Light-Guided Motility of a Minimal Synthetic Cell

Bartelt, Solveig Mareike; Steinkühler, Jan; Dimova, Rumiana; Wegner, Seraphine V.

doi:10.1021/acs.nanolett.8b03469

Cited by 50 publications

(62 citation statements)

References 31 publications

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“…[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. 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. [12,20,21] Owing to their liquid-like nature and the weak molecular interactions,s ynthetic coacervate droplets can dynamically respond to external stimuli.…”

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confidence: 99%

“…[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. 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. 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.…”

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confidence: 99%

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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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confidence: 99%

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confidence: 99%

Photoswitchable Phase Separation and Oligonucleotide Trafficking in DNA Coacervate Microdroplets

et al. 2019

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“…Biomimetic adhesions that can be triggered with an external stimulus provide similarly temporal and/or spatial control. [7] This requires regulating the adhesions in space at subcellular spatial resolution and within minutes. For instance, the adhesion of a GUV rich in negatively charged lipids can be induced at any given point in time using an external electric field and can be reversed by turning the trigger off.…”

Section: Stimuli Responsive Synthetic Cell To Matrix Adhesionmentioning

confidence: 99%

“…Additionally, the reversibility of cell adhesions is another important feature of cell adhesions, which should be considered in recapitulating cell adhesions. [7] This allowed to trigger adhesion under blue light and reverse it in the dark at similar time scales and to modulate the adhesion energy with light. [27] A prime example of spatiotemporal control over cell-matrix adhesions is observed during cell motility.…”

Section: Stimuli Responsive Synthetic Cell To Matrix Adhesionmentioning

confidence: 99%

“…The compartmentalization of incompatible biochemical reactions was a crucial step in the origin of life and allowed early cells to form a barrier with its environment. [7] Copyright 2018, American Chemical Society. [30] This compartmentalization helps the regulation of the metabolic pathways by making them more targeted and accurate and preventing their interference with each other.…”

Section: Cell-cell Adhesionmentioning

confidence: 99%

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Mimicking Adhesion in Minimal Synthetic Cells

et al. 2019

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Cell adhesions to the extracellular matrix and to neighboring cells are fundamental to cell behavior and have also been implemented into minimal synthetic cells, which are assembled from molecular building blocks from the bottom‐up. Investigating adhesion in cell mimetic models with reduced complexity provides a better understanding of biochemical and biophysical concepts underlying the cell adhesion machinery. In return, implementing cell–matrix and cell–cell adhesions into minimal synthetic cells allows reconstructing cell functions associated with cell adhesions including cell motility, multicellular prototissues, fusion of vesicles, and the self‐sorting of different cell types. Cell adhesions have been mimicked using both the native cell receptors and reductionist mimetics providing a variety of specific, reversible, dynamic, and spatiotemporally controlled interactions. This review gives an overview of different minimal adhesion modules integrated into different minimal synthetic cells drawing inspiration from cell and colloidal science.

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Self‐Assembly of Giant Unilamellar Vesicles by Film Hydration Methodologies

2019

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Self‐assembly of lipids or polymeric amphiphiles into vesicular structures has been achieved by various methods since the first generation of liposomes in the 1960s. Vesicles can be obtained with diameters from the nanometer to the micrometer regime. From the perspective of cell mimicking, vesicles with diameters of several micrometers are most relevant. These vesicles are called giant unilamellar vesicles (GUVs). Commonly used methods to form GUVs are solvent‐displacement techniques, especially since the development of microfluidics. These methodologies however, trap undesirable organic solvents in their membrane as well as other potentially undesired additives (surfactants, polyelectrolytes, polymers, etc.). In contrast to those strategies, summarized herein are solvent‐free approaches as suitable clean alternatives. The vesicles are formed from a dry thin layer of the lipid or amphiphilic polymers and are hydrated in aqueous media using the entropically favored self‐assembly of amphiphiles into GUVs. The rearrangement of the amphiphilic films into vesicular structures is usually aided by shear forces such as an alternative current (electroformation) or the swelling of water‐soluble polymeric supports (gel‐assisted hydration).

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Light-Guided Motility of a Minimal Synthetic Cell

Cited by 50 publications

References 31 publications

Photoswitchable Phase Separation and Oligonucleotide Trafficking in DNA Coacervate Microdroplets

Photoswitchable Phase Separation and Oligonucleotide Trafficking in DNA Coacervate Microdroplets

Mimicking Adhesion in Minimal Synthetic Cells

Self‐Assembly of Giant Unilamellar Vesicles by Film Hydration Methodologies

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