Saved in:
Bibliographic Details
Main Authors: Siddique, Arslan, Chauhan, Dev, Dutton, Alethea, Reddy, Kavish, De, Soumya Kanti, Fahrenbach, Albert C., Barber, Tracie, Van Kranendonk, Martin, Wang, Anna
Format: Preprint
Published: 2026
Subjects:
Online Access:https://arxiv.org/abs/2604.05223
Tags: Add Tag
No Tags, Be the first to tag this record!
Table of Contents:
  • The emergence of membranous compartments (protocells) with encapsulated genetic material was a crucial step life's origin and evolution. The hot spring hypothesis for the origin of life suggests that protocells could have formed in hot spring pools and encapsulated organic matter. Previous investigations have focused on mimicking wet-dry (WD) cycles within a single pool, which precludes simulation of many hydrothermal field conditions, such as differential mineralogy, variable temperature and pH and water flow between multiple hot spring pools. Here, we present a modular 3D-printed hydrothermal field simulator that mimics the complex nature of hot spring fields by controlling the variability of a series of linked pools, including WD cycles, temperature, pH, mineralogy, and mixing of different fluids. Results from using the prototype hot spring field design demonstrate the ability to spontaneously form lipid vesicles that encapsulate organic matter within membranous compartments comprised of decanoic acid:decanol (4:1) or the phospholipids POPC:POPG (1:1). We observed distinct morphological differences in the vesicles, ranging from thick-walled multilamellar, thin-walled oligolamellar and unilamellar as well as giant unilamellar vesicles formed under multiple WD cycles in the simulator pools. Cargo encapsulation was favoured in the cell-like giant unilamellar and small oligolamellar vesicles. Overall, hot-spring simulator offers a customisable avenue for studying other hot spring processes such as prebiotic chemical reactions, mineral surface catalysis, and the complexity of hydrothermal field dynamics.