FUS Phase Separation Is Modulated by a Molecular Chaperone and Methylation of Arginine Cation-π Interactions

Qamar, Seema; Wang, Guo Zhen; Randle, Suzanne J.; Ruggeri, Francesco Simone; Varela, Juan A.; Lin, Julie Qiaojin; Phillips, Emma Claire; Miyashita, Akinori; Williams, Declan; Ströhl, Florian; Meadows, William; Ferry, Rodylyn Rose; Dardov, Victoria; Tartaglia, Gian Gaetano; Farrer, Lindsay A.; Schierle, Gabriele S. Kaminski; Kaminski, Clemens F.; Holt, Christine E.; Fraser, Paul E.; Schmitt‐Ulms, Gerold; Klenerman, David; Knowles, Tuomas P. J.; Vendruscolo, Michele; George-Hyslop, Peter St

doi:10.1016/j.cell.2018.03.056

Cited by 700 publications

(857 citation statements)

References 30 publications

(38 reference statements)

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“…In support of the notion that local concentrations of negative charge play major roles for LLPS, nucleic acid‐mimicking biopolymers such as poly‐ADP‐ribose (PAR) induced phase transitions in vitro and in vivo and phosphorylation of low complexity regions in aggregation‐prone proteins disrupted their phase separation . Furthermore, also post‐translational modifications (i.e., methylation) affecting the charge of particular amino acids in IDR‐containing proteins disrupted cation‐pi interactions thereby modulating LLPS . Moreover, introducing additional negative charge to PLD‐containing proteins enhanced phase separation mediated by intermolecular interactions among PLDs and RRMs .…”

Section: Which Biophysical Properties Of Rnas Could Affect Llps?mentioning

confidence: 98%

“…Intriguingly, while the contribution of the biophysical characteristics of RNA to these processes is being increasingly appreciated, it remains unclear how particular RNA properties are modulated at the level of individual RNAs. In the following paragraphs, we list the known characteristics and effects of post‐transcriptional chemical modifications in RNA and discuss how such modifications could be a means to dynamically regulate RNA properties during LLPS and in analogy to the recently reported roles for post‐translational modifications of proteins in the process …”

Section: Rna Modifications: Potential For Dynamic Regulation Of Rna Pmentioning

confidence: 99%

“…In addition, transcriptome‐wide mapping of in vivo RNA structures revealed that m 6 A was indeed enriched in unstructured RNA regions, indicating the potential for particular RNA modifications in regulating structure. Of note, m 5 C changes the dipole moment of the modified base, thereby impacting the aromatic amino acid‐cation interactions, which have been shown to influence LLPS . Furthermore, particular methyl groups (i.e., m 5 C or m 6 A) introduce a hydrophobic moiety to the RNA major groove, which cannot be fully solvated.…”

Section: Rna Modifications: Potential For Dynamic Regulation Of Rna Pmentioning

confidence: 99%

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RNAs, Phase Separation, and Membrane‐Less Organelles: Are Post‐Transcriptional Modifications Modulating Organelle Dynamics?

Drino¹,

Schaefer²

2018

BioEssays

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Membranous organelles allow sub‐compartmentalization of biological processes. However, additional subcellular structures create dynamic reaction spaces without the need for membranes. Such membrane‐less organelles (MLOs) are physiologically relevant and impact development, gene expression regulation, and cellular stress responses. The phenomenon resulting in the formation of MLOs is called liquid–liquid phase separation (LLPS), and is primarily governed by the interactions of multi‐domain proteins or proteins harboring intrinsically disordered regions as well as RNA‐binding domains. Although the presence of RNAs affects the formation and dissolution of MLOs, it remains unclear how the properties of RNAs exactly contribute to these effects. Here, the authors review this emerging field, and explore how particular RNA properties can affect LLPS and the behavior of MLOs. It is suggested that post‐transcriptional RNA modification systems could be contributors for dynamically modulating the assembly and dissolution of MLOs.

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Section: Which Biophysical Properties Of Rnas Could Affect Llps?mentioning

confidence: 98%

Section: Rna Modifications: Potential For Dynamic Regulation Of Rna Pmentioning

confidence: 99%

Section: Rna Modifications: Potential For Dynamic Regulation Of Rna Pmentioning

confidence: 99%

See 1 more Smart Citation

RNAs, Phase Separation, and Membrane‐Less Organelles: Are Post‐Transcriptional Modifications Modulating Organelle Dynamics?

Drino¹,

Schaefer²

2018

BioEssays

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“…The interaction between FUS and its import receptor, karyopherin‐ß2 (Karβ2)/importin‐ß2, significantly diminishes FUS aggregation in vitro . The proline/tyrosine‐nuclear localization signal of FUS is frequently mutated in ALS, precluding the FUS/Karβ2 interaction and accelerating FUS aggregation (Figure C). Inhibition of the molecular chaperone, HSP70, also slows the internal dynamics of cellular SGs .…”

Section: Biomolecular Condensates In Neurodegenerationmentioning

confidence: 99%

“…Inhibition of the molecular chaperone, HSP70, also slows the internal dynamics of cellular SGs . Interestingly, chaperone inhibition also delays SG disassembly post‐stress, suggesting that SG persistence and aggregation may be linked. Supporting this, constitutively inducing SG protein phase separation in cells (using optogenetic oligomerization tags) causes their aggregation .…”

Section: Biomolecular Condensates In Neurodegenerationmentioning

confidence: 99%

Biomolecular condensates in neurodegeneration and cancer

Spannl

Tereshchenko

Mastromarco

et al. 2019

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The intracellular environment is partitioned into functionally distinct compartments containing specific sets of molecules and reactions. Biomolecular condensates, also referred to as membrane‐less organelles, are diverse and abundant cellular compartments that lack membranous enclosures. Molecules assemble into condensates by phase separation; multivalent weak interactions drive molecules to separate from their surroundings and concentrate in discrete locations. Biomolecular condensates exist in all eukaryotes and in some prokaryotes, and participate in various essential house‐keeping, stress‐response and cell type‐specific processes. An increasing number of recent studies link abnormal condensate formation, composition and material properties to a number of disease states. In this review, we discuss current knowledge and models describing the regulation of condensates and how they become dysregulated in neurodegeneration and cancer. Further research on the regulation of biomolecular phase separation will help us to better understand their role in cell physiology and disease.

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Dissection of FUS domains involved in regulation of SnRNP70 gene expression

Nakaya

2020

FEBS Letters

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FUS is one of the causative factors of amyotrophic lateral sclerosis. Loss and/or gain of its physiological functions has been believed to be linked to the pathogenesis of this condition. However, its functions remain incompletely understood. This study dissected the domains of FUS regulating the expression of SnRNP70, which functions in mRNA splicing. Biochemical analysis revealed that all FUS domains except for RGG1 contribute to determining Snrnp70 transcript abundance and thus its protein abundance. RNA‐Seq analysis using the Gly‐rich domain‐deleted mutant coupled with snRNP70 knockdown revealed that FUS has a potential to regulate gene expression in both snRNP70‐dependent and snRNP70‐independent manners through the Gly‐rich domain. These results provide insight into molecular details of the regulation of gene expression by FUS.

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FUS Phase Separation Is Modulated by a Molecular Chaperone and Methylation of Arginine Cation-π Interactions

Cited by 700 publications

References 30 publications

RNAs, Phase Separation, and Membrane‐Less Organelles: Are Post‐Transcriptional Modifications Modulating Organelle Dynamics?

RNAs, Phase Separation, and Membrane‐Less Organelles: Are Post‐Transcriptional Modifications Modulating Organelle Dynamics?

Biomolecular condensates in neurodegeneration and cancer

Dissection of FUS domains involved in regulation of SnRNP70 gene expression

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