Wortman JR

References (22)

Title : Genomic epidemiology of the Escherichia coli O104:H4 outbreaks in Europe, 2011 - Grad_2012_Proc.Natl.Acad.Sci.U.S.A_109_3065
Author(s) : Grad YH , Lipsitch M , Feldgarden M , Arachchi HM , Cerqueira GC , FitzGerald M , Godfrey P , Haas BJ , Murphy CI , Russ C , Sykes S , Walker BJ , Wortman JR , Young S , Zeng Q , Abouelleil A , Bochicchio J , Chauvin S , Desmet T , Gujja S , McCowan C , Montmayeur A , Steelman S , Frimodt-Moller J , Petersen AM , Struve C , Krogfelt KA , Bingen E , Weill FX , Lander ES , Nusbaum C , Birren BW , Hung DT , Hanage WP
Ref : Proc Natl Acad Sci U S A , 109 :3065 , 2012
Abstract : The degree to which molecular epidemiology reveals information about the sources and transmission patterns of an outbreak depends on the resolution of the technology used and the samples studied. Isolates of Escherichia coli O104:H4 from the outbreak centered in Germany in May-July 2011, and the much smaller outbreak in southwest France in June 2011, were indistinguishable by standard tests. We report a molecular epidemiological analysis using multiplatform whole-genome sequencing and analysis of multiple isolates from the German and French outbreaks. Isolates from the German outbreak showed remarkably little diversity, with only two single nucleotide polymorphisms (SNPs) found in isolates from four individuals. Surprisingly, we found much greater diversity (19 SNPs) in isolates from seven individuals infected in the French outbreak. The German isolates form a clade within the more diverse French outbreak strains. Moreover, five isolates derived from a single infected individual from the French outbreak had extremely limited diversity. The striking difference in diversity between the German and French outbreak samples is consistent with several hypotheses, including a bottleneck that purged diversity in the German isolates, variation in mutation rates in the two E. coli outbreak populations, or uneven distribution of diversity in the seed populations that led to each outbreak.
ESTHER : Grad_2012_Proc.Natl.Acad.Sci.U.S.A_109_3065
PubMedSearch : Grad_2012_Proc.Natl.Acad.Sci.U.S.A_109_3065
PubMedID: 22315421
Gene_locus related to this paper: ecoli-fes , ecoli-MCMK , ecoli-yaim , ecoli-ycfp , ecoli-YFBB , ecoli-yhet , ecoli-yiel , ecoli-yqia , ecoli-YfhR

Title : A catalog of reference genomes from the human microbiome - Nelson_2010_Science_328_994
Author(s) : Nelson KE , Weinstock GM , Highlander SK , Worley KC , Creasy HH , Wortman JR , Rusch DB , Mitreva M , Sodergren E , Chinwalla AT , Feldgarden M , Gevers D , Haas BJ , Madupu R , Ward DV , Birren BW , Gibbs RA , Methe B , Petrosino JF , Strausberg RL , Sutton GG , White OR , Wilson RK , Durkin S , Giglio MG , Gujja S , Howarth C , Kodira CD , Kyrpides N , Mehta T , Muzny DM , Pearson M , Pepin K , Pati A , Qin X , Yandava C , Zeng Q , Zhang L , Berlin AM , Chen L , Hepburn TA , Johnson J , McCorrison J , Miller J , Minx P , Nusbaum C , Russ C , Sykes SM , Tomlinson CM , Young S , Warren WC , Badger J , Crabtree J , Markowitz VM , Orvis J , Cree A , Ferriera S , Fulton LL , Fulton RS , Gillis M , Hemphill LD , Joshi V , Kovar C , Torralba M , Wetterstrand KA , Abouellleil A , Wollam AM , Buhay CJ , Ding Y , Dugan S , Fitzgerald MG , Holder M , Hostetler J , Clifton SW , Allen-Vercoe E , Earl AM , Farmer CN , Liolios K , Surette MG , Xu Q , Pohl C , Wilczek-Boney K , Zhu D
Ref : Science , 328 :994 , 2010
Abstract : The human microbiome refers to the community of microorganisms, including prokaryotes, viruses, and microbial eukaryotes, that populate the human body. The National Institutes of Health launched an initiative that focuses on describing the diversity of microbial species that are associated with health and disease. The first phase of this initiative includes the sequencing of hundreds of microbial reference genomes, coupled to metagenomic sequencing from multiple body sites. Here we present results from an initial reference genome sequencing of 178 microbial genomes. From 547,968 predicted polypeptides that correspond to the gene complement of these strains, previously unidentified ("novel") polypeptides that had both unmasked sequence length greater than 100 amino acids and no BLASTP match to any nonreference entry in the nonredundant subset were defined. This analysis resulted in a set of 30,867 polypeptides, of which 29,987 (approximately 97%) were unique. In addition, this set of microbial genomes allows for approximately 40% of random sequences from the microbiome of the gastrointestinal tract to be associated with organisms based on the match criteria used. Insights into pan-genome analysis suggest that we are still far from saturating microbial species genetic data sets. In addition, the associated metrics and standards used by our group for quality assurance are presented.
ESTHER : Nelson_2010_Science_328_994
PubMedSearch : Nelson_2010_Science_328_994
PubMedID: 20489017
Gene_locus related to this paper: strp2-q04l35 , strpn-AXE1 , strpn-pepx

Title : Draft genome sequence of the oilseed species Ricinus communis - Chan_2010_Nat.Biotechnol_28_951
Author(s) : Chan AP , Crabtree J , Zhao Q , Lorenzi H , Orvis J , Puiu D , Melake-Berhan A , Jones KM , Redman J , Chen G , Cahoon EB , Gedil M , Stanke M , Haas BJ , Wortman JR , Fraser-Liggett CM , Ravel J , Rabinowicz PD
Ref : Nat Biotechnol , 28 :951 , 2010
Abstract : Castor bean (Ricinus communis) is an oilseed crop that belongs to the spurge (Euphorbiaceae) family, which comprises approximately 6,300 species that include cassava (Manihot esculenta), rubber tree (Hevea brasiliensis) and physic nut (Jatropha curcas). It is primarily of economic interest as a source of castor oil, used for the production of high-quality lubricants because of its high proportion of the unusual fatty acid ricinoleic acid. However, castor bean genomics is also relevant to biosecurity as the seeds contain high levels of ricin, a highly toxic, ribosome-inactivating protein. Here we report the draft genome sequence of castor bean (4.6-fold coverage), the first for a member of the Euphorbiaceae. Whereas most of the key genes involved in oil synthesis and turnover are single copy, the number of members of the ricin gene family is larger than previously thought. Comparative genomics analysis suggests the presence of an ancient hexaploidization event that is conserved across the dicotyledonous lineage.
ESTHER : Chan_2010_Nat.Biotechnol_28_951
PubMedSearch : Chan_2010_Nat.Biotechnol_28_951
PubMedID: 20729833
Gene_locus related to this paper: ricco-b9r7h7 , ricco-b9re31 , ricco-b9rgi7 , ricco-b9riy7 , ricco-b9rlg6 , ricco-b9rm64 , ricco-b9rsg5 , ricco-b9rtk6 , ricco-b9rtt3 , ricco-b9ry83 , ricco-b9s8p2 , ricco-b9s817 , ricco-b9sby7 , ricco-b9scn1 , ricco-b9scn2 , ricco-b9scn3 , ricco-b9scn5 , ricco-b9ssj7 , ricco-b9ssj8 , ricco-b9sx01 , ricco-b9szu0 , ricco-b9t4l4 , ricco-b9t5x2 , ricco-b9tb84 , ricco-b9rkb0 , ricco-b9rru1 , ricco-b9rdy5 , ricco-b9tey4 , ricco-b9sfw5 , ricco-b9sjw6 , ricco-b9shs6 , ricco-b9rsl2 , ricco-b9r7f8 , ricco-b9rne4 , ricco-b9r8z8 , ricco-b9rf65 , ricco-b9rjk8 , ricco-b9sip5 , ricco-b9t3r4

Title : The 2008 update of the Aspergillus nidulans genome annotation: a community effort - Wortman_2009_Fungal.Genet.Biol_46 Suppl 1_S2
Author(s) : Wortman JR , Gilsenan JM , Joardar V , Deegan J , Clutterbuck J , Andersen MR , Archer D , Bencina M , Braus G , Coutinho P , von Dohren H , Doonan J , Driessen AJ , Durek P , Espeso E , Fekete E , Flipphi M , Estrada CG , Geysens S , Goldman G , de Groot PW , Hansen K , Harris SD , Heinekamp T , Helmstaedt K , Henrissat B , Hofmann G , Homan T , Horio T , Horiuchi H , James S , Jones M , Karaffa L , Karanyi Z , Kato M , Keller N , Kelly DE , Kiel JA , Kim JM , van der Klei IJ , Klis FM , Kovalchuk A , Krasevec N , Kubicek CP , Liu B , Maccabe A , Meyer V , Mirabito P , Miskei M , Mos M , Mullins J , Nelson DR , Nielsen J , Oakley BR , Osmani SA , Pakula T , Paszewski A , Paulsen I , Pilsyk S , Pocsi I , Punt PJ , Ram AF , Ren Q , Robellet X , Robson G , Seiboth B , van Solingen P , Specht T , Sun J , Taheri-Talesh N , Takeshita N , Ussery D , vanKuyk PA , Visser H , van de Vondervoort PJ , de Vries RP , Walton J , Xiang X , Xiong Y , Zeng AP , Brandt BW , Cornell MJ , van den Hondel CA , Visser J , Oliver SG , Turner G
Ref : Fungal Genet Biol , 46 Suppl 1 :S2 , 2009
Abstract : The identification and annotation of protein-coding genes is one of the primary goals of whole-genome sequencing projects, and the accuracy of predicting the primary protein products of gene expression is vital to the interpretation of the available data and the design of downstream functional applications. Nevertheless, the comprehensive annotation of eukaryotic genomes remains a considerable challenge. Many genomes submitted to public databases, including those of major model organisms, contain significant numbers of wrong and incomplete gene predictions. We present a community-based reannotation of the Aspergillus nidulans genome with the primary goal of increasing the number and quality of protein functional assignments through the careful review of experts in the field of fungal biology.
ESTHER : Wortman_2009_Fungal.Genet.Biol_46 Suppl 1_S2
PubMedSearch : Wortman_2009_Fungal.Genet.Biol_46 Suppl 1_S2
PubMedID: 19146970
Gene_locus related to this paper: emeni-axe1 , emeni-c8v4m7 , emeni-faec , emeni-ppme1 , emeni-q5ara9 , emeni-q5arf0 , emeni-q5as30 , emeni-q5ase8 , emeni-q5av79 , emeni-q5aw09 , emeni-q5awc3 , emeni-q5awc7 , emeni-q5awu9 , emeni-q5aww4 , emeni-q5ax50 , emeni-q5ay37 , emeni-q5ay57 , emeni-q5ay59 , emeni-q5ayk9 , emeni-q5ays5 , emeni-q5az32 , emeni-q5az91 , emeni-q5az97 , emeni-q5azp1 , emeni-q5b0i6 , emeni-q5b1h2 , emeni-q5b2a9 , emeni-q5b2p7 , emeni-q5b3d2 , emeni-q5b4q7 , emeni-q5b5u7 , emeni-q5b5y4 , emeni-q5b9e7 , emeni-q5b9i0 , emeni-q5b364 , emeni-q5b446 , emeni-q5b938 , emeni-q5ba78 , emeni-q5bcd1 , emeni-q5bcd2 , emeni-q5bde7 , emeni-q5bdr0 , emeni-q5bf92 , emeni-q7si80 , emeni-q5bdv9 , emeni-c8vu15 , 9euro-a0a3d8t644 , emeni-q5b719 , emeni-q5ax97 , emeni-tdia , emeni-afoc , emeni-dbae

Title : Comparative genomic analyses of the human fungal pathogens Coccidioides and their relatives - Sharpton_2009_Genome.Res_19_1722
Author(s) : Sharpton TJ , Stajich JE , Rounsley SD , Gardner MJ , Wortman JR , Jordar VS , Maiti R , Kodira CD , Neafsey DE , Zeng Q , Hung CY , McMahan C , Muszewska A , Grynberg M , Mandel MA , Kellner EM , Barker BM , Galgiani JN , Orbach MJ , Kirkland TN , Cole GT , Henn MR , Birren BW , Taylor JW
Ref : Genome Res , 19 :1722 , 2009
Abstract : While most Ascomycetes tend to associate principally with plants, the dimorphic fungi Coccidioides immitis and Coccidioides posadasii are primary pathogens of immunocompetent mammals, including humans. Infection results from environmental exposure to Coccidiodies, which is believed to grow as a soil saprophyte in arid deserts. To investigate hypotheses about the life history and evolution of Coccidioides, the genomes of several Onygenales, including C. immitis and C. posadasii; a close, nonpathogenic relative, Uncinocarpus reesii; and a more diverged pathogenic fungus, Histoplasma capsulatum, were sequenced and compared with those of 13 more distantly related Ascomycetes. This analysis identified increases and decreases in gene family size associated with a host/substrate shift from plants to animals in the Onygenales. In addition, comparison among Onygenales genomes revealed evolutionary changes in Coccidioides that may underlie its infectious phenotype, the identification of which may facilitate improved treatment and prevention of coccidioidomycosis. Overall, the results suggest that Coccidioides species are not soil saprophytes, but that they have evolved to remain associated with their dead animal hosts in soil, and that Coccidioides metabolism genes, membrane-related proteins, and putatively antigenic compounds have evolved in response to interaction with an animal host.
ESTHER : Sharpton_2009_Genome.Res_19_1722
PubMedSearch : Sharpton_2009_Genome.Res_19_1722
PubMedID: 19717792
Gene_locus related to this paper: ajecg-c0nbn5 , ajecg-c0nbz4 , ajecg-c0ndw0 , ajecg-c0nqc6 , ajecg-c0nst6 , ajecg-c0ntx5 , ajecg-c0nu33 , ajecg-c0nzh6 , ajecg-c0p0h0 , ajech-c6h1y9 , ajecn-a6qs62 , ajecn-a6quy7 , ajecn-a6r2c0 , ajecn-a6r491 , ajecn-a6r635 , ajecn-a6rab7 , ajecn-a6ram0 , ajecn-a6rf08 , ajecn-a6rf70 , ajecn-atg15 , ajecn-dapb , ajeds-c5jqx1 , cocim-atg15 , cocim-bst1 , cocim-j3k8a1 , cocp7-c5p0f2 , cocp7-c5p0i6 , cocp7-c5p1s3 , cocp7-c5p1u2 , cocp7-c5p2u8 , cocp7-c5p4s8 , cocp7-c5p4z1 , cocp7-c5p5s7 , cocp7-c5p129 , cocp7-c5p172 , cocp7-c5p250 , cocps-e9ctz7 , cocp7-c5pae0 , cocp7-c5pby4 , cocp7-c5pdn8 , cocp7-c5pdv9 , cocp7-c5pe69 , cocp7-c5pf68 , cocp7-c5pgk6 , cocp7-c5pid0 , cocp7-dapb , cocps-e9cz73 , cocps-e9dbi4 , cocps-e9dbu0 , cocps-e9dfh7 , uncre-c4jf72 , uncre-c4jf79 , uncre-c4ji27 , uncre-c4jj62 , uncre-c4jjs9 , uncre-c4jk71 , uncre-c4jlm9 , uncre-c4jlp5 , uncre-c4jlr7 , uncre-c4jnk2 , uncre-c4jnn3 , uncre-c4juj6 , uncre-c4jve9 , uncre-c4jvh5 , uncre-c4jw09 , uncre-c4jyw9 , uncre-c4jzs5 , uncre-dapb , ajech-c6h9r4 , uncre-c4jds5 , cocp7-c5pii3 , ajecn-a6r5v8 , cocim-j3ka92 , cocp7-c5phc6 , ajecn-a6qtc4 , ajecn-a6r145 , cocps-e9d3i4 , cocp7-c5p7x1 , cocps-e9csw0 , ajecg-c0nww6 , ajecn-kex1 , uncre-kex1 , uncre-cbpya , cocps-kex1 , ajecn-cbpya

Title : Comparative genomics of the neglected human malaria parasite Plasmodium vivax - Carlton_2008_Nature_455_757
Author(s) : Carlton JM , Adams JH , Silva JC , Bidwell SL , Lorenzi H , Caler E , Crabtree J , Angiuoli SV , Merino EF , Amedeo P , Cheng Q , Coulson RM , Crabb BS , Del Portillo HA , Essien K , Feldblyum TV , Fernandez-Becerra C , Gilson PR , Gueye AH , Guo X , Kang'a S , Kooij TW , Korsinczky M , Meyer EV , Nene V , Paulsen I , White O , Ralph SA , Ren Q , Sargeant TJ , Salzberg SL , Stoeckert CJ , Sullivan SA , Yamamoto MM , Hoffman SL , Wortman JR , Gardner MJ , Galinski MR , Barnwell JW , Fraser-Liggett CM
Ref : Nature , 455 :757 , 2008
Abstract : The human malaria parasite Plasmodium vivax is responsible for 25-40% of the approximately 515 million annual cases of malaria worldwide. Although seldom fatal, the parasite elicits severe and incapacitating clinical symptoms and often causes relapses months after a primary infection has cleared. Despite its importance as a major human pathogen, P. vivax is little studied because it cannot be propagated continuously in the laboratory except in non-human primates. We sequenced the genome of P. vivax to shed light on its distinctive biological features, and as a means to drive development of new drugs and vaccines. Here we describe the synteny and isochore structure of P. vivax chromosomes, and show that the parasite resembles other malaria parasites in gene content and metabolic potential, but possesses novel gene families and potential alternative invasion pathways not recognized previously. Completion of the P. vivax genome provides the scientific community with a valuable resource that can be used to advance investigation into this neglected species.
ESTHER : Carlton_2008_Nature_455_757
PubMedSearch : Carlton_2008_Nature_455_757
PubMedID: 18843361
Gene_locus related to this paper: plakh-b3lb44 , plavi-a5kcq0 , plavs-a5k2k6 , plavs-a5k3z4 , plavs-a5k4s6 , plavs-a5k5e4 , plavs-a5k7t5 , plavs-a5k686 , plavs-a5kaa1 , plavs-a5kaa3 , plavs-a5kas6 , plavs-a5kcm2

Title : Genomic islands in the pathogenic filamentous fungus Aspergillus fumigatus - Fedorova_2008_PLoS.Genet_4_e1000046
Author(s) : Fedorova ND , Khaldi N , Joardar VS , Maiti R , Amedeo P , Anderson MJ , Crabtree J , Silva JC , Badger JH , Albarraq A , Angiuoli S , Bussey H , Bowyer P , Cotty PJ , Dyer PS , Egan A , Galens K , Fraser-Liggett CM , Haas BJ , Inman JM , Kent R , Lemieux S , Malavazi I , Orvis J , Roemer T , Ronning CM , Sundaram JP , Sutton G , Turner G , Venter JC , White OR , Whitty BR , Youngman P , Wolfe KH , Goldman GH , Wortman JR , Jiang B , Denning DW , Nierman WC
Ref : PLoS Genet , 4 :e1000046 , 2008
Abstract : We present the genome sequences of a new clinical isolate of the important human pathogen, Aspergillus fumigatus, A1163, and two closely related but rarely pathogenic species, Neosartorya fischeri NRRL181 and Aspergillus clavatus NRRL1. Comparative genomic analysis of A1163 with the recently sequenced A. fumigatus isolate Af293 has identified core, variable and up to 2% unique genes in each genome. While the core genes are 99.8% identical at the nucleotide level, identity for variable genes can be as low 40%. The most divergent loci appear to contain heterokaryon incompatibility (het) genes associated with fungal programmed cell death such as developmental regulator rosA. Cross-species comparison has revealed that 8.5%, 13.5% and 12.6%, respectively, of A. fumigatus, N. fischeri and A. clavatus genes are species-specific. These genes are significantly smaller in size than core genes, contain fewer exons and exhibit a subtelomeric bias. Most of them cluster together in 13 chromosomal islands, which are enriched for pseudogenes, transposons and other repetitive elements. At least 20% of A. fumigatus-specific genes appear to be functional and involved in carbohydrate and chitin catabolism, transport, detoxification, secondary metabolism and other functions that may facilitate the adaptation to heterogeneous environments such as soil or a mammalian host. Contrary to what was suggested previously, their origin cannot be attributed to horizontal gene transfer (HGT), but instead is likely to involve duplication, diversification and differential gene loss (DDL). The role of duplication in the origin of lineage-specific genes is further underlined by the discovery of genomic islands that seem to function as designated "gene dumps" and, perhaps, simultaneously, as "gene factories".
ESTHER : Fedorova_2008_PLoS.Genet_4_e1000046
PubMedSearch : Fedorova_2008_PLoS.Genet_4_e1000046
PubMedID: 18404212
Gene_locus related to this paper: aspcl-a1c4m6 , aspcl-a1c5a7 , aspcl-a1c6w3 , aspcl-a1c8p7 , aspcl-a1c8q9 , aspcl-a1c9k4 , aspcl-a1c759 , aspcl-a1c786 , aspcl-a1c823 , aspcl-a1c859 , aspcl-a1c881 , aspcl-a1c994 , aspcl-a1cag4 , aspcl-a1caj8 , aspcl-a1cas0 , aspcl-a1cc86 , aspcl-a1ccq2 , aspcl-a1cfv7 , aspcl-a1chj6 , aspcl-a1cif4 , aspcl-a1ck14 , aspcl-a1cke4 , aspcl-a1ckq1 , aspcl-a1cli1 , aspcl-a1cln8 , aspcl-a1cm72 , aspcl-a1cns2 , aspcl-a1cpk9 , aspcl-a1cra8 , aspcl-a1crr5 , aspcl-a1crs9 , aspcl-a1cs04 , aspcl-a1cs39 , aspcl-a1cu39 , aspcl-atg15 , aspcl-axe1 , aspcl-cuti1 , aspcl-cuti3 , aspcl-dapb , aspcl-dpp4 , aspcl-dpp5 , aspcl-faeb , aspcl-faec1 , aspcl-faec2 , aspfc-b0xp50 , aspfc-b0xu40 , aspfc-b0xzj6 , aspfc-b0y2h6 , aspfc-b0y962 , aspfc-b0yaj6 , aspfc-dpp5 , aspfu-DPP4 , aspfu-faeb1 , aspfu-faec , aspfu-ppme1 , aspfu-q4w9r3 , aspfu-q4w9t5 , aspfu-q4w9z4 , aspfu-q4wa57 , aspfu-q4wa78 , aspfu-q4wag0 , aspfu-q4wal3 , aspfu-q4wbc5 , aspfu-q4wbj7 , aspfu-q4wdg2 , aspfu-q4wf06 , aspfu-q4wf29 , aspfu-q4wf56 , aspfu-q4wfq9 , aspfu-q4wg73 , aspfu-q4wgm4 , aspfu-q4win2 , aspfu-q4wk31 , aspfu-q4wk44 , aspfu-q4wk90 , aspfu-q4wm12 , aspfu-q4wm84 , aspfu-q4wm86 , aspfu-q4wmr0 , aspfu-q4wny7 , aspfu-q4wp19 , aspfu-q4wpb9 , aspfu-q4wqj8 , aspfu-q4wqv2 , aspfu-q4wrr7 , aspfu-q4wu51 , aspfu-q4wub2 , aspfu-q4wui7 , aspfu-q4wuk8 , aspfu-q4wum3 , aspfu-q4wuw0 , aspfu-q4wvy1 , aspfu-q4ww22 , aspfu-q4wx13 , aspfu-q4wxd0 , aspfu-q4wxe4 , aspfu-q4wxr1 , aspfu-q4wyq5 , aspfu-q4wz16 , aspfu-q4wzd5 , aspfu-q4wzh6 , aspfu-q4x0n6 , aspfu-q4x1n0 , aspfu-q4x1w9 , aspfu-q4x078 , neofi-a1cwa6 , neofi-a1d4m8 , neofi-a1d4p0 , neofi-a1d5p2 , neofi-a1d104 , neofi-a1d380 , neofi-a1d512 , neofi-a1d654 , neofi-a1da18 , neofi-a1dal8 , neofi-a1df46 , neofi-a1dhj0 , neofi-a1di44 , neofi-a1dk35 , neofi-a1dki7 , neofi-a1dkt6 , neofi-a1dn55 , neofi-atg15 , neofi-axe1 , neofi-faeb1 , neofi-faeb2 , neofi-faec , aspcl-a1cd34 , aspcl-a1cd88 , neofi-a1dc66 , aspcl-a1ceh5 , neofi-a1dfr9 , aspfm-a0a084bf80 , aspcl-a1cqb5 , aspcl-a1cs44 , neofi-a1d517 , neofi-a1dbz0 , neofi-a1cuz0 , aspcl-a1c5e8 , neofi-a1d0b8 , aspcl-a1cdf0 , aspcl-a1ccd3 , neofi-a1da82 , neofi-a1d5e6 , aspcl-kex1 , aspcl-cbpya

Title : Draft genome sequence of the sexually transmitted pathogen Trichomonas vaginalis - Carlton_2007_Science_315_207
Author(s) : Carlton JM , Hirt RP , Silva JC , Delcher AL , Schatz M , Zhao Q , Wortman JR , Bidwell SL , Alsmark UC , Besteiro S , Sicheritz-Ponten T , Noel CJ , Dacks JB , Foster PG , Simillion C , Van de Peer Y , Miranda-Saavedra D , Barton GJ , Westrop GD , Muller S , Dessi D , Fiori PL , Ren Q , Paulsen I , Zhang H , Bastida-Corcuera FD , Simoes-Barbosa A , Brown MT , Hayes RD , Mukherjee M , Okumura CY , Schneider R , Smith AJ , Vanacova S , Villalvazo M , Haas BJ , Pertea M , Feldblyum TV , Utterback TR , Shu CL , Osoegawa K , de Jong PJ , Hrdy I , Horvathova L , Zubacova Z , Dolezal P , Malik SB , Logsdon JM, Jr. , Henze K , Gupta A , Wang CC , Dunne RL , Upcroft JA , Upcroft P , White O , Salzberg SL , Tang P , Chiu CH , Lee YS , Embley TM , Coombs GH , Mottram JC , Tachezy J , Fraser-Liggett CM , Johnson PJ
Ref : Science , 315 :207 , 2007
Abstract : We describe the genome sequence of the protist Trichomonas vaginalis, a sexually transmitted human pathogen. Repeats and transposable elements comprise about two-thirds of the approximately 160-megabase genome, reflecting a recent massive expansion of genetic material. This expansion, in conjunction with the shaping of metabolic pathways that likely transpired through lateral gene transfer from bacteria, and amplification of specific gene families implicated in pathogenesis and phagocytosis of host proteins may exemplify adaptations of the parasite during its transition to a urogenital environment. The genome sequence predicts previously unknown functions for the hydrogenosome, which support a common evolutionary origin of this unusual organelle with mitochondria.
ESTHER : Carlton_2007_Science_315_207
PubMedSearch : Carlton_2007_Science_315_207
PubMedID: 17218520
Gene_locus related to this paper: triva-a2d7i4 , triva-a2d9w5 , triva-a2d766 , triva-a2dah5 , triva-a2dlx9 , triva-a2dul1 , triva-a2dy49 , triva-a2e6h5 , triva-a2e7p9 , triva-a2e9l3 , triva-a2e414 , triva-a2e613 , triva-a2e983 , triva-a2eau8 , triva-a2ekb9 , triva-a2en58 , triva-a2erp5 , triva-a2et59 , triva-a2f7u4 , triva-a2f801 , triva-a2fa76 , triva-a2fbq3 , triva-a2fe47 , triva-a2fgl0 , triva-a2fhp7 , triva-a2fie6 , triva-a2fk22 , triva-a2fla2 , triva-a2fqm0 , triva-a2fqq2 , triva-a2frq0 , triva-a2frr3 , triva-a2fsq9 , triva-a2fsz5 , triva-a2fux4 , triva-a2fz57 , triva-a2g2h0 , triva-a2g9x0 , triva-a2fqi4

Title : Genome sequence of Babesia bovis and comparative analysis of apicomplexan hemoprotozoa - Brayton_2007_PLoS.Pathog_3_1401
Author(s) : Brayton KA , Lau AO , Herndon DR , Hannick L , Kappmeyer LS , Berens SJ , Bidwell SL , Brown WC , Crabtree J , Fadrosh D , Feldblum T , Forberger HA , Haas BJ , Howell JM , Khouri H , Koo H , Mann DJ , Norimine J , Paulsen IT , Radune D , Ren Q , Smith RK, Jr. , Suarez CE , White O , Wortman JR , Knowles DP, Jr. , McElwain TF , Nene VM
Ref : PLoS Pathog , 3 :1401 , 2007
Abstract : Babesia bovis is an apicomplexan tick-transmitted pathogen of cattle imposing a global risk and severe constraints to livestock health and economic development. The complete genome sequence was undertaken to facilitate vaccine antigen discovery, and to allow for comparative analysis with the related apicomplexan hemoprotozoa Theileria parva and Plasmodium falciparum. At 8.2 Mbp, the B. bovis genome is similar in size to that of Theileria spp. Structural features of the B. bovis and T. parva genomes are remarkably similar, and extensive synteny is present despite several chromosomal rearrangements. In contrast, B. bovis and P. falciparum, which have similar clinical and pathological features, have major differences in genome size, chromosome number, and gene complement. Chromosomal synteny with P. falciparum is limited to microregions. The B. bovis genome sequence has allowed wide scale analyses of the polymorphic variant erythrocyte surface antigen protein (ves1 gene) family that, similar to the P. falciparum var genes, is postulated to play a role in cytoadhesion, sequestration, and immune evasion. The approximately 150 ves1 genes are found in clusters that are distributed throughout each chromosome, with an increased concentration adjacent to a physical gap on chromosome 1 that contains multiple ves1-like sequences. ves1 clusters are frequently linked to a novel family of variant genes termed smorfs that may themselves contribute to immune evasion, may play a role in variant erythrocyte surface antigen protein biology, or both. Initial expression analysis of ves1 and smorf genes indicates coincident transcription of multiple variants. B. bovis displays a limited metabolic potential, with numerous missing pathways, including two pathways previously described for the P. falciparum apicoplast. This reduced metabolic potential is reflected in the B. bovis apicoplast, which appears to have fewer nuclear genes targeted to it than other apicoplast containing organisms. Finally, comparative analyses have identified several novel vaccine candidates including a positional homolog of p67 and SPAG-1, Theileria sporozoite antigens targeted for vaccine development. The genome sequence provides a greater understanding of B. bovis metabolism and potential avenues for drug therapies and vaccine development.
ESTHER : Brayton_2007_PLoS.Pathog_3_1401
PubMedSearch : Brayton_2007_PLoS.Pathog_3_1401
PubMedID: 17953480
Gene_locus related to this paper: babbo-a7amu4 , babbo-a7as90 , babbo-a7au28 , babbo-a7avh4

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 : Draft genome of the filarial nematode parasite Brugia malayi - Ghedin_2007_Science_317_1756
Author(s) : Ghedin E , Wang S , Spiro D , Caler E , Zhao Q , Crabtree J , Allen JE , Delcher AL , Guiliano DB , Miranda-Saavedra D , Angiuoli SV , Creasy T , Amedeo P , Haas B , El-Sayed NM , Wortman JR , Feldblyum T , Tallon L , Schatz M , Shumway M , Koo H , Salzberg SL , Schobel S , Pertea M , Pop M , White O , Barton GJ , Carlow CK , Crawford MJ , Daub J , Dimmic MW , Estes CF , Foster JM , Ganatra M , Gregory WF , Johnson NM , Jin J , Komuniecki R , Korf I , Kumar S , Laney S , Li BW , Li W , Lindblom TH , Lustigman S , Ma D , Maina CV , Martin DM , McCarter JP , McReynolds L , Mitreva M , Nutman TB , Parkinson J , Peregrin-Alvarez JM , Poole C , Ren Q , Saunders L , Sluder AE , Smith K , Stanke M , Unnasch TR , Ware J , Wei AD , Weil G , Williams DJ , Zhang Y , Williams SA , Fraser-Liggett C , Slatko B , Blaxter ML , Scott AL
Ref : Science , 317 :1756 , 2007
Abstract : Parasitic nematodes that cause elephantiasis and river blindness threaten hundreds of millions of people in the developing world. We have sequenced the approximately 90 megabase (Mb) genome of the human filarial parasite Brugia malayi and predict approximately 11,500 protein coding genes in 71 Mb of robustly assembled sequence. Comparative analysis with the free-living, model nematode Caenorhabditis elegans revealed that, despite these genes having maintained little conservation of local synteny during approximately 350 million years of evolution, they largely remain in linkage on chromosomal units. More than 100 conserved operons were identified. Analysis of the predicted proteome provides evidence for adaptations of B. malayi to niches in its human and vector hosts and insights into the molecular basis of a mutualistic relationship with its Wolbachia endosymbiont. These findings offer a foundation for rational drug design.
ESTHER : Ghedin_2007_Science_317_1756
PubMedSearch : Ghedin_2007_Science_317_1756
PubMedID: 17885136
Gene_locus related to this paper: bruma-a8ndk6 , bruma-a8njt8 , bruma-a8nl88 , bruma-a8npi4 , bruma-a8npi6 , bruma-a8p6g9 , bruma-a8pah3 , bruma-a8pc38 , bruma-a8pek5 , bruma-a8piq4 , bruma-a8pnw8 , bruma-a8psu4 , bruma-a8pte1 , bruma-a8q606 , bruma-a8q632 , bruma-a8q937 , bruma-a8qav5 , bruma-a8qbd9 , bruma-a8qgj6 , bruma-a8qh78 , bruma-a8q143 , bruma-a0a024mej5 , bruma-a0a0k0jju9 , bruma-a0a0i9n517

Title : Macronuclear genome sequence of the ciliate Tetrahymena thermophila, a model eukaryote - Eisen_2006_PLoS.Biol_4_e286
Author(s) : Eisen JA , Coyne RS , Wu M , Wu D , Thiagarajan M , Wortman JR , Badger JH , Ren Q , Amedeo P , Jones KM , Tallon LJ , Delcher AL , Salzberg SL , Silva JC , Haas BJ , Majoros WH , Farzad M , Carlton JM , Smith RK, Jr. , Garg J , Pearlman RE , Karrer KM , Sun L , Manning G , Elde NC , Turkewitz AP , Asai DJ , Wilkes DE , Wang Y , Cai H , Collins K , Stewart BA , Lee SR , Wilamowska K , Weinberg Z , Ruzzo WL , Wloga D , Gaertig J , Frankel J , Tsao CC , Gorovsky MA , Keeling PJ , Waller RF , Patron NJ , Cherry JM , Stover NA , Krieger CJ , del Toro C , Ryder HF , Williamson SC , Barbeau RA , Hamilton EP , Orias E
Ref : PLoS Biol , 4 :e286 , 2006
Abstract : The ciliate Tetrahymena thermophila is a model organism for molecular and cellular biology. Like other ciliates, this species has separate germline and soma functions that are embodied by distinct nuclei within a single cell. The germline-like micronucleus (MIC) has its genome held in reserve for sexual reproduction. The soma-like macronucleus (MAC), which possesses a genome processed from that of the MIC, is the center of gene expression and does not directly contribute DNA to sexual progeny. We report here the shotgun sequencing, assembly, and analysis of the MAC genome of T. thermophila, which is approximately 104 Mb in length and composed of approximately 225 chromosomes. Overall, the gene set is robust, with more than 27,000 predicted protein-coding genes, 15,000 of which have strong matches to genes in other organisms. The functional diversity encoded by these genes is substantial and reflects the complexity of processes required for a free-living, predatory, single-celled organism. This is highlighted by the abundance of lineage-specific duplications of genes with predicted roles in sensing and responding to environmental conditions (e.g., kinases), using diverse resources (e.g., proteases and transporters), and generating structural complexity (e.g., kinesins and dyneins). In contrast to the other lineages of alveolates (apicomplexans and dinoflagellates), no compelling evidence could be found for plastid-derived genes in the genome. UGA, the only T. thermophila stop codon, is used in some genes to encode selenocysteine, thus making this organism the first known with the potential to translate all 64 codons in nuclear genes into amino acids. We present genomic evidence supporting the hypothesis that the excision of DNA from the MIC to generate the MAC specifically targets foreign DNA as a form of genome self-defense. The combination of the genome sequence, the functional diversity encoded therein, and the presence of some pathways missing from other model organisms makes T. thermophila an ideal model for functional genomic studies to address biological, biomedical, and biotechnological questions of fundamental importance.
ESTHER : Eisen_2006_PLoS.Biol_4_e286
PubMedSearch : Eisen_2006_PLoS.Biol_4_e286
PubMedID: 16933976
Gene_locus related to this paper: tetts-i7mam3 , tetts-i7ml33

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 : Comparative genomics of trypanosomatid parasitic protozoa - El-Sayed_2005_Science_309_404
Author(s) : El-Sayed NM , Myler PJ , Blandin G , Berriman M , Crabtree J , Aggarwal G , Caler E , Renauld H , Worthey EA , Hertz-Fowler C , Ghedin E , Peacock C , Bartholomeu DC , Haas BJ , Tran AN , Wortman JR , Alsmark UC , Angiuoli S , Anupama A , Badger J , Bringaud F , Cadag E , Carlton JM , Cerqueira GC , Creasy T , Delcher AL , Djikeng A , Embley TM , Hauser C , Ivens AC , Kummerfeld SK , Pereira-Leal JB , Nilsson D , Peterson J , Salzberg SL , Shallom J , Silva JC , Sundaram J , Westenberger S , White O , Melville SE , Donelson JE , Andersson B , Stuart KD , Hall N
Ref : Science , 309 :404 , 2005
Abstract : A comparison of gene content and genome architecture of Trypanosoma brucei, Trypanosoma cruzi, and Leishmania major, three related pathogens with different life cycles and disease pathology, revealed a conserved core proteome of about 6200 genes in large syntenic polycistronic gene clusters. Many species-specific genes, especially large surface antigen families, occur at nonsyntenic chromosome-internal and subtelomeric regions. Retroelements, structural RNAs, and gene family expansion are often associated with syntenic discontinuities that-along with gene divergence, acquisition and loss, and rearrangement within the syntenic regions-have shaped the genomes of each parasite. Contrary to recent reports, our analyses reveal no evidence that these species are descended from an ancestor that contained a photosynthetic endosymbiont.
ESTHER : El-Sayed_2005_Science_309_404
PubMedSearch : El-Sayed_2005_Science_309_404
PubMedID: 16020724
Gene_locus related to this paper: tryb2-q382c1 , trycr-q4dhv2 , trycr-q4dpt2 , trycr-q4dpy4

Title : Genome sequencing and analysis of Aspergillus oryzae - Machida_2005_Nature_438_1157
Author(s) : Machida M , Asai K , Sano M , Tanaka T , Kumagai T , Terai G , Kusumoto K , Arima T , Akita O , Kashiwagi Y , Abe K , Gomi K , Horiuchi H , Kitamoto K , Kobayashi T , Takeuchi M , Denning DW , Galagan JE , Nierman WC , Yu J , Archer DB , Bennett JW , Bhatnagar D , Cleveland TE , Fedorova ND , Gotoh O , Horikawa H , Hosoyama A , Ichinomiya M , Igarashi R , Iwashita K , Juvvadi PR , Kato M , Kato Y , Kin T , Kokubun A , Maeda H , Maeyama N , Maruyama J , Nagasaki H , Nakajima T , Oda K , Okada K , Paulsen I , Sakamoto K , Sawano T , Takahashi M , Takase K , Terabayashi Y , Wortman JR , Yamada O , Yamagata Y , Anazawa H , Hata Y , Koide Y , Komori T , Koyama Y , Minetoki T , Suharnan S , Tanaka A , Isono K , Kuhara S , Ogasawara N , Kikuchi H
Ref : Nature , 438 :1157 , 2005
Abstract : The genome of Aspergillus oryzae, a fungus important for the production of traditional fermented foods and beverages in Japan, has been sequenced. The ability to secrete large amounts of proteins and the development of a transformation system have facilitated the use of A. oryzae in modern biotechnology. Although both A. oryzae and Aspergillus flavus belong to the section Flavi of the subgenus Circumdati of Aspergillus, A. oryzae, unlike A. flavus, does not produce aflatoxin, and its long history of use in the food industry has proved its safety. Here we show that the 37-megabase (Mb) genome of A. oryzae contains 12,074 genes and is expanded by 7-9 Mb in comparison with the genomes of Aspergillus nidulans and Aspergillus fumigatus. Comparison of the three aspergilli species revealed the presence of syntenic blocks and A. oryzae-specific blocks (lacking synteny with A. nidulans and A. fumigatus) in a mosaic manner throughout the genome of A. oryzae. The blocks of A. oryzae-specific sequence are enriched for genes involved in metabolism, particularly those for the synthesis of secondary metabolites. Specific expansion of genes for secretory hydrolytic enzymes, amino acid metabolism and amino acid/sugar uptake transporters supports the idea that A. oryzae is an ideal microorganism for fermentation.
ESTHER : Machida_2005_Nature_438_1157
PubMedSearch : Machida_2005_Nature_438_1157
PubMedID: 16372010
Gene_locus related to this paper: aspor-Q2U722 , aspfn-b8mvx2 , aspfn-b8mwk1 , aspfn-b8n1a4 , aspfn-b8n5l3 , aspfn-b8n7y0 , aspfn-b8n829 , aspfn-b8ncj5 , aspfn-b8nhj9 , aspfn-b8njx6 , aspfn-b8nsk2 , aspfu-q4wj61 , aspor-axe1 , aspor-CPI , aspor-cutas , aspor-cuti2 , aspor-DPPIV , aspor-faec , aspor-MDLB , aspor-ppme1 , aspor-q2tw11 , aspor-q2tw16 , aspor-q2tw28 , aspor-q2twc4 , aspor-q2twg0 , aspor-q2twj3 , aspor-q2twv2 , aspor-q2twv4 , aspor-q2tx21 , aspor-q2txq8 , aspor-q2tya1 , aspor-q2tyh6 , aspor-q2tyn9 , aspor-q2typ0 , aspor-q2tyq4 , aspor-q2tyv8 , aspor-q2tz03 , aspor-q2tzh3 , aspor-q2tzr5 , aspor-q2tzv9 , aspor-q2u0k7 , aspor-q2u0q2 , aspor-q2u0r6 , aspor-q2u1a5 , aspor-q2u1a6 , aspor-q2u1k0 , aspor-q2u1k8 , aspor-q2u1m8 , aspor-q2u2a1 , aspor-q2u2a4 , aspor-q2u3a3 , aspor-q2u3a6 , aspor-q2u3k5 , aspor-q2u3l6 , aspor-q2u4a0 , aspor-q2u4e0 , aspor-q2u4f6 , aspor-q2u4g6 , aspor-q2u4h9 , aspor-q2u4w9 , aspor-q2u4y8 , aspor-q2u5f5 , aspor-q2u5n3 , aspor-q2u5y8 , aspor-q2u6h7 , aspor-q2u6j5 , aspor-q2u6m8 , aspor-q2u6m9 , aspor-q2u6n6 , aspor-q2u7i2 , aspor-q2u7v0 , aspor-q2u8j8 , aspor-q2u8r1 , aspor-q2u8r4 , aspor-q2u8t5 , aspor-q2u8z3 , aspor-q2u9a1 , aspor-q2u9n5 , aspor-q2u144 , aspor-q2u161 , aspor-q2u185 , aspor-q2u199 , aspor-q2u212 , aspor-q2u331 , aspor-q2u348 , aspor-q2u400 , aspor-q2u453 , aspor-q2u489 , aspor-q2u704 , aspor-q2u728 , aspor-q2u798 , aspor-q2u822 , aspor-q2u854 , aspor-q2u875 , aspor-q2u908 , aspor-q2ua10 , aspor-q2ua48 , aspor-q2uab6 , aspor-q2uak9 , aspor-q2uaq4 , aspor-q2ub32 , aspor-q2ub76 , aspor-q2uba1 , aspor-q2ubd6 , aspor-q2ubm2 , aspor-q2ubr2 , aspor-q2uc28 , aspor-q2uc65 , aspor-q2uc77 , aspor-q2uc98 , aspor-q2uck0 , aspor-q2ucy7 , aspor-q2ud03 , aspor-q2ud06 , aspor-q2ud08 , aspor-q2ud23 , aspor-q2udn5 , aspor-q2udr0 , aspor-q2uec1 , aspor-q2uef3 , aspor-q2uf10 , aspor-q2uf27 , aspor-q2uf48 , aspor-q2ufd8 , aspor-q2ufe5 , aspor-q2ufm4 , aspor-q2ufr3 , aspor-q2ufz8 , aspor-q2ug78 , aspor-q2ugd6 , aspor-q2uge1 , aspor-q2ugg7 , aspor-q2ugi2 , aspor-q2ugl2 , aspor-q2ugy9 , aspor-q2uh24 , aspor-q2uh73 , aspor-q2uhe4 , aspor-q2uhf0 , aspor-q2uhj6 , aspor-q2uhn1 , aspor-q2uhq0 , aspor-q2ui56 , aspor-q2uib2 , aspor-q2uib5 , aspor-q2uie9 , aspor-q2uih1 , aspor-q2uii1 , aspor-q2uik9 , aspor-q2uiq0 , aspor-q2uiu1 , aspor-q2uix9 , aspor-q2uiy5 , aspor-q2uiz4 , aspor-q2uj89 , aspor-q2uja2 , aspor-q2uju3 , aspor-q2uk31 , aspor-q2uk42 , aspor-q2ukb6 , aspor-q2ukq7 , aspor-q2ul81 , aspor-q2uli9 , aspor-q2ulr2 , aspor-q2ulv7 , aspor-q2umf3 , aspor-q2umv2 , aspor-q2umx6 , aspor-q2unw5 , aspor-q2up23 , aspor-q2up89 , aspor-q2upe6 , aspor-q2upi1 , aspor-q2upl1 , aspor-q2upw4 , aspor-q2uq56 , aspor-q2uqb4 , aspor-q2uqm7 , aspor-q2ur58 , aspor-q2ur64 , aspor-q2ur80 , aspor-q2ur83 , aspor-q2ure7 , aspor-q2urf3 , aspor-q2urg5 , aspor-q2urq0 , aspor-q2urt4 , aspor-q2uru5 , aspor-q2usi0 , aspor-q2usp7 , aspor-q2usq8 , aspor-q2usv6 , aspor-q2uta5 , aspor-q2uu89 , aspor-q2uub4 , aspor-q2uux8 , aspor-q2uv29 , aspor-TGLA , aspor-q2ue03 , aspor-q2uj83 , aspno-a0a0l1j1c9

Title : Sequencing of Aspergillus nidulans and comparative analysis with A. fumigatus and A. oryzae - Galagan_2005_Nature_438_1105
Author(s) : Galagan JE , Calvo SE , Cuomo C , Ma LJ , Wortman JR , Batzoglou S , Lee SI , Basturkmen M , Spevak CC , Clutterbuck J , Kapitonov V , Jurka J , Scazzocchio C , Farman M , Butler J , Purcell S , Harris S , Braus GH , Draht O , Busch S , d'Enfert C , Bouchier C , Goldman GH , Bell-Pedersen D , Griffiths-Jones S , Doonan JH , Yu J , Vienken K , Pain A , Freitag M , Selker EU , Archer DB , Penalva MA , Oakley BR , Momany M , Tanaka T , Kumagai T , Asai K , Machida M , Nierman WC , Denning DW , Caddick M , Hynes M , Paoletti M , Fischer R , Miller B , Dyer P , Sachs MS , Osmani SA , Birren BW
Ref : Nature , 438 :1105 , 2005
Abstract : The aspergilli comprise a diverse group of filamentous fungi spanning over 200 million years of evolution. Here we report the genome sequence of the model organism Aspergillus nidulans, and a comparative study with Aspergillus fumigatus, a serious human pathogen, and Aspergillus oryzae, used in the production of sake, miso and soy sauce. Our analysis of genome structure provided a quantitative evaluation of forces driving long-term eukaryotic genome evolution. It also led to an experimentally validated model of mating-type locus evolution, suggesting the potential for sexual reproduction in A. fumigatus and A. oryzae. Our analysis of sequence conservation revealed over 5,000 non-coding regions actively conserved across all three species. Within these regions, we identified potential functional elements including a previously uncharacterized TPP riboswitch and motifs suggesting regulation in filamentous fungi by Puf family genes. We further obtained comparative and experimental evidence indicating widespread translational regulation by upstream open reading frames. These results enhance our understanding of these widely studied fungi as well as provide new insight into eukaryotic genome evolution and gene regulation.
ESTHER : Galagan_2005_Nature_438_1105
PubMedSearch : Galagan_2005_Nature_438_1105
PubMedID: 16372000
Gene_locus related to this paper: emeni-axe1 , emeni-BST1 , emeni-c8vrl3 , emeni-CUTI3 , emeni-faec , emeni-ppme1 , emeni-q5aqv0 , emeni-q5ara9 , emeni-q5av79 , emeni-q5avd3 , emeni-q5awc7 , emeni-q5awq3 , emeni-q5awu9 , emeni-q5aww7 , emeni-q5ax50 , emeni-q5ay37 , emeni-q5ay57 , emeni-q5ayk9 , emeni-q5az32 , emeni-q5azl2 , emeni-q5azp1 , emeni-q5b1v2 , emeni-q5b2c1 , emeni-q5b3d2 , emeni-q5b5j7 , emeni-q5b7i6 , emeni-q5b8p6 , emeni-q5b9e7 , emeni-q5b246 , emeni-q5b446 , emeni-q5b602 , emeni-q5b938 , emeni-q5ba78 , emeni-q5bad3 , emeni-q5bar0 , emeni-q5bcd1 , emeni-q5bcd2 , emeni-q5bcf8 , emeni-q5bdr0 , emeni-q5beh9 , emeni-q5bgk7 , emeni-q7si80 , emeni-q5bdv9 , emeni-c8vu15 , 9euro-a0a3d8t644 , emeni-q5b719 , emeni-q5ax97 , emeni-tdia , emeni-afoc , emeni-dbae

Title : Genome sequence of Theileria parva, a bovine pathogen that transforms lymphocytes - Gardner_2005_Science_309_134
Author(s) : Gardner MJ , Bishop R , Shah T , de Villiers EP , Carlton JM , Hall N , Ren Q , Paulsen IT , Pain A , Berriman M , Wilson RJ , Sato S , Ralph SA , Mann DJ , Xiong Z , Shallom SJ , Weidman J , Jiang L , Lynn J , Weaver B , Shoaibi A , Domingo AR , Wasawo D , Crabtree J , Wortman JR , Haas B , Angiuoli SV , Creasy TH , Lu C , Suh B , Silva JC , Utterback TR , Feldblyum TV , Pertea M , Allen J , Nierman WC , Taracha EL , Salzberg SL , White OR , Fitzhugh HA , Morzaria S , Venter JC , Fraser CM , Nene V
Ref : Science , 309 :134 , 2005
Abstract : We report the genome sequence of Theileria parva, an apicomplexan pathogen causing economic losses to smallholder farmers in Africa. The parasite chromosomes exhibit limited conservation of gene synteny with Plasmodium falciparum, and its plastid-like genome represents the first example where all apicoplast genes are encoded on one DNA strand. We tentatively identify proteins that facilitate parasite segregation during host cell cytokinesis and contribute to persistent infection of transformed host cells. Several biosynthetic pathways are incomplete or absent, suggesting substantial metabolic dependence on the host cell. One protein family that may generate parasite antigenic diversity is not telomere-associated.
ESTHER : Gardner_2005_Science_309_134
PubMedSearch : Gardner_2005_Science_309_134
PubMedID: 15994558
Gene_locus related to this paper: thepa-q4mzr2 , thepa-q4n0b4 , thepa-q4n2i4 , thepa-q4n4i8 , thepa-q4n5d6 , thepa-q4n5m4 , thepa-q4n006 , thepa-q4n9g7 , thepa-q4n315 , thepa-q4n349 , thepa-q4n803

Title : Genomic sequence of the pathogenic and allergenic filamentous fungus Aspergillus fumigatus - Nierman_2005_Nature_438_1151
Author(s) : Nierman WC , Pain A , Anderson MJ , Wortman JR , Kim HS , Arroyo J , Berriman M , Abe K , Archer DB , Bermejo C , Bennett J , Bowyer P , Chen D , Collins M , Coulsen R , Davies R , Dyer PS , Farman M , Fedorova N , Feldblyum TV , Fischer R , Fosker N , Fraser A , Garcia JL , Garcia MJ , Goble A , Goldman GH , Gomi K , Griffith-Jones S , Gwilliam R , Haas B , Haas H , Harris D , Horiuchi H , Huang J , Humphray S , Jimenez J , Keller N , Khouri H , Kitamoto K , Kobayashi T , Konzack S , Kulkarni R , Kumagai T , Lafon A , Latge JP , Li W , Lord A , Lu C , Majoros WH , May GS , Miller BL , Mohamoud Y , Molina M , Monod M , Mouyna I , Mulligan S , Murphy L , O'Neil S , Paulsen I , Penalva MA , Pertea M , Price C , Pritchard BL , Quail MA , Rabbinowitsch E , Rawlins N , Rajandream MA , Reichard U , Renauld H , Robson GD , Rodriguez de Cordoba S , Rodriguez-Pena JM , Ronning CM , Rutter S , Salzberg SL , Sanchez M , Sanchez-Ferrero JC , Saunders D , Seeger K , Squares R , Squares S , Takeuchi M , Tekaia F , Turner G , Vazquez de Aldana CR , Weidman J , White O , Woodward J , Yu JH , Fraser C , Galagan JE , Asai K , Machida M , Hall N , Barrell B , Denning DW
Ref : Nature , 438 :1151 , 2005
Abstract : Aspergillus fumigatus is exceptional among microorganisms in being both a primary and opportunistic pathogen as well as a major allergen. Its conidia production is prolific, and so human respiratory tract exposure is almost constant. A. fumigatus is isolated from human habitats and vegetable compost heaps. In immunocompromised individuals, the incidence of invasive infection can be as high as 50% and the mortality rate is often about 50% (ref. 2). The interaction of A. fumigatus and other airborne fungi with the immune system is increasingly linked to severe asthma and sinusitis. Although the burden of invasive disease caused by A. fumigatus is substantial, the basic biology of the organism is mostly obscure. Here we show the complete 29.4-megabase genome sequence of the clinical isolate Af293, which consists of eight chromosomes containing 9,926 predicted genes. Microarray analysis revealed temperature-dependent expression of distinct sets of genes, as well as 700 A. fumigatus genes not present or significantly diverged in the closely related sexual species Neosartorya fischeri, many of which may have roles in the pathogenicity phenotype. The Af293 genome sequence provides an unparalleled resource for the future understanding of this remarkable fungus.
ESTHER : Nierman_2005_Nature_438_1151
PubMedSearch : Nierman_2005_Nature_438_1151
PubMedID: 16372009
Gene_locus related to this paper: aspfc-b0xp50 , aspfc-b0xu40 , aspfc-b0xzj6 , aspfc-dpp5 , aspfu-apth1 , aspfu-axe1 , aspfu-CBPYA , aspfu-faec , aspfu-kex1 , aspfu-ppme1 , aspfu-q4wa39 , aspfu-q4wa78 , aspfu-q4wf56 , aspfu-q4wg73 , aspfu-q4wk44 , aspfu-q4wkh6 , aspfu-q4wnx3 , aspfu-q4wpb9 , aspfu-q4wqv2 , aspfu-q4wub2 , aspfu-q4wxr1 , aspfu-q4x0n6 , aspfu-q4x1n0 , aspfu-q5vjg7 , neofi-a1cwa6 , neofi-a1dfr9 , aspfm-a0a084bf80 , aspfu-fmac

Title : The genome sequence of the malaria mosquito Anopheles gambiae - Holt_2002_Science_298_129
Author(s) : Holt RA , Subramanian GM , Halpern A , Sutton GG , Charlab R , Nusskern DR , Wincker P , Clark AG , Ribeiro JM , Wides R , Salzberg SL , Loftus B , Yandell M , Majoros WH , Rusch DB , Lai Z , Kraft CL , Abril JF , Anthouard V , Arensburger P , Atkinson PW , Baden H , de Berardinis V , Baldwin D , Benes V , Biedler J , Blass C , Bolanos R , Boscus D , Barnstead M , Cai S , Center A , Chaturverdi K , Christophides GK , Chrystal MA , Clamp M , Cravchik A , Curwen V , Dana A , Delcher A , Dew I , Evans CA , Flanigan M , Grundschober-Freimoser A , Friedli L , Gu Z , Guan P , Guigo R , Hillenmeyer ME , Hladun SL , Hogan JR , Hong YS , Hoover J , Jaillon O , Ke Z , Kodira C , Kokoza E , Koutsos A , Letunic I , Levitsky A , Liang Y , Lin JJ , Lobo NF , Lopez JR , Malek JA , McIntosh TC , Meister S , Miller J , Mobarry C , Mongin E , Murphy SD , O'Brochta DA , Pfannkoch C , Qi R , Regier MA , Remington K , Shao H , Sharakhova MV , Sitter CD , Shetty J , Smith TJ , Strong R , Sun J , Thomasova D , Ton LQ , Topalis P , Tu Z , Unger MF , Walenz B , Wang A , Wang J , Wang M , Wang X , Woodford KJ , Wortman JR , Wu M , Yao A , Zdobnov EM , Zhang H , Zhao Q , Zhao S , Zhu SC , Zhimulev I , Coluzzi M , della Torre A , Roth CW , Louis C , Kalush F , Mural RJ , Myers EW , Adams MD , Smith HO , Broder S , Gardner MJ , Fraser CM , Birney E , Bork P , Brey PT , Venter JC , Weissenbach J , Kafatos FC , Collins FH , Hoffman SL
Ref : Science , 298 :129 , 2002
Abstract : Anopheles gambiae is the principal vector of malaria, a disease that afflicts more than 500 million people and causes more than 1 million deaths each year. Tenfold shotgun sequence coverage was obtained from the PEST strain of A. gambiae and assembled into scaffolds that span 278 million base pairs. A total of 91% of the genome was organized in 303 scaffolds; the largest scaffold was 23.1 million base pairs. There was substantial genetic variation within this strain, and the apparent existence of two haplotypes of approximately equal frequency ("dual haplotypes") in a substantial fraction of the genome likely reflects the outbred nature of the PEST strain. The sequence produced a conservative inference of more than 400,000 single-nucleotide polymorphisms that showed a markedly bimodal density distribution. Analysis of the genome sequence revealed strong evidence for about 14,000 protein-encoding transcripts. Prominent expansions in specific families of proteins likely involved in cell adhesion and immunity were noted. An expressed sequence tag analysis of genes regulated by blood feeding provided insights into the physiological adaptations of a hematophagous insect.
ESTHER : Holt_2002_Science_298_129
PubMedSearch : Holt_2002_Science_298_129
PubMedID: 12364791
Gene_locus related to this paper: anoga-a0nb77 , anoga-a0nbp6 , anoga-a0neb7 , anoga-a0nei9 , anoga-a0nej0 , anoga-a0ngj1 , anoga-a7ut12 , anoga-a7uuz9 , anoga-ACHE1 , anoga-ACHE2 , anoga-agCG44620 , anoga-agCG44666 , anoga-agCG45273 , anoga-agCG45279 , anoga-agCG45511 , anoga-agCG46741 , anoga-agCG47651 , anoga-agCG47655 , anoga-agCG47661 , anoga-agCG47690 , anoga-agCG48797 , anoga-AGCG49362 , anoga-agCG49462 , anoga-agCG49870 , anoga-agCG49872 , anoga-agCG49876 , anoga-agCG50851 , anoga-agCG51879 , anoga-agCG52383 , anoga-agCG54954 , anoga-AGCG55021 , anoga-agCG55401 , anoga-agCG55408 , anoga-agCG56978 , anoga-ebiG239 , anoga-ebiG2660 , anoga-ebiG5718 , anoga-ebiG5974 , anoga-ebiG8504 , anoga-ebiG8742 , anoga-glita , anoga-nrtac , anoga-q5tpv0 , anoga-Q5TVS6 , anoga-q7pm39 , anoga-q7ppw9 , anoga-q7pq17 , anoga-Q7PQT0 , anoga-q7q8m4 , anoga-q7q626 , anoga-q7qa14 , anoga-q7qa52 , anoga-q7qal7 , anoga-q7qbj0 , anoga-f5hl20 , anoga-q7qkh2 , anoga-a0a1s4h1y7 , anoga-q7q887

Title : A comparison of whole-genome shotgun-derived mouse chromosome 16 and the human genome - Mural_2002_Science_296_1661
Author(s) : Mural RJ , Adams MD , Myers EW , Smith HO , Miklos GL , Wides R , Halpern A , Li PW , Sutton GG , Nadeau J , Salzberg SL , Holt RA , Kodira CD , Lu F , Chen L , Deng Z , Evangelista CC , Gan W , Heiman TJ , Li J , Li Z , Merkulov GV , Milshina NV , Naik AK , Qi R , Shue BC , Wang A , Wang J , Wang X , Yan X , Ye J , Yooseph S , Zhao Q , Zheng L , Zhu SC , Biddick K , Bolanos R , Delcher AL , Dew IM , Fasulo D , Flanigan MJ , Huson DH , Kravitz SA , Miller JR , Mobarry CM , Reinert K , Remington KA , Zhang Q , Zheng XH , Nusskern DR , Lai Z , Lei Y , Zhong W , Yao A , Guan P , Ji RR , Gu Z , Wang ZY , Zhong F , Xiao C , Chiang CC , Yandell M , Wortman JR , Amanatides PG , Hladun SL , Pratts EC , Johnson JE , Dodson KL , Woodford KJ , Evans CA , Gropman B , Rusch DB , Venter E , Wang M , Smith TJ , Houck JT , Tompkins DE , Haynes C , Jacob D , Chin SH , Allen DR , Dahlke CE , Sanders R , Li K , Liu X , Levitsky AA , Majoros WH , Chen Q , Xia AC , Lopez JR , Donnelly MT , Newman MH , Glodek A , Kraft CL , Nodell M , Ali F , An HJ , Baldwin-Pitts D , Beeson KY , Cai S , Carnes M , Carver A , Caulk PM , Center A , Chen YH , Cheng ML , Coyne MD , Crowder M , Danaher S , Davenport LB , Desilets R , Dietz SM , Doup L , Dullaghan P , Ferriera S , Fosler CR , Gire HC , Gluecksmann A , Gocayne JD , Gray J , Hart B , Haynes J , Hoover J , Howland T , Ibegwam C , Jalali M , Johns D , Kline L , Ma DS , MacCawley S , Magoon A , Mann F , May D , McIntosh TC , Mehta S , Moy L , Moy MC , Murphy BJ , Murphy SD , Nelson KA , Nuri Z , Parker KA , Prudhomme AC , Puri VN , Qureshi H , Raley JC , Reardon MS , Regier MA , Rogers YH , Romblad DL , Schutz J , Scott JL , Scott R , Sitter CD , Smallwood M , Sprague AC , Stewart E , Strong RV , Suh E , Sylvester K , Thomas R , Tint NN , Tsonis C , Wang G , Williams MS , Williams SM , Windsor SM , Wolfe K , Wu MM , Zaveri J , Chaturvedi K , Gabrielian AE , Ke Z , Sun J , Subramanian G , Venter JC , Pfannkoch CM , Barnstead M , Stephenson LD
Ref : Science , 296 :1661 , 2002
Abstract : The high degree of similarity between the mouse and human genomes is demonstrated through analysis of the sequence of mouse chromosome 16 (Mmu 16), which was obtained as part of a whole-genome shotgun assembly of the mouse genome. The mouse genome is about 10% smaller than the human genome, owing to a lower repetitive DNA content. Comparison of the structure and protein-coding potential of Mmu 16 with that of the homologous segments of the human genome identifies regions of conserved synteny with human chromosomes (Hsa) 3, 8, 12, 16, 21, and 22. Gene content and order are highly conserved between Mmu 16 and the syntenic blocks of the human genome. Of the 731 predicted genes on Mmu 16, 509 align with orthologs on the corresponding portions of the human genome, 44 are likely paralogous to these genes, and 164 genes have homologs elsewhere in the human genome; there are 14 genes for which we could find no human counterpart.
ESTHER : Mural_2002_Science_296_1661
PubMedSearch : Mural_2002_Science_296_1661
PubMedID: 12040188
Gene_locus related to this paper: mouse-ABH15 , mouse-Ces3b , mouse-Ces4a , mouse-dpp4 , mouse-FAP , mouse-Lipg , mouse-Q8C1A9 , mouse-rbbp9 , mouse-SERHL , mouse-SPG21 , mouse-w4vsp6

Title : The sequence of the human genome - Venter_2001_Science_291_1304
Author(s) : Venter JC , Adams MD , Myers EW , Li PW , Mural RJ , Sutton GG , Smith HO , Yandell M , Evans CA , Holt RA , Gocayne JD , Amanatides P , Ballew RM , Huson DH , Wortman JR , Zhang Q , Kodira CD , Zheng XH , Chen L , Skupski M , Subramanian G , Thomas PD , Zhang J , Gabor Miklos GL , Nelson C , Broder S , Clark AG , Nadeau J , McKusick VA , Zinder N , Levine AJ , Roberts RJ , Simon M , Slayman C , Hunkapiller M , Bolanos R , Delcher A , Dew I , Fasulo D , Flanigan M , Florea L , Halpern A , Hannenhalli S , Kravitz S , Levy S , Mobarry C , Reinert K , Remington K , Abu-Threideh J , Beasley E , Biddick K , Bonazzi V , Brandon R , Cargill M , Chandramouliswaran I , Charlab R , Chaturvedi K , Deng Z , Di Francesco V , Dunn P , Eilbeck K , Evangelista C , Gabrielian AE , Gan W , Ge W , Gong F , Gu Z , Guan P , Heiman TJ , Higgins ME , Ji RR , Ke Z , Ketchum KA , Lai Z , Lei Y , Li Z , Li J , Liang Y , Lin X , Lu F , Merkulov GV , Milshina N , Moore HM , Naik AK , Narayan VA , Neelam B , Nusskern D , Rusch DB , Salzberg S , Shao W , Shue B , Sun J , Wang Z , Wang A , Wang X , Wang J , Wei M , Wides R , Xiao C , Yan C , Yao A , Ye J , Zhan M , Zhang W , Zhang H , Zhao Q , Zheng L , Zhong F , Zhong W , Zhu S , Zhao S , Gilbert D , Baumhueter S , Spier G , Carter C , Cravchik A , Woodage T , Ali F , An H , Awe A , Baldwin D , Baden H , Barnstead M , Barrow I , Beeson K , Busam D , Carver A , Center A , Cheng ML , Curry L , Danaher S , Davenport L , Desilets R , Dietz S , Dodson K , Doup L , Ferriera S , Garg N , Gluecksmann A , Hart B , Haynes J , Haynes C , Heiner C , Hladun S , Hostin D , Houck J , Howland T , Ibegwam C , Johnson J , Kalush F , Kline L , Koduru S , Love A , Mann F , May D , McCawley S , McIntosh T , McMullen I , Moy M , Moy L , Murphy B , Nelson K , Pfannkoch C , Pratts E , Puri V , Qureshi H , Reardon M , Rodriguez R , Rogers YH , Romblad D , Ruhfel B , Scott R , Sitter C , Smallwood M , Stewart E , Strong R , Suh E , Thomas R , Tint NN , Tse S , Vech C , Wang G , Wetter J , Williams S , Williams M , Windsor S , Winn-Deen E , Wolfe K , Zaveri J , Zaveri K , Abril JF , Guigo R , Campbell MJ , Sjolander KV , Karlak B , Kejariwal A , Mi H , Lazareva B , Hatton T , Narechania A , Diemer K , Muruganujan A , Guo N , Sato S , Bafna V , Istrail S , Lippert R , Schwartz R , Walenz B , Yooseph S , Allen D , Basu A , Baxendale J , Blick L , Caminha M , Carnes-Stine J , Caulk P , Chiang YH , Coyne M , Dahlke C , Mays A , Dombroski M , Donnelly M , Ely D , Esparham S , Fosler C , Gire H , Glanowski S , Glasser K , Glodek A , Gorokhov M , Graham K , Gropman B , Harris M , Heil J , Henderson S , Hoover J , Jennings D , Jordan C , Jordan J , Kasha J , Kagan L , Kraft C , Levitsky A , Lewis M , Liu X , Lopez J , Ma D , Majoros W , McDaniel J , Murphy S , Newman M , Nguyen T , Nguyen N , Nodell M , Pan S , Peck J , Peterson M , Rowe W , Sanders R , Scott J , Simpson M , Smith T , Sprague A , Stockwell T , Turner R , Venter E , Wang M , Wen M , Wu D , Wu M , Xia A , Zandieh A , Zhu X
Ref : Science , 291 :1304 , 2001
Abstract : A 2.91-billion base pair (bp) consensus sequence of the euchromatic portion of the human genome was generated by the whole-genome shotgun sequencing method. The 14.8-billion bp DNA sequence was generated over 9 months from 27,271,853 high-quality sequence reads (5.11-fold coverage of the genome) from both ends of plasmid clones made from the DNA of five individuals. Two assembly strategies-a whole-genome assembly and a regional chromosome assembly-were used, each combining sequence data from Celera and the publicly funded genome effort. The public data were shredded into 550-bp segments to create a 2.9-fold coverage of those genome regions that had been sequenced, without including biases inherent in the cloning and assembly procedure used by the publicly funded group. This brought the effective coverage in the assemblies to eightfold, reducing the number and size of gaps in the final assembly over what would be obtained with 5.11-fold coverage. The two assembly strategies yielded very similar results that largely agree with independent mapping data. The assemblies effectively cover the euchromatic regions of the human chromosomes. More than 90% of the genome is in scaffold assemblies of 100,000 bp or more, and 25% of the genome is in scaffolds of 10 million bp or larger. Analysis of the genome sequence revealed 26,588 protein-encoding transcripts for which there was strong corroborating evidence and an additional approximately 12,000 computationally derived genes with mouse matches or other weak supporting evidence. Although gene-dense clusters are obvious, almost half the genes are dispersed in low G+C sequence separated by large tracts of apparently noncoding sequence. Only 1.1% of the genome is spanned by exons, whereas 24% is in introns, with 75% of the genome being intergenic DNA. Duplications of segmental blocks, ranging in size up to chromosomal lengths, are abundant throughout the genome and reveal a complex evolutionary history. Comparative genomic analysis indicates vertebrate expansions of genes associated with neuronal function, with tissue-specific developmental regulation, and with the hemostasis and immune systems. DNA sequence comparisons between the consensus sequence and publicly funded genome data provided locations of 2.1 million single-nucleotide polymorphisms (SNPs). A random pair of human haploid genomes differed at a rate of 1 bp per 1250 on average, but there was marked heterogeneity in the level of polymorphism across the genome. Less than 1% of all SNPs resulted in variation in proteins, but the task of determining which SNPs have functional consequences remains an open challenge.
ESTHER : Venter_2001_Science_291_1304
PubMedSearch : Venter_2001_Science_291_1304
PubMedID: 11181995
Gene_locus related to this paper: human-AADAC , human-ABHD1 , human-ABHD10 , human-ABHD11 , human-ACHE , human-BCHE , human-LDAH , human-ABHD18 , human-CMBL , human-ABHD17A , human-KANSL3 , human-LIPA , human-LYPLAL1 , human-NDRG2 , human-NLGN3 , human-NLGN4X , human-NLGN4Y , human-PAFAH2 , human-PREPL , human-RBBP9 , human-SPG21

Title : The genome sequence of Drosophila melanogaster - Adams_2000_Science_287_2185
Author(s) : Adams MD , Celniker SE , Holt RA , Evans CA , Gocayne JD , Amanatides PG , Scherer SE , Li PW , Hoskins RA , Galle RF , George RA , Lewis SE , Richards S , Ashburner M , Henderson SN , Sutton GG , Wortman JR , Yandell MD , Zhang Q , Chen LX , Brandon RC , Rogers YH , Blazej RG , Champe M , Pfeiffer BD , Wan KH , Doyle C , Baxter EG , Helt G , Nelson CR , Gabor GL , Abril JF , Agbayani A , An HJ , Andrews-Pfannkoch C , Baldwin D , Ballew RM , Basu A , Baxendale J , Bayraktaroglu L , Beasley EM , Beeson KY , Benos PV , Berman BP , Bhandari D , Bolshakov S , Borkova D , Botchan MR , Bouck J , Brokstein P , Brottier P , Burtis KC , Busam DA , Butler H , Cadieu E , Center A , Chandra I , Cherry JM , Cawley S , Dahlke C , Davenport LB , Davies P , de Pablos B , Delcher A , Deng Z , Mays AD , Dew I , Dietz SM , Dodson K , Doup LE , Downes M , Dugan-Rocha S , Dunkov BC , Dunn P , Durbin KJ , Evangelista CC , Ferraz C , Ferriera S , Fleischmann W , Fosler C , Gabrielian AE , Garg NS , Gelbart WM , Glasser K , Glodek A , Gong F , Gorrell JH , Gu Z , Guan P , Harris M , Harris NL , Harvey D , Heiman TJ , Hernandez JR , Houck J , Hostin D , Houston KA , Howland TJ , Wei MH , Ibegwam C , Jalali M , Kalush F , Karpen GH , Ke Z , Kennison JA , Ketchum KA , Kimmel BE , Kodira CD , Kraft C , Kravitz S , Kulp D , Lai Z , Lasko P , Lei Y , Levitsky AA , Li J , Li Z , Liang Y , Lin X , Liu X , Mattei B , McIntosh TC , McLeod MP , McPherson D , Merkulov G , Milshina NV , Mobarry C , Morris J , Moshrefi A , Mount SM , Moy M , Murphy B , Murphy L , Muzny DM , Nelson DL , Nelson DR , Nelson KA , Nixon K , Nusskern DR , Pacleb JM , Palazzolo M , Pittman GS , Pan S , Pollard J , Puri V , Reese MG , Reinert K , Remington K , Saunders RD , Scheeler F , Shen H , Shue BC , Siden-Kiamos I , Simpson M , Skupski MP , Smith T , Spier E , Spradling AC , Stapleton M , Strong R , Sun E , Svirskas R , Tector C , Turner R , Venter E , Wang AH , Wang X , Wang ZY , Wassarman DA , Weinstock GM , Weissenbach J , Williams SM , WoodageT , Worley KC , Wu D , Yang S , Yao QA , Ye J , Yeh RF , Zaveri JS , Zhan M , Zhang G , Zhao Q , Zheng L , Zheng XH , Zhong FN , Zhong W , Zhou X , Zhu S , Zhu X , Smith HO , Gibbs RA , Myers EW , Rubin GM , Venter JC
Ref : Science , 287 :2185 , 2000
Abstract : The fly Drosophila melanogaster is one of the most intensively studied organisms in biology and serves as a model system for the investigation of many developmental and cellular processes common to higher eukaryotes, including humans. We have determined the nucleotide sequence of nearly all of the approximately 120-megabase euchromatic portion of the Drosophila genome using a whole-genome shotgun sequencing strategy supported by extensive clone-based sequence and a high-quality bacterial artificial chromosome physical map. Efforts are under way to close the remaining gaps; however, the sequence is of sufficient accuracy and contiguity to be declared substantially complete and to support an initial analysis of genome structure and preliminary gene annotation and interpretation. The genome encodes approximately 13,600 genes, somewhat fewer than the smaller Caenorhabditis elegans genome, but with comparable functional diversity.
ESTHER : Adams_2000_Science_287_2185
PubMedSearch : Adams_2000_Science_287_2185
PubMedID: 10731132
Gene_locus related to this paper: drome-1vite , drome-2vite , drome-3vite , drome-a1z6g9 , drome-abhd2 , drome-ACHE , drome-b6idz4 , drome-BEM46 , drome-CG5707 , drome-CG5704 , drome-CG1309 , drome-CG1882 , drome-CG1986 , drome-CG2059 , drome-CG2493 , drome-CG2528 , drome-CG2772 , drome-CG3160 , drome-CG3344 , drome-CG3523 , drome-CG3524 , drome-CG3734 , drome-CG3739 , drome-CG3744 , drome-CG3841 , drome-CG4267 , drome-CG4382 , drome-CG4390 , drome-CG4572 , drome-CG4582 , drome-CG4851 , drome-CG4979 , drome-CG5068 , drome-CG5162 , drome-CG5355 , drome-CG5377 , drome-CG5397 , drome-CG5412 , drome-CG5665 , drome-CG5932 , drome-CG5966 , drome-CG6018 , drome-CG6113 , drome-CG6271 , drome-CG6283 , drome-CG6295 , drome-CG6296 , drome-CG6414 , drome-CG6431 , drome-CG6472 , drome-CG6567 , drome-CG6675 , drome-CG6753 , drome-CG6847 , drome-CG7329 , drome-CG7367 , drome-CG7529 , drome-CG7632 , drome-CG8058 , drome-CG8093 , drome-CG8233 , drome-CG8424 , drome-CG8425 , drome-CG9059 , drome-CG9186 , drome-CG9287 , drome-CG9289 , drome-CG9542 , drome-CG9858 , drome-CG9953 , drome-CG9966 , drome-CG10116 , drome-CG10163 , drome-CG10175 , drome-CG10339 , drome-CG10357 , drome-CG10982 , drome-CG11034 , drome-CG11055 , drome-CG11309 , drome-CG11319 , drome-CG11406 , drome-CG11598 , drome-CG11600 , drome-CG11608 , drome-CG11626 , drome-CG11935 , drome-CG12108 , drome-CG12869 , drome-CG13282 , drome-CG13562 , drome-CG13772 , drome-CG14034 , drome-nlg3 , drome-CG14717 , drome-CG15101 , drome-CG15102 , drome-CG15106 , drome-CG15111 , drome-CG15820 , drome-CG15821 , drome-CG15879 , drome-CG17097 , drome-CG17099 , drome-CG17101 , drome-CG17191 , drome-CG17192 , drome-CG17292 , drome-CG18258 , drome-CG18284 , drome-CG18301 , drome-CG18302 , drome-CG18493 , drome-CG18530 , drome-CG18641 , drome-CG18815 , drome-CG31089 , drome-CG31091 , drome-CG32333 , drome-CG32483 , drome-CG33174 , drome-dnlg1 , drome-este4 , drome-este6 , drome-GH02384 , drome-GH02439 , drome-glita , drome-KRAKEN , drome-lip1 , drome-LIP2 , drome-lip3 , drome-MESK2 , drome-nrtac , drome-OME , drome-q7k274 , drome-Q9VJN0 , drome-Q8IP31 , drome-q9vux3