Parallel adaptive evolution of Atlantic cod on both sides of the Atlantic Ocean in response to temperature.
about
Using neutral, selected, and hitchhiker loci to assess connectivity of marine populations in the genomic eraAdaptation to Low Salinity Promotes Genomic Divergence in Atlantic Cod (Gadus morhua L.)The conserved Phe GH5 of importance for hemoglobin intersubunit contact is mutated in gadoid fishNatural selection and neutral evolution jointly drive population divergence between alpine and lowland ecotypes of the allopolyploid plant Anemone multifida (Ranunculaceae)Whole mitochondrial genome scan for population structure and selection in the Atlantic herringPlastic and evolutionary responses to climate change in fishHigh evolutionary potential of marine zooplankton.Highly localized divergence within supergenes in Atlantic cod (Gadus morhua) within the Gulf of Maine.Upper thermal limits of the hearts of Arctic cod Boreogadus saida: adults compared with larvae.How fisheries management can benefit from genomics?Variation in spawning time promotes genetic variability in population responses to environmental change in a marine fishThermal growth potential of Atlantic cod by the end of the 21st century.Genomic divergence between the migratory and stationary ecotypes of Atlantic cod.Parallel adaptive evolution of geographically distant herring populations on both sides of the North Atlantic Ocean.Impact of life history traits on gene flow: A multispecies systematic review across oceanographic barriers in the Mediterranean Sea.Polymorphism, selection and tandem duplication of transferrin genes in Atlantic cod (Gadus morhua)--conserved synteny between fish monolobal and tetrapod bilobal transferrin lociMonitoring adaptive genetic responses to environmental change.Long distance linkage disequilibrium and limited hybridization suggest cryptic speciation in atlantic cod.Widespread signals of convergent adaptation to high altitude in Asia and americaEnvironmental selection on transcriptome-derived SNPs in a high gene flow marine fish, the Atlantic herring (Clupea harengus).Uninformative polymorphisms bias genome scans for signatures of selection.Contrasting patterns of genome-wide polymorphism in the native and invasive range of the marine mollusc Crepidula fornicata.Spatiotemporal SNP analysis reveals pronounced biocomplexity at the northern range margin of Atlantic cod Gadus morhua.Regional environmental pressure influences population differentiation in turbot (Scophthalmus maximus).Applications and implications of neutral versus non-neutral markers in molecular ecologyNucleotide variation and balancing selection at the Ckma gene in Atlantic cod: analysis with multiple merger coalescent models.Multiplexing with three-primer PCR for rapid and economical microsatellite validation.Population genomic evidence for adaptive differentiation in Baltic Sea three-spined sticklebacks.Juvenile habitat partitioning and relative productivity in allochronically isolated sockeye salmon (Oncorhynchus nerka)Two adjacent inversions maintain genomic differentiation between migratory and stationary ecotypes of Atlantic cod.Three chromosomal rearrangements promote genomic divergence between migratory and stationary ecotypes of Atlantic codHistorical changes in genotypic frequencies at the Pantophysin locus in Atlantic cod (Gadus morhua) in Icelandic waters: evidence of fisheries-induced selection?Population genomics of an endemic Mediterranean fish: differentiation by fine scale dispersal and adaptation.Outlier Loci Detect Intraspecific Biodiversity amongst Spring and Autumn Spawning Herring across Local Scales.Oceanographic connectivity and environmental correlates of genetic structuring in Atlantic herring in the Baltic Sea.Population genomics shed light on the demographic and adaptive histories of European invasion in the Pacific oyster, Crassostrea gigasIdentifying patterns of dispersal, connectivity and selection in the sea scallop, Placopecten magellanicus, using RADseq-derived SNPs.The coupling hypothesis: why genome scans may fail to map local adaptation genes.Ancient DNA reveals the Arctic origin of Viking Age cod from Haithabu, Germany.Sex matters in massive parallel sequencing: Evidence for biases in genetic parameter estimation and investigation of sex determination systems.
P2860
Q26781108-8C258E75-B667-49BA-A2A8-827FB1AB21B6Q28647437-C35506A6-6B76-4DB9-9206-863ED45D590CQ28658403-A4CEAEDD-B2C8-43A2-B538-A5B4C83764E1Q28677034-D80CC69E-BB41-4F83-B509-20B8B34A9734Q28709971-DBCD28AA-A5DD-4320-A104-8E011C493844Q30740373-B401CE2F-CBEF-4C74-8774-291F87686777Q30764360-5598F3D7-E6B2-444E-8ED1-F60BE115B682Q30843440-7C8940DD-209A-408F-A2F4-45F69AD47B74Q31028280-755B07F0-4491-4A21-9BB4-B8F07581886FQ31060973-F38151CD-4DC5-44CC-BBC2-24EF813D7C67Q31107676-154F17E8-4A77-4453-B963-72041C1249E6Q31112480-178CC6A6-93AB-423D-A1EF-0FEB06266540Q31136664-7332D7C1-7ACF-4D2A-9304-BC5C7C4BEB96Q33620093-FA9CA58E-29BF-4859-B86E-06013605A3E5Q33657177-CBBB1B94-E124-4CF3-9F51-D8263A47F08DQ33911730-962737AB-0B93-4DDF-8ADA-35F3599ADBB9Q34136085-553E4C36-077B-4BE1-8DBB-4C934F18F0CFQ34259001-6ECB3E59-5719-4C5F-BAE0-DB80F6CF4322Q34288700-DD1218BC-ADCF-4A44-9EE2-893C4BAB4B5FQ34302869-009E8225-7E7E-4B47-94CC-6C3C423DF708Q34315172-D63E618E-61A3-4FD5-B4EE-C9B1B815DE97Q34535819-4A653C66-B24A-424C-ACD2-DEBEDBF344F0Q34780203-B32F4B26-753C-4723-93AF-E8C3CD31E2ABQ35071935-54CDC991-9E03-4FA4-9396-69037FCC348EQ35091846-3B11741B-3BEE-47B1-BD2D-C3A1EEB57129Q35145937-505D1467-915F-481D-A0E6-FF4983EE27E7Q35209510-CBB77872-AA6A-4DBD-A525-7792D259284AQ35540650-AA559598-A2B5-4914-A91C-05D75D3C9423Q35780631-35DDF4AB-A41F-44F7-85CD-70D57CB5CB68Q35938747-28D87B05-55DE-4628-84F7-D1F333A11E86Q35959858-00271342-AB29-469A-AF9B-735E56387B39Q35960800-9A8CE1FD-0CC0-45FF-BF15-EEFFA4C52854Q36297947-68053CE6-CD9D-4F74-8B03-8CF869ADA99DQ36771447-CBF88FC0-1BA0-49EB-8729-AAE5B35D27EDQ36904975-9DE61258-D818-477A-A4B1-184F1D072EBFQ37244660-29579A4B-1840-446A-A65E-F24E2FC2A20EQ37539932-A40EC407-5064-45DA-9D6D-5A2615ED6A1BQ37863191-B659CE44-5F8F-466B-B9A1-858022C94050Q38368392-10F00704-8468-4674-9E2A-2C45AF0CDAD5Q38704386-74B3AF09-71D8-4C24-8CED-0B1ADC37B99F
P2860
Parallel adaptive evolution of Atlantic cod on both sides of the Atlantic Ocean in response to temperature.
description
2010 nî lūn-bûn
@nan
2010年の論文
@ja
2010年学术文章
@wuu
2010年学术文章
@zh
2010年学术文章
@zh-cn
2010年学术文章
@zh-hans
2010年学术文章
@zh-my
2010年学术文章
@zh-sg
2010年學術文章
@yue
2010年學術文章
@zh-hant
name
Parallel adaptive evolution of ...... an in response to temperature.
@en
Parallel adaptive evolution of ...... an in response to temperature.
@nl
type
label
Parallel adaptive evolution of ...... an in response to temperature.
@en
Parallel adaptive evolution of ...... an in response to temperature.
@nl
prefLabel
Parallel adaptive evolution of ...... an in response to temperature.
@en
Parallel adaptive evolution of ...... an in response to temperature.
@nl
P2093
P2860
P356
P1476
Parallel adaptive evolution of ...... ean in response to temperature
@en
P2093
Brent Higgins
Chris T Taggart
Corey J Morris
Daniel E Ruzzante
David C Hardie
Ian G Paterson
Ian R Bradbury
Paul Bentzen
Paul V R Snelgrove
Robert S Gregory
P2860
P304
P356
10.1098/RSPB.2010.0985
P577
2010-06-30T00:00:00Z