Green PJ

References (5)

Title : The genome of the seagrass Zostera marina reveals angiosperm adaptation to the sea - Olsen_2016_Nature_530_331
Author(s) : Olsen JL , Rouze P , Verhelst B , Lin YC , Bayer T , Collen J , Dattolo E , De Paoli E , Dittami S , Maumus F , Michel G , Kersting A , Lauritano C , Lohaus R , Topel M , Tonon T , Vanneste K , Amirebrahimi M , Brakel J , Bostrom C , Chovatia M , Grimwood J , Jenkins JW , Jueterbock A , Mraz A , Stam WT , Tice H , Bornberg-Bauer E , Green PJ , Pearson GA , Procaccini G , Duarte CM , Schmutz J , Reusch TB , Van de Peer Y
Ref : Nature , 530 :331 , 2016
Abstract : Seagrasses colonized the sea on at least three independent occasions to form the basis of one of the most productive and widespread coastal ecosystems on the planet. Here we report the genome of Zostera marina (L.), the first, to our knowledge, marine angiosperm to be fully sequenced. This reveals unique insights into the genomic losses and gains involved in achieving the structural and physiological adaptations required for its marine lifestyle, arguably the most severe habitat shift ever accomplished by flowering plants. Key angiosperm innovations that were lost include the entire repertoire of stomatal genes, genes involved in the synthesis of terpenoids and ethylene signalling, and genes for ultraviolet protection and phytochromes for far-red sensing. Seagrasses have also regained functions enabling them to adjust to full salinity. Their cell walls contain all of the polysaccharides typical of land plants, but also contain polyanionic, low-methylated pectins and sulfated galactans, a feature shared with the cell walls of all macroalgae and that is important for ion homoeostasis, nutrient uptake and O2/CO2 exchange through leaf epidermal cells. The Z. marina genome resource will markedly advance a wide range of functional ecological studies from adaptation of marine ecosystems under climate warming, to unravelling the mechanisms of osmoregulation under high salinities that may further inform our understanding of the evolution of salt tolerance in crop plants.
ESTHER : Olsen_2016_Nature_530_331
PubMedSearch : Olsen_2016_Nature_530_331
PubMedID: 26814964
Gene_locus related to this paper: zosmr-a0a0k9p2z2 , zosmr-a0a0k9q3d3 , zosmr-a0a0k9nzq4 , zosmr-a0a0k9pcd8 , zosmr-a0a0k9p120 , zosmr-a0a0k9npe9

Title : The Medicago genome provides insight into the evolution of rhizobial symbioses - Young_2011_Nature_480_520
Author(s) : Young ND , Debelle F , Oldroyd GE , Geurts R , Cannon SB , Udvardi MK , Benedito VA , Mayer KF , Gouzy J , Schoof H , Van de Peer Y , Proost S , Cook DR , Meyers BC , Spannagl M , Cheung F , De Mita S , Krishnakumar V , Gundlach H , Zhou S , Mudge J , Bharti AK , Murray JD , Naoumkina MA , Rosen B , Silverstein KA , Tang H , Rombauts S , Zhao PX , Zhou P , Barbe V , Bardou P , Bechner M , Bellec A , Berger A , Berges H , Bidwell S , Bisseling T , Choisne N , Couloux A , Denny R , Deshpande S , Dai X , Doyle JJ , Dudez AM , Farmer AD , Fouteau S , Franken C , Gibelin C , Gish J , Goldstein S , Gonzalez AJ , Green PJ , Hallab A , Hartog M , Hua A , Humphray SJ , Jeong DH , Jing Y , Jocker A , Kenton SM , Kim DJ , Klee K , Lai H , Lang C , Lin S , Macmil SL , Magdelenat G , Matthews L , McCorrison J , Monaghan EL , Mun JH , Najar FZ , Nicholson C , Noirot C , O'Bleness M , Paule CR , Poulain J , Prion F , Qin B , Qu C , Retzel EF , Riddle C , Sallet E , Samain S , Samson N , Sanders I , Saurat O , Scarpelli C , Schiex T , Segurens B , Severin AJ , Sherrier DJ , Shi R , Sims S , Singer SR , Sinharoy S , Sterck L , Viollet A , Wang BB , Wang K , Wang M , Wang X , Warfsmann J , Weissenbach J , White DD , White JD , Wiley GB , Wincker P , Xing Y , Yang L , Yao Z , Ying F , Zhai J , Zhou L , Zuber A , Denarie J , Dixon RA , May GD , Schwartz DC , Rogers J , Quetier F , Town CD , Roe BA
Ref : Nature , 480 :520 , 2011
Abstract : Legumes (Fabaceae or Leguminosae) are unique among cultivated plants for their ability to carry out endosymbiotic nitrogen fixation with rhizobial bacteria, a process that takes place in a specialized structure known as the nodule. Legumes belong to one of the two main groups of eurosids, the Fabidae, which includes most species capable of endosymbiotic nitrogen fixation. Legumes comprise several evolutionary lineages derived from a common ancestor 60 million years ago (Myr ago). Papilionoids are the largest clade, dating nearly to the origin of legumes and containing most cultivated species. Medicago truncatula is a long-established model for the study of legume biology. Here we describe the draft sequence of the M. truncatula euchromatin based on a recently completed BAC assembly supplemented with Illumina shotgun sequence, together capturing approximately 94% of all M. truncatula genes. A whole-genome duplication (WGD) approximately 58 Myr ago had a major role in shaping the M. truncatula genome and thereby contributed to the evolution of endosymbiotic nitrogen fixation. Subsequent to the WGD, the M. truncatula genome experienced higher levels of rearrangement than two other sequenced legumes, Glycine max and Lotus japonicus. M. truncatula is a close relative of alfalfa (Medicago sativa), a widely cultivated crop with limited genomics tools and complex autotetraploid genetics. As such, the M. truncatula genome sequence provides significant opportunities to expand alfalfa's genomic toolbox.
ESTHER : Young_2011_Nature_480_520
PubMedSearch : Young_2011_Nature_480_520
PubMedID: 22089132
Gene_locus related to this paper: medtr-b7fki4 , medtr-b7fmi1 , medtr-g7itl1 , medtr-g7iu67 , medtr-g7izm0 , medtr-g7j641 , medtr-g7jtf8 , medtr-g7jtg2 , medtr-g7jtg4 , medtr-g7kem3 , medtr-g7kml3 , medtr-g7ksx5 , medtr-g7leb3 , medtr-q1s5d8 , medtr-q1s9m3 , medtr-q1t171 , medtr-g7k9e1 , medtr-g7k9e3 , medtr-g7k9e5 , medtr-g7k9e8 , medtr-g7k9e9 , medtr-g7lbp2 , medtr-g7lch3 , medtr-g7ib94 , medtr-g7ljk8 , medtr-g7i6w5 , medtr-g7kvg4 , medtr-g7iam1 , medtr-g7iam3 , medtr-g7l754 , medtr-g7jr41 , medtr-g7l4f5 , medtr-g7l755 , medtr-a0a072vyl4 , medtr-g7jwk8 , medtr-a0a072vhg0 , medtr-a0a072vrv9 , medtr-g7kmk5 , medtr-a0a072uuf6 , medtr-a0a072urp3 , medtr-g7zzc3 , medtr-g7ie19 , medtr-g7kst7 , medtr-a0a072u5k5 , medtr-a0a072v056 , medtr-scp1 , medtr-g7kyn0 , medtr-g7inw6 , medtr-g7j3q3

Title : Genome sequencing and analysis of the model grass Brachypodium distachyon. -
Author(s) : Vogel JP , Garvin DF , Mockler TC , Schmutz J , Rokhsar D , Bevan MW , Barry K , Lucas S , Harmon-Smith M , Lail K , Tice H , Grimwood J , McKenzie N , Huo N , Gu YQ , Lazo GR , Anderson OD , You FM , Luo MC , Dvorak J , Wright J , Febrer M , Idziak D , Hasterok R , Lindquist E , Wang M , Fox SE , Priest HD , Filichkin SA , Givan SA , Bryant DW , Chang JH , Wu H , Wu W , Hsia AP , Schnable PS , Kalyanaraman A , Barbazuk B , Michael TP , Hazen SP , Bragg JN , Laudencia-Chingcuanco D , Weng Y , Haberer G , Spannagl M , Mayer K , Rattei T , Mitros T , Lee SJ , Rose JK , Mueller LA , York TL , Wicker T , Buchmann JP , Tanskanen J , Schulman AH , Gundlach H , Bevan M , de Oliveira AC , Maia Lda C , Belknap W , Jiang N , Lai J , Zhu L , Ma J , Sun C , Pritham E , Salse J , Murat F , Abrouk M , Bruggmann R , Messing J , Fahlgren N , Sullivan CM , Carrington JC , Chapman EJ , May GD , Zhai J , Ganssmann M , Gurazada SG , German M , Meyers BC , Green PJ , Tyler L , Wu J , Thomson J , Chen S , Scheller HV , Harholt J , Ulvskov P , Kimbrel JA , Bartley LE , Cao P , Jung KH , Sharma MK , Vega-Sanchez M , Ronald P , Dardick CD , De Bodt S , Verelst W , Inz D , Heese M , Schnittger A , Yang X , Kalluri UC , Tuskan GA , Hua Z , Vierstra RD , Cui Y , Ouyang S , Sun Q , Liu Z , Yilmaz A , Grotewold E , Sibout R , Hematy K , Mouille G , Hofte H , Michael T , Pelloux J , O'Connor D , Schnable J , Rowe S , Harmon F , Cass CL , Sedbrook JC , Byrne ME , Walsh S , Higgins J , Li P , Brutnell T , Unver T , Budak H , Belcram H , Charles M , Chalhoub B , Baxter I
Ref : Nature , 463 :763 , 2010
PubMedID: 20148030
Gene_locus related to this paper: bradi-i1grm0 , bradi-i1gx82 , bradi-i1hb80 , bradi-i1hkv6 , bradi-i1hpu6 , bradi-i1i3e4 , bradi-i1i9i0 , bradi-i1i435 , bradi-i1ix93 , bradi-i1gsk6 , bradi-i1hk44 , bradi-i1hk45 , bradi-i1hnk7 , bradi-i1hsd5 , bradi-i1huy4 , bradi-i1huy9 , bradi-i1huz0 , bradi-i1gxx9 , bradi-i1hl25 , bradi-i1hcw7 , bradi-i1hyv6 , bradi-i1hyb5 , bradi-i1hvr8 , bradi-i1hmu2 , bradi-i1hf05 , bradi-i1gry7 , bradi-i1hf06 , bradi-i1i5z8 , bradi-i1icy3 , bradi-i1j1h3 , bradi-i1h1e3 , bradi-i1hvr9 , bradi-a0a0q3r7i7 , bradi-i1i377 , bradi-i1hjg5 , bradi-i1h3i9 , bradi-i1gsg5 , bradi-a0a0q3mph9 , bradi-i1h682 , bradi-a0a0q3lc91 , bradi-i1gx49 , bradi-i1i839 , bradi-a0a2k2dsp5 , bradi-i1gsb5

Title : Genome sequence and analysis of the Irish potato famine pathogen Phytophthora infestans - Haas_2009_Nature_461_393
Author(s) : Haas BJ , Kamoun S , Zody MC , Jiang RH , Handsaker RE , Cano LM , Grabherr M , Kodira CD , Raffaele S , Torto-Alalibo T , Bozkurt TO , Ah-Fong AM , Alvarado L , Anderson VL , Armstrong MR , Avrova A , Baxter L , Beynon J , Boevink PC , Bollmann SR , Bos JI , Bulone V , Cai G , Cakir C , Carrington JC , Chawner M , Conti L , Costanzo S , Ewan R , Fahlgren N , Fischbach MA , Fugelstad J , Gilroy EM , Gnerre S , Green PJ , Grenville-Briggs LJ , Griffith J , Grunwald NJ , Horn K , Horner NR , Hu CH , Huitema E , Jeong DH , Jones AM , Jones JD , Jones RW , Karlsson EK , Kunjeti SG , Lamour K , Liu Z , Ma L , Maclean D , Chibucos MC , McDonald H , McWalters J , Meijer HJ , Morgan W , Morris PF , Munro CA , O'Neill K , Ospina-Giraldo M , Pinzon A , Pritchard L , Ramsahoye B , Ren Q , Restrepo S , Roy S , Sadanandom A , Savidor A , Schornack S , Schwartz DC , Schumann UD , Schwessinger B , Seyer L , Sharpe T , Silvar C , Song J , Studholme DJ , Sykes S , Thines M , van de Vondervoort PJ , Phuntumart V , Wawra S , Weide R , Win J , Young C , Zhou S , Fry W , Meyers BC , van West P , Ristaino J , Govers F , Birch PR , Whisson SC , Judelson HS , Nusbaum C
Ref : Nature , 461 :393 , 2009
Abstract : Phytophthora infestans is the most destructive pathogen of potato and a model organism for the oomycetes, a distinct lineage of fungus-like eukaryotes that are related to organisms such as brown algae and diatoms. As the agent of the Irish potato famine in the mid-nineteenth century, P. infestans has had a tremendous effect on human history, resulting in famine and population displacement. To this day, it affects world agriculture by causing the most destructive disease of potato, the fourth largest food crop and a critical alternative to the major cereal crops for feeding the world's population. Current annual worldwide potato crop losses due to late blight are conservatively estimated at $$6.7 billion. Management of this devastating pathogen is challenged by its remarkable speed of adaptation to control strategies such as genetically resistant cultivars. Here we report the sequence of the P. infestans genome, which at approximately 240 megabases (Mb) is by far the largest and most complex genome sequenced so far in the chromalveolates. Its expansion results from a proliferation of repetitive DNA accounting for approximately 74% of the genome. Comparison with two other Phytophthora genomes showed rapid turnover and extensive expansion of specific families of secreted disease effector proteins, including many genes that are induced during infection or are predicted to have activities that alter host physiology. These fast-evolving effector genes are localized to highly dynamic and expanded regions of the P. infestans genome. This probably plays a crucial part in the rapid adaptability of the pathogen to host plants and underpins its evolutionary potential.
ESTHER : Haas_2009_Nature_461_393
PubMedSearch : Haas_2009_Nature_461_393
PubMedID: 19741609
Gene_locus related to this paper: phyin-ENDO2 , phyin-q2m440 , phyin-q58g92 , phyit-d0mqp1 , phyit-d0mqp2 , phyit-d0mt75 , phyit-d0muv1 , phyit-d0mv34 , phyit-d0mv35 , phyit-d0mwf9 , phyit-d0mxu5 , phyit-d0n935 , phyit-d0nax9 , phyit-d0nfs3 , phyit-d0nhj2 , phyit-d0nhj4 , phyit-d0nhj8 , phyit-d0ni28 , phyit-d0nj14 , phyit-d0nj53 , phyit-d0nj54 , phyit-d0njf2 , phyit-d0nkm4 , phyit-d0nr53 , phyit-d0nrb1 , phyit-d0nrk9 , phyit-d0nrl4 , phyit-d0ns26 , phyit-d0ns42 , phyit-d0ns43 , phyit-d0nsr8 , phyit-d0nu41 , phyit-d0nvt3 , phyit-d0nwb6 , phyit-d0nwm8 , phyit-d0nzc0 , phyit-d0nzc1 , phyit-d0p0z1 , phyit-d0p3z2 , phyit-kex1 , phyit-d0n6q6 , phyit-d0n4i8 , phyit-d0mqf7 , phyit-d0n5g6

Title : The Rice Annotation Project Database (RAP-DB): 2008 update - Tanaka_2008_Nucleic.Acids.Res_36_D1028
Author(s) : Tanaka T , Antonio BA , Kikuchi S , Matsumoto T , Nagamura Y , Numa H , Sakai H , Wu J , Itoh T , Sasaki T , Aono R , Fujii Y , Habara T , Harada E , Kanno M , Kawahara Y , Kawashima H , Kubooka H , Matsuya A , Nakaoka H , Saichi N , Sanbonmatsu R , Sato Y , Shinso Y , Suzuki M , Takeda J , Tanino M , Todokoro F , Yamaguchi K , Yamamoto N , Yamasaki C , Imanishi T , Okido T , Tada M , Ikeo K , Tateno Y , Gojobori T , Lin YC , Wei FJ , Hsing YI , Zhao Q , Han B , Kramer MR , McCombie RW , Lonsdale D , O'Donovan CC , Whitfield EJ , Apweiler R , Koyanagi KO , Khurana JP , Raghuvanshi S , Singh NK , Tyagi AK , Haberer G , Fujisawa M , Hosokawa S , Ito Y , Ikawa H , Shibata M , Yamamoto M , Bruskiewich RM , Hoen DR , Bureau TE , Namiki N , Ohyanagi H , Sakai Y , Nobushima S , Sakata K , Barrero RA , Souvorov A , Smith-White B , Tatusova T , An S , An G , S OO , Fuks G , Messing J , Christie KR , Lieberherr D , Kim H , Zuccolo A , Wing RA , Nobuta K , Green PJ , Lu C , Meyers BC , Chaparro C , Piegu B , Panaud O , Echeverria M
Ref : Nucleic Acids Research , 36 :D1028 , 2008
Abstract : The Rice Annotation Project Database (RAP-DB) was created to provide the genome sequence assembly of the International Rice Genome Sequencing Project (IRGSP), manually curated annotation of the sequence, and other genomics information that could be useful for comprehensive understanding of the rice biology. Since the last publication of the RAP-DB, the IRGSP genome has been revised and reassembled. In addition, a large number of rice-expressed sequence tags have been released, and functional genomics resources have been produced worldwide. Thus, we have thoroughly updated our genome annotation by manual curation of all the functional descriptions of rice genes. The latest version of the RAP-DB contains a variety of annotation data as follows: clone positions, structures and functions of 31 439 genes validated by cDNAs, RNA genes detected by massively parallel signature sequencing (MPSS) technology and sequence similarity, flanking sequences of mutant lines, transposable elements, etc. Other annotation data such as Gnomon can be displayed along with those of RAP for comparison. We have also developed a new keyword search system to allow the user to access useful information. The RAP-DB is available at: http://rapdb.dna.affrc.go.jp/ and http://rapdb.lab.nig.ac.jp/.
ESTHER : Tanaka_2008_Nucleic.Acids.Res_36_D1028
PubMedSearch : Tanaka_2008_Nucleic.Acids.Res_36_D1028
PubMedID: 18089549
Gene_locus related to this paper: orysa-Q9FW17 , orysa-Q0JK71 , orysa-B9EWJ8 , orysa-Q5N7L1 , orysa-pir7a , orysa-q2qyj1 , orysj-q6yse8 , orysa-q6yzk1 , orysa-Q8S0U8 , orysa-q33aq0 , orysa-Q0J0A4 , orysi-a2z179 , orysi-a2zef2 , orysi-b8a7e6 , orysi-b8a7e7 , orysi-b8bfe5 , orysi-b8bhp9 , orysj-b9fi05 , orysj-b9fkb0 , orysj-cgep , orysj-q0djj0 , orysj-q0dud7 , orysj-q0jaf0 , orysj-q0jga1 , 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 , orysj-pla4 , orysj-pla1