McCombie WR

References (10)

Title : Genome and transcriptome of the regeneration-competent flatworm, Macrostomum lignano - Wasik_2015_Proc.Natl.Acad.Sci.U.S.A_112_12462
Author(s) : Wasik K , Gurtowski J , Zhou X , Ramos OM , Delas MJ , Battistoni G , El Demerdash O , Falciatori I , Vizoso DB , Smith AD , Ladurner P , Scharer L , McCombie WR , Hannon GJ , Schatz M
Ref : Proc Natl Acad Sci U S A , 112 :12462 , 2015
Abstract : The free-living flatworm, Macrostomum lignano has an impressive regenerative capacity. Following injury, it can regenerate almost an entirely new organism because of the presence of an abundant somatic stem cell population, the neoblasts. This set of unique properties makes many flatworms attractive organisms for studying the evolution of pathways involved in tissue self-renewal, cell-fate specification, and regeneration. The use of these organisms as models, however, is hampered by the lack of a well-assembled and annotated genome sequences, fundamental to modern genetic and molecular studies. Here we report the genomic sequence of M. lignano and an accompanying characterization of its transcriptome. The genome structure of M. lignano is remarkably complex, with approximately 75% of its sequence being comprised of simple repeats and transposon sequences. This has made high-quality assembly from Illumina reads alone impossible (N50=222 bp). We therefore generated 130x coverage by long sequencing reads from the Pacific Biosciences platform to create a substantially improved assembly with an N50 of 64 Kbp. We complemented the reference genome with an assembled and annotated transcriptome, and used both of these datasets in combination to probe gene-expression patterns during regeneration, examining pathways important to stem cell function.
ESTHER : Wasik_2015_Proc.Natl.Acad.Sci.U.S.A_112_12462
PubMedSearch : Wasik_2015_Proc.Natl.Acad.Sci.U.S.A_112_12462
PubMedID: 26392545
Gene_locus related to this paper: 9plat-a0a267ec96 , 9plat-a0a267e1q9 , 9plat-a0a1i8i888 , 9plat-a0a1i8i7g4 , 9plat-a0a1i8gq29 , 9plat-a0a1i8h217 , 9plat-a0a1i8g0z8.1 , 9plat-a0a1i8ggj9 , 9plat-a0a1i8gre8 , 9plat-a0a1i8hbi6.1 , 9plat-a0a1i8isp7

Title : Improvement of the Oryza sativa Nipponbare reference genome using next generation sequence and optical map data - Kawahara_2013_Rice.(N.Y)_6_4
Author(s) : Kawahara Y , de la Bastide M , Hamilton JP , Kanamori H , McCombie WR , Ouyang S , Schwartz DC , Tanaka T , Wu J , Zhou S , Childs KL , Davidson RM , Lin H , Quesada-Ocampo L , Vaillancourt B , Sakai H , Lee SS , Kim J , Numa H , Itoh T , Buell CR , Matsumoto T
Ref : Rice (N Y) , 6 :4 , 2013
Abstract : BACKGROUND: Rice research has been enabled by access to the high quality reference genome sequence generated in 2005 by the International Rice Genome Sequencing Project (IRGSP). To further facilitate genomic-enabled research, we have updated and validated the genome assembly and sequence for the Nipponbare cultivar of Oryza sativa (japonica group). RESULTS: The Nipponbare genome assembly was updated by revising and validating the minimal tiling path of clones with the optical map for rice. Sequencing errors in the revised genome assembly were identified by re-sequencing the genome of two different Nipponbare individuals using the Illumina Genome Analyzer II/IIx platform. A total of 4,886 sequencing errors were identified in 321 Mb of the assembled genome indicating an error rate in the original IRGSP assembly of only 0.15 per 10,000 nucleotides. A small number (five) of insertions/deletions were identified using longer reads generated using the Roche 454 pyrosequencing platform. As the re-sequencing data were generated from two different individuals, we were able to identify a number of allelic differences between the original individual used in the IRGSP effort and the two individuals used in the re-sequencing effort. The revised assembly, termed Os-Nipponbare-Reference-IRGSP-1.0, is now being used in updated releases of the Rice Annotation Project and the Michigan State University Rice Genome Annotation Project, thereby providing a unified set of pseudomolecules for the rice community. CONCLUSIONS: A revised, error-corrected, and validated assembly of the Nipponbare cultivar of rice was generated using optical map data, re-sequencing data, and manual curation that will facilitate on-going and future research in rice. Detection of polymorphisms between three different Nipponbare individuals highlights that allelic differences between individuals should be considered in diversity studies.
ESTHER : Kawahara_2013_Rice.(N.Y)_6_4
PubMedSearch : Kawahara_2013_Rice.(N.Y)_6_4
PubMedID: 24280374
Gene_locus related to this paper: orysa-Q0JK71 , orysj-q6yse8 , orysa-q6yzk1 , orysa-q7xej4 , orysa-q7xem8 , orysa-q7xr64 , orysj-a0a0p0y6l9 , orysj-pla4 , orysj-pla1 , orysj-q2r2z8

Title : Analysis of the bread wheat genome using whole-genome shotgun sequencing - Brenchley_2012_Nature_491_705
Author(s) : Brenchley R , Spannagl M , Pfeifer M , Barker GL , D'Amore R , Allen AM , McKenzie N , Kramer M , Kerhornou A , Bolser D , Kay S , Waite D , Trick M , Bancroft I , Gu Y , Huo N , Luo MC , Sehgal S , Gill B , Kianian S , Anderson O , Kersey P , Dvorak J , McCombie WR , Hall A , Mayer KF , Edwards KJ , Bevan MW , Hall N
Ref : Nature , 491 :705 , 2012
Abstract : Bread wheat (Triticum aestivum) is a globally important crop, accounting for 20 per cent of the calories consumed by humans. Major efforts are underway worldwide to increase wheat production by extending genetic diversity and analysing key traits, and genomic resources can accelerate progress. But so far the very large size and polyploid complexity of the bread wheat genome have been substantial barriers to genome analysis. Here we report the sequencing of its large, 17-gigabase-pair, hexaploid genome using 454 pyrosequencing, and comparison of this with the sequences of diploid ancestral and progenitor genomes. We identified between 94,000 and 96,000 genes, and assigned two-thirds to the three component genomes (A, B and D) of hexaploid wheat. High-resolution synteny maps identified many small disruptions to conserved gene order. We show that the hexaploid genome is highly dynamic, with significant loss of gene family members on polyploidization and domestication, and an abundance of gene fragments. Several classes of genes involved in energy harvesting, metabolism and growth are among expanded gene families that could be associated with crop productivity. Our analyses, coupled with the identification of extensive genetic variation, provide a resource for accelerating gene discovery and improving this major crop.
ESTHER : Brenchley_2012_Nature_491_705
PubMedSearch : Brenchley_2012_Nature_491_705
PubMedID: 23192148
Gene_locus related to this paper: aegta-r7w1w2 , wheat-w5asu5 , wheat-w5caq3 , wheat-w5a8u5 , wheat-a0a080yuw6 , wheat-w5d1z6 , wheat-w5d232 , wheat-w5fha9 , wheat-w5d425 , wheat-w5bnf5 , wheat-w5dsp5 , wheat-w5ia79 , wheat-w5f9d9 , wheat-w4zq98 , wheat-w5cae4 , aegta-r7w4e1 , wheat-w5gam9 , wheat-w5h0x4 , wheat-w5bda5 , wheat-w5cqa5 , wheat-w5ggq1 , wheat-w5h2c8 , wheat-w5f1j8 , wheat-a0a077rex4 , wheat-a0a1d5vkr8 , wheat-a0a1d5wx81 , wheat-a0a1d5zjt9 , wheat-a0a1d6adr6 , wheat-a0a1d6axb7 , wheat-a0a1d6s980 , wheat-a0a1d6sag1

Title : Draft genome sequence of pigeonpea (Cajanus cajan), an orphan legume crop of resource-poor farmers - Varshney_2011_Nat.Biotechnol_30_83
Author(s) : Varshney RK , Chen W , Li Y , Bharti AK , Saxena RK , Schlueter JA , Donoghue MT , Azam S , Fan G , Whaley AM , Farmer AD , Sheridan J , Iwata A , Tuteja R , Penmetsa RV , Wu W , Upadhyaya HD , Yang SP , Shah T , Saxena KB , Michael T , McCombie WR , Yang B , Zhang G , Yang H , Wang J , Spillane C , Cook DR , May GD , Xu X , Jackson SA
Ref : Nat Biotechnol , 30 :83 , 2011
Abstract : Pigeonpea is an important legume food crop grown primarily by smallholder farmers in many semi-arid tropical regions of the world. We used the Illumina next-generation sequencing platform to generate 237.2 Gb of sequence, which along with Sanger-based bacterial artificial chromosome end sequences and a genetic map, we assembled into scaffolds representing 72.7% (605.78 Mb) of the 833.07 Mb pigeonpea genome. Genome analysis predicted 48,680 genes for pigeonpea and also showed the potential role that certain gene families, for example, drought tolerance-related genes, have played throughout the domestication of pigeonpea and the evolution of its ancestors. Although we found a few segmental duplication events, we did not observe the recent genome-wide duplication events observed in soybean. This reference genome sequence will facilitate the identification of the genetic basis of agronomically important traits, and accelerate the development of improved pigeonpea varieties that could improve food security in many developing countries.
ESTHER : Varshney_2011_Nat.Biotechnol_30_83
PubMedSearch : Varshney_2011_Nat.Biotechnol_30_83
PubMedID: 22057054
Gene_locus related to this paper: cajca-a0a151r9d2 , cajca-a0a151u2m0 , cajca-a0a151tes0 , cajca-a0a151u784 , cajca-a0a151sf79 , cajca-a0a151qu18 , cajca-a0a151sz37 , cajca-a0a151ss18 , cajca-a0a151rb44 , cajca-a0a151ryr0 , cajca-a0a151qzm6 , cajca-a0a151rsm6 , cajca-a0a151rsn1 , cajca-a0a151tig2 , cajca-a0a151rwt3 , cajca-a0a151rx08 , cajca-a0a151rws4 , cajca-a0a151r0b7

Title : The B73 maize genome: complexity, diversity, and dynamics - Schnable_2009_Science_326_1112
Author(s) : Schnable PS , Ware D , Fulton RS , Stein JC , Wei F , Pasternak S , Liang C , Zhang J , Fulton L , Graves TA , Minx P , Reily AD , Courtney L , Kruchowski SS , Tomlinson C , Strong C , Delehaunty K , Fronick C , Courtney B , Rock SM , Belter E , Du F , Kim K , Abbott RM , Cotton M , Levy A , Marchetto P , Ochoa K , Jackson SM , Gillam B , Chen W , Yan L , Higginbotham J , Cardenas M , Waligorski J , Applebaum E , Phelps L , Falcone J , Kanchi K , Thane T , Scimone A , Thane N , Henke J , Wang T , Ruppert J , Shah N , Rotter K , Hodges J , Ingenthron E , Cordes M , Kohlberg S , Sgro J , Delgado B , Mead K , Chinwalla A , Leonard S , Crouse K , Collura K , Kudrna D , Currie J , He R , Angelova A , Rajasekar S , Mueller T , Lomeli R , Scara G , Ko A , Delaney K , Wissotski M , Lopez G , Campos D , Braidotti M , Ashley E , Golser W , Kim H , Lee S , Lin J , Dujmic Z , Kim W , Talag J , Zuccolo A , Fan C , Sebastian A , Kramer M , Spiegel L , Nascimento L , Zutavern T , Miller B , Ambroise C , Muller S , Spooner W , Narechania A , Ren L , Wei S , Kumari S , Faga B , Levy MJ , McMahan L , Van Buren P , Vaughn MW , Ying K , Yeh CT , Emrich SJ , Jia Y , Kalyanaraman A , Hsia AP , Barbazuk WB , Baucom RS , Brutnell TP , Carpita NC , Chaparro C , Chia JM , Deragon JM , Estill JC , Fu Y , Jeddeloh JA , Han Y , Lee H , Li P , Lisch DR , Liu S , Liu Z , Nagel DH , McCann MC , SanMiguel P , Myers AM , Nettleton D , Nguyen J , Penning BW , Ponnala L , Schneider KL , Schwartz DC , Sharma A , Soderlund C , Springer NM , Sun Q , Wang H , Waterman M , Westerman R , Wolfgruber TK , Yang L , Yu Y , Zhang L , Zhou S , Zhu Q , Bennetzen JL , Dawe RK , Jiang J , Jiang N , Presting GG , Wessler SR , Aluru S , Martienssen RA , Clifton SW , McCombie WR , Wing RA , Wilson RK
Ref : Science , 326 :1112 , 2009
Abstract : We report an improved draft nucleotide sequence of the 2.3-gigabase genome of maize, an important crop plant and model for biological research. Over 32,000 genes were predicted, of which 99.8% were placed on reference chromosomes. Nearly 85% of the genome is composed of hundreds of families of transposable elements, dispersed nonuniformly across the genome. These were responsible for the capture and amplification of numerous gene fragments and affect the composition, sizes, and positions of centromeres. We also report on the correlation of methylation-poor regions with Mu transposon insertions and recombination, and copy number variants with insertions and/or deletions, as well as how uneven gene losses between duplicated regions were involved in returning an ancient allotetraploid to a genetically diploid state. These analyses inform and set the stage for further investigations to improve our understanding of the domestication and agricultural improvements of maize.
ESTHER : Schnable_2009_Science_326_1112
PubMedSearch : Schnable_2009_Science_326_1112
PubMedID: 19965430
Gene_locus related to this paper: maize-b4ffc7 , maize-b6u7e1 , maize-c0pcy5 , maize-c0pgf7 , maize-c0pgw1 , maize-c0pfl3 , maize-b4fpr7 , maize-k7vy73 , maize-a0a096swr3 , maize-k7v3i9 , maize-b6u9v9 , maize-a0a3l6e780 , maize-b4fv80 , maize-a0a1d6nse2 , maize-c4j9a1 , maize-k7uba1

Title : Curated genome annotation of Oryza sativa ssp. japonica and comparative genome analysis with Arabidopsis thaliana - Itoh_2007_Genome.Res_17_175
Author(s) : Itoh T , Tanaka T , Barrero RA , Yamasaki C , Fujii Y , Hilton PB , Antonio BA , Aono H , Apweiler R , Bruskiewich R , Bureau T , Burr F , Costa de Oliveira A , Fuks G , Habara T , Haberer G , Han B , Harada E , Hiraki AT , Hirochika H , Hoen D , Hokari H , Hosokawa S , Hsing YI , Ikawa H , Ikeo K , Imanishi T , Ito Y , Jaiswal P , Kanno M , Kawahara Y , Kawamura T , Kawashima H , Khurana JP , Kikuchi S , Komatsu S , Koyanagi KO , Kubooka H , Lieberherr D , Lin YC , Lonsdale D , Matsumoto T , Matsuya A , McCombie WR , Messing J , Miyao A , Mulder N , Nagamura Y , Nam J , Namiki N , Numa H , Nurimoto S , O'Donovan C , Ohyanagi H , Okido T , Oota S , Osato N , Palmer LE , Quetier F , Raghuvanshi S , Saichi N , Sakai H , Sakai Y , Sakata K , Sakurai T , Sato F , Sato Y , Schoof H , Seki M , Shibata M , Shimizu Y , Shinozaki K , Shinso Y , Singh NK , Smith-White B , Takeda J , Tanino M , Tatusova T , Thongjuea S , Todokoro F , Tsugane M , Tyagi AK , Vanavichit A , Wang A , Wing RA , Yamaguchi K , Yamamoto M , Yamamoto N , Yu Y , Zhang H , Zhao Q , Higo K , Burr B , Gojobori T , Sasaki T
Ref : Genome Res , 17 :175 , 2007
Abstract : We present here the annotation of the complete genome of rice Oryza sativa L. ssp. japonica cultivar Nipponbare. All functional annotations for proteins and non-protein-coding RNA (npRNA) candidates were manually curated. Functions were identified or inferred in 19,969 (70%) of the proteins, and 131 possible npRNAs (including 58 antisense transcripts) were found. Almost 5000 annotated protein-coding genes were found to be disrupted in insertional mutant lines, which will accelerate future experimental validation of the annotations. The rice loci were determined by using cDNA sequences obtained from rice and other representative cereals. Our conservative estimate based on these loci and an extrapolation suggested that the gene number of rice is approximately 32,000, which is smaller than previous estimates. We conducted comparative analyses between rice and Arabidopsis thaliana and found that both genomes possessed several lineage-specific genes, which might account for the observed differences between these species, while they had similar sets of predicted functional domains among the protein sequences. A system to control translational efficiency seems to be conserved across large evolutionary distances. Moreover, the evolutionary process of protein-coding genes was examined. Our results suggest that natural selection may have played a role for duplicated genes in both species, so that duplication was suppressed or favored in a manner that depended on the function of a gene.
ESTHER : Itoh_2007_Genome.Res_17_175
PubMedSearch : Itoh_2007_Genome.Res_17_175
PubMedID: 17210932
Gene_locus related to this paper: orysa-Q7XTC5 , orysa-Q852M6 , orysa-Q8GSE8 , orysa-Q9FYP7 , orysa-Q5ZA26 , orysa-Q5JLP6 , orysa-Q8H5P5 , orysa-Q7F1Y5 , orysa-cbp3 , orysa-cbpx , orysa-Q6YSZ8 , orysa-Q9FW17 , orysa-Q84QZ6 , orysa-Q0JK71 , orysa-B9EWJ8 , orysa-Q6ZDG6 , orysa-Q6ZDG5 , orysa-Q658B2 , orysa-Q5N7L1 , orysa-Q8RYV9 , orysa-Q8H3R3 , orysa-Q5SNH3 , orysa-pir7a , orysa-q2qnj4 , orysa-q2qyj1 , orysa-q2r077 , orysa-Q4VWY7 , orysa-q5smv5 , orysa-q5z901 , orysa-Q5ZBI5 , orysa-q6atz0 , orysa-q6i5q3 , orysa-q6j657 , orysa-q6k4q2 , orysj-q6yse8 , orysa-q6yy42 , orysa-q6yzk1 , orysa-q6z8b1 , orysa-q6z995 , orysa-q6zjq6 , orysa-q7x7y5 , orysa-Q7XC50 , orysa-q7xr62 , orysa-q7xr63 , orysa-q7xsg1 , orysa-q7xsq2 , orysa-q7xts6 , orysa-q7xv53 , orysa-Q8LQS5 , orysa-Q8RZ79 , orysa-Q8S0U8 , orysa-Q8W3C6 , orysa-Q9LHX5 , orysa-q53m20 , orysa-q53nd8 , orysa-q60e79 , orysa-q67iz2 , orysa-q67iz3 , orysa-q67iz7 , orysa-q67iz8 , orysa-q67j02 , orysa-q67j05 , orysa-q67j09 , orysa-q67j10 , orysa-q67tr6 , orysa-q67tv0 , orysa-q69j38 , orysa-q69y21 , orysa-q75hy1 , orysa-q75hy2 , orysa-Q0J0A4 , orysa-q651a8 , orysa-q652g4 , orysa-q688m8 , orysa-Q6H8G1 , orysi-a2z179 , orysi-a2zef2 , orysi-b8a7e6 , orysi-b8a7e7 , orysi-b8bfe5 , orysi-b8bhp9 , orysj-b9fi05 , orysj-q0djj0 , orysj-q0jaf0 , orysj-q0jga1 , orysj-q0jhi5 , orysj-q5jl22 , orysj-q5jlw7 , orysj-q6h7q9 , orysj-q6yvk6 , orysj-q7f8x1 , orysj-q7xcx3 , orysj-q9fwm6 , orysj-q10j20 , orysj-q10ss2 , orysj-q69uw6 , orysj-q94d71 , orysj-q0iq98 , orysj-b9gbs4 , orysj-b9gbs1

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

Title : The genome sequence of Schizosaccharomyces pombe - Wood_2002_Nature_415_871
Author(s) : Wood V , Gwilliam R , Rajandream MA , Lyne M , Lyne R , Stewart A , Sgouros J , Peat N , Hayles J , Baker S , Basham D , Bowman S , Brooks K , Brown D , Brown S , Chillingworth T , Churcher C , Collins M , Connor R , Cronin A , Davis P , Feltwell T , Fraser A , Gentles S , Goble A , Hamlin N , Harris D , Hidalgo J , Hodgson G , Holroyd S , Hornsby T , Howarth S , Huckle EJ , Hunt S , Jagels K , James K , Jones L , Jones M , Leather S , McDonald S , McLean J , Mooney P , Moule S , Mungall K , Murphy L , Niblett D , Odell C , Oliver K , O'Neil S , Pearson D , Quail MA , Rabbinowitsch E , Rutherford K , Rutter S , Saunders D , Seeger K , Sharp S , Skelton J , Simmonds M , Squares R , Squares S , Stevens K , Taylor K , Taylor RG , Tivey A , Walsh S , Warren T , Whitehead S , Woodward J , Volckaert G , Aert R , Robben J , Grymonprez B , Weltjens I , Vanstreels E , Rieger M , Schafer M , Muller-Auer S , Gabel C , Fuchs M , Dusterhoft A , Fritzc C , Holzer E , Moestl D , Hilbert H , Borzym K , Langer I , Beck A , Lehrach H , Reinhardt R , Pohl TM , Eger P , Zimmermann W , Wedler H , Wambutt R , Purnelle B , Goffeau A , Cadieu E , Dreano S , Gloux S , Lelaure V , Mottier S , Galibert F , Aves SJ , Xiang Z , Hunt C , Moore K , Hurst SM , Lucas M , Rochet M , Gaillardin C , Tallada VA , Garzon A , Thode G , Daga RR , Cruzado L , Jimenez J , Sanchez M , del Rey F , Benito J , Dominguez A , Revuelta JL , Moreno S , Armstrong J , Forsburg SL , Cerutti L , Lowe T , McCombie WR , Paulsen I , Potashkin J , Shpakovski GV , Ussery D , Barrell BG , Nurse P
Ref : Nature , 415 :871 , 2002
Abstract : We have sequenced and annotated the genome of fission yeast (Schizosaccharomyces pombe), which contains the smallest number of protein-coding genes yet recorded for a eukaryote: 4,824. The centromeres are between 35 and 110 kilobases (kb) and contain related repeats including a highly conserved 1.8-kb element. Regions upstream of genes are longer than in budding yeast (Saccharomyces cerevisiae), possibly reflecting more-extended control regions. Some 43% of the genes contain introns, of which there are 4,730. Fifty genes have significant similarity with human disease genes; half of these are cancer related. We identify highly conserved genes important for eukaryotic cell organization including those required for the cytoskeleton, compartmentation, cell-cycle control, proteolysis, protein phosphorylation and RNA splicing. These genes may have originated with the appearance of eukaryotic life. Few similarly conserved genes that are important for multicellular organization were identified, suggesting that the transition from prokaryotes to eukaryotes required more new genes than did the transition from unicellular to multicellular organization.
ESTHER : Wood_2002_Nature_415_871
PubMedSearch : Wood_2002_Nature_415_871
PubMedID: 11859360
Gene_locus related to this paper: schpo-APTH1 , schpo-be46 , schpo-BST1 , schpo-C2E11.08 , schpo-C14C4.15C , schpo-C22H12.03 , schpo-C23C4.16C , schpo-C57A10.08C , schpo-dyr , schpo-este1 , schpo-KEX1 , schpo-PCY1 , schpo-pdat , schpo-PLG7 , schpo-ppme1 , schpo-q9c0y8 , schpo-SPAC4A8.06C , schpo-C22A12.06C , schpo-SPAC977.15 , schpo-SPAPB1A11.02 , schpo-SPBC14C8.15 , schpo-SPBC530.12C , schpo-SPBC1711.12 , schpo-SPBPB2B2.02 , schpo-SPCC5E4.05C , schpo-SPCC417.12 , schpo-SPCC1672.09 , schpo-yb4e , schpo-yblh , schpo-ydw6 , schpo-ye7a , schpo-ye63 , schpo-ye88 , schpo-yeld , schpo-yk68 , schpo-clr3 , schpo-ykv6

Title : Sequence and analysis of chromosome 5 of the plant Arabidopsis thaliana - Tabata_2000_Nature_408_823
Author(s) : Tabata S , Kaneko T , Nakamura Y , Kotani H , Kato T , Asamizu E , Miyajima N , Sasamoto S , Kimura T , Hosouchi T , Kawashima K , Kohara M , Matsumoto M , Matsuno A , Muraki A , Nakayama S , Nakazaki N , Naruo K , Okumura S , Shinpo S , Takeuchi C , Wada T , Watanabe A , Yamada M , Yasuda M , Sato S , de la Bastide M , Huang E , Spiegel L , Gnoj L , O'Shaughnessy A , Preston R , Habermann K , Murray J , Johnson D , Rohlfing T , Nelson J , Stoneking T , Pepin K , Spieth J , Sekhon M , Armstrong J , Becker M , Belter E , Cordum H , Cordes M , Courtney L , Courtney W , Dante M , Du H , Edwards J , Fryman J , Haakensen B , Lamar E , Latreille P , Leonard S , Meyer R , Mulvaney E , Ozersky P , Riley A , Strowmatt C , Wagner-McPherson C , Wollam A , Yoakum M , Bell M , Dedhia N , Parnell L , Shah R , Rodriguez M , See LH , Vil D , Baker J , Kirchoff K , Toth K , King L , Bahret A , Miller B , Marra M , Martienssen R , McCombie WR , Wilson RK , Murphy G , Bancroft I , Volckaert G , Wambutt R , Dusterhoft A , Stiekema W , Pohl T , Entian KD , Terryn N , Hartley N , Bent E , Johnson S , Langham SA , McCullagh B , Robben J , Grymonprez B , Zimmermann W , Ramsperger U , Wedler H , Balke K , Wedler E , Peters S , van Staveren M , Dirkse W , Mooijman P , Lankhorst RK , Weitzenegger T , Bothe G , Rose M , Hauf J , Berneiser S , Hempel S , Feldpausch M , Lamberth S , Villarroel R , Gielen J , Ardiles W , Bents O , Lemcke K , Kolesov G , Mayer K , Rudd S , Schoof H , Schueller C , Zaccaria P , Mewes HW , Bevan M , Fransz P
Ref : Nature , 408 :823 , 2000
Abstract : The genome of the model plant Arabidopsis thaliana has been sequenced by an international collaboration, The Arabidopsis Genome Initiative. Here we report the complete sequence of chromosome 5. This chromosome is 26 megabases long; it is the second largest Arabidopsis chromosome and represents 21% of the sequenced regions of the genome. The sequence of chromosomes 2 and 4 have been reported previously and that of chromosomes 1 and 3, together with an analysis of the complete genome sequence, are reported in this issue. Analysis of the sequence of chromosome 5 yields further insights into centromere structure and the sequence determinants of heterochromatin condensation. The 5,874 genes encoded on chromosome 5 reveal several new functions in plants, and the patterns of gene organization provide insights into the mechanisms and extent of genome evolution in plants.
ESTHER : Tabata_2000_Nature_408_823
PubMedSearch : Tabata_2000_Nature_408_823
PubMedID: 11130714
Gene_locus related to this paper: arath-At5g11650 , arath-At5g16120 , arath-at5g18630 , arath-AT5G20520 , arath-At5g21950 , arath-AT5G27320 , arath-CXE15 , arath-F1N13.220 , arath-F14F8.240 , arath-q3e9e4 , arath-q8lae9 , arath-Q8LFB7 , arath-q9ffg7 , arath-q9fij5 , arath-Q9LVU7 , arath-q66gm8 , arath-SCPL34 , arath-B9DFR3 , arath-a0a1p8bcz0

Title : Sequence and analysis of chromosome 4 of the plant Arabidopsis thaliana - Mayer_1999_Nature_402_769
Author(s) : Mayer K , Schuller C , Wambutt R , Murphy G , Volckaert G , Pohl T , Dusterhoft A , Stiekema W , Entian KD , Terryn N , Harris B , Ansorge W , Brandt P , Grivell L , Rieger M , Weichselgartner M , de Simone V , Obermaier B , Mache R , Muller M , Kreis M , Delseny M , Puigdomenech P , Watson M , Schmidtheini T , Reichert B , Portatelle D , Perez-Alonso M , Boutry M , Bancroft I , Vos P , Hoheisel J , Zimmermann W , Wedler H , Ridley P , Langham SA , McCullagh B , Bilham L , Robben J , Van der Schueren J , Grymonprez B , Chuang YJ , Vandenbussche F , Braeken M , Weltjens I , Voet M , Bastiaens I , Aert R , Defoor E , Weitzenegger T , Bothe G , Ramsperger U , Hilbert H , Braun M , Holzer E , Brandt A , Peters S , van Staveren M , Dirske W , Mooijman P , Klein Lankhorst R , Rose M , Hauf J , Kotter P , Berneiser S , Hempel S , Feldpausch M , Lamberth S , Van den Daele H , De Keyser A , Buysshaert C , Gielen J , Villarroel R , De Clercq R , van Montagu M , Rogers J , Cronin A , Quail M , Bray-Allen S , Clark L , Doggett J , Hall S , Kay M , Lennard N , McLay K , Mayes R , Pettett A , Rajandream MA , Lyne M , Benes V , Rechmann S , Borkova D , Blocker H , Scharfe M , Grimm M , Lohnert TH , Dose S , de Haan M , Maarse A , Schafer M , Muller-Auer S , Gabel C , Fuchs M , Fartmann B , Granderath K , Dauner D , Herzl A , Neumann S , Argiriou A , Vitale D , Liguori R , Piravandi E , Massenet O , Quigley F , Clabauld G , Mundlein A , Felber R , Schnabl S , Hiller R , Schmidt W , Lecharny A , Aubourg S , Chefdor F , Cooke R , Berger C , Montfort A , Casacuberta E , Gibbons T , Weber N , Vandenbol M , Bargues M , Terol J , Torres A , Perez-Perez A , Purnelle B , Bent E , Johnson S , Tacon D , Jesse T , Heijnen L , Schwarz S , Scholler P , Heber S , Francs P , Bielke C , Frishman D , Haase D , Lemcke K , Mewes HW , Stocker S , Zaccaria P , Bevan M , Wilson RK , de la Bastide M , Habermann K , Parnell L , Dedhia N , Gnoj L , Schutz K , Huang E , Spiegel L , Sehkon M , Murray J , Sheet P , Cordes M , Abu-Threideh J , Stoneking T , Kalicki J , Graves T , Harmon G , Edwards J , Latreille P , Courtney L , Cloud J , Abbott A , Scott K , Johnson D , Minx P , Bentley D , Fulton B , Miller N , Greco T , Kemp K , Kramer J , Fulton L , Mardis E , Dante M , Pepin K , Hillier L , Nelson J , Spieth J , Ryan E , Andrews S , Geisel C , Layman D , Du H , Ali J , Berghoff A , Jones K , Drone K , Cotton M , Joshu C , Antonoiu B , Zidanic M , Strong C , Sun H , Lamar B , Yordan C , Ma P , Zhong J , Preston R , Vil D , Shekher M , Matero A , Shah R , Swaby IK , O'Shaughnessy A , Rodriguez M , Hoffmann J , Till S , Granat S , Shohdy N , Hasegawa A , Hameed A , Lodhi M , Johnson A , Chen E , Marra M , Martienssen R , McCombie WR
Ref : Nature , 402 :769 , 1999
Abstract : The higher plant Arabidopsis thaliana (Arabidopsis) is an important model for identifying plant genes and determining their function. To assist biological investigations and to define chromosome structure, a coordinated effort to sequence the Arabidopsis genome was initiated in late 1996. Here we report one of the first milestones of this project, the sequence of chromosome 4. Analysis of 17.38 megabases of unique sequence, representing about 17% of the genome, reveals 3,744 protein coding genes, 81 transfer RNAs and numerous repeat elements. Heterochromatic regions surrounding the putative centromere, which has not yet been completely sequenced, are characterized by an increased frequency of a variety of repeats, new repeats, reduced recombination, lowered gene density and lowered gene expression. Roughly 60% of the predicted protein-coding genes have been functionally characterized on the basis of their homology to known genes. Many genes encode predicted proteins that are homologous to human and Caenorhabditis elegans proteins.
ESTHER : Mayer_1999_Nature_402_769
PubMedSearch : Mayer_1999_Nature_402_769
PubMedID: 10617198
Gene_locus related to this paper: arath-AT4G00500 , arath-AT4G16690 , arath-AT4G17480 , arath-AT4G24380 , arath-AT4g30610 , arath-o65513 , arath-o65713 , arath-LPAAT , arath-f4jt64