Out-of-equilibrium microcompartments for the bottom-up integration of metabolic functions

Beneyton, Thomas; Krafft, Dorothee; Bednarz, Claudia; Kleineberg, Christin; Woelfer, Christian; Ivanov, Ivan; Vidaković‐Koch, Tanja; Sundmacher, Kai; Baret, Jean‐Christophe

doi:10.1038/s41467-018-04825-1

Cited by 59 publications

(51 citation statements)

References 67 publications

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“…These include energy conversion, [100] metabolism, [101] polarisation, [19] growth, [14,16,102] division, [103] signaling/communication, [97,104] and motility. In the context of using the bottom-up approach for the construction artificial cells, there are a number of functionalities currently being explored.…”

Section: Perspectives For Microfluidic Handling Of Artificial Cellsmentioning

confidence: 99%

Microfluidic Handling and Analysis of Giant Vesicles for Use as Artificial Cells: A Review

Robinson

2019

Adv. Biosys.

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One of the goals of synthetic biology is the bottom‐up construction of an artificial cell, the successful realization of which could shed light on how cellular life emerged and could also be a useful tool for studying the function of modern cells. Using liposomes as biomimetic containers is particularly promising because lipid membranes are biocompatible and much of the required machinery can be reconstituted within them. Giant lipid vesicles have been used extensively in other fields such as biophysics and drug discovery, but their use as artificial cells has only recently seen an increase. Despite the prevalence of giant vesicles, many experiments remain challenging or impossible due to their delicate nature compared to biological cells. This review aims to highlight the effectiveness of microfluidic technologies in handling and analyzing giant vesicles. The advantages and disadvantages of different microfluidic approaches and what new insights can be gained from various applications are introduced. Finally, future directions are discussed in which the unique combination of microfluidics and giant lipid vesicles can push forward the bottom‐up construction of artificial cells.

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Section: Perspectives For Microfluidic Handling Of Artificial Cellsmentioning

confidence: 99%

Microfluidic Handling and Analysis of Giant Vesicles for Use as Artificial Cells: A Review

Robinson

2019

Adv. Biosys.

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“…Besides the relevance for the Origins of Life, we hope that our work could trigger new research directions on applications of transient compartmentalization for chemistry or biochemistry. Perhaps, these new research directions could help overcome practical and fundamental hurdles associated with the synthesis of complex molecules, and facilitate the making of new catalysts or artificial cells [31].…”

Section: Resultsmentioning

confidence: 99%

Survival of self-replicating molecules under transient compartmentalization with natural selection

Laurent

Peliti²,

Lacoste

2019

Preprint

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The problem of the emergence and survival of self-replicating molecules in origin-of-life 1 scenarios is plagued by the error catastrophe, which is usually escaped by considering effects of 2 compartmentalization, as in the stochastic corrector model. By addressing the problem in a simple 3 system composed of a self-replicating molecule (a replicase) and a parasite molecule that needs the 4 replicase for copying itself, we show that transient (rather than permanent) compartmentalization 5 is sufficient to the task. We also exhibit a regime in which the concentrations of the two kinds of 6 molecules undergo sustained oscillations. Our model should be relevant not only for origin-of-life 7 scenarios but also for describing directed evolution experiments, which increasingly rely on transient 8 compartmentalization with pooling and natural selection.9

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“…Importantly, this metabolic system was able to convert chemical energy into movement, since the release of oxygen was capable of propelling the compartment. Although the metabolism was not tied to something useful for the cellular mimic, Beneyton et al [119] constructed water-in-oil droplets that contained enzymes that produced NADH and bacterially derived inverted vesicles with embedded, native NADH dehydrogenases. That is, NADH was continuously generated and consumed as long as the feedstock (glucose-6-phosphate) was present.…”

Section: Metabolic Pathwaysmentioning

confidence: 99%

Toward long-lasting artificial cells that better mimic natural living cells

Martín

Valer

Mansy

2019

Emerging Topics in Life Sciences

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Chemical communication is ubiquitous in biology, and so efforts in building convincing cellular mimics must consider how cells behave on a population level. Simple model systems have been built in the laboratory that show communication between different artificial cells and artificial cells with natural, living cells. Examples include artificial cells that depend on purely abiological components and artificial cells built from biological components and are driven by biological mechanisms. However, an artificial cell solely built to communicate chemically without carrying the machinery needed for self-preservation cannot remain active for long periods of time. What is needed is to begin integrating the pathways required for chemical communication with metabolic-like chemistry so that robust artificial systems can be built that better inform biology and aid in the generation of new technologies.

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Out-of-equilibrium microcompartments for the bottom-up integration of metabolic functions

Cited by 59 publications

References 67 publications

Microfluidic Handling and Analysis of Giant Vesicles for Use as Artificial Cells: A Review

Microfluidic Handling and Analysis of Giant Vesicles for Use as Artificial Cells: A Review

Survival of self-replicating molecules under transient compartmentalization with natural selection

Toward long-lasting artificial cells that better mimic natural living cells

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