Eichler EE

References (14)

Title : The Chromosome-Based Rubber Tree Genome Provides New Insights into Spurge Genome Evolution and Rubber Biosynthesis - Liu_2020_Mol.Plant_13_336
Author(s) : Liu J , Shi C , Shi CC , Li W , Zhang QJ , Zhang Y , Li K , Lu HF , Zhu ST , Xiao ZY , Nan H , Yue Y , Zhu XG , Wu Y , Hong XN , Fan GY , Tong Y , Zhang D , Mao CL , Liu YL , Hao SJ , Liu WQ , Lv MQ , Zhang HB , Liu Y , Hu-Tang GR , Wang JP , Wang JH , Sun YH , Ni SB , Chen WB , Zhang XC , Jiao YN , Eichler EE , Li GH , Liu X , Gao LZ
Ref : Mol Plant , 13 :336 , 2020
Abstract : The rubber tree, Hevea brasiliensis, produces natural rubber that serves as an essential industrial raw material. Here, we present a high-quality reference genome for a rubber tree cultivar GT1 using single-molecule real-time sequencing (SMRT) and Hi-C technologies to anchor the -1.47-Gb genome assembly into 18 pseudochromosomes. The chromosome-based genome analysis enabled us to establish a model of spurge chromosome evolution, since the common paleopolyploid event occurred before the split of Hevea and Manihot. We show recent and rapid bursts of the three Hevea-specific LTR-retrotransposon families during the last 10 million years, leading to the massive expansion by -65.88% (-970 Mbp) of the whole rubber tree genome since the divergence from Manihot. We identify large-scale expansion of genes associated with whole rubber biosynthesis processes, such as basal metabolic processes, ethylene biosynthesis, and the activation of polysaccharide and glycoprotein lectin, which are important properties for latex production. A map of genomic variation between the cultivated and wild rubber trees was obtained, which contains -15.7 million high-quality single-nucleotide polymorphisms. We identified hundreds of candidate domestication genes with drastically lowered genomic diversity in the cultivated but not wild rubber trees despite a relatively short domestication history of rubber tree, some of which are involved in rubber biosynthesis. This genome assembly represents key resources for future rubber tree research and breeding, providing novel targets for improving plant biotic and abiotic tolerance and rubber production.
ESTHER : Liu_2020_Mol.Plant_13_336
PubMedSearch : Liu_2020_Mol.Plant_13_336
PubMedID: 31838037
Gene_locus related to this paper: hevbr-a0a6a6mdr9

Title : The bonobo genome compared with the chimpanzee and human genomes - Prufer_2012_Nature_486_527
Author(s) : Prufer K , Munch K , Hellmann I , Akagi K , Miller JR , Walenz B , Koren S , Sutton G , Kodira C , Winer R , Knight JR , Mullikin JC , Meader SJ , Ponting CP , Lunter G , Higashino S , Hobolth A , Dutheil J , Karakoc E , Alkan C , Sajjadian S , Catacchio CR , Ventura M , Marques-Bonet T , Eichler EE , Andre C , Atencia R , Mugisha L , Junhold J , Patterson N , Siebauer M , Good JM , Fischer A , Ptak SE , Lachmann M , Symer DE , Mailund T , Schierup MH , Andres AM , Kelso J , Paabo S
Ref : Nature , 486 :527 , 2012
Abstract : Two African apes are the closest living relatives of humans: the chimpanzee (Pan troglodytes) and the bonobo (Pan paniscus). Although they are similar in many respects, bonobos and chimpanzees differ strikingly in key social and sexual behaviours, and for some of these traits they show more similarity with humans than with each other. Here we report the sequencing and assembly of the bonobo genome to study its evolutionary relationship with the chimpanzee and human genomes. We find that more than three per cent of the human genome is more closely related to either the bonobo or the chimpanzee genome than these are to each other. These regions allow various aspects of the ancestry of the two ape species to be reconstructed. In addition, many of the regions that overlap genes may eventually help us understand the genetic basis of phenotypes that humans share with one of the two apes to the exclusion of the other.
ESTHER : Prufer_2012_Nature_486_527
PubMedSearch : Prufer_2012_Nature_486_527
PubMedID: 22722832
Gene_locus related to this paper: panpa-a0a2r8z5s1 , panpa-a0a2r8zh05 , panpa-a0a2r9a219 , panpa-a0a2r9cp60 , panpa-a0a2r8zm37 , panpa-a0a2r8ztc4 , panpa-a0a2r9b1a7 , panpa-a0a2r9bxk5 , panpa-a0a2r8zr38 , panpa-a0a2r8zvr0 , panpa-a0a2r9bln0 , panpa-a0a2r9acy6 , panpa-a0a2r8ztx2 , panpa-a0a2r9clu7 , panpa-a0a2r9c6z8 , panpa-a0a2r9cay0 , panpa-a0a2r9aqi9 , panpa-a0a2r9aqr5 , panpa-a0a2r9bpf0 , panpa-a0a2r9cj39

Title : Insights into hominid evolution from the gorilla genome sequence - Scally_2012_Nature_483_169
Author(s) : Scally A , Dutheil JY , Hillier LW , Jordan GE , Goodhead I , Herrero J , Hobolth A , Lappalainen T , Mailund T , Marques-Bonet T , McCarthy S , Montgomery SH , Schwalie PC , Tang YA , Ward MC , Xue Y , Yngvadottir B , Alkan C , Andersen LN , Ayub Q , Ball EV , Beal K , Bradley BJ , Chen Y , Clee CM , Fitzgerald S , Graves TA , Gu Y , Heath P , Heger A , Karakoc E , Kolb-Kokocinski A , Laird GK , Lunter G , Meader S , Mort M , Mullikin JC , Munch K , O'Connor TD , Phillips AD , Prado-Martinez J , Rogers AS , Sajjadian S , Schmidt D , Shaw K , Simpson JT , Stenson PD , Turner DJ , Vigilant L , Vilella AJ , Whitener W , Zhu B , Cooper DN , de Jong P , Dermitzakis ET , Eichler EE , Flicek P , Goldman N , Mundy NI , Ning Z , Odom DT , Ponting CP , Quail MA , Ryder OA , Searle SM , Warren WC , Wilson RK , Schierup MH , Rogers J , Tyler-Smith C , Durbin R
Ref : Nature , 483 :169 , 2012
Abstract : Gorillas are humans' closest living relatives after chimpanzees, and are of comparable importance for the study of human origins and evolution. Here we present the assembly and analysis of a genome sequence for the western lowland gorilla, and compare the whole genomes of all extant great ape genera. We propose a synthesis of genetic and fossil evidence consistent with placing the human-chimpanzee and human-chimpanzee-gorilla speciation events at approximately 6 and 10 million years ago. In 30% of the genome, gorilla is closer to human or chimpanzee than the latter are to each other; this is rarer around coding genes, indicating pervasive selection throughout great ape evolution, and has functional consequences in gene expression. A comparison of protein coding genes reveals approximately 500 genes showing accelerated evolution on each of the gorilla, human and chimpanzee lineages, and evidence for parallel acceleration, particularly of genes involved in hearing. We also compare the western and eastern gorilla species, estimating an average sequence divergence time 1.75 million years ago, but with evidence for more recent genetic exchange and a population bottleneck in the eastern species. The use of the genome sequence in these and future analyses will promote a deeper understanding of great ape biology and evolution.
ESTHER : Scally_2012_Nature_483_169
PubMedSearch : Scally_2012_Nature_483_169
PubMedID: 22398555
Gene_locus related to this paper: gorgo-g3qfr8 , gorgo-g3qgi3 , gorgo-g3r1s1 , gorgo-g3r9p9 , gorgo-a0a2i2zrx6 , gorgo-g3re16 , gorgo-g3s122 , gorgo-a0a2i2y3x8

Title : The genome of a songbird - Warren_2010_Nature_464_757
Author(s) : Warren WC , Clayton DF , Ellegren H , Arnold AP , Hillier LW , Kunstner A , Searle S , White S , Vilella AJ , Fairley S , Heger A , Kong L , Ponting CP , Jarvis ED , Mello CV , Minx P , Lovell P , Velho TA , Ferris M , Balakrishnan CN , Sinha S , Blatti C , London SE , Li Y , Lin YC , George J , Sweedler J , Southey B , Gunaratne P , Watson M , Nam K , Backstrom N , Smeds L , Nabholz B , Itoh Y , Whitney O , Pfenning AR , Howard J , Volker M , Skinner BM , Griffin DK , Ye L , McLaren WM , Flicek P , Quesada V , Velasco G , Lopez-Otin C , Puente XS , Olender T , Lancet D , Smit AF , Hubley R , Konkel MK , Walker JA , Batzer MA , Gu W , Pollock DD , Chen L , Cheng Z , Eichler EE , Stapley J , Slate J , Ekblom R , Birkhead T , Burke T , Burt D , Scharff C , Adam I , Richard H , Sultan M , Soldatov A , Lehrach H , Edwards SV , Yang SP , Li X , Graves T , Fulton L , Nelson J , Chinwalla A , Hou S , Mardis ER , Wilson RK
Ref : Nature , 464 :757 , 2010
Abstract : The zebra finch is an important model organism in several fields with unique relevance to human neuroscience. Like other songbirds, the zebra finch communicates through learned vocalizations, an ability otherwise documented only in humans and a few other animals and lacking in the chicken-the only bird with a sequenced genome until now. Here we present a structural, functional and comparative analysis of the genome sequence of the zebra finch (Taeniopygia guttata), which is a songbird belonging to the large avian order Passeriformes. We find that the overall structures of the genomes are similar in zebra finch and chicken, but they differ in many intrachromosomal rearrangements, lineage-specific gene family expansions, the number of long-terminal-repeat-based retrotransposons, and mechanisms of sex chromosome dosage compensation. We show that song behaviour engages gene regulatory networks in the zebra finch brain, altering the expression of long non-coding RNAs, microRNAs, transcription factors and their targets. We also show evidence for rapid molecular evolution in the songbird lineage of genes that are regulated during song experience. These results indicate an active involvement of the genome in neural processes underlying vocal communication and identify potential genetic substrates for the evolution and regulation of this behaviour.
ESTHER : Warren_2010_Nature_464_757
PubMedSearch : Warren_2010_Nature_464_757
PubMedID: 20360741
Gene_locus related to this paper: taegu-b5fyu7 , taegu-BCHE , taegu-h0z4h9 , taegu-h0z9w8 , taegu-h0zat6 , taegu-h0ze48 , taegu-h0zha8 , taegu-h0zkr8 , taegu-h0zqp3 , taegu-h0zz82 , taegu-h0zqs1 , taegu-h0yy64 , taegu-h0yv40 , taegu-h0yyt1 , taegu-h0zcc8 , taegu-h0z3k5 , taegu-h0yw95 , taegu-h0zkm7 , taegu-h1a198 , taegu-h0z6w2 , taegu-h0zl93 , taegu-h0zt33 , taegu-h0yp71 , taegu-h0ypu5 , taegu-h1a048 , taegu-h0ztq1 , fical-u3kau2 , 9pass-a0a093qu66 , taegu-h0z7g0 , fical-u3jnn0 , taegu-h0zb80 , taegu-h0zb89 , taegu-h0z994 , taegu-h0ztj6

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

Title : Lineage-specific biology revealed by a finished genome assembly of the mouse - Church_2009_PLoS.Biol_7_e1000112
Author(s) : Church DM , Goodstadt L , Hillier LW , Zody MC , Goldstein S , She X , Bult CJ , Agarwala R , Cherry JL , DiCuccio M , Hlavina W , Kapustin Y , Meric P , Maglott D , Birtle Z , Marques AC , Graves T , Zhou S , Teague B , Potamousis K , Churas C , Place M , Herschleb J , Runnheim R , Forrest D , Amos-Landgraf J , Schwartz DC , Cheng Z , Lindblad-Toh K , Eichler EE , Ponting CP
Ref : PLoS Biol , 7 :e1000112 , 2009
Abstract : The mouse (Mus musculus) is the premier animal model for understanding human disease and development. Here we show that a comprehensive understanding of mouse biology is only possible with the availability of a finished, high-quality genome assembly. The finished clone-based assembly of the mouse strain C57BL/6J reported here has over 175,000 fewer gaps and over 139 Mb more of novel sequence, compared with the earlier MGSCv3 draft genome assembly. In a comprehensive analysis of this revised genome sequence, we are now able to define 20,210 protein-coding genes, over a thousand more than predicted in the human genome (19,042 genes). In addition, we identified 439 long, non-protein-coding RNAs with evidence for transcribed orthologs in human. We analyzed the complex and repetitive landscape of 267 Mb of sequence that was missing or misassembled in the previously published assembly, and we provide insights into the reasons for its resistance to sequencing and assembly by whole-genome shotgun approaches. Duplicated regions within newly assembled sequence tend to be of more recent ancestry than duplicates in the published draft, correcting our initial understanding of recent evolution on the mouse lineage. These duplicates appear to be largely composed of sequence regions containing transposable elements and duplicated protein-coding genes; of these, some may be fixed in the mouse population, but at least 40% of segmentally duplicated sequences are copy number variable even among laboratory mouse strains. Mouse lineage-specific regions contain 3,767 genes drawn mainly from rapidly-changing gene families associated with reproductive functions. The finished mouse genome assembly, therefore, greatly improves our understanding of rodent-specific biology and allows the delineation of ancestral biological functions that are shared with human from derived functions that are not.
ESTHER : Church_2009_PLoS.Biol_7_e1000112
PubMedSearch : Church_2009_PLoS.Biol_7_e1000112
PubMedID: 19468303
Gene_locus related to this paper: mouse-1neur , mouse-2neur , mouse-abd12 , mouse-abhd3 , mouse-abhd5 , mouse-acnt1 , mouse-adcl3 , mouse-bphl , mouse-c1ib , mouse-cauxin , mouse-Ces1a , mouse-Ces1b , mouse-Ces1c , mouse-Ces1e , mouse-Ces1h , mouse-Ces2a , mouse-Ces2c , mouse-Ces2f , mouse-Ces2g , mouse-Ces2h , mouse-Ces3b , mouse-Ces4a , mouse-CMBL , mouse-Dorz1 , mouse-DPP6 , mouse-dpp10 , mouse-ephx4 , mouse-g3uzn6 , mouse-KFA , mouse-LIPN , mouse-Lipo2 , mouse-Lipo4 , mouse-MEST , mouse-ndr1 , mouse-ndr4 , mouse-notum , mouse-q3uuq7 , mouse-Q8C1A9 , mouse-Q9DAI6 , mouse-SERHL , mouse-Tex30 , mouse-thyro , mouse-tmco4 , mouse-b1avu7 , mouse-b2rwd2 , mouse-j3qpi0 , mouse-w4vsp6 , mouse-f172a , mouse-f6yqt7

Title : Genome analysis of the platypus reveals unique signatures of evolution - Warren_2008_Nature_453_175
Author(s) : Warren WC , Hillier LW , Marshall Graves JA , Birney E , Ponting CP , Grutzner F , Belov K , Miller W , Clarke L , Chinwalla AT , Yang SP , Heger A , Locke DP , Miethke P , Waters PD , Veyrunes F , Fulton L , Fulton B , Graves T , Wallis J , Puente XS , Lopez-Otin C , Ordonez GR , Eichler EE , Chen L , Cheng Z , Deakin JE , Alsop A , Thompson K , Kirby P , Papenfuss AT , Wakefield MJ , Olender T , Lancet D , Huttley GA , Smit AF , Pask A , Temple-Smith P , Batzer MA , Walker JA , Konkel MK , Harris RS , Whittington CM , Wong ES , Gemmell NJ , Buschiazzo E , Vargas Jentzsch IM , Merkel A , Schmitz J , Zemann A , Churakov G , Kriegs JO , Brosius J , Murchison EP , Sachidanandam R , Smith C , Hannon GJ , Tsend-Ayush E , McMillan D , Attenborough R , Rens W , Ferguson-Smith M , Lefevre CM , Sharp JA , Nicholas KR , Ray DA , Kube M , Reinhardt R , Pringle TH , Taylor J , Jones RC , Nixon B , Dacheux JL , Niwa H , Sekita Y , Huang X , Stark A , Kheradpour P , Kellis M , Flicek P , Chen Y , Webber C , Hardison R , Nelson J , Hallsworth-Pepin K , Delehaunty K , Markovic C , Minx P , Feng Y , Kremitzki C , Mitreva M , Glasscock J , Wylie T , Wohldmann P , Thiru P , Nhan MN , Pohl CS , Smith SM , Hou S , Nefedov M , de Jong PJ , Renfree MB , Mardis ER , Wilson RK
Ref : Nature , 453 :175 , 2008
Abstract : We present a draft genome sequence of the platypus, Ornithorhynchus anatinus. This monotreme exhibits a fascinating combination of reptilian and mammalian characters. For example, platypuses have a coat of fur adapted to an aquatic lifestyle; platypus females lactate, yet lay eggs; and males are equipped with venom similar to that of reptiles. Analysis of the first monotreme genome aligned these features with genetic innovations. We find that reptile and platypus venom proteins have been co-opted independently from the same gene families; milk protein genes are conserved despite platypuses laying eggs; and immune gene family expansions are directly related to platypus biology. Expansions of protein, non-protein-coding RNA and microRNA families, as well as repeat elements, are identified. Sequencing of this genome now provides a valuable resource for deep mammalian comparative analyses, as well as for monotreme biology and conservation.
ESTHER : Warren_2008_Nature_453_175
PubMedSearch : Warren_2008_Nature_453_175
PubMedID: 18464734
Gene_locus related to this paper: ornan-f6s0q0 , ornan-f6ty74 , ornan-f6u2k2 , ornan-f6uve1 , ornan-f6vpb6 , ornan-f6ybp3 , ornan-f7bgu8 , ornan-f7ct41 , ornan-f7cza1 , ornan-f7ejp8 , ornan-f7exu1 , ornan-f7f392 , ornan-f7f9y6 , ornan-f6ve87 , ornan-f7f1d9 , ornan-f6z3l1 , ornan-f6r3f9 , ornan-f6r3g8 , ornan-f6vs71 , ornan-f7g4v8

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 : Analysis of the DNA sequence and duplication history of human chromosome 15 - Zody_2006_Nature_440_671
Author(s) : Zody MC , Garber M , Sharpe T , Young SK , Rowen L , O'Neill K , Whittaker CA , Kamal M , Chang JL , Cuomo CA , Dewar K , Fitzgerald MG , Kodira CD , Madan A , Qin S , Yang X , Abbasi N , Abouelleil A , Arachchi HM , Baradarani L , Birditt B , Bloom S , Bloom T , Borowsky ML , Burke J , Butler J , Cook A , DeArellano K , Decaprio D , Dorris L, 3rd , Dors M , Eichler EE , Engels R , Fahey J , Fleetwood P , Friedman C , Gearin G , Hall JL , Hensley G , Johnson E , Jones C , Kamat A , Kaur A , Locke DP , Munson G , Jaffe DB , Lui A , Macdonald P , Mauceli E , Naylor JW , Nesbitt R , Nicol R , O'Leary SB , Ratcliffe A , Rounsley S , She X , Sneddon KM , Stewart S , Sougnez C , Stone SM , Topham K , Vincent D , Wang S , Zimmer AR , Birren BW , Hood L , Lander ES , Nusbaum C
Ref : Nature , 440 :671 , 2006
Abstract : Here we present a finished sequence of human chromosome 15, together with a high-quality gene catalogue. As chromosome 15 is one of seven human chromosomes with a high rate of segmental duplication, we have carried out a detailed analysis of the duplication structure of the chromosome. Segmental duplications in chromosome 15 are largely clustered in two regions, on proximal and distal 15q; the proximal region is notable because recombination among the segmental duplications can result in deletions causing Prader-Willi and Angelman syndromes. Sequence analysis shows that the proximal and distal regions of 15q share extensive ancient similarity. Using a simple approach, we have been able to reconstruct many of the events by which the current duplication structure arose. We find that most of the intrachromosomal duplications seem to share a common ancestry. Finally, we demonstrate that some remaining gaps in the genome sequence are probably due to structural polymorphisms between haplotypes; this may explain a significant fraction of the gaps remaining in the human genome.
ESTHER : Zody_2006_Nature_440_671
PubMedSearch : Zody_2006_Nature_440_671
PubMedID: 16572171
Gene_locus related to this paper: human-DPP8 , human-LIPC , human-SPG21

Title : Generation and annotation of the DNA sequences of human chromosomes 2 and 4 - Hillier_2005_Nature_434_724
Author(s) : Hillier LW , Graves TA , Fulton RS , Fulton LA , Pepin KH , Minx P , Wagner-McPherson C , Layman D , Wylie K , Sekhon M , Becker MC , Fewell GA , Delehaunty KD , Miner TL , Nash WE , Kremitzki C , Oddy L , Du H , Sun H , Bradshaw-Cordum H , Ali J , Carter J , Cordes M , Harris A , Isak A , Van Brunt A , Nguyen C , Du F , Courtney L , Kalicki J , Ozersky P , Abbott S , Armstrong J , Belter EA , Caruso L , Cedroni M , Cotton M , Davidson T , Desai A , Elliott G , Erb T , Fronick C , Gaige T , Haakenson W , Haglund K , Holmes A , Harkins R , Kim K , Kruchowski SS , Strong CM , Grewal N , Goyea E , Hou S , Levy A , Martinka S , Mead K , McLellan MD , Meyer R , Randall-Maher J , Tomlinson C , Dauphin-Kohlberg S , Kozlowicz-Reilly A , Shah N , Swearengen-Shahid S , Snider J , Strong JT , Thompson J , Yoakum M , Leonard S , Pearman C , Trani L , Radionenko M , Waligorski JE , Wang C , Rock SM , Tin-Wollam AM , Maupin R , Latreille P , Wendl MC , Yang SP , Pohl C , Wallis JW , Spieth J , Bieri TA , Berkowicz N , Nelson JO , Osborne J , Ding L , Sabo A , Shotland Y , Sinha P , Wohldmann PE , Cook LL , Hickenbotham MT , Eldred J , Williams D , Jones TA , She X , Ciccarelli FD , Izaurralde E , Taylor J , Schmutz J , Myers RM , Cox DR , Huang X , McPherson JD , Mardis ER , Clifton SW , Warren WC , Chinwalla AT , Eddy SR , Marra MA , Ovcharenko I , Furey TS , Miller W , Eichler EE , Bork P , Suyama M , Torrents D , Waterston RH , Wilson RK
Ref : Nature , 434 :724 , 2005
Abstract : Human chromosome 2 is unique to the human lineage in being the product of a head-to-head fusion of two intermediate-sized ancestral chromosomes. Chromosome 4 has received attention primarily related to the search for the Huntington's disease gene, but also for genes associated with Wolf-Hirschhorn syndrome, polycystic kidney disease and a form of muscular dystrophy. Here we present approximately 237 million base pairs of sequence for chromosome 2, and 186 million base pairs for chromosome 4, representing more than 99.6% of their euchromatic sequences. Our initial analyses have identified 1,346 protein-coding genes and 1,239 pseudogenes on chromosome 2, and 796 protein-coding genes and 778 pseudogenes on chromosome 4. Extensive analyses confirm the underlying construction of the sequence, and expand our understanding of the structure and evolution of mammalian chromosomes, including gene deserts, segmental duplications and highly variant regions.
ESTHER : Hillier_2005_Nature_434_724
PubMedSearch : Hillier_2005_Nature_434_724
PubMedID: 15815621
Gene_locus related to this paper: human-ABHD1 , human-LDAH , human-ABHD18 , human-KANSL3 , human-PGAP1 , human-PREPL

Title : The DNA sequence and biology of human chromosome 19 - Grimwood_2004_Nature_428_529
Author(s) : Grimwood J , Gordon LA , Olsen A , Terry A , Schmutz J , Lamerdin J , Hellsten U , Goodstein D , Couronne O , Tran-Gyamfi M , Aerts A , Altherr M , Ashworth L , Bajorek E , Black S , Branscomb E , Caenepeel S , Carrano A , Caoile C , Chan YM , Christensen M , Cleland CA , Copeland A , Dalin E , Dehal P , Denys M , Detter JC , Escobar J , Flowers D , Fotopulos D , Garcia C , Georgescu AM , Glavina T , Gomez M , Gonzales E , Groza M , Hammon N , Hawkins T , Haydu L , Ho I , Huang W , Israni S , Jett J , Kadner K , Kimball H , Kobayashi A , Larionov V , Leem SH , Lopez F , Lou Y , Lowry S , Malfatti S , Martinez D , McCready P , Medina C , Morgan J , Nelson K , Nolan M , Ovcharenko I , Pitluck S , Pollard M , Popkie AP , Predki P , Quan G , Ramirez L , Rash S , Retterer J , Rodriguez A , Rogers S , Salamov A , Salazar A , She X , Smith D , Slezak T , Solovyev V , Thayer N , Tice H , Tsai M , Ustaszewska A , Vo N , Wagner M , Wheeler J , Wu K , Xie G , Yang J , Dubchak I , Furey TS , DeJong P , Dickson M , Gordon D , Eichler EE , Pennacchio LA , Richardson P , Stubbs L , Rokhsar DS , Myers RM , Rubin EM , Lucas SM
Ref : Nature , 428 :529 , 2004
Abstract : Chromosome 19 has the highest gene density of all human chromosomes, more than double the genome-wide average. The large clustered gene families, corresponding high G + C content, CpG islands and density of repetitive DNA indicate a chromosome rich in biological and evolutionary significance. Here we describe 55.8 million base pairs of highly accurate finished sequence representing 99.9% of the euchromatin portion of the chromosome. Manual curation of gene loci reveals 1,461 protein-coding genes and 321 pseudogenes. Among these are genes directly implicated in mendelian disorders, including familial hypercholesterolaemia and insulin-resistant diabetes. Nearly one-quarter of these genes belong to tandemly arranged families, encompassing more than 25% of the chromosome. Comparative analyses show a fascinating picture of conservation and divergence, revealing large blocks of gene orthology with rodents, scattered regions with more recent gene family expansions and deletions, and segments of coding and non-coding conservation with the distant fish species Takifugu.
ESTHER : Grimwood_2004_Nature_428_529
PubMedSearch : Grimwood_2004_Nature_428_529
PubMedID: 15057824

Title : Genome sequence of the Brown Norway rat yields insights into mammalian evolution - Gibbs_2004_Nature_428_493
Author(s) : Gibbs RA , Weinstock GM , Metzker ML , Muzny DM , Sodergren EJ , Scherer S , Scott G , Steffen D , Worley KC , Burch PE , Okwuonu G , Hines S , Lewis L , DeRamo C , Delgado O , Dugan-Rocha S , Miner G , Morgan M , Hawes A , Gill R , Celera , Holt RA , Adams MD , Amanatides PG , Baden-Tillson H , Barnstead M , Chin S , Evans CA , Ferriera S , Fosler C , Glodek A , Gu Z , Jennings D , Kraft CL , Nguyen T , Pfannkoch CM , Sitter C , Sutton GG , Venter JC , Woodage T , Smith D , Lee HM , Gustafson E , Cahill P , Kana A , Doucette-Stamm L , Weinstock K , Fechtel K , Weiss RB , Dunn DM , Green ED , Blakesley RW , Bouffard GG , de Jong PJ , Osoegawa K , Zhu B , Marra M , Schein J , Bosdet I , Fjell C , Jones S , Krzywinski M , Mathewson C , Siddiqui A , Wye N , McPherson J , Zhao S , Fraser CM , Shetty J , Shatsman S , Geer K , Chen Y , Abramzon S , Nierman WC , Havlak PH , Chen R , Durbin KJ , Egan A , Ren Y , Song XZ , Li B , Liu Y , Qin X , Cawley S , Cooney AJ , D'Souza LM , Martin K , Wu JQ , Gonzalez-Garay ML , Jackson AR , Kalafus KJ , McLeod MP , Milosavljevic A , Virk D , Volkov A , Wheeler DA , Zhang Z , Bailey JA , Eichler EE , Tuzun E , Birney E , Mongin E , Ureta-Vidal A , Woodwark C , Zdobnov E , Bork P , Suyama M , Torrents D , Alexandersson M , Trask BJ , Young JM , Huang H , Wang H , Xing H , Daniels S , Gietzen D , Schmidt J , Stevens K , Vitt U , Wingrove J , Camara F , Mar Alba M , Abril JF , Guigo R , Smit A , Dubchak I , Rubin EM , Couronne O , Poliakov A , Hubner N , Ganten D , Goesele C , Hummel O , Kreitler T , Lee YA , Monti J , Schulz H , Zimdahl H , Himmelbauer H , Lehrach H , Jacob HJ , Bromberg S , Gullings-Handley J , Jensen-Seaman MI , Kwitek AE , Lazar J , Pasko D , Tonellato PJ , Twigger S , Ponting CP , Duarte JM , Rice S , Goodstadt L , Beatson SA , Emes RD , Winter EE , Webber C , Brandt P , Nyakatura G , Adetobi M , Chiaromonte F , Elnitski L , Eswara P , Hardison RC , Hou M , Kolbe D , Makova K , Miller W , Nekrutenko A , Riemer C , Schwartz S , Taylor J , Yang S , Zhang Y , Lindpaintner K , Andrews TD , Caccamo M , Clamp M , Clarke L , Curwen V , Durbin R , Eyras E , Searle SM , Cooper GM , Batzoglou S , Brudno M , Sidow A , Stone EA , Payseur BA , Bourque G , Lopez-Otin C , Puente XS , Chakrabarti K , Chatterji S , Dewey C , Pachter L , Bray N , Yap VB , Caspi A , Tesler G , Pevzner PA , Haussler D , Roskin KM , Baertsch R , Clawson H , Furey TS , Hinrichs AS , Karolchik D , Kent WJ , Rosenbloom KR , Trumbower H , Weirauch M , Cooper DN , Stenson PD , Ma B , Brent M , Arumugam M , Shteynberg D , Copley RR , Taylor MS , Riethman H , Mudunuri U , Peterson J , Guyer M , Felsenfeld A , Old S , Mockrin S , Collins F
Ref : Nature , 428 :493 , 2004
Abstract : The laboratory rat (Rattus norvegicus) is an indispensable tool in experimental medicine and drug development, having made inestimable contributions to human health. We report here the genome sequence of the Brown Norway (BN) rat strain. The sequence represents a high-quality 'draft' covering over 90% of the genome. The BN rat sequence is the third complete mammalian genome to be deciphered, and three-way comparisons with the human and mouse genomes resolve details of mammalian evolution. This first comprehensive analysis includes genes and proteins and their relation to human disease, repeated sequences, comparative genome-wide studies of mammalian orthologous chromosomal regions and rearrangement breakpoints, reconstruction of ancestral karyotypes and the events leading to existing species, rates of variation, and lineage-specific and lineage-independent evolutionary events such as expansion of gene families, orthology relations and protein evolution.
ESTHER : Gibbs_2004_Nature_428_493
PubMedSearch : Gibbs_2004_Nature_428_493
PubMedID: 15057822
Gene_locus related to this paper: rat-abhea , rat-abheb , rat-cd029 , rat-d3zaw4 , rat-dpp9 , rat-d3zhq1 , rat-d3zkp8 , rat-d3zuq1 , rat-d3zxw8 , rat-d4a4w4 , rat-d4a7w1 , rat-d4a9l7 , rat-d4a071 , rat-d4aa31 , rat-d4aa33 , rat-d4aa61 , rat-dglb , rat-f1lz91 , rat-Kansl3 , rat-nceh1 , rat-Tex30 , ratno-1hlip , ratno-1neur , ratno-1plip , ratno-2neur , ratno-3neur , ratno-3plip , ratno-ABH15 , ratno-ACHE , ratno-balip , ratno-BCHE , ratno-cauxin , ratno-Ces1d , ratno-Ces1e , ratno-Ces2f , ratno-d3ze31 , ratno-d3zp14 , ratno-d3zxi3 , ratno-d3zxq0 , ratno-d3zxq1 , ratno-d4a3d4 , ratno-d4aa05 , ratno-dpp4 , ratno-dpp6 , ratno-est8 , ratno-FAP , ratno-hyep , ratno-hyes , ratno-kmcxe , ratno-lmcxe , ratno-LOC246252 , ratno-MGLL , ratno-pbcxe , ratno-phebest , ratno-Ppgb , ratno-q4qr68 , ratno-q6ayr2 , ratno-q6q629 , ratno-SPG21 , ratno-thyro , rat-m0rc77 , rat-a0a0g2k9y7 , rat-a0a0g2kb83 , rat-d3zba8 , rat-d3zbj1 , rat-d3zcr8 , rat-d3zxw5 , rat-d4a340 , rat-f1lvg7 , rat-m0r509 , rat-m0r5d4 , rat-b5den3 , rat-d3zxk4 , rat-d4a1b6 , rat-d3zmg4 , rat-ab17c

Title : The sequence and analysis of duplication-rich human chromosome 16 - Martin_2004_Nature_432_988
Author(s) : Martin J , Han C , Gordon LA , Terry A , Prabhakar S , She X , Xie G , Hellsten U , Chan YM , Altherr M , Couronne O , Aerts A , Bajorek E , Black S , Blumer H , Branscomb E , Brown NC , Bruno WJ , Buckingham JM , Callen DF , Campbell CS , Campbell ML , Campbell EW , Caoile C , Challacombe JF , Chasteen LA , Chertkov O , Chi HC , Christensen M , Clark LM , Cohn JD , Denys M , Detter JC , Dickson M , Dimitrijevic-Bussod M , Escobar J , Fawcett JJ , Flowers D , Fotopulos D , Glavina T , Gomez M , Gonzales E , Goodstein D , Goodwin LA , Grady DL , Grigoriev I , Groza M , Hammon N , Hawkins T , Haydu L , Hildebrand CE , Huang W , Israni S , Jett J , Jewett PB , Kadner K , Kimball H , Kobayashi A , Krawczyk MC , Leyba T , Longmire JL , Lopez F , Lou Y , Lowry S , Ludeman T , Manohar CF , Mark GA , McMurray KL , Meincke LJ , Morgan J , Moyzis RK , Mundt MO , Munk AC , Nandkeshwar RD , Pitluck S , Pollard M , Predki P , Parson-Quintana B , Ramirez L , Rash S , Retterer J , Ricke DO , Robinson DL , Rodriguez A , Salamov A , Saunders EH , Scott D , Shough T , Stallings RL , Stalvey M , Sutherland RD , Tapia R , Tesmer JG , Thayer N , Thompson LS , Tice H , Torney DC , Tran-Gyamfi M , Tsai M , Ulanovsky LE , Ustaszewska A , Vo N , White PS , Williams AL , Wills PL , Wu JR , Wu K , Yang J , DeJong P , Bruce D , Doggett NA , Deaven L , Schmutz J , Grimwood J , Richardson P , Rokhsar DS , Eichler EE , Gilna P , Lucas SM , Myers RM , Rubin EM , Pennacchio LA
Ref : Nature , 432 :988 , 2004
Abstract : Human chromosome 16 features one of the highest levels of segmentally duplicated sequence among the human autosomes. We report here the 78,884,754 base pairs of finished chromosome 16 sequence, representing over 99.9% of its euchromatin. Manual annotation revealed 880 protein-coding genes confirmed by 1,670 aligned transcripts, 19 transfer RNA genes, 341 pseudogenes and three RNA pseudogenes. These genes include metallothionein, cadherin and iroquois gene families, as well as the disease genes for polycystic kidney disease and acute myelomonocytic leukaemia. Several large-scale structural polymorphisms spanning hundreds of kilobase pairs were identified and result in gene content differences among humans. Whereas the segmental duplications of chromosome 16 are enriched in the relatively gene-poor pericentromere of the p arm, some are involved in recent gene duplication and conversion events that are likely to have had an impact on the evolution of primates and human disease susceptibility.
ESTHER : Martin_2004_Nature_432_988
PubMedSearch : Martin_2004_Nature_432_988
PubMedID: 15616553
Gene_locus related to this paper: human-CES1 , human-CES2 , human-CES3 , human-CES4A , human-CES5A

Title : The DNA sequence of human chromosome 7 - Hillier_2003_Nature_424_157
Author(s) : Hillier LW , Fulton RS , Fulton LA , Graves TA , Pepin KH , Wagner-McPherson C , Layman D , Maas J , Jaeger S , Walker R , Wylie K , Sekhon M , Becker MC , O'Laughlin MD , Schaller ME , Fewell GA , Delehaunty KD , Miner TL , Nash WE , Cordes M , Du H , Sun H , Edwards J , Bradshaw-Cordum H , Ali J , Andrews S , Isak A , Vanbrunt A , Nguyen C , Du F , Lamar B , Courtney L , Kalicki J , Ozersky P , Bielicki L , Scott K , Holmes A , Harkins R , Harris A , Strong CM , Hou S , Tomlinson C , Dauphin-Kohlberg S , Kozlowicz-Reilly A , Leonard S , Rohlfing T , Rock SM , Tin-Wollam AM , Abbott A , Minx P , Maupin R , Strowmatt C , Latreille P , Miller N , Johnson D , Murray J , Woessner JP , Wendl MC , Yang SP , Schultz BR , Wallis JW , Spieth J , Bieri TA , Nelson JO , Berkowicz N , Wohldmann PE , Cook LL , Hickenbotham MT , Eldred J , Williams D , Bedell JA , Mardis ER , Clifton SW , Chissoe SL , Marra MA , Raymond C , Haugen E , Gillett W , Zhou Y , James R , Phelps K , Iadanoto S , Bubb K , Simms E , Levy R , Clendenning J , Kaul R , Kent WJ , Furey TS , Baertsch RA , Brent MR , Keibler E , Flicek P , Bork P , Suyama M , Bailey JA , Portnoy ME , Torrents D , Chinwalla AT , Gish WR , Eddy SR , McPherson JD , Olson MV , Eichler EE , Green ED , Waterston RH , Wilson RK
Ref : Nature , 424 :157 , 2003
Abstract : Human chromosome 7 has historically received prominent attention in the human genetics community, primarily related to the search for the cystic fibrosis gene and the frequent cytogenetic changes associated with various forms of cancer. Here we present more than 153 million base pairs representing 99.4% of the euchromatic sequence of chromosome 7, the first metacentric chromosome completed so far. The sequence has excellent concordance with previously established physical and genetic maps, and it exhibits an unusual amount of segmentally duplicated sequence (8.2%), with marked differences between the two arms. Our initial analyses have identified 1,150 protein-coding genes, 605 of which have been confirmed by complementary DNA sequences, and an additional 941 pseudogenes. Of genes confirmed by transcript sequences, some are polymorphic for mutations that disrupt the reading frame.
ESTHER : Hillier_2003_Nature_424_157
PubMedSearch : Hillier_2003_Nature_424_157
PubMedID: 12853948
Gene_locus related to this paper: human-ABHD11 , human-ACHE , human-CPVL , human-DPP6 , human-MEST