Kirkness EF

References (13)

Title : Widespread divergence between incipient Anopheles gambiae species revealed by whole genome sequences - Lawniczak_2010_Science_330_512
Author(s) : Lawniczak MK , Emrich SJ , Holloway AK , Regier AP , Olson M , White B , Redmond S , Fulton L , Appelbaum E , Godfrey J , Farmer C , Chinwalla A , Yang SP , Minx P , Nelson J , Kyung K , Walenz BP , Garcia-Hernandez E , Aguiar M , Viswanathan LD , Rogers YH , Strausberg RL , Saski CA , Lawson D , Collins FH , Kafatos FC , Christophides GK , Clifton SW , Kirkness EF , Besansky NJ
Ref : Science , 330 :512 , 2010
Abstract : The Afrotropical mosquito Anopheles gambiae sensu stricto, a major vector of malaria, is currently undergoing speciation into the M and S molecular forms. These forms have diverged in larval ecology and reproductive behavior through unknown genetic mechanisms, despite considerable levels of hybridization. Previous genome-wide scans using gene-based microarrays uncovered divergence between M and S that was largely confined to gene-poor pericentromeric regions, prompting a speciation-with-ongoing-gene-flow model that implicated only about 3% of the genome near centromeres in the speciation process. Here, based on the complete M and S genome sequences, we report widespread and heterogeneous genomic divergence inconsistent with appreciable levels of interform gene flow, suggesting a more advanced speciation process and greater challenges to identify genes critical to initiating that process.
ESTHER : Lawniczak_2010_Science_330_512
PubMedSearch : Lawniczak_2010_Science_330_512
PubMedID: 20966253
Gene_locus related to this paper: anoga-Q7PVF9 , anoga-q7q837 , 9dipt-a0a182ksz6 , anost-a0a182xxz0 , anost-a0a182xzf1 , anoga-q7q887

Title : The dynamic genome of Hydra - Chapman_2010_Nature_464_592
Author(s) : Chapman JA , Kirkness EF , Simakov O , Hampson SE , Mitros T , Weinmaier T , Rattei T , Balasubramanian PG , Borman J , Busam D , Disbennett K , Pfannkoch C , Sumin N , Sutton GG , Viswanathan LD , Walenz B , Goodstein DM , Hellsten U , Kawashima T , Prochnik SE , Putnam NH , Shu S , Blumberg B , Dana CE , Gee L , Kibler DF , Law L , Lindgens D , Martinez DE , Peng J , Wigge PA , Bertulat B , Guder C , Nakamura Y , Ozbek S , Watanabe H , Khalturin K , Hemmrich G , Franke A , Augustin R , Fraune S , Hayakawa E , Hayakawa S , Hirose M , Hwang JS , Ikeo K , Nishimiya-Fujisawa C , Ogura A , Takahashi T , Steinmetz PR , Zhang X , Aufschnaiter R , Eder MK , Gorny AK , Salvenmoser W , Heimberg AM , Wheeler BM , Peterson KJ , Bottger A , Tischler P , Wolf A , Gojobori T , Remington KA , Strausberg RL , Venter JC , Technau U , Hobmayer B , Bosch TC , Holstein TW , Fujisawa T , Bode HR , David CN , Rokhsar DS , Steele RE
Ref : Nature , 464 :592 , 2010
Abstract : The freshwater cnidarian Hydra was first described in 1702 and has been the object of study for 300 years. Experimental studies of Hydra between 1736 and 1744 culminated in the discovery of asexual reproduction of an animal by budding, the first description of regeneration in an animal, and successful transplantation of tissue between animals. Today, Hydra is an important model for studies of axial patterning, stem cell biology and regeneration. Here we report the genome of Hydra magnipapillata and compare it to the genomes of the anthozoan Nematostella vectensis and other animals. The Hydra genome has been shaped by bursts of transposable element expansion, horizontal gene transfer, trans-splicing, and simplification of gene structure and gene content that parallel simplification of the Hydra life cycle. We also report the sequence of the genome of a novel bacterium stably associated with H. magnipapillata. Comparisons of the Hydra genome to the genomes of other animals shed light on the evolution of epithelia, contractile tissues, developmentally regulated transcription factors, the Spemann-Mangold organizer, pluripotency genes and the neuromuscular junction.
ESTHER : Chapman_2010_Nature_464_592
PubMedSearch : Chapman_2010_Nature_464_592
PubMedID: 20228792
Gene_locus related to this paper: 9burk-c9y6c0 , 9burk-c9y8q9 , 9burk-c9y9d4 , 9burk-c9ya28 , 9burk-c9yb37 , 9burk-c9ycr9 , 9burk-c9ydq0 , 9burk-c9ydr2 , 9burk-c9yew1 , 9burk-c9yf78 , 9burk-c9ygh2 , 9burk-c9y7j2

Title : Genome sequences of the human body louse and its primary endosymbiont provide insights into the permanent parasitic lifestyle - Kirkness_2010_Proc.Natl.Acad.Sci.U.S.A_107_12168
Author(s) : Kirkness EF , Haas BJ , Sun W , Braig HR , Perotti MA , Clark JM , Lee SH , Robertson HM , Kennedy RC , Elhaik E , Gerlach D , Kriventseva EV , Elsik CG , Graur D , Hill CA , Veenstra JA , Walenz B , Tubio JM , Ribeiro JM , Rozas J , Johnston JS , Reese JT , Popadic A , Tojo M , Raoult D , Reed DL , Tomoyasu Y , Kraus E , Mittapalli O , Margam VM , Li HM , Meyer JM , Johnson RM , Romero-Severson J , Vanzee JP , Alvarez-Ponce D , Vieira FG , Aguade M , Guirao-Rico S , Anzola JM , Yoon KS , Strycharz JP , Unger MF , Christley S , Lobo NF , Seufferheld MJ , Wang N , Dasch GA , Struchiner CJ , Madey G , Hannick LI , Bidwell S , Joardar V , Caler E , Shao R , Barker SC , Cameron S , Bruggner RV , Regier A , Johnson J , Viswanathan L , Utterback TR , Sutton GG , Lawson D , Waterhouse RM , Venter JC , Strausberg RL , Berenbaum MR , Collins FH , Zdobnov EM , Pittendrigh BR
Ref : Proc Natl Acad Sci U S A , 107 :12168 , 2010
Abstract : As an obligatory parasite of humans, the body louse (Pediculus humanus humanus) is an important vector for human diseases, including epidemic typhus, relapsing fever, and trench fever. Here, we present genome sequences of the body louse and its primary bacterial endosymbiont Candidatus Riesia pediculicola. The body louse has the smallest known insect genome, spanning 108 Mb. Despite its status as an obligate parasite, it retains a remarkably complete basal insect repertoire of 10,773 protein-coding genes and 57 microRNAs. Representing hemimetabolous insects, the genome of the body louse thus provides a reference for studies of holometabolous insects. Compared with other insect genomes, the body louse genome contains significantly fewer genes associated with environmental sensing and response, including odorant and gustatory receptors and detoxifying enzymes. The unique architecture of the 18 minicircular mitochondrial chromosomes of the body louse may be linked to the loss of the gene encoding the mitochondrial single-stranded DNA binding protein. The genome of the obligatory louse endosymbiont Candidatus Riesia pediculicola encodes less than 600 genes on a short, linear chromosome and a circular plasmid. The plasmid harbors a unique arrangement of genes required for the synthesis of pantothenate, an essential vitamin deficient in the louse diet. The human body louse, its primary endosymbiont, and the bacterial pathogens that it vectors all possess genomes reduced in size compared with their free-living close relatives. Thus, the body louse genome project offers unique information and tools to use in advancing understanding of coevolution among vectors, symbionts, and pathogens.
ESTHER : Kirkness_2010_Proc.Natl.Acad.Sci.U.S.A_107_12168
PubMedSearch : Kirkness_2010_Proc.Natl.Acad.Sci.U.S.A_107_12168
PubMedID: 20566863
Gene_locus related to this paper: pedhb-ACHE1 , pedhb-ACHE2 , pedhc-e0v9b5 , pedhc-e0v9b6 , pedhc-e0v9b7 , pedhc-e0vbv5 , pedhc-e0vcd0 , pedhc-e0vcl7 , pedhc-e0vd69 , pedhc-e0ve50 , pedhc-e0vel6 , pedhc-e0vel7 , pedhc-e0vf98 , pedhc-e0vfs8 , pedhc-e0vfv0 , pedhc-e0vg01 , pedhc-e0vha2 , pedhc-e0vha4 , pedhc-e0vi52 , pedhc-e0vp42 , pedhc-e0vqu6 , pedhc-e0vuj9 , pedhc-e0vup6 , pedhc-e0vv55 , pedhc-e0vwv3 , pedhc-e0vxf7 , pedhc-e0vxg1 , pedhc-e0w4a6 , pedhc-e0w4c8 , pedhc-e0w271 , pedhc-e0w444 , pedhc-e0vym0 , pedhc-e0vdk9 , pedhc-e0vk10 , pedhc-e0vgw4 , pedhc-e0vgw7 , pedhc-e0vga1 , pedhc-e0w3s1 , pedhc-e0vzt2

Title : Evolution of genes and genomes on the Drosophila phylogeny - Clark_2007_Nature_450_203
Author(s) : Clark AG , Eisen MB , Smith DR , Bergman CM , Oliver B , Markow TA , Kaufman TC , Kellis M , Gelbart W , Iyer VN , Pollard DA , Sackton TB , Larracuente AM , Singh ND , Abad JP , Abt DN , Adryan B , Aguade M , Akashi H , Anderson WW , Aquadro CF , Ardell DH , Arguello R , Artieri CG , Barbash DA , Barker D , Barsanti P , Batterham P , Batzoglou S , Begun D , Bhutkar A , Blanco E , Bosak SA , Bradley RK , Brand AD , Brent MR , Brooks AN , Brown RH , Butlin RK , Caggese C , Calvi BR , Bernardo de Carvalho A , Caspi A , Castrezana S , Celniker SE , Chang JL , Chapple C , Chatterji S , Chinwalla A , Civetta A , Clifton SW , Comeron JM , Costello JC , Coyne JA , Daub J , David RG , Delcher AL , Delehaunty K , Do CB , Ebling H , Edwards K , Eickbush T , Evans JD , Filipski A , Findeiss S , Freyhult E , Fulton L , Fulton R , Garcia AC , Gardiner A , Garfield DA , Garvin BE , Gibson G , Gilbert D , Gnerre S , Godfrey J , Good R , Gotea V , Gravely B , Greenberg AJ , Griffiths-Jones S , Gross S , Guigo R , Gustafson EA , Haerty W , Hahn MW , Halligan DL , Halpern AL , Halter GM , Han MV , Heger A , Hillier L , Hinrichs AS , Holmes I , Hoskins RA , Hubisz MJ , Hultmark D , Huntley MA , Jaffe DB , Jagadeeshan S , Jeck WR , Johnson J , Jones CD , Jordan WC , Karpen GH , Kataoka E , Keightley PD , Kheradpour P , Kirkness EF , Koerich LB , Kristiansen K , Kudrna D , Kulathinal RJ , Kumar S , Kwok R , Lander E , Langley CH , Lapoint R , Lazzaro BP , Lee SJ , Levesque L , Li R , Lin CF , Lin MF , Lindblad-Toh K , Llopart A , Long M , Low L , Lozovsky E , Lu J , Luo M , Machado CA , Makalowski W , Marzo M , Matsuda M , Matzkin L , McAllister B , McBride CS , McKernan B , McKernan K , Mendez-Lago M , Minx P , Mollenhauer MU , Montooth K , Mount SM , Mu X , Myers E , Negre B , Newfeld S , Nielsen R , Noor MA , O'Grady P , Pachter L , Papaceit M , Parisi MJ , Parisi M , Parts L , Pedersen JS , Pesole G , Phillippy AM , Ponting CP , Pop M , Porcelli D , Powell JR , Prohaska S , Pruitt K , Puig M , Quesneville H , Ram KR , Rand D , Rasmussen MD , Reed LK , Reenan R , Reily A , Remington KA , Rieger TT , Ritchie MG , Robin C , Rogers YH , Rohde C , Rozas J , Rubenfield MJ , Ruiz A , Russo S , Salzberg SL , Sanchez-Gracia A , Saranga DJ , Sato H , Schaeffer SW , Schatz MC , Schlenke T , Schwartz R , Segarra C , Singh RS , Sirot L , Sirota M , Sisneros NB , Smith CD , Smith TF , Spieth J , Stage DE , Stark A , Stephan W , Strausberg RL , Strempel S , Sturgill D , Sutton G , Sutton GG , Tao W , Teichmann S , Tobari YN , Tomimura Y , Tsolas JM , Valente VL , Venter E , Venter JC , Vicario S , Vieira FG , Vilella AJ , Villasante A , Walenz B , Wang J , Wasserman M , Watts T , Wilson D , Wilson RK , Wing RA , Wolfner MF , Wong A , Wong GK , Wu CI , Wu G , Yamamoto D , Yang HP , Yang SP , Yorke JA , Yoshida K , Zdobnov E , Zhang P , Zhang Y , Zimin AV , Baldwin J , Abdouelleil A , Abdulkadir J , Abebe A , Abera B , Abreu J , Acer SC , Aftuck L , Alexander A , An P , Anderson E , Anderson S , Arachi H , Azer M , Bachantsang P , Barry A , Bayul T , Berlin A , Bessette D , Bloom T , Blye J , Boguslavskiy L , Bonnet C , Boukhgalter B , Bourzgui I , Brown A , Cahill P , Channer S , Cheshatsang Y , Chuda L , Citroen M , Collymore A , Cooke P , Costello M , D'Aco K , Daza R , De Haan G , DeGray S , DeMaso C , Dhargay N , Dooley K , Dooley E , Doricent M , Dorje P , Dorjee K , Dupes A , Elong R , Falk J , Farina A , Faro S , Ferguson D , Fisher S , Foley CD , Franke A , Friedrich D , Gadbois L , Gearin G , Gearin CR , Giannoukos G , Goode T , Graham J , Grandbois E , Grewal S , Gyaltsen K , Hafez N , Hagos B , Hall J , Henson C , Hollinger A , Honan T , Huard MD , Hughes L , Hurhula B , Husby ME , Kamat A , Kanga B , Kashin S , Khazanovich D , Kisner P , Lance K , Lara M , Lee W , Lennon N , Letendre F , LeVine R , Lipovsky A , Liu X , Liu J , Liu S , Lokyitsang T , Lokyitsang Y , Lubonja R , Lui A , Macdonald P , Magnisalis V , Maru K , Matthews C , McCusker W , McDonough S , Mehta T , Meldrim J , Meneus L , Mihai O , Mihalev A , Mihova T , Mittelman R , Mlenga V , Montmayeur A , Mulrain L , Navidi A , Naylor J , Negash T , Nguyen T , Nguyen N , Nicol R , Norbu C , Norbu N , Novod N , O'Neill B , Osman S , Markiewicz E , Oyono OL , Patti C , Phunkhang P , Pierre F , Priest M , Raghuraman S , Rege F , Reyes R , Rise C , Rogov P , Ross K , Ryan E , Settipalli S , Shea T , Sherpa N , Shi L , Shih D , Sparrow T , Spaulding J , Stalker J , Stange-Thomann N , Stavropoulos S , Stone C , Strader C , Tesfaye S , Thomson T , Thoulutsang Y , Thoulutsang D , Topham K , Topping I , Tsamla T , Vassiliev H , Vo A , Wangchuk T , Wangdi T , Weiand M , Wilkinson J , Wilson A , Yadav S , Young G , Yu Q , Zembek L , Zhong D , Zimmer A , Zwirko Z , Alvarez P , Brockman W , Butler J , Chin C , Grabherr M , Kleber M , Mauceli E , MacCallum I
Ref : Nature , 450 :203 , 2007
Abstract : Comparative analysis of multiple genomes in a phylogenetic framework dramatically improves the precision and sensitivity of evolutionary inference, producing more robust results than single-genome analyses can provide. The genomes of 12 Drosophila species, ten of which are presented here for the first time (sechellia, simulans, yakuba, erecta, ananassae, persimilis, willistoni, mojavensis, virilis and grimshawi), illustrate how rates and patterns of sequence divergence across taxa can illuminate evolutionary processes on a genomic scale. These genome sequences augment the formidable genetic tools that have made Drosophila melanogaster a pre-eminent model for animal genetics, and will further catalyse fundamental research on mechanisms of development, cell biology, genetics, disease, neurobiology, behaviour, physiology and evolution. Despite remarkable similarities among these Drosophila species, we identified many putatively non-neutral changes in protein-coding genes, non-coding RNA genes, and cis-regulatory regions. These may prove to underlie differences in the ecology and behaviour of these diverse species.
ESTHER : Clark_2007_Nature_450_203
PubMedSearch : Clark_2007_Nature_450_203
PubMedID: 17994087
Gene_locus related to this paper: droan-ACHE , droan-b3lx10 , droan-b3lx75 , droan-b3lxv7 , droan-b3ly87 , droan-b3lyh4 , droan-b3lyh5 , droan-b3lyh7 , droan-b3lyh9 , droan-b3lyi0 , droan-b3lyi2 , droan-b3lyi3 , droan-b3lyi4 , droan-b3lyj8 , droan-b3lyj9 , droan-b3lyx4 , droan-b3lyx5 , droan-b3lyx6 , droan-b3lyx7 , droan-b3lyx9 , droan-b3lz72 , droan-b3m1x3 , droan-b3m2d4 , droan-b3m3d9 , droan-b3m4e3 , droan-b3m5w1 , droan-b3m6i7 , droan-b3m7v2 , droan-b3m9a5 , droan-b3m9f4 , droan-b3m9p3 , droan-b3m254 , droan-b3m259 , droan-b3m260 , droan-b3m262 , droan-b3m524 , droan-b3m635 , droan-b3m845 , droan-b3m846 , droan-b3md01 , droan-b3mdh7 , droan-b3mdm6 , droan-b3mdw8 , droan-b3mee1 , droan-b3mf47 , droan-b3mf48 , droan-b3mg94 , droan-b3mgk2 , droan-b3mgn6 , droan-b3mii3 , droan-b3mjk2 , droan-b3mjk3 , droan-b3mjk4 , droan-b3mjk5 , droan-b3mjl2 , droan-b3mjl4 , droan-b3mjl7 , droan-b3mjl9 , droan-b3mjm8 , droan-b3mjm9 , droan-b3mjs6 , droan-b3mkr0 , droan-b3ml20 , droan-b3mly4 , droan-b3mly5 , droan-b3mly6 , droan-b3mmm8 , droan-b3mnb5 , droan-b3mny9 , droan-b3mtj5 , droan-b3muw4 , droan-b3muw8 , droan-b3n0e7 , droan-b3n2j7 , droan-b3n247 , droan-c5idb2 , droer-ACHE , droer-b3n5c7 , droer-b3n5d0 , droer-b3n5d8 , droer-b3n5d9 , droer-b3n5t7 , droer-b3n5y4 , droer-b3n7d2 , droer-b3n7d3 , droer-b3n7d4 , droer-b3n7k8 , droer-b3n8e4 , droer-b3n8f7 , droer-b3n8f8 , droer-b3n9e1 , droer-b3n319 , droer-b3n547 , droer-b3n549 , droer-b3n558 , droer-b3n560 , droer-b3n577 , droer-b3n612 , droer-b3nar5 , droer-b3nb91 , droer-b3nct9 , droer-b3nd53 , droer-b3ndh9 , droer-b3ndq8 , droer-b3ne66 , droer-b3ne67 , droer-b3ne97 , droer-b3nfk3 , droer-b3nfq9 , droer-b3nim7 , droer-b3nkn2 , droer-b3nm11 , droer-b3nmh4 , droer-b3nmy2 , droer-b3npx2 , droer-b3npx3 , droer-b3nq76 , droer-b3nqg9 , droer-b3nqm8 , droer-b3nr28 , droer-b3nrd3 , droer-b3nst4 , droer-b3nwa7 , droer-b3nyp5.1 , droer-b3nyp5.2 , droer-b3nyp6 , droer-b3nyp7 , droer-b3nyp8 , droer-b3nyp9 , droer-b3nyq3 , droer-b3nz06 , droer-b3nz14 , droer-b3nzj0 , droer-b3p0c0 , droer-b3p0c1 , droer-b3p0c2 , droer-b3p2x6 , droer-b3p2x7 , droer-b3p2x9 , droer-b3p2y1 , droer-b3p2y2 , droer-b3p6d4 , droer-b3p6d5 , droer-b3p6w3 , droer-b3p7b4 , droer-b3p7h9 , droer-b3p152 , droer-b3p486 , droer-b3p487 , droer-b3p488 , droer-b3p489 , droer-EST6 , droer-q670j5 , drogr-ACHE , drogr-b4iwp3 , drogr-b4iww3 , drogr-b4iwy3 , drogr-b4ixf7 , drogr-b4ixh4 , drogr-b4iyz5 , drogr-b4j2s2 , drogr-b4j2u8 , drogr-b4j3u1 , drogr-b4j3v3 , drogr-b4j4g7 , drogr-b4j4x9 , drogr-b4j6e6 , drogr-b4j9c9 , drogr-b4j9y4 , drogr-b4j156 , drogr-b4j384 , drogr-b4j605 , drogr-b4j685 , drogr-b4ja76 , drogr-b4jay5 , drogr-b4jcf0 , drogr-b4jcf1 , drogr-b4jdg6 , drogr-b4jdg7 , drogr-b4jdh6 , drogr-b4jdz1 , drogr-b4jdz2 , drogr-b4jdz4 , drogr-b4je66 , drogr-b4je79 , drogr-b4je82 , drogr-b4je88 , drogr-b4je89 , drogr-b4je90 , drogr-b4je91 , drogr-b4jf76 , drogr-b4jf79 , drogr-b4jf80 , drogr-b4jf81 , drogr-b4jf82 , drogr-b4jf83 , drogr-b4jf84 , drogr-b4jf85 , drogr-b4jf87 , drogr-b4jf91 , drogr-b4jf92 , drogr-b4jg66 , drogr-b4jgh0 , drogr-b4jgh1 , drogr-b4jgr9 , drogr-b4ji67 , drogr-b4jls2 , drogr-b4jnh9 , drogr-b4jpc6 , drogr-b4jpq3 , drogr-b4jpx9 , drogr-b4jql2 , drogr-b4jrh5 , drogr-b4jsb2 , drogr-b4jth3 , drogr-b4jti1 , drogr-b4jul5 , drogr-b4jur4 , drogr-b4jvh3 , drogr-b4jz00 , drogr-b4jz03 , drogr-b4jz04 , drogr-b4jz05 , drogr-b4jzh2 , drogr-b4k0u2 , drogr-b4k2r1 , drogr-b4k234 , drogr-b4k235 , drome-BEM46 , drome-CG3734 , drome-CG9953 , drome-CG11626 , drome-GH02439 , dromo-ACHE , dromo-b4k6a7 , dromo-b4k6a8 , dromo-b4k6q8 , dromo-b4k6q9 , dromo-b4k6r1 , dromo-b4k6r3 , dromo-b4k6r4 , dromo-b4k6r5 , dromo-b4k6r6 , dromo-b4k6r7 , dromo-b4k6r8 , dromo-b4k6r9 , dromo-b4k6s0 , dromo-b4k6s1 , dromo-b4k6s2 , dromo-b4k9c7 , dromo-b4k9d3 , dromo-b4k571 , dromo-b4k721 , dromo-b4ka74 , dromo-b4ka89 , dromo-b4kaj4 , dromo-b4kc20 , dromo-b4kcl2 , dromo-b4kcl3 , dromo-b4kd55.1 , dromo-b4kd55.2 , dromo-b4kd56 , dromo-b4kd57 , dromo-b4kde1 , dromo-b4kdg2 , dromo-b4kdh4 , dromo-b4kdh5 , dromo-b4kdh6 , dromo-A0A0Q9XDF2 , dromo-b4kdh8.1 , dromo-b4kdh8.2 , dromo-b4kg04 , dromo-b4kg05 , dromo-b4kg06 , dromo-b4kg16 , dromo-b4kg44 , dromo-b4kg90 , dromo-b4kh20 , dromo-b4kh21 , dromo-b4kht7 , dromo-b4kid3 , dromo-b4kik0 , dromo-b4kjx0 , dromo-b4kki1 , dromo-b4kkp6 , dromo-b4kkp8 , dromo-b4kkq8 , dromo-b4kkr0 , dromo-b4kkr3 , dromo-b4kkr4 , dromo-b4kks0 , dromo-b4kks1 , dromo-b4kks2 , dromo-b4kla1 , dromo-b4klv8 , dromo-b4knt4 , dromo-b4kp08 , dromo-b4kp16 , dromo-b4kqa6 , dromo-b4kqa7 , dromo-b4kqa8 , dromo-b4kqh1 , dromo-b4kst4 , dromo-b4ksy6 , dromo-b4kt84 , dromo-b4ktf5 , dromo-b4ktf6 , dromo-b4kvl3 , dromo-b4kvw2 , dromo-b4kwv4 , dromo-b4kwv5 , dromo-b4kxz6 , dromo-b4ky12 , dromo-b4ky36 , dromo-b4ky44 , dromo-b4kzu7 , dromo-b4l0n8 , dromo-b4l4u5 , dromo-b4l6l9 , dromo-b4l084 , drope-ACHE , drope-b4g3s6 , drope-b4g4p7 , drope-b4g6v4 , drope-b4g8m0 , drope-b4g8n6 , drope-b4g8n7 , drope-b4g9p2 , drope-b4g815 , drope-b4g816 , drope-b4gat7 , drope-b4gav5 , drope-b4gb05 , drope-b4gc08 , drope-b4gcr3 , drope-b4gdk2 , drope-b4gdl9 , drope-b4gdv9 , drope-b4gei8 , drope-b4gei9 , drope-b4gej0 , drope-b4ghz9 , drope-b4gj62 , drope-b4gj64 , drope-b4gj74 , drope-b4gkf4 , drope-b4gkv2 , drope-b4gky9 , drope-b4gl76 , drope-b4glf3 , drope-b4gmt3 , drope-b4gmt7 , drope-b4gmt9 , drope-b4gmu2 , drope-b4gmu3 , drope-b4gmu4 , drope-b4gmu5 , drope-b4gmu6 , drope-b4gmu7 , drope-b4gmv1 , drope-b4gn08 , drope-b4gpa7 , drope-b4gq13 , drope-b4grh7 , drope-b4gsf9 , drope-b4gsw4 , drope-b4gsw5 , drope-b4gsx2 , drope-b4gsx7 , drope-b4gsy6 , drope-b4gsy7 , drope-b4guj8 , drope-b4gw36 , drope-b4gzc2 , drope-b4gzc6 , drope-b4gzc7 , drope-b4h4p9 , drope-b4h5l3 , drope-b4h6a0 , drope-b4h6a8 , drope-b4h6a9 , drope-b4h6b0 , drope-b4h7m7 , drope-b4h462 , drope-b4h601 , drope-b4h602 , drope-b4hay1 , drope-b4hb18 , drope-est5a , drope-est5b , drope-est5c , drops-ACHE , drops-b5dhd2 , drops-b5dk96 , drops-b5dpe3 , drops-b5drp9 , drops-b5dwa7 , drops-b5dwa8 , drops-b5dz85 , drops-b5dz86 , drops-est5a , drops-est5b , drops-q29bq2 , drops-q29dd7 , drops-q29ew0 , drops-q291d5 , drops-q291e8 , drops-q293n1 , drops-q293n4 , drops-q293n5 , drops-q293n6 , drops-q294n6 , drops-q294n7 , drops-q294n9 , drops-q294p4 , drose-b4he97 , drose-b4hfu2 , drose-b4hg54 , drose-b4hga0 , drose-b4hgu9 , drose-b4hgv0 , drose-b4hgv3 , drose-b4hgv4 , drose-b4hhm8 , drose-b4hhs6 , drose-b4hie4 , drose-b4him9 , drose-b4hk63 , drose-b4hkj5 , drose-b4hr07 , drose-b4hr81 , drose-b4hre7 , drose-b4hs13 , drose-b4hsj9 , drose-b4hsk0 , drose-b4hsm8 , drose-b4hvr5 , drose-b4hwr7 , drose-b4hwr8 , drose-b4hwr9 , drose-b4hws6 , drose-b4hws7 , drose-b4hwt0 , drose-b4hwt2 , drose-b4hwu1 , drose-b4hwu2 , drose-b4hxs9 , drose-b4hxu4 , drose-b4hxz1 , drose-b4hyp8 , drose-b4hyp9 , drose-b4hyq0 , drose-b4hyz4 , drose-b4hyz5 , drose-b4i1k8 , drose-b4i2f3 , drose-b4i2w5 , drose-b4i4u3 , drose-b4i4u7 , drose-b4i4u9 , drose-b4i4v0 , drose-b4i4v1 , drose-b4i4v4 , drose-b4i4v5 , drose-b4i4v6 , drose-b4i4v7 , drose-b4i4v8 , drose-b4i4w0 , drose-b4i7s6 , drose-b4i133 , drose-b4i857 , drose-b4iam7 , drose-b4iam9 , drose-b4iaq6 , drose-b4icf6 , drose-b4icf7 , drose-b4id80 , drose-b4ifc5 , drose-b4ihv9 , drose-b4iie9 , drose-b4ilj8 , drose-b4in13 , drose-b4inj9 , drosi-ACHE , drosi-aes04a , drosi-b4nsh8 , drosi-b4q3d7 , drosi-b4q4w5 , drosi-b4q4y7 , drosi-b4q6h6 , drosi-b4q7u2 , drosi-b4q7u3 , drosi-b4q9c6 , drosi-b4q9c7 , drosi-b4q9d3 , drosi-b4q9d4 , drosi-b4q9r0 , drosi-b4q9r1 , drosi-b4q9r3 , drosi-b4q9s2 , drosi-b4q9s3 , drosi-b4q429 , drosi-b4q530 , drosi-b4q734 , drosi-b4q782 , drosi-b4q783 , drosi-b4q942 , drosi-b4qet1 , drosi-b4qfv6 , drosi-b4qge5 , drosi-b4qgh5 , drosi-b4qgs5 , drosi-b4qhf3 , drosi-b4qhf4 , drosi-b4qhi5 , drosi-b4qjr2 , drosi-b4qjr3 , drosi-b4qjv6 , drosi-b4qk23 , drosi-b4qk51 , drosi-b4qlt1 , drosi-b4qlz9 , drosi-b4qmn9 , drosi-b4qrq7 , drosi-b4qs01 , drosi-b4qs57 , drosi-b4qs82 , drosi-b4qs83 , drosi-b4qs84 , drosi-b4qs85 , drosi-b4qs86 , drosi-b4qsq1 , drosi-b4quk6 , drosi-b4qvg5 , drosi-b4qvg6 , drosi-b4qzn2 , drosi-b4qzn3 , drosi-b4qzn5 , drosi-b4qzn7 , drosi-b4qzn8 , drosi-b4qzp2 , drosi-b4qzp3 , drosi-b4qzp4 , drosi-b4qzp5 , drosi-b4qzp6 , drosi-b4qzp7 , drosi-b4r1a4 , drosi-b4r025 , drosi-b4r207 , drosi-b4r662 , drosi-este6 , drosi-q670k8 , drovi-ACHE , drovi-b4lev2 , drovi-b4lf33 , drovi-b4lf51 , drovi-b4lg54 , drovi-b4lg72 , drovi-b4lgc6 , drovi-b4lgd5 , drovi-b4lgg0 , drovi-b4lgk5 , drovi-b4lgn2 , drovi-b4lh17 , drovi-b4lh18 , drovi-b4lk43 , drovi-b4ll59 , drovi-b4ll60 , drovi-b4llm5 , drovi-b4lln3 , drovi-b4lmk4 , drovi-b4lmp0 , drovi-b4lnr4 , drovi-b4lp47 , drovi-b4lpd0 , drovi-b4lps0 , drovi-b4lqc6 , drovi-b4lr00 , drovi-b4lrp6 , drovi-b4lrw2 , drovi-b4lse7 , drovi-b4lse9 , drovi-b4lsf0 , drovi-b4lsn0 , drovi-b4lsq5 , drovi-b4lt32 , drovi-b4ltr1 , drovi-b4lui7 , drovi-b4lui9 , drovi-b4luj8 , drovi-b4luk0 , drovi-b4luk3 , drovi-b4luk8 , drovi-b4luk9 , drovi-b4lul0 , drovi-b4lve2 , drovi-b4lxi9 , drovi-b4lxj8 , drovi-b4lyf3 , drovi-b4lyq2 , drovi-b4lyq3 , drovi-b4lz07 , drovi-b4lz13 , drovi-b4lz14 , drovi-b4lz15 , drovi-b4m0j7 , drovi-b4m0s0 , drovi-b4m2b6 , drovi-b4m4h7 , drovi-b4m4h8 , drovi-b4m4i0 , drovi-b4m4i2 , drovi-b4m4i3.A , drovi-b4m4i3.B , drovi-b4m4i4 , drovi-b4m4i5 , drovi-b4m4i6 , drovi-b4m4i7 , drovi-b4m4i8 , drovi-b4m4i9 , drovi-b4m4j2 , drovi-b4m5a0 , drovi-b4m5a1 , drovi-b4m5a2 , drovi-b4m6b9 , drovi-b4m7k9 , drovi-b4m9g9 , drovi-b4m9h0 , drovi-b4m564 , drovi-b4m599 , drovi-b4m918 , drovi-b4mb87 , drovi-b4mc71 , drovi-b4mfa4 , drowi-ACHE , drowi-b4mjb9 , drowi-b4mkt7 , drowi-b4mlc1 , drowi-b4mp68 , drowi-b4mqe9 , drowi-b4mqf0.2 , drowi-b4mqf1 , drowi-b4mqf3 , drowi-b4mqf4 , drowi-b4mqf5 , drowi-b4mqq6 , drowi-b4mrd1 , drowi-b4mrk3 , drowi-b4mtl5 , drowi-b4mug2 , drowi-b4muj8 , drowi-b4mv18 , drowi-b4mw32 , drowi-b4mw85 , drowi-b4mwp2 , drowi-b4mwp6 , drowi-b4mwq5 , drowi-b4mwr0 , drowi-b4mwr8 , drowi-b4mwr9 , drowi-b4mwt1 , drowi-b4mwz7 , drowi-b4mxn5 , drowi-b4my54 , drowi-b4myg1 , drowi-b4myh5 , drowi-b4n0d4 , drowi-b4n1a7 , drowi-b4n1c8 , drowi-b4n3s9 , drowi-b4n3x7 , drowi-b4n4x9 , drowi-b4n4y0 , drowi-b4n6m1 , drowi-b4n6n0 , drowi-b4n6n7 , drowi-b4n6u6 , drowi-b4n7s6 , drowi-b4n7s7 , drowi-b4n7s8 , drowi-b4n899.1 , drowi-b4n8a1 , drowi-b4n8a2 , drowi-b4n8a3 , drowi-b4n8a4 , drowi-b4n8a9 , drowi-b4n023 , drowi-b4n075 , drowi-b4n543 , drowi-b4n888 , drowi-b4n889 , drowi-b4n891 , drowi-b4n893 , drowi-b4n895 , drowi-b4n897 , drowi-b4n898 , drowi-b4n899.2 , drowi-b4nae3 , drowi-b4ner8 , drowi-b4ng76 , drowi-b4nga7 , drowi-b4ngb5 , drowi-b4nhz9 , drowi-b4nj18 , drowi-b4nj19 , drowi-b4nja7 , drowi-b4nja8 , drowi-b4nja9 , drowi-b4njk8 , drowi-b4nkc8 , drowi-b4nky0 , drowi-b4nl36 , drowi-b4nm27 , drowi-b4nn59 , drowi-b4nnc1 , drowi-b4nng1 , drowi-b4nng2 , droya-ACHE , droya-aes04 , droya-b4itg2 , droya-b4itg6 , droya-b4itu9 , droya-b4iuv4 , droya-b4iuv5 , droya-b4nxe6 , droya-b4nxg5 , droya-b4nxg6 , droya-b4nxg8 , droya-b4nxw4 , droya-b4ny57 , droya-b4ny58 , droya-b4ny86 , droya-b4nzz8 , droya-b4p0b5 , droya-b4p0q9 , droya-b4p0r0 , droya-b4p0r7 , droya-b4p0r8 , droya-b4p0r9 , droya-b4p0s0 , droya-b4p0s2 , droya-b4p0t0 , droya-b4p0t1 , droya-b4p3h4 , droya-b4p3x8 , droya-b4p5g8 , droya-b4p6c9 , droya-b4p6l9 , droya-b4p6r1 , droya-b4p6r2 , droya-b4p7u4 , droya-b4p8w7 , droya-b4p023 , droya-b4p241 , droya-b4p774 , droya-b4pat9 , droya-b4pbl1 , droya-b4pd22 , droya-b4pd70 , droya-b4pdm8 , droya-b4pet9 , droya-b4pff9 , droya-b4pga7 , droya-b4pgu0 , droya-b4pig3 , droya-b4pjt8 , droya-b4pka2 , droya-b4plh2 , droya-b4pma3 , droya-b4pmv3 , droya-b4pmv4 , droya-b4pmv5 , droya-b4pn92 , droya-b4pp65 , droya-b4ppc5 , droya-b4ppc6 , droya-b4ppc7 , droya-b4ppc8 , droya-b4pq03 , droya-b4prg6B , droya-b4prg9 , droya-b4prh3 , droya-b4prh4 , droya-b4prh6 , droya-b4prh7 , droya-b4psz8 , droya-b4psz9 , droya-b4pv22 , droya-b4q0g5 , droya-b4q246 , droya-EST6 , droya-q71d76 , drowi-b4n7m9 , drope-b4gkk1 , droer-b3n5s3 , drose-b4i1w5 , drowi-a0a0q9x0t3 , drogr-b4jvm7 , dromo-b4ku70 , drovi-b4mcn9 , drovi-b4lty2 , drogr-b4jdu1 , drovi-a0a0q9wiq8 , dromo-b4kf70 , drosi-b2zi86 , droya-b4p2y4 , drose-b2zic5 , droer-b3n895

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

Title : Survey sequencing and comparative analysis of the elephant shark (Callorhinchus milii) genome - Venkatesh_2007_PLoS.Biol_5_e101
Author(s) : Venkatesh B , Kirkness EF , Loh YH , Halpern AL , Lee AP , Johnson J , Dandona N , Viswanathan LD , Tay A , Venter JC , Strausberg RL , Brenner S
Ref : PLoS Biol , 5 :e101 , 2007
Abstract : Owing to their phylogenetic position, cartilaginous fishes (sharks, rays, skates, and chimaeras) provide a critical reference for our understanding of vertebrate genome evolution. The relatively small genome of the elephant shark, Callorhinchus milii, a chimaera, makes it an attractive model cartilaginous fish genome for whole-genome sequencing and comparative analysis. Here, the authors describe survey sequencing (1.4x coverage) and comparative analysis of the elephant shark genome, one of the first cartilaginous fish genomes to be sequenced to this depth. Repetitive sequences, represented mainly by a novel family of short interspersed element-like and long interspersed element-like sequences, account for about 28% of the elephant shark genome. Fragments of approximately 15,000 elephant shark genes reveal specific examples of genes that have been lost differentially during the evolution of tetrapod and teleost fish lineages. Interestingly, the degree of conserved synteny and conserved sequences between the human and elephant shark genomes are higher than that between human and teleost fish genomes. Elephant shark contains putative four Hox clusters indicating that, unlike teleost fish genomes, the elephant shark genome has not experienced an additional whole-genome duplication. These findings underscore the importance of the elephant shark as a critical reference vertebrate genome for comparative analysis of the human and other vertebrate genomes. This study also demonstrates that a survey-sequencing approach can be applied productively for comparative analysis of distantly related vertebrate genomes.
ESTHER : Venkatesh_2007_PLoS.Biol_5_e101
PubMedSearch : Venkatesh_2007_PLoS.Biol_5_e101
PubMedID: 17407382
Gene_locus related to this paper: calmi-a0a4w3h3v0 , calmi-a0a4w3hel5

Title : Ancient noncoding elements conserved in the human genome - Venkatesh_2006_Science_314_1892
Author(s) : Venkatesh B , Kirkness EF , Loh YH , Halpern AL , Lee AP , Johnson J , Dandona N , Viswanathan LD , Tay A , Venter JC , Strausberg RL , Brenner S
Ref : Science , 314 :1892 , 2006
Abstract : Cartilaginous fishes represent the living group of jawed vertebrates that diverged from the common ancestor of human and teleost fish lineages about 530 million years ago. We generated approximately 1.4x genome sequence coverage for a cartilaginous fish, the elephant shark (Callorhinchus milii), and compared this genome with the human genome to identify conserved noncoding elements (CNEs). The elephant shark sequence revealed twice as many CNEs as were identified by whole-genome comparisons between teleost fishes and human. The ancient vertebrate-specific CNEs in the elephant shark and human genomes are likely to play key regulatory roles in vertebrate gene expression.
ESTHER : Venkatesh_2006_Science_314_1892
PubMedSearch : Venkatesh_2006_Science_314_1892
PubMedID: 17185593
Gene_locus related to this paper: calmi-a0a4w3h3v0 , calmi-a0a4w3hel5

Title : The 5-hydroxytryptamine type 3 (5-HT3) receptor reveals a novel determinant of single-channel conductance - Peters_2004_Biochem.Soc.Trans_32_547
Author(s) : Peters JA , Kelley SP , Dunlop JI , Kirkness EF , Hales TG , Lambert JJ
Ref : Biochemical Society Transactions , 32 :547 , 2004
Abstract : 5-HT3 (5-hydroxytryptamine type 3) receptors are cation-selective ion channels of the Cys-loop transmitter-gated ion channel superfamily. Two 5-HT3 receptor subunits, 5-HT3A and 5-HT3B, have been characterized in detail, although additional putative 5-HT3 subunit genes (HTR3C, HTR3D and HTR3E) have recently been reported. 5-HT3 receptors function as homopentameric assemblies of the 5-HT3 subunit, or heteropentamers of 5-HT3A and 5-HT3B subunits of unknown stoichiometry. The single-channel conductances of human recombinant homomeric and heteromeric 5-HT3 receptors are markedly different, being <1 and approx. 16 pS respectively. Paradoxically, from the results of studies performed on the closely related nicotinic acetylcholine receptor, the channel-lining M2 domain of the 5-HT3A subunit is predicted to enhance cation conduction, whereas that of the 5-HT3B subunit would not. The present study describes a novel determinant of single-channel conductance, out with the M2 domain, which accounts for this anomaly. Utilizing a panel of chimaeric 5-HT3A and 5-HT3B subunits, a profound determinant of single-channel conductance was traced to a putative amphipathic helix (the 'HA stretch') within the large cytoplasmic loop of the receptor. Replacement of three arginine residues (R432, R436 and R440) unique to the HA stretch of the 5-HT3A subunit with the aligned residues (Q395, D399 and A403) of the 5-HT3B subunit increased the single-channel conductance 28-fold. Significantly, from ultrastructural studies of the Torpedo nicotinic acetylcholine receptor, the key residues may be components of narrow openings within the inner vestibule of the channel, located in the cytoplasm, which contribute to the permeation pathway. Our findings indicate an important and hitherto unappreciated function for the HA stretch in the Cys-loop family of transmitter-gated ion channels.
ESTHER : Peters_2004_Biochem.Soc.Trans_32_547
PubMedSearch : Peters_2004_Biochem.Soc.Trans_32_547
PubMedID: 15157181

Title : Cell surface expression of 5-hydroxytryptamine type 3 receptors is controlled by an endoplasmic reticulum retention signal - Boyd_2003_J.Biol.Chem_278_27681
Author(s) : Boyd GW , Doward AI , Kirkness EF , Millar NS , Connolly CN
Ref : Journal of Biological Chemistry , 278 :27681 , 2003
Abstract : Two subunits of the 5-hydroxytryptamine type 3 (5-HT3) have been identified (5-HT3A and 5-HT3B) that assemble into homomeric (5-HT3A) and heteromeric (5-HT3A+5-HT3B) complexes. Unassembled 5-HT3B subunits are efficiently retained within the cell. In this study, we address the mechanism controlling the release of 5-HT3B from the endoplasmic reticulum (ER). An analysis of chimeric 5-HT3A receptor(R).5-HT3BR constructs suggests the presence of elements downstream of the first transmembrane domain of 5-HT3B subunits that inhibit cell surface expression. To investigate this possibility, truncated 5-HT3B subunits were constructed and assessed for their ability to access the cell surface in COS-7 and ts201 cells. Using this approach, we have identified the presence of an ER retention signal located within the first cytoplasmic loop between transmembrane domains I and II of 5-HT3B. Transplantation of this signal (CRAR) into the homologous region of 5-HT3A results in the ER retention of this subunit until rescued by co-assembly with wild-type 5-HT3A. The mutation of this ER retention signal in 5-HT3B (5-HT3BSGER) does not lead to cell surface expression, suggesting the presence of other signals or mechanisms to control the surface expression of 5-HT3BRs. The generation of truncated 5-HT3BSGER constructs confirmed that the CRAR signal does play an important role in the ER retention of 5-HT3B.
ESTHER : Boyd_2003_J.Biol.Chem_278_27681
PubMedSearch : Boyd_2003_J.Biol.Chem_278_27681
PubMedID: 12750374

Title : A cytoplasmic region determines single-channel conductance in 5-HT3 receptors - Kelley_2003_Nature_424_321
Author(s) : Kelley SP , Dunlop JI , Kirkness EF , Lambert JJ , Peters JA
Ref : Nature , 424 :321 , 2003
Abstract : 5-hydroxytryptamine type 3 (5-HT3) receptors are cation-selective transmitter-gated ion channels of the Cys-loop superfamily. The single-channel conductance of human recombinant 5-HT3 receptors assembled as homomers of 5-HT3A subunits, or heteromers of 5-HT3A and 5-HT3B subunits, are markedly different, being 0.4 pS (refs 6, 9) and 16 pS (ref. 7), respectively. Paradoxically, the channel-lining M2 domain of the 5-HT3A subunit would be predicted to promote cation conduction, whereas that of the 5-HT3B subunit would not. Here we describe a determinant of single-channel conductance that can explain these observations. By constructing chimaeric 5-HT3A and 5-HT3B subunits we identified a region (the 'HA-stretch') within the large cytoplasmic loop of the receptor that markedly influences channel conductance. Replacement of three arginine residues unique to the HA-stretch of the 5-HT3A subunit by their 5-HT3B subunit counterparts increased single-channel conductance 28-fold. Significantly, ultrastructural studies of the Torpedo nicotinic acetylcholine receptor indicate that the key residues might frame narrow openings that contribute to the permeation pathway. Our findings solve the conundrum of the anomalously low conductance of homomeric 5-HT3A receptors and indicate an important function for the HA-stretch in Cys-loop transmitter-gated ion channels.
ESTHER : Kelley_2003_Nature_424_321
PubMedSearch : Kelley_2003_Nature_424_321
PubMedID: 12867984

Title : The complete genome sequence of the hyperthermophilic, sulphate-reducing archaeon Archaeoglobus fulgidus - Klenk_1997_Nature_390_364
Author(s) : Klenk HP , Clayton RA , Tomb JF , White O , Nelson KE , Ketchum KA , Dodson RJ , Gwinn M , Hickey EK , Peterson JD , Richardson DL , Kerlavage AR , Graham DE , Kyrpides NC , Fleischmann RD , Quackenbush J , Lee NH , Sutton GG , Gill S , Kirkness EF , Dougherty BA , McKenney K , Adams MD , Loftus B , Peterson S , Reich CI , McNeil LK , Badger JH , Glodek A , Zhou L , Overbeek R , Gocayne JD , Weidman JF , McDonald L , Utterback T , Cotton MD , Spriggs T , Artiach P , Kaine BP , Sykes SM , Sadow PW , D'Andrea KP , Bowman C , Fujii C , Garland SA , Mason TM , Olsen GJ , Fraser CM , Smith HO , Woese CR , Venter JC
Ref : Nature , 390 :364 , 1997
Abstract : Archaeoglobus fulgidus is the first sulphur-metabolizing organism to have its genome sequence determined. Its genome of 2,178,400 base pairs contains 2,436 open reading frames (ORFs). The information processing systems and the biosynthetic pathways for essential components (nucleotides, amino acids and cofactors) have extensive correlation with their counterparts in the archaeon Methanococcus jannaschii. The genomes of these two Archaea indicate dramatic differences in the way these organisms sense their environment, perform regulatory and transport functions, and gain energy. In contrast to M. jannaschii, A. fulgidus has fewer restriction-modification systems, and none of its genes appears to contain inteins. A quarter (651 ORFs) of the A. fulgidus genome encodes functionally uncharacterized yet conserved proteins, two-thirds of which are shared with M. jannaschii (428 ORFs). Another quarter of the genome encodes new proteins indicating substantial archaeal gene diversity.
ESTHER : Klenk_1997_Nature_390_364
PubMedSearch : Klenk_1997_Nature_390_364
PubMedID: 9389475
Gene_locus related to this paper: arcfu-AF0514 , arcfu-AF0675 , arcfu-AF1134 , arcfu-AF1563 , arcfu-AF1753 , arcfu-AF1763 , arcfu-est1 , arcfu-est2 , arcfu-est3 , arcfu-estea , arcfu-o28594 , arcfu-o29442 , arcfu-pcbd

Title : The complete genome sequence of the gastric pathogen Helicobacter pylori. - Tomb_1997_Nature_388_539
Author(s) : Tomb J-F , White O , Kerlavage AR , Clayton RA , Sutton GG , Fleischmann RD , Ketchum KA , Klenk H-P , Gill S , Dougherty BA , Nelson K , Quackenbush J , Zhou L , Kirkness EF , Peterson S , Loftus B , Richardson D , Dodson R , Khalak HG , Glodek A , McKenney K , FitzGerald LM , Lee N , Adams MD , Hickey EK , Berg DE , Gocayne JD , Utterback TR , Peterson JD , Kelley JM , Cotton MD , Weidman JM , Fujii C , Bowman C , Watthey L , Wallin E , Hayes WS , Borodovsky M , Karp PD , Smith HO , Fraser CM , Venter JC
Ref : Nature , 388 :539 , 1997
Abstract : Helicobacter pylori, strain 26695, has a circular genome of 1,667,867 base pairs and 1,590 predicted coding sequences. Sequence analysis indicates that H. pylori has well-developed systems for motility, for scavenging iron, and for DNA restriction and modification. Many putative adhesins, lipoproteins and other outer membrane proteins were identified, underscoring the potential complexity of host-pathogen interaction. Based on the large number of sequence-related genes encoding outer membrane proteins and the presence of homopolymeric tracts and dinucleotide repeats in coding sequences, H. pylori, like several other mucosal pathogens, probably uses recombination and slipped-strand mispairing within repeats as mechanisms for antigenic variation and adaptive evolution. Consistent with its restricted niche, H. pylori has a few regulatory networks, and a limited metabolic repertoire and biosynthetic capacity. Its survival in acid conditions depends, in part, on its ability to establish a positive inside-membrane potential in low pH.
ESTHER : Tomb_1997_Nature_388_539
PubMedSearch : Tomb_1997_Nature_388_539
PubMedID: 9252185
Gene_locus related to this paper: helpy-HP0739 , helpy-o25061

Title : Whole-genome random sequencing and assembly of Haemophilus influenzae Rd - Fleischmann_1995_Science_269_496
Author(s) : Fleischmann RD , Adams MD , White O , Clayton RA , Kirkness EF , Kerlavage AR , Bult CJ , Tomb JF , Dougherty BA , Merrick JM , McKenney K , Sutton G , FitzHugh W , Fields C , Gocayne JD , Scott J , Shirley R , Liu LI , Glodek A , Kelley JM , Weidman JF , Phillips CA , Spriggs T , Hedblom E , Cotton MD , Utterback TR , Hanna MC , Nguyen DT , Saudek DM , Brandon RC , FineLD , Fritchman JL , Fuhrmann JL , Geoghagen NS , Gnehm CL , McDonald LA , Keith V , Small KV , Fraser CM , Smith HO , Venter JC
Ref : Science , 269 :496 , 1995
Abstract : An approach for genome analysis based on sequencing and assembly of unselected pieces of DNA from the whole chromosome has been applied to obtain the complete nucleotide sequence (1,830,137 base pairs) of the genome from the bacterium Haemophilus influenzae Rd. This approach eliminates the need for initial mapping efforts and is therefore applicable to the vast array of microbial species for which genome maps are unavailable. The H. influenzae Rd genome sequence (Genome Sequence DataBase accession number L42023) represents the only complete genome sequence from a free-living organism.
ESTHER : Fleischmann_1995_Science_269_496
PubMedSearch : Fleischmann_1995_Science_269_496
PubMedID: 7542800
Gene_locus related to this paper: haein-HI0193 , haein-metx , haein-pldb , haein-sfgh , haein-y1552 , haein-yfbb