Waterston R

References (4)

Title : Finding functional features in Saccharomyces genomes by phylogenetic footprinting - Cliften_2003_Science_301_71
Author(s) : Cliften P , Sudarsanam P , Desikan A , Fulton L , Fulton B , Majors J , Waterston R , Cohen BA , Johnston M
Ref : Science , 301 :71 , 2003
Abstract : The sifting and winnowing of DNA sequence that occur during evolution cause nonfunctional sequences to diverge, leaving phylogenetic footprints of functional sequence elements in comparisons of genome sequences. We searched for such footprints among the genome sequences of six Saccharomyces species and identified potentially functional sequences. Comparison of these sequences allowed us to revise the catalog of yeast genes and identify sequence motifs that may be targets of transcriptional regulatory proteins. Some of these conserved sequence motifs reside upstream of genes with similar functional annotations or similar expression patterns or those bound by the same transcription factor and are thus good candidates for functional regulatory sequences.
ESTHER : Cliften_2003_Science_301_71
PubMedSearch : Cliften_2003_Science_301_71
PubMedID: 12775844
Gene_locus related to this paper: sack1-j5ri36

Title : Analysis of the mouse transcriptome based on functional annotation of 60,770 full-length cDNAs - Okazaki_2002_Nature_420_563
Author(s) : Okazaki Y , Furuno M , Kasukawa T , Adachi J , Bono H , Kondo S , Nikaido I , Osato N , Saito R , Suzuki H , Yamanaka I , Kiyosawa H , Yagi K , Tomaru Y , Hasegawa Y , Nogami A , Schonbach C , Gojobori T , Baldarelli R , Hill DP , Bult C , Hume DA , Quackenbush J , Schriml LM , Kanapin A , Matsuda H , Batalov S , Beisel KW , Blake JA , Bradt D , Brusic V , Chothia C , Corbani LE , Cousins S , Dalla E , Dragani TA , Fletcher CF , Forrest A , Frazer KS , Gaasterland T , Gariboldi M , Gissi C , Godzik A , Gough J , Grimmond S , Gustincich S , Hirokawa N , Jackson IJ , Jarvis ED , Kanai A , Kawaji H , Kawasawa Y , Kedzierski RM , King BL , Konagaya A , Kurochkin IV , Lee Y , Lenhard B , Lyons PA , Maglott DR , Maltais L , Marchionni L , McKenzie L , Miki H , Nagashima T , Numata K , Okido T , Pavan WJ , Pertea G , Pesole G , Petrovsky N , Pillai R , Pontius JU , Qi D , Ramachandran S , Ravasi T , Reed JC , Reed DJ , Reid J , Ring BZ , Ringwald M , Sandelin A , Schneider C , Semple CA , Setou M , Shimada K , Sultana R , Takenaka Y , Taylor MS , Teasdale RD , Tomita M , Verardo R , Wagner L , Wahlestedt C , Wang Y , Watanabe Y , Wells C , Wilming LG , Wynshaw-Boris A , Yanagisawa M , Yang I , Yang L , Yuan Z , Zavolan M , Zhu Y , Zimmer A , Carninci P , Hayatsu N , Hirozane-Kishikawa T , Konno H , Nakamura M , Sakazume N , Sato K , Shiraki T , Waki K , Kawai J , Aizawa K , Arakawa T , Fukuda S , Hara A , Hashizume W , Imotani K , Ishii Y , Itoh M , Kagawa I , Miyazaki A , Sakai K , Sasaki D , Shibata K , Shinagawa A , Yasunishi A , Yoshino M , Waterston R , Lander ES , Rogers J , Birney E , Hayashizaki Y
Ref : Nature , 420 :563 , 2002
Abstract : Only a small proportion of the mouse genome is transcribed into mature messenger RNA transcripts. There is an international collaborative effort to identify all full-length mRNA transcripts from the mouse, and to ensure that each is represented in a physical collection of clones. Here we report the manual annotation of 60,770 full-length mouse complementary DNA sequences. These are clustered into 33,409 'transcriptional units', contributing 90.1% of a newly established mouse transcriptome database. Of these transcriptional units, 4,258 are new protein-coding and 11,665 are new non-coding messages, indicating that non-coding RNA is a major component of the transcriptome. 41% of all transcriptional units showed evidence of alternative splicing. In protein-coding transcripts, 79% of splice variations altered the protein product. Whole-transcriptome analyses resulted in the identification of 2,431 sense-antisense pairs. The present work, completely supported by physical clones, provides the most comprehensive survey of a mammalian transcriptome so far, and is a valuable resource for functional genomics.
ESTHER : Okazaki_2002_Nature_420_563
PubMedSearch : Okazaki_2002_Nature_420_563
PubMedID: 12466851
Gene_locus related to this paper: mouse-1lipg , mouse-1llip , mouse-1plrp , mouse-3neur , mouse-ABH15 , mouse-abhd4 , mouse-abhd5 , mouse-Abhd8 , mouse-Abhd11 , mouse-abhda , mouse-acot4 , mouse-adcl4 , mouse-AI607300 , mouse-BAAT , mouse-bphl , mouse-C87498 , mouse-Ldah , mouse-Ces1d , mouse-Ces2e , mouse-CMBL , mouse-DGLB , mouse-dpp9 , mouse-ES10 , mouse-F135A , mouse-FASN , mouse-hslip , mouse-hyes , mouse-Kansl3 , mouse-LIPH , mouse-LIPK , mouse-lipli , mouse-LIPM , mouse-lypla1 , mouse-lypla2 , mouse-MEST , mouse-MGLL , mouse-ndr4 , mouse-OVCA2 , mouse-pafa , mouse-pcp , mouse-ppce , mouse-Ppgb , mouse-PPME1 , mouse-q3uuq7 , mouse-Q8BLF1 , mouse-ACOT6 , mouse-Q8C1A9 , mouse-Q9DAI6 , mouse-Q80UX8 , mouse-Q8BGG9 , mouse-Q8C167 , mouse-rbbp9 , mouse-SERHL , mouse-tssp

Title : Complete genome sequence of Salmonella enterica serovar Typhimurium LT2 - McClelland_2001_Nature_413_852
Author(s) : McClelland M , Sanderson KE , Spieth J , Clifton SW , Latreille P , Courtney L , Porwollik S , Ali J , Dante M , Du F , Hou S , Layman D , Leonard S , Nguyen C , Scott K , Holmes A , Grewal N , Mulvaney E , Ryan E , Sun H , Florea L , Miller W , Stoneking T , Nhan M , Waterston R , Wilson RK
Ref : Nature , 413 :852 , 2001
Abstract : Salmonella enterica subspecies I, serovar Typhimurium (S. typhimurium), is a leading cause of human gastroenteritis, and is used as a mouse model of human typhoid fever. The incidence of non-typhoid salmonellosis is increasing worldwide, causing millions of infections and many deaths in the human population each year. Here we sequenced the 4,857-kilobase (kb) chromosome and 94-kb virulence plasmid of S. typhimurium strain LT2. The distribution of close homologues of S. typhimurium LT2 genes in eight related enterobacteria was determined using previously completed genomes of three related bacteria, sample sequencing of both S. enterica serovar Paratyphi A (S. paratyphi A) and Klebsiella pneumoniae, and hybridization of three unsequenced genomes to a microarray of S. typhimurium LT2 genes. Lateral transfer of genes is frequent, with 11% of the S. typhimurium LT2 genes missing from S. enterica serovar Typhi (S. typhi), and 29% missing from Escherichia coli K12. The 352 gene homologues of S. typhimurium LT2 confined to subspecies I of S. enterica-containing most mammalian and bird pathogens-are useful for studies of epidemiology, host specificity and pathogenesis. Most of these homologues were previously unknown, and 50 may be exported to the periplasm or outer membrane, rendering them accessible as therapeutic or vaccine targets.
ESTHER : McClelland_2001_Nature_413_852
PubMedSearch : McClelland_2001_Nature_413_852
PubMedID: 11677609
Gene_locus related to this paper: salen-OPDB , salti-q8z717 , salty-AES , salty-BIOH , salty-ENTF , salty-FES , salty-IROD , salty-IROE , salty-P74847 , salty-PLDB , salty-STM0332 , salty-STM2547 , salty-STM3079 , salty-STM4506 , salty-STY1441 , salty-STY2428 , salty-STY3846 , salty-yafa , salty-YBFF , salty-ycfp , salty-YFBB , salty-YHET , salty-YJFP , salty-YQIA

Title : The DNA sequence of human chromosome 22 - Dunham_1999_Nature_402_489
Author(s) : Dunham I , Hunt AR , Collins JE , Bruskiewich R , Beare DM , Clamp M , Smink LJ , Ainscough R , Almeida JP , Babbage AK , Bagguley C , Bailey J , Barlow KF , Bates KN , Beasley OP , Bird CP , Blakey SE , Bridgeman AM , Buck D , Burgess J , Burrill WD , Burton J , Carder C , Carter NP , Chen Y , Clark G , Clegg SM , Cobley VE , Cole CG , Collier RE , Connor R , Conroy D , Corby NR , Coville GJ , Cox AV , Davis J , Dawson E , Dhami PD , Dockree C , Dodsworth SJ , Durbin RM , Ellington AG , Evans KL , Fey JM , Fleming K , French L , Garner AA , Gilbert JGR , Goward ME , Grafham DV , Griffiths MND , Hall C , Hall RE , Hall-Tamlyn G , Heathcott RW , Ho S , Holmes S , Hunt SE , Jones MC , Kershaw J , Kimberley AM , King A , Laird GK , Langford CF , Leversha MA , Lloyd C , Lloyd DM , Martyn ID , Mashreghi-Mohammadi M , Matthews LH , Mccann OT , Mcclay J , Mclaren S , McMurray AA , Milne SA , Mortimore BJ , Odell CN , Pavitt R , Pearce AV , Pearson D , Phillimore BJCT , Phillips SH , Plumb RW , Ramsay H , Ramsey Y , Rogers L , Ross MT , Scott CE , Sehra HK , Skuce CD , Smalley S , Smith ML , Soderlund C , Spragon L , Steward CA , Sulston JE , Swann RM , Vaudin M , Wall M , Wallis JM , Whiteley MN , Willey DL , Williams L , Williams SA , Williamson H , Wilmer TE , Wilming L , Wright CL , Hubbard T , Bentley DR , Beck S , Rogers J , Shimizu N , Minoshima S , Kawasaki K , Sasaki T , Asakawa S , Kudoh J , Shintani A , Shibuya K , Yoshizaki Y , Aoki N , Mitsuyama S , Roe BA , Chen F , Chu L , Crabtree J , Deschamps S , Do A , Do T , Dorman A , Fang F , Fu Y , Hu P , Hua A , Kenton S , Lai H , Lao HI , Lewis J , Lewis S , Lin S-P , Loh P , Malaj E , Nguyen T , Pan H , Phan S , Qi S , Qian Y , Ray L , Ren Q , Shaull S , Sloan D , Song L , Wang Q , Wang Y , Wang Z , White J , Willingham D , Wu H , Yao Z , Zhan M , Zhang G , Chissoe S , Murray J , Miller N , Minx P , Fulton R , Johnson D , Bemis G , Bentley D , Bradshaw H , Bourne S , Cordes M , Du Z , Fulton L , Goela D , Graves T , Hawkins J , Hinds K , Kemp K , Latreille P , Layman D , Ozersky P , Rohlfing T , Scheet P , Walker C , Wamsley A , Wohldmann P , Pepin K , Nelson J , Korf I , Bedell JA , Hillier L , Mardis E , Waterston R , Wilson R , Emanuel BS , Shaikh T , Kurahashi H , Saitta S , Budarf ML , McDermid HE , Johnson A , Wong ACC , Morrow BE , Edelmann L , Kim UJ , Shizuya H , Simon MI , Dumanski JP , Peyrard M , Kedra D , Seroussi E , Fransson I , Tapia I , Bruder CE , O'Brien KP
Ref : Nature , 402 :489 , 1999
Abstract : Knowledge of the complete genomic DNA sequence of an organism allows a systematic approach to defining its genetic components. The genomic sequence provides access to the complete structures of all genes, including those without known function, their control elements, and, by inference, the proteins they encode, as well as all other biologically important sequences. Furthermore, the sequence is a rich and permanent source of information for the design of further biological studies of the organism and for the study of evolution through cross-species sequence comparison. The power of this approach has been amply demonstrated by the determination of the sequences of a number of microbial and model organisms. The next step is to obtain the complete sequence of the entire human genome. Here we report the sequence of the euchromatic part of human chromosome 22. The sequence obtained consists of 12 contiguous segments spanning 33.4 megabases, contains at least 545 genes and 134 pseudogenes, and provides the first view of the complex chromosomal landscapes that will be found in the rest of the genome.
ESTHER : Dunham_1999_Nature_402_489
PubMedSearch : Dunham_1999_Nature_402_489
PubMedID: 10591208
Gene_locus related to this paper: human-CES5A , human-SERHL2