Toward the reconstitution of synthetic cell motility

Siton-Mendelson, Orit; Bernheim‐Groswasser, Anne

doi:10.1080/19336918.2016.1170260

Cited by 15 publications

(17 citation statements)

References 109 publications

(123 reference statements)

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“…Thus, the creation of artificial cell‐like structures by using bottom‐up biology is an expanding research field that aims to understand the mechanisms underlying biological processes via in vitro assembly of their essential components into artificial cells. In this regard, the method and the research imparting motility as living cells for cell‐like objects have been actively studied with reconstitution of bleb‐based migration with nonspecific (low) adhesion and protrusion‐based migration with specific (strong) adhesion, and more recently, protrusion‐based migration with specific adhesion, as well as photoswitchable protein interactions on the surface of an artificial cell, induced by light …”

Section: Toward Cellular Motilitiesmentioning

confidence: 99%

Toward Artificial Cells: Novel Advances in Energy Conversion and Cellular Motility

Jeong

Nguyen

Kim

et al. 2020

Adv Funct Materials

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The demand to discover every single cellular component has been continuously increasing along with the development of biological techniques. The bottom‐up approach to construct a cell‐mimicking system from well‐defined and tunable compositions is accelerating, with the ultimate goal of comprehending a biological cell. From among the available techniques, the artificial cell has been increasingly recognized as one of the most powerful tools for building a cell‐like system from scratch. This review summarizes the development of artificial cells, from a pure giant unilamellar vesicle (GUV) to a controllable, self‐fueled proteoliposome, both of which are highly compartmentalized. The basic components of an artificial cell, as well as the optimal conditions required for successful, reproducible GUV formation and protein reconstitution, are discussed. Most importantly, progress in studying the metabolic reactions in and the motility of a reconstituted artificial cell are the main focus of the review. The ability to perform a complicated reaction cascade in a controllable manner is highlighted as a promising perspective to obtaining an autonomous and movable GUV.

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Section: Toward Cellular Motilitiesmentioning

confidence: 99%

Toward Artificial Cells: Novel Advances in Energy Conversion and Cellular Motility

Jeong

Nguyen

Kim

et al. 2020

Adv Funct Materials

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“…[18] For example during cell motility, the cell dynamically has to alter its adhesions to move in a defined direction; the cell forms more and new adhesions to the matrix at the leading edge as it dissembles existing adhesions at the trailing edge. Among these, the adhesion of cells through integrin transmembrane receptors to extracellular matrix proteins such as fibronectin, collagen, and fibrinogen are the best most studied.…”

Section: Cell-matrix Adhesionsmentioning

confidence: 99%

“…Another layer of complexity in cell-matrix adhesions comes from their dynamics and their spatiotemporal regulation during different cell events including wound healing, immune response, and embryonic and tissue development. [18] For example during cell motility, the cell dynamically has to alter its adhesions to move in a defined direction; the cell forms more and new adhesions to the matrix at the leading edge as it dissembles existing adhesions at the trailing edge. Given the complexity of cellmatrix adhesion from the molecular, biophysical, signaling, and spatiotemporal control perspective, it is obvious that it is a challenge to reconstitute cell-adhesions from the bottom-up.…”

Section: Cell-matrix Adhesionsmentioning

confidence: 99%

“…[27] A prime example of spatiotemporal control over cell-matrix adhesions is observed during cell motility. [18] As the cell moves forward, it assembles new adhesions at the leading edge at the same rate as it disassembles them at the trailing edge. [7] This requires regulating the adhesions in space at subcellular spatial Adv.…”

Section: Stimuli Responsive Synthetic Cell To Matrix 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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“…[1,2] Conventionally, biomolecules, often proteins, have been isolated from cells and reconstituted in cell-sized confinement to reconstruct versatile cellular functions and sophisticated processes like adhesion, [3][4][5] energy generation, [6,7] or motility. [8][9][10] For efficient encapsulation of biocontent, droplet-based microfluidics proved to be a very useful technique due to its high degree of controllability and high-throughput formation of monodisperse compartments. [3,[11][12][13][14] In particular, actin networks have been reconstituted into water-in-oil droplets [15][16][17] and giant unilamellar vesicles [18][19][20] to observe the role of specific proteins regulating cellular morphology.…”

Section: Introductionmentioning

confidence: 99%

Engineering Light‐Responsive Contractile Actomyosin Networks with DNA Nanotechnology

et al. 2020

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External control and precise manipulation is key for the bottom‐up engineering of complex synthetic cells. Minimal actomyosin networks have been reconstituted into synthetic cells; however, their light‐triggered symmetry breaking contraction has not yet been demonstrated. Here, light‐activated directional contractility of a minimal synthetic actomyosin network inside microfluidic cell‐sized compartments is engineered. Actin filaments, heavy‐meromyosin‐coated beads, and caged ATP are co‐encapsulated into water‐in‐oil droplets. ATP is released upon illumination, leading to a myosin‐generated force which results in a motion of the beads along the filaments and hence a contraction of the network. Symmetry breaking is achieved using DNA nanotechnology to establish a link between the network and the compartment periphery. It is demonstrated that the DNA‐linked actin filaments contract to one side of the compartment forming actin asters and quantify the dynamics of this process. This work exemplifies that an engineering approach to bottom‐up synthetic biology, combining biological and artificial elements, can circumvent challenges related to active multi‐component systems and thereby greatly enrich the complexity of synthetic cellular systems.

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Toward the reconstitution of synthetic cell motility

Cited by 15 publications

References 109 publications

Toward Artificial Cells: Novel Advances in Energy Conversion and Cellular Motility

Toward Artificial Cells: Novel Advances in Energy Conversion and Cellular Motility

Mimicking Adhesion in Minimal Synthetic Cells

Engineering Light‐Responsive Contractile Actomyosin Networks with DNA Nanotechnology

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