about
The theory of facilitated variationCryptic genetic variation is enriched for potential adaptationsCompensatory evolution and the origins of innovationsRobustness and evolvabilityPhenotypic Novelty in EvoDevo: The Distinction Between Continuous and Discontinuous Variation and Its Importance in Evolutionary TheoryMolecular mechanisms of robustness in plantsEpistasis and quantitative traits: using model organisms to study gene-gene interactionsPlasticity-mediated persistence in new and changing environmentsDevelopment and evolution of character displacementHsp90 selectively modulates phenotype in vertebrate developmentRole of pleiotropy in the evolution of a cryptic developmental variation in Caenorhabditis elegansDoes your gene need a background check? How genetic background impacts the analysis of mutations, genes, and evolutionModular Brain NetworksMechanisms of mutational robustness in transcriptional regulationEffects of ploidy and recombination on evolution of robustness in a model of the segment polarity networkNatural variation in the strength and direction of male mating preferences for female pheromones in Drosophila melanogasterNatural Variation Identifies ICARUS1, a Universal Gene Required for Cell Proliferation and Growth at High Temperatures in Arabidopsis thalianaEcophenotypic Variation and Developmental Instability in the Late Cretaceous Echinoid Micraster brevis (Irregularia; Spatangoida)The Relationship between Gene Network Structure and Expression Variation among Individuals and SpeciesDegeneracy allows for both apparent homogeneity and diversification in populationsBiological robustness: paradigms, mechanisms, and systems principlesT Cell Adaptive Immunity Proceeds through Environment-Induced Adaptation from the Exposure of Cryptic Genetic VariationThe genetic architecture of skeletal convergence and sex determination in ninespine sticklebacksThe gene balance hypothesis: implications for gene regulation, quantitative traits and evolutionStress-induced variation in evolution: from behavioural plasticity to genetic assimilationEvolutionary response when selection and genetic variation covary across environments.Early developmental conditioning of later health and disease: physiology or pathophysiology?Widespread genomic incompatibilities in Caenorhabditis elegans.The quantitative genetics of sexually selected traits, preferred traits and preference: a review and analysis of the data.Genetic assimilation: a review of its potential proximate causes and evolutionary consequences.Gene expression profiling of the green seed problem in Soybean.Histone variant HTZ1 shows extensive epistasis with, but does not increase robustness to, new mutations.Genomic Characterization of the Evolutionary Potential of the Sea Urchin Strongylocentrotus droebachiensis Facing Ocean AcidificationA single basis for developmental buffering of Drosophila wing shapeThreshold-dominated regulation hides genetic variation in gene expression networksGenetical genomics: spotlight on QTL hotspotsThe Drosophila foraging gene mediates adult plasticity and gene-environment interactions in behaviour, metabolites, and gene expression in response to food deprivation.Chromosomal loci important for cotyledon opening under UV-B in Arabidopsis thaliana.Cryptic variation between species and the basis of hybrid performanceTransient genotype-by-environment interactions following environmental shock provide a source of expression variation for essential genes
P2860
Q22066347-00BC64D5-0845-471D-A4DF-0E4980077187Q24545852-ED27C838-63B1-424A-BB41-CEC27E8EC775Q24600021-88129D76-583B-4F4C-BA2A-ABB78084B9E4Q24634833-15D61DBF-2DB6-477E-91F0-0C7A4167087FQ26779598-2C783C81-4C72-48DD-B57F-C38995F240F5Q26822913-3747657F-21A7-4E9C-85BC-0AAC3EF0424AQ26824140-B04227E4-9D6C-4FA4-8DFE-25744D08E57EQ26863269-0D215481-BF35-4C06-8AC6-628B3C6FED6BQ27010287-DF90216A-3581-4148-BFD3-95EEFDA30558Q27314993-5D5753B1-11FD-4CF4-8D17-8DC18E128B83Q27320539-726BFD6E-2027-42D1-97FE-1AF0CBD6C4DBQ27693280-3B34D814-EA6B-40EC-BC3C-0EC05E569A95Q28081428-AE44C043-193F-49D2-BB0F-D903F5221857Q28082759-03E4EC70-BAE0-4E81-96D2-F96BDC422A08Q28474766-655105B2-153E-46AC-92FA-5083C2C2381AQ28539255-0C4AF0F0-D0A0-4CA8-AD76-13072C9F7F43Q28547076-68C5011C-C722-4850-A482-9DC9964C4A98Q28601176-83748112-9F65-40B6-9C48-4C838EB7B6F2Q28608333-E0A9625B-BE6B-439E-927A-088DBBEE0773Q28673578-37FFB271-4FCA-487F-844D-58B4EE70B843Q28730028-D0A1D43E-4743-4A29-9033-A21944E3B1A8Q28732174-BE91F3FA-89D4-46DF-BA44-B3306D8F9956Q28751792-AD7C8DD2-C1BA-4925-B021-D2113E439672Q28752488-53914811-3083-4AF1-89EB-11DD033E6031Q28767873-5A758E1C-EA65-4E38-BE61-F97857853CBBQ30276106-013FC054-E021-4C55-97BF-FC822945A55AQ30387485-B49E20FC-2354-4122-A3A7-B3F8263EF13AQ30593069-13B5BC54-F579-4747-9067-FC036D831D15Q30855674-4D9BD845-5F33-49E9-A5AC-2961D121409BQ30992984-70537156-9314-4EC7-9596-4718111F3FE9Q31041739-2AE21C2A-D80B-42DE-A653-0808A4C480C3Q31130020-D2FB3D8B-3242-4ECE-977D-08FA8FAD3C77Q31154472-FC8A3067-FC67-4792-8F56-38826236E594Q33267330-6362BBB8-C5CC-4102-9AF1-42F4AC47CA37Q33308922-D2129310-131C-40DB-B5E9-0D90D6FC3398Q33379081-A00EAB9B-C8EC-4442-AD74-15220FDA8CA0Q33495554-1C125CBE-E551-4E08-88E9-84B9017BC692Q33610723-1CE75D91-A86C-4AE5-9798-DFCE0A565183Q33638416-27FE7D37-E113-4F22-914D-7BA2E5ACCD0AQ33688918-62AAE3D4-1957-48C4-9C00-DCFACE4889A2
P2860
description
2004 nî lūn-bûn
@nan
2004年の論文
@ja
2004年論文
@yue
2004年論文
@zh-hant
2004年論文
@zh-hk
2004年論文
@zh-mo
2004年論文
@zh-tw
2004年论文
@wuu
2004年论文
@zh
2004年论文
@zh-cn
name
Uncovering cryptic genetic variation.
@ast
Uncovering cryptic genetic variation.
@en
type
label
Uncovering cryptic genetic variation.
@ast
Uncovering cryptic genetic variation.
@en
prefLabel
Uncovering cryptic genetic variation.
@ast
Uncovering cryptic genetic variation.
@en
P356
P1476
Uncovering cryptic genetic variation
@en
P2093
Greg Gibson
P2888
P304
P356
10.1038/NRG1426
P50
P577
2004-09-01T00:00:00Z