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Genomic data of the Ostrich (Struthio camelus australis)
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关键词:
Genomic
DOI:
doi:10.5524/101013
摘要:
The Southern Ostrich (Struthio camelus australis (Gurney, 1868)) is a sub-species of The Common Ostrich (Struthio camelus
Data from: Preferred gait and walk–run transition speeds in ostriches measured using GPS-IMU sensors
负责人:
关键词:
Struthio camelus;locomotion;biomechanics;energetics;Gait transition
DOI:
doi:10.5061/dryad.h846r
摘要:
The ostrich (Struthio camelus) is widely appreciated as a fast and agile bipedal athlete, and is a useful comparative bipedal model
Data from: Inferring muscle functional roles of the ostrich pelvic limb during walking and running using computer optimization
负责人:
关键词:
OpenSim;computed muscle control;forward dynamics;Struthio camelus;static optimization;inverse dynamics;musculoskeletal model
DOI:
doi:10.5061/dryad.fh3h6
摘要:
Owing to their cursorial background, ostriches (Struthio camelus) walk and run with high metabolic economy, can reach very fast ru
Data from: Chromosome-level assembly reveals extensive rearrangement in saker falcon and budgerigar, but not ostrich, genomes
负责人:
关键词:
Falco cherrug;Struthio camelus;Chromosome;Avian;Genome;Melopsittacus undulatus
DOI:
doi:10.5061/dryad.q70q40m
摘要:
(saker falcon, budgerigar, and ostrich) previously reported as karyotypically rearranged compared to most birds. We also test the hypothesis tha
Data from: A re-evaluation of the chemical composition of avian urinary excreta
负责人:
关键词:
struvite;ammonium urate;Bubo virginianus;urine;Dromaius novaehollandiae;Struthio camelus;Trichoglossus moluccanus;Birds;Numida meleagris;Aara ararauna;uric acid;Gallus gallus;Aratinga jandaya
DOI:
doi:10.5061/dryad.d39b44r
摘要:
, as commonly reported. None of the analyzed samples were found to contain uric acid. Instead, a variety of compounds including ammonium urate, stru
Data from: Here and there, but not everywhere: repeated loss of uncoupling protein 1 in amniotes
负责人:
关键词:
Gavia stellata;Canis familiaris;Haliaeetus albicilla;Balaenoptera acutorostrata;Anolis carolinensis;Picoides pubescens;Cuculus canorus;Pteropus vampyrus;Merops nubicus;Cavia porcellus;Struthio camelus australis;Pseudopodoces humilis;Aquila chrysaetos canadensis;Meleagris gallopavo;Serinus canaria;Procavia capensis;Sarcophilus harrisii;Tupaia belangeri;Zonotrichia albicollis;Buceros rhinoceros silvestris;Homo Sapiens;Dipodomys ordii;Papio anubis;Candoia aspera;Melopsittacus undulatus;Pan troglogdytes;Myotis lucifugus;Thamnophis couchii;Corvus cornix cornix;Sus scrofa;Sceloporus undulatus;Charadrius vociferus;Rattus norvegicus;Crocodylus porosus?;Alligator sinensis;Tauraco erythrolophus;Erinaceus europaeus;Microcebus murinus;Nipponia nippon;Xenopeltis unicolor;Ophiophagus hannah;Choloepus hoffmanni;Myotis brandtii;Dasypus novemcinctus;Tinamus guttatus;Pygoscelis adeliae;Orcinus orca;Tursiops truncatus;Phaethon lepturus;Phalacrocorax carbo;Falco cherrug;Alligator mississippiensis;Microtus ochrogaster;Tyto alba;heterocephalus glaber;Aptenodytes forsteri;Apaloderma vittatum;Macropus eugenii;Chlorocebus sabaeus;Cariama cristata;Egretta garzetta;Pterocles gutturalis;Agkistrodon piscivorus;Macaca mulatta;Felis catus;Physeter macrocephalus;Calypte anna;Gavialis gangeticus;Vicugna pacos;Elgaria multicarinata;Manacus vitellinus;Chaetura pelagica;Gallus gallus;Otolemur garnettii;Pelecanus crispus;turtle;Anolis sagrei;Bos taurus;Balearica regulorum gibbericeps;Chelonia mydas;thermogenesis;Sorex araneus;Ovis aries;Nestor notabilis;Mesitornis unicolor;Opisthocomus hoazin;Python molurus bivittatus;cetacean;Equus caballus;Chrysemys picta;Ficedula albicollis;Mus musculus;Ochotona princeps;Pogona vitticeps;Callithrix jacchus;Colius striatus;Leptosomus discolor;UCP1;Snake;Lamprophis fuliginosus;Anser cygnoides domesticus;Terrapene ornata;Gorilla gorilla;Oryctolagus cuniculus;Fulmarus glacialis;Corvus brachyrhynchos;Sternotherus odoratus;Taeniopygia guttata;Eublepharis macularius;Pongo abelii;Caprimulgus carolinensis;lizard;Monodelphis domestica;Haliaeetus leucocephalus;Mustela putorius;Pelodiscus sinensis;Pelusios castaneus;Chlamydotis macqueenii;Eurypyga helias;Ornithorhynchus anatinus;Columba livia;Loxodonta africana;Echinops telfairi;Falco peregrinus;Nomascus leucogenys;Geospiza fortis;Scincella lateralis;Thamnophis elegans;Tarsius syrichta;Ictidomys tridecemlineatus;Anas platyrhynchos;Ailuropoda melanoleuca;Cheyldra serpentina
DOI:
doi:10.5061/dryad.934fg
摘要:
Endothermy is an evolutionary innovation in eutherian mammals and birds. In eutherian mammals, UCP1 is a key protein in adaptive nonshivering thermogenesis (NST). Although ucp1 arose early in the vertebrate lineage, the loss of ucp1 was previously documented in several reptile species (including birds). Here we determine that ucp1 was lost at the base of the reptile lineage, as we fail to find ucp1 in every major reptile lineage. Furthermore, though UCP1 plays a key role in mammalian NST, we confirm that pig has lost several exons from ucp1 and conclude that pig is not a sole outlier as the only eutherian mammal lineage to do so. Through similarity searches and synteny analysis, we show that ucp1 has also been lost/pseudogenized in Delphinidae (dolphin, orca) and potentially Xenarthra (sloth, armadillo) and Afrotheria (hyrax). These lineages provide models for investigating alternate mechanisms of thermoregulation and energy metabolism in the absence of functional UCP1. Further, the repeated losses of a functional UCP1 suggest the pervasiveness of NST via UCP1 across the mammalian lineage needs re-evaluation.
GBIF Occurrence Download
负责人:
关键词:
GBIF biodiversity species occurrences
DOI:
doi:10.15468/dl.wabjjb
摘要:
A dataset containing 12802 species occurrences available in GBIF matching the query: TaxonKey: Struthio camelus Linnaeus, 1758. The dataset includes

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