Madan Babu M

References (2)

Title : The genome of the social amoeba Dictyostelium discoideum - Eichinger_2005_Nature_435_43
Author(s) : Eichinger L , Pachebat JA , Glockner G , Rajandream MA , Sucgang R , Berriman M , Song J , Olsen R , Szafranski K , Xu Q , Tunggal B , Kummerfeld S , Madera M , Konfortov BA , Rivero F , Bankier AT , Lehmann R , Hamlin N , Davies R , Gaudet P , Fey P , Pilcher K , Chen G , Saunders D , Sodergren E , Davis P , Kerhornou A , Nie X , Hall N , Anjard C , Hemphill L , Bason N , Farbrother P , Desany B , Just E , Morio T , Rost R , Churcher C , Cooper J , Haydock S , van Driessche N , Cronin A , Goodhead I , Muzny D , Mourier T , Pain A , Lu M , Harper D , Lindsay R , Hauser H , James K , Quiles M , Madan Babu M , Saito T , Buchrieser C , Wardroper A , Felder M , Thangavelu M , Johnson D , Knights A , Loulseged H , Mungall K , Oliver K , Price C , Quail MA , Urushihara H , Hernandez J , Rabbinowitsch E , Steffen D , Sanders M , Ma J , Kohara Y , Sharp S , Simmonds M , Spiegler S , Tivey A , Sugano S , White B , Walker D , Woodward J , Winckler T , Tanaka Y , Shaulsky G , Schleicher M , Weinstock G , Rosenthal A , Cox EC , Chisholm RL , Gibbs R , Loomis WF , Platzer M , Kay RR , Williams J , Dear PH , Noegel AA , Barrell B , Kuspa A
Ref : Nature , 435 :43 , 2005
Abstract : The social amoebae are exceptional in their ability to alternate between unicellular and multicellular forms. Here we describe the genome of the best-studied member of this group, Dictyostelium discoideum. The gene-dense chromosomes of this organism encode approximately 12,500 predicted proteins, a high proportion of which have long, repetitive amino acid tracts. There are many genes for polyketide synthases and ABC transporters, suggesting an extensive secondary metabolism for producing and exporting small molecules. The genome is rich in complex repeats, one class of which is clustered and may serve as centromeres. Partial copies of the extrachromosomal ribosomal DNA (rDNA) element are found at the ends of each chromosome, suggesting a novel telomere structure and the use of a common mechanism to maintain both the rDNA and chromosomal termini. A proteome-based phylogeny shows that the amoebozoa diverged from the animal-fungal lineage after the plant-animal split, but Dictyostelium seems to have retained more of the diversity of the ancestral genome than have plants, animals or fungi.
ESTHER : Eichinger_2005_Nature_435_43
PubMedSearch : Eichinger_2005_Nature_435_43
PubMedID: 15875012
Gene_locus related to this paper: dicdi-abhd , dicdi-ACHE , dicdi-apra , dicdi-cinbp , dicdi-CMBL , dicdi-crysp , dicdi-DPOA , dicdi-P90528 , dicdi-ppme1 , dicdi-Q8MYE7 , dicdi-q54cf7 , dicdi-q54cl7 , dicdi-q54cm0 , dicdi-q54ct5 , dicdi-q54cu1 , dicdi-q54d54 , dicdi-q54d66 , dicdi-q54dj5 , dicdi-q54dy7 , dicdi-q54ek1 , dicdi-q54eq6 , dicdi-q54et1 , dicdi-q54et7 , dicdi-q54f01 , dicdi-q54g24 , dicdi-q54g47 , dicdi-q54gi7 , dicdi-q54gw5 , dicdi-q54gx3 , dicdi-q54h23 , dicdi-q54h73 , dicdi-q54i38 , dicdi-q54ie5 , dicdi-q54in4 , dicdi-q54kz1 , dicdi-q54l36 , dicdi-q54li1 , dicdi-q54m29 , dicdi-q54n21 , dicdi-q54n35 , dicdi-q54n85 , dicdi-q54qe7 , dicdi-q54qi3 , dicdi-q54qk2 , dicdi-q54rl3 , dicdi-q54rl8 , dicdi-q54sy6 , dicdi-q54sz3 , dicdi-q54t49 , dicdi-q54t91 , dicdi-q54th2 , dicdi-q54u01 , dicdi-q54vc2 , dicdi-q54vw1 , dicdi-q54xe3 , dicdi-q54xl3 , dicdi-q54xu1 , dicdi-q54xu2 , dicdi-q54y48 , dicdi-q54yd0 , dicdi-q54ye0 , dicdi-q54yl1 , dicdi-q54yr8 , dicdi-q54z90 , dicdi-q55bx3 , dicdi-q55d01 , dicdi-q55d81 , dicdi-q55du6 , dicdi-q55eu1 , dicdi-q55eu8 , dicdi-q55fk4 , dicdi-q55gk7 , dicdi-Q54ZA6 , dicdi-q86h82 , dicdi-Q86HC9 , dicdi-Q86HM5 , dicdi-Q86HM6 , dicdi-q86iz7 , dicdi-q86jb6 , dicdi-Q86KU7 , dicdi-q550s3 , dicdi-q552c0 , dicdi-q553t5 , dicdi-q555e5 , dicdi-q555h0 , dicdi-q555h1 , dicdi-q557k5 , dicdi-q558u2 , dicdi-Q869Q8 , dicdi-u554 , dicdi-y9086 , dicdi-q54r44 , dicdi-f172a

Title : The transcriptional landscape of the mammalian genome - Carninci_2005_Science_309_1559
Author(s) : Carninci P , Kasukawa T , Katayama S , Gough J , Frith MC , Maeda N , Oyama R , Ravasi T , Lenhard B , Wells C , Kodzius R , Shimokawa K , Bajic VB , Brenner SE , Batalov S , Forrest AR , Zavolan M , Davis MJ , Wilming LG , Aidinis V , Allen JE , Ambesi-Impiombato A , Apweiler R , Aturaliya RN , Bailey TL , Bansal M , Baxter L , Beisel KW , Bersano T , Bono H , Chalk AM , Chiu KP , Choudhary V , Christoffels A , Clutterbuck DR , Crowe ML , Dalla E , Dalrymple BP , de Bono B , Della Gatta G , di Bernardo D , Down T , Engstrom P , Fagiolini M , Faulkner G , Fletcher CF , Fukushima T , Furuno M , Futaki S , Gariboldi M , Georgii-Hemming P , Gingeras TR , Gojobori T , Green RE , Gustincich S , Harbers M , Hayashi Y , Hensch TK , Hirokawa N , Hill D , Huminiecki L , Iacono M , Ikeo K , Iwama A , Ishikawa T , Jakt M , Kanapin A , Katoh M , Kawasawa Y , Kelso J , Kitamura H , Kitano H , Kollias G , Krishnan SP , Kruger A , Kummerfeld SK , Kurochkin IV , Lareau LF , Lazarevic D , Lipovich L , Liu J , Liuni S , McWilliam S , Madan Babu M , Madera M , Marchionni L , Matsuda H , Matsuzawa S , Miki H , Mignone F , Miyake S , Morris K , Mottagui-Tabar S , Mulder N , Nakano N , Nakauchi H , Ng P , Nilsson R , Nishiguchi S , Nishikawa S , Nori F , Ohara O , Okazaki Y , Orlando V , Pang KC , Pavan WJ , Pavesi G , Pesole G , Petrovsky N , Piazza S , Reed J , Reid JF , Ring BZ , Ringwald M , Rost B , Ruan Y , Salzberg SL , Sandelin A , Schneider C , Schonbach C , Sekiguchi K , Semple CA , Seno S , Sessa L , Sheng Y , Shibata Y , Shimada H , Shimada K , Silva D , Sinclair B , Sperling S , Stupka E , Sugiura K , Sultana R , Takenaka Y , Taki K , Tammoja K , Tan SL , Tang S , Taylor MS , Tegner J , Teichmann SA , Ueda HR , van Nimwegen E , Verardo R , Wei CL , Yagi K , Yamanishi H , Zabarovsky E , Zhu S , Zimmer A , Hide W , Bult C , Grimmond SM , Teasdale RD , Liu ET , Brusic V , Quackenbush J , Wahlestedt C , Mattick JS , Hume DA , Kai C , Sasaki D , Tomaru Y , Fukuda S , Kanamori-Katayama M , Suzuki M , Aoki J , Arakawa T , Iida J , Imamura K , Itoh M , Kato T , Kawaji H , Kawagashira N , Kawashima T , Kojima M , Kondo S , Konno H , Nakano K , Ninomiya N , Nishio T , Okada M , Plessy C , Shibata K , Shiraki T , Suzuki S , Tagami M , Waki K , Watahiki A , Okamura-Oho Y , Suzuki H , Kawai J , Hayashizaki Y
Ref : Science , 309 :1559 , 2005
Abstract : This study describes comprehensive polling of transcription start and termination sites and analysis of previously unidentified full-length complementary DNAs derived from the mouse genome. We identify the 5' and 3' boundaries of 181,047 transcripts with extensive variation in transcripts arising from alternative promoter usage, splicing, and polyadenylation. There are 16,247 new mouse protein-coding transcripts, including 5154 encoding previously unidentified proteins. Genomic mapping of the transcriptome reveals transcriptional forests, with overlapping transcription on both strands, separated by deserts in which few transcripts are observed. The data provide a comprehensive platform for the comparative analysis of mammalian transcriptional regulation in differentiation and development.
ESTHER : Carninci_2005_Science_309_1559
PubMedSearch : Carninci_2005_Science_309_1559
PubMedID: 16141072
Gene_locus related to this paper: mouse-abhd1 , mouse-abhd3 , mouse-abhd4 , mouse-acot4 , mouse-adcl4 , mouse-DGLB , mouse-ephx3 , mouse-Kansl3 , mouse-lipli , mouse-LIPN , mouse-Ppgb , mouse-q3uuq7 , mouse-srac1 , mouse-Tex30 , mouse-tmco4 , mouse-tmm53 , mouse-f172a