about
Natural Genetic Variation and Candidate Genes for Morphological Traits in Drosophila melanogasterReticulation, divergence, and the phylogeography-phylogenetics continuumThe Impact of Reconstruction Methods, Phylogenetic Uncertainty and Branch Lengths on Inference of Chromosome Number Evolution in American Daisies (Melampodium, Asteraceae)Fitness consequences of polymorphic inversions in the zebra finch genomeConstruction of Ultradense Linkage Maps with Lep-MAP2: Stickleback F2 Recombinant Crosses as an ExampleGenetic differentiation and evolutionary adaptation in Cryptomeria japonicaMolecular cytogenetic and genomic insights into chromosomal evolutionCaenorhabditis briggsae recombinant inbred line genotypes reveal inter-strain incompatibility and the evolution of recombinationHow much can history constrain adaptive evolution? A real-time evolutionary approach of inversion polymorphisms in Drosophila subobscura.Following the footprints of polymorphic inversions on SNP data: from detection to association tests.The 8p23 inversion polymorphism determines local recombination heterogeneity across human populationsIdentifying the genes underlying quantitative traits: a rationale for the QTN programmeUnprecedented within-species chromosome number cline in the Wood White butterfly Leptidea sinapis and its significance for karyotype evolution and speciation.Patterns and mechanisms of evolutionary transitions between genetic sex-determining systems.Divergent population structure and climate associations of a chromosomal inversion polymorphism across the Mimulus guttatus species complexEmerging knowledge from genome sequencing of crop species.Y-chromosome evolution: emerging insights into processes of Y-chromosome degenerationGene alterations at Drosophila inversion breakpoints provide prima facie evidence for natural selection as an explanation for rapid chromosomal evolutionIdentification of polymorphic inversions from genotypes.Integration of the genetic map and genome assembly of fugu facilitates insights into distinct features of genome evolution in teleosts and mammals.Investigation of inversion polymorphisms in the human genome using principal components analysisA supergene determines highly divergent male reproductive morphs in the ruff.The genetic content of chromosomal inversions across a wide latitudinal gradient.Chromosome inversions, genomic differentiation and speciation in the African malaria mosquito Anopheles gambiae.The genetics of divergence and reproductive isolation between ecotypes of Panicum hallii.Patterns of genetic variation across inversions: geographic variation in the In(2L)t inversion in populations of Drosophila melanogaster from eastern Australia.The effect of inversion at 8p23 on BLK association with lupus in Caucasian populationNext-generation sequencing, FISH mapping and synteny-based modeling reveal mechanisms of decreasing dysploidy in Cucumis.Validation and genotyping of multiple human polymorphic inversions mediated by inverted repeats reveals a high degree of recurrence.Transposable elements as agents of rapid adaptation may explain the genetic paradox of invasive species.The devil is in the details: genetic variation in introduced populations and its contributions to invasion.A recombination suppressor contributes to ecological speciation in OSTRINIA moths.Adaptive Role of Inversion Polymorphism of Drosophila subobscura in Lead Stressed Environment.Genetic panmixia within a narrow contact zone between chromosomally and ecologically distinct black fly sibling species (Diptera: Simuliidae).Recombination of chl-fus gene (Plastid Origin) downstream of hop: a locus of chromosomal instability.Scrambling eggs: meiotic drive and the evolution of female recombination rates.Functional Impact and Evolution of a Novel Human Polymorphic Inversion That Disrupts a Gene and Creates a Fusion Transcript.Where's the money? Inversions, genes, and the hunt for genomic targets of selectionSegmental duplication, microinversion, and gene loss associated with a complex inversion breakpoint region in Drosophila.Exploiting genotyping by sequencing to characterize the genomic structure of the American cranberry through high-density linkage mapping
P2860
Q26315226-6F8766AC-8663-4A84-9C2A-0F5577588A67Q27316290-7A06EC17-5C4B-4AB7-A5FC-0463ED0CC6B2Q28596002-B1BFA60E-2683-49B8-9467-82D15D333C64Q28598120-D0C7D685-8AF3-44AA-BDEC-FFCDB736C0EBQ28604114-FE839065-B229-4989-8ECE-26C2FB9E6B44Q28649682-BBFC4970-93A5-4602-A75F-052166B722A0Q28741422-D2B2516D-1DE5-49D5-8A6F-24D9EF222885Q28742637-7DBAC6CD-8991-4DE6-A962-74836CA0EC61Q30872273-8B33DB52-1A6B-4974-87FB-2C1088D08FA1Q30891383-72C3FC92-E087-447B-BAD7-46DB363BE57EQ33556713-5EB15EB1-E0AD-45E9-A375-FDFFC75AABAFQ33685340-D44EF08B-FFD2-438F-8B08-DB505629598BQ33877877-18EEA5AA-6F1B-4CE5-996B-065DDE4DFB50Q33938593-4F337457-F7AA-44A9-BDE4-7914F59EF32DQ33950843-D9769C38-A2D8-48CB-A83A-F08941B933A0Q33984893-8D126A04-DC25-4AEE-B0CC-B30C4A63CA02Q33996690-4C6D3117-5075-4D4E-994A-7B9B91601C36Q34148263-92E2FE51-7AB3-4E5D-AB9A-7BE9739A4A04Q34155398-8D9E771B-6710-4CF2-A1F4-C2D0F2EE4F85Q34183424-14FB50C3-3406-4CCC-88CE-B3EDD1C93038Q34341880-79E2B73D-186A-4778-8013-2D6C2208784BQ34501835-25748C6A-7366-47B6-81E2-7D62F7DAFD97Q34525393-A7B09C4D-C0F8-4CE2-9C32-05F174D5B5DBQ34634025-08677590-6F09-411E-BEE1-72544A9A5E20Q34693533-3C6EB428-6EF8-4252-9409-59E24F7A2230Q34728888-4BA9E112-0C14-430A-9968-759C373ACEC7Q34783230-58093D86-61B8-47CB-9201-A028C0E641EDQ35017625-DE32DBDD-F72F-4EB3-A3F5-A0B65FA2FD1BQ35126612-0E85C15B-8A40-4B4B-BD88-21416B88F005Q35547265-C5FD5373-207D-4404-ABB3-61A7D6E47BD1Q35595754-90DF8F9A-FFA4-45CA-A9C0-B0BA7BD9E5E0Q35614525-5AE5813B-B131-4F5E-9D4E-5CB11FCCD68EQ35671706-377060DF-6E55-4CC0-BACA-4617C0F05BC7Q35673379-1D262446-9866-4E69-8541-AB9CAA063E69Q35735575-544B039A-91F9-43EB-9306-BFA04848CE29Q35748191-62460E47-A761-4C9E-B084-6CD50D13F908Q35795357-06EA76B5-50D2-432D-80C7-9C1556CE8035Q35863022-5AEC1990-A3C7-4B58-A9E7-E1277FC0C498Q36032967-8AF5389A-0336-4013-A58C-5A23C53ED2EDQ36050689-B72BFB46-A0C3-41A0-88A8-AEA62D0EA4DA
P2860
description
2010 nî lūn-bûn
@nan
2010 թուականի Սեպտեմբերին հրատարակուած գիտական յօդուած
@hyw
2010 թվականի սեպտեմբերին հրատարակված գիտական հոդված
@hy
2010年の論文
@ja
2010年論文
@yue
2010年論文
@zh-hant
2010年論文
@zh-hk
2010年論文
@zh-mo
2010年論文
@zh-tw
2010年论文
@wuu
name
How and why chromosome inversions evolve.
@ast
How and why chromosome inversions evolve.
@en
type
label
How and why chromosome inversions evolve.
@ast
How and why chromosome inversions evolve.
@en
prefLabel
How and why chromosome inversions evolve.
@ast
How and why chromosome inversions evolve.
@en
P2860
P1433
P1476
How and why chromosome inversions evolve.
@en
P2093
Mark Kirkpatrick
P2860
P356
10.1371/JOURNAL.PBIO.1000501
P407
P577
2010-09-28T00:00:00Z