Terry A

References (14)

Title : Niche of harmful alga Aureococcus anophagefferens revealed through ecogenomics - Gobler_2011_Proc.Natl.Acad.Sci.U.S.A_108_4352
Author(s) : Gobler CJ , Berry DL , Dyhrman ST , Wilhelm SW , Salamov A , Lobanov AV , Zhang Y , Collier JL , Wurch LL , Kustka AB , Dill BD , Shah M , VerBerkmoes NC , Kuo A , Terry A , Pangilinan J , Lindquist EA , Lucas S , Paulsen IT , Hattenrath-Lehmann TK , Talmage SC , Walker EA , Koch F , Burson AM , Marcoval MA , Tang YZ , Lecleir GR , Coyne KJ , Berg GM , Bertrand EM , Saito MA , Gladyshev VN , Grigoriev IV
Ref : Proc Natl Acad Sci U S A , 108 :4352 , 2011
Abstract : Harmful algal blooms (HABs) cause significant economic and ecological damage worldwide. Despite considerable efforts, a comprehensive understanding of the factors that promote these blooms has been lacking, because the biochemical pathways that facilitate their dominance relative to other phytoplankton within specific environments have not been identified. Here, biogeochemical measurements showed that the harmful alga Aureococcus anophagefferens outcompeted co-occurring phytoplankton in estuaries with elevated levels of dissolved organic matter and turbidity and low levels of dissolved inorganic nitrogen. We subsequently sequenced the genome of A. anophagefferens and compared its gene complement with those of six competing phytoplankton species identified through metaproteomics. Using an ecogenomic approach, we specifically focused on gene sets that may facilitate dominance within the environmental conditions present during blooms. A. anophagefferens possesses a larger genome (56 Mbp) and has more genes involved in light harvesting, organic carbon and nitrogen use, and encoding selenium- and metal-requiring enzymes than competing phytoplankton. Genes for the synthesis of microbial deterrents likely permit the proliferation of this species, with reduced mortality losses during blooms. Collectively, these findings suggest that anthropogenic activities resulting in elevated levels of turbidity, organic matter, and metals have opened a niche within coastal ecosystems that ideally suits the unique genetic capacity of A. anophagefferens and thus, has facilitated the proliferation of this and potentially other HABs.
ESTHER : Gobler_2011_Proc.Natl.Acad.Sci.U.S.A_108_4352
PubMedSearch : Gobler_2011_Proc.Natl.Acad.Sci.U.S.A_108_4352
PubMedID: 21368207
Gene_locus related to this paper: auran-f0xvq5 , auran-f0xwb9 , auran-f0y4x4 , auran-f0y5a8 , auran-f0ycl4 , auran-f0ycp7 , auran-f0ye99 , auran-f0yge8 , auran-f0yci9 , auran-f0yr72 , auran-f0y8q8 , auran-f0y7s1

Title : The genome of the Western clawed frog Xenopus tropicalis - Hellsten_2010_Science_328_633
Author(s) : Hellsten U , Harland RM , Gilchrist MJ , Hendrix D , Jurka J , Kapitonov V , Ovcharenko I , Putnam NH , Shu S , Taher L , Blitz IL , Blumberg B , Dichmann DS , Dubchak I , Amaya E , Detter JC , Fletcher R , Gerhard DS , Goodstein D , Graves T , Grigoriev IV , Grimwood J , Kawashima T , Lindquist E , Lucas SM , Mead PE , Mitros T , Ogino H , Ohta Y , Poliakov AV , Pollet N , Robert J , Salamov A , Sater AK , Schmutz J , Terry A , Vize PD , Warren WC , Wells D , Wills A , Wilson RK , Zimmerman LB , Zorn AM , Grainger R , Grammer T , Khokha MK , Richardson PM , Rokhsar DS
Ref : Science , 328 :633 , 2010
Abstract : The western clawed frog Xenopus tropicalis is an important model for vertebrate development that combines experimental advantages of the African clawed frog Xenopus laevis with more tractable genetics. Here we present a draft genome sequence assembly of X. tropicalis. This genome encodes more than 20,000 protein-coding genes, including orthologs of at least 1700 human disease genes. Over 1 million expressed sequence tags validated the annotation. More than one-third of the genome consists of transposable elements, with unusually prevalent DNA transposons. Like that of other tetrapods, the genome of X. tropicalis contains gene deserts enriched for conserved noncoding elements. The genome exhibits substantial shared synteny with human and chicken over major parts of large chromosomes, broken by lineage-specific chromosome fusions and fissions, mainly in the mammalian lineage.
ESTHER : Hellsten_2010_Science_328_633
PubMedSearch : Hellsten_2010_Science_328_633
PubMedID: 20431018
Gene_locus related to this paper: xenla-q6pcj9 , xentr-a9umk0 , xentr-abhdb , xentr-ACHE , xentr-b0bm77 , xentr-b1h0y7 , xentr-b2guc4 , xentr-b7zt03 , xentr-b7ztj4 , xentr-BCHE1 , xentr-BCHE2 , xentr-cxest2 , xentr-d2x2k4 , xentr-d2x2k6 , xentr-f6rff6 , xentr-f6v0g3 , xentr-f6v2j6 , xentr-f6v3z1 , xentr-f6y4c8 , xentr-f6yve5 , xentr-f7a4y9 , xentr-f7acc5 , xentr-f7e2e2 , xentr-LOC394897 , xentr-ndrg1 , xentr-q0vfb6 , xentr-f7cpl7 , xentr-f6yj44 , xentr-f7ejk4 , xentr-f6q8j8 , xentr-f6z8f0 , xentr-f7d709 , xentr-b0bmb8 , xentr-f7af63 , xentr-a0a1b8y2w9 , xentr-f7d4k9 , xentr-f6r032 , xentr-f6yvq3 , xentr-a0a1b8y2z3 , xentr-f7afg4 , xentr-f6xb15 , xentr-f7e1r2 , xentr-a4ihf1 , xentr-f7eue5 , xentr-f6u7u3 , xentr-f172a , xentr-f7equ8 , xentr-f7dd89 , xentr-a9jtx5

Title : Genomic analysis of organismal complexity in the multicellular green alga Volvox carteri - Prochnik_2010_Science_329_223
Author(s) : Prochnik SE , Umen J , Nedelcu AM , Hallmann A , Miller SM , Nishii I , Ferris P , Kuo A , Mitros T , Fritz-Laylin LK , Hellsten U , Chapman J , Simakov O , Rensing SA , Terry A , Pangilinan J , Kapitonov V , Jurka J , Salamov A , Shapiro H , Schmutz J , Grimwood J , Lindquist E , Lucas S , Grigoriev IV , Schmitt R , Kirk D , Rokhsar DS
Ref : Science , 329 :223 , 2010
Abstract : The multicellular green alga Volvox carteri and its morphologically diverse close relatives (the volvocine algae) are well suited for the investigation of the evolution of multicellularity and development. We sequenced the 138-mega-base pair genome of V. carteri and compared its approximately 14,500 predicted proteins to those of its unicellular relative Chlamydomonas reinhardtii. Despite fundamental differences in organismal complexity and life history, the two species have similar protein-coding potentials and few species-specific protein-coding gene predictions. Volvox is enriched in volvocine-algal-specific proteins, including those associated with an expanded and highly compartmentalized extracellular matrix. Our analysis shows that increases in organismal complexity can be associated with modifications of lineage-specific proteins rather than large-scale invention of protein-coding capacity.
ESTHER : Prochnik_2010_Science_329_223
PubMedSearch : Prochnik_2010_Science_329_223
PubMedID: 20616280
Gene_locus related to this paper: volca-d8tmz1 , volca-d8tne9 , volca-d8tnn6 , volca-d8tns6 , volca-d8tr92 , volca-d8u2d3 , volca-d8u5r0 , volca-d8u7s7 , volca-d8u7s8 , volca-d8u9w4 , volca-d8u460 , volca-d8uab7 , volca-d8uai0 , volca-d8uev0 , volca-d8uhi9 , volca-d8uiw9 , volca-d8ujv0 , volca-d8uf23 , volca-d8tmz9 , volca-d8u6e0

Title : The Chlorella variabilis NC64A genome reveals adaptation to photosymbiosis, coevolution with viruses, and cryptic sex - Blanc_2010_Plant.Cell_22_2943
Author(s) : Blanc G , Duncan G , Agarkova I , Borodovsky M , Gurnon J , Kuo A , Lindquist E , Lucas S , Pangilinan J , Polle J , Salamov A , Terry A , Yamada T , Dunigan DD , Grigoriev IV , Claverie JM , Van Etten JL
Ref : Plant Cell , 22 :2943 , 2010
Abstract : Chlorella variabilis NC64A, a unicellular photosynthetic green alga (Trebouxiophyceae), is an intracellular photobiont of Paramecium bursaria and a model system for studying virus/algal interactions. We sequenced its 46-Mb nuclear genome, revealing an expansion of protein families that could have participated in adaptation to symbiosis. NC64A exhibits variations in GC content across its genome that correlate with global expression level, average intron size, and codon usage bias. Although Chlorella species have been assumed to be asexual and nonmotile, the NC64A genome encodes all the known meiosis-specific proteins and a subset of proteins found in flagella. We hypothesize that Chlorella might have retained a flagella-derived structure that could be involved in sexual reproduction. Furthermore, a survey of phytohormone pathways in chlorophyte algae identified algal orthologs of Arabidopsis thaliana genes involved in hormone biosynthesis and signaling, suggesting that these functions were established prior to the evolution of land plants. We show that the ability of Chlorella to produce chitinous cell walls likely resulted from the capture of metabolic genes by horizontal gene transfer from algal viruses, prokaryotes, or fungi. Analysis of the NC64A genome substantially advances our understanding of the green lineage evolution, including the genomic interplay with viruses and symbiosis between eukaryotes.
ESTHER : Blanc_2010_Plant.Cell_22_2943
PubMedSearch : Blanc_2010_Plant.Cell_22_2943
PubMedID: 20852019
Gene_locus related to this paper: chlva-e1z3j3 , chlva-e1z3n9 , chlva-e1z620 , chlva-e1z882 , chlva-e1zd56 , chlva-e1zdd9 , chlva-e1zde0 , chlva-e1ze02 , chlva-e1zeh7 , chlva-e1zhu4 , chlva-e1zie3 , chlva-e1zii9 , chlva-e1zmj6 , chlva-e1ztt0 , chlva-e1z5k1 , chlva-e1ztf4

Title : Genome sequencing and analysis of the biomass-degrading fungus Trichoderma reesei (syn. Hypocrea jecorina) - Martinez_2008_Nat.Biotechnol_26_553
Author(s) : Martinez D , Berka RM , Henrissat B , Saloheimo M , Arvas M , Baker SE , Chapman J , Chertkov O , Coutinho PM , Cullen D , Danchin EG , Grigoriev IV , Harris P , Jackson M , Kubicek CP , Han CS , Ho I , Larrondo LF , de Leon AL , Magnuson JK , Merino S , Misra M , Nelson B , Putnam N , Robbertse B , Salamov AA , Schmoll M , Terry A , Thayer N , Westerholm-Parvinen A , Schoch CL , Yao J , Barabote R , Nelson MA , Detter C , Bruce D , Kuske CR , Xie G , Richardson P , Rokhsar DS , Lucas SM , Rubin EM , Dunn-Coleman N , Ward M , Brettin TS
Ref : Nat Biotechnol , 26 :553 , 2008
Abstract : Trichoderma reesei is the main industrial source of cellulases and hemicellulases used to depolymerize biomass to simple sugars that are converted to chemical intermediates and biofuels, such as ethanol. We assembled 89 scaffolds (sets of ordered and oriented contigs) to generate 34 Mbp of nearly contiguous T. reesei genome sequence comprising 9,129 predicted gene models. Unexpectedly, considering the industrial utility and effectiveness of the carbohydrate-active enzymes of T. reesei, its genome encodes fewer cellulases and hemicellulases than any other sequenced fungus able to hydrolyze plant cell wall polysaccharides. Many T. reesei genes encoding carbohydrate-active enzymes are distributed nonrandomly in clusters that lie between regions of synteny with other Sordariomycetes. Numerous genes encoding biosynthetic pathways for secondary metabolites may promote survival of T. reesei in its competitive soil habitat, but genome analysis provided little mechanistic insight into its extraordinary capacity for protein secretion. Our analysis, coupled with the genome sequence data, provides a roadmap for constructing enhanced T. reesei strains for industrial applications such as biofuel production.
ESTHER : Martinez_2008_Nat.Biotechnol_26_553
PubMedSearch : Martinez_2008_Nat.Biotechnol_26_553
PubMedID: 18454138
Gene_locus related to this paper: hypjq-g0rh85 , hypjq-cip2 , hypjq-g0r9d1 , hypjq-g0r810 , hypjq-g0rbm4 , hypjq-g0rez4 , hypjq-g0rfr3 , hypjq-g0rg60 , hypjq-g0rij9 , hypjq-g0riu1 , hypjq-g0rl87 , hypjq-g0rlh4 , hypjq-g0rme5 , hypjq-g0rwy5 , hypje-axylest , hypje-q7z9m3 , hypjq-g0r6x2 , hypje-a0a024s1b8 , hypjr-a0a024s1s9 , hypjq-g0rxi5

Title : The amphioxus genome and the evolution of the chordate karyotype - Putnam_2008_Nature_453_1064
Author(s) : Putnam NH , Butts T , Ferrier DE , Furlong RF , Hellsten U , Kawashima T , Robinson-Rechavi M , Shoguchi E , Terry A , Yu JK , Benito-Gutierrez EL , Dubchak I , Garcia-Fernandez J , Gibson-Brown JJ , Grigoriev IV , Horton AC , de Jong PJ , Jurka J , Kapitonov VV , Kohara Y , Kuroki Y , Lindquist E , Lucas S , Osoegawa K , Pennacchio LA , Salamov AA , Satou Y , Sauka-Spengler T , Schmutz J , Shin IT , Toyoda A , Bronner-Fraser M , Fujiyama A , Holland LZ , Holland PW , Satoh N , Rokhsar DS
Ref : Nature , 453 :1064 , 2008
Abstract : Lancelets ('amphioxus') are the modern survivors of an ancient chordate lineage, with a fossil record dating back to the Cambrian period. Here we describe the structure and gene content of the highly polymorphic approximately 520-megabase genome of the Florida lancelet Branchiostoma floridae, and analyse it in the context of chordate evolution. Whole-genome comparisons illuminate the murky relationships among the three chordate groups (tunicates, lancelets and vertebrates), and allow not only reconstruction of the gene complement of the last common chordate ancestor but also partial reconstruction of its genomic organization, as well as a description of two genome-wide duplications and subsequent reorganizations in the vertebrate lineage. These genome-scale events shaped the vertebrate genome and provided additional genetic variation for exploitation during vertebrate evolution.
ESTHER : Putnam_2008_Nature_453_1064
PubMedSearch : Putnam_2008_Nature_453_1064
PubMedID: 18563158
Gene_locus related to this paper: brafl-ACHE1 , brafl-ACHE2 , brafl-ACHEA , brafl-ACHEB , brafl-c3xqm2 , brafl-c3xqm5 , brafl-c3xtl0 , brafl-c3xtl1 , brafl-c3xut6 , brafl-c3xut7 , brafl-c3xvw5 , brafl-c3xx27 , brafl-c3xx28 , brafl-c3xx30 , brafl-c3xx32 , brafl-c3xx36 , brafl-c3xx38 , brafl-c3xx39 , brafl-c3xx40 , brafl-c3xx41 , brafl-c3xxt9 , brafl-c3xyd7 , brafl-c3xyd8 , brafl-c3xyd9 , brafl-c3xye0 , brafl-c3xyt7 , brafl-c3xzy1 , brafl-c3xzy2 , brafl-c3y1p9 , brafl-c3y1t3 , brafl-c3y2u3 , brafl-c3y4l1 , brafl-c3y6v9 , brafl-c3y6y4 , brafl-c3y7d7 , brafl-c3y7s1 , brafl-c3y8k5 , brafl-c3y8t3 , brafl-c3y8t4 , brafl-c3y8t5 , brafl-c3y8v8 , brafl-c3y8w1.1 , brafl-c3y8w2 , brafl-c3y9i7 , brafl-c3y9i8 , brafl-c3y9l9 , brafl-c3y9y3 , brafl-c3y087 , brafl-c3yan2 , brafl-c3yaw4 , brafl-c3ybw7 , brafl-c3yc67 , brafl-c3ydm8 , brafl-c3yfm5 , brafl-c3yfz8 , brafl-c3ygc7 , brafl-c3ygc9.1 , brafl-c3ygd0 , brafl-c3ygd1 , brafl-c3ygd2.1 , brafl-c3ygd4 , brafl-c3ygg6 , brafl-c3ygr1 , brafl-c3yi63 , brafl-c3yi64 , brafl-c3yi67 , brafl-c3yi68 , brafl-c3yi69 , brafl-c3yk61 , brafl-c3ykb2 , brafl-c3yla7 , brafl-c3ylp9 , brafl-c3ylq0 , brafl-c3ylq1 , brafl-c3ymu0 , brafl-c3yne9 , brafl-c3ypm6 , brafl-c3yr72 , brafl-c3yra8 , brafl-c3ys59 , brafl-c3yv27 , brafl-c3ywf1 , brafl-c3ywh9 , brafl-c3yx17 , brafl-c3yx19 , brafl-c3yxb9 , brafl-c3yxi7 , brafl-c3yyq5 , brafl-c3yz04 , brafl-c3z1c7 , brafl-c3z1u9 , brafl-c3z1v0 , brafl-c3z3n7 , brafl-c3z5c8 , brafl-c3z9f4 , brafl-c3z066 , brafl-c3z139 , brafl-c3z975 , brafl-c3zab8 , brafl-c3zab9 , brafl-c3zbr4 , brafl-c3zci7 , brafl-c3zcy8 , brafl-c3zd14 , brafl-c3zer1 , brafl-c3zf44 , brafl-c3zf47 , brafl-c3zf48 , brafl-c3zfs6 , brafl-c3zhm6 , brafl-c3ziv7.1 , brafl-c3ziv7.2 , brafl-c3zlg0 , brafl-c3zlg2 , brafl-c3zlg3 , brafl-c3zli5 , brafl-c3zme7 , brafl-c3zme8 , brafl-c3zmp8 , brafl-c3zmv1 , brafl-c3zmv2 , brafl-c3znd6 , brafl-c3znl2 , brafl-c3zqg7 , brafl-c3zqz2 , brafl-c3zs46 , brafl-c3zs49 , brafl-c3zs56 , brafl-c3zv54 , brafl-c3zvv1 , brafl-c3zwz6 , brafl-c3zxg2 , brafl-c3zxq3 , brafl-c3yim2 , brafl-c3zfs5 , brafl-c3zfs3 , brafl-c3xr79 , brafl-c3y7r2 , brafl-c3yj62 , brafl-c3zg22 , brafl-c3y2t9 , brafl-c3y2u0 , brafl-c3ycg1 , brafl-c3ycg2 , brafl-c3ycg4 , brafl-c3z1l3 , brafl-c3zn71 , brafl-c3zj72 , brafl-c3yf35 , brafl-c3z474 , brafl-c3zqr8 , brafl-c3yde6

Title : The Physcomitrella genome reveals evolutionary insights into the conquest of land by plants - Rensing_2008_Science_319_64
Author(s) : Rensing SA , Lang D , Zimmer AD , Terry A , Salamov A , Shapiro H , Nishiyama T , Perroud PF , Lindquist EA , Kamisugi Y , Tanahashi T , Sakakibara K , Fujita T , Oishi K , Shin IT , Kuroki Y , Toyoda A , Suzuki Y , Hashimoto S , Yamaguchi K , Sugano S , Kohara Y , Fujiyama A , Anterola A , Aoki S , Ashton N , Barbazuk WB , Barker E , Bennetzen JL , Blankenship R , Cho SH , Dutcher SK , Estelle M , Fawcett JA , Gundlach H , Hanada K , Heyl A , Hicks KA , Hughes J , Lohr M , Mayer K , Melkozernov A , Murata T , Nelson DR , Pils B , Prigge M , Reiss B , Renner T , Rombauts S , Rushton PJ , Sanderfoot A , Schween G , Shiu SH , Stueber K , Theodoulou FL , Tu H , Van de Peer Y , Verrier PJ , Waters E , Wood A , Yang L , Cove D , Cuming AC , Hasebe M , Lucas S , Mishler BD , Reski R , Grigoriev IV , Quatrano RS , Boore JL
Ref : Science , 319 :64 , 2008
Abstract : We report the draft genome sequence of the model moss Physcomitrella patens and compare its features with those of flowering plants, from which it is separated by more than 400 million years, and unicellular aquatic algae. This comparison reveals genomic changes concomitant with the evolutionary movement to land, including a general increase in gene family complexity; loss of genes associated with aquatic environments (e.g., flagellar arms); acquisition of genes for tolerating terrestrial stresses (e.g., variation in temperature and water availability); and the development of the auxin and abscisic acid signaling pathways for coordinating multicellular growth and dehydration response. The Physcomitrella genome provides a resource for phylogenetic inferences about gene function and for experimental analysis of plant processes through this plant's unique facility for reverse genetics.
ESTHER : Rensing_2008_Science_319_64
PubMedSearch : Rensing_2008_Science_319_64
PubMedID: 18079367
Gene_locus related to this paper: phypa-a9rbi6 , phypa-a9rfh1 , phypa-a9rg19 , phypa-a9rgt9 , phypa-a9rhz9 , phypa-a9rkj1 , phypa-a9rns2 , phypa-a9rp52 , phypa-a9rq03 , phypa-a9ry17 , phypa-a9ry72 , phypa-a9s5n8 , phypa-a9s6w1 , phypa-a9s8c7 , phypa-a9s299 , phypa-a9san7 , phypa-a9sc75 , phypa-a9se75 , phypa-a9sg07 , phypa-a9skf7 , phypa-a9skr1 , phypa-a9skw1 , phypa-a9sl58 , phypa-a9slp7 , phypa-a9smq5 , phypa-a9sp13 , phypa-a9ssb0 , phypa-a9sse1 , phypa-a9ssf6 , phypa-a9st85 , phypa-a9sx74 , phypa-a9sy58 , phypa-a9syy4 , phypa-a9t0n4 , phypa-a9t0p4 , phypa-a9t1j2 , phypa-a9t5h1 , phypa-a9t7g6 , phypa-a9t8u8 , phypa-a9t9c9 , phypa-a9t9d9 , phypa-a0a7i4d2t7 , phypa-a9t498 , phypa-a9tbu4 , phypa-a9tc36 , phypa-a9tds0 , phypa-a9te64 , phypa-a9tfw2 , phypa-a9tin6 , phypa-a9tja4 , phypa-a9tmp3 , phypa-a9tmr4 , phypa-a9tql4 , phypa-a9tr83 , phypa-a9tsl1 , phypa-a9tsv6 , phypa-a9tu05 , phypa-a9tw81 , phypa-a9tyr8 , phypa-a9u0c9 , phypa-a9u0k3 , phypa-a9u0p4 , phypa-a9u2u7 , phypa-a9u3s0 , phypa-a9tfm7 , phypa-a9tfp6 , phypa-a9syg9 , phypa-a9tzk2 , phypa-a9tvg4 , phypa-a9t1y4 , phypa-a9tqt6 , phypa-a9st18 , phypa-a9tix9 , phypa-a0a2k1kfe3 , phypa-a9sqk3 , phypa-a0a2k1ie71 , phypa-a0a2k1kg29 , phypa-a0a2k1iji3

Title : The Chlamydomonas genome reveals the evolution of key animal and plant functions - Merchant_2007_Science_318_245
Author(s) : Merchant SS , Prochnik SE , Vallon O , Harris EH , Karpowicz SJ , Witman GB , Terry A , Salamov A , Fritz-Laylin LK , Marechal-Drouard L , Marshall WF , Qu LH , Nelson DR , Sanderfoot AA , Spalding MH , Kapitonov VV , Ren Q , Ferris P , Lindquist E , Shapiro H , Lucas SM , Grimwood J , Schmutz J , Cardol P , Cerutti H , Chanfreau G , Chen CL , Cognat V , Croft MT , Dent R , Dutcher S , Fernandez E , Fukuzawa H , Gonzalez-Ballester D , Gonzalez-Halphen D , Hallmann A , Hanikenne M , Hippler M , Inwood W , Jabbari K , Kalanon M , Kuras R , Lefebvre PA , Lemaire SD , Lobanov AV , Lohr M , Manuell A , Meier I , Mets L , Mittag M , Mittelmeier T , Moroney JV , Moseley J , Napoli C , Nedelcu AM , Niyogi K , Novoselov SV , Paulsen IT , Pazour G , Purton S , Ral JP , Riano-Pachon DM , Riekhof W , Rymarquis L , Schroda M , Stern D , Umen J , Willows R , Wilson N , Zimmer SL , Allmer J , Balk J , Bisova K , Chen CJ , Elias M , Gendler K , Hauser C , Lamb MR , Ledford H , Long JC , Minagawa J , Page MD , Pan J , Pootakham W , Roje S , Rose A , Stahlberg E , Terauchi AM , Yang P , Ball S , Bowler C , Dieckmann CL , Gladyshev VN , Green P , Jorgensen R , Mayfield S , Mueller-Roeber B , Rajamani S , Sayre RT , Brokstein P , Dubchak I , Goodstein D , Hornick L , Huang YW , Jhaveri J , Luo Y , Martinez D , Ngau WC , Otillar B , Poliakov A , Porter A , Szajkowski L , Werner G , Zhou K , Grigoriev IV , Rokhsar DS , Grossman AR
Ref : Science , 318 :245 , 2007
Abstract : Chlamydomonas reinhardtii is a unicellular green alga whose lineage diverged from land plants over 1 billion years ago. It is a model system for studying chloroplast-based photosynthesis, as well as the structure, assembly, and function of eukaryotic flagella (cilia), which were inherited from the common ancestor of plants and animals, but lost in land plants. We sequenced the approximately 120-megabase nuclear genome of Chlamydomonas and performed comparative phylogenomic analyses, identifying genes encoding uncharacterized proteins that are likely associated with the function and biogenesis of chloroplasts or eukaryotic flagella. Analyses of the Chlamydomonas genome advance our understanding of the ancestral eukaryotic cell, reveal previously unknown genes associated with photosynthetic and flagellar functions, and establish links between ciliopathy and the composition and function of flagella.
ESTHER : Merchant_2007_Science_318_245
PubMedSearch : Merchant_2007_Science_318_245
PubMedID: 17932292
Gene_locus related to this paper: chlre-a0a2k3e2k6 , chlre-a8hmd4 , chlre-a8hqa9 , chlre-a8htq0 , chlre-a8hus6.1 , chlre-a8hus6.2 , chlre-a8icg4 , chlre-a8iwm0 , chlre-a8ize5 , chlre-a8j2s9 , chlre-a8j5w6 , chlre-a8j7f8 , chlre-a8j8u9 , chlre-a8j8v0 , chlre-a8j9u6 , chlre-a8j143 , chlre-a8j248 , chlre-a8jd32 , chlre-a8jd42 , chlre-a8jgj2 , chlre-a8jhc8 , chlre-a8jhe5 , chlre-a8iwj1 , chlre-a8j7d5 , chlre-a0a2k3dii0

Title : Sea anemone genome reveals ancestral eumetazoan gene repertoire and genomic organization - Putnam_2007_Science_317_86
Author(s) : Putnam NH , Srivastava M , Hellsten U , Dirks B , Chapman J , Salamov A , Terry A , Shapiro H , Lindquist E , Kapitonov VV , Jurka J , Genikhovich G , Grigoriev IV , Lucas SM , Steele RE , Finnerty JR , Technau U , Martindale MQ , Rokhsar DS
Ref : Science , 317 :86 , 2007
Abstract : Sea anemones are seemingly primitive animals that, along with corals, jellyfish, and hydras, constitute the oldest eumetazoan phylum, the Cnidaria. Here, we report a comparative analysis of the draft genome of an emerging cnidarian model, the starlet sea anemone Nematostella vectensis. The sea anemone genome is complex, with a gene repertoire, exon-intron structure, and large-scale gene linkage more similar to vertebrates than to flies or nematodes, implying that the genome of the eumetazoan ancestor was similarly complex. Nearly one-fifth of the inferred genes of the ancestor are eumetazoan novelties, which are enriched for animal functions like cell signaling, adhesion, and synaptic transmission. Analysis of diverse pathways suggests that these gene "inventions" along the lineage leading to animals were likely already well integrated with preexisting eukaryotic genes in the eumetazoan progenitor.
ESTHER : Putnam_2007_Science_317_86
PubMedSearch : Putnam_2007_Science_317_86
PubMedID: 17615350
Gene_locus related to this paper: nemve-a7rfc6 , nemve-a7rhs0 , nemve-a7rhw2 , nemve-a7ric9 , nemve-a7riu9 , nemve-a7rk54 , nemve-a7rlg8 , nemve-a7rlv4 , nemve-a7rn07 , nemve-a7rn08 , nemve-a7rn68 , nemve-a7rnv3 , nemve-a7rpb3 , nemve-a7rpq4 , nemve-a7rqa8 , nemve-a7rqw3 , nemve-a7rwv1 , nemve-a7rxl6 , nemve-a7s1d5 , nemve-a7s3l3 , nemve-a7s3q1 , nemve-a7s5u3 , nemve-a7s6g4 , nemve-a7s6s7 , nemve-a7sa46 , nemve-a7sbd9 , nemve-a7sbe0 , nemve-a7sbm6 , nemve-a7scy7 , nemve-a7sex0 , nemve-a7sfa0 , nemve-a7sff3 , nemve-a7sgb1 , nemve-a7shf2 , nemve-a7siv4 , nemve-a7sj77 , nemve-a7sjw1 , nemve-a7skr3 , nemve-a7slm1 , nemve-a7slm2 , nemve-a7sp35 , nemve-a7sq47 , nemve-a7sq73 , nemve-a7sqk0 , nemve-a7su21 , nemve-a7su25 , nemve-a7svn0 , nemve-a7svu2 , nemve-a7sx21 , nemve-a7syk4 , nemve-a7t3e6 , nemve-a7suy2 , nemve-a7s803 , nemve-a7t3m9 , nemve-a0a1t4jh34 , nemve-a7rvd5 , nemve-a7rhu9 , nemve-a7si15

Title : The genome of black cottonwood, Populus trichocarpa (Torr. &\; Gray) - Tuskan_2006_Science_313_1596
Author(s) : Tuskan GA , Difazio S , Jansson S , Bohlmann J , Grigoriev I , Hellsten U , Putnam N , Ralph S , Rombauts S , Salamov A , Schein J , Sterck L , Aerts A , Bhalerao RR , Bhalerao RP , Blaudez D , Boerjan W , Brun A , Brunner A , Busov V , Campbell M , Carlson J , Chalot M , Chapman J , Chen GL , Cooper D , Coutinho PM , Couturier J , Covert S , Cronk Q , Cunningham R , Davis J , Degroeve S , Dejardin A , dePamphilis C , Detter J , Dirks B , Dubchak I , Duplessis S , Ehlting J , Ellis B , Gendler K , Goodstein D , Gribskov M , Grimwood J , Groover A , Gunter L , Hamberger B , Heinze B , Helariutta Y , Henrissat B , Holligan D , Holt R , Huang W , Islam-Faridi N , Jones S , Jones-Rhoades M , Jorgensen R , Joshi C , Kangasjarvi J , Karlsson J , Kelleher C , Kirkpatrick R , Kirst M , Kohler A , Kalluri U , Larimer F , Leebens-Mack J , Leple JC , Locascio P , Lou Y , Lucas S , Martin F , Montanini B , Napoli C , Nelson DR , Nelson C , Nieminen K , Nilsson O , Pereda V , Peter G , Philippe R , Pilate G , Poliakov A , Razumovskaya J , Richardson P , Rinaldi C , Ritland K , Rouze P , Ryaboy D , Schmutz J , Schrader J , Segerman B , Shin H , Siddiqui A , Sterky F , Terry A , Tsai CJ , Uberbacher E , Unneberg P , Vahala J , Wall K , Wessler S , Yang G , Yin T , Douglas C , Marra M , Sandberg G , Van de Peer Y , Rokhsar D
Ref : Science , 313 :1596 , 2006
Abstract : We report the draft genome of the black cottonwood tree, Populus trichocarpa. Integration of shotgun sequence assembly with genetic mapping enabled chromosome-scale reconstruction of the genome. More than 45,000 putative protein-coding genes were identified. Analysis of the assembled genome revealed a whole-genome duplication event; about 8000 pairs of duplicated genes from that event survived in the Populus genome. A second, older duplication event is indistinguishably coincident with the divergence of the Populus and Arabidopsis lineages. Nucleotide substitution, tandem gene duplication, and gross chromosomal rearrangement appear to proceed substantially more slowly in Populus than in Arabidopsis. Populus has more protein-coding genes than Arabidopsis, ranging on average from 1.4 to 1.6 putative Populus homologs for each Arabidopsis gene. However, the relative frequency of protein domains in the two genomes is similar. Overrepresented exceptions in Populus include genes associated with lignocellulosic wall biosynthesis, meristem development, disease resistance, and metabolite transport.
ESTHER : Tuskan_2006_Science_313_1596
PubMedSearch : Tuskan_2006_Science_313_1596
PubMedID: 16973872
Gene_locus related to this paper: burvg-a4jw31 , delas-a9c1v9 , poptr-a9pfp5 , poptr-a9ph43 , poptr-a9ph71 , poptr-a9pha7 , poptr-b9giq0 , poptr-b9gjs0 , poptr-b9gl72 , poptr-b9gmx8 , poptr-b9gnp9 , poptr-b9gny4 , poptr-b9grg2 , poptr-b9gsc2 , poptr-b9gvp3 , poptr-b9gvs3 , poptr-b9gwn9 , poptr-b9gy32 , poptr-b9gyq1 , poptr-b9gys8 , poptr-b9h0h0 , poptr-b9h4j2 , poptr-b9h6c2 , poptr-b9h6c5 , poptr-b9h6l8 , poptr-b9h8c9 , poptr-b9h301 , poptr-b9h579 , poptr-b9hbl2 , poptr-b9hbw5 , poptr-b9hcn9 , poptr-b9hee0 , poptr-b9hee2 , poptr-b9hee5 , poptr-b9hee6 , poptr-b9hef3 , poptr-b9hfa7 , poptr-b9hfd3 , poptr-b9hfi6 , poptr-b9hft8 , poptr-b9hg83 , poptr-b9hif5 , poptr-b9hll5 , poptr-b9hmd0 , poptr-b9hnv3 , poptr-b9hqr6 , poptr-b9hqr7 , poptr-b9hrv7 , poptr-b9hs66 , poptr-b9huf0 , poptr-b9hur3 , poptr-b9hux1 , poptr-b9hwp2 , poptr-b9hxr7 , poptr-b9hyk8 , poptr-b9hyx2 , poptr-b9i2q8 , poptr-b9i5b8 , poptr-b9i5j8 , poptr-b9i5j9 , poptr-b9i5k0 , poptr-b9i6b6 , poptr-b9i7b7 , poptr-b9i9p8 , poptr-b9i484 , poptr-b9i994 , poptr-b9ial3 , poptr-b9ial4 , poptr-b9ib28 , poptr-b9ibr8 , poptr-b9id97 , poptr-b9idr4 , poptr-b9iid9 , poptr-b9iip0 , poptr-b9ik80 , poptr-b9ik90 , poptr-b9il63 , poptr-b9ink7 , poptr-b9iqa0 , poptr-b9iqd5 , poptr-b9mwf1 , poptr-b9mwi8 , poptr-b9n0c6 , poptr-b9n0n1 , poptr-b9n0n4 , poptr-b9n0z5 , poptr-b9n1t8 , poptr-b9n1z3 , poptr-b9n3m7 , poptr-b9n233 , poptr-b9n236 , poptr-b9n395 , poptr-b9nd33 , poptr-b9nd34 , poptr-b9ndi6 , poptr-b9ndj5 , poptr-b9p9i8 , poptr-a9pfa7 , poptr-b9hdp2 , poptr-b9inj0 , poptr-b9n5g7 , poptr-b9i8q4 , poptr-u5g0r4 , poptr-u5gf59 , poptr-u7e1l9 , poptr-b9hj61 , poptr-b9hwd0 , poptr-u5fz17 , poptr-a0a2k2brq1 , poptr-a0a2k2b9i6 , poptr-a0a2k1x9y8 , poptr-a9pch4 , poptr-a0a2k1wwt1 , poptr-a0a2k1wv10 , poptr-a0a2k2a850 , poptr-a0a2k2asj6 , poptr-a0a2k1x6k1 , poptr-u5fv96 , poptr-a0a2k2blg2 , poptr-a0a2k1xpi3 , poptr-a0a2k1xpj0 , poptr-a0a2k2b331 , poptr-a0a2k2byl7 , poptr-b9iek5 , poptr-a9pfg4 , poptr-a0a2k1xzs5 , poptr-b9gga9 , poptr-b9guw6 , poptr-b9hff2

Title : Phytophthora genome sequences uncover evolutionary origins and mechanisms of pathogenesis - Tyler_2006_Science_313_1261
Author(s) : Tyler BM , Tripathy S , Zhang X , Dehal P , Jiang RH , Aerts A , Arredondo FD , Baxter L , Bensasson D , Beynon JL , Chapman J , Damasceno CM , Dorrance AE , Dou D , Dickerman AW , Dubchak IL , Garbelotto M , Gijzen M , Gordon SG , Govers F , Grunwald NJ , Huang W , Ivors KL , Jones RW , Kamoun S , Krampis K , Lamour KH , Lee MK , McDonald WH , Medina M , Meijer HJ , Nordberg EK , Maclean DJ , Ospina-Giraldo MD , Morris PF , Phuntumart V , Putnam NH , Rash S , Rose JK , Sakihama Y , Salamov AA , Savidor A , Scheuring CF , Smith BM , Sobral BW , Terry A , Torto-Alalibo TA , Win J , Xu Z , Zhang H , Grigoriev IV , Rokhsar DS , Boore JL
Ref : Science , 313 :1261 , 2006
Abstract : Draft genome sequences have been determined for the soybean pathogen Phytophthora sojae and the sudden oak death pathogen Phytophthora ramorum. Oomycetes such as these Phytophthora species share the kingdom Stramenopila with photosynthetic algae such as diatoms, and the presence of many Phytophthora genes of probable phototroph origin supports a photosynthetic ancestry for the stramenopiles. Comparison of the two species' genomes reveals a rapid expansion and diversification of many protein families associated with plant infection such as hydrolases, ABC transporters, protein toxins, proteinase inhibitors, and, in particular, a superfamily of 700 proteins with similarity to known oomycete avirulence genes.
ESTHER : Tyler_2006_Science_313_1261
PubMedSearch : Tyler_2006_Science_313_1261
PubMedID: 16946064
Gene_locus related to this paper: phyrm-h3ga89 , phyrm-h3gbl6.1 , phyrm-h3gbl6.2 , phyrm-h3gbl7 , phyrm-h3gdd4 , phyrm-h3gl36 , phyrm-h3gq42 , phyrm-h3gx86 , phyrm-h3gyi2 , phyrm-h3gyi3 , phyrm-h3gyi4 , phyrm-h3h292 , phyrm-h3h293 , phyrm-h3h967 , phyrm-h3hcf9 , physp-g4ynp3 , physp-g4yut6 , physp-g4yut8 , physp-g4yw23 , physp-g4zis3 , physp-g4zqe3 , physp-g4zqe4 , physp-g4zqf0 , physp-g4zqn9 , physp-g4zwy9 , physp-g5a582 , physp-g5a583 , physp-g5aav9 , phyrm-h3g9e7 , physp-g4zwu9 , phyrm-h3ggp1 , physp-g4ztq5 , physp-g4zwu8 , physp-g4zwv7 , physp-g4zwv6 , physp-g4zwv0 , physp-g4zwv8 , phyrm-h3gp95 , phyrm-h3g6r5 , physp-g4zwv9 , physp-g5a510 , phyrm-h3glu3 , physp-g5aci1 , phyrm-h3h2d0 , physp-g4ztb2 , physp-g4yg47 , phyrm-h3h2c9 , physp-g4ztb3 , phyrm-h3gvj3 , phyrm-h3gy62 , physp-g4yg46 , physp-g4zdt9 , phyrm-h3gdh5 , physp-g4zm41 , physp-g5abj7 , phyrm-h3gz76 , physp-g5a425 , phyrm-h3h080 , physp-g4ytv0 , phyrm-h3gcw7

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 : 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 draft genome of Ciona intestinalis: insights into chordate and vertebrate origins - Dehal_2002_Science_298_2157
Author(s) : Dehal P , Satou Y , Campbell RK , Chapman J , Degnan B , De Tomaso A , Davidson B , Di Gregorio A , Gelpke M , Goodstein DM , Harafuji N , Hastings KE , Ho I , Hotta K , Huang W , Kawashima T , Lemaire P , Martinez D , Meinertzhagen IA , Necula S , Nonaka M , Putnam N , Rash S , Saiga H , Satake M , Terry A , Yamada L , Wang HG , Awazu S , Azumi K , Boore J , Branno M , Chin-Bow S , DeSantis R , Doyle S , Francino P , Keys DN , Haga S , Hayashi H , Hino K , Imai KS , Inaba K , Kano S , Kobayashi K , Kobayashi M , Lee BI , Makabe KW , Manohar C , Matassi G , Medina M , Mochizuki Y , Mount S , Morishita T , Miura S , Nakayama A , Nishizaka S , Nomoto H , Ohta F , Oishi K , Rigoutsos I , Sano M , Sasaki A , Sasakura Y , Shoguchi E , Shin-I T , Spagnuolo A , Stainier D , Suzuki MM , Tassy O , Takatori N , Tokuoka M , Yagi K , Yoshizaki F , Wada S , Zhang C , Hyatt PD , Larimer F , Detter C , Doggett N , Glavina T , Hawkins T , Richardson P , Lucas S , Kohara Y , Levine M , Satoh N , Rokhsar DS
Ref : Science , 298 :2157 , 2002
Abstract : The first chordates appear in the fossil record at the time of the Cambrian explosion, nearly 550 million years ago. The modern ascidian tadpole represents a plausible approximation to these ancestral chordates. To illuminate the origins of chordate and vertebrates, we generated a draft of the protein-coding portion of the genome of the most studied ascidian, Ciona intestinalis. The Ciona genome contains approximately 16,000 protein-coding genes, similar to the number in other invertebrates, but only half that found in vertebrates. Vertebrate gene families are typically found in simplified form in Ciona, suggesting that ascidians contain the basic ancestral complement of genes involved in cell signaling and development. The ascidian genome has also acquired a number of lineage-specific innovations, including a group of genes engaged in cellulose metabolism that are related to those in bacteria and fungi.
ESTHER : Dehal_2002_Science_298_2157
PubMedSearch : Dehal_2002_Science_298_2157
PubMedID: 12481130
Gene_locus related to this paper: cioin-141645 , cioin-147959 , cioin-150181 , cioin-154370 , cioin-ACHE1 , cioin-ACHE2 , cioin-cxest , cioin-f6qcp0 , cioin-f6r8z1 , cioin-f6u176 , cioin-f6vac9 , cioin-f6x584 , cioin-f6xa69 , cioin-f6y403 , cioin-h2xqb4 , cioin-H2XTI0 , cioin-F6T1M3 , cioin-H2XUP7 , cioin-CIN.7233 , cioin-F6V269 , cioin-Cin16330 , cioin-h2xua2 , cioin-f6vaa5 , cioin-f6v9x6 , cioin-f6swc9 , cioin-f7amz2 , cioin-f6s021 , cioin-h2xxq9 , cioin-h2xne6 , cioin-f6ynr2