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Engineering transient dynamics of artificial cells by stochastic distribution of enzymes

Chemistry

Engineering transient dynamics of artificial cells by stochastic distribution of enzymes

S. Song, A. F. Mason, et al.

This groundbreaking research introduces an innovative artificial platform that utilizes stochasticity to control the motility of artificial cells. By confining enzymes to fluidic polymer membranes, the study reveals how asymmetric distribution of propulsive units enhances motility in the presence of substrates, paving the way for synthetic systems mimicking life-like behaviors. This work was carried out by Shidong Song, Alexander F. Mason, Richard A. J. Post, Marco De Corato, Rafael Mestre, N. Amy Yewdall, Shoupeng Cao, Remco W. van der Hofstad, Samuel Sanchez, Loai K. E. A. Abdelmohsen, and Jan C. M. van Hest.

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~3 min • Beginner • English
Abstract
Random fluctuations are inherent to all complex molecular systems. Although nature has evolved mechanisms to control stochastic events to achieve the desired biological output, reproducing this in synthetic systems represents a significant challenge. Here we present an artificial platform that enables us to exploit stochasticity to direct motile behavior. We found that enzymes, when confined to the fluidic polymer membrane of a core-shell coacervate, were distributed stochastically in time and space. This resulted in a transient, asymmetric configuration of propulsive units, which imparted motility to such coacervates in presence of substrate. This mechanism was confirmed by stochastic modelling and simulations in silico. Furthermore, we showed that a deeper understanding of the mechanism of stochasticity could be utilized to modulate the motion output. Conceptually, this work represents a leap in design philosophy in the construction of synthetic systems with life-like behaviors.
Publisher
Nature Communications
Published On
Nov 25, 2021
Authors
Shidong Song, Alexander F. Mason, Richard A. J. Post, Marco De Corato, Rafael Mestre, N. Amy Yewdall, Shoupeng Cao, Remco W. van der Hofstad, Samuel Sanchez, Loai K. E. A. Abdelmohsen, Jan C. M. van Hest
DOI
https://doi.org/https://doi.org/10.1038/s41467-021-27229-0
Tags
artificial cells
stochasticity
coacervates
motility
synthetic systems
enzymes
propulsive units

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