Reconstitution of CPSF active in polyadenylation: recognition of the polyadenylation signal by WDR33.
about
Processing and transcriptome expansion at the mRNA 3' end in health and disease: finding the right endFUS-mediated regulation of alternative RNA processing in neurons: insights from global transcriptome analysisThe end of the message: multiple protein-RNA interactions define the mRNA polyadenylation siteStructural basis for snRNA recognition by the double-WD40 repeat domain of Gemin5A potent antimalarial benzoxaborole targets a Plasmodium falciparum cleavage and polyadenylation specificity factor homologueA comprehensive analysis of 3' end sequencing data sets reveals novel polyadenylation signals and the repressive role of heterogeneous ribonucleoprotein C on cleavage and polyadenylationRole of cleavage and polyadenylation specificity factor 100: anchoring poly(A) sites and modulating transcription termination.Drosophila melanogaster retrotransposon and inverted repeat-derived endogenous siRNAs are differentially processed in distinct cellular locations.Alternative polyadenylation of mRNA precursors.CPSF30 and Wdr33 directly bind to AAUAAA in mammalian mRNA 3' processingSystematic profiling of poly(A)+ transcripts modulated by core 3' end processing and splicing factors reveals regulatory rules of alternative cleavage and polyadenylation.Canonical Poly(A) Polymerase Activity Promotes the Decay of a Wide Variety of Mammalian Nuclear RNAs.Integrative genome-wide analysis reveals HLP1, a novel RNA-binding protein, regulates plant flowering by targeting alternative polyadenylationIn vivo characterization of the Drosophila mRNA 3' end processing core cleavage complex.Experimental Genome-Wide Determination of RNA Polyadenylation in Chlamydomonas reinhardtii.Dissecting the expression relationships between RNA-binding proteins and their cognate targets in eukaryotic post-transcriptional regulatory networks.The Cstf2t Polyadenylation Gene Plays a Sex-Specific Role in Learning Behaviors in MiceContext-dependent modulation of Pol II CTD phosphatase SSUP-72 regulates alternative polyadenylation in neuronal development.From polyadenylation to splicing: Dual role for mRNA 3' end formation factorsCleavage and polyadenylation specificity factor 30: An RNA-binding zinc-finger protein with an unexpected 2Fe-2S cluster.Genome-Wide Analysis of Polyadenylation Events in Schmidtea mediterraneaGlobal analysis of regulatory divergence in the evolution of mouse alternative polyadenylation.Targeting Toxoplasma gondii CPSF3 as a new approach to control toxoplasmosis.Roles of Sumoylation in mRNA Processing and Metabolism.Coordination of RNA Polymerase II Pausing and 3' End Processing Factor Recruitment with Alternative Polyadenylation.CstF-64 and 3'-UTR cis-element determine Star-PAP specificity for target mRNA selection by excluding PAPα.Position-specific binding of FUS to nascent RNA regulates mRNA length.Optimization of PAR-CLIP for transcriptome-wide identification of binding sites of RNA-binding proteins.The nuclear poly(A) binding protein of mammals, but not of fission yeast, participates in mRNA polyadenylation.Cleavage and polyadenylation: Ending the message expands gene regulation.The polyadenylation complex of Trypanosoma brucei: Characterization of the functional poly(A) polymerase.A snoRNA modulates mRNA 3' end processing and regulates the expression of a subset of mRNAs.The Y3** ncRNA promotes the 3' end processing of histone mRNAs.Molecular basis for the recognition of the human AAUAAA polyadenylation signal.snoRNAs associate with mRNA 3' processing complex: New wine in old bottles.Structural insights into the assembly and polyA signal recognition mechanism of the human CPSF complex.Reconstitution of the CstF complex unveils a regulatory role for CstF-50 in recognition of 3'-end processing signals.Architecture of eukaryotic mRNA 3'-end processing machinery.SETD6 dominant negative mutation in familial colorectal cancer type X.Targeting a Single Alternative Polyadenylation Site Coordinately Blocks Expression of Androgen Receptor mRNA Splice Variants in Prostate Cancer.
P2860
Q26746120-C0A2A475-87DE-4D32-918D-2EBEFE926379Q26773038-54AFDB82-AD79-4C67-BD08-6D0859FB82E0Q28082339-BF96ACBC-517B-43B4-9736-7817F6D3CA50Q28118454-0123C960-1DF4-435C-976D-90B1FE889324Q30045921-F28CD625-FB55-4B0B-99F0-0DAD41775367Q31112743-8CA65EF5-85F4-4426-A455-16D5A40DE915Q33365612-692195F9-CFB2-43F2-B8D5-BD651931A03DQ33568513-CAEE4BE1-6F2B-4540-BE64-72E3D0AB29D2Q33832891-0BA402DB-490B-42A7-B360-527030635236Q34430715-6A8AAE86-28A5-40A1-87BD-E0E4ECF841E0Q35532398-3CD659ED-D527-427C-9954-A76A0A5D1C70Q35814334-5056085F-6E15-4BB2-BFCD-7F35A86F3AEDQ35823834-36125DEB-4133-4012-9223-3AC23F0DDDCAQ35875832-898C8559-0E88-4FE9-96A2-46EA7B25BE54Q35885134-B001DF21-7D3D-44E4-AA68-9B26DA4EFABBQ36012895-77315918-BF65-4F4B-B755-D9283A44B15AQ36182348-F7FC6E99-D127-4C69-9069-908CFBA7B946Q36406376-31C0174F-34D5-4C72-B4AA-ED73AF8E05B6Q36791576-CB697C4A-5B6B-47E5-BD4A-94EB08203713Q36866046-17592456-8F05-46B9-9707-940114D7E49BQ37347972-3F62A704-48D0-435E-92BF-44CC0855CFD8Q37544650-0B748EA0-F0FD-49AE-8AC9-349FCE2ADB9EQ37672675-4011AA65-FC2D-40EB-892B-49B4CFC48A6BQ38757480-B9064AFB-7DF0-4E76-A90E-C0D896E6597AQ38822658-397FC6A5-FEC7-4E4D-B0AE-B8806CA3FD49Q38825492-1920339F-0086-42E2-ACBA-AEACA6C3E94AQ38872764-428ABEFB-B930-414C-B8C1-C78CDC8978A2Q38986620-372836D5-FA59-4D85-AD02-212A595CD4F4Q39016020-07D9A9B2-6E6D-40A0-8714-D866FF00174DQ39269835-F42FE675-EA92-4037-9C1B-9A22D501EAA3Q40090853-E9ADCF97-E03F-49AF-A36B-7DD79A17680EQ41626584-418F83BB-872E-41CF-91E5-BC843E72EF50Q42150115-2BB55B58-01F4-4A48-A8D4-6BB46923A903Q46335657-28F389B0-9C7F-406E-A464-9FDDB0015E08Q47214605-B0C1B25A-6565-4B10-965D-6B68219CE9BFQ47258918-4DAD2844-238D-4FB5-A96C-D9FFD32B5D91Q47351875-38CE012A-6843-4727-99E6-EDADFD07521CQ47598334-6B62120F-3C0F-4E1A-82E9-9B5A01453B41Q47706997-B2A1A476-A67D-4D6A-8B7D-56887A2B1FD0Q47776194-F694C774-EA22-4B41-BCAF-C8C366CE5DF2
P2860
Reconstitution of CPSF active in polyadenylation: recognition of the polyadenylation signal by WDR33.
description
2014 nî lūn-bûn
@nan
2014 թուականի Հոկտեմբերին հրատարակուած գիտական յօդուած
@hyw
2014 թվականի հոտեմբերին հրատարակված գիտական հոդված
@hy
2014年の論文
@ja
2014年論文
@yue
2014年論文
@zh-hant
2014年論文
@zh-hk
2014年論文
@zh-mo
2014年論文
@zh-tw
2014年论文
@wuu
name
Reconstitution of CPSF active ...... lyadenylation signal by WDR33.
@ast
Reconstitution of CPSF active ...... lyadenylation signal by WDR33.
@en
Reconstitution of CPSF active ...... lyadenylation signal by WDR33.
@nl
type
label
Reconstitution of CPSF active ...... lyadenylation signal by WDR33.
@ast
Reconstitution of CPSF active ...... lyadenylation signal by WDR33.
@en
Reconstitution of CPSF active ...... lyadenylation signal by WDR33.
@nl
prefLabel
Reconstitution of CPSF active ...... lyadenylation signal by WDR33.
@ast
Reconstitution of CPSF active ...... lyadenylation signal by WDR33.
@en
Reconstitution of CPSF active ...... lyadenylation signal by WDR33.
@nl
P2093
P2860
P50
P356
P1433
P1476
Reconstitution of CPSF active ...... lyadenylation signal by WDR33.
@en
P2093
Georges Martin
Lars Schönemann
Peter Schäfer
Walter Keller
P2860
P304
P356
10.1101/GAD.250985.114
P577
2014-10-09T00:00:00Z