about
On the origin and trigger of the notothenioid adaptive radiationA demonstration of nesting in two antarctic icefish (genus Chionodraco) using a fin dimorphism analysis and ex situ videosIdentification of the notothenioid sister lineage illuminates the biogeographic history of an Antarctic adaptive radiationATP regulation of the ligand-binding properties in temperate and cold-adapted haemoglobins. X-ray structure and ligand-binding kinetics in the sub-Antarctic fish Eleginops maclovinusComparative phylogeography of the ocean planetEvolution in an extreme environment: developmental biases and phenotypic integration in the adaptive radiation of antarctic notothenioidsLifestyle and Ice: The Relationship between Ecological Specialization and Response to Pleistocene Climate ChangeDiversity and disparity through time in the adaptive radiation of Antarctic notothenioid fishesA new model army: Emerging fish models to study the genomics of vertebrate Evo-DevoThe genome sequence of the Antarctic bullhead notothen reveals evolutionary adaptations to a cold environmentEcomorphological disparity in an adaptive radiation: opercular bone shape and stable isotopes in Antarctic icefishesAncient climate change, antifreeze, and the evolutionary diversification of Antarctic fishes.Evolution and biodiversity of Antarctic organisms: a molecular perspectiveTranscriptomic and genomic evolution under constant cold in Antarctic notothenioid fish.Antifreeze protein-induced superheating of ice inside Antarctic notothenioid fishes inhibits melting during summer warming.Evidence for past and present hybridization in three Antarctic icefish species provides new perspectives on an evolutionary radiation.Description of Ganymedes yurii sp. n. (Ganymedidae), a New Gregarine Species from the Antarctic Amphipod Gondogeneia sp. (Crustacea).Revision of Neolebouria Gibson, 1976 (Digenea: Opecoelidae), with Trilobovarium n. g., for species infecting tropical and subtropical shallow-water fishes.How will fish that evolved at constant sub-zero temperatures cope with global warming? Notothenioids as a case study.Cold physiology: postprandial blood flow dynamics and metabolism in the Antarctic fish Pagothenia borchgrevinkiParallel ecological diversification in Antarctic notothenioid fishes as evidence for adaptive radiation.Is the species flock concept operational? The Antarctic shelf case.Applications of very high-resolution imagery in the study and conservation of large predators in the Southern Ocean.A New APEH Cluster with Antioxidant Functions in the Antarctic Hemoglobinless Icefish Chionodraco hamatus.More than meets the eye: functionally salient changes in internal bone architecture accompany divergence in cichlid feeding modeThe Gut Microbial Community of Antarctic Fish Detected by 16S rRNA Gene Sequence Analysis.Neofunctionalization of zona pellucida proteins enhances freeze-prevention in the eggs of Antarctic notothenioids.Understanding processes at the origin of species flocks with a focus on the marine Antarctic fauna.Population divergences despite long pelagic larval stages: lessons from crocodile icefishes (Channichthyidae).Divergence in skeletal mass and bone morphology in antarctic notothenioid fishes.In situ gene mapping of two genes supports independent evolution of sex chromosomes in cold-adapted Antarctic fish.Structure and dynamics of Antarctic fish neuroglobin assessed by computer simulations.A novel class of bifunctional acylpeptide hydrolases--potential role in the antioxidant defense systems of the Antarctic fish Trematomus bernacchii.Expansion of capacities for iron transport and sequestration reflects plasma volumes and heart mass among white-blooded notothenioid fishes.New Lessons from an Old Fish: What Antarctic Icefishes May Reveal about the Functions of Oxygen-Binding Proteins.Metabolic responses of the Antarctic fishes Notothenia rossii and Notothenia coriiceps to sewage pollution.Adaptive evolution of hepcidin genes in antarctic notothenioid fishes.Hypoxia-Inducible Factor-1α in Antarctic notothenioids contains a polyglutamine and glutamic acid insert that varies in length with phylogeny.Evolutionary suppression of erythropoiesis via the modulation of TGF-β signalling in an Antarctic icefish.The unique mitochondrial form and function of Antarctic channichthyid icefishes.
P2860
Q21089973-3609AF27-5EB7-40DE-82C9-99264B65AA8DQ21090647-C8D9EEFD-42AD-4A3E-8492-2B9D960E5A0AQ21999493-05F8DA94-8CE9-4381-8FD0-8D39BB916F8AQ27682948-FFB453DA-C973-48C4-B97E-BFA55F93BB17Q28595846-2E6BC2FC-930E-454C-997C-D775EDE486ECQ28597017-845DC0E1-8148-4E01-B744-344CF795AE5CQ28607695-8B418B15-D29C-49DD-A4E8-4B42EC65A325Q28648503-1AF1E604-2A5A-4223-B8F3-7AB5B7B8CD72Q28650067-F995032E-4242-4FAC-900C-2477E763F476Q28654783-DB55F291-FBD9-4273-B42B-E42DB20258B3Q28677002-029F0795-8E6F-415F-A7AE-1CEFBFAFABECQ28731494-5725D0AE-6617-479D-86A9-9F8BB85816E6Q28757837-4F24E824-9A55-4BAD-A2AD-4801F1CF3FA3Q30483384-504E30BD-400B-4538-A803-D6742B0967FFQ30596263-4532C16B-4E3C-4615-8395-2A69FF2F0F55Q30662555-92DD8F55-7849-4737-9B17-64C3D8C8C724Q31107326-D4B18B96-E8E8-4921-A90F-6A46CD4FC17EQ31165031-72034196-041E-4059-8913-23016258613BQ33811056-FC20F971-752C-4A83-AAD4-4AF70E390CC3Q34201021-5F56AA83-BAB1-4346-B62F-351518B8DDC4Q34219721-B70F46C7-9C26-4A46-BD3E-ADA76ECC1148Q34924179-3F4389DA-BA95-4AED-892B-ED378760E303Q35221397-B61E45E5-7C17-4484-88DC-05DDEA3C8C7DQ35623205-F2696375-331E-4493-85EC-14F6F4C6803BQ35993781-58E84440-4D83-4C85-907C-0A0CFE2EE450Q36221330-B32057AD-D160-48A8-B5D2-44BF62212672Q37329806-6D35E148-16F7-4AD6-AE36-07528334DCF1Q38368267-27EFD948-7466-48AE-B655-E9FD78035907Q38696484-43A2F77F-EDE0-4D57-859C-029F0A3BCCD2Q42646350-2B563E20-455A-432E-8831-C1FEE0FB481BQ43239216-826E1808-86E4-489C-941A-78D7F23D180BQ44562842-2070ABE3-2907-40C1-AB95-A77BBC411636Q45190087-C25E222C-6ECA-475A-9BBF-A1049FD576CDQ46510134-F9D0660C-C1F7-4AE1-8469-7DFC3BF6F637Q46538916-152B6756-1BCA-4BA0-B582-785DDB7828B3Q46721002-43D3D048-EF17-4273-9A67-D6BC5D5D57E3Q46725636-C83D5AEC-0432-4653-A179-3CA174A03FE2Q50074081-63B154D5-58A8-4740-B5E9-3E3F1F4DB359Q50438430-6257CE89-0B6A-4795-A778-BA295828FAFEQ50537215-FEF100BF-9437-4DA3-9E93-67C4EE00C81F
P2860
description
im September 2004 veröffentlichter wissenschaftlicher Artikel
@de
scientific article published in September 2004
@en
wetenschappelijk artikel
@nl
наукова стаття, опублікована у вересні 2004
@uk
name
The nature of the diversity of Antarctic fishes
@en
The nature of the diversity of Antarctic fishes
@nl
type
label
The nature of the diversity of Antarctic fishes
@en
The nature of the diversity of Antarctic fishes
@nl
prefLabel
The nature of the diversity of Antarctic fishes
@en
The nature of the diversity of Antarctic fishes
@nl
P1433
P1476
The nature of the diversity of Antarctic fishes
@en
P2860
P2888
P304
P356
10.1007/S00300-004-0667-4
P577
2004-09-24T00:00:00Z