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References (4)

Title : The genome of the hydatid tapeworm Echinococcus granulosus - Zheng_2013_Nat.Genet_45_1168
Author(s) : Zheng H , Zhang W , Zhang L , Zhang Z , Li J , Lu G , Zhu Y , Wang Y , Huang Y , Liu J , Kang H , Chen J , Wang L , Chen A , Yu S , Gao Z , Jin L , Gu W , Wang Z , Zhao L , Shi B , Wen H , Lin R , Jones MK , Brejova B , Vinar T , Zhao G , McManus DP , Chen Z , Zhou Y , Wang S
Ref : Nat Genet , 45 :1168 , 2013
Abstract : Cystic echinococcosis (hydatid disease), caused by the tapeworm E. granulosus, is responsible for considerable human morbidity and mortality. This cosmopolitan disease is difficult to diagnose, treat and control. We present a draft genomic sequence for the worm comprising 151.6 Mb encoding 11,325 genes. Comparisons with the genome sequences from other taxa show that E. granulosus has acquired a spectrum of genes, including the EgAgB family, whose products are secreted by the parasite to interact and redirect host immune responses. We also find that genes in bile salt pathways may control the bidirectional development of E. granulosus, and sequence differences in the calcium channel subunit EgCavbeta1 may be associated with praziquantel sensitivity. Our study offers insights into host interaction, nutrient acquisition, strobilization, reproduction, immune evasion and maturation in the parasite and provides a platform to facilitate the development of new, effective treatments and interventions for echinococcosis control.
ESTHER : Zheng_2013_Nat.Genet_45_1168
PubMedSearch : Zheng_2013_Nat.Genet_45_1168
PubMedID: 24013640
Gene_locus related to this paper: echgr-k4epc5 , echmu-u6hbw4 , echgr-w6ugl0 , echgr-w6u7y4 , echgr-w6vaq5 , echgr-a0a068wxj3 , echgr-a0a068wgw1 , echgr-a0a068wl60

Title : Sequencing the genome of Marssonina brunnea reveals fungus-poplar co-evolution - Zhu_2012_BMC.Genomics_13_382
Author(s) : Zhu S , Cao YZ , Jiang C , Tan BY , Wang Z , Feng S , Zhang L , Su XH , Brejova B , Vinar T , Xu M , Wang MX , Zhang SG , Huang MR , Wu R , Zhou Y
Ref : BMC Genomics , 13 :382 , 2012
Abstract : BACKGROUND: The fungus Marssonina brunnea is a causal pathogen of Marssonina leaf spot that devastates poplar plantations by defoliating susceptible trees before normal fall leaf drop.
RESULTS: We sequence the genome of M. brunnea with a size of 52 Mb assembled into 89 scaffolds, representing the first sequenced Dermateaceae genome. By inoculating this fungus onto a poplar hybrid clone, we investigate how M. brunnea interacts and co-evolves with its host to colonize poplar leaves. While a handful of virulence genes in M. brunnea, mostly from the LysM family, are detected to up-regulate during infection, the poplar down-regulates its resistance genes, such as nucleotide binding site domains and leucine rich repeats, in response to infection. From 10,027 predicted proteins of M. brunnea in a comparison with those from poplar, we identify four poplar transferases that stimulate the host to resist M. brunnea. These transferas-encoding genes may have driven the co-evolution of M. brunnea and Populus during the process of infection and anti-infection.
CONCLUSIONS: Our results from the draft sequence of the M. brunnea genome provide evidence for genome-genome interactions that play an important role in poplar-pathogen co-evolution. This knowledge could help to design effective strategies for controlling Marssonina leaf spot in poplar.
ESTHER : Zhu_2012_BMC.Genomics_13_382
PubMedSearch : Zhu_2012_BMC.Genomics_13_382
PubMedID: 22876864
Gene_locus related to this paper: marbu-k1wj37 , marbu-k1xt94 , marbu-k1wdc0 , marbu-k1wht2 , marbu-k1wj82 , marbu-k1wkk6 , marbu-k1wnk8 , marbu-k1wpc4 , marbu-k1wrg1 , marbu-k1wsf4 , marbu-k1wtx1 , marbu-k1x087 , marbu-k1x383 , marbu-k1x3g3 , marbu-k1x464 , marbu-k1x8c9 , marbu-k1xi08 , marbu-k1xzh8 , marbu-k1y283 , marbu-k1x918 , marbu-k1wzc0 , marbu-k1xu92 , marbu-k1xws5 , marbu-k1wxv8

Title : The sequence and de novo assembly of the giant panda genome - Li_2010_Nature_463_311
Author(s) : Li R , Fan W , Tian G , Zhu H , He L , Cai J , Huang Q , Cai Q , Li B , Bai Y , Zhang Z , Zhang Y , Wang W , Li J , Wei F , Li H , Jian M , Nielsen R , Li D , Gu W , Yang Z , Xuan Z , Ryder OA , Leung FC , Zhou Y , Cao J , Sun X , Fu Y , Fang X , Guo X , Wang B , Hou R , Shen F , Mu B , Ni P , Lin R , Qian W , Wang G , Yu C , Nie W , Wang J , Wu Z , Liang H , Min J , Wu Q , Cheng S , Ruan J , Wang M , Shi Z , Wen M , Liu B , Ren X , Zheng H , Dong D , Cook K , Shan G , Zhang H , Kosiol C , Xie X , Lu Z , Li Y , Steiner CC , Lam TT , Lin S , Zhang Q , Li G , Tian J , Gong T , Liu H , Zhang D , Fang L , Ye C , Zhang J , Hu W , Xu A , Ren Y , Zhang G , Bruford MW , Li Q , Ma L , Guo Y , An N , Hu Y , Zheng Y , Shi Y , Li Z , Liu Q , Chen Y , Zhao J , Qu N , Zhao S , Tian F , Wang X , Wang H , Xu L , Liu X , Vinar T , Wang Y , Lam TW , Yiu SM , Liu S , Huang Y , Yang G , Jiang Z , Qin N , Li L , Bolund L , Kristiansen K , Wong GK , Olson M , Zhang X , Li S , Yang H
Ref : Nature , 463 :311 , 2010
Abstract : Using next-generation sequencing technology alone, we have successfully generated and assembled a draft sequence of the giant panda genome. The assembled contigs (2.25 gigabases (Gb)) cover approximately 94% of the whole genome, and the remaining gaps (0.05 Gb) seem to contain carnivore-specific repeats and tandem repeats. Comparisons with the dog and human showed that the panda genome has a lower divergence rate. The assessment of panda genes potentially underlying some of its unique traits indicated that its bamboo diet might be more dependent on its gut microbiome than its own genetic composition. We also identified more than 2.7 million heterozygous single nucleotide polymorphisms in the diploid genome. Our data and analyses provide a foundation for promoting mammalian genetic research, and demonstrate the feasibility for using next-generation sequencing technologies for accurate, cost-effective and rapid de novo assembly of large eukaryotic genomes.
ESTHER : Li_2010_Nature_463_311
PubMedSearch : Li_2010_Nature_463_311
PubMedID: 20010809
Gene_locus related to this paper: ailme-ABH15 , ailme-ACHE , ailme-BCHE , ailme-d2gtv3 , ailme-d2gty9 , ailme-d2gu87 , ailme-d2gu97 , ailme-d2gve7 , ailme-d2gwu1 , ailme-d2gx08 , ailme-d2gyt0 , ailme-d2gz36 , ailme-d2gz37 , ailme-d2gz38 , ailme-d2gz39 , ailme-d2gz40 , ailme-d2h5r9 , ailme-d2h7b7 , ailme-d2h9c9 , ailme-d2h794 , ailme-d2hau7 , ailme-d2hau8 , ailme-d2hcd9 , ailme-d2hdi6 , ailme-d2heu6 , ailme-d2hga4 , ailme-d2hqw5 , ailme-d2hs98 , ailme-d2hsx4 , ailme-d2hti6 , ailme-d2htv3 , ailme-d2htz6 , ailme-d2huc7 , ailme-d2hwj8 , ailme-d2hwy7 , ailme-d2hxm1 , ailme-d2hyc8 , ailme-d2hyv2 , ailme-d2hz11 , ailme-d2hza3 , ailme-d2hzr4 , ailme-d2i1l4 , ailme-d2i2g8 , ailme-g1l7m3 , ailme-g1lu36 , ailme-g1m769 , ailme-g1mc29 , ailme-g1mdj8 , ailme-g1mdr5 , ailme-g1mfp4 , ailme-g1mfx5 , ailme-g1lj41 , ailme-g1lm28 , ailme-g1l3u1 , ailme-g1l7l1 , ailme-g1m5i3 , ailme-g1l2f6 , ailme-g1lji5 , ailme-g1lqk3 , ailme-g1l8s9 , ailme-d2h717 , ailme-d2h718 , ailme-d2h719 , ailme-d2h720 , ailme-g1m5v0 , ailme-g1m5y7 , ailme-g1lkt7 , ailme-g1l2a1 , ailme-g1lsc8 , ailme-g1lrp4 , ailme-d2gv02 , ailme-g1mik5 , ailme-g1ljr1 , ailme-g1lxw7 , ailme-d2h8b5 , ailme-d2h2r2 , ailme-d2h9w7 , ailme-g1meh3 , ailme-g1m719

Title : Evolutionary and biomedical insights from the rhesus macaque genome - Gibbs_2007_Science_316_222
Author(s) : Gibbs RA , Rogers J , Katze MG , Bumgarner R , Weinstock GM , Mardis ER , Remington KA , Strausberg RL , Venter JC , Wilson RK , Batzer MA , Bustamante CD , Eichler EE , Hahn MW , Hardison RC , Makova KD , Miller W , Milosavljevic A , Palermo RE , Siepel A , Sikela JM , Attaway T , Bell S , Bernard KE , Buhay CJ , Chandrabose MN , Dao M , Davis C , Delehaunty KD , Ding Y , Dinh HH , Dugan-Rocha S , Fulton LA , Gabisi RA , Garner TT , Godfrey J , Hawes AC , Hernandez J , Hines S , Holder M , Hume J , Jhangiani SN , Joshi V , Khan ZM , Kirkness EF , Cree A , Fowler RG , Lee S , Lewis LR , Li Z , Liu YS , Moore SM , Muzny D , Nazareth LV , Ngo DN , Okwuonu GO , Pai G , Parker D , Paul HA , Pfannkoch C , Pohl CS , Rogers YH , Ruiz SJ , Sabo A , Santibanez J , Schneider BW , Smith SM , Sodergren E , Svatek AF , Utterback TR , Vattathil S , Warren W , White CS , Chinwalla AT , Feng Y , Halpern AL , Hillier LW , Huang X , Minx P , Nelson JO , Pepin KH , Qin X , Sutton GG , Venter E , Walenz BP , Wallis JW , Worley KC , Yang SP , Jones SM , Marra MA , Rocchi M , Schein JE , Baertsch R , Clarke L , Csuros M , Glasscock J , Harris RA , Havlak P , Jackson AR , Jiang H , Liu Y , Messina DN , Shen Y , Song HX , Wylie T , Zhang L , Birney E , Han K , Konkel MK , Lee J , Smit AF , Ullmer B , Wang H , Xing J , Burhans R , Cheng Z , Karro JE , Ma J , Raney B , She X , Cox MJ , Demuth JP , Dumas LJ , Han SG , Hopkins J , Karimpour-Fard A , Kim YH , Pollack JR , Vinar T , Addo-Quaye C , Degenhardt J , Denby A , Hubisz MJ , Indap A , Kosiol C , Lahn BT , Lawson HA , Marklein A , Nielsen R , Vallender EJ , Clark AG , Ferguson B , Hernandez RD , Hirani K , Kehrer-Sawatzki H , Kolb J , Patil S , Pu LL , Ren Y , Smith DG , Wheeler DA , Schenck I , Ball EV , Chen R , Cooper DN , Giardine B , Hsu F , Kent WJ , Lesk A , Nelson DL , O'Brien W E , Prufer K , Stenson PD , Wallace JC , Ke H , Liu XM , Wang P , Xiang AP , Yang F , Barber GP , Haussler D , Karolchik D , Kern AD , Kuhn RM , Smith KE , Zwieg AS
Ref : Science , 316 :222 , 2007
Abstract : The rhesus macaque (Macaca mulatta) is an abundant primate species that diverged from the ancestors of Homo sapiens about 25 million years ago. Because they are genetically and physiologically similar to humans, rhesus monkeys are the most widely used nonhuman primate in basic and applied biomedical research. We determined the genome sequence of an Indian-origin Macaca mulatta female and compared the data with chimpanzees and humans to reveal the structure of ancestral primate genomes and to identify evidence for positive selection and lineage-specific expansions and contractions of gene families. A comparison of sequences from individual animals was used to investigate their underlying genetic diversity. The complete description of the macaque genome blueprint enhances the utility of this animal model for biomedical research and improves our understanding of the basic biology of the species.
ESTHER : Gibbs_2007_Science_316_222
PubMedSearch : Gibbs_2007_Science_316_222
PubMedID: 17431167
Gene_locus related to this paper: macmu-3neur , macmu-ACHE , macmu-BCHE , macmu-f6rul6 , macmu-f6sz31 , macmu-f6the6 , macmu-f6unj2 , macmu-f6wtx1 , macmu-f6zkq5 , macmu-f7aa58 , macmu-f7ai42 , macmu-f7aim4 , macmu-f7buk8 , macmu-f7cfi8 , macmu-f7cnr2 , macmu-f7cu68 , macmu-f7flv1 , macmu-f7ggk1 , macmu-f7hir7 , macmu-g7n054 , macmu-KANSL3 , macmu-TEX30 , macmu-Y4neur , macmu-g7n4x3 , macmu-i2cy02 , macmu-f7ba84 , macmu-CES2 , macmu-h9er02 , macmu-a0a1d5rbr3 , macmu-a0a1d5q4k5 , macmu-g7mxj6 , macmu-f7dn71 , macmu-f7hkw9 , macmu-f7hm08 , macmu-g7mke4 , macmu-a0a1d5rh04 , macmu-h9fud6 , macmu-f6qwx1 , macmu-f7h4t2 , macmu-h9zaw9 , macmu-f7h550 , macmu-a0a1d5q9w1 , macmu-f7gkb9 , macmu-f7hp78 , macmu-a0a1d5qvu5