Cell-free Formation of RNA Granules: Low Complexity Sequence Domains Form Dynamic Fibers within Hydrogels

Kato, Masato; Han, Tina W.; Xie, Shanhai; Shi, Kevin; Du, Xiaoqiang; Wu, Leeju C.; Mirzaei, Hamid; Goldsmith, Elizabeth J.; Longgood, Jamie; Pei, Jimin; Grishin, Nick V.; Frantz, Douglas E.; Schneider, Jay W.; Chen, She; Li, Lin; Sawaya, M.R.; Eisenberg, David; Tycko, Robert; McKnight, Steven L.

doi:10.1016/j.cell.2012.04.017

Cited by 1,757 publications

(2,265 citation statements)

References 51 publications

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“…The growth rate and extent of droplet formation depended on the degree of phosphorylation, whereby the introduced negative charges (as in tau441E17) could only account for some of this effect; it seems likely that the addition of phosphate groups at certain positions is relevant for the conformational changes that can lead to LLPS of tau. The lack of tau droplet coalescence suggests a fast increase in the viscoelasticity of phospho‐tau droplets preventing droplet fusion (Abbott, 1977; Gu et al , 2011); this is characteristic for the “maturation” of liquids into hydrogels (Kato et al , 2012). The subsequent deformation of p‐tau441 droplets and the formation of tau aggregates in the droplets are strong indicators for the further transition of the tau droplets from a gel‐like into an aggregate state of lower energy; a similar maturation has been described for FUS (Patel et al , 2015).…”

Section: Resultsmentioning

confidence: 99%

“…To evaluate the transition from a liquid to a gel‐like state, which is characterized by an increase in viscoelasticity and, hence, a decrease in molecular diffusion rates in the gel state (Kato et al , 2012), we performed FRAP microscopy of freshly prepared p‐tau441 droplets that contained 10% of fluorescently labeled protein of the same kind (p‐tau441‐dl488). When bleaching the entire droplets (Fig 4A) at different times after droplet initiation (addition of 10% PEG), we found a rapid decrease of recovery in the first 15 min and virtually no recovery after 30 min.…”

Section: Resultsmentioning

confidence: 99%

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Tau protein liquid–liquid phase separation can initiate tau aggregation

et al. 2018

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The transition between soluble intrinsically disordered tau protein and aggregated tau in neurofibrillary tangles in Alzheimer's disease is unknown. Here, we propose that soluble tau species can undergo liquid–liquid phase separation (LLPS) under cellular conditions and that phase‐separated tau droplets can serve as an intermediate toward tau aggregate formation. We demonstrate that phosphorylated or mutant aggregation prone recombinant tau undergoes LLPS, as does high molecular weight soluble phospho‐tau isolated from human Alzheimer brain. Droplet‐like tau can also be observed in neurons and other cells. We found that tau droplets become gel‐like in minutes, and over days start to spontaneously form thioflavin‐S‐positive tau aggregates that are competent of seeding cellular tau aggregation. Since analogous LLPS observations have been made for FUS, hnRNPA1, and TDP43, which aggregate in the context of amyotrophic lateral sclerosis, we suggest that LLPS represents a biophysical process with a role in multiple different neurodegenerative diseases.

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Section: Resultsmentioning

confidence: 99%

Section: Resultsmentioning

confidence: 99%

Tau protein liquid–liquid phase separation can initiate tau aggregation

et al. 2018

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“…Recent work strongly points to the ability of these domains to form functional interactions with specific sets of proteins bearing similar low‐complexity (or prion‐like) domains (Kato et al , 2012; Molliex et al , 2015). Currently, many questions remain about the molecular nature of these interactions inside RNP granules—that is, where each specific membraneless organelle falls on a continuum of molecular architectures (Aguzzi & Altmeyer, 2016) ranging from structured cross‐β amyloids to disordered polymer chains (Patel et al , 2015; Xiang et al , 2015; Boke et al , 2016).…”

Section: Discussionmentioning

confidence: 99%

“…Further efforts are needed to determine how phase separation is governed in cells where a multitude of components make up physiological granules. FUS‐containing membraneless organelles are not homogeneous structures composed of one protein and one RNA (Kato et al , 2012; Jain et al , 2016). The addition of other granule components and molecular chaperones in vivo may decrease the dominant role of charge–charge repulsion in the effect on phase separation observed in vitro .…”

Section: Discussionmentioning

confidence: 99%

Phosphorylation of the FUS low‐complexity domain disrupts phase separation, aggregation, and toxicity

et al. 2017

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Neuronal inclusions of aggregated RNA‐binding protein fused in sarcoma (FUS) are hallmarks of ALS and frontotemporal dementia subtypes. Intriguingly, FUS's nearly uncharged, aggregation‐prone, yeast prion‐like, low sequence‐complexity domain (LC) is known to be targeted for phosphorylation. Here we map in vitro and in‐cell phosphorylation sites across FUS LC. We show that both phosphorylation and phosphomimetic variants reduce its aggregation‐prone/prion‐like character, disrupting FUS phase separation in the presence of RNA or salt and reducing FUS propensity to aggregate. Nuclear magnetic resonance spectroscopy demonstrates the intrinsically disordered structure of FUS LC is preserved after phosphorylation; however, transient domain collapse and self‐interaction are reduced by phosphomimetics. Moreover, we show that phosphomimetic FUS reduces aggregation in human and yeast cell models, and can ameliorate FUS‐associated cytotoxicity. Hence, post‐translational modification may be a mechanism by which cells control physiological assembly and prevent pathological protein aggregation, suggesting a potential treatment pathway amenable to pharmacologic modulation.

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“…[106][107][108][109] These granules contain non-translating mRNAs and are involved in the control of all stages of mRNA turnover, including storage and degradation. The structure of these granules is highly dynamic, as their protein and RNA composition undergoes significant changes depending on the particular needs of the cell.…”

Section: Prions Amyloids and Mrna Turnovermentioning

confidence: 99%

Prions, amyloids, and RNA: Pieces of a puzzle

Nizhnikov

Antonets

Bondarev

et al. 2016

Prion

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ABSTRACT. Amyloids are protein aggregates consisting of fibrils rich in b-sheets. Growth of amyloid fibrils occurs by the addition of protein molecules to the tip of an aggregate with a concurrent change of a conformation. Thus, amyloids are self-propagating protein conformations. In certain cases these conformations are transmissible / infectious; they are known as prions. Initially, amyloids were discovered as pathological extracellular deposits occurring in different tissues and organs. To date, amyloids and prions have been associated with over 30 incurable diseases in humans and animals. However, a number of recent studies demonstrate that amyloids are also functionally involved in a variety of biological processes, from biofilm formation by bacteria, to long-term memory in animals. Interestingly, amyloid-forming proteins are highly overrepresented among cellular factors engaged in all stages of mRNA life cycle: from transcription and translation, to storage and degradation. Here we review rapidly accumulating data on functional and pathogenic amyloids associated with mRNA processing, and discuss possible significance of prion and amyloid networks in the modulation of key cellular functions.

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Cell-free Formation of RNA Granules: Low Complexity Sequence Domains Form Dynamic Fibers within Hydrogels

Cited by 1,757 publications

References 51 publications

Tau protein liquid–liquid phase separation can initiate tau aggregation

Tau protein liquid–liquid phase separation can initiate tau aggregation

Phosphorylation of the FUS low‐complexity domain disrupts phase separation, aggregation, and toxicity

Prions, amyloids, and RNA: Pieces of a puzzle

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