Pre-mRNA secondary structures influence exon recognition.
about
Novel splicing factor RBM25 modulates Bcl-x pre-mRNA 5' splice site selectionRole of RNA structure in regulating pre-mRNA splicingSplicing regulation: from a parts list of regulatory elements to an integrated splicing codeA short antisense oligonucleotide masking a unique intronic motif prevents skipping of a critical exon in spinal muscular atrophyIdentification of small molecule and genetic modulators of AON-induced dystrophin exon skipping by high-throughput screeningGlobal or local? Predicting secondary structure and accessibility in mRNAsEvidence for widespread association of mammalian splicing and conserved long-range RNA structuresA conditional random fields method for RNA sequence-structure relationship modeling and conformation samplingComputational prediction of splicing regulatory elements shared by Tetrapoda organismsAlternative splicing of Alu exons--two arms are better than oneMechanisms of alternative splicing regulation: insights from molecular and genomics approachesThe secondary structure of the human immunodeficiency virus type 1 transcript modulates viral splicing and infectivity.Intronic Alus influence alternative splicing.Alu exonization events reveal features required for precise recognition of exons by the splicing machineryFunctional properties and evolutionary splicing constraints on a composite exonic regulatory element of splicing in CFTR exon 12The intronic splicing code: multiple factors involved in ATM pseudoexon definition.A birth of bipartite exon by intragenic deletionPrediction of alternatively spliced exons using support vector machinesGraphProt: modeling binding preferences of RNA-binding proteins.Competing upstream 5' splice sites enhance the rate of proximal splicing.GC content around splice sites affects splicing through pre-mRNA secondary structuresGenomic features defining exonic variants that modulate splicing.The organization of nucleosomes around splice sites.Complexity of the 5'UTR region of the CLCN5 gene: eleven 5'UTR ends are differentially expressed in the human kidneyMuscleblind-like 1 (Mbnl1) promotes insulin receptor exon 11 inclusion via binding to a downstream evolutionarily conserved intronic enhancer.Expression and regulation of a low-density lipoprotein receptor exon 12 splice variant.Multiple tandem splicing silencer elements suppress aberrant splicing within the long exon 26 of the human Apolipoprotein B gene.Ab initio prediction of mutation-induced cryptic splice-site activation and exon skipping.Stress-induced endogenous siRNAs targeting regulatory intron sequences in Brachypodium.RNA structure and the mechanisms of alternative splicing.RNA folding in transcription elongation complex: implication for transcription termination.Structural basis of pre-mRNA recognition by the human cleavage factor Im complexKey features of the two-intron Saccharomyces cerevisiae gene SUS1 contribute to its alternative splicing.Efficient internal exon recognition depends on near equal contributions from the 3' and 5' splice sites.Splicing predictions reliably classify different types of alternative splicing.RNA Structures as Mediators of Neurological Diseases and as Drug Targets.RNA secondary structure mediates alternative 3'ss selection in Saccharomyces cerevisiaeParallel computation of genome-scale RNA secondary structure to detect structural constraints on human genome.In silico and in vitro evaluation of exonic and intronic off-target effects form a critical element of therapeutic ASO gapmer optimization.The role of short RNA loops in recognition of a single-hairpin exon derived from a mammalian-wide interspersed repeat.
P2860
Q24318369-3CE7BECD-A4C0-4FA1-90FA-8A298D314703Q24631714-FBC07617-064F-45AE-9751-BD787CDE9986Q24642620-9AFC41A0-2D30-4F52-8AF4-2EC78CCAB87CQ28244480-A5822B4B-ABFE-4864-8A4D-B14D72AD22CBQ28472268-9BA90840-4B35-413F-9FA7-7C89BBF45B5DQ28727954-787AC222-58B4-466E-8C07-3B7DC58E71C9Q28732709-522015FC-8845-424C-9FB6-4DE54659F470Q28743534-FFCFE618-A080-4A7D-9425-44A3FD1F6C8DQ28750125-2B308733-F8D4-410D-A3B9-AD4D5BBF561DQ28754872-C249AF39-D97F-45A3-8457-F9227DCCB846Q29615084-5EB08BDF-EF39-4CA0-A9F6-A4524004DF1BQ30440740-01BEAFF7-05AE-431B-A190-12B26029E1A2Q33372114-DCB0D3B4-BC84-458E-AB83-CE028DD2B8A7Q33415448-C5C05D12-C269-490B-91D9-600C85C55BE3Q33608817-092D017C-81F1-45C9-A718-07625B84FADCQ33690608-BE4F8664-AF8E-471F-ABE2-7881754524C1Q33718512-45E0150C-BEA8-4E6B-AB11-E7955142CD98Q33739074-D8FCDCF9-FD61-4E58-BFE4-07A54B39892AQ33741982-78BB19D1-F2AA-4EFA-9B52-741AEAD95D1BQ33769266-D4144410-2CDC-4EC4-9670-0F53C3647DBAQ33807911-AF7623F2-FD0A-4070-8E67-5D5800618FB5Q33861632-5CB763A5-AD75-4515-BE0F-A61C46E89971Q33871238-223F0653-38DF-4768-A3CC-2C08FC4CF0C2Q33929370-3EFB4FC1-5C46-4548-867D-61596B2C0B54Q34055812-49E25AFE-AE41-4BF1-AE1B-D22314E0992CQ34385583-03FC445D-3E3A-4758-9118-76F06F923CF0Q34580416-DF94C993-7327-4BDD-A9D6-9402B527760AQ34921189-71354007-59C9-4EC0-9E34-67976410D68BQ35113601-B337AA94-1D9A-43F4-B326-D92357724F87Q35146258-B885C75E-9989-41A8-A841-F592B99047EAQ35213191-58179B44-4D6A-416E-8338-B9C7FA9CA2BEQ35348899-8543DCC8-0DAF-46B3-901B-08691E3C28BAQ35447539-71417935-81F0-4A17-8AD1-2E319D1EC0C8Q35468251-3340AE21-22F2-45EC-924A-01C7CAE2306BQ35534944-8DB2736A-F009-4626-AA65-1A711C06EA54Q35868044-6B05C067-DB32-4A2E-BF82-6E04EAEA35C2Q35981884-13F5136A-F12F-4DAC-93FD-76EE228BBE9EQ36011235-C4858C42-CEE1-4230-9AC9-0F0B352B2E6EQ36160667-AAEDEA8A-AF08-4470-B58D-41D66E148913Q36190201-42D1E18A-2DB6-4392-B26C-E013AF1122FC
P2860
Pre-mRNA secondary structures influence exon recognition.
description
2007 nî lūn-bûn
@nan
2007 թուականի Նոյեմբերին հրատարակուած գիտական յօդուած
@hyw
2007 թվականի նոյեմբերին հրատարակված գիտական հոդված
@hy
2007年の論文
@ja
2007年論文
@yue
2007年論文
@zh-hant
2007年論文
@zh-hk
2007年論文
@zh-mo
2007年論文
@zh-tw
2007年论文
@wuu
name
Pre-mRNA secondary structures influence exon recognition.
@ast
Pre-mRNA secondary structures influence exon recognition.
@en
Pre-mRNA secondary structures influence exon recognition.
@nl
type
label
Pre-mRNA secondary structures influence exon recognition.
@ast
Pre-mRNA secondary structures influence exon recognition.
@en
Pre-mRNA secondary structures influence exon recognition.
@nl
prefLabel
Pre-mRNA secondary structures influence exon recognition.
@ast
Pre-mRNA secondary structures influence exon recognition.
@en
Pre-mRNA secondary structures influence exon recognition.
@nl
P2093
P2860
P1433
P1476
Pre-mRNA secondary structures influence exon recognition
@en
P2093
Michael Hiller
Stefan Stamm
Zhaiyi Zhang
P2860
P356
10.1371/JOURNAL.PGEN.0030204
P577
2007-11-01T00:00:00Z