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SimulFold: simultaneously inferring RNA structures including pseudoknots, alignments, and trees using a Bayesian MCMC frameworkA model for the RNA-catalyzed replication of RNAKinefold web server for RNA/DNA folding path and structure prediction including pseudoknots and knotsMetastable structures and refolding kinetics in hok mRNA of plasmid R1Co-transcriptional folding is encoded within RNA genesDynamics of co-transcriptional pre-mRNA folding influences the induction of dystrophin exon skipping by antisense oligonucleotides.TRANSAT-- method for detecting the conserved helices of functional RNA structures, including transient, pseudo-knotted and alternative structuresCotranscriptional folding of a riboswitch at nucleotide resolution.Dynamic energy landscapes of riboswitches help interpret conformational rearrangements and function.Comparison of pausing during transcription and replicationDesign, synthesis, and application of Spinach molecular beacons triggered by strand displacement.A counterintuitive Mg2+-dependent and modification-assisted functional folding of mitochondrial tRNAsCotranscriptional folding kinetics of ribonucleic acid secondary structuresThe Drosophila Helicase MLE Targets Hairpin Structures in Genomic Transcripts.Determination of secondary structure in the initiation region of ovalbumin mRNATransient RNA structure features are evolutionarily conserved and can be computationally predicted.Extremely sensitive, background-free gene detection using binary probes and beta replicase.Dual masking of specific negative splicing regulatory elements resulted in maximal exon 7 inclusion of SMN2 gene.On the importance of cotranscriptional RNA structure formationCo-Transcriptional Folding and Regulation Mechanisms of Riboswitches.Detection and analysis of hairpin II, an essential metastable structural element in viroid replication intermediates.Characterization of the initiation sites of both polarity strands of a viroid RNA reveals a motif conserved in sequence and structure.COFOLD: an RNA secondary structure prediction method that takes co-transcriptional folding into accountThe 9S RNA precursor of Escherichia coli 5S RNA has three structural domains: implications for processing.Evolution and replication of tobacco ringspot virus satellite RNA mutants.Mutations affecting primer RNA interaction with the replication repressor RNA I in plasmid CoIE1: potential RNA folding pathway mutants.Encoding folding paths of RNA switches.Computer simulation of chaperone effects of Archaeal C/D box sRNA binding on rRNA foldingThe folding of large RNAs studied by hybridization to arrays of complementary oligonucleotides.Effect of transcription on folding of the Tetrahymena ribozyme.Computational Methods for Modeling Aptamers and Designing Riboswitches.RNA Regulations and Functions Decoded by Transcriptome-wide RNA Structure Probing.In vivo probing of nascent RNA structures reveals principles of cotranscriptional folding.A Boltzmann filter improves the prediction of RNA folding pathways in a massively parallel genetic algorithm.
P2860
Q21563523-A13C7547-30F1-4094-B483-49D2B5F527E1Q22066218-4FADDD71-DC1F-44C9-95A8-DFD47CE1F4A1Q24530528-A726A3C0-4227-4BF9-BEAF-D13FE7EF909CQ24539417-CD56283F-AA0D-4CA5-8FC2-739E535BF73CQ24803935-3C3C6E0E-9EA7-4D60-B83C-5F3073393067Q33325470-C787FD7D-E174-4D46-83E9-4300EFDE4543Q33621382-0256BDF4-AAC8-4E48-BD67-787607867DFDQ33871774-0B934362-EA92-4871-80EC-D94845585571Q34167824-A647C64A-6FCD-4D40-AABC-431CFEF2CD8CQ35565396-4B0FE047-01BD-4C3F-8EEF-7EDB1B0A0E23Q35600937-700BFE0C-B867-4265-8685-3A0CAF09367BQ35610021-91450561-29EA-4CA7-BB1F-683D06303D47Q35662888-5ADC7AEC-54DA-47DB-BBD6-F038B419D4D9Q35890330-5EE92C7B-3E2A-4DF7-AE1D-AE90E82F19E6Q36077293-E86C11F8-680D-4346-913A-D471D679BA9DQ36963281-3726C1C0-F74C-4544-8C59-A0FB813F3541Q37586985-6691F21F-1496-4D36-9361-185F38DCD738Q37696051-C26A465E-3ACE-49C2-870B-E5061BDF9CE3Q38153167-880F39D1-1231-4276-ADA8-992C929C0C42Q39432546-6447E2AA-ED00-4D15-907F-DE524EB4770DQ39686990-32B42E8C-4C6C-458C-A016-7BA5572DDF96Q39958866-3297B64D-071C-4BAF-8E40-6C2096AF6F6CQ40366609-F20AD95C-83DD-41D4-A341-BC4F260EF02AQ40554448-F49CDA56-834F-44C6-B5D0-0C20B16AE698Q40873511-3A8F099A-4D90-438E-BDE9-06040FFFE333Q41201331-58CA8416-9A4F-4FCE-A1A5-A1D43CC78BD6Q42021639-88FC4675-9C71-496F-9026-756E11E1E4FFQ42081006-EBA3ED3D-0A1C-42F0-BCD0-FB464591C57AQ42106386-01180AA7-5DDD-4922-97FD-4989F1A1083EQ43207093-6EC195E8-25E8-4BC4-BDF1-E71EB54E253FQ47096979-284BABB0-E410-47B9-99D4-9C58B9C8B3F6Q47148082-AD8E9863-ED28-4E85-ADA7-86B5955C6FA9Q47766904-D8F60264-0B91-4F10-A63C-05F783860B9BQ52082927-28494C28-DE92-4295-8529-D04E3C9C97B8
P2860
description
1981 nî lūn-bûn
@nan
1981年の論文
@ja
1981年論文
@yue
1981年論文
@zh-hant
1981年論文
@zh-hk
1981年論文
@zh-mo
1981年論文
@zh-tw
1981年论文
@wuu
1981年论文
@zh
1981年论文
@zh-cn
name
Secondary structure formation during RNA synthesis
@ast
Secondary structure formation during RNA synthesis
@en
type
label
Secondary structure formation during RNA synthesis
@ast
Secondary structure formation during RNA synthesis
@en
prefLabel
Secondary structure formation during RNA synthesis
@ast
Secondary structure formation during RNA synthesis
@en
P2860
P356
P1476
Secondary structure formation during RNA synthesis
@en
P2093
P2860
P304
P356
10.1093/NAR/9.19.5109
P407
P577
1981-10-01T00:00:00Z