Weinstock G

References (6)

Title : Whole-Genome Sequencing of Salmonella enterica subsp. enterica Serovar Cubana Strains Isolated from Agricultural Sources - Benahmed_2014_Genome.Announc_2_e01184
Author(s) : Benahmed FH , Gopinath GR , Wang H , Jean-Gilles Beaubrun J , Grim C , Cheng CM , McClelland M , Ayers S , Abbott J , Desai P , Frye JG , Weinstock G , Hammack TS , Hanes DE , Rasmussen MA , Davidson MK
Ref : Genome Announc , 2 : , 2014
Abstract : We report the draft genomes of Salmonella enterica subsp. enterica serovar Cubana strain CVM42234, isolated from chick feed in 2012, and S. Cubana strain 76814, isolated from swine in 2004. The genome sizes are 4,975,046 and 4,936,251 bp, respectively.
ESTHER : Benahmed_2014_Genome.Announc_2_e01184
PubMedSearch : Benahmed_2014_Genome.Announc_2_e01184
PubMedID: 24459266
Gene_locus related to this paper: salty-STY1441

Title : The genome of the model beetle and pest Tribolium castaneum - Richards_2008_Nature_452_949
Author(s) : Richards S , Gibbs RA , Weinstock GM , Brown SJ , Denell R , Beeman RW , Gibbs R , Bucher G , Friedrich M , Grimmelikhuijzen CJ , Klingler M , Lorenzen M , Roth S , Schroder R , Tautz D , Zdobnov EM , Muzny D , Attaway T , Bell S , Buhay CJ , Chandrabose MN , Chavez D , Clerk-Blankenburg KP , Cree A , Dao M , Davis C , Chacko J , Dinh H , Dugan-Rocha S , Fowler G , Garner TT , Garnes J , Gnirke A , Hawes A , Hernandez J , Hines S , Holder M , Hume J , Jhangiani SN , Joshi V , Khan ZM , Jackson L , Kovar C , Kowis A , Lee S , Lewis LR , Margolis J , Morgan M , Nazareth LV , Nguyen N , Okwuonu G , Parker D , Ruiz SJ , Santibanez J , Savard J , Scherer SE , Schneider B , Sodergren E , Vattahil S , Villasana D , White CS , Wright R , Park Y , Lord J , Oppert B , Brown S , Wang L , Weinstock G , Liu Y , Worley K , Elsik CG , Reese JT , Elhaik E , Landan G , Graur D , Arensburger P , Atkinson P , Beidler J , Demuth JP , Drury DW , Du YZ , Fujiwara H , Maselli V , Osanai M , Robertson HM , Tu Z , Wang JJ , Wang S , Song H , Zhang L , Werner D , Stanke M , Morgenstern B , Solovyev V , Kosarev P , Brown G , Chen HC , Ermolaeva O , Hlavina W , Kapustin Y , Kiryutin B , Kitts P , Maglott D , Pruitt K , Sapojnikov V , Souvorov A , Mackey AJ , Waterhouse RM , Wyder S , Kriventseva EV , Kadowaki T , Bork P , Aranda M , Bao R , Beermann A , Berns N , Bolognesi R , Bonneton F , Bopp D , Butts T , Chaumot A , Denell RE , Ferrier DE , Gordon CM , Jindra M , Lan Q , Lattorff HM , Laudet V , von Levetsow C , Liu Z , Lutz R , Lynch JA , da Fonseca RN , Posnien N , Reuter R , Schinko JB , Schmitt C , Schoppmeier M , Shippy TD , Simonnet F , Marques-Souza H , Tomoyasu Y , Trauner J , Van der Zee M , Vervoort M , Wittkopp N , Wimmer EA , Yang X , Jones AK , Sattelle DB , Ebert PR , Nelson D , Scott JG , Muthukrishnan S , Kramer KJ , Arakane Y , Zhu Q , Hogenkamp D , Dixit R , Jiang H , Zou Z , Marshall J , Elpidina E , Vinokurov K , Oppert C , Evans J , Lu Z , Zhao P , Sumathipala N , Altincicek B , Vilcinskas A , Williams M , Hultmark D , Hetru C , Hauser F , Cazzamali G , Williamson M , Li B , Tanaka Y , Predel R , Neupert S , Schachtner J , Verleyen P , Raible F , Walden KK , Angeli S , Foret S , Schuetz S , Maleszka R , Miller SC , Grossmann D
Ref : Nature , 452 :949 , 2008
Abstract : Tribolium castaneum is a member of the most species-rich eukaryotic order, a powerful model organism for the study of generalized insect development, and an important pest of stored agricultural products. We describe its genome sequence here. This omnivorous beetle has evolved the ability to interact with a diverse chemical environment, as shown by large expansions in odorant and gustatory receptors, as well as P450 and other detoxification enzymes. Development in Tribolium is more representative of other insects than is Drosophila, a fact reflected in gene content and function. For example, Tribolium has retained more ancestral genes involved in cell-cell communication than Drosophila, some being expressed in the growth zone crucial for axial elongation in short-germ development. Systemic RNA interference in T. castaneum functions differently from that in Caenorhabditis elegans, but nevertheless offers similar power for the elucidation of gene function and identification of targets for selective insect control.
ESTHER : Richards_2008_Nature_452_949
PubMedSearch : Richards_2008_Nature_452_949
PubMedID: 18362917
Gene_locus related to this paper: trica-ACHE1 , trica-ACHE2 , trica-d2a0g9 , trica-d2a0h0 , trica-d2a0w9 , trica-d2a0x0 , trica-d2a0x1 , trica-d2a0x3 , trica-d2a0x4.1 , trica-d2a0x4.2 , trica-d2a0x6 , trica-d2a2b8 , trica-d2a2h1 , trica-d2a3c3 , trica-d2a3g9 , trica-d2a5y5 , trica-d2a309 , trica-d2a514 , trica-d2a515 , trica-d2a516 , trica-d2a577 , trica-d2a578 , trica-d6w6x8 , trica-d6w7f9 , trica-d6w7h2 , trica-d6w8e7 , trica-d6w9c0 , trica-d6w855 , trica-d6wac8 , trica-d6wan4 , trica-d6wd50 , trica-d6wd73 , trica-d6wd74 , trica-A0A139WM97 , trica-d6wfu3 , trica-d6wgl2 , trica-d6wj57 , trica-d6wj59 , trica-d6wjs3 , trica-d6wl31 , trica-d6wnv1 , trica-d6wpl0 , trica-d6wqd6 , trica-d6wqr4 , trica-d6ws52 , trica-d6wsm0 , trica-d6wu38 , trica-d6wu39 , trica-d6wu40 , trica-d6wu41 , trica-d6wu44 , trica-d6wvk5 , trica-d6wvz7 , trica-d6wwu9 , trica-d6wwv0 , trica-d6wxz0 , trica-d6wyy1 , trica-d6wyy2 , trica-d6x0z2 , trica-d6x0z5 , trica-d6x0z6 , trica-d6x4b2 , trica-d6x4e8 , trica-d6x4e9 , trica-d6x197 , trica-d7eip7 , trica-d7eld3 , trica-d7us45 , trica-q5wm43 , trica-q5zex9 , trica-d6wie5 , trica-d6w7t0 , trica-d6x4h0 , trica-d6x4h1 , trica-a0a139wae8 , trica-a0a139wc96 , trica-d6x325 , trica-d2a4s2 , trica-d6wvw8

Title : The DNA sequence, annotation and analysis of human chromosome 3 - Muzny_2006_Nature_440_1194
Author(s) : Muzny DM , Scherer SE , Kaul R , Wang J , Yu J , Sudbrak R , Buhay CJ , Chen R , Cree A , Ding Y , Dugan-Rocha S , Gill R , Gunaratne P , Harris RA , Hawes AC , Hernandez J , Hodgson AV , Hume J , Jackson A , Khan ZM , Kovar-Smith C , Lewis LR , Lozado RJ , Metzker ML , Milosavljevic A , Miner GR , Morgan MB , Nazareth LV , Scott G , Sodergren E , Song XZ , Steffen D , Wei S , Wheeler DA , Wright MW , Worley KC , Yuan Y , Zhang Z , Adams CQ , Ansari-Lari MA , Ayele M , Brown MJ , Chen G , Chen Z , Clendenning J , Clerc-Blankenburg KP , Davis C , Delgado O , Dinh HH , Dong W , Draper H , Ernst S , Fu G , Gonzalez-Garay ML , Garcia DK , Gillett W , Gu J , Hao B , Haugen E , Havlak P , He X , Hennig S , Hu S , Huang W , Jackson LR , Jacob LS , Kelly SH , Kube M , Levy R , Li Z , Liu B , Liu J , Liu W , Lu J , Maheshwari M , Nguyen BV , Okwuonu GO , Palmeiri A , Pasternak S , Perez LM , Phelps KA , Plopper FJ , Qiang B , Raymond C , Rodriguez R , Saenphimmachak C , Santibanez J , Shen H , Shen Y , Subramanian S , Tabor PE , Verduzco D , Waldron L , Wang Q , Williams GA , Wong GK , Yao Z , Zhang J , Zhang X , Zhao G , Zhou J , Zhou Y , Nelson D , Lehrach H , Reinhardt R , Naylor SL , Yang H , Olson M , Weinstock G , Gibbs RA
Ref : Nature , 440 :1194 , 2006
Abstract : After the completion of a draft human genome sequence, the International Human Genome Sequencing Consortium has proceeded to finish and annotate each of the 24 chromosomes comprising the human genome. Here we describe the sequencing and analysis of human chromosome 3, one of the largest human chromosomes. Chromosome 3 comprises just four contigs, one of which currently represents the longest unbroken stretch of finished DNA sequence known so far. The chromosome is remarkable in having the lowest rate of segmental duplication in the genome. It also includes a chemokine receptor gene cluster as well as numerous loci involved in multiple human cancers such as the gene encoding FHIT, which contains the most common constitutive fragile site in the genome, FRA3B. Using genomic sequence from chimpanzee and rhesus macaque, we were able to characterize the breakpoints defining a large pericentric inversion that occurred some time after the split of Homininae from Ponginae, and propose an evolutionary history of the inversion.
ESTHER : Muzny_2006_Nature_440_1194
PubMedSearch : Muzny_2006_Nature_440_1194
PubMedID: 16641997
Gene_locus related to this paper: human-AADAC , human-AADACL2 , human-ABHD5 , human-ABHD6 , human-ABHD10 , human-ABHD14A , human-APEH , human-BCHE , human-CIB , human-LIPH , human-MGLL , human-NLGN1 , human-PLA1A

Title : The genome of the social amoeba Dictyostelium discoideum - Eichinger_2005_Nature_435_43
Author(s) : Eichinger L , Pachebat JA , Glockner G , Rajandream MA , Sucgang R , Berriman M , Song J , Olsen R , Szafranski K , Xu Q , Tunggal B , Kummerfeld S , Madera M , Konfortov BA , Rivero F , Bankier AT , Lehmann R , Hamlin N , Davies R , Gaudet P , Fey P , Pilcher K , Chen G , Saunders D , Sodergren E , Davis P , Kerhornou A , Nie X , Hall N , Anjard C , Hemphill L , Bason N , Farbrother P , Desany B , Just E , Morio T , Rost R , Churcher C , Cooper J , Haydock S , van Driessche N , Cronin A , Goodhead I , Muzny D , Mourier T , Pain A , Lu M , Harper D , Lindsay R , Hauser H , James K , Quiles M , Madan Babu M , Saito T , Buchrieser C , Wardroper A , Felder M , Thangavelu M , Johnson D , Knights A , Loulseged H , Mungall K , Oliver K , Price C , Quail MA , Urushihara H , Hernandez J , Rabbinowitsch E , Steffen D , Sanders M , Ma J , Kohara Y , Sharp S , Simmonds M , Spiegler S , Tivey A , Sugano S , White B , Walker D , Woodward J , Winckler T , Tanaka Y , Shaulsky G , Schleicher M , Weinstock G , Rosenthal A , Cox EC , Chisholm RL , Gibbs R , Loomis WF , Platzer M , Kay RR , Williams J , Dear PH , Noegel AA , Barrell B , Kuspa A
Ref : Nature , 435 :43 , 2005
Abstract : The social amoebae are exceptional in their ability to alternate between unicellular and multicellular forms. Here we describe the genome of the best-studied member of this group, Dictyostelium discoideum. The gene-dense chromosomes of this organism encode approximately 12,500 predicted proteins, a high proportion of which have long, repetitive amino acid tracts. There are many genes for polyketide synthases and ABC transporters, suggesting an extensive secondary metabolism for producing and exporting small molecules. The genome is rich in complex repeats, one class of which is clustered and may serve as centromeres. Partial copies of the extrachromosomal ribosomal DNA (rDNA) element are found at the ends of each chromosome, suggesting a novel telomere structure and the use of a common mechanism to maintain both the rDNA and chromosomal termini. A proteome-based phylogeny shows that the amoebozoa diverged from the animal-fungal lineage after the plant-animal split, but Dictyostelium seems to have retained more of the diversity of the ancestral genome than have plants, animals or fungi.
ESTHER : Eichinger_2005_Nature_435_43
PubMedSearch : Eichinger_2005_Nature_435_43
PubMedID: 15875012
Gene_locus related to this paper: dicdi-abhd , dicdi-ACHE , dicdi-apra , dicdi-cinbp , dicdi-CMBL , dicdi-crysp , dicdi-DPOA , dicdi-P90528 , dicdi-ppme1 , dicdi-Q8MYE7 , dicdi-q54cf7 , dicdi-q54cl7 , dicdi-q54cm0 , dicdi-q54ct5 , dicdi-q54cu1 , dicdi-q54d54 , dicdi-q54d66 , dicdi-q54dj5 , dicdi-q54dy7 , dicdi-q54ek1 , dicdi-q54eq6 , dicdi-q54et1 , dicdi-q54et7 , dicdi-q54f01 , dicdi-q54g24 , dicdi-q54g47 , dicdi-q54gi7 , dicdi-q54gw5 , dicdi-q54gx3 , dicdi-q54h23 , dicdi-q54h73 , dicdi-q54i38 , dicdi-q54ie5 , dicdi-q54in4 , dicdi-q54kz1 , dicdi-q54l36 , dicdi-q54li1 , dicdi-q54m29 , dicdi-q54n21 , dicdi-q54n35 , dicdi-q54n85 , dicdi-q54qe7 , dicdi-q54qi3 , dicdi-q54qk2 , dicdi-q54rl3 , dicdi-q54rl8 , dicdi-q54sy6 , dicdi-q54sz3 , dicdi-q54t49 , dicdi-q54t91 , dicdi-q54th2 , dicdi-q54u01 , dicdi-q54vc2 , dicdi-q54vw1 , dicdi-q54xe3 , dicdi-q54xl3 , dicdi-q54xu1 , dicdi-q54xu2 , dicdi-q54y48 , dicdi-q54yd0 , dicdi-q54ye0 , dicdi-q54yl1 , dicdi-q54yr8 , dicdi-q54z90 , dicdi-q55bx3 , dicdi-q55d01 , dicdi-q55d81 , dicdi-q55du6 , dicdi-q55eu1 , dicdi-q55eu8 , dicdi-q55fk4 , dicdi-q55gk7 , dicdi-Q54ZA6 , dicdi-q86h82 , dicdi-Q86HC9 , dicdi-Q86HM5 , dicdi-Q86HM6 , dicdi-q86iz7 , dicdi-q86jb6 , dicdi-Q86KU7 , dicdi-q550s3 , dicdi-q552c0 , dicdi-q553t5 , dicdi-q555e5 , dicdi-q555h0 , dicdi-q555h1 , dicdi-q557k5 , dicdi-q558u2 , dicdi-Q869Q8 , dicdi-u554 , dicdi-y9086 , dicdi-q54r44 , dicdi-f172a

Title : The DNA sequence of the human X chromosome - Ross_2005_Nature_434_325
Author(s) : Ross MT , Grafham DV , Coffey AJ , Scherer S , McLay K , Muzny D , Platzer M , Howell GR , Burrows C , Bird CP , Frankish A , Lovell FL , Howe KL , Ashurst JL , Fulton RS , Sudbrak R , Wen G , Jones MC , Hurles ME , Andrews TD , Scott CE , Searle S , Ramser J , Whittaker A , Deadman R , Carter NP , Hunt SE , Chen R , Cree A , Gunaratne P , Havlak P , Hodgson A , Metzker ML , Richards S , Scott G , Steffen D , Sodergren E , Wheeler DA , Worley KC , Ainscough R , Ambrose KD , Ansari-Lari MA , Aradhya S , Ashwell RI , Babbage AK , Bagguley CL , Ballabio A , Banerjee R , Barker GE , Barlow KF , Barrett IP , Bates KN , Beare DM , Beasley H , Beasley O , Beck A , Bethel G , Blechschmidt K , Brady N , Bray-Allen S , Bridgeman AM , Brown AJ , Brown MJ , Bonnin D , Bruford EA , Buhay C , Burch P , Burford D , Burgess J , Burrill W , Burton J , Bye JM , Carder C , Carrel L , Chako J , Chapman JC , Chavez D , Chen E , Chen G , Chen Y , Chen Z , Chinault C , Ciccodicola A , Clark SY , Clarke G , Clee CM , Clegg S , Clerc-Blankenburg K , Clifford K , Cobley V , Cole CG , Conquer JS , Corby N , Connor RE , David R , Davies J , Davis C , Davis J , Delgado O , Deshazo D , Dhami P , Ding Y , Dinh H , Dodsworth S , Draper H , Dugan-Rocha S , Dunham A , Dunn M , Durbin KJ , Dutta I , Eades T , Ellwood M , Emery-Cohen A , Errington H , Evans KL , Faulkner L , Francis F , Frankland J , Fraser AE , Galgoczy P , Gilbert J , Gill R , Glockner G , Gregory SG , Gribble S , Griffiths C , Grocock R , Gu Y , Gwilliam R , Hamilton C , Hart EA , Hawes A , Heath PD , Heitmann K , Hennig S , Hernandez J , Hinzmann B , Ho S , Hoffs M , Howden PJ , Huckle EJ , Hume J , Hunt PJ , Hunt AR , Isherwood J , Jacob L , Johnson D , Jones S , de Jong PJ , Joseph SS , Keenan S , Kelly S , Kershaw JK , Khan Z , Kioschis P , Klages S , Knights AJ , Kosiura A , Kovar-Smith C , Laird GK , Langford C , Lawlor S , Leversha M , Lewis L , Liu W , Lloyd C , Lloyd DM , Loulseged H , Loveland JE , Lovell JD , Lozado R , Lu J , Lyne R , Ma J , Maheshwari M , Matthews LH , McDowall J , Mclaren S , McMurray A , Meidl P , Meitinger T , Milne S , Miner G , Mistry SL , Morgan M , Morris S , Muller I , Mullikin JC , Nguyen N , Nordsiek G , Nyakatura G , O'Dell CN , Okwuonu G , Palmer S , Pandian R , Parker D , Parrish J , Pasternak S , Patel D , Pearce AV , Pearson DM , Pelan SE , Perez L , Porter KM , Ramsey Y , Reichwald K , Rhodes S , Ridler KA , Schlessinger D , Schueler MG , Sehra HK , Shaw-Smith C , Shen H , Sheridan EM , Shownkeen R , Skuce CD , Smith ML , Sotheran EC , Steingruber HE , Steward CA , Storey R , Swann RM , Swarbreck D , Tabor PE , Taudien S , Taylor T , Teague B , Thomas K , Thorpe A , Timms K , Tracey A , Trevanion S , Tromans AC , d'Urso M , Verduzco D , Villasana D , Waldron L , Wall M , Wang Q , Warren J , Warry GL , Wei X , West A , Whitehead SL , Whiteley MN , Wilkinson JE , Willey DL , Williams G , Williams L , Williamson A , Williamson H , Wilming L , Woodmansey RL , Wray PW , Yen J , Zhang J , Zhou J , Zoghbi H , Zorilla S , Buck D , Reinhardt R , Poustka A , Rosenthal A , Lehrach H , Meindl A , Minx PJ , Hillier LW , Willard HF , Wilson RK , Waterston RH , Rice CM , Vaudin M , Coulson A , Nelson DL , Weinstock G , Sulston JE , Durbin R , Hubbard T , Gibbs RA , Beck S , Rogers J , Bentley DR
Ref : Nature , 434 :325 , 2005
Abstract : The human X chromosome has a unique biology that was shaped by its evolution as the sex chromosome shared by males and females. We have determined 99.3% of the euchromatic sequence of the X chromosome. Our analysis illustrates the autosomal origin of the mammalian sex chromosomes, the stepwise process that led to the progressive loss of recombination between X and Y, and the extent of subsequent degradation of the Y chromosome. LINE1 repeat elements cover one-third of the X chromosome, with a distribution that is consistent with their proposed role as way stations in the process of X-chromosome inactivation. We found 1,098 genes in the sequence, of which 99 encode proteins expressed in testis and in various tumour types. A disproportionately high number of mendelian diseases are documented for the X chromosome. Of this number, 168 have been explained by mutations in 113 X-linked genes, which in many cases were characterized with the aid of the DNA sequence.
ESTHER : Ross_2005_Nature_434_325
PubMedSearch : Ross_2005_Nature_434_325
PubMedID: 15772651
Gene_locus related to this paper: human-NLGN3 , human-NLGN4X

Title : Finishing a whole-genome shotgun: release 3 of the Drosophila melanogaster euchromatic genome sequence - Celniker_2002_Genome.Biol_3_RESEARCH0079
Author(s) : Celniker SE , Wheeler DA , Kronmiller B , Carlson JW , Halpern A , Patel S , Adams M , Champe M , Dugan SP , Frise E , Hodgson A , George RA , Hoskins RA , Laverty T , Muzny DM , Nelson CR , Pacleb JM , Park S , Pfeiffer BD , Richards S , Sodergren EJ , Svirskas R , Tabor PE , Wan K , Stapleton M , Sutton GG , Venter C , Weinstock G , Scherer SE , Myers EW , Gibbs RA , Rubin GM
Ref : Genome Biol , 3 :RESEARCH0079 , 2002
Abstract : BACKGROUND: The Drosophila melanogaster genome was the first metazoan genome to have been sequenced by the whole-genome shotgun (WGS) method. Two issues relating to this achievement were widely debated in the genomics community: how correct is the sequence with respect to base-pair (bp) accuracy and frequency of assembly errors? And, how difficult is it to bring a WGS sequence to the accepted standard for finished sequence? We are now in a position to answer these questions.
RESULTS: Our finishing process was designed to close gaps, improve sequence quality and validate the assembly. Sequence traces derived from the WGS and draft sequencing of individual bacterial artificial chromosomes (BACs) were assembled into BAC-sized segments. These segments were brought to high quality, and then joined to constitute the sequence of each chromosome arm. Overall assembly was verified by comparison to a physical map of fingerprinted BAC clones. In the current version of the 116.9 Mb euchromatic genome, called Release 3, the six euchromatic chromosome arms are represented by 13 scaffolds with a total of 37 sequence gaps. We compared Release 3 to Release 2; in autosomal regions of unique sequence, the error rate of Release 2 was one in 20,000 bp.
CONCLUSIONS: The WGS strategy can efficiently produce a high-quality sequence of a metazoan genome while generating the reagents required for sequence finishing. However, the initial method of repeat assembly was flawed. The sequence we report here, Release 3, is a reliable resource for molecular genetic experimentation and computational analysis.
ESTHER : Celniker_2002_Genome.Biol_3_RESEARCH0079
PubMedSearch : Celniker_2002_Genome.Biol_3_RESEARCH0079
PubMedID: 12537568
Gene_locus related to this paper: drome-CG8058 , drome-CG9542 , drome-CG11309 , drome-CG11406 , drome-CG17097 , drome-CG17374 , drome-glita , drome-KRAKEN