Ryder OA

References (4)

Title : Insights into hominid evolution from the gorilla genome sequence - Scally_2012_Nature_483_169
Author(s) : Scally A , Dutheil JY , Hillier LW , Jordan GE , Goodhead I , Herrero J , Hobolth A , Lappalainen T , Mailund T , Marques-Bonet T , McCarthy S , Montgomery SH , Schwalie PC , Tang YA , Ward MC , Xue Y , Yngvadottir B , Alkan C , Andersen LN , Ayub Q , Ball EV , Beal K , Bradley BJ , Chen Y , Clee CM , Fitzgerald S , Graves TA , Gu Y , Heath P , Heger A , Karakoc E , Kolb-Kokocinski A , Laird GK , Lunter G , Meader S , Mort M , Mullikin JC , Munch K , O'Connor TD , Phillips AD , Prado-Martinez J , Rogers AS , Sajjadian S , Schmidt D , Shaw K , Simpson JT , Stenson PD , Turner DJ , Vigilant L , Vilella AJ , Whitener W , Zhu B , Cooper DN , de Jong P , Dermitzakis ET , Eichler EE , Flicek P , Goldman N , Mundy NI , Ning Z , Odom DT , Ponting CP , Quail MA , Ryder OA , Searle SM , Warren WC , Wilson RK , Schierup MH , Rogers J , Tyler-Smith C , Durbin R
Ref : Nature , 483 :169 , 2012
Abstract : Gorillas are humans' closest living relatives after chimpanzees, and are of comparable importance for the study of human origins and evolution. Here we present the assembly and analysis of a genome sequence for the western lowland gorilla, and compare the whole genomes of all extant great ape genera. We propose a synthesis of genetic and fossil evidence consistent with placing the human-chimpanzee and human-chimpanzee-gorilla speciation events at approximately 6 and 10 million years ago. In 30% of the genome, gorilla is closer to human or chimpanzee than the latter are to each other; this is rarer around coding genes, indicating pervasive selection throughout great ape evolution, and has functional consequences in gene expression. A comparison of protein coding genes reveals approximately 500 genes showing accelerated evolution on each of the gorilla, human and chimpanzee lineages, and evidence for parallel acceleration, particularly of genes involved in hearing. We also compare the western and eastern gorilla species, estimating an average sequence divergence time 1.75 million years ago, but with evidence for more recent genetic exchange and a population bottleneck in the eastern species. The use of the genome sequence in these and future analyses will promote a deeper understanding of great ape biology and evolution.
ESTHER : Scally_2012_Nature_483_169
PubMedSearch : Scally_2012_Nature_483_169
PubMedID: 22398555
Gene_locus related to this paper: gorgo-g3qfr8 , gorgo-g3qgi3 , gorgo-g3r1s1 , gorgo-g3r9p9 , gorgo-a0a2i2zrx6 , gorgo-g3re16 , gorgo-g3s122 , gorgo-a0a2i2y3x8

Title : Impacts of the Cretaceous Terrestrial Revolution and KPg extinction on mammal diversification - Meredith_2011_Science_334_521
Author(s) : Meredith RW , Janecka JE , Gatesy J , Ryder OA , Fisher CA , Teeling EC , Goodbla A , Eizirik E , Simao TL , Stadler T , Rabosky DL , Honeycutt RL , Flynn JJ , Ingram CM , Steiner C , Williams TL , Robinson TJ , Burk-Herrick A , Westerman M , Ayoub NA , Springer MS , Murphy WJ
Ref : Science , 334 :521 , 2011
Abstract : Previous analyses of relations, divergence times, and diversification patterns among extant mammalian families have relied on supertree methods and local molecular clocks. We constructed a molecular supermatrix for mammalian families and analyzed these data with likelihood-based methods and relaxed molecular clocks. Phylogenetic analyses resulted in a robust phylogeny with better resolution than phylogenies from supertree methods. Relaxed clock analyses support the long-fuse model of diversification and highlight the importance of including multiple fossil calibrations that are spread across the tree. Molecular time trees and diversification analyses suggest important roles for the Cretaceous Terrestrial Revolution and Cretaceous-Paleogene (KPg) mass extinction in opening up ecospace that promoted interordinal and intraordinal diversification, respectively. By contrast, diversification analyses provide no support for the hypothesis concerning the delayed rise of present-day mammals during the Eocene Period.
ESTHER : Meredith_2011_Science_334_521
PubMedSearch : Meredith_2011_Science_334_521
PubMedID: 21940861
Gene_locus related to this paper: ailme-BCHE , hetga-g5atg6 , pig-BCHE

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 : Genome sequence, comparative analysis, and population genetics of the domestic horse - Wade_2009_Science_326_865
Author(s) : Wade CM , Giulotto E , Sigurdsson S , Zoli M , Gnerre S , Imsland F , Lear TL , Adelson DL , Bailey E , Bellone RR , Blocker H , Distl O , Edgar RC , Garber M , Leeb T , Mauceli E , MacLeod JN , Penedo MC , Raison JM , Sharpe T , Vogel J , Andersson L , Antczak DF , Biagi T , Binns MM , Chowdhary BP , Coleman SJ , Della Valle G , Fryc S , Guerin G , Hasegawa T , Hill EW , Jurka J , Kiialainen A , Lindgren G , Liu J , Magnani E , Mickelson JR , Murray J , Nergadze SG , Onofrio R , Pedroni S , Piras MF , Raudsepp T , Rocchi M , Roed KH , Ryder OA , Searle S , Skow L , Swinburne JE , Syvanen AC , Tozaki T , Valberg SJ , Vaudin M , White JR , Zody MC , Lander ES , Lindblad-Toh K
Ref : Science , 326 :865 , 2009
Abstract : We report a high-quality draft sequence of the genome of the horse (Equus caballus). The genome is relatively repetitive but has little segmental duplication. Chromosomes appear to have undergone few historical rearrangements: 53% of equine chromosomes show conserved synteny to a single human chromosome. Equine chromosome 11 is shown to have an evolutionary new centromere devoid of centromeric satellite DNA, suggesting that centromeric function may arise before satellite repeat accumulation. Linkage disequilibrium, showing the influences of early domestication of large herds of female horses, is intermediate in length between dog and human, and there is long-range haplotype sharing among breeds.
ESTHER : Wade_2009_Science_326_865
PubMedSearch : Wade_2009_Science_326_865
PubMedID: 19892987
Gene_locus related to this paper: horse-1plip , horse-2plrp , horse-ACHE , horse-BCHE , horse-f6pri5 , horse-f6qlk6 , horse-f6qsc5 , horse-f6r958 , horse-f6sfg0 , horse-f6uif6 , horse-f6un85 , horse-f6vxp7 , horse-f6wfs9 , horse-f6wzv8 , horse-f6x0i7 , horse-f6x5e5 , horse-f6zmg7 , horse-f7afw6 , horse-f7agv7 , horse-f7bj10 , horse-f7bk45 , horse-f7bvl6 , horse-f7c7a8 , horse-f7cdt1 , horse-f7cxj0 , horse-f6ut17 , horse-f6svq9 , horse-f6xgj6 , horse-f6s101 , horse-f6wfa7 , horse-f7cpx3 , horse-f7adj7 , horse-f6r609 , horse-f6y0j2 , horse-f6zvb2 , horse-f7e4g0 , horse-f6ti02 , horse-f6re01 , horse-f6xmp6 , horse-f6vts1 , horse-f6quf7 , horse-f6tn81 , horse-f7bm46 , horse-f6q1u3 , horse-f6zna7 , horse-f6q208 , horse-f7cuh0 , horse-f6tq73 , horse-f6xa70 , horse-f6qj19 , horse-f6wgf3 , horse-f7d8t6 , horse-f6ul42 , horse-f7am73 , horse-f7dme2