Highly conserved low-copy nuclear genes as effective markers for phylogenetic analyses in angiosperms.
about
Phylogenomic analyses of nuclear genes reveal the evolutionary relationships within the BEP clade and the evidence of positive selection in PoaceaeThe Amborella Genome and the Evolution of Flowering PlantsTelling plant species apart with DNA: from barcodes to genomesPolyploidy-associated genome modifications during land plant evolutionMultiple Polyploidization Events across Asteraceae with Two Nested Events in the Early History Revealed by Nuclear PhylogenomicsComparative Transcriptome and Chloroplast Genome Analyses of Two Related Dipteronia SpeciesPlastid Phylogenomic Analyses Resolve Tofieldiaceae as the Root of the Early Diverging Monocot Order AlismatalesResolution of Brassicaceae Phylogeny Using Nuclear Genes Uncovers Nested Radiations and Supports Convergent Morphological EvolutionSynteny analysis in Rosids with a walnut physical map reveals slow genome evolution in long-lived woody perennialsA genome-scale mining strategy for recovering novel rapidly-evolving nuclear single-copy genes for addressing shallow-scale phylogenetics in HydrangeaGenome-wide analysis reveals diverged patterns of codon bias, gene expression, and rates of sequence evolution in picea gene familiesInfrageneric phylogeny and temporal divergence of Sorghum (Andropogoneae, Poaceae) based on low-copy nuclear and plastid sequencesResolution of deep angiosperm phylogeny using conserved nuclear genes and estimates of early divergence timesPhylogeny and divergence times of gymnosperms inferred from single-copy nuclear genesSingle-copy nuclear genes place haustorial Hydnoraceae within piperales and reveal a cretaceous origin of multiple parasitic angiosperm lineagesPhylogeny of the cycads based on multiple single-copy nuclear genes: congruence of concatenated parsimony, likelihood and species tree inference methodsAdvances in the floral structural characterization of the major subclades of Malpighiales, one of the largest orders of flowering plantsEvolution of Rosaceae Fruit Types Based on Nuclear Phylogeny in the Context of Geological Times and Genome Duplication.Another look at the root of the angiosperms reveals a familiar tale.Widespread and frequent horizontal transfers of transposable elements in plantsCoalescent versus concatenation methods and the placement of Amborella as sister to water lilies.Genomic repeat abundances contain phylogenetic signal.Comparative transcriptome resources of eleven Primulina species, a group of 'stone plants' from a biodiversity hot spot.A metacalibrated time-tree documents the early rise of flowering plant phylogenetic diversity.Genome size shifts: karyotype evolution in Crepis section Neglectoides (Asteraceae).Comparative transcriptome resources of two Dysosma species (Berberidaceae) and molecular evolution of the CYP719A gene in Podophylloideae.Congruent Deep Relationships in the Grape Family (Vitaceae) Based on Sequences of Chloroplast Genomes and Mitochondrial Genes via Genome Skimming.Mining from transcriptomes: 315 single-copy orthologous genes concatenated for the phylogenetic analyses of Orchidaceae.Assembled Plastid and Mitochondrial Genomes, as well as Nuclear Genes, Place the Parasite Family Cynomoriaceae in the Saxifragales.Conservation of the abscission signaling peptide IDA during Angiosperm evolution: withstanding genome duplications and gain and loss of the receptors HAE/HSL2.Plastome phylogeny and early diversification of BrassicaceaeResolution of deep eudicot phylogeny and their temporal diversification using nuclear genes from transcriptomic and genomic datasets.Establishment of transient gene expression systems in protoplasts from Liriodendron hybrid mesophyll cells.ASTRAL-II: coalescent-based species tree estimation with many hundreds of taxa and thousands of genes.Fast Coalescent-Based Computation of Local Branch Support from Quartet Frequencies.Bioinformatics Approach in Plant Genomic Research.A Genome-Scale Investigation of How Sequence, Function, and Tree-Based Gene Properties Influence Phylogenetic InferencePlastid Phylogenomics Resolve Deep Relationships among Eupolypod II Ferns with Rapid Radiation and Rate Heterogeneity.Single-Copy Genes as Molecular Markers for Phylogenomic Studies in Seed Plants.Molecular Phylogenetics: Concepts for a Newcomer.
P2860
Q21559625-D17FAFC5-1A2C-4904-8C9E-8FA14D2FCC5FQ22065597-2CBD1B09-3A54-43CC-9DD0-E65BE14FD630Q26740119-967485C5-9FD5-4CF0-BFA1-DBB9D4C84541Q26866243-3DD1B722-115D-4D06-A1BA-243F3A9B2405Q28597678-ABCAD96B-2A0F-4383-B3CD-6CF001E2BA3CQ28597696-688E710F-7786-4DA4-8CD0-513C6D3BCEA1Q28601045-047231C1-002D-4DB9-9023-9C296F0659C1Q28602804-517DDF65-DD94-492D-96CD-F9CA40DC73D3Q28607516-B9389DC1-FE0B-4373-9058-BA5F2B9BF496Q28647587-CBC66614-9957-4391-B706-E19227A5CFF6Q28648066-7C6BCC63-B014-4651-8D87-481FF78E7FE6Q28654540-CB27D8C3-6BC1-49B3-AFA4-80893218C86EQ28654622-4A3E279F-C1BD-4B6D-8160-F053F8A22FF1Q28655754-3E0F8352-3FF8-4255-9687-2DDBB5142C6AQ28661619-A0CD1129-22E9-4C42-B275-D0C20C659FC5Q28662197-B72C3D27-197D-4897-8D00-3306C533F5BEQ28708907-656F5A13-EBD3-436C-8E47-E261CF3BCBD3Q33590746-3D16AF81-D9E4-443A-92D8-2CA2E8B95B2AQ34395825-82342156-3C5B-46F7-8152-C1663CF9AE05Q34403633-2FE3362A-0BC2-4612-B4F1-E5065C1CC469Q34431575-BA1C974D-F368-45E0-AF55-9ECF103A6B75Q34692463-94D178B2-F896-4586-8627-4EBC549639CEQ35268761-7EEE23D5-C671-4769-BF15-F3D46148605DQ35547985-DB6F11B5-6E92-4A89-9A40-9D855E8773C4Q35561742-4AF19334-8362-4DF4-B522-76388B34C071Q35603070-AA10400E-9DC7-4B8B-A537-95D274FC6107Q35866229-0F64D4CE-EFC0-4533-B87A-7A6419C8777BQ36054185-E3D233A6-4845-4002-87D9-B37CD5225946Q36064493-2A6D2EE0-AFA4-4676-8726-6AA4BE978AD8Q36232202-40D100BF-A433-495F-9E0F-5CF227A3EA7AQ36283273-6F47A56C-4659-4625-BFC3-55DB63C889A5Q36308252-17D63A1C-9223-471F-90F6-C8E82AB1ACACQ36316560-B9DCDFC5-3480-43D1-B72F-1CAD46FCDA84Q36614037-0757CB11-49E4-4A10-8BBC-AD0B9D5C86F7Q37025084-ECA54C10-0B4B-48EC-9781-38F798774F93Q37112910-01915452-FBD9-433E-83D6-7A8B4486B8F0Q37231281-2E3424A3-3A5A-45CE-80E0-C97344199734Q38367920-E638D31D-44ED-40CB-BAA9-E6625D4A8B8EQ38810987-EA2829CA-CF0A-4F3F-BBCE-A467A8380298Q38991249-0C6C6288-BE16-4C8C-8F8F-1FCA2675481A
P2860
Highly conserved low-copy nuclear genes as effective markers for phylogenetic analyses in angiosperms.
description
2012 nî lūn-bûn
@nan
2012年の論文
@ja
2012年学术文章
@wuu
2012年学术文章
@zh-cn
2012年学术文章
@zh-hans
2012年学术文章
@zh-my
2012年学术文章
@zh-sg
2012年學術文章
@yue
2012年學術文章
@zh
2012年學術文章
@zh-hant
name
Highly conserved low-copy nucl ...... netic analyses in angiosperms.
@en
Highly conserved low-copy nucl ...... netic analyses in angiosperms.
@nl
type
label
Highly conserved low-copy nucl ...... netic analyses in angiosperms.
@en
Highly conserved low-copy nucl ...... netic analyses in angiosperms.
@nl
prefLabel
Highly conserved low-copy nucl ...... netic analyses in angiosperms.
@en
Highly conserved low-copy nucl ...... netic analyses in angiosperms.
@nl
P2093
P2860
P1433
P1476
Highly conserved low-copy nucl ...... netic analyses in angiosperms.
@en
P2093
Hongyan Shan
Liping Zeng
Ning Zhang
P2860
P304
P356
10.1111/J.1469-8137.2012.04212.X
P407
P577
2012-07-11T00:00:00Z