Transcriptional pausing coordinates folding of the aptamer domain and the expression platform of a riboswitch.
about
Linking aptamer-ligand binding and expression platform folding in riboswitches: prospects for mechanistic modeling and designViral RNA switch mediates the dynamic control of flavivirus replicase recruitment by genome cyclizationInsights into the Regulatory Landscape of the Lysine RiboswitchNucleotides Adjacent to the Ligand-Binding Pocket are Linked to Activity Tuning in the Purine RiboswitchProgress and challenges for chemical probing of RNA structure inside living cellsFolding and ligand recognition of the TPP riboswitch aptamer at single-molecule resolution.Cotranscriptional folding of a riboswitch at nucleotide resolution.Distributed biotin-streptavidin transcription roadblocks for mapping cotranscriptional RNA folding.RNA polymerase pausing and nascent-RNA structure formation are linked through clamp-domain movementGene regulation by riboswitches with and without negative feedback loop.A kissing loop is important for btuB riboswitch ligand sensing and regulatory control.The primary σ factor in Escherichia coli can access the transcription elongation complex from solution in vivo.A DEAD-box RNA helicase promotes thermodynamic equilibration of kinetically trapped RNA structures in vivoFluorescence monitoring of riboswitch transcription regulation using a dual molecular beacon assayA Two-Way Street: Regulatory Interplay between RNA Polymerase and Nascent RNA Structure.Diversity of cobalamin riboswitches in the corrinoid-producing organohalide respirer Desulfitobacterium hafniense.Mg(2+)-induced conformational changes in the btuB riboswitch from E. coliTranslation rate is controlled by coupled trade-offs between site accessibility, selective RNA unfolding and sliding at upstream standby sites.On the importance of cotranscriptional RNA structure formationRegulatory effects of cotranscriptional RNA structure formation and transitions.Conformational Dynamics of mRNA in Gene Expression as New Pharmaceutical Target.Co-Transcriptional Folding and Regulation Mechanisms of Riboswitches.Quantitative and predictive model of kinetic regulation by E. coli TPP riboswitches.Direct observation of cotranscriptional folding in an adenine riboswitch.Transcriptional pausing at the translation start site operates as a critical checkpoint for riboswitch regulation.Changes in transcriptional pausing modify the folding dynamics of the pH-responsive RNA elementPausing guides RNA folding to populate transiently stable RNA structures for riboswitch-based transcription regulation.Disparity between microRNA levels and promoter strength is associated with initiation rate and Pol II pausing.Computational Methods for Modeling Aptamers and Designing Riboswitches.Site-specific dual-color labeling of long RNAs for single-molecule spectroscopy.Closed for business: exit-channel coupling to active site conformation in bacterial RNA polymerase.New insights into gene regulation--high-resolution structures of cobalamin riboswitches.Mimicking Co-Transcriptional RNA Folding Using a Superhelicase
P2860
Q26781454-06911410-D387-4A0C-B4E1-D76C4F918AEEQ27108074-BFCB5B7D-75D8-4531-98A5-E0952F8B7E47Q27670668-52589832-9871-4B59-82E8-2E4EAEF2E5AFQ27676791-B4519A83-F21D-4536-8ABE-BD10E17F4644Q27691278-32410DF5-42DA-40E7-B2CE-B58B7DD37C9EQ30537755-A90614B4-0C92-4FFF-85D8-F123952C0406Q33871774-54C570A7-25A1-4186-BCA3-55DF7EFB8F1FQ33878041-20407379-E94A-4961-B34F-B45C80BDCF7FQ34145524-CB1AF113-D09F-42F6-895B-68370BC57495Q34320541-667EF2D2-73A3-49D6-89AE-30754AA46575Q35775149-D9543A0A-75D0-47A0-8438-824B623ABD86Q36159198-EE65CA62-7CF6-4409-A7FF-8B4C01F052D6Q36566607-E60EF469-BFA4-4145-8407-78D4F4AA3E58Q36878385-4BDA4452-E041-4BE0-8A49-217075688A66Q37014169-D7EEBE39-4D68-42D9-B4DD-B695D42E0B49Q37264149-59D18E6A-19A7-466A-94E2-96B7FC2066CDQ37400274-61B87E33-3158-4A75-89C5-340619A0A751Q37606918-7C4CD99B-617F-4C19-A43E-88F0B00ED108Q38153167-FD5F485C-3BD6-4932-8A5C-F5D3FCE2EFC4Q38793689-F558E542-9902-4BB8-A9AD-C6DC8DE50607Q39312942-1EE5D054-37D9-46F4-A33C-A711A71899C6Q39432546-B019BC8D-EA06-4F4B-AF02-07F5A5ECCDF2Q40517162-7951A54F-6B8E-4F56-ACF3-25DDC49950E2Q41203371-78FCB0D9-9E3B-47F9-91D2-EF0B6A12655BQ42018354-5747DEE6-E3FC-4FAE-9127-C22C3C3EFD39Q42031820-AAE08FC8-CE50-450D-84C8-6683750E18FCQ42220858-CE3344EE-521E-45D2-9891-512BA0EA1F2CQ46833286-38BED9DA-EDC0-4569-9E22-C56A89095EB8Q47096979-2382A12E-443F-4991-B928-DA5256860A27Q48601682-8D752CD0-DEF1-4BD1-960A-682CB4289C81Q54282531-267DAD00-5BDE-4B0D-8CAE-CCC4C63F26E3Q54458887-18330269-D4A7-448E-BB28-EB752F3615FFQ57753340-173387BE-A810-4F21-92D5-02D2F40F2656
P2860
Transcriptional pausing coordinates folding of the aptamer domain and the expression platform of a riboswitch.
description
2012 nî lūn-bûn
@nan
2012年の論文
@ja
2012年論文
@yue
2012年論文
@zh-hant
2012年論文
@zh-hk
2012年論文
@zh-mo
2012年論文
@zh-tw
2012年论文
@wuu
2012年论文
@zh
2012年论文
@zh-cn
name
Transcriptional pausing coordi ...... sion platform of a riboswitch.
@ast
Transcriptional pausing coordi ...... sion platform of a riboswitch.
@en
type
label
Transcriptional pausing coordi ...... sion platform of a riboswitch.
@ast
Transcriptional pausing coordi ...... sion platform of a riboswitch.
@en
prefLabel
Transcriptional pausing coordi ...... sion platform of a riboswitch.
@ast
Transcriptional pausing coordi ...... sion platform of a riboswitch.
@en
P2093
P2860
P356
P1476
Transcriptional pausing coordi ...... sion platform of a riboswitch.
@en
P2093
George A Perdrizet
Ran Furman
P2860
P304
P356
10.1073/PNAS.1113086109
P407
P577
2012-02-13T00:00:00Z