Controlling compartmentalization by non-membrane-bound organelles

Wheeler, Richard J.; Hyman, Anthony

doi:10.1098/rstb.2017.0193

Cited by 146 publications

(139 citation statements)

References 60 publications

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“…The products of this type of protein-protein interaction, where the interaction interface cannot be described by a single conformation, have been termed “fuzzy complexes” (Tompa and Fuxreiter, 2008). These dynamic interactions are also typical of the IDR-IDR interactions that facilitate formation of phase-separated biomolecular condensates (Alberti, 2017; Banani et al, 2017; Hyman et al, 2014; Shin and Brangwynne, 2017; Wheeler and Hyman, 2018). …”

Section: Introductionmentioning

confidence: 94%

Transcription Factors Activate Genes through the Phase-Separation Capacity of Their Activation Domains

Boija

Klein

Sabari

et al. 2018

Cell

1,377

1,301

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Gene expression is controlled by transcription factors (TFs) that consist of DNA-binding domains (DBDs) and activation domains (ADs). The DBDs have been well-characterized, but little is known about the mechanisms by which ADs effect gene activation. Here we report that diverse ADs form phase-separated condensates with the Mediator coactivator. For the OCT4 and GCN4 TFs, we show that the ability to form phase-separated droplets with Mediator in vitro and the ability to activate genes in vivo are dependent on the same amino acid residues. For the estrogen receptor (ER), a ligand-dependent activator, we show that estrogen enhances phase separation with Mediator, again linking phase separation with gene activation. These results suggest that diverse TFs can interact with Mediator through the phase-separating capacity of their ADs and that formation of condensates with Mediator is involved in gene activation.

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Section: Introductionmentioning

confidence: 94%

Transcription Factors Activate Genes through the Phase-Separation Capacity of Their Activation Domains

Boija

Klein

Sabari

et al. 2018

Cell

1,377

1,301

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“…[1,2] They play acrucial role for example in the compaction of polynucleotides and regulation of genetic expression. Herein, we describe the formation and photoswitchable behavior of light-responsive coacervate droplets prepared from mixtures of double-stranded DNAa nd an azobenzene cation.…”

mentioning

confidence: 99%

“…[1,2] They play acrucial role for example in the compaction of polynucleotides and regulation of genetic expression. [1,2] They play acrucial role for example in the compaction of polynucleotides and regulation of genetic expression.…”

mentioning

confidence: 99%

Photoswitchable Phase Separation and Oligonucleotide Trafficking in DNA Coacervate Microdroplets

et al. 2019

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Coacervate microdroplets produced by liquid-liquid phase separation have been used as synthetic protocells that mimic the dynamical organization of membrane-free organelles in living systems.A chieving spatiotemporal control over droplet condensation and disassembly remains challenging. Herein, we describe the formation and photoswitchable behavior of light-responsive coacervate droplets prepared from mixtures of double-stranded DNAa nd an azobenzene cation. The droplets disassemble and reassemble under UV and blue light, respectively,d ue to azobenzene trans/cis photoisomerisation. Sequestration and release of captured oligonucleotides followt he dynamics of phase separation such that light-activated transfer,m ixing,h ybridization, and trafficking of the oligonucleotides can be controlled in binary populations of the droplets.O ur results open perspectives for the spatiotemporal control of DNAc oacervates and provide as tep towards the dynamic regulation of synthetic protocells.The dynamic compartmentalization of biological components in space and time is ah allmark of functional synchronization in living cells.Biomolecular condensates formed via liquid-liquid phase separation are dynamic subcellular compartments that are actively formed and dissolved in response to environmental cues. [1,2] They play acrucial role for example in the compaction of polynucleotides and regulation of genetic expression. [3,4] Microdroplets produced in vitro by associative (coacervates) or segregative (aqueous two-phase systems) liquid-liquid phase separation have recently been used as synthetic models of dynamic protocells. [5][6][7] These membrane-free molecularly crowded compartments seques-ter functional biomolecules [5,8] and support enzymatic activity, [9,10] protein folding, [11] RNAc atalysis, [12,13] and cell-free protein expression. [14] Polynucleotides have been used as scaffold components to assemble coacervate droplets, [15][16][17][18][19] and selective sequestration of guest polynucleotides has been demonstrated in preformed coacervates. [12,20,21] Owing to their liquid-like nature and the weak molecular interactions,s ynthetic coacervate droplets can dynamically respond to external stimuli. [7,22,23] Fori nstance,t heir formation and dissolution has been achieved by changes in pH, [5] temperature, [24][25][26] ionic strength, [27,28] and more recently by enzymemediated catalytic activity. [15,[29][30][31][32] However,p latforms enabling the rapid and localized actuation of polynucleotide microphase separation have not yet been developed. Due to its favourable spectral and spatiotemporal capabilities,l ight holds great promise as aprogrammable trigger for controlling the reversible assembly and disassembly of coacervate droplets.L ight has been used to control synthetic microcompartments, [33][34][35] trigger biomolecular condensation in cellulo via optogenetic tools, [36,37] promote the dynamical shaping of soft colloids, [38] and induce the reversible compaction of single DNAc hains. [39][40][41] Here,w ee xploit t...

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“…Af ull description of thesei nteractions is very challenging, [25] butq uantitative image analysis, together with in vitro reconstitution by using well-defined solution compositions, can shed light on the physicochemical properties of these systems. [43] Biomolecular condensates show intricated ynamics: [5] their formation and dissolution are rapidly triggered by subtle changes in their concentrations or in the solution conditions, and they easily exchange matter with their surroundings. [43] Biomolecular condensates show intricated ynamics: [5] their formation and dissolution are rapidly triggered by subtle changes in their concentrations or in the solution conditions, and they easily exchange matter with their surroundings.…”

Section: Bridging the Gap With Living Cells:i Ntracellular Biomoleculmentioning

confidence: 99%

Dynamic Synthetic Cells Based on Liquid–Liquid Phase Separation

2019

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Living cells have long been a source of inspiration for chemists. Their capacity of performing complex tasks relies on the spatiotemporal coordination of matter and energy fluxes. Recent years have witnessed growing interest in the bottom‐up construction of cell‐like models capable of reproducing aspects of such dynamic organisation. Liquid–liquid phase‐separation (LLPS) processes in water are increasingly recognised as representing a viable compartmentalisation strategy through which to produce dynamic synthetic cells. Herein, we highlight examples of the dynamic properties of LLPS used to assemble synthetic cells, including their biocatalytic activity, reversible condensation and dissolution, growth and division, and recent directions towards the design of higher‐order structures and behaviour.

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Controlling compartmentalization by non-membrane-bound organelles

Cited by 146 publications

References 60 publications

Transcription Factors Activate Genes through the Phase-Separation Capacity of Their Activation Domains

Transcription Factors Activate Genes through the Phase-Separation Capacity of Their Activation Domains

Photoswitchable Phase Separation and Oligonucleotide Trafficking in DNA Coacervate Microdroplets

Dynamic Synthetic Cells Based on Liquid–Liquid Phase Separation

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