An autonomously oscillating supramolecular self-replicator

A key goal of chemistry is to develop synthetic systems that mimic biology, such as self-assembling, self-replicating models of minimal life forms. Oscillations are often observed in complex biological networks, but oscillating, self-replicating species are unknown, and how to control autonomous sup...

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Veröffentlicht in:	Nature chemistry 2022-07, Vol.14 (7), p.805-810
Hauptverfasser:	Howlett, Michael G., Engwerda, Anthonius H. J., Scanes, Robert J. H., Fletcher, Stephen P.
Format:	Artikel
Sprache:	eng
Schlagworte:	639/638/541/966 639/638/904 Analytical Chemistry Biochemistry Biomimetics Chemistry Chemistry and Materials Science Chemistry/Food Science Control systems Equilibrium Inorganic Chemistry Kinetics Mass transport Microscopy Molecular pumps Nanotechnology Organic Chemistry Oscillations Physical Chemistry Reagents Replication Self-assembly Species Surfactants
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creator	Howlett, Michael G. Engwerda, Anthonius H. J. Scanes, Robert J. H. Fletcher, Stephen P.
description	A key goal of chemistry is to develop synthetic systems that mimic biology, such as self-assembling, self-replicating models of minimal life forms. Oscillations are often observed in complex biological networks, but oscillating, self-replicating species are unknown, and how to control autonomous supramolecular-level oscillating systems is also not yet established. Here we show how a population of self-assembling self-replicators can autonomously oscillate, so that simple micellar species repeatedly appear and disappear in time. The interplay of molecular and supramolecular events is key to observing oscillations: the repeated formation and disappearance of compartments is connected to a reaction network where molecular-level species are formed and broken down. The dynamic behaviour of our system across different length scales offers the opportunities for mass transport, as we demonstrate via reversible dye uptake. We believe these findings will inspire new biomimetic systems and may unlock nanotechnology systems such as (supra)molecular pumps, where compartment formation is controlled in time and space. Oscillations are widespread throughout the natural world and a number of fascinating inorganic oscillating reactions are known—but the formation and control of oscillating, self-replicating synthetic systems has remained challenging. Now, it has been shown that chemically fuelled oscillations within a network of organic replicators can drive supramolecular assembly and disassembly.
doi_str_mv	10.1038/s41557-022-00949-6
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subjects	639/638/541/966 639/638/904 Analytical Chemistry Biochemistry Biomimetics Chemistry Chemistry and Materials Science Chemistry/Food Science Control systems Equilibrium Inorganic Chemistry Kinetics Mass transport Microscopy Molecular pumps Nanotechnology Organic Chemistry Oscillations Physical Chemistry Reagents Replication Self-assembly Species Surfactants
title	An autonomously oscillating supramolecular self-replicator
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