalli LK , Song J , Zhu B , Bradley DG , Brinkman FS , Lau LP , Whiteside MD , Walker A , Wheeler TT , Casey T , German JB , Lemay DG , Maqbool NJ , Molenaar AJ , Seo S , Stothard P , Baldwin CL , Baxter R , Brinkmeyer-Langford CL , Brown WC , Childers CP , Connelley T , Ellis SA , Fritz K , Glass EJ , Herzig CT , Iivanainen A , Lahmers KK , Bennett AK , Dickens CM , Gilbert JG , Hagen DE , Salih H , Aerts J , Caetano AR , Dalrymple B , Garcia JF , Gill CA , Hiendleder SG , Memili E , Spurlock D , Williams JL , Alexander L , Brownstein MJ , Guan L , Holt RA , Jones SJ , Marra MA , Moore R , Moore SS , Roberts A , Taniguchi M , Waterman RC , Chacko J , Chandrabose MM , Cree A , Dao MD , Dinh HH , Gabisi RA , Hines S , Hume J , Jhangiani SN , Joshi V , Kovar CL , Lewis LR , Liu YS , Lopez J , Morgan MB , Nguyen NB , Okwuonu GO , Ruiz SJ , Santibanez J , Wright RA , Buhay C , Ding Y , Dugan-Rocha S , Herdandez J , Holder M , Sabo A , Egan A , Goodell J , Wilczek-Boney K , Fowler GR , Hitchens ME , Lozado RJ , Moen C , Steffen D , Warren JT , Zhang J , Chiu R , Schein JE , Durbin KJ , Havlak P , Jiang H , Liu Y , Qin X , Ren Y , Shen Y , Song H , Bell SN , Davis C , Johnson AJ , Lee S , Nazareth LV , Patel BM , Pu LL , Vattathil S , Williams RL, Jr. , Curry S , Hamilton C , Sodergren E , Wheeler DA , Barris W , Bennett GL , Eggen A , Green RD , Harhay GP , Hobbs M , Jann O , Keele JW , Kent MP , Lien S , McKay SD , McWilliam S , Ratnakumar A , Schnabel RD , Smith T , Snelling WM , Sonstegard TS , Stone RT , Sugimoto Y , Takasuga A , Taylor JF , Van Tassell CP , Macneil MD , Abatepaulo AR , Abbey CA , Ahola V , Almeida IG , Amadio AF , Anatriello E , Bahadue SM , Biase FH , Boldt CR , Carroll JA , Carvalho WA , Cervelatti EP , Chacko E , Chapin JE , Cheng Y , Choi J , Colley AJ , de Campos TA , De Donato M , Santos IK , de Oliveira CJ , Deobald H , Devinoy E , Donohue KE , Dovc P , Eberlein A , Fitzsimmons CJ , Franzin AM , Garcia GR , Genini S , Gladney CJ , Grant JR , Greaser ML , Green JA , Hadsell DL , Hakimov HA , Halgren R , Harrow JL , Hart EA , Hastings N , Hernandez M , Hu ZL , Ingham A , Iso-Touru T , Jamis C , Jensen K , Kapetis D , Kerr T , Khalil SS , Khatib H , Kolbehdari D , Kumar CG , Kumar D , Leach R , Lee JC , Li C , Logan KM , Malinverni R , Marques E , Martin WF , Martins NF , Maruyama SR , Mazza R , McLean KL , Medrano JF , Moreno BT , More DD , Muntean CT , Nandakumar HP , Nogueira MF , Olsaker I , Pant SD , Panzitta F , Pastor RC , Poli MA , Poslusny N , Rachagani S , Ranganathan S , Razpet A , Riggs PK , Rincon G , Rodriguez-Osorio N , Rodriguez-Zas SL , Romero NE , Rosenwald A , Sando L , Schmutz SM , Shen L , Sherman L , Southey BR , Lutzow YS , Sweedler JV , Tammen I , Telugu BP , Urbanski JM , Utsunomiya YT , Verschoor CP , Waardenberg AJ , Wang Z , Ward R , Weikard R , Welsh TH, Jr. , White SN , Wilming LG , Wunderlich KR , Yang J , Zhao FQ
Ref : Science , 324 :522 , 2009
Abstract : To understand the biology and evolution of ruminants, the cattle genome was sequenced to about sevenfold coverage. The cattle genome contains a minimum of 22,000 genes, with a core set of 14,345 orthologs shared among seven mammalian species of which 1217 are absent or undetected in noneutherian (marsupial or monotreme) genomes. Cattle-specific evolutionary breakpoint regions in chromosomes have a higher density of segmental duplications, enrichment of repetitive elements, and species-specific variations in genes associated with lactation and immune responsiveness. Genes involved in metabolism are generally highly conserved, although five metabolic genes are deleted or extensively diverged from their human orthologs. The cattle genome sequence thus provides a resource for understanding mammalian evolution and accelerating livestock genetic improvement for milk and meat production.
ESTHER : Elsik_2009_Science_324_522
PubMedSearch : Elsik_2009_Science_324_522
PubMedID: 19390049
Gene_locus related to this paper: bovin-2neur , bovin-a0jnh8 , bovin-a5d7b7 , bovin-ACHE , bovin-balip , bovin-dpp4 , bovin-dpp6 , bovin-e1bi31 , bovin-e1bn79 , bovin-est8 , bovin-f1mbd6 , bovin-f1mi11 , bovin-f1mr65 , bovin-f1n1l4 , bovin-g3mxp5 , bovin-q0vcc8 , bovin-q2kj30 , bovin-q3t0r6 , bovin-thyro

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 : Evolutionary and biomedical insights from the rhesus macaque genome - Gibbs_2007_Science_316_222
Author(s) : Gibbs RA , Rogers J , Katze MG , Bumgarner R , Weinstock GM , Mardis ER , Remington KA , Strausberg RL , Venter JC , Wilson RK , Batzer MA , Bustamante CD , Eichler EE , Hahn MW , Hardison RC , Makova KD , Miller W , Milosavljevic A , Palermo RE , Siepel A , Sikela JM , Attaway T , Bell S , Bernard KE , Buhay CJ , Chandrabose MN , Dao M , Davis C , Delehaunty KD , Ding Y , Dinh HH , Dugan-Rocha S , Fulton LA , Gabisi RA , Garner TT , Godfrey J , Hawes AC , Hernandez J , Hines S , Holder M , Hume J , Jhangiani SN , Joshi V , Khan ZM , Kirkness EF , Cree A , Fowler RG , Lee S , Lewis LR , Li Z , Liu YS , Moore SM , Muzny D , Nazareth LV , Ngo DN , Okwuonu GO , Pai G , Parker D , Paul HA , Pfannkoch C , Pohl CS , Rogers YH , Ruiz SJ , Sabo A , Santibanez J , Schneider BW , Smith SM , Sodergren E , Svatek AF , Utterback TR , Vattathil S , Warren W , White CS , Chinwalla AT , Feng Y , Halpern AL , Hillier LW , Huang X , Minx P , Nelson JO , Pepin KH , Qin X , Sutton GG , Venter E , Walenz BP , Wallis JW , Worley KC , Yang SP , Jones SM , Marra MA , Rocchi M , Schein JE , Baertsch R , Clarke L , Csuros M , Glasscock J , Harris RA , Havlak P , Jackson AR , Jiang H , Liu Y , Messina DN , Shen Y , Song HX , Wylie T , Zhang L , Birney E , Han K , Konkel MK , Lee J , Smit AF , Ullmer B , Wang H , Xing J , Burhans R , Cheng Z , Karro JE , Ma J , Raney B , She X , Cox MJ , Demuth JP , Dumas LJ , Han SG , Hopkins J , Karimpour-Fard A , Kim YH , Pollack JR , Vinar T , Addo-Quaye C , Degenhardt J , Denby A , Hubisz MJ , Indap A , Kosiol C , Lahn BT , Lawson HA , Marklein A , Nielsen R , Vallender EJ , Clark AG , Ferguson B , Hernandez RD , Hirani K , Kehrer-Sawatzki H , Kolb J , Patil S , Pu LL , Ren Y , Smith DG , Wheeler DA , Schenck I , Ball EV , Chen R , Cooper DN , Giardine B , Hsu F , Kent WJ , Lesk A , Nelson DL , O'Brien W E , Prufer K , Stenson PD , Wallace JC , Ke H , Liu XM , Wang P , Xiang AP , Yang F , Barber GP , Haussler D , Karolchik D , Kern AD , Kuhn RM , Smith KE , Zwieg AS
Ref : Science , 316 :222 , 2007
Abstract : The rhesus macaque (Macaca mulatta) is an abundant primate species that diverged from the ancestors of Homo sapiens about 25 million years ago. Because they are genetically and physiologically similar to humans, rhesus monkeys are the most widely used nonhuman primate in basic and applied biomedical research. We determined the genome sequence of an Indian-origin Macaca mulatta female and compared the data with chimpanzees and humans to reveal the structure of ancestral primate genomes and to identify evidence for positive selection and lineage-specific expansions and contractions of gene families. A comparison of sequences from individual animals was used to investigate their underlying genetic diversity. The complete description of the macaque genome blueprint enhances the utility of this animal model for biomedical research and improves our understanding of the basic biology of the species.
ESTHER : Gibbs_2007_Science_316_222
PubMedSearch : Gibbs_2007_Science_316_222
PubMedID: 17431167
Gene_locus related to this paper: macmu-3neur , macmu-ACHE , macmu-BCHE , macmu-f6rul6 , macmu-f6sz31 , macmu-f6the6 , macmu-f6unj2 , macmu-f6wtx1 , macmu-f6zkq5 , macmu-f7aa58 , macmu-f7ai42 , macmu-f7aim4 , macmu-f7buk8 , macmu-f7cfi8 , macmu-f7cnr2 , macmu-f7cu68 , macmu-f7flv1 , macmu-f7ggk1 , macmu-f7hir7 , macmu-g7n054 , macmu-KANSL3 , macmu-TEX30 , macmu-Y4neur , macmu-g7n4x3 , macmu-i2cy02 , macmu-f7ba84 , macmu-CES2 , macmu-h9er02 , macmu-a0a1d5rbr3 , macmu-a0a1d5q4k5 , macmu-g7mxj6 , macmu-f7dn71 , macmu-f7hkw9 , macmu-f7hm08 , macmu-g7mke4 , macmu-a0a1d5rh04 , macmu-h9fud6 , macmu-f6qwx1 , macmu-f7h4t2 , macmu-h9zaw9 , macmu-f7h550 , macmu-a0a1d5q9w1 , macmu-f7gkb9 , macmu-f7hp78 , macmu-a0a1d5qvu5

Title : The complete genome of Rhodococcus sp. RHA1 provides insights into a catabolic powerhouse - McLeod_2006_Proc.Natl.Acad.Sci.U.S.A_103_15582
Author(s) : McLeod MP , Warren RL , Hsiao WW , Araki N , Myhre M , Fernandes C , Miyazawa D , Wong W , Lillquist AL , Wang D , Dosanjh M , Hara H , Petrescu A , Morin RD , Yang G , Stott JM , Schein JE , Shin H , Smailus D , Siddiqui AS , Marra MA , Jones SJ , Holt R , Brinkman FS , Miyauchi K , Fukuda M , Davies JE , Mohn WW , Eltis LD
Ref : Proc Natl Acad Sci U S A , 103 :15582 , 2006
Abstract : Rhodococcus sp. RHA1 (RHA1) is a potent polychlorinated biphenyl-degrading soil actinomycete that catabolizes a wide range of compounds and represents a genus of considerable industrial interest. RHA1 has one of the largest bacterial genomes sequenced to date, comprising 9,702,737 bp (67% G+C) arranged in a linear chromosome and three linear plasmids. A targeted insertion methodology was developed to determine the telomeric sequences. RHA1's 9,145 predicted protein-encoding genes are exceptionally rich in oxygenases (203) and ligases (192). Many of the oxygenases occur in the numerous pathways predicted to degrade aromatic compounds (30) or steroids (4). RHA1 also contains 24 nonribosomal peptide synthase genes, six of which exceed 25 kbp, and seven polyketide synthase genes, providing evidence that rhodococci harbor an extensive secondary metabolism. Among sequenced genomes, RHA1 is most similar to those of nocardial and mycobacterial strains. The genome contains few recent gene duplications. Moreover, three different analyses indicate that RHA1 has acquired fewer genes by recent horizontal transfer than most bacteria characterized to date and far fewer than Burkholderia xenovorans LB400, whose genome size and catabolic versatility rival those of RHA1. RHA1 and LB400 thus appear to demonstrate that ecologically similar bacteria can evolve large genomes by different means. Overall, RHA1 appears to have evolved to simultaneously catabolize a diverse range of plant-derived compounds in an O(2)-rich environment. In addition to establishing RHA1 as an important model for studying actinomycete physiology, this study provides critical insights that facilitate the exploitation of these industrially important microorganisms.
ESTHER : McLeod_2006_Proc.Natl.Acad.Sci.U.S.A_103_15582
PubMedSearch : McLeod_2006_Proc.Natl.Acad.Sci.U.S.A_103_15582
PubMedID: 17030794
Gene_locus related to this paper: rhoob-c1ar27 , rhoob-c1arb5 , rhoob-c1asz4 , rhoob-c1at13 , rhoob-c1ata3 , rhoob-c1atk8 , rhoob-c1atq0 , rhoob-c1ats8 , rhoob-c1att5 , rhoob-c1au11 , rhoob-c1auh5 , rhoob-c1aux1 , rhoob-c1av24 , rhoob-c1awr1 , rhoob-c1axf2 , rhoob-c1ayb0 , rhoob-c1b0a8 , rhoob-c1b0g7 , rhoob-c1b0w8 , rhoob-c1b1i6 , rhoob-c1b7t4 , rhoob-c1b8z9 , rhoob-c1b9l2 , rhoob-c1b9v1 , rhoob-c1b9y1 , rhoob-c1b930 , rhoob-c1b931 , rhoob-c1b932 , rhoob-c1b996 , rhoob-c1bbl3 , rhoob-c1bbq4 , rhoop-pcaL , rhosp-bphD2 , rhosp-EtbD1 , rhosr-q0rwt2 , rhosr-q0rwv3 , rhosr-q0rxc8 , rhosr-q0ryc0 , rhosr-q0ryn3 , rhosr-q0rz46 , rhosr-q0rz78 , rhosr-q0s0s0 , rhosr-q0s1l0 , rhosr-q0s1m1 , rhosr-q0s1n4 , rhosr-q0s1x5 , rhosr-q0s1x6 , rhosr-q0s2i6 , rhosr-q0s2n9 , rhosr-q0s2t5 , rhosr-q0s3c8 , rhosr-q0s3s6 , rhosr-q0s4f1 , rhosr-q0s5h5 , rhosr-q0s5m7 , rhosr-q0s6a9 , rhosr-q0s6b3 , rhosr-q0s6b5 , rhosr-q0s7i7 , rhosr-q0s7r1 , rhosr-q0s008 , rhosr-q0s8b3 , rhosr-q0s8f4 , rhosr-q0s8p7 , rhosr-q0s8z9 , rhosr-q0s9l3 , rhosr-q0s9m1 , rhosr-q0s101 , rhosr-q0s125 , rhosr-q0s230 , rhosr-q0s252 , rhosr-q0s393 , rhosr-q0s477 , rhosr-q0s545 , rhojr-q0s546 , rhosr-q0s837 , rhosr-q0s849 , rhosr-q0sa25 , rhosr-q0sa26 , rhosr-q0sa61 , rhosr-q0saa5 , rhosr-q0san0 , rhosr-q0saw3 , rhosr-q0sbd3 , rhosr-q0sc04 , rhosr-q0scq2 , rhosr-q0sd10 , rhosr-q0sdb8 , rhosr-q0sdh6 , rhosr-q0sdr2 , rhosr-q0sdr5 , rhosr-q0sdt1 , rhosr-q0sdu5 , rhosr-q0sej4 , rhosr-q0ses6 , rhosr-q0set7 , rhosr-q0sex8 , rhosr-q0sf05 , rhosr-q0sfh8 , rhosr-q0sfl2 , rhosr-q0sfz6 , rhosr-q0sgc8 , rhosr-q0sgj4 , rhosr-q0sgv4 , rhosr-q0sgw4 , rhosr-q0sh74 , rhosr-q0shd6 , rhosr-q0shi2 , rhosr-q0sjy0 , rhosr-q0skn1 , rhoob-c1b934 , rhosr-q0sab7 , rhosr-q0rwx4 , rhoob-c1asm3 , rhosr-q0ruu2 , rhosr-q0s747 , rhosr-q0ry47 , rhosr-q0rwa1 , rhosr-q0sj22 , 9noca-j2j8s8 , rhojr-q0sd80 , rhojr-q0sf05

Title : The genome of the basidiomycetous yeast and human pathogen Cryptococcus neoformans - Loftus_2005_Science_307_1321
Author(s) : Loftus BJ , Fung E , Roncaglia P , Rowley D , Amedeo P , Bruno D , Vamathevan J , Miranda M , Anderson IJ , Fraser JA , Allen JE , Bosdet IE , Brent MR , Chiu R , Doering TL , Donlin MJ , D'Souza CA , Fox DS , Grinberg V , Fu J , Fukushima M , Haas BJ , Huang JC , Janbon G , Jones SJ , Koo HL , Krzywinski MI , Kwon-Chung JK , Lengeler KB , Maiti R , Marra MA , Marra RE , Mathewson CA , Mitchell TG , Pertea M , Riggs FR , Salzberg SL , Schein JE , Shvartsbeyn A , Shin H , Shumway M , Specht CA , Suh BB , Tenney A , Utterback TR , Wickes BL , Wortman JR , Wye NH , Kronstad JW , Lodge JK , Heitman J , Davis RW , Fraser CM , Hyman RW
Ref : Science , 307 :1321 , 2005
Abstract : Cryptococcus neoformans is a basidiomycetous yeast ubiquitous in the environment, a model for fungal pathogenesis, and an opportunistic human pathogen of global importance. We have sequenced its approximately 20-megabase genome, which contains approximately 6500 intron-rich gene structures and encodes a transcriptome abundant in alternatively spliced and antisense messages. The genome is rich in transposons, many of which cluster at candidate centromeric regions. The presence of these transposons may drive karyotype instability and phenotypic variation. C. neoformans encodes unique genes that may contribute to its unusual virulence properties, and comparison of two phenotypically distinct strains reveals variation in gene content in addition to sequence polymorphisms between the genomes.
ESTHER : Loftus_2005_Science_307_1321
PubMedSearch : Loftus_2005_Science_307_1321
PubMedID: 15653466
Gene_locus related to this paper: cryne-apth1 , cryne-ppme1 , cryne-q5k7g1 , cryne-q5k7h2 , cryne-q5k7p6 , cryne-q5k8p2 , cryne-q5k8s0 , cryne-q5k9e7 , cryne-q5k9p3 , cryne-q5k9y9 , cryne-q5k721 , cryne-q5k987 , cryne-q5ka03 , cryne-q5ka24 , cryne-q5ka58 , cryne-q5kat4 , cryne-q5kav3 , cryne-q5kbu4 , cryne-q5kbw4 , cryne-q5kc00 , cryne-q5kec5 , cryne-q5kei3 , cryne-q5kei7 , cryne-q5ker2 , cryne-q5key5 , cryne-q5kf48 , cryne-q5kfk6 , cryne-q5kfz0 , cryne-q5kgq3 , cryne-q5kh37 , cryne-q5khb0 , cryne-q5khb9 , cryne-q5kip7 , cryne-q5kiu5 , cryne-q5kj56 , cryne-q5kjf8 , cryne-q5kjh3 , cryne-q5kjp9 , cryne-q5kjw7 , cryne-q5kky1 , cryne-q5kkz7 , cryne-q5kl13 , cryne-q5klu9 , cryne-q5km63 , cryne-q5kme9 , cryne-q5kni1 , cryne-q5knq0 , cryne-q5knr2 , cryne-q5knw0 , cryne-q5kq08 , cryne-Q5KCH9 , cryne-q55ta1 , cryne-q5kjh4 , crynj-q5knp8 , crynj-q5kpe0

Title : The status, quality, and expansion of the NIH full-length cDNA project: the Mammalian Gene Collection (MGC) - Gerhard_2004_Genome.Res_14_2121
Author(s) : Gerhard DS , Wagner L , Feingold EA , Shenmen CM , Grouse LH , Schuler G , Klein SL , Old S , Rasooly R , Good P , Guyer M , Peck AM , Derge JG , Lipman D , Collins FS , Jang W , Sherry S , Feolo M , Misquitta L , Lee E , Rotmistrovsky K , Greenhut SF , Schaefer CF , Buetow K , Bonner TI , Haussler D , Kent J , Kiekhaus M , Furey T , Brent M , Prange C , Schreiber K , Shapiro N , Bhat NK , Hopkins RF , Hsie F , Driscoll T , Soares MB , Casavant TL , Scheetz TE , Brown-stein MJ , Usdin TB , Toshiyuki S , Carninci P , Piao Y , Dudekula DB , Ko MS , Kawakami K , Suzuki Y , Sugano S , Gruber CE , Smith MR , Simmons B , Moore T , Waterman R , Johnson SL , Ruan Y , Wei CL , Mathavan S , Gunaratne PH , Wu J , Garcia AM , Hulyk SW , Fuh E , Yuan Y , Sneed A , Kowis C , Hodgson A , Muzny DM , McPherson J , Gibbs RA , Fahey J , Helton E , Ketteman M , Madan A , Rodrigues S , Sanchez A , Whiting M , Madari A , Young AC , Wetherby KD , Granite SJ , Kwong PN , Brinkley CP , Pearson RL , Bouffard GG , Blakesly RW , Green ED , Dickson MC , Rodriguez AC , Grimwood J , Schmutz J , Myers RM , Butterfield YS , Griffith M , Griffith OL , Krzywinski MI , Liao N , Morin R , Palmquist D , Petrescu AS , Skalska U , Smailus DE , Stott JM , Schnerch A , Schein JE , Jones SJ , Holt RA , Baross A , Marra MA , Clifton S , Makowski KA , Bosak S , Malek J
Ref : Genome Res , 14 :2121 , 2004
Abstract : The National Institutes of Health's Mammalian Gene Collection (MGC) project was designed to generate and sequence a publicly accessible cDNA resource containing a complete open reading frame (ORF) for every human and mouse gene. The project initially used a random strategy to select clones from a large number of cDNA libraries from diverse tissues. Candidate clones were chosen based on 5'-EST sequences, and then fully sequenced to high accuracy and analyzed by algorithms developed for this project. Currently, more than 11,000 human and 10,000 mouse genes are represented in MGC by at least one clone with a full ORF. The random selection approach is now reaching a saturation point, and a transition to protocols targeted at the missing transcripts is now required to complete the mouse and human collections. Comparison of the sequence of the MGC clones to reference genome sequences reveals that most cDNA clones are of very high sequence quality, although it is likely that some cDNAs may carry missense variants as a consequence of experimental artifact, such as PCR, cloning, or reverse transcriptase errors. Recently, a rat cDNA component was added to the project, and ongoing frog (Xenopus) and zebrafish (Danio) cDNA projects were expanded to take advantage of the high-throughput MGC pipeline.
ESTHER : Gerhard_2004_Genome.Res_14_2121
PubMedSearch : Gerhard_2004_Genome.Res_14_2121
PubMedID: 15489334
Gene_locus related to this paper: human-AFMID , human-CES4A , human-CES5A , human-NOTUM , human-SERAC1 , human-SERHL2 , human-TMEM53 , mouse-acot1 , mouse-adcl4 , mouse-Ces2f , mouse-Ces4a , mouse-notum , mouse-q6wqj1 , mouse-Q9DAI6 , mouse-rbbp9 , mouse-SERHL , mouse-srac1 , mouse-tmm53 , rat-abhd6 , rat-abhda , rat-abhea , rat-abheb , rat-Ldah , rat-cd029 , rat-estd , rat-Kansl3 , rat-nceh1 , ratno-acph , ratno-CMBL , mouse-b2rwd2 , rat-b5den3 , rat-ab17c

Title : The genome sequence of Caenorhabditis briggsae: a platform for comparative genomics - Stein_2003_PLoS.Biol_1_E45
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
Ref : PLoS Biol , 1 :E45 , 2003
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.
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

Title : Generation and initial analysis of more than 15,000 full-length human and mouse cDNA sequences - Strausberg_2002_Proc.Natl.Acad.Sci.U.S.A_99_16899
Author(s) : Strausberg RL , Feingold EA , Grouse LH , Derge JG , Klausner RD , Collins FS , Wagner L , Shenmen CM , Schuler GD , Altschul SF , Zeeberg B , Buetow KH , Schaefer CF , Bhat NK , Hopkins RF , Jordan H , Moore T , Max SI , Wang J , Hsieh F , Diatchenko L , Marusina K , Farmer AA , Rubin GM , Hong L , Stapleton M , Soares MB , Bonaldo MF , Casavant TL , Scheetz TE , Brownstein MJ , Usdin TB , Toshiyuki S , Carninci P , Prange C , Raha SS , Loquellano NA , Peters GJ , Abramson RD , Mullahy SJ , Bosak SA , McEwan PJ , McKernan KJ , Malek JA , Gunaratne PH , Richards S , Worley KC , Hale S , Garcia AM , Gay LJ , Hulyk SW , Villalon DK , Muzny DM , Sodergren EJ , Lu X , Gibbs RA , Fahey J , Helton E , Ketteman M , Madan A , Rodrigues S , Sanchez A , Whiting M , Young AC , Shevchenko Y , Bouffard GG , Blakesley RW , Touchman JW , Green ED , Dickson MC , Rodriguez AC , Grimwood J , Schmutz J , Myers RM , Butterfield YS , Krzywinski MI , Skalska U , Smailus DE , Schnerch A , Schein JE , Jones SJ , Marra MA
Ref : Proc Natl Acad Sci U S A , 99 :16899 , 2002
Abstract : The National Institutes of Health Mammalian Gene Collection (MGC) Program is a multiinstitutional effort to identify and sequence a cDNA clone containing a complete ORF for each human and mouse gene. ESTs were generated from libraries enriched for full-length cDNAs and analyzed to identify candidate full-ORF clones, which then were sequenced to high accuracy. The MGC has currently sequenced and verified the full ORF for a nonredundant set of >9,000 human and >6,000 mouse genes. Candidate full-ORF clones for an additional 7,800 human and 3,500 mouse genes also have been identified. All MGC sequences and clones are available without restriction through public databases and clone distribution networks (see http:mgc.nci.nih.gov).
ESTHER : Strausberg_2002_Proc.Natl.Acad.Sci.U.S.A_99_16899
PubMedSearch : Strausberg_2002_Proc.Natl.Acad.Sci.U.S.A_99_16899
PubMedID: 12477932
Gene_locus related to this paper: bovin-q3zcj6 , danre-OVCA2 , danre-q4qrh4 , danre-q4v960 , danre-q32ls6 , danre-q503e2 , ratno-CPVL , ratno-q3mhs0 , ratno-q4qr68 , ratno-q5fvr5 , ratno-q32q55 , xenla-a2bd54 , xenla-q2tap9 , xenla-q3kq37 , xenla-q3kq76 , xenla-q4klb6 , xenla-q32n48 , xenla-q32ns5 , xenla-q52l41 , xentr-q4va73 , danre-a7mbu9