Phylogenetic constraints in key functional traits behind species' climate niches: patterns of desiccation and cold resistance across 95 Drosophila species.
about
Does oxygen limit thermal tolerance in arthropods? A critical review of current evidenceHeat freezes niche evolutionUpper thermal limits of Drosophila are linked to species distributions and strongly constrained phylogeneticallyEstimating divergence dates and substitution rates in the Drosophila phylogenyFunctional genomic and phenotypic responses to desiccation in natural populations of a desert drosophilidSeasonal gene expression kinetics between diapause phases in Drosophila virilis group species and overwintering differences between diapausing and non-diapausing females.Contemporary climate change and terrestrial invertebrates: evolutionary versus plastic changes.Sensitivity to thermal extremes in Australian Drosophila implies similar impacts of climate change on the distribution of widespread and tropical species.Which host-dependent insects are most prone to coextinction under changed climates?Climate-driven extinctions shape the phylogenetic structure of temperate tree floras.Basking behavior predicts the evolution of heat tolerance in Australian rainforest lizards.Divergence of thermal physiological traits in terrestrial breeding frogs along a tropical elevational gradient.Macroevolution of thermal tolerance in intertidal crabs from Neotropical provinces: A phylogenetic comparative evaluation of critical limits.Repeated evolution of camouflage in speciose desert rodentsA comparison of inbreeding depression in tropical and widespread Drosophila speciesEvidence for recent evolution of cold tolerance in grasses suggests current distribution is not limited by (low) temperature.Trait associations across evolutionary time within a drosophila phylogeny: correlated selection or genetic constraint?Anhydrobiosis and freezing-tolerance: adaptations that facilitate the establishment of Panagrolaimus nematodes in polar habitats.Low evolutionary potential for egg-to-adult viability in Drosophila melanogaster at high temperatures.Why close relatives make bad neighbours: phylogenetic conservatism in niche preferences and dispersal disproves Darwin's naturalization hypothesis in the thistle tribe.The Role of Inducible Hsp70, and Other Heat Shock Proteins, in Adaptive Complex of Cold Tolerance of the Fruit Fly (Drosophila melanogaster)Egg Viability, Mating Frequency and Male Mating Ability Evolve in Populations of Drosophila melanogaster Selected for Resistance to Cold Shock.Strong Costs and Benefits of Winter Acclimatization in Drosophila melanogasterPhysiological Limits along an Elevational Gradient in a Radiation of Montane Ground BeetlesEcological determinants of mean family age of angiosperm trees in forest communities in ChinaMultiple Independent Retroelement Insertions in the Promoter of a Stress Response Gene Have Variable Molecular and Functional Effects in Drosophila.Inducing Cold-Sensitivity in the Frigophilic Fly Drosophila montana by RNAiBenefits from living together? Clades whose species use similar habitats may persist as a result of eco-evolutionary feedbacks.The mode and tempo of genome size evolution in the subgenus Sophophora.The capacity to maintain ion and water homeostasis underlies interspecific variation in Drosophila cold tolerance.How consistent are the transcriptome changes associated with cold acclimation in two species of the Drosophila virilis group?Cold acclimation wholly reorganizes the Drosophila melanogaster transcriptome and metabolomePhotosynthetic innovation broadens the niche within a single species.Life span variation in 13 Drosophila species: a comparative study on life span, environmental variables and stress resistance.Inferring the demographic history of Drosophila subobscura from nucleotide variation at regions not affected by chromosomal inversions.Thermal acclimation mitigates cold-induced paracellular leak from the Drosophila gut.Cross-tolerance and cross-talk in the cold: relating low temperatures to desiccation and immune stress in insects.The influence of abdominal pigmentation on desiccation and ultraviolet resistance in two species of Drosophila.Optimal temperature range of a plastic species, Drosophila simulans.Niche evolution and thermal adaptation in the temperate species Drosophila americana.
P2860
Q26778517-FADEFF2F-0289-48D4-A997-30F818DB099AQ27006928-4987B381-CBC7-4ACE-A6A3-AA93C550530EQ28715125-B3DE1D49-3C4D-4208-818D-F06A04A59D5AQ28717197-314F85A6-BEC1-4232-B933-887D66398BC6Q30602943-91330462-9DDE-4AE8-8CE1-EF2AC3592ECFQ30654058-D1333768-D5C9-4D64-A540-DDE2AA4EB422Q30740361-677F42B0-25C0-448A-A36D-F6CDB3BE0CCEQ30759634-BEB5F464-65B2-4B48-9E67-F207C3666C2DQ30822095-205CB48F-1873-45C7-8E76-03C4A842F629Q30885325-07A5C787-1104-427F-B529-A2A29876F17BQ31128362-05BDA3EE-0936-4EB4-947A-F4277EBE6874Q33633884-8BA24EAC-317F-42F3-9881-483A7925350BQ33633946-9F5CE9F2-B411-412D-89BD-BA170F4B02D0Q33799149-CF8039A7-84DC-43A4-8EFA-DC2B2DE0453AQ34608219-1CE907BE-30A7-4B87-A8FA-3CA7E4259F30Q34635833-15474FFB-EB46-4F91-91BD-16E6693ECAD6Q34981353-C50425C0-9D94-4220-8C84-071C24AD3B2DQ35154658-12BA1077-94DB-4C0F-916B-A828F8ABA63EQ35553830-1F95AD46-8B64-40E5-A412-1E7CB5F89E32Q35626473-4F5C9D50-4D4D-4F51-96EF-FFB93226DF55Q35649650-69BD9628-2288-4062-AE6B-B70811BAA312Q35660967-552EE832-15BF-4A51-85A9-A514F128ACFBQ35663735-D72236B7-B7EE-4916-8841-0D229B6ACC68Q35979141-4EB40FEF-ED3E-4B73-AD64-1C66EAD6689FQ36063644-40CEA426-776A-4925-87E4-522277E3E99CQ36102676-83CDBE87-2AF2-488B-9105-D8675EB0A363Q36188641-49550855-76A0-499E-9578-AAECC63C52C0Q36202345-BCB01EF1-31F5-4314-B6B7-5B9949207417Q36299551-DB30287B-D058-4D76-B5B2-083D040891BAQ36382720-9CF850D2-36FD-4D67-81B6-DBC65849D0FAQ36749918-4C33AD6A-2B49-4990-B8E2-BD28E603B34BQ37054248-370BE11E-59D3-44A7-853B-4DA366BB0A98Q38858214-C0F12993-F79F-4E44-9B5C-73CA31B50369Q39598896-B189AD91-D786-4D83-943E-4856FB58CD6FQ41209718-B873619C-D110-4324-B0D2-67EBCBE4EFACQ41459646-26F2B919-5AE0-469E-8FFC-14CC8BFEC2A4Q43607717-93D1D74D-D8D9-435A-80D2-56EF1FFFC984Q44502561-68BF33D7-62C4-4DAB-965E-4E59BDBF1EF4Q44577270-1FDAD3A9-7703-4ED0-B50D-C91C2E696F00Q44969418-2974CD2B-5E46-4604-9BF1-3333BB9F1B25
P2860
Phylogenetic constraints in key functional traits behind species' climate niches: patterns of desiccation and cold resistance across 95 Drosophila species.
description
2012 nî lūn-bûn
@nan
2012 թուականի Մայիսին հրատարակուած գիտական յօդուած
@hyw
2012 թվականի մայիսին հրատարակված գիտական հոդված
@hy
2012年の論文
@ja
2012年論文
@yue
2012年論文
@zh-hant
2012年論文
@zh-hk
2012年論文
@zh-mo
2012年論文
@zh-tw
2012年论文
@wuu
name
Phylogenetic constraints in ke ...... across 95 Drosophila species.
@ast
Phylogenetic constraints in ke ...... across 95 Drosophila species.
@en
Phylogenetic constraints in ke ...... across 95 Drosophila species.
@nl
type
label
Phylogenetic constraints in ke ...... across 95 Drosophila species.
@ast
Phylogenetic constraints in ke ...... across 95 Drosophila species.
@en
Phylogenetic constraints in ke ...... across 95 Drosophila species.
@nl
prefLabel
Phylogenetic constraints in ke ...... across 95 Drosophila species.
@ast
Phylogenetic constraints in ke ...... across 95 Drosophila species.
@en
Phylogenetic constraints in ke ...... across 95 Drosophila species.
@nl
P2860
P50
P1433
P1476
Phylogenetic constraints in ke ...... across 95 Drosophila species.
@en
P2093
Jean R David
Vanessa Kellermann
P2860
P304
P356
10.1111/J.1558-5646.2012.01685.X
P50
P577
2012-05-28T00:00:00Z