about
Ancient evolutionary trade-offs between yeast ploidy statesTrait variation in yeast is defined by population historyConcerted evolution of life stage performances signals recent selection on yeast nitrogen use.Disentangling genetic and epigenetic determinants of ultrafast adaptationGenotype-Phenotype Map Characteristics of an In silico Heart CellMulti-way metamodelling facilitates insight into the complex input-output maps of nonlinear dynamic modelsA computational pipeline for quantification of mouse myocardial stiffness parametersNonlinear regulation enhances the phenotypic expression of trans-acting genetic polymorphismsThreshold-dominated regulation hides genetic variation in gene expression networksAllele interaction--single locus genetics meets regulatory biologyTowards a quantitative understanding of the MITF-PIAS3-STAT3 connectionParameters in dynamic models of complex traits are containers of missing heritability.The Atlantic salmon genome provides insights into rediploidization.Bridging the genotype-phenotype gap: what does it take?Towards causally cohesive genotype-phenotype modelling for characterization of the soft-tissue mechanics of the heart in normal and pathological geometries.Monotonicity is a key feature of genotype-phenotype maps.Life-stage associated remodeling of lipid metabolism regulation in Atlantic salmon.Order-preserving principles underlying genotype-phenotype maps ensure high additive proportions of genetic variance.Transcriptional development of phospholipid and lipoprotein metabolism in different intestinal regions of Atlantic salmon (Salmo salar) fry.Loss of function mutations in essential genes cause embryonic lethality in pigsPower of QTL mapping experiments in commercial Atlantic salmon populations, exploiting linkage and linkage disequilibrium and effect of limited recombination in males
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Q21092412-57BB2012-582F-465B-BF11-004315D4656CQ21144951-69F06C30-15D6-4189-A796-EDA77B804532Q27938036-08AC610D-7C42-40A7-BB67-CFAA2A72D3ABQ28584571-9CB5DCC2-80D9-4E5E-B5FC-3D5EA4283D26Q28740827-83A0AA96-6F13-4588-8930-A384A78D7107Q30527792-D3C98A39-D16A-41E3-B8EE-027ADDB16A09Q30671085-E6D0FFC9-5E69-4D27-932D-537EF6DC6AA6Q33291673-CC0793CA-269A-4822-8CE9-CAA26E553195Q33308922-83FE6749-1779-4B94-8EBF-E16E04D3FEE2Q33534703-A5405F08-552A-4488-967D-9C44196432ACQ34153534-304B633F-6359-4218-9BBF-D9B91070F78EQ34229563-08F92921-8ED6-4BA8-89AD-781495FAD290Q35992393-CFCB11E7-2DBD-4AAB-85CC-B1F5AEABFE5CQ38080836-90DB44F5-3E87-496E-9863-8316F4655678Q40442620-7B7FA605-8121-4728-9D2E-9F1F5ED4E0A5Q42919531-07E42B4D-0A25-4377-A409-D27BFBF60A9DQ50065259-E9B5D587-D570-4B06-9CBB-7E754440049AQ51540888-26AF932B-08FD-40CF-AF9C-19F52B6B20AFQ55379842-FB345B65-209A-4A2F-92C8-459B7022A666Q64090169-3DDF84E9-4970-4783-9EF9-259DB9329B54Q83311323-ED9FE68C-0E40-48D2-A09C-CDB5E93AD23C
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description
researcher
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wetenschapper
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հետազոտող
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name
Arne B Gjuvsland
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Arne B Gjuvsland
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Arne B Gjuvsland
@es
Arne B Gjuvsland
@nl
type
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Arne B Gjuvsland
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Arne B Gjuvsland
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Arne B Gjuvsland
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Arne B Gjuvsland
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prefLabel
Arne B Gjuvsland
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Arne B Gjuvsland
@en
Arne B Gjuvsland
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Arne B Gjuvsland
@nl
P106
P2456
P31
P496
0000-0002-4391-3411