Small-molecule autocatalysis drives compartment growth, competition and reproduction.
Heng LuAlex BlokhuisRebecca Turk-MacLeodJayaprakash KaruppusamyAndrea FranconiGabrielle WoronoffCyrille JeancolasAfshin AbrishamkarEstelle LoireFabien FerragePhilippe PelupessyLudovic JullienEörs SzathmaryPhilippe NgheAndrew D GriffithsPublished in: Nature chemistry (2023)
Sustained autocatalysis coupled to compartment growth and division is a key step in the origin of life, but an experimental demonstration of this phenomenon in an artificial system has previously proven elusive. We show that autocatalytic reactions within compartments-when autocatalysis, and reactant and solvent exchange outpace product exchange-drive osmosis and diffusion, resulting in compartment growth. We demonstrate, using the formose reaction compartmentalized in aqueous droplets in an emulsion, that compartment volume can more than double. Competition for a common reactant (formaldehyde) causes variation in droplet growth rate based on the composition of the surrounding droplets. These growth rate variations are partially transmitted after selective division of the largest droplets by shearing, which converts growth-rate differences into differences in droplet frequency. This shows how a combination of properties of living systems (growth, division, variation, competition, rudimentary heredity and selection) can arise from simple physical-chemical processes and may have paved the way for the emergence of evolution by natural selection.