about
Exploring the folding landscape of a structured RNADesign of multistable RNA moleculesAssembly of core helices and rapid tertiary folding of a small bacterial group I ribozymeMultiple native states reveal persistent ruggedness of an RNA folding landscapeDMS footprinting of structured RNAs and RNA-protein complexesConcerted folding of a Candida ribozyme into the catalytically active structure posterior to a rapid RNA compactionMolecular beacons as probes of RNA unfolding under native conditions.Strategies for RNA folding and assemblyIn vitro suicide inhibition of self-splicing of a group I intron from Pneumocystis carinii by an N3' --> P5' phosphoramidate hexanucleotideTertiary structure formation in the hairpin ribozyme monitored by fluorescence resonance energy transferConfigurational diffusion down a folding funnel describes the dynamics of DNA hairpins.An assembly landscape for the 30S ribosomal subunit.Mechanical unfolding of RNA: from hairpins to structures with internal multiloops.Ribosome assembly factors Pwp1 and Nop12 are important for folding of 5.8S rRNA during ribosome biogenesis in Saccharomyces cerevisiae.Kinetic cooperativity in Escherichia coli 30S ribosomal subunit reconstitution reveals additional complexity in the assembly landscape.Maximizing RNA folding rates: a balancing act.Multiple unfolding events during native folding of the Tetrahymena group I ribozymeRapid compaction during RNA folding.Multistage collapse of a bacterial ribozyme observed by time-resolved small-angle X-ray scattering.The rate-limiting step in the folding of a large ribozyme without kinetic trapsCoupled nucleotide covariations reveal dynamic RNA interaction patterns.Folding pathways of the Tetrahymena ribozymeOsmolytes stimulate the reconstitution of functional 50S ribosomes from in vitro transcripts of Escherichia coli 23S rRNA.Intracellular folding of the Tetrahymena group I intron depends on exon sequence and promoter choice.Conformational changes involved in initiation of minus-strand synthesis of a virus-associated RNA.RNA folding energy landscapes.A pseudoknot in a preactive form of a viral RNA is part of a structural switch activating minus-strand synthesis.The Azoarcus group I intron ribozyme misfolds and is accelerated for refolding by ATP-dependent RNA chaperone proteins.On secondary structure rearrangements and equilibria of small RNAs.Chain length determines the folding rates of RNA.Distinct contribution of electrostatics, initial conformational ensemble, and macromolecular stability in RNA folding.Computational prediction of efficient splice sites for trans-splicing ribozymes.Allosteric tertiary interactions preorganize the c-di-GMP riboswitch and accelerate ligand binding.Native secondary structure formation in RNA may be a slave to tertiary folding.Quantitation of ten 30S ribosomal assembly intermediates using fluorescence triple correlation spectroscopy.Communication between RNA folding domains revealed by folding of circularly permuted ribozymes.RNA under tension: Folding Landscapes, Kinetic partitioning Mechanism, and Molecular TensegrityAn optimal Mg(2+) concentration for kinetic folding of the tetrahymena ribozyme.Understanding the role of three-dimensional topology in determining the folding intermediates of group I introns.Free energy landscapes of RNA/RNA complexes: with applications to snRNA complexes in spliceosomes.
P2860
Q24531270-BFD13CEA-EF82-4F22-9954-0D6BB433D2D8Q24539901-71A446B5-54CF-47BD-8985-716C5FF9264AQ24550734-7CF7B4D2-E2AC-445F-8B01-9A201DDD2A61Q24651791-2E71977D-2E36-474C-B3C1-700EC6DDC121Q24657868-00E89F0F-0051-4BC1-8488-9B8BF25E2E0EQ24680499-6063E617-E5F4-493F-AC60-911F0971B7B1Q24811796-59244594-9351-45EE-B73D-31EF8053F138Q28291162-BD8BDA00-2E01-4301-A8BF-1E1058D6E820Q28343202-35B635EC-D6CD-413D-BDA6-0712F8BC5680Q28769589-5244C5DA-DA4C-407E-B45E-81A73E40AF53Q30994432-88CFE07B-642B-4F6D-8CCD-A6FB20BF9B4FQ33228236-CB078ECF-F5A2-47AE-BB4D-1E7879E9F789Q33259722-88F52BE7-0BAD-48A0-869B-A1ABBF108A62Q33602516-45CF8367-3E72-43FB-93E1-AC4999F7D989Q33777643-13A341FF-96FD-4216-9F8D-FDA160947A68Q33948609-45AFD57E-7138-4DB7-8ED0-958B2BB8451AQ34001156-95D887C4-CF47-41A2-ADC4-7596450329E1Q34047327-DE9248B3-6041-4EDD-A251-4BF12C7C0443Q34054104-D5B07260-C77E-4DBD-A840-3D4E97B11BE3Q34064701-DB29B770-2B4A-44A1-BE5E-62B3D57BCCFDQ34098396-223085C9-1783-48B1-B020-43C0DBCEAA7DQ34255755-7845ADF7-80F4-4CCE-9D16-0182C1A01661Q34364319-C6CBC9EF-C864-4160-87DF-0755CCEFD009Q34366030-D527EA3C-8FDC-47BC-A2F9-653826B6B49CQ34366788-4B3EE0A8-6A27-4EAF-845E-DCB7BAC27D9DQ34971727-4785DF9F-2748-4BBF-A13D-29B8DD31FAA0Q35024280-B9437155-4132-4F41-AEA1-416CE8C411FAQ35423608-E0521627-DEF5-4793-97D1-10FCB1F8511CQ35549352-9C7FA5F4-6B8A-4BFC-AD0B-ECB973D07A31Q35743278-F27DF8A0-0B62-4FDE-86B8-300FC82B2DF7Q35758464-C973BA85-0491-4A73-8784-8C3F48847988Q35775827-5B3D48D6-BBCD-4B2F-8E68-BCB9C1A64DD8Q35973505-98E82B1D-F025-4759-8862-1321C9BFAEBBQ36076703-994B5292-6767-41CD-9E72-DF943765A44FQ36187174-FC1B5269-E492-4105-9979-EF7D67D014A2Q36329006-678A20BD-11DB-4671-BBF0-EA49AC762647Q36534066-3709A5E0-C21A-4603-95A3-492993206278Q36542678-9BC53F24-8DAB-4CEB-9AFB-3A8B57E82076Q36700154-5AB593AA-6433-4B12-8031-099D81862265Q36742536-D9A6EB54-9852-404F-9AAB-0A818F807FCD
P2860
description
im Oktober 1997 veröffentlichter wissenschaftlicher Artikel
@de
wetenschappelijk artikel
@nl
наукова стаття, опублікована в жовтні 1997
@uk
name
Folding of RNA involves parallel pathways
@en
Folding of RNA involves parallel pathways
@nl
type
label
Folding of RNA involves parallel pathways
@en
Folding of RNA involves parallel pathways
@nl
prefLabel
Folding of RNA involves parallel pathways
@en
Folding of RNA involves parallel pathways
@nl
P356
P1476
Folding of RNA involves parallel pathways
@en
P2093
D. Thirumalai
P356
10.1006/JMBI.1997.1311
P407
P577
1997-10-01T00:00:00Z