Issue 18, 2023

Designing negative feedback loops in enzymatic coacervate droplets

Abstract

Membraneless organelles within the living cell use phase separation of biomolecules coupled with enzymatic reactions to regulate cellular processes. The diverse functions of these biomolecular condensates motivate the pursuit of simpler in vitro models that exhibit primitive forms of self-regulation based on internal feedback mechanisms. Here, we investigate one such model based on complex coacervation of the enzyme catalase with an oppositely charge polyelectrolyte DEAE-dextran to form pH-responsive catalytic droplets. Upon addition of hydrogen peroxide “fuel”, enzyme activity localized within the droplets causes a rapid increase in the pH. Under appropriate conditions, this reaction-induced pH change triggers coacervate dissolution owing to its pH-responsive phase behavior. Notably, this destabilizing effect of the enzymatic reaction on phase separation depends on droplet size owing to the diffusive delivery and removal of reaction components. Reaction-diffusion models informed by the experimental data show that larger drops support larger changes in the local pH thereby enhancing their dissolution relative to smaller droplets. Together, these results provide a basis for achieving droplet size control based on negative feedback between pH-dependent phase separation and pH-changing enzymatic reactions.

Graphical abstract: Designing negative feedback loops in enzymatic coacervate droplets

Supplementary files

Article information

Article type
Edge Article
Submitted
11 Jul 2022
Accepted
13 Mar 2023
First published
19 Apr 2023
This article is Open Access

All publication charges for this article have been paid for by the Royal Society of Chemistry
Creative Commons BY-NC license

Chem. Sci., 2023,14, 4735-4744

Designing negative feedback loops in enzymatic coacervate droplets

N. Modi, S. Chen, I. N. A. Adjei, B. L. Franco, K. J. M. Bishop and A. C. Obermeyer, Chem. Sci., 2023, 14, 4735 DOI: 10.1039/D2SC03838B

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