AI Article Synopsis
- * The study reveals that these droplets can grow by synthesizing new material driven by specific fuels, and they do not experience Ostwald ripening thanks to attractive interactions within the droplets.
- * Variations in environmental conditions and droplet composition, such as the addition of RNA, significantly impact the growth rates and overall fitness of these droplets, allowing them to serve as a model for studying cellular dynamics and population fitness.
Article Abstract
Active coacervate droplets are liquid condensates coupled to a chemical reaction that turns over their components, keeping the droplets out of equilibrium. This turnover can be used to drive active processes such as growth, and provide an insight into the chemical requirements underlying (proto)cellular behaviour. Moreover, controlled growth is a key requirement to achieve population fitness and survival. Here we present a minimal, nucleotide-based coacervate model for active droplets, and report three key findings that make these droplets into evolvable protocells. First, we show that coacervate droplets form and grow by the fuel-driven synthesis of new coacervate material. Second, we find that these droplets do not undergo Ostwald ripening, which we attribute to the attractive electrostatic interactions and translational entropy within complex coacervates, active or passive. Finally, we show that the droplet growth rate reflects experimental conditions such as substrate, enzyme and protein concentration, and that a different droplet composition (addition of RNA) leads to altered growth rates and droplet fitness. These findings together make active coacervate droplets a powerful platform to mimic cellular growth at a single-droplet level, and to study fitness at a population level.
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| http://www.ncbi.nlm.nih.gov/pmc/articles/PMC8217494 | PMC |
| http://dx.doi.org/10.1038/s41467-021-24111-x | DOI Listing |
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Article Synopsis
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