Bridging the Gap Between Primitive and Modern Phase Separation

Cannelli, Selene M.C.; Gupta, Ritvik; Nguyen, Tan; Poddar, Arunava; Sharma, Srishti; Vithole, Prachiti V.; Jia, Tony Z.

doi:10.26434/chemrxiv-2023-fv8dp

Cited by 2 publications

(2 citation statements)

References 243 publications

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“…Upon hydration, Fox's proteinoids exhibit a remarkable ability to self-assemble into spherical vesicles. These microspherical membranes serve as a model for the formation of semi-permeable protocell structures from simple abiotic polypeptides [64][65][66][67][68][69].…”

Section: Membrane Assembly and Compositionmentioning

confidence: 99%

Proto-Neurons from Abiotic Polypeptides

Mougkogiannis,

Adamatzky

2024

Encyclopedia

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To understand the origins of life, we must first gain a grasp of the unresolved emergence of the first informational polymers and cell-like assemblies that developed into living systems. Heating amino acid mixtures to their boiling point produces thermal proteins that self-assemble into membrane-bound protocells, offering a compelling abiogenic route for forming polypeptides. Recent research has revealed the presence of electrical excitability and signal processing capacities in proteinoids, indicating the possibility of primitive cognitive functions and problem-solving capabilities. This review examines the characteristics exhibited by proteinoids, including electrical activity and self-assembly properties, exploring the possible roles of such polypeptides under prebiotic conditions in the emergence of early biomolecular complexity. Experiments showcasing the possibility of unconventional computing with proteinoids as well as modelling proteinoid assemblies into synthetic proto-brains are given. Proteinoids’ robust abiogenic production, biomimetic features, and computational capability shed light on potential phases in the evolution of polypeptides and primitive life from the primordial environment.

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Section: Membrane Assembly and Compositionmentioning

confidence: 99%

Proto-Neurons from Abiotic Polypeptides

Mougkogiannis,

Adamatzky

2024

Encyclopedia

View full text Add to dashboard Cite

show abstract

Section: Membrane Assembly and Compositionmentioning

confidence: 99%

Proto–Neurons from Abiotic Polypeptides

---,

Adamatzky

2023

Preprint

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Understanding the origins of life involves dealing with the unresolved question of how the first informational polymers and cell-like structures emerged from prebiotic chemistry. The formation of thermal proteinoids through the heating of mixtures of amino acids, leading to the spontaneous formation of protocells enclosed by membranes, presents a compelling model for the synthesis of polypeptides in an abiogenic context. Recent research has revealed the presence of electrical excitability and signal processing capacities in proteinoids, indicating the possibility of primitive cognitive functions and problem-solving capabilities. The present study provides a comprehensive examination of the features shown by heat proteinoids and their potential significance in the context of the artificial formation of polypeptides during the early stages of Earth’s development. Experiments showcasing the possibility for unconventional computing with proteinoids as well as modelling proteinoid assemblies into synthetic proto-brains are given. Proteinoids’ robust abiogenic production, biomimetic features, and computational capability shed light on potential phases in the evolution of polypeptides and primitive life from the primordial environment.

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Bridging the Gap Between Primitive and Modern Phase Separation

Cited by 2 publications

References 243 publications

Proto-Neurons from Abiotic Polypeptides

Proto-Neurons from Abiotic Polypeptides

Proto–Neurons from Abiotic Polypeptides

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