Widespread Expansion of Protein Interaction Capabilities by Alternative Splicing.
about
The contribution of intrinsically disordered regions to protein function, cellular complexity, and human diseaseThe BioGRID interaction database: 2017 updatePath2enet: generation of human pathway-derived networks in an expression specific context.Alternative splicing shapes transcriptome but not proteome diversity in Physcomitrella patens.Ligand Similarity Complements Sequence, Physical Interaction, and Co-Expression for Gene Function Prediction.Rewiring of the inferred protein interactome during blood development studied with the tool PPICompare.An alternative splicing program promotes adipose tissue thermogenesisDrosophila Protein Kinase CK2: Genetics, Regulatory Complexity and Emerging Roles during Development.Identification of protein features encoded by alternative exons using Exon Ontology.An Orchestrated Intron Retention Program in Meiosis Controls Timely Usage of Transcripts during Germ Cell DifferentiationComprehensive Analyses of Tissue-Specific Networks with Implications to Psychiatric Diseases.Domain-based prediction of the human isoform interactome provides insights into the functional impact of alternative splicing.Mechanisms of regulation and diversification of deubiquitylating enzyme function.Identification of a novel transcript isoform of the TTLL12 gene in human cancersGene co-expression analysis for functional classification and gene-disease predictions.Cellular identity at the single-cell level.Proteome-Scale Human Interactomics.The state of play in higher eukaryote gene annotation.Neurogenesis: Regulation by Alternative Splicing and Related Posttranscriptional Processes.Alternative splicing and the evolution of phenotypic novelty.Activation-Dependent TRAF3 Exon 8 Alternative Splicing Is Controlled by CELF2 and hnRNP C Binding to an Upstream Intronic Element.Intersections of post-transcriptional gene regulatory mechanisms with intermediary metabolism.pathDIP: an annotated resource for known and predicted human gene-pathway associations and pathway enrichment analysis.The Evolutionary Relationship between Alternative Splicing and Gene Duplication.Intron retention as a component of regulated gene expression programs.Caught in the act - protein adaptation and the expanding roles of the PACS proteins in tissue homeostasis and disease.Novel Rbfox2 isoforms associated with alternative exon usage in rat cortex and suprachiasmatic nucleus.The DDX6-4E-T interaction mediates translational repression and P-body assemblyPrediction of Protein-Protein Interactions.Living Organisms Author Their Read-Write Genomes in Evolution.Human canonical CD157/Bst1 is an alternatively spliced isoform masking a previously unidentified primate-specific exon included in a novel transcript.Revealing the Determinants of Widespread Alternative Splicing Perturbation in Cancer.ASpedia: a comprehensive encyclopedia of human alternative splicing.The comparison of alternative splicing among the multiple tissues in cucumber.Alternative RNA splicing in the endothelium mediated in part by Rbfox2 regulates the arterial response to low flow.Extended linkers improve the detection of PPIs by DHFR PCA in living cells.Expanding Proteoform Identifications in Top-Down Proteomic Analyses by Constructing Proteoform Families.Alternative start and termination sites of transcription drive most transcript isoform differences across human tissues.Microfluidic isoform sequencing shows widespread splicing coordination in the human transcriptome.A High-Resolution Genome-Wide CRISPR/Cas9 Viability Screen Reveals Structural Features and Contextual Diversity of the Human Cell-Essential Proteome.
P2860
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
P248
Q28080017-475F0710-23E7-4D86-9961-E6D63E494367Q28818109-F3D40179-899C-4CBD-B888-1AE2E385395EQ30490273-63F1F36D-89F8-4BEA-A63A-7E2BFE47A0A5Q33758717-7844E8F1-F408-419D-A481-A6171F352F29Q36088820-00499E3F-BFBC-4507-AEFD-183C4955DE3CQ36334812-BFCB56CE-3AF8-40E9-9CB8-8E424628DCE2Q37262475-EFA2B1BD-F0DB-4318-BE0A-5EA13F58159DQ37731305-07E19E08-05AE-4696-8C3D-203457A04153Q38434650-5A80EEF2-E517-4143-9FBE-04C30F9FE48FQ38435173-52164D25-ED5A-4ABF-9F1C-AB5F626EF11EQ38604254-F798B454-143A-498F-AC50-CCAAAEA40C12Q38605706-B85CD0D9-4958-42A7-B5B3-A9AE08D82650Q38687124-C9CCD021-FFEF-4FB2-9DEC-00E485905E96Q38740701-E62117B8-59DF-44FA-BA72-CE3A06397AEAQ38771720-FF507248-4C5C-4A64-8F05-74E4ED4C5DCDQ38909245-6FA385DE-C792-443E-84D0-245ADD7DD32DQ38913438-7A72AACF-728C-484D-BD24-1CDFFC663677Q38989042-0044CD5C-5BCD-45F4-87D9-1D9552EA7614Q39005973-5B8A68F6-C62E-48CE-9350-C9A730CA25DFQ39043804-69893479-2FDD-4A67-B7DC-8CC49FD3AFDFQ39056768-10211E09-5725-4588-ABBA-E8D22BD22123Q39088851-4B174FE7-82C4-45D6-923D-5D464C562752Q39144596-B6A67919-88D7-4B2D-B9C5-3486680E20DAQ39162652-298D2E75-C65E-4E37-8661-C769077D2D7CQ39229528-BC15588E-79A5-4595-BE21-D0444BF9DA53Q39286948-8E19482A-6B59-43B3-941E-C5CC95B55BD7Q41564932-FE36AC45-B845-45CB-9ED1-F3E84592522EQ42324171-43CC6490-1E0E-4E1C-9DF1-60D966BED148Q45943145-4BDF0739-5715-4311-8AD1-694F7523238DQ46246927-6B687DA4-D6CB-4D1D-B632-AFAF9770DB54Q46271115-5E0DCFED-211D-43CF-A363-51137C041689Q46430505-44436ED9-3498-4688-A1AA-6B10D5AD9D7AQ47129855-2ED6E147-DC56-40F8-B288-0EEFAF005BEBQ47169888-51C98EF6-9266-4C80-B07D-E80AE80EE1CCQ47224745-E0DF644A-4467-4DC6-8C1E-29D39B88CE62Q47285564-C94D60B7-2DE9-4341-9F42-70F2B56E8F22Q47308214-14F6AD0C-A5C6-4266-81F8-38E9257E77BEQ47334204-AB993B31-8BF6-4DDB-8B6D-8CEF6FADA336Q47340251-D890F073-FE89-4E45-AC15-90F7C4D43236Q47644126-6F40F77F-BF34-46D8-AE11-9ACBB622F938
P2860
Widespread Expansion of Protein Interaction Capabilities by Alternative Splicing.
description
2016 nî lūn-bûn
@nan
2016年の論文
@ja
2016年論文
@yue
2016年論文
@zh-hant
2016年論文
@zh-hk
2016年論文
@zh-mo
2016年論文
@zh-tw
2016年论文
@wuu
2016年论文
@zh
2016年论文
@zh-cn
name
Widespread Expansion of Protein Interaction Capabilities by Alternative Splicing.
@en
type
label
Widespread Expansion of Protein Interaction Capabilities by Alternative Splicing.
@en
prefLabel
Widespread Expansion of Protein Interaction Capabilities by Alternative Splicing.
@en
P2093
P2860
P50
P921
P1433
P1476
Widespread Expansion of Protein Interaction Capabilities by Alternative Splicing.
@en
P2093
Aaron Richardson
Andrew MacWilliams
Benoit Charloteaux
Brenda Andrews
Bridget E Begg
Charles Boone
David E Hill
Dawit Balcha
Frederick P Roth
P2860
P304
P356
10.1016/J.CELL.2016.01.029
P407
P577
2016-02-01T00:00:00Z