Affiliation:
1. Department of Chemical Engineering and Biotechnology University of Cambridge Cambridge UK
2. Instituto Andaluz de Ciencias de la Tierra CSIC–Universidad de Granada Granada Spain
3. Instituto Carlos I de Física Teórica y Computacional Universidad de Granada Granada Spain
Abstract
AbstractThe osmotic rupture of a cell, its osmotic lysis or cytolysis, is a phenomenon that active biological cell volume regulation mechanisms have evolved in the cell membrane to avoid. How then, at the origin of life, did the first protocells survive prior to such active processes? The pores of alkaline hydrothermal vents in the oceans form natural nanoreactors in which osmosis across a mineral membrane plays a fundamental role. Here, we discuss the dynamics of lysis and its avoidance in an abiotic system without any active mechanisms, reliant upon self‐organized behaviour, similar to the first self‐organized mineral membranes within which complex chemistry may have begun to evolve into metabolism. We show that such mineral nanoreactors could function as protocells without exploding because their self‐organized dynamics have a large regime in parameter space where osmotic lysis does not occur and homeostasis is possible. The beginnings of Darwinian evolution in proto‐biochemistry must have involved the survival of protocells that remained within such a safe regime.