Evolutionary dynamics of coding and non-coding transcriptomes.
about
Long non-coding RNA Databases in Cardiovascular ResearchOn the evolutionary relationship between chondrocytes and osteoblastsLong Intergenic Non-Coding RNAs: Novel Drivers of Human Lymphocyte DifferentiationCirculating MicroRNAs as Potential Biomarkers of Exercise ResponseIntegrating Epigenomics into the Understanding of Biomedical InsightFast turnover of genome transcription across evolutionary time exposes entire non-coding DNA to de novo gene emergenceThe life history of retrocopies illuminates the evolution of new mammalian genesTreeExp1.0: R Package for Analyzing Expression Evolution Based on RNA-Seq Data.Large-scale mapping of mammalian transcriptomes identifies conserved genes associated with different cell states.An alternative splicing event amplifies evolutionary differences between vertebrates.Complex transcriptional regulation and independent evolution of fungal-like traits in a relative of animalsLong non-coding RNA discovery across the genus anopheles reveals conserved secondary structures within and beyond the Gambiae complex.Tissue-Specific Evolution of Protein Coding Genes in Human and MouseA comparison of human and mouse gene co-expression networks reveals conservation and divergence at the tissue, pathway and disease levelsGlobal expression differences and tissue specific expression differences in rice evolution result in two contrasting types of differentially expressed genes.Comparative genomics of Steinernema reveals deeply conserved gene regulatory networks.Tissue-Specificity of Gene Expression Diverges Slowly between Orthologs, and Rapidly between Paralogs.Transcriptome analysis of pancreatic cells across distant species highlights novel important regulator genes.In silico prediction of lncRNA function using tissue specific and evolutionary conserved expression.Long non-coding RNAs display higher natural expression variation than protein-coding genes in healthy humansHost gene constraints and genomic context impact the expression and evolution of human microRNAs.What to compare and how: Comparative transcriptomics for Evo-Devo.Genomes of Ellobius species provide insight into the evolutionary dynamics of mammalian sex chromosomes.The evolution of the human genome.Genes affecting β-cell function in type 1 diabetes.Evolution of regulatory networks in Candida glabrata: learning to live with the human host.Biological function in the twilight zone of sequence conservationThe importance of drug transporters in human pluripotent stem cells and in early tissue differentiation.The evolution of duplicate gene expression in mammalian organs.Gene expression is more strongly influenced by age than caste in the ant Lasius niger.Natural gene expression variation studies in yeast.miRNA in Macrophage Development and Function.Deep homology in the age of next-generation sequencing.The Robo3 receptor, a key player in the development, evolution, and function of commissural systems.Comparative transcriptomics in human and mouse.Characterization of the genome and transcriptome of the blue tit Cyanistes caeruleus: polymorphisms, sex-biased expression and selection signals.Predominant contribution of cis-regulatory divergence in the evolution of mouse alternative splicing.Long noncoding RNAs in the model species Brachypodium distachyon.Anatomy of protein disorder, flexibility and disease-related mutationsNetworks of Cultured iPSC-Derived Neurons Reveal the Human Synaptic Activity-Regulated Adaptive Gene Program.
P2860
Q26751395-AF15C4DE-BA96-4814-9468-595E95757F95Q26781138-D7C6527C-EC07-4AD0-B133-A32FAD68A240Q26828561-440BAA48-C141-4834-A5C3-1ED3739A3EC2Q28070031-10225FFF-9CFE-4BCC-B3AE-C65B97CAD086Q28077579-4465E9E5-CE6E-4272-B321-0BDAFF6617E7Q28600845-6074D1C5-ECF0-474F-8458-24ADC1FCC932Q28603561-4E236274-8912-461D-BE76-62FA34A31E5FQ31139096-17632E6A-53C9-4C67-A946-215845A07F8DQ33557481-F6912955-4ECC-49BD-9D4E-6EA567B6E7CBQ34490402-1EAF112C-97A5-4D53-B9F5-5A4C75BA1521Q34497928-171F6F7E-69AB-44F7-8C68-54014EAF50DDQ35538795-B33E4C59-D437-42D8-BEFA-4935AF2A5DAAQ35677210-E1CE12A8-0943-4207-BC75-91567DCE402FQ35847610-B4BBD95C-DABB-4048-A905-95ECC342E264Q35877335-5C7C594F-B61D-44A8-B230-7CCD75CF3E2CQ36083006-BED365EC-4113-4FB3-BBBF-1D52C388A038Q36234551-340BE00E-8208-4627-849D-D3BE25ACB2F9Q36317537-94EC305B-37C9-427A-9469-AEF1CACAE6DAQ36329484-EB31BA2E-3AAD-4EF5-A462-C532E58099ECQ36517502-1C61F917-F78A-4031-AB38-119AEBE55A77Q36845900-16E8210E-FD21-419A-BD43-261D9925B74EQ37105223-E04E4FE3-9CC2-471C-A869-3FE7E0D485DAQ37313657-C71BBFFF-158F-410B-8319-720D6FC56F01Q38580560-86501FB0-1EC1-48E4-838B-86366EBE4895Q38590582-FF42DA6B-FF90-4676-81B7-3265E139531BQ38602694-C6ECA6B0-9EEE-4DD7-B7EE-87D19D9E5CD2Q38621680-FF3BA6F0-6777-43D3-8548-01661F5D7564Q38642449-9A3C7D35-312F-43D6-AE95-D716FE027845Q38661582-71F65044-E979-4542-9553-06754C9EE598Q38662093-391E678D-C473-415A-9EA0-FE0130425078Q38817687-EAF369A2-D875-44B6-8577-678984FE8971Q38847523-317B9AC3-7415-43D2-8600-504CEBCCDAD0Q39043805-5987DD2A-EB75-475A-878B-24B34E44B22CQ39062294-72F0B544-8A0C-4011-823F-2824C0271E22Q39289394-E3B943AA-E865-4B6C-AAFF-8A834E122E8FQ40684611-B8ECF3C1-D7AA-4F06-87C8-C28132321B7BQ40776050-04AC9A95-A6B6-43DC-908F-296312307F6CQ41201086-ADF0B1E8-9F2E-41A8-9162-1ED6CACA8589Q41919553-DCEF59DD-CE6F-4260-9E5B-8025D23CF26FQ42196975-2CAC17FB-9132-4112-9AD5-8ED13CD1279C
P2860
Evolutionary dynamics of coding and non-coding transcriptomes.
description
2014 nî lūn-bûn
@nan
2014年の論文
@ja
2014年学术文章
@wuu
2014年学术文章
@zh-cn
2014年学术文章
@zh-hans
2014年学术文章
@zh-my
2014年学术文章
@zh-sg
2014年學術文章
@yue
2014年學術文章
@zh
2014年學術文章
@zh-hant
name
Evolutionary dynamics of coding and non-coding transcriptomes.
@en
type
label
Evolutionary dynamics of coding and non-coding transcriptomes.
@en
prefLabel
Evolutionary dynamics of coding and non-coding transcriptomes.
@en
P2860
P356
P1476
Evolutionary dynamics of coding and non-coding transcriptomes.
@en
P2093
Henrik Kaessmann
P2860
P2888
P304
P356
10.1038/NRG3802
P577
2014-10-09T00:00:00Z
P6179
1027212387