Modeling protein evolution with several amino acid replacement matrices depending on site rates.
about
Entorrhizomycota: A New Fungal Phylum Reveals New Perspectives on the Evolution of FungiCauses of evolutionary rate variation among protein sitesThe plastid genome of some eustigmatophyte algae harbours a bacteria-derived six-gene cluster for biosynthesis of a novel secondary metaboliteExploring Phylogenetic Relationships within Myriapoda and the Effects of Matrix Composition and Occupancy on Phylogenomic ReconstructionProbabilistic models of eukaryotic evolution: time for integrationNuclear genomic signals of the 'microturbellarian' roots of platyhelminth evolutionary innovationPhylogenomic resolution of scorpions reveals multilevel discordance with morphological phylogenetic signalRAxML version 8: a tool for phylogenetic analysis and post-analysis of large phylogeniesImproving evolutionary models for mitochondrial protein data with site-class specific amino acid exchangeability matricesHeme pathway evolution in kinetoplastid protistsXenacoelomorpha is the sister group to NephrozoaAn ancestral bacterial division system is widespread in eukaryotic mitochondria.Evaluating topological conflict in centipede phylogeny using transcriptomic data sets.Genome-wide analysis of gene expression and protein secretion of Babesia canis during virulent infection identifies potential pathogenicity factors.Reconstruction of cyclooxygenase evolution in animals suggests variable, lineage-specific duplications, and homologs with low sequence identity.Phylogenomics Using Transcriptome Data.Evolution of the 3R-MYB Gene Family in Plants.Improved mitochondrial amino acid substitution models for metazoan evolutionary studies.Palpitomonas bilix represents a basal cryptist lineage: insight into the character evolution in CryptistaChloroplast phylogenomic analysis resolves deep-level relationships within the green algal class Trebouxiophyceae.Six newly sequenced chloroplast genomes from prasinophyte green algae provide insights into the relationships among prasinophyte lineages and the diversity of streamlined genome architecture in picoplanktonic species.Phylogenomic interrogation of arachnida reveals systemic conflicts in phylogenetic signal.Chromerid genomes reveal the evolutionary path from photosynthetic algae to obligate intracellular parasites.Support for Lungfish as the Closest Relative of Tetrapods by Using Slowly Evolving Ray-Finned Fish as the OutgroupA dimeric chlorite dismutase exhibits O2-generating activity and acts as a chlorite antioxidant in Klebsiella pneumoniae MGH 78578.Superiority of a mechanistic codon substitution model even for protein sequences in phylogenetic analysis.Genomic analysis of the causative agents of coccidiosis in domestic chickensLateral gene transfer and gene duplication played a key role in the evolution of Mastigamoeba balamuthi hydrogenosomes.A transcriptomic approach to ribbon worm systematics (nemertea): resolving the pilidiophora problem.Comparative genomic analyses of freshly isolated Giardia intestinalis assemblage A isolatesEvolutionary ecology of beta-lactam gene clusters in animals.The multiple evolutionary origins of the eukaryotic N-glycosylation pathway.Novel Hydrogenosomes in the Microaerophilic Jakobid Stygiella incarcerataIncreased sequence coverage through combined targeting of variant and conserved epitopes correlates with control of HIV replication.The house spider genome reveals an ancient whole-genome duplication during arachnid evolution.Evolutionarily Conserved Alternative Splicing Across Monocots.A Phylogenomic Framework to Study the Diversity and Evolution of Stramenopiles (=Heterokonts).Smoothed Bootstrap Aggregation for Assessing Selection Pressure at Amino Acid Sites.The Identification of the Closest Living Relative(s) of Tetrapods: Phylogenomic Lessons for Resolving Short Ancient Internodes.W-IQ-TREE: a fast online phylogenetic tool for maximum likelihood analysis.
P2860
Q21089643-15069E7C-39B9-4548-9673-0789D3491F01Q26771275-9E47B35C-DC58-4197-B92C-79B794E63428Q28590696-4AE7F368-D5DD-46A3-8A17-2AFC6B4EAFB9Q28597241-1EF8615D-73AD-460F-91EC-307B39F185CCQ28607617-1A2F019C-FB97-406E-B7E4-FA71BBA77020Q28649621-2689E98A-22F5-42D1-83BC-D9179EC59DBDQ28651363-BCE1B66D-2A2B-46CD-9A55-ED4624993780Q28658397-14C9F7DF-50E4-4809-99FA-FF81136AF03BQ28709313-C261A76F-C6CE-4943-9A16-9839CCC00945Q28834051-87C778E2-DDAA-43BC-96A6-172D99966632Q29305163-63796C83-3256-490F-903D-15F17454C320Q30662233-1ED298CA-5FCC-4B18-B7B0-798A92759E41Q30786867-87265329-9BD9-4BBB-AF52-83ED4BA966F7Q30855654-790DD0E3-AF34-438F-B453-209161203FFCQ30908324-013922B8-D293-4ED6-A24B-A23CC5B04803Q31117690-2EA88FE7-227E-40A6-94FC-05C86C1530A6Q33603957-F577D96F-DE80-463D-A523-A9774562602AQ33792247-964D06B4-8C12-4921-9E37-EDCC2857961AQ34040493-66467F8D-14E5-4659-BE03-2EEF650A46C4Q34304593-C0784DD3-5DAA-45E8-ABBC-6D18372F6A5EQ34325762-E2CB5640-EFED-423A-8E86-221688BCD148Q34433014-C23790F1-47B5-4C57-BCF1-3B6AAF645D22Q34485095-AD9C5C3F-7063-4AE0-AC1C-7564F3D32198Q34549104-83A44B26-5D02-446F-9C2A-E097BC27A053Q35001145-6BEBF13F-8105-45E6-BA94-DDF73996785FQ35047540-94538DCD-7B69-4DCC-BF99-3CD359504553Q35205763-E992C703-8F1F-42B5-BDCD-471B34A304A1Q35232380-0268DCAA-B5CE-4B7A-B72E-D347F934F23DQ35234624-88700FD6-9525-4B97-AF6C-CDE248979C30Q35775316-0AE8DD21-53D3-4D46-9C4E-D496F1FBD795Q36313747-8657D964-B1A2-4DDA-B7B0-2A124070FF39Q37151926-1C6843CE-8BD9-42E3-B308-2E0A5F4A1752Q37184696-FA6FE607-126C-4FD0-87D7-ADDD0B26C0B6Q37547472-E504C498-25E5-4AF0-8EE4-C2C519F61783Q38368790-3FDF1003-7E32-4479-9382-EF5F50AB6DFDQ38609470-C7A2007E-63E5-449F-B3AE-7842ABB8AFBEQ39501450-56FFAE13-52FB-4618-AFE4-D92D8516255EQ39530493-9AA9AC4B-3A8E-4F02-93F7-356390F9A736Q39593552-853FEAB3-F80A-401B-BDFC-31A4E453A02DQ39846291-293E2443-690E-43EC-8EB2-2E6699E082B3
P2860
Modeling protein evolution with several amino acid replacement matrices depending on site rates.
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
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-hant
name
Modeling protein evolution wit ...... rices depending on site rates.
@en
Modeling protein evolution wit ...... rices depending on site rates.
@nl
type
label
Modeling protein evolution wit ...... rices depending on site rates.
@en
Modeling protein evolution wit ...... rices depending on site rates.
@nl
prefLabel
Modeling protein evolution wit ...... rices depending on site rates.
@en
Modeling protein evolution wit ...... rices depending on site rates.
@nl
P2860
P356
P1476
Modeling protein evolution wit ...... trices depending on site rates
@en
P2093
Cuong Cao Dang
Olivier Gascuel
P2860
P304
P356
10.1093/MOLBEV/MSS112
P50
P577
2012-04-06T00:00:00Z