Haas B

References (9)

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 : The genome sequence of Trypanosoma cruzi, etiologic agent of Chagas disease - El-Sayed_2005_Science_309_409
Author(s) : El-Sayed NM , Myler PJ , Bartholomeu DC , Nilsson D , Aggarwal G , Tran AN , Ghedin E , Worthey EA , Delcher AL , Blandin G , Westenberger SJ , Caler E , Cerqueira GC , Branche C , Haas B , Anupama A , Arner E , Aslund L , Attipoe P , Bontempi E , Bringaud F , Burton P , Cadag E , Campbell DA , Carrington M , Crabtree J , Darban H , da Silveira JF , de Jong P , Edwards K , Englund PT , Fazelina G , Feldblyum T , Ferella M , Frasch AC , Gull K , Horn D , Hou L , Huang Y , Kindlund E , Klingbeil M , Kluge S , Koo H , Lacerda D , Levin MJ , Lorenzi H , Louie T , Machado CR , McCulloch R , McKenna A , Mizuno Y , Mottram JC , Nelson S , Ochaya S , Osoegawa K , Pai G , Parsons M , Pentony M , Pettersson U , Pop M , Ramirez JL , Rinta J , Robertson L , Salzberg SL , Sanchez DO , Seyler A , Sharma R , Shetty J , Simpson AJ , Sisk E , Tammi MT , Tarleton R , Teixeira S , Van Aken S , Vogt C , Ward PN , Wickstead B , Wortman J , White O , Fraser CM , Stuart KD , Andersson B
Ref : Science , 309 :409 , 2005
Abstract : Whole-genome sequencing of the protozoan pathogen Trypanosoma cruzi revealed that the diploid genome contains a predicted 22,570 proteins encoded by genes, of which 12,570 represent allelic pairs. Over 50% of the genome consists of repeated sequences, such as retrotransposons and genes for large families of surface molecules, which include trans-sialidases, mucins, gp63s, and a large novel family (>1300 copies) of mucin-associated surface protein (MASP) genes. Analyses of the T. cruzi, T. brucei, and Leishmania major (Tritryp) genomes imply differences from other eukaryotes in DNA repair and initiation of replication and reflect their unusual mitochondrial DNA. Although the Tritryp lack several classes of signaling molecules, their kinomes contain a large and diverse set of protein kinases and phosphatases; their size and diversity imply previously unknown interactions and regulatory processes, which may be targets for intervention.
ESTHER : El-Sayed_2005_Science_309_409
PubMedSearch : El-Sayed_2005_Science_309_409
PubMedID: 16020725
Gene_locus related to this paper: tryb2-q6h9e3 , tryb2-q6ha27 , tryb2-q38cd5 , tryb2-q38cd6 , tryb2-q38cd7 , tryb2-q38dc1 , tryb2-q38de4 , tryb2-q38ds6 , tryb2-q38dx1 , tryb2-q380z6 , tryb2-q382l4 , tryb2-q383a9 , tryb2-q386e3 , tryb2-q387r7 , tryb2-q388n1 , tryb2-q389w3 , trybr-PEPTB , trycr-q4cq28 , trycr-q4cq94 , trycr-q4cq95 , trycr-q4cq96 , trycr-q4cqq5 , trycr-q4csm0 , trycr-q4cwv3 , trycr-q4cx66 , trycr-q4cxr6 , trycr-q4cyc3 , trycr-q4cyc5 , trycr-q4cyf6 , trycr-q4czy3 , trycr-q4d1s2 , trycr-q4d2n1 , trycr-q4d3a2 , trycr-q4d3x3 , trycr-q4d3y4 , trycr-q4d6h1 , trycr-q4d8h8 , trycr-q4d8h9 , trycr-q4d8i0 , trycr-q4d786 , trycr-q4d975 , trycr-q4da08 , trycr-q4dab1 , trycr-q4dap6 , trycr-q4dap7 , trycr-q4dbm2 , trycr-q4dbn1 , trycr-q4ddw7 , trycr-q4de42 , trycr-q4dhn8 , trycr-q4dkk8 , trycr-q4dkk9 , trycr-q4dm56 , trycr-q4dp03 , trycr-q4dqa6 , trycr-q4dry8 , trycr-q4dt91 , trycr-q4dvl8 , trycr-q4dvp1 , trycr-q4dvp2 , trycr-q4dw34 , trycr-q4dwm3 , trycr-q4dy49 , trycr-q4dy82 , trycr-q4dzp6 , trycr-q4e3m8 , trycr-q4e4t5 , trycr-q4e5d1 , trycr-q4e5z2 , trycr-q6y3z8 , trycr-Q94795 , trycr-TCPO

Title : The genome of the African trypanosome Trypanosoma brucei - Berriman_2005_Science_309_416
Author(s) : Berriman M , Ghedin E , Hertz-Fowler C , Blandin G , Renauld H , Bartholomeu DC , Lennard NJ , Caler E , Hamlin NE , Haas B , Bohme U , Hannick L , Aslett MA , Shallom J , Marcello L , Hou L , Wickstead B , Alsmark UC , Arrowsmith C , Atkin RJ , Barron AJ , Bringaud F , Brooks K , Carrington M , Cherevach I , Chillingworth TJ , Churcher C , Clark LN , Corton CH , Cronin A , Davies RM , Doggett J , Djikeng A , Feldblyum T , Field MC , Fraser A , Goodhead I , Hance Z , Harper D , Harris BR , Hauser H , Hostetler J , Ivens A , Jagels K , Johnson D , Johnson J , Jones K , Kerhornou AX , Koo H , Larke N , Landfear S , Larkin C , Leech V , Line A , Lord A , MacLeod A , Mooney PJ , Moule S , Martin DM , Morgan GW , Mungall K , Norbertczak H , Ormond D , Pai G , Peacock CS , Peterson J , Quail MA , Rabbinowitsch E , Rajandream MA , Reitter C , Salzberg SL , Sanders M , Schobel S , Sharp S , Simmonds M , Simpson AJ , Tallon L , Turner CM , Tait A , Tivey AR , Van Aken S , Walker D , Wanless D , Wang S , White B , White O , Whitehead S , Woodward J , Wortman J , Adams MD , Embley TM , Gull K , Ullu E , Barry JD , Fairlamb AH , Opperdoes F , Barrell BG , Donelson JE , Hall N , Fraser CM , Melville SE , El-Sayed NM
Ref : Science , 309 :416 , 2005
Abstract : African trypanosomes cause human sleeping sickness and livestock trypanosomiasis in sub-Saharan Africa. We present the sequence and analysis of the 11 megabase-sized chromosomes of Trypanosoma brucei. The 26-megabase genome contains 9068 predicted genes, including approximately 900 pseudogenes and approximately 1700 T. brucei-specific genes. Large subtelomeric arrays contain an archive of 806 variant surface glycoprotein (VSG) genes used by the parasite to evade the mammalian immune system. Most VSG genes are pseudogenes, which may be used to generate expressed mosaic genes by ectopic recombination. Comparisons of the cytoskeleton and endocytic trafficking systems with those of humans and other eukaryotic organisms reveal major differences. A comparison of metabolic pathways encoded by the genomes of T. brucei, T. cruzi, and Leishmania major reveals the least overall metabolic capability in T. brucei and the greatest in L. major. Horizontal transfer of genes of bacterial origin has contributed to some of the metabolic differences in these parasites, and a number of novel potential drug targets have been identified.
ESTHER : Berriman_2005_Science_309_416
PubMedSearch : Berriman_2005_Science_309_416
PubMedID: 16020726
Gene_locus related to this paper: tryb2-q6h9e3 , tryb2-q6ha27 , tryb2-q38cd5 , tryb2-q38cd6 , tryb2-q38cd7 , tryb2-q38dc1 , tryb2-q38de4 , tryb2-q38ds6 , tryb2-q38dx1 , tryb2-q380z6 , tryb2-q382c1 , tryb2-q382l4 , tryb2-q383a9 , tryb2-q386e3 , tryb2-q387r7 , tryb2-q388n1 , tryb2-q389w3 , trybr-PEPTB , trycr-q4cq28 , trycr-q4cq94 , trycr-q4cq95 , trycr-q4cq96 , trycr-q4csm0 , trycr-q4cwv3 , trycr-q4cx66 , trycr-q4cxr6 , trycr-q4cyc5 , trycr-q4cyf6 , trycr-q4d3a2 , trycr-q4d3x3 , trycr-q4d3y4 , trycr-q4d6h1 , trycr-q4d8h8 , trycr-q4d8h9 , trycr-q4d8i0 , trycr-q4d786 , trycr-q4d975 , trycr-q4da08 , trycr-q4dap6 , trycr-q4dbm2 , trycr-q4dbn1 , trycr-q4ddw7 , trycr-q4de42 , trycr-q4dhn8 , trycr-q4dkk8 , trycr-q4dkk9 , trycr-q4dm56 , trycr-q4dqa6 , trycr-q4dt91 , trycr-q4dvp2 , trycr-q4dw34 , trycr-q4dwm3 , trycr-q4dy49 , trycr-q4dy82 , trycr-q4dzp6 , trycr-q4e3m8 , trycr-q4e4t5 , trycr-q4e5d1 , trycr-q4e5z2

Title : Sequence, annotation, and analysis of synteny between rice chromosome 3 and diverged grass species - Buell_2005_Genome.Res_15_1284
Author(s) : Buell CR , Yuan Q , Ouyang S , Liu J , Zhu W , Wang A , Maiti R , Haas B , Wortman J , Pertea M , Jones KM , Kim M , Overton L , Tsitrin T , Fadrosh D , Bera J , Weaver B , Jin S , Johri S , Reardon M , Webb K , Hill J , Moffat K , Tallon L , Van Aken S , Lewis M , Utterback T , Feldblyum T , Zismann V , Iobst S , Hsiao J , de Vazeille AR , Salzberg SL , White O , Fraser C , Yu Y , Kim H , Rambo T , Currie J , Collura K , Kernodle-Thompson S , Wei F , Kudrna K , Ammiraju JS , Luo M , Goicoechea JL , Wing RA , Henry D , Oates R , Palmer M , Pries G , Saski C , Simmons J , Soderlund C , Nelson W , de la Bastide M , Spiegel L , Nascimento L , Huang E , Preston R , Zutavern T , Palmer LE , O'Shaughnessy A , Dike S , McCombie WR , Minx P , Cordum H , Wilson R , Jin W , Lee HR , Jiang J , Jackson S
Ref : Genome Res , 15 :1284 , 2005
Abstract : Rice (Oryza sativa L.) chromosome 3 is evolutionarily conserved across the cultivated cereals and shares large blocks of synteny with maize and sorghum, which diverged from rice more than 50 million years ago. To begin to completely understand this chromosome, we sequenced, finished, and annotated 36.1 Mb ( approximately 97%) from O. sativa subsp. japonica cv Nipponbare. Annotation features of the chromosome include 5915 genes, of which 913 are related to transposable elements. A putative function could be assigned to 3064 genes, with another 757 genes annotated as expressed, leaving 2094 that encode hypothetical proteins. Similarity searches against the proteome of Arabidopsis thaliana revealed putative homologs for 67% of the chromosome 3 proteins. Further searches of a nonredundant amino acid database, the Pfam domain database, plant Expressed Sequence Tags, and genomic assemblies from sorghum and maize revealed only 853 nontransposable element related proteins from chromosome 3 that lacked similarity to other known sequences. Interestingly, 426 of these have a paralog within the rice genome. A comparative physical map of the wild progenitor species, Oryza nivara, with japonica chromosome 3 revealed a high degree of sequence identity and synteny between these two species, which diverged approximately 10,000 years ago. Although no major rearrangements were detected, the deduced size of the O. nivara chromosome 3 was 21% smaller than that of japonica. Synteny between rice and other cereals using an integrated maize physical map and wheat genetic map was strikingly high, further supporting the use of rice and, in particular, chromosome 3, as a model for comparative studies among the cereals.
ESTHER : Buell_2005_Genome.Res_15_1284
PubMedSearch : Buell_2005_Genome.Res_15_1284
PubMedID: 16109971
Gene_locus related to this paper: orysa-Q852M6 , orysa-Q8S5X5 , orysa-Q84QZ6 , orysa-Q84QY7 , orysa-Q851E3 , orysa-q6ave2 , orysj-cgep , orysj-q0dud7 , orysj-q10j20 , orysj-q10ss2

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 : Sequence and analysis of chromosome 3 of the plant Arabidopsis thaliana - Salanoubat_2000_Nature_408_820
Author(s) : Salanoubat M , Lemcke K , Rieger M , Ansorge W , Unseld M , Fartmann B , Valle G , Blocker H , Perez-Alonso M , Obermaier B , Delseny M , Boutry M , Grivell LA , Mache R , Puigdomenech P , de Simone V , Choisne N , Artiguenave F , Robert C , Brottier P , Wincker P , Cattolico L , Weissenbach J , Saurin W , Quetier F , Schafer M , Muller-Auer S , Gabel C , Fuchs M , Benes V , Wurmbach E , Drzonek H , Erfle H , Jordan N , Bangert S , Wiedelmann R , Kranz H , Voss H , Holland R , Brandt P , Nyakatura G , Vezzi A , D'Angelo M , Pallavicini A , Toppo S , Simionati B , Conrad A , Hornischer K , Kauer G , Lohnert TH , Nordsiek G , Reichelt J , Scharfe M , Schon O , Bargues M , Terol J , Climent J , Navarro P , Collado C , Perez-Perez A , Ottenwalder B , Duchemin D , Cooke R , Laudie M , Berger-Llauro C , Purnelle B , Masuy D , de Haan M , Maarse AC , Alcaraz JP , Cottet A , Casacuberta E , Monfort A , Argiriou A , Flores M , Liguori R , Vitale D , Mannhaupt G , Haase D , Schoof H , Rudd S , Zaccaria P , Mewes HW , Mayer KF , Kaul S , Town CD , Koo HL , Tallon LJ , Jenkins J , Rooney T , Rizzo M , Walts A , Utterback T , Fujii CY , Shea TP , Creasy TH , Haas B , Maiti R , Wu D , Peterson J , Van Aken S , Pai G , Militscher J , Sellers P , Gill JE , Feldblyum TV , Preuss D , Lin X , Nierman WC , Salzberg SL , White O , Venter JC , Fraser CM , Kaneko T , Nakamura Y , Sato S , Kato T , Asamizu E , Sasamoto S , Kimura T , Idesawa K , Kawashima K , Kishida Y , Kiyokawa C , Kohara M , Matsumoto M , Matsuno A , Muraki A , Nakayama S , Nakazaki N , Shinpo S , Takeuchi C , Wada T , Watanabe A , Yamada M , Yasuda M , Tabata S
Ref : Nature , 408 :820 , 2000
Abstract : Arabidopsis thaliana is an important model system for plant biologists. In 1996 an international collaboration (the Arabidopsis Genome Initiative) was formed to sequence the whole genome of Arabidopsis and in 1999 the sequence of the first two chromosomes was reported. The sequence of the last three chromosomes and an analysis of the whole genome are reported in this issue. Here we present the sequence of chromosome 3, organized into four sequence segments (contigs). The two largest (13.5 and 9.2 Mb) correspond to the top (long) and the bottom (short) arms of chromosome 3, and the two small contigs are located in the genetically defined centromere. This chromosome encodes 5,220 of the roughly 25,500 predicted protein-coding genes in the genome. About 20% of the predicted proteins have significant homology to proteins in eukaryotic genomes for which the complete sequence is available, pointing to important conserved cellular functions among eukaryotes.
ESTHER : Salanoubat_2000_Nature_408_820
PubMedSearch : Salanoubat_2000_Nature_408_820
PubMedID: 11130713
Gene_locus related to this paper: arath-MES17 , arath-AT3G12150 , arath-At3g61680 , arath-AT3g62590 , arath-CXE12 , arath-eds1 , arath-SCP25 , arath-F1P2.110 , arath-F1P2.140 , arath-F11F8.28 , arath-F14D17.80 , arath-F16B3.4 , arath-SCP27 , arath-At3g50790 , arath-At3g05600 , arath-PAD4 , arath-At3g51000 , arath-SCP16 , arath-gid1 , arath-GID1B , arath-Q9LUG8 , arath-Q84JS1 , arath-Q9SFF6 , arath-q9m236 , arath-q9sr22 , arath-q9sr23 , arath-SCP7 , arath-SCP14 , arath-SCP15 , arath-SCP17 , arath-SCP36 , arath-SCP37 , arath-SCP39 , arath-SCP40 , arath-SCP49 , arath-T19F11.2

Title : Sequence and analysis of chromosome 1 of the plant Arabidopsis thaliana - Theologis_2000_Nature_408_816
Author(s) : Theologis A , Ecker JR , Palm CJ , Federspiel NA , Kaul S , White O , Alonso J , Altafi H , Araujo R , Bowman CL , Brooks SY , Buehler E , Chan A , Chao Q , Chen H , Cheuk RF , Chin CW , Chung MK , Conn L , Conway AB , Conway AR , Creasy TH , Dewar K , Dunn P , Etgu P , Feldblyum TV , Feng J , Fong B , Fujii CY , Gill JE , Goldsmith AD , Haas B , Hansen NF , Hughes B , Huizar L , Hunter JL , Jenkins J , Johnson-Hopson C , Khan S , Khaykin E , Kim CJ , Koo HL , Kremenetskaia I , Kurtz DB , Kwan A , Lam B , Langin-Hooper S , Lee A , Lee JM , Lenz CA , Li JH , Li Y , Lin X , Liu SX , Liu ZA , Luros JS , Maiti R , Marziali A , Militscher J , Miranda M , Nguyen M , Nierman WC , Osborne BI , Pai G , Peterson J , Pham PK , Rizzo M , Rooney T , Rowley D , Sakano H , Salzberg SL , Schwartz JR , Shinn P , Southwick AM , Sun H , Tallon LJ , Tambunga G , Toriumi MJ , Town CD , Utterback T , Van Aken S , Vaysberg M , Vysotskaia VS , Walker M , Wu D , Yu G , Fraser CM , Venter JC , Davis RW
Ref : Nature , 408 :816 , 2000
Abstract : The genome of the flowering plant Arabidopsis thaliana has five chromosomes. Here we report the sequence of the largest, chromosome 1, in two contigs of around 14.2 and 14.6 megabases. The contigs extend from the telomeres to the centromeric borders, regions rich in transposons, retrotransposons and repetitive elements such as the 180-base-pair repeat. The chromosome represents 25% of the genome and contains about 6,850 open reading frames, 236 transfer RNAs (tRNAs) and 12 small nuclear RNAs. There are two clusters of tRNA genes at different places on the chromosome. One consists of 27 tRNA(Pro) genes and the other contains 27 tandem repeats of tRNA(Tyr)-tRNA(Tyr)-tRNA(Ser) genes. Chromosome 1 contains about 300 gene families with clustered duplications. There are also many repeat elements, representing 8% of the sequence.
ESTHER : Theologis_2000_Nature_408_816
PubMedSearch : Theologis_2000_Nature_408_816
PubMedID: 11130712
Gene_locus related to this paper: arath-At1g05790 , arath-At1g09280 , arath-At1g09980 , arath-AT1G29120 , arath-AT1G52695 , arath-AT1G66900 , arath-At1g73750 , arath-AT1G73920 , arath-AT1G74640 , arath-AT1G76140 , arath-AT1G78210 , arath-clh1 , arath-F1O17.3 , arath-F1O17.4 , arath-F1O17.5 , arath-F5I6.3 , arath-At1g52700 , arath-F6D8.27 , arath-F6D8.32 , arath-F9L1.44 , arath-F9P14.11 , arath-F12A4.4 , arath-MES11 , arath-F14G24.2 , arath-F14G24.3 , arath-F14I3.4 , arath-F14O10.2 , arath-F16N3.25 , arath-LCAT2 , arath-At1g34340 , arath-MES15 , arath-CXE6 , arath-ICML1 , arath-At1g72620 , arath-LCAT1 , arath-PLA12 , arath-PLA15 , arath-PLA17 , arath-Q8L7S1 , arath-At1g15070 , arath-SCP2 , arath-SCP4 , arath-SCP5 , arath-SCP18 , arath-SCP32 , arath-SCP44 , arath-SCP45 , arath-SCPL6 , arath-F4IE65 , arath-At1g30370 , arath-T6L1.8 , arath-T6L1.20 , arath-T14P4.6 , arath-MES14 , arath-SCP3 , arath-AXR4 , arath-At1g10040 , arath-ZW18 , arath-pae2 , arath-pae1 , arath-a0a1p8awg3