RNA Duplex Map in Living Cells Reveals Higher-Order Transcriptome Structure - Wikidata - awgldk - TriplyDB

RNA Duplex Map in Living Cells Reveals Higher-Order Transcriptome Structure

RNA Duplex Map in Living Cells Reveals Higher-Order Transcriptome Structure

http://www.wikidata.org/entity/Q30460141

about

Insights from Global Analyses of Long Noncoding RNAs in Breast Cancer Using hiCLIP to identify RNA duplexes that interact with a specific RNA-binding protein.Structural Characteristics of Simple RNA Repeats Associated with Disease and their Deleterious Protein Interactions.Comparative and integrative analysis of RNA structural profiling data: current practices and emerging questions.Transcription factor Wilms' tumor 1 regulates developmental RNAs through 3' UTR interaction.RIblast: An ultrafast RNA-RNA interaction prediction system based on a seed-and-extension approach.RNA Matchmaking: Finding Cellular Pairing Partners Does mRNA structure contain genetic information for regulating co-translational protein folding?Evolution to the rescue: using comparative genomics to understand long non-coding RNAs.RIsearch2: suffix array-based large-scale prediction of RNA-RNA interactions and siRNA off-targets.The roles of RNA processing in translating genotype to phenotype A comprehensive benchmark of RNA-RNA interaction prediction tools for all domains of life.RNA modifications and structures cooperate to guide RNA-protein interactions.Novel players in X inactivation: insights into Xist-mediated gene silencing and chromosome conformation.The alternative life of RNA-sequencing meets single molecule approaches.RNA structure inference through chemical mapping after accidental or intentional mutations.Engineering Structurally Interacting RNA (sxRNA).Genome-wide mapping of infection-induced SINE RNAs reveals a role in selective mRNA export.Direct Duplex Detection: An Emerging Tool in the RNA Structure Analysis Toolbox Xist RNA repeat E is essential for ASH2L recruitment to the inactive X and regulates histone modifications and escape gene expression.The identification and functional annotation of RNA structures conserved in vertebrates.lncRNAs in development and disease: from functions to mechanisms.The role of interactions of long non-coding RNAs and heterogeneous nuclear ribonucleoproteins in regulating cellular functions.How do lncRNAs regulate transcription?Protein-mediated RNA folding governs sequence-specific interactions between rotavirus genome segments A transfer-RNA-derived small RNA regulates ribosome biogenesis.RISE: a database of RNA interactome from sequencing experiments.The Secret Life of RNA: Lessons from Emerging Methodologies.Mapping RNA-RNA Interactions Globally Using Biotinylated Psoralen.A mutually exclusive stem-loop arrangement in roX2 RNA is essential for X-chromosome regulation in Drosophila.Function by Structure: Spotlights on Xist Long Non-coding RNA.Swellix: a computational tool to explore RNA conformational space.The RNA binding protein EWS is broadly involved in the regulation of pri-miRNA processing in mammalian cells.DotAligner: identification and clustering of RNA structure motifs.RNA Regulations and Functions Decoded by Transcriptome-wide RNA Structure Probing.An RNA structure-mediated, posttranscriptional model of human α-1-antitrypsin expression.snoRNAs associate with mRNA 3' processing complex: New wine in old bottles.RNA2DMut: A web tool for the design and analysis of RNA structure mutations.Quantitative analysis of multilayer organization of proteins and RNA in nuclear speckles at super resolution.Emerging mechanisms of long noncoding RNA function during normal and malignant hematopoiesis.

P2860

Q33787422-DC146FBD-ECC5-48B0-8C35-1D5886A0EABD Q36288222-11B6207E-721C-4A58-80D8-829E5EACCB8A Q37747172-0B02DA65-394F-4060-ADDA-0388AEF15F97 Q38674649-0140B78A-81D0-4055-AC21-868048FF71BA Q38712379-4F14A12C-4D68-4436-86AB-B59417140D56 Q38811058-3C0DD0BB-35EE-4600-B33D-4B1E365CC856 Q38905622-0EB9BC1F-20E6-4CEA-B77D-E585212E94E1 Q38921682-ED83A316-89E1-490C-85F5-E17B31ED534A Q38940313-FC8CCAC9-BFCB-49EE-91CA-C9B90F53F1D7 Q39008805-C9B452FB-A1BF-40AE-99C6-5BA81E85AE88 Q39009636-86EB4FE8-3EFF-400C-A5AA-5F8286FD3C36 Q39086567-FDFE7CA1-E11E-41B0-BB01-0546FD6DAE56 Q39112521-626BDFA2-52F4-4A75-98BE-D0FAAFA0C415 Q39159965-26049B2F-3875-4723-9196-08F280F447EA Q39215683-6CC5AE12-2E32-487D-9670-C415D79A3AAF Q40066032-BFBFE95C-DC5D-4FA8-8DDF-2F9EB70FFFF0 Q40275395-EE27949D-D180-43CF-8D4C-6EEC6ED1A88A Q40281406-78194AAE-2058-4E7B-BA23-A544282290C5 Q40961232-A05CE4E3-2DE0-4374-97F0-134BBBC8F755 Q41090643-FAFAEA7C-AE57-4B96-AA98-44D864CFA987 Q41199610-A15E5B17-D054-47C0-80DC-183B9C4CFBEA Q41225381-C00E3F99-5D9A-4537-9F38-41ECBC921292 Q41357008-998EDCD4-47BC-46C6-BE68-568B0BC75693 Q41678364-30C9D0DF-12FE-4586-86F5-7DDEF588A050 Q41835315-CABBE641-DA40-4EC2-9D96-C07F5FD74D18 Q46004961-45CB7663-CDFD-4CDC-9B3A-2447A14A838A Q46006907-44B08998-AD0C-4434-B584-9EFF46000475 Q46262964-80DA339C-E1F9-43B3-A9C4-12DFE83D343E Q46357948-265C236B-4BEB-4EB3-836D-DBD1A9821F12 Q47099046-E34BEB62-8AA8-4CE9-B650-034866CFEFD5 Q47102761-8733EFB8-D254-4EF6-B7FB-7AEDAD238EAB Q47103063-C55274F4-EDB5-4AA1-B750-5153CBE9EB7F Q47111365-BEE27175-15F5-4311-8999-4D59FF755F23 Q47128079-2DFC5082-88AA-4D71-9FCE-369DE58DF1B7 Q47148082-EE39D9C5-078C-4644-AD9A-41987E1B1CDD Q47162066-7796F593-4533-476A-A697-31A3EA51039E Q47214605-A30A77A9-2B21-4365-BA8A-AE7C6945193C Q47304703-C321DE89-66F1-4BC1-A9A4-6688D91598E7 Q47352667-59E467AB-D066-4851-962B-C2D1938A0FE9 Q47657395-BD40DBCC-0886-4E7F-9C12-CE581D7DD9B6

P2860

RNA Duplex Map in Living Cells Reveals Higher-Order Transcriptome Structure

http://www.wikidata.org/entity/Q30460141

description

2016 nî lūn-bûn

@nan

2016 թուականի Մայիսին հրատարակուած գիտական յօդուած

@hyw

2016 թվականի մայիսին հրատարակված գիտական հոդված

@hy

2016年の論文

@ja

2016年論文

@yue

2016年論文

@zh-hant

2016年論文

@zh-hk

2016年論文

@zh-mo

2016年論文

@zh-tw

2016年论文

@wuu

name

RNA Duplex Map in Living Cells Reveals Higher-Order Transcriptome Structure

@ast

RNA Duplex Map in Living Cells Reveals Higher-Order Transcriptome Structure

@en

type

label

RNA Duplex Map in Living Cells Reveals Higher-Order Transcriptome Structure

@ast

RNA Duplex Map in Living Cells Reveals Higher-Order Transcriptome Structure

@en

prefLabel

RNA Duplex Map in Living Cells Reveals Higher-Order Transcriptome Structure

@ast

RNA Duplex Map in Living Cells Reveals Higher-Order Transcriptome Structure

@en

P1433

Q30460141-F73A589A-3378-48A3-ABDA-4E714CAF2686

P1476

Q30460141-C1DA7901-9711-4093-8D63-93949FD41FC6

P2093

Q30460141-4660A03B-C34C-4F1B-AF02-6328EDC92DB6

Q30460141-57FD5B52-AD99-4DC8-AB03-429B1AD7E043

Q30460141-70E5F222-5523-451F-B69A-8EC4A4621E1D

Q30460141-9133B489-A11D-452A-AA1B-943C1D01C506

Q30460141-AD216A7D-3310-4C06-9709-5BD7F6E89A36

Q30460141-BE0D21EB-4E40-4388-B59B-37B0A9947B44

Q30460141-E9B9AF93-1002-4B48-8FE3-A46519DD4850

P2860

Q30460141-01BBAD10-9F73-49A6-807A-7EE4C3BD4F02

Q30460141-06E0BB19-8E29-47AD-87A8-EA09587ECFAA

Q30460141-0C990B46-B620-4C4F-89E5-E96AF61620B9

Q30460141-133D2D4E-88BC-4D23-957C-7FBC7057F707

Q30460141-195D07F1-5ECD-4168-80DC-911B5A92B196

Q30460141-1AB408D1-74FA-4970-BF99-0809E2D267A4

Q30460141-1B88E8C9-BB5D-4079-95E8-F8BEA9B5606F

Q30460141-25DC0ED1-2ED9-43BC-AF9E-7BE5BE62267F

Q30460141-26F7138B-240C-448A-8243-A6BC2BE1E58B

Q30460141-2AB0F779-1FD0-43F6-97E2-244F997A92E8

P304

Q30460141-D5421CD7-26DB-43F9-BD6F-4AA72B33AD8F

P31

Q30460141-54C1177E-624E-4885-8089-AB47AF397FA3

P356

Q30460141-A0871FF8-BF10-4E7D-A9B8-2F6EC080F89E

P407

Q30460141-A8F7FC77-6266-43E1-9F63-42DB85F7100F

P433

Q30460141-4DAB7C87-5502-4600-93A0-A18A2DACE986

P478

Q30460141-15E482E2-0752-4AA2-9513-7BD45FE5748D

P50

Q30460141-1670C4B4-F353-4F1D-B85C-BF1A7DA945E6

Q30460141-1EA18962-9ADE-48C3-882C-D06E3FF90142

Q30460141-564A38BA-E86C-4BE1-8BAB-98799A397A88

Q30460141-73FD01DF-1BF5-42C8-8DA7-482D3E5E345D

Q30460141-7800B49C-3154-4531-81BD-1ADBE3B9109E

Q30460141-A2F140D2-1D75-4E64-90A7-864E407AABAF

P577

Q30460141-13C0ED3F-E7E8-4480-8696-11D96833E603

P698

Q30460141-04631E46-5D5A-4B14-8533-1E56DC14616B

P921

Q30460141-5309480F-FD1E-4326-B240-D8EC32586C43

P932

Q30460141-CCF64D3E-0BF7-46A3-A1E5-3E6871F98609

P356

J.CELL.2016.04.028

P1433

P1476

RNA Duplex Map in Living Cells Reveals Higher-Order Transcriptome Structure

@en

P2093

Anne R Gooding

http://www.w3.org/2001/XMLSchema#string

Byron Lee

http://www.w3.org/2001/XMLSchema#string

Howard Y Chang

http://www.w3.org/2001/XMLSchema#string

James T Robinson

http://www.w3.org/2001/XMLSchema#string

Karen J Goodrich

http://www.w3.org/2001/XMLSchema#string

Martin A Smith

http://www.w3.org/2001/XMLSchema#string

Qiangfeng Cliff Zhang

http://www.w3.org/2001/XMLSchema#string

P2860

2-D structure of the A region of Xist RNA and its implication for PRC2 association

A dual origin of the Xist gene from a protein-coding gene and a set of transposable elements

Ultraconserved Elements in the Human Genome

Widespread purifying selection on RNA structure in mammals

A Pumilio-induced RNA structure switch in p27-3' UTR controls miR-221 and miR-222 accessibility

Small nucleolar RNA-guided post-transcriptional modification of cellular RNAs

The sequence of the 5' end of the U8 small nucleolar RNA is critical for 5.8S and 28S rRNA maturation

The noncoding RNA revolution-trashing old rules to forge new ones

The crystal structure of the Split End protein SHARP adds a new layer of complexity to proteins containing RNA recognition motifs

The equilibrium partition function and base pair binding probabilities for RNA secondary structure

P304

1267-1279

http://www.w3.org/2001/XMLSchema#string

P31

scholarly article

P356

10.1016/J.CELL.2016.04.028

http://www.w3.org/2001/XMLSchema#string

P407

P433

5

http://www.w3.org/2001/XMLSchema#string

P478

165

http://www.w3.org/2001/XMLSchema#string

P50

Jill P. Mesirov

Chen Davidovich

John S. Mattick

P577

2016-05-11T00:00:00Z

http://www.w3.org/2001/XMLSchema#dateTime

P698

27180905

http://www.w3.org/2001/XMLSchema#string

P921

P932

5029792

http://www.w3.org/2001/XMLSchema#string