about
The distributions, mechanisms, and structures of metabolite-binding riboswitchesMitochondrial enzyme rhodanese is essential for 5 S ribosomal RNA import into human mitochondriaRNA structural requirements for the association of the spliceosomal hPrp31 protein with the U4 and U4atac small nuclear ribonucleoproteinsIdentification of dynamical hinge points of the L1 ligase molecular switchThe emerging field of RNA nanotechnologyTurning limited experimental information into 3D models of RNAThe structure of a tetrahydrofolate-sensing riboswitch reveals two ligand binding sites in a single aptamerMolecular modelling of the GIR1 branching ribozyme gives new insight into evolution of structurally related ribozymesProhead RNA: a noncoding viral RNA of novel structure and functionLong Intergenic Non-Coding RNAs: Novel Drivers of Human Lymphocyte DifferentiationRecognition of S-adenosylmethionine by riboswitchesH/ACA small nucleolar RNA pseudouridylation pockets bind substrate RNA to form three-way junctions that position the target U for modificationStructural Insights into Ligand Recognition by a Sensing Domain of the Cooperative Glycine RiboswitchThe structural stabilization of the three-way junction by Mg(II) represents the first step in the folding of a group II intronStructure of the yeast U2/U6 snRNA complexStructure and sequence elements of the CR4/5 domain of medaka telomerase RNA important for telomerase functionThe Structural Basis of Pathogenic Subgenomic Flavivirus RNA (sfRNA) ProductionStructural insights into recognition of c-di-AMP by the ydaO riboswitchCrystal structure of a c-di-AMP riboswitch reveals an internally pseudo-dimeric RNASecondary structure of a conserved domain in the intron of influenza A NS1 mRNACommentary: History of the ribosome and the origin of translationComputing the origin and evolution of the ribosome from its structure - Uncovering processes of macromolecular accretion benefiting synthetic biologyRibozymes, riboswitches and beyond: regulation of gene expression without proteinsAncestral Insertions and Expansions of rRNA do not Support an Origin of the Ribosome in Its Peptidyl Transferase CenterEvolution of the ribosome at atomic resolutionRNA secondary structure analysis using RNAstructureQuantum chemical studies of nucleic acids: can we construct a bridge to the RNA structural biology and bioinformatics communities?The building blocks and motifs of RNA architectureIn vitro reconstitution of an mRNA-transport complex reveals mechanisms of assembly and motor activation.Phylogenetic Reconstruction of the Calosphaeriales and Togniniales Using Five Genes and Predicted RNA Secondary Structures of ITS, and Flabellascus tenuirostris gen. et sp. novPredicting helical topologies in RNA junctions as tree graphs.RNA-Puzzles Round III: 3D RNA structure prediction of five riboswitches and one ribozymeFinding 3D motifs in ribosomal RNA structures.COGNAC: a web server for searching and annotating hydrogen-bonded base interactions in RNA three-dimensional structures.Theory and Modeling of RNA Structure and Interactions with Metal Ions and Small Molecules.Regulation of PKR by HCV IRES RNA: importance of domain II and NS5ASecondary structure of a conserved domain in an intron of influenza A M1 mRNAThe purine riboswitch as a model system for exploring RNA biology and chemistryEnhancing immunomodulation on innate immunity by shape transition among RNA triangle, square and pentagon nanovehicles.Molecular dynamics simulations suggest that RNA three-way junctions can act as flexible RNA structural elements in the ribosome
P2860
Q21184134-8E40F3B4-8D5F-4384-8DEC-EF3CEE5738D0Q24293228-FCBB5747-D650-4B4F-BEE7-5BEEA6001B1AQ24297661-42797454-BC29-400F-911C-E44036D33C55Q24615974-11141D9C-1743-4CB1-B4FC-E03823DEFCF3Q24623416-75A0A836-E674-460B-9C18-F8B6B7717D2DQ24630208-D570A82B-2825-4C21-AB1E-98D9C93A717BQ24634946-D9E88BBD-839E-4528-AB47-A51ECF5E799FQ24643381-60E0C8F0-1B4D-462D-9C06-69CACF9D7075Q26774780-54107FD8-F3A2-421E-B3EC-B61E6A027A47Q26828561-736E4C9D-9962-441F-BCF7-4B023463A203Q27012766-532AF22A-9E16-4199-ACB0-CE090B212ED6Q27644371-AB5B57FA-5C84-4B60-9890-0A6454795B53Q27666293-732BDA7F-01DA-444B-B375-288F6C17800AQ27675662-17AD3D2C-324C-49B0-999B-E926B2D30006Q27677233-EB768F19-9C10-407D-9BF3-ACEBDD676BB7Q27680870-4D2159B0-C868-404C-9D08-5D743C5855C0Q27683468-BF260FC2-B94D-4D42-972E-8D2BF9BA5A41Q27684917-6C525CFA-13DD-44C1-B95D-C89F866FAE81Q28248973-072CAD0D-5178-432D-8AD4-7B0CD89C1952Q28536401-704C21B4-0768-405B-8092-83CF6E497EAAQ28583162-5A833FAE-E267-40AB-8998-7C8486CE540EQ28601049-BC0E578E-017E-4590-BC61-F65D11921759Q28603616-A01DC31E-92CD-4484-98F3-237980803366Q28608244-5F53B441-1172-47A8-BEB7-A9C59C82F20DQ28655503-393437ED-A0A2-43D2-A263-9E193D67811FQ28655982-DDC378A2-3A0E-4370-B46B-7EB02AD6C1B7Q28834147-F4907D1F-D473-4778-AB8C-1688D346C48AQ29031588-02B9BCB3-0077-4EDE-8F94-DD703BE9C2F1Q30560522-21CEE6E3-13AF-46E3-848A-A7EA61065CC8Q31033704-8432D3FD-EBB5-4379-8FCB-DB6375AF9774Q31131985-68A9694D-9241-40A6-B55C-DDD37D74229EQ33364669-3D4E949E-0BC9-4707-BDFA-3C8234E9BCD9Q33401462-D53EAD65-D87A-4F36-AC66-B317E703A251Q33860605-2D0C2039-223E-44BD-A0D2-3DBF35B2D8F4Q33901748-2412CFF1-3C78-482C-8702-3493FB65F1B1Q33987197-E6671687-BDF2-4A1A-A77C-481DB34D3C5EQ34070147-74E25819-BA81-4EF1-9842-220AB0C31EF8Q34105617-D205D7F8-A451-49BC-996B-05D9000A0CC6Q34115320-82E4FA4B-6FA8-4C76-A512-66BDD4376BE0Q34189280-29455941-2988-4D36-97C9-8CBB01EC6304
P2860
description
2006 nî lūn-bûn
@nan
2006年の論文
@ja
2006年学术文章
@wuu
2006年学术文章
@zh
2006年学术文章
@zh-cn
2006年学术文章
@zh-hans
2006年学术文章
@zh-my
2006年学术文章
@zh-sg
2006年學術文章
@yue
2006年學術文章
@zh-hant
name
Topology of three-way junctions in folded RNAs.
@en
Topology of three-way junctions in folded RNAs.
@nl
type
label
Topology of three-way junctions in folded RNAs.
@en
Topology of three-way junctions in folded RNAs.
@nl
prefLabel
Topology of three-way junctions in folded RNAs.
@en
Topology of three-way junctions in folded RNAs.
@nl
P2860
P356
P1433
P1476
Topology of three-way junctions in folded RNAs.
@en
P2093
Aurélie Lescoute
P2860
P356
10.1261/RNA.2208106
P407
P50
P577
2006-01-01T00:00:00Z