about
Direct observation of structure and dynamics during phase separation of an elastomeric protein.Early nucleolar disorganization in Dictyostelium cell death.Protein Quality Control and the Amyotrophic Lateral Sclerosis/Frontotemporal Dementia ContinuumRNA metabolism in neurodegenerative disease.The Cajal body and the nucleolus: "In a relationship" or "It's complicated"?The ApaH-like phosphatase TbALPH1 is the major mRNA decapping enzyme of trypanosomes.Spatial patterning of P granules by RNA-induced phase separation of the intrinsically-disordered protein MEG-3Independent active and thermodynamic processes govern the nucleolus assembly in vivo.Genetic and epigenetic control of the spatial organization of the genome.RNA Localization in the Vertebrate Oocyte: Establishment of Oocyte Polarity and Localized mRNA Assemblages.mRNPs meet stress granules.FUS inclusions disrupt RNA localization by sequestering kinesin-1 and inhibiting microtubule detyrosination.On the origin of non-membrane-bound organelles, and their physiological function.Chromatin loops and causality loops: the influence of RNA upon spatial nuclear architecture.The code and beyond: transcription regulation by the RNA polymerase II carboxy-terminal domain.Activation of transcription enforces the formation of distinct nuclear bodies in zebrafish embryos.Post-transcriptional control of gene expression following stress: the role of RNA-binding proteins.Polyphosphate granule biogenesis is temporally and functionally tied to cell cycle exit during starvation in Pseudomonas aeruginosaProteostasis disturbance in amyotrophic lateral sclerosis.All about the RNA after all.RNA-Seeded Functional Amyloids Balance Growth and Survival.Specific genomic cues regulate Cajal body assemblyPhosphorylation of the FUS low-complexity domain disrupts phase separation, aggregation, and toxicity.Splicing Activation by Rbfox Requires Self-Aggregation through Its Tyrosine-Rich Domain.The Secret Life of RNA: Lessons from Emerging Methodologies.The Physiological and Pathological Implications of the Formation of Hydrogels, with a Specific Focus on Amyloid Polypeptides.Coordinating cell cycle-regulated histone gene expression through assembly and function of the Histone Locus Body.Electrostatic Interactions in Protein Structure, Folding, Binding, and Condensation.Gold nanourchins and celastrol reorganize the nucleo- and cytoskeleton of glioblastoma cells.Alternative mRNA processing sites decrease genetic variability while increasing functional diversity.From Heterochromatin to Long Noncoding RNAs in Drosophila: Expanding the Arena of Gene Function and Regulation.Stress-dependent miR-980 regulation of Rbfox1/A2bp1 promotes ribonucleoprotein granule formation and cell survival.Reversible generation of coacervate droplets in an enzymatic network.TAR DNA-binding protein 43 (TDP-43) liquid-liquid phase separation is mediated by just a few aromatic residues.Mechanistic View of hnRNPA2 Low-Complexity Domain Structure, Interactions, and Phase Separation Altered by Mutation and Arginine Methylation.Splicing and transcription touch base: co-transcriptional spliceosome assembly and function.Conformational switching within dynamic oligomers underpins toxic gain-of-function by diabetes-associated amyloid.Specific Spatial Localization of Actin and DNA in a Water/Water Microdroplet: Self-Emergence of a Cell-Like Structure.Dual roles for ATP in the regulation of phase separated protein aggregates in oocyte nucleoliStructural centrosome aberrations sensitize polarized epithelia to basal cell extrusion
P2860
Q30401989-C59C65ED-AB0B-4B8C-8E6C-7ADE6CB2843EQ30844769-4961730A-1D0F-42A6-88DA-08E83DC59A94Q33653996-13BF8F24-ACE1-49F1-92B4-A466EAC2EF21Q33746283-22710F62-314B-4207-978A-3B303848E599Q34047421-646BBE2F-346B-4B0E-9300-639E3C6F8E81Q36409252-B7FE31AD-B533-488B-B018-6F03BDB46547Q37603781-1ACD626D-2853-4CA9-BEFB-5002632D6DB4Q37640420-6EB05649-2A50-4384-AD76-23F0B218D8E8Q37686820-4B62E048-488D-48B1-8F3A-6C0E1A6877ECQ38646606-2FEA08A5-9BC6-4A1E-B245-DB33D7936852Q38659834-10D4C50E-54E5-4BA6-8396-8C24E25DA1E4Q38712151-101B9293-4BB0-496F-B23A-4528B95052D0Q38732836-38CA84A1-C36A-4B7A-B6A0-F4152DB38C1FQ38737169-F26E4C51-BD7C-40A8-8B2A-ABB24ACF6A3CQ39156173-213C19A3-9B92-45AA-AD51-177C7AF31EE5Q39178331-294F3F2F-F8DD-41D0-B0DA-D7989A6D49E1Q39436212-B1BE337A-F858-4910-B62F-03096E756944Q41710108-45AB8487-F9A0-488E-B32D-FC1FF976E4C2Q41991266-ED56F970-90E0-49A4-B26C-36BC53CB228FQ42143506-2296341E-3FFC-4138-B5D7-89164E3E5477Q42329738-A50E7909-2425-46B8-A59B-3E8980FDCE50Q42335063-DCEC5B76-53F4-4A6D-BB19-00FCFA31AC5CQ42378053-B9499180-8734-41A9-9005-67B57D96B81EQ46113977-BAC9C98D-2FDC-4DC4-A34E-1800419FAAF0Q46262964-E91238D9-4326-4602-835D-783EBC5B499FQ46302852-418F1897-D016-4674-835D-6BF2A90EE2F2Q47110577-CF1BCC21-F7ED-4984-A59D-7B310B780659Q47214435-372A829F-227E-4D7F-8628-D46C14163875Q47225712-12AD66F7-4138-4DA3-9847-CB89052CAC01Q47445724-B4EC8286-FEB2-43A2-99AD-DA46F0BBB96AQ47942917-CB292279-A347-4F1C-B25D-10635B881A00Q48190107-148BB74D-D306-49C9-870D-93E3280193A5Q49331084-C3BDD69D-FCF4-4A6F-886A-5341AF2762ACQ52365240-720FBA67-5A6F-41C6-91D4-D76F5029F036Q52390768-BBA52922-6B29-48A1-A95A-387A7FA159D9Q52547079-036DAD37-19C4-4980-B19B-16AA0A29FDA6Q52608994-689BC523-350C-47D1-9CD6-B282FCE2B0AFQ52718026-ED9ECB29-B140-45AD-8D67-F954ACFE1896Q56534985-C6B2C2B7-0314-41ED-95CE-2947851BE7F3Q57985050-A82941AC-9720-4AA8-B7E5-5DCD5C6139FA
P2860
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
Droplet organelles?
@en
type
label
Droplet organelles?
@en
prefLabel
Droplet organelles?
@en
P2093
P2860
P356
P1433
P1476
Droplet organelles?
@en
P2093
Edward M Courchaine
Karla M Neugebauer
P2860
P304
P356
10.15252/EMBJ.201593517
P407
P577
2016-06-29T00:00:00Z