Hybridization reveals the evolving genomic architecture of speciation
about
Linked selection and recombination rate variation drive the evolution of the genomic landscape of differentiation across the speciation continuum of Ficedula flycatchersEvolution of heterogeneous genome differentiation across multiple contact zones in a crow species complexMultilocus species trees show the recent adaptive radiation of the mimetic heliconius butterfliesAdaptive introgression between Anopheles sibling species eliminates a major genomic island but not reproductive isolationSignatures of Archaic Adaptive Introgression in Present-Day Human Populations.Population genomics of parallel hybrid zones in the mimetic butterflies, H. melpomene and H. eratoAssessing when chromosomal rearrangements affect the dynamics of speciation: implications from computer simulations.Evaluating the use of ABBA-BABA statistics to locate introgressed loci.Why and how might genetic and phylogenetic diversity be reflected in the identification of key biodiversity areas?Phylogeography of Heliconius cydno and its closest relatives: disentangling their origin and diversification.The functional basis of wing patterning in Heliconius butterflies: the molecules behind mimicry.The diversification of Heliconius butterflies: what have we learned in 150 years?Divergence with gene flow across a speciation continuum of Heliconius butterflies.Evolutionary Patterns and Processes: Lessons from Ancient DNA.Consequences of divergence and introgression for speciation in Andean cloud forest birds.Genome-wide introgression among distantly related Heliconius butterfly species.Natural Selection and Genetic Diversity in the Butterfly Heliconius melpomene.The comparative landscape of duplications in Heliconius melpomene and Heliconius cydno.A neutral view of the evolving genomic architecture of speciation.Evolution of novel mimicry rings facilitated by adaptive introgression in tropical butterflies.Making sense of genomic islands of differentiation in light of speciation.Efficient Strategies for Calculating Blockwise Likelihoods Under the Coalescent.Divergence history of the Carpathian and smooth newts modelled in space and time.The complete mitogenome of the Cydno Longwing Heliconius cydno (Insecta: Lepidoptera: Nymphalidae).The complete mitochondrial genome of Heliconius pachinus (Insecta: Lepidoptera: Nymphalidae).The complete mitochondrial genome sequence of Heliconius hecale (Insecta: Lepidoptera: Nymphalidae).Can genomic data alone tell us whether speciation happened with gene flow?Introgression between divergent corn borer species in a region of sympatry: Implications on the evolution and adaptation of pest arthropods.Hybrids and horizontal transfer: introgression allows adaptive allele discovery.Genomic differentiation and patterns of gene flow between two long-tailed tit species (Aegithalos).Speciation, species persistence and the goals of studying genomic barriers to gene flow.A test of genomic modularity among life-history adaptations promoting speciation with gene flow.Quantified reproductive isolation in Heliconius butterflies: Implications for introgression and hybrid speciation.RNA Interference Pathways Display High Rates of Adaptive Protein Evolution in Multiple Invertebrates.Patterns of Z chromosome divergence among Heliconius species highlight the importance of historical demography.Genome-scale portrait and evolutionary significance of human-specific core promoter tri- and tetranucleotide short tandem repeats.Hybridization and gene flow in the mega-pest lineage of moth, Helicoverpa.Transitions from Single- to Multi-Locus Processes during Speciation with Gene Flow.No evidence for maintenance of a sympatric species barrier by chromosomal inversions
P2860
Q22065760-E625C10C-EB54-4AF9-A683-224F53541F80Q28314914-BE38D5EB-3D56-410F-999E-E684AF854819Q28649720-4F181EEA-AA82-4290-A6F6-3932A3EEB4A4Q31075931-7AB65604-EA83-48D0-AFDD-182324C57339Q33590851-24714F49-B415-4F77-91BF-C5B86A2989FCQ33994836-9A1B58F5-3373-4687-9B0C-133C09399C57Q34087588-93075136-3F98-4899-9640-2026C1718FDDQ34740681-5A3EFFEC-4B88-4B83-B507-B8B539FEBD8FQ34911598-5E7582FE-B7FC-4B0A-9EE1-C346E706AA5DQ35194317-FC8F5877-21DC-4F7F-A303-4D3ACCCCE7FAQ35579764-EBEE8680-23FD-4D0F-8139-1F8E08D16085Q35664966-37E04E75-167F-4E65-BA07-C4F3CA0359D5Q35786984-CDECFF10-ECE3-4C74-BC14-5EC9802E146DQ36273126-CA290E56-3670-46EF-B55B-4CF7FE4A0BAFQ36344357-DB427F69-859E-4F3E-AF3D-DFD57AE8E60DQ36625666-6DA19123-1B22-4707-A0CD-978F65901F3FQ36875695-E90DF7D5-1A34-4C3A-90BE-668B07674728Q37524442-CC540770-8532-466F-AB0C-9F8DE29F45EBQ38598741-8B37BFA1-64B0-4A5E-8CA0-F92630186BE8Q38640589-91AB8A81-7AF5-46FA-9D3B-D83FA3C5C686Q38795762-A31DFA55-31B4-4351-A346-4E157294F68EQ38942691-2448CC04-5323-4811-AD7F-421D7D726236Q39691292-9A9D0B8C-2C6C-4E78-A4D9-27A38268B36BQ42001947-C6492EAD-7515-4A51-8C19-5A1A6B0BD15FQ42002235-C1503802-70C3-4C78-A799-CE105BA7F6E8Q42002240-A637ABDB-779F-44B6-AC53-078BAB7B3E22Q44918344-C9639129-2E4F-49B8-88BA-43342FE6F9CCQ46268285-C562F9C8-67CE-4406-8C89-6E22F6B93FF9Q46270112-C157CBB3-B6E4-4C14-AEC7-C9C97A3F9AB7Q46278661-1E66E260-6AA5-437B-9615-5CBED5C756B6Q46324319-C0A529CD-0F0D-4773-816D-BE13D6EC9F54Q48148547-135E8683-2980-4695-AAD0-26B0C78F95FAQ48155353-69B02433-C307-47B1-9FB8-7496995104F0Q50043723-3A5CBAE0-4AC3-44A7-AEDC-E2D170EBBF8BQ51145552-A6F73E7E-6BD7-4875-993C-41BF9908126AQ52604129-3A7807F1-0D24-43BF-BF6A-ABAE08FC2696Q52611907-3895AEFE-377E-4583-83DB-321009B5C78BQ55617698-40914F38-9230-40B4-A36F-F990066B0338Q57153210-0BF0B6E8-24D6-4740-A01E-B298BCB9B437
P2860
Hybridization reveals the evolving genomic architecture of speciation
description
2013 nî lūn-bûn
@nan
2013 թուականի Հոկտեմբերին հրատարակուած գիտական յօդուած
@hyw
2013 թվականի հոտեմբերին հրատարակված գիտական հոդված
@hy
2013年の論文
@ja
2013年学术文章
@wuu
2013年学术文章
@zh-cn
2013年学术文章
@zh-hans
2013年学术文章
@zh-my
2013年学术文章
@zh-sg
2013年學術文章
@yue
name
Hybridization reveals the evolving genomic architecture of speciation
@ast
Hybridization reveals the evolving genomic architecture of speciation
@en
type
label
Hybridization reveals the evolving genomic architecture of speciation
@ast
Hybridization reveals the evolving genomic architecture of speciation
@en
prefLabel
Hybridization reveals the evolving genomic architecture of speciation
@ast
Hybridization reveals the evolving genomic architecture of speciation
@en
P2093
P2860
P1433
P1476
Hybridization reveals the evolving genomic architecture of speciation
@en
P2093
Durrell D Kapan
Marcus R Kronforst
Matthew E B Hansen
Nicholas G Crawford
Rob J Kulathinal
Sean P Mullen
P2860
P304
P356
10.1016/J.CELREP.2013.09.042
P577
2013-10-31T00:00:00Z