Entropy-Driven Amino Acid-Based Coacervates with Enzyme-Free Metabolism and Prebiotic Robustness

Entropy-Driven Amino Acid-Based Coacervates with Enzyme-Free Metabolism and Prebiotic Robustness

Protocells capable of nonenzymatic metabolism and environmental adaptation are essential models for understanding the emergence of cellular life. However, existing protocell designs often lack the robustness or prebiotic relevance to explain how functional supramolecular assemblies could have formed...

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Bibliografische gegevens
Hoofdauteur: Shuai Cao (775058) (author)
Andere auteurs: Guangle Li (4458430) (author), Peng Zhou (116747) (author), Ehud Gazit (231491) (author), Xuehai Yan (591222) (author), Chengqian Yuan (4746615) (author)
Gepubliceerd in: 2025
Onderwerpen:
Biophysics
Biochemistry
Cell Biology
Genetics
Evolutionary Biology
Environmental Sciences not elsewhere classified
Astronomical and Space Sciences not elsewhere classified
Biological Sciences not elsewhere classified
Chemical Sciences not elsewhere classified
Information Systems not elsewhere classified
sustaining biochemical complexity
structures autonomously generate
stress tolerance within
geochemically plausible pathway
exhibit exceptional resilience
driven amino acid
compact spherical morphologies
also adaptively remodel
6 – 2
sudden environmental changes
early earth conditions
prebiotic pigment synthesis
including sulfur metabolism
δph ≈ 0
form membraneless protocells
sup >+</ sup
prebiotic conditions
environmental adaptation
prebiotic relevance
nonenzymatic metabolism
free metabolism
work highlights
synergistic effect
selective enrichment
results establish
proton gradient
nonenzymatic catalysis
mediated hydrogen
living systems
interfacial acceleration
integrating compartmentalization
high salinity
functional protocells
free reactions
extraterrestrial bodies
essential models
energy transduction
divalent cations
coacervation process
cellular life
bridge nonliving
bonding networks
based systems
based microcompartments
based coacervates
antiport activity
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Samenvatting:Protocells capable of nonenzymatic metabolism and environmental adaptation are essential models for understanding the emergence of cellular life. However, existing protocell designs often lack the robustness or prebiotic relevance to explain how functional supramolecular assemblies could have formed under early Earth conditions. In this study, we demonstrate that simple amino acid derivatives, observed on extraterrestrial bodies and under simulated prebiotic Earth conditions, undergo entropy-driven liquid–liquid phase separation to form membraneless protocells through a self-coacervation process. The synergistic effect of selective enrichment of metabolites and interfacial acceleration in these coacervate microdroplets enhances enzyme-free reactions, including sulfur metabolism and prebiotic pigment synthesis. The protocells are stabilized by water-mediated hydrogen-bonding networks and exhibit exceptional resilience to prebiotically plausible stressorssuch as high salinity (up to 4.0 M NaCl), high concentrations of divalent cations (4.0 M Mg<sup>2+</sup>/Ca<sup>2+</sup>), UV radiation, and extreme temperature fluctuationswhich typically disrupt existing vesicle-based systems. Remarkably, these structures autonomously generate and maintain a proton gradient (ΔpH ≈ 0.6–2.1) across their interfaces, enabling primitive chemiosmotic coupling via Na<sup>+</sup>–H<sup>+</sup> antiport activity. They also adaptively remodel into compact spherical morphologies in response to sudden environmental changes, thereby preserving structural integrity. By integrating compartmentalization, nonenzymatic catalysis, energy transduction, and stress tolerance within a minimalist amino acid framework, our results establish a geochemically plausible pathway for the formation and persistence of functional protocells. This work highlights the potential of coacervate-based microcompartments to bridge nonliving and living systems by sustaining biochemical complexity under prebiotic conditions.

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