Evolution of nectarivory in phyllostomid bats (Phyllostomidae Gray, 1825, Chiroptera: Mammalia)
about
sameAs
Miocene Fossils Reveal Ancient Roots for New Zealand's Endemic Mystacina (Chiroptera) and Its Rainforest HabitatFour new bat species (Rhinolophus hildebrandtii complex) reflect Plio-Pleistocene divergence of dwarfs and giants across an Afromontane archipelago.Nectar uptake in bats using a pumping-tongue mechanism.Molecular Evolution of the Nuclear Factor (Erythroid-Derived 2)-Like 2 Gene Nrf2 in Old World Fruit Bats (Chiroptera: Pteropodidae)Bayesian hierarchical models suggest oldest known plant-visiting bat was omnivorousA novel endogenous betaretrovirus in the common vampire bat (Desmodus rotundus) suggests multiple independent infection and cross-species transmission eventsParasite diversity of European Myotis species with special emphasis on Myotis myotis (Microchiroptera, Vespertilionidae) from a typical nursery roostPhosphoenolpyruvate carboxykinase 1 gene (Pck1) displays parallel evolution between Old World and New World fruit batsRepeated horizontal transfers of four DNA transposons in invertebrates and batsRelaxed evolution in the tyrosine aminotransferase gene tat in old world fruit bats (Chiroptera: Pteropodidae)Contrasting evolutionary dynamics of the developmental regulator PAX9, among bats, with evidence for a novel post-transcriptional regulatory mechanismAdaptive evolution of the myo6 gene in old world fruit bats (family: pteropodidae)Understanding phylogenetic incongruence: lessons from phyllostomid batsThe voltage-gated potassium channel subfamily KQT member 4 (KCNQ4) displays parallel evolution in echolocating bats.Adaptive evolution in the glucose transporter 4 gene Slc2a4 in Old World fruit bats (family: Pteropodidae)Evolutionary patterns and processes in the radiation of phyllostomid bats.Evolutionary relationships of the old world fruit bats (Chiroptera, Pteropodidae): another star phylogeny?Relationship between spatial working memory performance and diet specialization in two sympatric nectar bats.The missing part of seed dispersal networks: structure and robustness of bat-fruit interactions.SUNPLIN: simulation with uncertainty for phylogenetic investigationsKaryotypic variation in Rhinophylla pumilio Peters, 1865 and comparative analysis with representatives of two subfamilies of Phyllostomidae (Chiroptera)Chromosomal evolution among leaf-nosed nectarivorous bats--evidence from cross-species chromosome painting (Phyllostomidae, Chiroptera).Integrating incomplete fossils by isolating conflicting signal in saturated and non-independent morphological characters.Phylogenetic reconstruction by cross-species chromosome painting and G-banding in four species of Phyllostomini tribe (Chiroptera, Phyllostomidae) in the Brazilian Amazon: an independent evidence for monophyly.Survey sequencing reveals elevated DNA transposon activity, novel elements, and variation in repetitive landscapes among vesper bats.A phylogenetic analysis using multidirectional chromosome painting of three species (Uroderma magnirostrum, U. bilobatum and Artibeus obscurus) of subfamily Stenodermatinae (Chiroptera-Phyllostomidae).Sugar Metabolism in Hummingbirds and Nectar Bats.Microbiome analysis among bats describes influences of host phylogeny, life history, physiology and geography.Simplifying a wing: diversity and functional consequences of digital joint reduction in bat wings.The thermal niche of Neotropical nectar-feeding bats: Its evolution and application to predict responses to global warming.Ultrastructure of spermatogenesis in the short-tailed fruit bat, Carollia perspicillata (Chiroptera: Phyllostomidae: Carollinae).Dietary hardness, loading behavior, and the evolution of skull form in bats.Parallel evolution of the glycogen synthase 1 (muscle) gene Gys1 between Old World and New World fruit bats (Order: Chiroptera).The glycogen synthase 2 gene (Gys2) displays parallel evolution between Old World and New World fruit bats.A new, large-bodied omnivorous bat (Noctilionoidea: Mystacinidae) reveals lost morphological and ecological diversity since the Miocene in New Zealand.Is there a link between aging and microbiome diversity in exceptional mammalian longevity?Prestin shows divergent evolution between constant frequency echolocating bats.Phylogenetic fields of species: cross-species patterns of phylogenetic structure and geographical coexistence.Cloning and molecular evolution of the aldehyde dehydrogenase 2 gene (Aldh2) in bats (Chiroptera).When did plants become important to leaf-nosed bats? Diversification of feeding habits in the family Phyllostomidae.
P2860
Q21089642-4FECB1BF-1577-4455-BA8F-F105F022792BQ21090883-9BD3ED12-B745-45D6-BDDA-D9498E635913Q27339673-CE61EDE7-8702-4D6A-A2BB-8366BF36515EQ28552121-AB66F2B3-C398-479D-946F-73F25CD29FDCQ28603858-E16502A5-A30E-4B22-83DB-C565628E44EDQ28649469-1606F455-2E39-45E5-BF96-58001AD0A787Q28649576-5B638E0F-3F94-41E2-80D4-8756EA6C9CDEQ28651576-7F21AA6E-0917-40EA-AEA3-BA6007CBD533Q28652078-DB419F9B-B5DE-4EE0-AED0-C3D2985FB136Q28657416-F3E85FB4-5CAC-4FD2-91C9-C1F272DCA11AQ28706225-784D0C2F-9F56-40BA-9FC2-D18889E878E5Q28708921-B4B96FD5-D40C-404F-805A-EDD5FFC3CE07Q28708935-5D059B5E-0847-4B70-A328-62B61E0CC14BQ28730241-9383F480-FB4C-4FE6-BF76-01675AB282DDQ28730720-E38CD565-9121-43B1-BD46-143A2AE63D56Q28742879-58A2C17D-A85C-4874-A4B3-D1ED13489E58Q28743533-DAB53B05-80B0-41C7-9169-96F27CFD1D43Q30474104-1AE07B63-36B4-4F97-9EC9-C44A6B805CBEQ33840943-E3E8F5DD-D86A-46CE-87E4-37BB12DFD91BQ35042777-5DB46B25-7B94-4C5A-B3B4-CAD90B1D20B0Q35049625-524F1333-EDDC-4216-AA22-9A50AA616C9FQ35076232-81B6F62E-D911-404E-8A9F-0CC4FA0A6BD6Q35166775-B5B422B8-B86D-41C8-9AB0-65E728398036Q35217268-E6DFC1F4-56DA-4C9C-A8B9-EEE60CBF2D02Q35930322-939FB2A2-8EED-4A9A-9BD5-24364A86453BQ38425827-80F49AFA-689D-4F5D-9E1F-8D509CAA60F2Q39433133-2F57F3D1-22B1-4D58-B8E9-2B4B78E3ABE9Q39626919-41FAEC88-7F16-4FA8-94C1-7B5AD373E1D9Q40359282-F90CB00C-4DB4-40CD-B525-06AF06B56182Q41636108-E4DC146F-076A-45B4-91C4-1A34B343DAE4Q44038864-61CB2956-417F-46FC-A804-8EB32C82642FQ46009310-6F6E42E6-82F1-42A3-8151-20D2D757ECC8Q46629686-DDA5DBEA-63E6-43F5-87E2-284FA3FFDECEQ46969394-249A0767-7F14-4599-A1E4-1D5FD293C654Q48267438-4C54DE52-B34E-4BC7-BC82-85297095506FQ49412717-689BC87D-9558-465B-A820-648C1AFCED26Q50432902-1453D23F-578B-4DBC-8D62-9ABA8A207520Q51538397-C73A339D-B1BE-450A-8473-B55EF63BB162Q51548227-EE086E9D-25B5-46ED-91B7-FE64A7F4071DQ51602312-41E82D8E-E5FE-43FD-98D2-3005B65F44FF
P2860
Evolution of nectarivory in phyllostomid bats (Phyllostomidae Gray, 1825, Chiroptera: Mammalia)
description
2010 nî lūn-bûn
@nan
2010 թուականի Յունիսին հրատարակուած գիտական յօդուած
@hyw
2010 թվականի հունիսին հրատարակված գիտական հոդված
@hy
2010年の論文
@ja
2010年論文
@yue
2010年論文
@zh-hant
2010年論文
@zh-hk
2010年論文
@zh-mo
2010年論文
@zh-tw
2010年论文
@wuu
name
Evolution of nectarivory in ph ...... y, 1825, Chiroptera: Mammalia)
@ast
Evolution of nectarivory in ph ...... y, 1825, Chiroptera: Mammalia)
@en
Evolution of nectarivory in ph ...... y, 1825, Chiroptera: Mammalia)
@nl
type
label
Evolution of nectarivory in ph ...... y, 1825, Chiroptera: Mammalia)
@ast
Evolution of nectarivory in ph ...... y, 1825, Chiroptera: Mammalia)
@en
Evolution of nectarivory in ph ...... y, 1825, Chiroptera: Mammalia)
@nl
prefLabel
Evolution of nectarivory in ph ...... y, 1825, Chiroptera: Mammalia)
@ast
Evolution of nectarivory in ph ...... y, 1825, Chiroptera: Mammalia)
@en
Evolution of nectarivory in ph ...... y, 1825, Chiroptera: Mammalia)
@nl
P2093
P2860
P356
P1476
Evolution of nectarivory in ph ...... y, 1825, Chiroptera: Mammalia)
@en
P2093
Frieder Mayer
Otto von Helversen
Thomas Datzmann
P2860
P2888
P356
10.1186/1471-2148-10-165
P407
P577
2010-06-04T00:00:00Z
P5875
P6179
1026009333